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ROUNDABOUTS: AN INFORMATIONAL GUIDE/TRAFFIC CALMING� � .� �� , �, '� �" � � d �. , � �{ � �� , � �, ��: �� s� � �� 0 �� , �� u � Y ^ � , � �_ � d �� _ �� '- �� p �;n � �° � � ��LL. ` +M��k �� s ; . �., �� ''. ,oe _:,., �:'� �' . .� � '_,,.y�.0 '� s�.r;:�� '� '� "�� " ;; �. � !` � . , � ` �_ � �, �y �: no� '� #f � � �� . , �^ :.R r a � .. �.:„ �� • Q�-�•�i,� �� 7 .Z rt��e � . 1 r U.S. Department of Transportation Federal Highway Administration Publication No. FHWA-RD-00-067 �. _ � _ ` ':'1► .�. .� Foreword Roundabouts are a form of intersection control in common use throughout the world. Until recently, many transportation professionals and agencies in the United States have been hesitant to recommend and install roundabouts, however, due to a lack of objective nationwide guidelines on planning, performance, and design of roundabouts. Prior to the development of this guide, transportation professionals who were interested in roundabouts had to rely on foreign roundabout design guides, consultants with roundabout experience, or in some States, statewide roundabout design guides.To facilitate safe, optimal operation and designs that are both consistent at a national level and consequential for driver expectation and safety, the Federal Highway Administration (FHWA) developed this informational guide on roundabouts. The information supplied in this document, Roundabouts: An Informational Guide, is based on established international and U.S. practices and is supplemented by recent research.The guide is comprehensive in recognition of the diverse needs of transportation professionals and the public for introductory materiai through design detail, as well as the wide range of potential applications of roundabout intersections. Roundabout operation and safety performance are particularly sensitive to geometric design elements. Uncertainty regarding evaluation procedures can result in over-design and less safety.The "design prob- lem" is essentially one of determining a design that will accommodate the traffic demand while minimizing some combination of delay, crashes, and cost to ali users, including motor vehicies, pedestrians, and bicyclists. Evaluation procedures are suggested, or information is provided, to quantify and cost how well a design achieves each of these aims. Since there is no absolutely optimum design, this guide is not intended as an inflexible "rule book;' but rather attempts to explain some principles of good design and indicate potential tradeoffs. In this respect, the "design space" consists of performance evaluation models and design principies such as those pro- vided in this guide, combined with the expert heuristic knowledge of a designer. Adherence to these principles still does not ensure good design, which remains the responsibility of the designer. / '/ / .. � Michael F Trentacoste Director, Office of Safety Research and Development NOTICE This publication is disseminated under the sponsorship of the Department ofTransportation in the interest of information exchange.The publication does not constitute a standard, specification, or regulation. Any trade or manufacturers' names that appear herein are included solely because they are considered essen- tial to the object of the publication. Technical Report Documentation Page 1. Report No. 2. Government Accession No. 3. RecipienYs Catalog No. F H WA-R D-00-067 4. Title and Subtitle 5. Report Date ROUNDABOUTS: An Informational Guide June 2000 6. Performing Organization Code 7. Author(s) 8. Performing Organization Report No. Principal Investigator: Bruce W. Robinson (brobinsonC�?kittelson.com) Project 2425 Co-Investigators: Lee Rodegerdts, Wade Scarborough, Wayne Kittelson. Co-Authors: Rod Troutbeck, Werner Brilon, Lothar Bondzio, Ken Courage, Michael Kyte, John Mason, Aimee Flannery, Edward Myers, Jonathan Bunker, Georges Jacquemart. 9. Performing Organization Name and Address 10. Work Unit No. (TRAIS) Kittelson & Associates, Inc. http://roundabouts.kittelson.com 610 SW Alder Street, Suite 700 Portland, Oregon 97205 U.S.A. 11. Contract or Grant No. Subconsultants: Queensland University of Technology (Australial; Ruhr-University DTFH61-97-R-00038 Bochum (Germany); University of Florida; University of Idaho; Pennsylvania State University; Hurst-Rosche Engineers; Eppell Olsen & Partners (Australial; Buckhurst Fish and Jacquemart. 12. Sponsoring Agency Name and Address 13. Type of Report and Period Covered Federal Highway Administration Informational Guide Book Tumer-Fairbank Highway Research Center September 1997 to December 1999 6300 Georgetown Pike, HSR 20, Room No. T301 McLean, Virginia 22101 14. Sponsoring Agency Code 15. Supplementary Notes Joe G. Bared (Joe.BaredC�3fhwa.dot.gov) at the Turner-Fairbank Highway Research Center (http://www.tfhrc.gov) was the Technical Representative for the Federal Highway Administration. 16. Abstract The guidance supplied in this document, Roundabouts: An Informational Guide, is based on established intemational and U.S. practices and is supplemented by recent research. The guide is comprehensive in recognition of the diverse needs of transportation professionals and the public for introductory material through design detail, as well as the wide range of potential applications of roundabout intersections. The following topics are addressed: definition of a roundabout and what distinguishes roundabouts from traffic circles; public acceptance and legal issues associated with roundabouts; consideration of all user modes, including heavy vehicles, buses, transit, bicycles, and pedestrians; a methodology for identifying appropriate sites for roundabouts and the range of conditions for which roundabouts offer optimal performance; methodologies for estimating roundabout capacity, delays, and queues with reference to the Highway Capacity Manual; design principles and guidance on safety and geometric design, with reference to applicable national standards such as the AASHTO Policy on Geometric Design of Highways and Streets; guidelines for control features such as signing and pavement markings, with reference to the Manual on Uniform Traffic Control Devices; illumination; and landscaping. 17. Key Word 18. Distribution Statement Roundaboutls), Traffic Circlelsl, Intersection, Traffic Control, Intersection Design, No restrictions. This document is available to the Intersection Performance, Intersection Safety, Highway Capacity public through the National Technical Information Service, Springfield, Virginia 22181. 19. Security Classif. (of this report) 20. Security Classif. (of this page) 21. No. of Pages 22. Price Unclassified Unclassified 2gq Form DOT F 1700.7 (8-72) Reproduction of completed page authorized ou n a ou s Kittelson & Associates, �n�. A n I n fo r m a t i o n a I Queensland University of Technology G u i d e Ruhr-University Bochum University of Florida University of Idaho Pennsylvania State University Hurst-Rosche Engineers Eppell Olsen & Partners Buckhurst Fish & Jacquemart FHWA Project Manager: Joe Bared Joe. Ba red@fhwa.dot.gov 202-493-3314 http://www.tfhrc.gov �� U.S. Department of Transportation Federal Highway Administration Publication No. FHWA-RD-00-067 Table of Contents List of Exhibits Photo Credits Chapter 7 - Introduction 1.1 1.2 1.3 1.4 1.5 1.6 1.7 Scope of Guide Organization of Guide Defining Physical Features Key Dimensions Distinguishing Roundabouts from Other Circular Intersections Roundabout Categories References Chapter 2 - Policy Considerations 2.1 Characteristics 2.2 Multimodal Considerations 2.3 Costs Associated with Roundabouts 2.4 Legal Considerations 2.5 Public Involvement 2.6 Education 2.7 References Chapter 3 - Planning 3.1 Planning Steps 3.2 Considerations of Context 3.3 Number of Entry Lanes 3.4 Selection Categories 3.5. Comparing Operational Performance of Alternative Intersection Types 3.6 Space Requirements �� xiv 1 2 3 5 5 8 12 20 21 23 32 36 37 40 43 48 49 51 53 55 58 64 69 Roundabouts: An Informational Guide I � 3.7 Economic Evaluation 3.8 References Chapter 4 - Operation 4.1 4.2 4.3 4.4 4.5 4.6 Traffic Operation at Roundabouts Data Requirements Capacity Performance Analysis Computer Software for Roundabouts References Chapter 5 - Safety 5.7 5.2 5.3 5.4 5.5 Introduction Conflicts Crash Statistics Crash Prediction Models References Chapter 6 - Geometric Design 6.1 6.2 6.3 6.4 6.5 6.6 6.7 Introduction General Design Principles Geometric Elements Double-Lane Roundabouts Rural Roundabouts Mini-Roundabouts References 70 76 79 82 83 86 91 96 98 101 103 104 111 122 125 127 130 132 145 172 176 179 181 �i'�,` I Federal HighwayAdministration Chapter 7- Traffic Design and Landscaping 7.1 7.2 7.3 7.4 7.5 7.6 Signing Pavement Markings Illumination Work Zone Traffic Control Landscaping References Chapter 8 - System Considerations 8.7 Traffic Signals at Roundabouts 8.2 At-Grade Rail Crossings 8.3 Closely Spaced Roundabouts 8.4 Roundabout Interchanges 8.5 Roundabouts in an Arterial Network 8.6 Microscopic Simulation 8.7 References Glossary Bibliography Appendix A: Operations Analysis Formulas Appendix B: Example Roundabout Designs Appendix C: MUTCD Recommendations 183 185 197 202 205 207 209 277 213 215 217 219 223 227 229 231 240 251 257 265 Roundabouts:An Informational Guide I ��' List of Exhibits Chapter 1 - Introduction Exhibit 1-1. Exhibit 1-2. Exhibit 1-3. Exhibit 7-4. Exhibit 7-5. Exhibit 1-6. Exhibit 1-7. Exhibit 1-8 Exhibit 1-9 Exhibit 1-10 Exhibit 1-17 Exhibit 7-12 Exhibit 1-73 Drawing of key roundabout features. Description of key roundabout features. Drawing of key roundabout dimensions. Description of key roundabout dimensions. Comparison of roundabouts with traffic circles. Common design elements at roundabouts. Basic design characteristics for each of the six roundabout categories. Typical mini-roundabout. Typical urban compact. Typical urban single-lane roundabout. Typical urban double-lane roundabout. Typical rural single-lane roundabout. Typical rural double-lane roundabout Chapter 2 - Policy Considerations Exhibit 2-1. Average annual crash frequencies at 11 U.S. intersections converted to roundabouts. Exhibit 2-2. Pedestrian's chances of death if hit by a motor vehicle. Exhibit 2-3. Comparisons of vehicle-vehicle conflict points for intersections with four single-lane approaches. Exhibit 2-4. Fastest vehicle path through a double-lane roundabout Exhibit 2-5. Examples of aesthetic treatments. Exhibit 2-6. Examples of informational brochures. Exhibit 2-7. Driving straight through a roundabout. Exhibit 2-8. Turning left at a roundabout. Chapter 3 - Planning Exhibit 3-1. Maximum daily service volumes for a four-leg roundabout. Exhibit 3-2. Planning-level maximum daily service volumes for mini-roundabouts. 6 6 7 7 8 10 13 14 15 16 17 18 19 23 25 26 27 31 42 45 46 57 57 VN1 � Federal HighwayAdministration Exhibit3-3. Example of community enhancement roundabout. 59 Exhibit3-4. Example of traffic calming roundabouts. 60 Exhibit 3-5. Comparison of predicted rural roundabout injury crashes with ruraITWSC intersections. 61 Exhibit3-6. Comparisons of predicted injury crashes for single-lane and double-lane roundabouts with rural or urban signalized intersections. 61 Exhibit 3-7. Average delay per vehicle at the MUTCD peak hour signal warrant threshold. 63 Exhibit 3-8. Comparison ofTWSC and single-lane roundabout capacity. 65 Exhibit 3-9. Sample hourly distribution of traffic. 66 Exhibit 3-10. Annual savings in delay of single-lane roundabout versus AWSC, 50 percent of volume on the major street. 67 Exhibit 3-11. Annual savings in delay of single-lane roundabout versus AWSC, 65 percent of volume on the major street. 67 Exhibit 3-12. Delay savings for roundabouts vs. signal, 50 percent volume on major street. 69 Exhibit 3-13. Delay savings for roundabouts vs. signal, 65 percent volume on major street. 69 Exhibit 3-14. Assumptions for spatial comparison of roundabouts and comparable conventional intersections. 70 Exhibit 3-15. Area comparison: Urban compact roundabout vs. comparable signalized intersection. 71 Exhibit 3-16. Area comparison: Urban single-lane roundabout vs. comparable signalized intersection. 71 Exhibit 3-17. Area comparison: Urban double-lane roundabout vs. comparable signalized intersection. 72 Exhibit 3-18. Area comparison: Urban flared roundabouts vs. comparable signalized intersection. 72 Exhibit 3-19. Estimated costs for crashes of varying levels of severity. 74 Chapter 4 - Operation Exhibit 4-1. Conversion factors for passenger car equivalents Ipce). 84 Exhibit 4-2. Traffic flow parameters. 85 Exhibit 4-3. Approach capacity of a single-lane roundabout. 87 Exhibit 4-4. Approach capacity of a double-lane roundabout. 88 Roundabouts:An Informational Guide IX Exhibit4-5. Capacity reduction factors for short lanes. Exhibit4-6. Capacity comparison of single-lane and double-lane roundabouts. Exhibit 4-7. Capacity reduction factor M for a single-lane roundabout assuming pedestrian priority. Exhibit 4-8. Capacity reduction factor M for a double-lane roundabout assuming pedestrian priority. Exhibit 4-9. Control delay as a function of capacity and circulating flow. Exhibit 4-10. 95th-percentile queue length estimation. Exhibit 4-11. Summary of roundabout software products for operational analysis. Chapter 5 - Safety Exhibit 5-1 Exhibit 5-2. Exhibit 5-3. Exhibit 5-4. Exhibit 5-5. Exhibit 5-6. Exhibit 5-7. Exhibit 5-8. Exhibit 5-9. Exhibit 5-10. Exhibit 5-77. Exhibit 5-12. Exhibit 5-13. Exhibit 5-14. Exhibit 5-15. Exhibit 5-16. Vehicle conflict points for "T" Intersections with single-lane approaches. Vehicle conflict point comparison for intersections with single-lane approaches. Improper lane-use conflicts in double-lane roundabouts. Improper turn conflicts in double-lane roundabouts. Pedestrian-vehicle conflicts at signalized intersections. Pedestrian-vehicle conflicts at single-lane roundabouts. Bicycle conflicts at conventional intersections. Bicycle conflicts at roundabouts. Average annual crash frequencies at 11 U.S. intersections converted to roundabouts. Mean crash reductions in various countries. Reported proportions of major crash types at roundabouts. Comparison of collision types at roundabouts. Graphical depiction of collision types at roundabouts. Accident percentage per type of user urban roundabouts in 15 towns in western France. British crash rates for pedestrians at roundabouts and signalized intersections. Percentage reduction in the number of accidents by mode at 181 converted Dutch roundabouts. 89 89 90 91 93 95 97 105 106 107 108 109 109 110 111 112 112 113 114 115 116 117 117 "� I Federal HighwayAdministration Exhibit 5-77. British crash rates (crashes per million trips) for bicyclists and motorcyclists at roundabouts and signalized intersections. Exhibit 5-18. A comparison of crashes between signalized and roundabout intersections in 1998 in 15 French towns Chapter 6 - Geometric Design Exhibit 6-1. Basic geometric elements of a roundabout. Exhibit 6-2. Roundabout design process. Exhibit 6-3. Sample theoretical speed profile (urban compact roundaboutl. Exhibit 6-4. Recommended maximum entry design speeds. Exhibit 6-5. Fastest vehicle path through single-lane roundabout. Exhibit 6-6. Fastest vehicle path through double-lane roundabout Exhibit 6-7. Example of critical right-turn movement. Exhibit 6-8. Side friction factors at various speeds (metric units). Exhibit 6-9. Side friction factors at various speeds (U.S. customary unitsl. Exhibit 6-10. Speed-radius relationship (metric unitsl. Exhibit 6-11. Speed-radius relationship (U.S. customary units�. Exhibit 6-12. Vehicle path radii. Exhibit6.13. Approximated R4values and corresponding R, values (metric units). Exhibit 6-14. Approximated R4values and corresponding R, values (U.S. customary units). Exhibit 6-15. Through-movement swept path of WB-15 (WB-50) vehicle. Exhibit 6-16. Left-turn and right-turn swept paths of WB-15 (WB-50) vehicle. Exhibit 6-17. Exhibit 6-78. Exhibit 6-19. Exhibit 6-20. Exhibit 6-21. Exhibit 6-22. Key dimensions of nonmotorized design users. Radial alignment of entries. Recommended inscribed circle diameter ranges Approach widening by adding full lane. Approach widening by entry flaring. Minimum circulatory lane widths for two-lane roundabouts. 120 120 131 131 133 133 134 135 135 137 137 138 138 139 141 141 143 143 144 145 146 148 148 150 Roundabouts: An Informational Guide I XI Exhibit 6-23. Exhibit 6.24. Exhibit 6-25. Exhibit 6-26. Exhibit 6-27. Exhibit 6-28. Exhibit 6-29. Exhibit 6-30. Exhibit 6-37. Exhibit 6-32. Exhibit 6-33. Exhibit 6-34. Exhibit 6-35. Exhibit 6-36. Exhibit 6-37. Exhibit 6-38. Exhibit 6-39. Exhibit 6-40. Exhibit 6-47. Exhibit 6-42. Exhibit 6-43. Exhibit 6-44. Exhibit 6-45. Exhibit 6-46. Exhibit 6-47. Exhibit 6-48. Exhibit 6-49. Example of central island with a traversable apron Single-lane roundabout entry design. Single-lane roundabout exit design. Minimum splitter island dimensions. Minimum splinter island nose radii and offsets. Design values for stopping sight distance. Approach sight distance. Sight distance on circulatory roadway. Sign distance to crosswalk on exit. Intersection sight distance. Computed length of conflicting leg of intersection sight triangle. Sample plan view. Sample approach profile. Sample central island profile. Typical circulatory roadway section. Typical section with a truck apron. Provisions for bicycles. Sidewalk treatments. Example of right-turn bypass lane. Configuration of right-turn bypass lane with acceleration lane. Configuration of right-turn bypass lane with yield at exit leg. Sketched natural paths through a double-lane roundabout. Path overlap at a double-lane roundabout. One method of entry design to avoid path overlap at double-lane roundabouts. Alternate method of entry design to avoid path �overlap at double-lane roundabouts. Extended splitter island treatment. Use of successive curves on high-speed approaches. Exhibit 6-50. Example of mini-roundabout. 151 153 154 157 158 159 160 160 161 162 163 164 165 165 166 166 168 169 170 171 172 173 174 175 175 178 179 180 �� Federal HighwayAdministration Chapter 7- Traific Design and Landscaping Exhibit 7-7. YIELD sign (R1-2). Exhibit 7-2. ONE WAY sign (R6-1 R). Exhibit7-3. KEEP RIGHTsign (R4-7�. Exhibit 7-4. Lane-use control signing for roundabouts with double- lane entries. Exhibit 7-5. Exhibit 7-6. Exhibit 7-7. Exhibit 7-8. Exhibit 7-9. Exhibit 7-10. Exhibit 7-77. Exhibit 7-72. Exhibit 7-13. Exhibit 7-14. Exhibit 7-15. Exhibit 7-76. Exhibit 7-17. Exhibit 7-78. Exhibit 7-19. Exhibit 7-20. Exhibit 7-27. Exhibit 7-22. Exhibit 7-23. Exhibit 7-24. Lane-use control signing for roundabouts with heavy turning traffic. Circular Intersection sign (W2-6). Advisory speed plate (W13-1 �. Roundabout Ahead Sign. YIELD AHEAD sign (W3-2a). Large Arrow sign (W1-6). Chevron plate (W1-8a. Pedestrian Crossing sign (W11-2a). Examples of advance destination guide signs. Exit guide sign (D1-1). Sample signing plan for an urban roundabout. Sample signing plan for a rural roundabout. Examples of speed reduction treatments. Sample signing plan for a mini-roundabout. Examples of yield lines. Approach pavement markings. Sample pavement marking plan for a mini-roundabout Illumination of a roundabout. Recommended street illumination levels. Landscaping of the central island. .. :. :^ � 188 189 189 189 189 190 190 190 191 192 193 194 195 196 198 199 201 202 204 208 Roundabouts:An Informational Guide I XIIF Chapter 8 - System Considerations Exhibit 8-1. Exhibit 8-2. Exhibit 8.3. Exhibit 8-4. Exhibit 8-5. Exhibit 8-6. Exhibit 8-7. Exhibit 8.8. Exhibit 8-9. Exhibit 8-10. Exhibit 8-11. Rail crossing treatments at roundabouts. Methods for accommodating a rail crossing adjacent to a roundabout. Example of closely spaced offsetT-intersections with roundabouts. Through bypass lanes at staggeredT-intersections. Two-bridge roundabout interchange. Example of two-bridge roundabout interchanges. Examples of one-bridge roundabout interchanges with circular central islands. One-bridge roundabout interchange with raindrop- shaped central islands. Roundabouts in an arterial network. Wide nodes and narrow roads. Summary of simulation models for roundabout analysis. Photo Credits 216 217 218 218 219 220 221 222 223 226 228 Ba�ry Crown: Exhibits 8-6, 8-7 Ken Courage: Exhibit 1-5 (g, Portland) Lee Rodegerdts: Exhibits 1-5 (all except g, Portland�, 1-6 (all except Fort Pierce), 2- 4(all except Fort Pierce), 3-3, 3-4, 6-23, 6-42, 7-10 (all►, 7-11 (all), 7-14 (all), 7-16 (alp, 7-22, 8-7, 8-8, 8-9, C-3 (a, d—i, k—n) Paul Ryus: Exhibits 1-6 (Fort Pierce), 2-4 (Fort Pierce), C-3 (b, c, j) �� I Federal HighwayAdministration 7.1 1.2 1.3 1.4 1.5 1.6 7.7 Exhibit 1-1. Exhibit 1-2. Exhibit 1-3. Exhibit 1-4. Exhibit 1-5. Exhibit 1-6. Exhibit 1-7. Exhibit 1-8. Exhibit 1-9. Exhibit 1-10. Exhibit 1-11. Exhibit 7-12. Exhibit 1-13. Introduction Scope of the Guide Organization of the Guide Defining Physical Features Key Dimensions Distinguishing Roundabouts from Other Circular Intersections Roundabout Categories 1.6.1 Comparison of roundabout categories 1.6.2 Mini-roundabouts 1.6.3 Urban compact roundabouts 1.6.4 Urban single-lane roundabouts 1.6.5 Urban double-lane roundabouts 1.6.6 Rural single-lane roundabouts 1.6.7 Rural double-lane roundabouts References Drawing of key roundabout features. Description of key roundabout features. Drawing of key roundabout dimensions. Description of key roundabout dimensions. Comparison of roundabouts with traffic circles. Common design elements at roundabouts. Basic design characteristics for each of the six roundabout categories. Typical mini-roundabout. Typical urban compact roundabout. Typical urban single-lane roundabout. Typical urban double-lane roundabout. Typical rural single-lane roundabout. Typical rural double-lane roundabout. 2 3 5 5 8 12 13 14 15 16 17 18 19 20 6 6 7 7 8 10 13 14 15 16 17 18 fl�'] �'` Chapter � �ntroduction Circular intersections Traffic circles have been part of the transportation system in the United States were first introduced since 1905, when the Columbus Circle designed by William Phelps Eno opened in in the U.S. in 1905. NewYork City. Subsequently, many large circles or rotaries were built in the United States. The prevailing designs enabled high-speed merging and weaving of ve- hicles. Priority was given to entering vehicles, facilitating high-speed entries. High crash experience and congestion in the circles led to rotaries falling out of favor in America after the mid-1950's. Internationally, the experience with traffic circles was equally negative, with many countries experiencing circles that locked up as traffic volumes increased. The modern roundabout was developed in the United Kingdom in the 1960's. The modern roundabout was developed in the United Kingdom to rectify problems associated with these traffic circles. In 1966, the United Kingdom adopted a man- datory "give-way" rule at all circular intersections, which required entering traffic to give way, or yield, to circulating traffic. This rule prevented circular intersections from locking up, by not allowing vehicles to enter the intersection until there were sufficient gaps in circulating traffic. In addition, smaller circular intersections were proposed that required adequate horizontal curvature of vehicle paths to achieve slower entry and circulating speeds. Modem roundabouts These changes improved the safety characteristics of the circular intersections by provide substantially better reducing the number and particularly the severity of collisions. Thus, the resultant operational and safety modern roundabout is significantly different from the older style traffic circle both characteristics than in how it operates and in how it is designed. The modern roundabout represents a older traffic circles substantial improvement, in terms of operations and safety, when compared with and rotaries. older rotaries and traffic circles (1, 2, 3). Therefore, many countries have adopted them as a common intersection form and some have developed extensive design guides and methods to evaluate the operational performance of modern round- abouts. 1.1 Scope of the Guide This guide provides information and guidance on roundabouts, resulting in designs that are suitable for a variety of typical conditions in the United States. The scope of this guide is to provide general information, planning techniques, evaluation pro- cedures for assessing operational and safety performance, and design guidelines for roundabouts. This guide has been developed with the input from transportation practitioners and researchers from around the world. In many cases, items from national and inter- International consensus has national practice and research indicate considerable consensus, and these items not been achieved on some have been included in this guide. However, other items have generated consider- aspects of roundabout design. able differences of opinion (e.g., methods of estimating capacity�, and some prac- tices vary considerably from country to country (e.g., marking of the circulatory roadway in multilane roundabouts). Where international consensus is not appar- ent, a reasoned approach is presented that the authors believe is currently most appropriate for the United States. As more roundabouts are built, the opportunity to conduct research to refine—or develop better—methods will enable future edi- tions of this guide to improve. Federal HighwayAdministration Despite the comprehensive nature of this document, it cannot discuss every issue related to roundabouts. In particular, it does not represent the following topics: Nonmountable traffic ca/ming circles. These are small traffic circles with raised Topics not discussed in this guide. central islands. They are typically used on local streets for speed and volume control. They are typically not designed to accommodate large vehicles, and often left-turning traffic is required to turn left in front of the circle. Mini-round- abouts, which are presented, may be an appropriate substitute. Specific legal or policy requirements and language. The legal information that is provided in this guide is intended only to make the reader aware of potential issues. The reader is encouraged to consult with an attorney on specific legal issues before adopting any of the recommendations contained herein. Simi- larly, regarding policy information, the guide refers to or encompasses appli- cable policies, such as those of the American Association of State Highway and Transportation Officials (AASHT0) (4). It does not, however, establish any new policies. Roundabouts with more than two entry lanes on an approach. While acknowl- edging the existence and potential of such large roundabouts, the guide does not provide specific guidance on the analysis or design of such roundabouts. However, the design principles contained in this document are also applicable to larger roundabouts. The relative safety advantages of roundabout intersec- tions diminish at high traffic flows, particularly with regard to pedestrians and bicyclists.The advantages of larger roundabouts are their higher capacities that may make them attractive alternatives at sites with high traffic volumes. More intricate design is required to ensure adequate operational and safety perfor- mance. Therefore, expert operations and design advice should be sought and roundabout analysis software should be utilized in such circumstances. As us- ers and designers in the United States become more familiar with roundabouts, this experience may then be extended to such applications. 7.2 Organization of the Guide This guide has been structured to address the needs of a variety of readers includ- ing the general public, policy-makers, transportation planners, operations and safety analysts, conceptual and detailed designers.This chapter distinguishes roundabouts from other traffic circles and defines the types of roundabouts addressed in the remainder of the guide. The remaining chapters in this guide generally increase in the level of detail provided. Chapter 2—Policy Considerations: This chapter provides a broad overview of the performance characteristics of roundabouts.The costs associated with roundabouts versus other forms of intersections, legal issues, and public involvement techniques are discussed. Chapter 3—Planning: This chapter discusses general guidelines for identifying appropriate intersection control options, given daily traffic volumes, and procedures for evaluating the feasibility of a roundabout at a given location. Chapters 2 and 3 provide sufficient detail to enable a transportation planner to decide under which circumstances roundabouts are likely to be appropriate, and how they compare to alternatives at a specific location. Roundabouts: An Informational Guide • 1: Introduction I � Chapter 4—Operational Analysis: Methods are presented for analyzing the op- erational performance of each category of roundabout in terms of capacity, delay, and queuing. Chapter 5—Safety: This chapter discusses the expected safety performance of roundabouts. Chapter 6—Geometric Design: Specific geometric design principles for round- abouts are presented. The chapter then discusses each design element in detail, along with appropriate parameters to use for each type of roundabout. Chapter 7—Traffic Design and Landscaping: This chapter discusses a number of traffic design aspects once the basic geometric design has been established.These include signs, pavement markings, and illumination. In addition, the chapter pro- vides discussion on traffic maintenance during construction and landscaping. Chapter 8—System Considerations: This chapter discusses specific issues and treatments that may arise from the systems context of a roundabout. The material may be of interest to transportation planners as well as operations and design engineers. Signal control at roundabouts is discussed. The chapter then considers the issue of rail crossings through the roundabout or in close proximity. Round- abouts in series with other roundabouts are discussed, including those at freeway interchanges and those in signalized arterial networks. Finally, the chapter pre- sents simulation models as supplementary operational tools capable of evaluating roundabout performance within an overall roadway system. Appendices: Three appendices are provided to expand upon topics in certain chap- ters. Appendix A provides information on the capacity models in Chapter 4. Appen- dix B provides design templates for each of the categories of roundabout described in Chapter 1, assuming four perpendicular legs. Appendix C provides information on the alternative signing and pavement marking in Chapter 7. Margin notes have been Several typographical devices have been used to enhance the readability of the used to highlight important guide. Margin notes, such as the note next to this paragraph, highlight important points. points or identify cross-references to other chapters of the guide. References have been listed at the end of each chapter and have been indicated in the text using numbers in parentheses, such as: (3). New terms are presented in italics and are defined in the glossary at the end of the document. � I Federal HighwayAdministration 1.3 Defining Physical Features A roundabout is a type of circular intersection, but not all circular intersections can be classified as roundabouts. In fact, there are at least three distinct types of circu- lar intersections: Rotaries are old-style circular intersections common to the United States prior to the 1960's. Rotaries are characterized by a large diameter, often in excess of 100 m(300 ft). This large diameter typically results in travel speeds within the circulatory roadway that exceed 50 km/h (30 mph).They typically provide little or no horizontal deflection of the paths of through traffic and may even operate according to the traditional "yield-to-the-right" rule, i.e., circulating traffic yields to entering traffic. Neighborhood traffic circles are typically built at the intersections of local streets for reasons of traffic calming and/or aesthetics. The intersection approaches may be uncontrolled or stop-controlled. They do not typically include raised channelization to guide the approaching driver onto the circulatory roadway. At some traffic circles, left-turning movements are allowed to occur to the left of (clockwise around) the central island, potentially conflicting with other circulat- ing traffic. Roundabouts are circular intersections with specific design and traffic control features. These features include yield control of all entering traffic, channelized approaches, and appropriate geometric curvature to ensure that travel speeds on the circulatory roadway are typically less than 50 km/h (30 mph).Thus, round- abouts are a subset of a wide range of circular intersection forms. To more clearly identify the defining characteristics of a roundabout, consistent definitions for each of the key features, dimensions, and terms are used through- out this guide. Exhibit 1-1 is a drawing of a typical roundabout, annotated to iden- tify the key features. Exhibit 1-2 provides a description of each of the key features. 1.4 Key Dimensions For operational analysis and design purposes, it is useful to define a number of key dimensions. Exhibit 1-3 shows a number of key dimensions that are described in Exhibit 1-4. Note that these exhibits do not present all of the dimensions needed in the detailed analysis and design of roundabouts; these will be presented and de- fined in later chapters as needed. Roundabouts: An Informational Guide • 7: Introduction Types of circular intersections. Key roundabout features include: • Yield control of entering traffic • Channelized approaches • Appropriate geometric curvature to slow speeds Exhibit 1-1. Drawing of key roundaboutfeatures. Splitter islands have multiple roles. They: • Separate entering and exiting traffic • Deflect and slow entering traffic • Provide a pedestrian refuge Exhibit 1-2. Description of key roundabout features. Feature Central island Splitter island Circulatory roadway Apron Yield line Accessible pedestrian crossings Bicycle treatments Description The central island is the raised area in the center of a roundabout around which traffic circulates. A splitter island is a raised or painted area on an approach used to separate entering from exiting traffic, deflect and slow entering traffic, and provide storage space for pedestrians crossing the road in two stages. The circulatory roadway is the curved path used by vehicles to travel in a counter- clockwise fashion around the central island If required on smaller roundabouts to accommodate the wheel tracking of large vehicles, an apron is the mountable portion of the central island adjacent to the circulatory roadway. A yield line is a pavement marking used to mark the point of entry from an ap- proach into the circulatory roadway and is generally marked along the inscribed circle. Entering vehicles must yield to any circulating traffic coming from the left before crossing this line into the circulatory roadway. Accessible pedestrian crossings should be provided at all roundabouts. The cross- ing location is set back from the yield line, and the splitter island is cut to allow pedestrians, wheelchairs, strollers, and bicycles to pass through. Bicycle treatments at roundabouts provide bicyclists the option of traveling through the roundabout either as a vehicle or as a pedestrian, depending on the bicyclist's level of comfort. Landscaping buffer Landscaping buffers are provided at most roundabouts to separate vehicular and pedestrian traffic and to encourage pedestrians to cross only at the designated crossing locations. Landscaping buffers can also significantly improve the aesthet- ics of the intersection. Federal HighwayAdministration Exhibit 1-3. Drawing of key roundabout dimensions. Exhibit 7-4. Description of key roundabout dimensions. Dimension Inscribed circle diameter Circulatory roadway width Approach width Departure width Entry width Exit width Entry radius Exit radius Description The inscribed circle diameier is the basic parameter used to define the size of a round- about. It is measured between the outer edges of the circulatory roadway. The circulatoryroadway width defines the roadway width for vehicle circulation around the central island. It is measured as the width between the outer edge of this roadway and the central island. It does not include the width of any mountable apron, which is defined to be part of the central island. The approach width is the width of the roadway used by approaching traffic upstream of any changes in width associated with the roundabout.The approach width is typically no more than half of the total width of the roadway. The departure width is the width of the roadway used by departing traffic downstream of any changes in width associated with the roundabout. The departure width is typically less than or equal to half of the total width of the roadway. The entry widih defines the width of the entry where it meets the inscribed circle. It is measured perpendicularly from the right edge of the entry to the intersection point of the left edge line and the inscribed circle. The exit width defines the width of the exit where it meets the inscribed circle. It is mea- sured perpendicularly from the right edge of the exit to the intersection point of the left edge line and the inscribed circle. The entry radius is the minimum radius of curvature of the outside curb at the entry. The exit radius is the minimum radius of curvature of the outside curb at the exit. Roundabouts: An Informational Guide • 1: Introduction Circular intersections that do not conform to the characteristics of modem roundabouts are called "traffic circles" in this guide. Exhibit 1-5. Comparison of roundabouts with traffic circles. Roundabouts must have all of the characteristics listed in the left column. Chapter 8 discusses signalization at roundabouts. 1.5 Distinguishing Roundabouts from Other Circular Intersections Since the purpose of this guide is to assist in the planning, design, and perfor- mance evaluation of roundabouts, not other circular intersections, it is important to be able to distinguish between them. Since these distinctions may not always be obvious, the negative aspects of rotaries or neighborhood traffic circles (hereafter referred to as "traffic circles") may be mistaken by the public for a roundabout. Therefore, the ability to carefully distinguish roundabouts from traffic circles is im- portant in terms of public understanding. How then does one distinguish a roundabout from other forms of circular intersec- tion? Exhibit 1-5 identifies some of the major characteristics of roundabouts and contrasts them with other traffic circles. Note that some of the traffic circles shown have many of the features associated with roundabouts but are deficient in one or more critical areas. Note also that these characteristics apply to yield-controlled roundabouts; signalized roundabouts are a special case discussed in Chapter 8. Roundabouts TrafFic Circles (a) Traffic control Yield control is used on all entries. The circulatory roadway has no control. Santa Barbara, CA Some traffic circles use stop control, or no control, on one or more entries. Hagerstown, MD (b) Priority to circulating vehicles Circulating vehicles have the right-of- way. Santa Barbara, CA Some traffic circles require circulating traffic to yield to entering traffic. Sarasota, FL $ I Federal HighwayAdministration Roundabouts Traffic Circles Exhibit 1-5. Icontinued). Comparison of roundabouts with traffic circles. (c) Pedestrian access Pedestrian access is allowed only across the legs of the roundabout, behind the yield line. Santa Barbara, CA Some traffic circles allow pedestrian ac- cess to the central island. Sarasota. FL (d) Parking No parking is allowed within the circula- tory roadway or at the entries. Avon, CO Some traffic circles allow parking within the circulatory roadway. Sarasota, FL (e) Direction of circulation All vehicles circulate counter-clockwise Some neighborhood traffic circles allow and pass to the right of the central is- left-turning vehicles to pass to the left land. Naples, FL of the central island. Portland, OR Roundabouts: An Informational Guide • 1: Introduction All traffic circulates counter-clockwise around a roundabouts central island. Exhibit 7-6. Common design elements at roundabouts. Roundabouts may have these additional design features. In addition to the design elements identified in Exhibit 1-5, roundabouts often in- clude one or more additional design elements intended to enhance the safety and/ or capacity of the intersection. However, their absence does not necessarily pre- clude an intersection from operating as a roundabout. These additional elements are identified in Exhibit 1-6. Characteristic (a) Adequate speed reduction Description Good roundabout design requires entering vehicles to nego- tiate a small enough radius to slow speeds to no greater than 50 km/h (30 mph). Once within the circulatory roadway, ve- hicles' paths are further deflected by the central island. West Boca Raton, FL Some roundabouts allow high-speed entries for major move- ments. This increases the risk for more severe collisions for vehicles, bicycles, and pedestrians. Bradenton Beach, FL �� Federal HighwayAdministration Characteristic Description Exhibit 1-6 (continuedl. Common design elements at roundabouts. (b) Design vehicle Good roundabout design makes accommodation for the ap- propriate design vehicle. For small roundabouts, this may re- quire the use of an apron. Lothian, MD Some roundabouts are too small to accommodate large ve- hicles that periodically approach the intersection. Nap/es, FL (c) Entry flare � � . `" - � � �' ° � a � . ,�"�i.= �9 y� 9 .. + �.r �$ �� _ i+� � , + ..,., � �. �:�� . �� T .�: Flare on an entry to a roundabout is the widening of an ap- proach to multiple lanes to provide additional capacity and storage at the yield line. Long Beach, CA Aprons can be used in small roundabouts to accommodate the occasional large vehicle that may use the intersection. Roundabouts: An Informational Guide • 1: Introduction I 11- Exhibit 1-6 (continued). Common design elements at roundabouts. This guide uses six basic roundabout categories. Multilane roundabouts with more than two approach lanes are possible, but not explicitly covered in this guide. Characteristic (d) Splitter island (e) Pedestrian crossing loca- tions Description All except mini-roundabouts have raised splitter islands.These are designed to separate traffic moving in opposite directions, deflect entering traffic, and to provide opportunities for pedes- trians to cross in two stages. Mini-roundabouts may have split- ter islands defined only by pavement markings. Tavares, FL Pedestrian crossings are located at least one vehicle length upstream of the yield point. Fort Pierce, FL 7.6 Roundabout Categories For the purposes of this guide, roundabouts have been categorized according to size and environment to facilitate discussion of specific performance or design issues. There are six basic categories based on environment, number of lanes, and size: • Mini-roundabouts • Urban compact roundabouts • Urban single-lane roundabouts • Urban double-lane roundabouts • Rural single-lane roundabouts • Rural double-lane roundabouts Multilane roundabouts with more than two approach lanes are possible, but they are not covered explicitly by this guide, although many of the design principles con- tained in this guide would still apply. For example, the guide provides guidance on the �� I Federal HighwayAdministration �. design of flaring approaches from one to two lanes. Although not explicitly discussed, this guidance could be extended to the design of larger roundabout entries. Note that separate categories have not been explicitly identified for suburban envi- Suburban roundabouts incorporate ronments. Suburban settings may combine higher approach speeds common in elements of both urban and rural rural areas with multimodal activity that is more similar to urban settings. There- roundabouts. fore, they should generally be designed as urban roundabouts, but with the high- speed approach treatments recommended for rural roundabouts. In most cases, designers should anticipate the needs of pedestrians, bicyclists, and large vehicles. Whenever a raised splitter island is provided, there should also be an at-grade pedestrian refuge. In this case, the pedestrian crossing facilitates two separate moves: curb-to-island and island-to-curb. The exit crossing will typi- cally require more vigilance from the pedestrian and motorist than the entry cross- ing. Further, it is recommended that all urban crosswalks be marked. Under all urban design categories, special attention should be given to assist pedestrian users who are visually impaired or blind, through design elements. For example, these users typically attempt to maintain their approach alignment to continue across a street in the crosswalk, since the crosswalk is often a direct extension of the sidewalk. A roundabout requires deviation from that alignment, and attention needs to be given to providing appropriate informational cues to pedestrians re- garding the location of the sidewalk and the crosswalk, even at mini-roundabouts. For example, appropriate landscaping is one method of providing some informa- tion. Another is to align the crosswalk ramps perpendicular to the pedestrian's line of travel through the pedestrian refuge. 1.6.1 Comparison of roundabout categories Roundabout design should generally accommodate pedestrian, bicycle, and large vehicle use. Exhibit 1-7 summarizes and compares some fundamental design and operational Exhibit 1-7. Basic design elements for each of the six roundabout categories developed for this guide. The characteristics for each of the six following sections provide a qualitative discussion of each category. roundabout categories. Mini- Urban Urban Urban Rural Rural Design Element Roundabout Compact Single-Lane Double-Lane Single-Lane Double-�ane Recommended 25 km/h 25 km/h 35 km/h maximum entry (15 mph) (15 mph) (20 mph) design speed Maximum number of entering lanes perapproach 40 km/h (25 mph) 2 40 km/h 50 km/h (25 mph) (30 mph) f�: Typical inscribed 13 m to 25 m 25 to 30 m 30 to 40 m 45 to 55 m 35 to 40 m 55 to 60 m circle diameter' (45 ft to 80 ft) (80 to 100 ft) (100 to 130 ft) (150 to 180 ft) (115 to 130 ft) (180 to 200 ft) Splitter island Raised if Raised, with Raised, with Raised, with Raised and Raised and treatment possible, crosswalk cut crosswalk cut crosswalk cut extended, with extended, with crosswalk crosswalk cut crosswalk cut cut if raised Typical daily service 10,000 15,000 volumes on 4-leg roundabout (veh/day) 1. Assumes 90-degree entries and no more than four legs. 20,000 Refer to 20,000 Refer to Chapter 4 Chapter 4 procedures procedures Roundabouts: An Informational Guide • 1: Introduction I 13' 1.6.2 Mini-roundabouts Mini-roundabouts can be useful Mini-roundabouts are small roundabouts used in low-speed urban environments, in low-speed urban with average operating speeds of 60km/h (35mph) or less. Exhibit 1-8 provides an environments with riyht-of-way example of a typical mini-roundabout. They can be useful in low speed urban envi- constraints. ronments in cases where conventional roundabout design is precluded by right-of- way constraints. In retrofit applications, mini-roundabouts are relatively inexpen- sive because they typically require minimal additional pavement at the intersecting roads-for example, minor widening at the corner curbs. They are mostly recom- mended when there is insufficient right-of-way for an urban compact roundabout. Because they are small, mini-roundabouts are perceived as pedestrian-friendly with short crossing distances and very low vehicle speeds on approaches and exits.The mini-roundabout is designed to accommodate passenger cars without requiring them to drive over the central island. To maintain its perceived compactness and low speed characteristics, the yield lines are positioned just outside of the swept path of the largest expected vehicle. However, the central island is mountable, and larger vehicles may cross over the central island, but not to the left of it. Speed control around the mountable central island should be provided in the design by requiring horizontal deflection. Capacity for this type of roundabout is expected to be similar to that of the compact urban roundabout. The recommended design of these roundabouts is based on the German method, with some influence from the United Kingdom. Exhibit 1-8. Typical mini-roundabout. ��' I Federal HighwayAdministration 1.6.3 Urban compact roundabouts Like mini-roundabouts, urban compact roundabouts are intended to be pedestrian- and bicyclist-friendly because their perpendicular approach legs require very low vehicle speeds to make a distinct right turn into and out of the circulatory roadway. All legs have single-lane entries. However, the urban compact treatment meets all the design requirements of effective roundabouts. The principal objective of this design is to enable pedestrians to have safe and effective use of the intersection. Capacity should not be a critical issue for this type of roundabout to be considered. The geometric design includes raised splitter islands that incorporate at-grade pe- destrian storage areas, and a nonmountable central island.There is usually an apron surrounding the nonmountable part of the compact central island to accommodate large vehicles.The recommended design of these roundabouts is similar to those in Germany and other northern European countries. Exhibit 1-9 provides an ex- ample of a typical urban compact roundabout. Roundabouts: An Informational Guide • 1: Introduction Urban compact roundabouts are intended to be pedestrian-friendly; capacity should not be a critical issue when considering this type. Exhibit 1-9. Typical urban compact roundabout. 1.6.4 Urban single-lane roundabouts Urban single-lane roundabouts have This type of roundabout is characterized as having a single lane entry at all legs and slightly higher speeds and capacities one circulatory lane. Exhibit 1-10 provides an example of a typical urban single-lane than urban compact roundabouts. roundabout.They are distinguished from urban compact roundabouts by their larger inscribed circle diameters and more tangential entries and exits, resulting in higher capacities. Their design allows slightly higher speeds at the entry, on the circula- tory roadway, and at the exit. Notwithstanding the larger inscribed circle diameters than compact roundabouts, the speed ranges recommended in this guide are some- what lower than those used in other countries, in order to enhance safety for bi- The design focuses on consistent entering and exiting speeds. cycles and pedestrians.The roundabout design is focused on achieving consistent entering and circulating vehicle speeds.The geometric design includes raised split- ter islands, a nonmountable central island, and preferably, no apron.The design of these roundabouts is similar to those in Australia, France, and the United Kingdom. Exhibit 1-10. Typical urban single-lane roundabout. ��' Federai HighwayAdministration ,r 1.6.5 Urban double-lane roundabouts Urban double-lane roundabouts include all roundabouts in urban areas that have at least one entry with two lanes. They include roundabouts with entries on one or more approaches that flare from one to two Ianes.These require wider circulatory roadways to accommodate more than one vehicle traveling side by side. Exhibit 1- 11 provides an example of a typical urban multilane roundabout.The speeds at the entry, on the circulatory roadway, and at the exit are similar to those for the urban single-lane roundabouts. Again, it is important that the vehicular speeds be consis- tent throughout the roundabout. The geometric design will include raised splitter islands, no truck apron, a nonmountable central island, and appropriate horizontal deflection. Alternate routes may be provided for bicyclists who choose to bypass the round- about. Bicycle and pedestrian pathways must be clearly delineated with sidewalk construction and landscaping to direct users to the appropriate crossing locations and alignment. Urban double-lane roundabouts located in areas with high pedes- trian or bicycle volumes may have special design recommendations such as those provided in Chapters 6 and 7. The design of these roundabouts is based on the methods used in the United Kingdom, with influences from Australia and France. Roundabouts: An Informational Guide • 7: Introduction The urban double-lane roundabout category includes roundabouts with one or more entries that flare from one to two lanes. See Chapters 6 and 7 for special design considerations for pedestrians and bicycles. Exhibit 7-71. Typical urban double-lane roundabout. Because of their higher approach speeds, rural single-lane roundabouts require supplementary geometric and traffic control device treatments on the approaches. 1.6.6 Rural single-lane roundabouts Rural single-lane roundabouts generally have high average approach speeds in the range of 80 to 100 km/h (50 to 60 mph).They require supplementary geometric and traffic control device treatments on approaches to encourage drivers to slow to an appropriate speed before entering the roundabout. Rural roundabouts may have larger diameters than urban roundabouts to allow slightly higher speeds at the entries, on the circulatory roadway, and at the exits.This is possible if few pedestri- ans are expected at these intersections, currently and in future.There is preferably no apron because their larger diameters should accommodate larger vehicles. Supplemental geometric design elements include extended and raised splitter is- lands, a nonmountable central island, and adequate horizontal deflection. The de- sign of these roundabouts is based primarily on the methods used by Australia, France, and the United Kingdom. Exhibit 1-12 provides an example of a typical rural single-lane roundabout. Rural roundabouts that may Rural roundabouts that may one day become part of an urbanized area should be become part of an urbanized designed as urban roundabouts, with slower speeds and pedestrian treatments. area should include urban However, in the interim, they should be designed with supplementary approach roundabout design features. and entry features to achieve safe speed reduction. Exhibit 1-12. Typical rural single-lane roundabout. Pedestrian � aocommodations Exit is somewhat tangential than ur Larger diameter than urban forms . � / Apron (if required) ,� I Federal HighwayAdministration 1.6.7 Rural double-lane roundabouts Rural double-lane roundabouts have speed characteristics similar to rural single- lane roundabouts with average approach speeds in the range of 80 to 100 km/h (50 to 60 mphl.They differ in having two entry lanes, or entries flared from one to two lanes, on one or more approaches. Consequently, many of the characteristics and design features of rural double-lane roundabouts mirror those of their urban coun- terparts. The main design differences are designs with higher entry speeds and larger diameters, and recommended supplementary approach treatments. The design of these roundabouts is based on the methods used by the United King- dom, Australia, and France. Exhibit 1-13 provides an example of a typical rural double- lane roundabout. Rural roundabouts that may one day become part of an urbanized area should be designed for slower speeds, with design details that fully accom- modate pedestrians and bicyclists. However, in the interim they should be de- signed with approach and entry features to achieve safe speed reduction. � — ,_ � �` Pedestrian accommodations � Extended splitter islands and supplemental approach treatmeMs . .� � ' �,�- � � � 1� 1 '� � Exit is somewhat more tangerKial than urban forms Rural double-lane roundabouts have higher entry speeds and larger diameters than their urban counterparts. Exhibit 7-13. Typical rural double-lane roundabout. Roundabouts: An Informational Guide • 7: Introduction I��.; 1.7 References 1. Brown, M. TRL State of the Art Review—The Design of Roundabouts. London: HMSO, 1995. 2. Todd, K. ';4 history of roundabouts in Britain" Transportation Quarterly, Vol. 45, No. 1, January 1991. 3. Jacquemart, G. Synthesis of Highway Practice 264: Modern Roundabout Prac- tice in the United States. National Cooperative Highway Research Program. Wash- ington, D.C: National Academy Press, 1998. 4. American Association of State Highway andTransportation Officials (AASHT01. A Policy on Geometric Design of Highways and Streets. Washington, D.C.: AASHTO, 1994. ,�� Federal HighwayAdministration d;� ' 2.1 2.2 2.3 2.4 Policy Considerations Characteristics 2.1.1 Safety 2.1.2 Vehicle delay and queue storage 2.1.3 Delay of major movements 2.1.4 Signal progression 2.1.5 Environmental factors 2.1.6 Spatial requirements 2.1.7 Operation and maintenance costs 2.1.8 Traffic calming 2.1.9 Aesthetics 2.1.10 Design for older drivers Multimodal Considerations 2.2.1 Pedestrians 2.2.2 Bicycles 2.2.3 Large vehicles 2.2.4 Transit 2.2.5 Emergency vehicles 2.2.6 Rail crossings Costs Associated with Roundabouts Legal Considerations 2.4.1 Definition of "intersection" 2.4.2 Right-of-way between vehicles 2.4.3 Required lane position at intersections 2.4.4 Priority within the circulatory roadway 2.4.5 Pedestrian accessibility 2.4.6 Parking 23 23 28 28 29 29 29 30 30 30 31 32 32 34 34 35 35 35 36 37 37 38 38 38 39 40 2.5 Public Involvement 40 2.5.1 Public meetings 41 2.5.2 Informational brochures 41 2.5.3 Informational videos 43 2.5.4 Media announcements 43 2.6 Education 43 2.6.1 Driver education 43 2.6.2 Bicyclist education 47 2.6.3 Pedestrian education 47 2.7 References 48 Exhibit 2-1. Average annual crash frequencies at 11 23 U.S. intersections converted to roundabouts. Exhibit 2-2. Pedestrian's chances of death if hit by a motor vehicle. 25 Exhibit 2-3. Comparisons of vehicle-vehicle conflict points for 26 intersections with four single-lane approaches. Exhibit 2-4. Fastest vehicle path through a double-lane roundabout. 27 Exhibit 2-5. Examples of aesthetic treatments. 31 Exhibit 2-6. Examples of informational brochures. 42 Exhibit 2-7. Driving straight through a roundabout. 45 Exhibit 2-8. Turning left at a roundabout. 46 2Z!, � Federal HighwayAdministration Chapter 2 policy Considerations Roundabouts have unique characteristics that warrant consideration by developers and managers of the road system.This chapter provides a general overview of the characteristics of roundabouts and policy considerations pertaining to them. The information may be useful to policy makers and the general public. The reader is encouraged to refer to later chapters on the specifics associated with planning, operation, safety, and design of roundabouts. 2.1 Characteristics The previous chapter described the physical features of a roundabout. This section describes performance characteristics that need to be considered, either at a policy level when introducing roundabouts into a region or at specific locations where a roundabout is one of the alternatives being considered. 2.1.1 Safety This section provides an overview of the safety performance of roundabouts and then discusses the general characteristics that lead to this performance. It does not attempt to discuss all of the issues related to safety; the reader is encouraged to refer to Chapter 5 for a more detailed discussion. Roundabouts are generally safer than other forms of intersection in terms of ag- Roundabouts have been gregate crash statistics for low and medium traffic capacity conditions (1). Injury demonstrated to be generally safer crash rates for motor vehicle occupants are generally lower, although the propor- for motor vehicles and pedestrians tion of single-vehicle crashes is typically higher. However, bicyclists and pedestri- than other forms of at-grade ans are involved in a relatively higher proportion of injury accidents than they are at intersections. other intersections (2). Exhibit 2-1 presents comparisons of before and after aggregate crash frequencies (average annual crashes per roundabout) involving users of eleven roundabouts constructed in the United States (31. The decrease in severe injury crashes is note- worthy. However, the "before" situation at these intersections required mitigation for safety. Therefore, some other feasible alternatives may also be expected to have resulted in a reduction in the crash frequencies.This studyyielded insufficient data to draw conclusions regarding the safety of bicyclists and pedestrians. Type of Before roundabout roundabout Sites Total Inj.' PDO° Single-Lane' 8 4.8 2.0 2.4 Multilanez 3 21.5 5.8 15.7 Exhibit 2-7. Average annual crash frequencies at 11 U.S. intersections converted to roundabouts. Roundabout Total Inj. PDO 2.4 0.5 1.6 15.3 4.0 11.3 Total 11 9.3 3.0 6.0 5.9 1.5 Notes: 1. Mostly single-lane roundabouts with an inscribed circle diameter of 30 to 35 m(100 to 115 ftl. 2. Multilane roundabouts with an inscribed circle diameter greater than 50 m(165 ftl. 3. Inj. = Injury crashes. 4. PDO = Property Damage Only crashes. Source: (3) 4.2 Percent change Total Inj. PDO -51 % -73 % -32 % -29% -31 % -10% -37% -51 % -29% Roundabouts: An Informational Guide • 2: Policy Considerations I�r� Good roundabout designs Good roundabout design places a high priority on speed reduction and speed con- encourage speed reduction sistency. Such designs require that vehicles negotiate the roundabout through a and speed consistency. series of turning maneuvers at low speeds, generally less than 30 km/h (20 mph). Speed consistency refers to the design objective of slowing vehicles in stages down to the desired negotiating speed to be consistent with the expectations of drivers. Speed control is provided by geometric features, not only by traffic control devices or by the impedance of other traffic. Because of this, speed reduction can be achieved at all times of day. If achieved by good design, then in principle, lower vehicle speeds should provide the following safety benefits: Potential safety benefits of low vehicle speeds. Visually impaired pedestrians are not provided with audible cues from vehicle streams. Lower circulating speeds can provide greater capacity. • Reduce crash severity for pedestrians and bicyclists, including older pedestri- ans, children, and impaired persons; • Provide more time for entering drivers to judge, adjust speed for, and enter a gap in circulating traffic; • Allow safer merges into circulating traffic; • Provide more time for all users to detect and correct for their mistakes or mis- takes of others; • Make collisions less frequent and less severe; and • Make the intersection safer for novice users. For example, Exhibit 2-2 shows that a pedestrian is about three times more likely to die when struck at 50 km/h (30 mph) than at 32 km/h (20 mphl, across a range of only 18 km/h (10 mph) difference in speed (4�. Typical commuter bicyclist speeds are in the range of ZO to 25 km/h (12 to 15 mph).Therefore, the difference in design speed is critical to all users who are not within the protective body of a motorized vehicle.The minor additional delay or inconvenience to drivers of lower-speed round- about designs (as compared to higher-speed roundabout designs) is a tradeoff for the substantial safety benefit to pedestrians and bicyclists. Older drivers may ben- efit from the additional time to perceive, think, react, and correct for errors (as may all users). It should be clarified that there has been no specific research performed on older drivers, older pedestrians, and older bicyclists at roundabouts. It should also be noted that visually impaired pedestrians are not provided the audible cues from vehicle streams that are available at a signal controlled intersection. For ex- ample, at roundabout exits, it may be difficult to discern the sound of vehicles which will continue to circulate from those exiting the roundabout.Therefore, infor- mation needs to be provided to these users through various appropriate design features to assist them in safely locating and navigating the crossings at round- abouts. Furthermore, the operational efficiency (capacity) of roundabouts is probably greater at lower circulating speed, because of these two phenomena: • The faster the circulating traffic, the larger the gaps that entering traffic will comfortably accept.This translates to fewer acceptable gaps and therefore more instances of entering vehicles stopping at the yield line. • Entering traffic, which is first stopped at the yield line, requires even larger gaps in the circulating traffic in order to accelerate and merge with the circulating traffic. The faster the circulating traffic, the larger this gap must be. This trans- lates into even fewer acceptable gaps and therefore longer delays for entering traffic. �,; I Federal HighwayAdministration 45% 15% Source: United Kingdom (4) 2.1.1.1 Single-lane roundabouts 85% The safety characteristics of single-lane and multilane roundabouts are somewhat different and are discussed separately. Single-lane roundabouts are the simplest form of roundabout and thus are a good starting point for discussing the safety characteristics of roundabouts relative to other forms of intersections. The frequency of crashes at an intersection is related to the number of conflict points at an intersection, as well as the magnitude of conflicting flows at each conflict point. A conflict point is a location where the paths of two vehicles, or a vehicle and a bicycle or pedestrian diverge, merge, or cross each other. For ex- ample, Exhibit 2-3 presents a diagram of vehicle-vehicle conflict points for a tradi- tional four-leg intersection and a four-leg roundabout intersection of two-lane roads. The number of vehicle-vehicle conflict points for four-leg intersections drops from thirty-two to eight with roundabouts, a 75 percent decrease. Fewer conflict points means fewer opportunities for collisions. These are not the only conflict points at roundabouts or traditional intersections, but are illustrative of the differences be- tween intersection types. Chapter 5 contains a more detailed comparison of con- flicts at more complex intersections and for pedestrians and bicyclists. The severity of a collision is determined largely by the speed of impact and the angle of impact.The higher the speed, the more severe the collision.The higher the angle of impact, the more severe the collision. Ro�ndabouts reduce in severity or eliminate many severe conflicts that are present in traditional intersections. Roundabouts: An Informational Guide • 2: Policy Considerations Exhibit 2-2. Pedestrian's chances of death if hit by a motor vehicle. Roundabouts bring the simplicity of a "T" intersection to intersections with more than three legs. A fourvleg intersection has 75 percent fewer conflicts between vehicles and pedestrians and other vehicles, compared to a conventional fouFleg intersection. See Chapter 5 for a comparison of intersection conflicts. Exhibit 2-3. Comparisons of vehicle-vehicle contlict points for intersections with four single-lane approaches. Types of intersection conflicts. � � � � � / . � � ' ��, � Diverging 8 � Diverging 4 Q Merging 8 Q Merging 4 � Crossing 16 � Crossing 0 32 8 Roundabouts eliminate crossing As Exhibit 2-3 shows, a roundabout eliminates vehicle-vehicle crossing conflicts by conflicts by converting all movements converting all movements to right turns. Separate turn lanes and traffic control to right turns. (stop signs or signalization) can often reduce but not eliminate the number of crossing conflicts at a traditional intersection by separating conflicts in space and/or time. However, the most severe crashes at signalized intersections occur when there is a violation of the traffic control device designed to separate conflicts by time (e.g., a right-angle collision due to a motorist running a red light, or vehicle-pedestrian collisionsl.The ability of roundabouts to reduce conflicts through physical, geomet- ric features has been demonstrated to be more effective than the reliance on driver obedience to traffic control devices. At intersections with more than four legs, a roundabout or pair of roundabouts may sometimes be the most practical alterna- tive to minimize the number of conflicts. Drivers approaching a single-lane roundabout have five basic decisions regarding other users. First, drivers must be mindful of any bicyclists merging into motor vehicle traffic from the right side of the road or a bicycle lane or shoulder.Then they must yield to any pedestrians crossing at the entry. Third, they must choose an acceptable gap in which to enter the roundabout. Then they must choose the cor- rect exit, and finally, they must yield to any pedestrians crossing the exit lane. By contrast, a driver making a left turn from the minor leg of a two-way stop- controlled intersection has to yield to pedestrians and bicyclists, and judge gaps in both of the major street through movements from both directions, as well as the major street left and right turns and opposing minor through and right turns. Signalized intersections have simplified the decision-making process for drivers, especially at locations where protected left-turn phasing is provided, by separating conflicts in time and space. However, the rules and driver decisions for negotiating signalized intersections are still quite complex when all the possible signal phasing schemes are accounted for. For signals with permitted left-turn phasing, the driver ��: I Federal HighwayAdministration must be cognizant of the opposing traffic including pedestrians, and the signal indication (to ensure a legal maneuverl. At roundabouts, once at the yield line, the entering driver can focus attention entirely on the circulating traffic stream approach- ing from the left. A driver behind the entering driver can focus entirely on crossing pedestrians. 2.1.1.2 Double-lane roundabouts As discussed in Chapter 1, double-lane roundabouts are those with at least one entry that has two lanes. In general, double-lane roundabouts have some of the same safety characteristics for vehicle occupants as their less complicated single- lane counterparts. However, due to the presence of multiple entry lanes and the accompanying need to provide wider circulatory and exit roadways, double-lane roundabouts have complications that result in poorer safety characteristics, par- ticularly for bicyclists and pedestrians, than single-lane roundabouts serving simi- lar traffic demands. This makes it important to use the minimum number of entry, circulating, and exit lanes, subject to capacity considerations. Due to their typically larger size compared to single-lane roundabouts, double-lane roundabouts often cannot achieve the same levels of speed reduction as their single- lane counterparts. Wider entering, circulating, and exiting roadways enable a ve- hicle to select a path that crosses multiple lanes, as shown in Exhibit 2-4. Because of the higher-speed geometry, single-vehicle accidents can be more severe. How- ever, design of double-lane roundabouts according to the procedures in Chapter 6, especially the approach and entry, can substantially reduce the speeds of entering vehicles and consequently reduce the severity of conflicts. Even so, speed control cannot occur to the extent possible with single-lane roundabouts. Pedestrians crossing double-lane roundabouts are exposed for a longer time and to faster vehicles. They can also be obscured from, or not see, approaching ve- hicles in adjacent lanes if vehicles in the nearest lane yield to them. Children, wheel- Increasing the number of lanes increases the number of conflict points. The design of double-lane roundabouts to control the speed of the fastest vehicle path is covered in Chapter 6. Exhibit 2-4. Fastest vehicle path through a double-lane roundabout. Roundabouts: An Informational Guide • 2: Policy Considerations I 2? r chair users, and visually impaired pedestrians face particular risks. Bicycles are also more exposed to severe conflicts when choosing to circulate with motor vehicles. Double-lane roundabouts can be Driver decisions are more complex at double-lane roundabouts. The requirement confusing without proper engineer- to yield to pedestrians still applies. The primary additional decisions are the choices ing and user education. of the proper lane for entering, lateral position for circulating, and proper lane for exiting the roundabout. Lane choice on approaching a double-lane roundabout is no different from approaching a signalized intersection: to turn left, stay left; to turn right, stay right. However, the decisions for circulating within and especially exiting a double-lane roundabout are unique. Consider guide signs for roundabouts Double-lane roundabouts with legs aligned at approximately 90-degree angles al- with skewed approaches or low motorists to determine the appropriate lane choice for their path through the more than four legs. roundabout in a relatively easy manner. Double-lane roundabouts with more than four legs and/or with legs aligned at angles significantly different from 90 degrees Sections 2.5 and 2.6 cover user make driver decisions more complicated. This occurs because it can be difficult on education topics. some legs to determine which movements are left, through, and right. For this rea- son, it is desirable that multilane roundabouts be limited to a maximum of four legs, with legs aligned at approximately 90-degree angles. If this is not possible, special advance guide signs showing appropriate lane choice should be considered. When double-lane roundabouts are first introduced to an area, there is a need for adequate user education. Recommendations for user education material specifi- cally related to this issue are presented later in this chapter. 2.7.2 Vehicle delay and queue storage Techniques for estimating delay When operating within their capacity, roundabout intersections typically operate are given in Chapter 4. with lower vehicle delays than other intersection forms and control types. With a roundabout, it is unnecessary for traffic to come to a complete stop when no con- flicts present themselves, or else deceleration will avoid a conflict. When there are queues on one or more approaches, traffic within the queues usually continues to move, and this is typically more tolerable to drivers than a stopped or standing queue.The performance of roundabouts during off-peak periods is particularly good in contrast to other intersection forms, typically with very low average delays. 2.1.3 Delay of major movements Since all intersection Roundabouts tend to treat all movements at an intersection equally. Each approach movements at a roundabout is required to yield to circulating traffic, regardless of whether the approach is a have equal priority, major street local street or major arterial. In other words, all movements are given equal priority. movements may be delayed This may result in more delay to the major movements than might otherwise be more than desired. desired.This problem is most acute at the intersection of high-volume major streets with low to medium-volume minor streets (e.g., major arterial streets with minor collectors or local streetsl. Therefore, the overall street classification system and hierarchy should be considered before selecting a roundabout (or stop-controlled) intersection. This limitation should be specifically considered on emergency re- sponse routes in comparison with other intersection types and control.The delays depend on the volume of turning movements and should be analyzed individually for each approach, according to the procedures in Chapter 4. � I Federal HighwayAdministration 2.1.4 Signal progression It is common practice to coordinate traffic signals on arterial roads to minimize stops and delay to through traffic on the major road. By requiring coordinated pla- toons to yield to traffic in the circulatory roadway, the introduction of a roundabout into a coordinated signal system may disperse and rearrange platoons of traffic if other conflicting flows are significant, thereby reducing progressive movement.To minimize overall system delay, it may be beneficial to divide the signal system into subsystems separated by the roundabout, assigning each subsystem its own cycle. The traffic performance of the combination roundabout-signal system should be tested in advance with signal systems and roundabout analysis tools. In some cases, total delay, stops, and queues will be reduced by the roundabout. The num- ber of available gaps for midblock unsignalized intersections and driveways may also be reduced by the introduction of roundabouts, although this may be offset by the reduced speeds near roundabouts. In addition, roundabouts can enable safe and quick U-turns that can substitute for more difficult midblock left turns, espe- cially where there is no left turn lane. 2.1.5 Environmental factors Roundabouts may provide environmental benefits if they reduce vehicle delay and the number and duration of stops compared with an alternative. Even when there are heavy volumes, vehicles continue to advance slowly in moving queues rather than coming to a complete stop.This may reduce noise and air quality impacts and fuel consumption significantly by reducing the number of acceleration/decelera- tion cycles and the time spent idling. In general, if stop or yield control is insufficient, traffic through roundabouts gener- ates less pollution and consumes less fuel than traffic at fixed-time signalized inter- sections. However, vehicle-actuated signals typically cause less delay, less fuel consumption, and less emissions than roundabouts as long as traffic volumes are low. During busy hours, vehicle-actuated signals tend to operate like fixed-time signals, and the percentage of cars that must stop becomes high (5). 2.1.6 Spatial requirements Roundabouts usually require more space for the circular roadway and central is- land than the rectangular space inside traditional intersections. Therefore, round- abouts often have a significant right-of-way impact on the corner properties at the intersection, especially when compared with other forms of unsignalized intersec- tion. The dimensions of a traditional intersection are typically comparable to the envelope formed by the approaching roadways. However, to the extent that a com- parable roundabout would outperform a signal in terms of reduced delay and thus shorter queues, it will require less queue storage space on the approach legs. If a signalized intersection requires long or multiple turn lanes to provide sufficient capacity or storage, a roundabout with similar capacity may require less space on the approaches. As a result, roundabouts may reduce the need for additional right- of-way on the links between intersections, at the expense of additional right-of- way requirements at the intersections themselves (refer to Chapters 3 and 8).The right-of-way savings between intersections may make it feasible to accommodate parking, wider sidewalks, planter strips, wider outside lanes, and/or bicycle lanes in order to better accommodate pedestrians and/or bicyclists. Another space-sav- ing strategy is the use of flared approach lanes to provide additional capacity at the Roundabouts: An Informational Guide • 2: Policy Considerations I'�$ By reducing speeds, roundabouts complement other traffic calming measures. intersection while maintaining the benefit of reduced spatial requirements upstream and downstream of an intersection. At interchange ramp terminals, paired roundabouts have been used to reduce the number of lanes in freeway over- and underpasses. In compact urban areas, there are typically signalized intersections at both ends of overpass bridges, necessitat- ing two additional overpass lanes to provide capacity and storage at the signalized intersections. 2.1.7 Operation and maintenance costs Compared to signalized intersections, a roundabout does not have signal equip- ment that requires constant power, periodic light bulb and detection maintenance, and regular signal timing updates. Roundabouts, however, can have higher land- scape maintenance costs, depending on the degree of landscaping provided on the central island, splitter islands, and perimeter. Illumination costs for roundabouts and signalized intersections are similar. Drivers sometimes face a confusing situa- tion when they approach a signalized intersection during a power failure, but such failures have minimal temporary effect on roundabouts or any other unsignalized intersections, other than the possible loss of illumination.The service life of a round- about is significantly longer, approximately 25 years, compared with 10 years for a typical signal (6). 2.1.8 Traffic calming Series of roundabouts can have secondary, traffic calming effects on streets by reducing vehicle speeds. As discussed previously, speed reduction at roundabouts is caused by geometry rather than by traffic control devices or traffic volume. Con- sequently, speed reduction can be realized at all times of day and on streets of any traffic volume. It is difficult to speed through an appropriately designed roundabout with raised channelization that forces vehicles to physically change direction. In this way, roundabouts can complement other traffic calming measures. Roundabouts have also been used successfully at the interface between rural and urban areas where speed limits change. In these applications, the traffic calming effects of roundabouts force drivers to slow and reinforce the notion of a signifi- cant change in the driving environment. 2.1.9 Aesthetics Landscaping issues are Roundabouts offer the opportunity to provide attractive entries or centerpieces to discussed in detail in communities. However, hard objects in the central island directly facing the entries Chapter 7. are a safety hazard. The portions of the central island and, to a lesser degree, the splitter islands that are not subject to sight-distance requirements offer opportuni- ties for aesthetic landscaping. Pavement textures can be varied on the aprons as well. Exhibit 2-5 presents examples of the aesthetic treatments that have been applied to roundabouts.They can also be used in tourist or shopping areas to facili- tate safe U-turns and to demarcate commercial uses from residential areas. They have been justified as a spur to economic development, conveying to developers that the area is favorable for investment in redevelopment. Some are exhibited as a"signature" feature on community postcards, advertisements, and travelogues. �1'r I Federal HighwayAdministration (a) West Boca Raton, FL (b) Santa Barbara, CA (c) Fort Pierce, FL 2.1.10 Design for older drivers (d) Vail, CO In the United States, there is a trend toward an aging population, as well as indi- viduals, continuing to drive until an older age. This trend has implications for all roadway design, including roundabout design, ranging from operations through geometric and sign design. In this regard, designers should consult available docu- ments such as the Federal Highway Administration (FHWA) Older Driver Highway Design Handbook (7): • The single greatest concern in accommodating older road users, both drivers and pedestrians, is the ability of these persons to safely maneuver through intersections. • Driving situations involving complex speed-distance judgments under time con- straints are more problematic for older drivers and pedestrians than for their younger counterparts. • Older drivers are much more likely to be involved in crashes where the drivers were driving too fast for the curve or, more significantly, were surprised by the curved alignment. • Many studies have shown that loss-of-control crashes result from an inability to maintain lateral position through the curve because of excessive speed, with inadequate deceleration in the approach zone. These problems in turn stem from a combination of factors, including poor anticipation of vehicle control re- quirements, induced by the driver's prior speed, and inadequate perception of the demands of the curve. • Older drivers have difficulties in allocating attention to the most relevant as- pects of novel driving situations. • Older drivers generally need more time than average drivers to react to events. Exhibit 2-5. Examples of aesthetic treatments. Roundabouts: An Informational Guide • 2: Policy Considerations I 31 While the Handbook is not specific to roundabouts, and since no age-related re- search has been conducted with U.S. roundabouts to date, these findings may apply to older persons encountering roundabouts, as well. The excerpts above all imply that lower, more conservative design speeds are appropriate. Roundabouts designed for low, consistent speeds cater to the preferences of older drivers: slower speeds; time to make decisions, act, and react; uncomplicated situations to inter- pret; simple decision-making; a reduced need to look over one's shoulder; a re- duced need to judge closing speeds of fast traffic accurately; and a reduced need to judge gaps in fast traffic accurately. For example, two-way stop-controlled inter- sections may be appropriate for replacement with a roundabout when a crash analysis indicates that age-related collisions are prevalent. 2.2 Multimodal Considerations As with any intersection design, each transportation mode present requires care- ful consideration. This section presents some of the general issues associated with each mode; additional detail on mode-specific safety and design issues is provided in subsequent chapters. 2.2.1 Pedestrians Pedestrian crossings should be set Pedestrians are accommodated by crossings around the perimeter of the round- back from the yield line by one or about. By providing space to pause on the splitter island, pedestrians can consider more vehicle lengths. one direction of conflicting traffic at a time, which simplifies the task of crossing the street. The roundabout should be designed to discourage pedestrians from crossing to the central island, e.g., with landscape buffers on the corners. Pedes- trian crossings are set back from the yield line by one or more vehicle lengths to: • Shorten the crossing distance compared to locations adjacent to the inscribed circle; • Separate vehicle-vehicle and vehicle-pedestrian conflict points; and • Allow the second entering driver to devote full attention to crossing pedestrians while waiting for the driver ahead to enter the circulatory roadway. If sidewalks on the intersecting roads are adjacent to the curbs, this setback may require the sidewalks to deviate from a straight path. This is not the case if side- walks are separated from the curbs by a generous landscape buffer. Most intersections are two-way stop-controlled, or uncontrolled. Compared to two- way stop-controlled intersections, roundabouts may make it easier and safer for pedestrians to cross the major street. At both roundabouts and two-way stop- controlled intersections, pedestrians have to judge gaps in the major (uncontrolled) stream of traffic. By reducing stopping distance, the low vehicular speeds through a roundabout generally reduce the frequency and severity of incidents involving pedestrians. In addition, when crossing an exit lane on the minor road, the sight angle is smaller than when watching for left-turning vehicles at a conventional inter- section. The comparison between roundabouts and all-way stop-controlled intersections is less clear. All-way stop control is virtually nonexistent in foreign countries that have 32 I Federal HighwayAdministration roundabouts, and so there is little international experience with which to compare. All-way stop-controlled intersections may be preferred by pedestrians with visual impairment because vehicles are required to stop before they enter the intersec- tion. However, crossing the exit leg of an all-way stop-controlled intersection can be intimidating for a pedestrian since traffic may be turning onto the exit from multiple directions. Roundabouts, on the other hand, allow pedestrians to cross one direction of traffic at a time; however, traffic may be moving (albeit at a slow speed), thus making it more challenging to judge gaps, especially for visually im- paired users, children, and the elderly. The biggest difference may be that all-way stop-controlled intersections, like two- way stops, do not provide positive geometric features to slow vehicles and instead rely entirely on the authority of the traffic control device.The roundabout geometry physically slows and deflects vehicles, reducing the likelihood of a high-speed col- lision due to a traffic control device violation. Signalized intersections offer positive guidance to pedestrians by providing visual and occasionally audible pedestrian signal indications. In this respect, the decision process for pedestrians requires less judgment at signalized intersections than at roundabouts, particularly for visually impaired and elderly pedestrians. However, pedestrians are still vulnerable at signalized intersections to right-turn and left-turn movements unprotected by a green arrow. In addition, high-speed collisions are still possible if a vehicle runs through a red indication. In this respect, the round- about provides a speed-constrained environment for through traffic. At two-way and all-way stop intersections, right-turning motorists often look only to the left in order to check for vehicular conflicts, endangering or inconveniencing pedestrians crossing from the right or on the right. This situation is exacerbated by the fact that many of these drivers do not come to a complete stop if they do not perceive any conflicts. With crosswalks located back from the circulatory roadway, roundabouts place pedestrians in a more visible location. The two populations at opposite ends of the age continuum—children and the elderly—and people with disabilities are particularly at risk at intersections. Chil- dren (owing to their lack of traffic experience, impulsiveness, and small size) and the elderly (owing to their age-related physical limitations) present challenges to the designer. In recognition of pedestrians with disabilities, intersections must com- ply with Americans with Disabilities Act (ADA) mandated accessibility standards discussed in Section 2.4.5 and Chapter 5. Elderly pedestrians, children, and the disabled find it more difficult to cross unpro- tected road crossings. These types of pedestrians generally prefer larger gaps in the traffic stream, and walk at slower speeds than other pedestrians. Multilane roadways entering and exiting double-lane roundabouts require additional skills to cross, since pedestrians need assurance that they have been seen by drivers in each lane they are crossing. When crossing a roundabout, there are several areas of difficulty for the blind and or visually impaired pedestrian. It is expected that a visually impaired pedestrian with good travel skilis must be able to arrive at an unfamiliar intersection and cross it with pre-existing skills and without special, intersection-specific training. Round- abouts pose problems at several points of the crossing experience, from the per- spective of information access. Roundabouts: An Informational Guide • 2: Policy Considerations When crossing a roundabout, there are several areas of difficulty for the blind and or visually impaired pedestrian. Unless these issues are addressed by a design, the intersection is "inaccessible" and may not be permissible under the ADA. Chapters 5, 6, and 7 provide specific suggestions to assist in providing the above information. However, more research is required to develop the information jurisdictions need to determine where round- abouts may be appropriate and what design features may be appropriate for the disabled, such as audible signalized crossings. Until specific standards are adopted, engineers and jurisdictions must rely on existing related research and professional judgment to design pedestrian features so that they are usable by pedestrians with disabilities. 2.2.2 Bicycles Roundabouts may not provide safety benefits to bicyclists (1). Nevertheless, the recommended roundabout designs discourage erratic or undesirable driver behav- ior.They slow drivers to speeds more compatible with bicycle speeds, while reduc- ing high-speed conflicts and simplifying turn movements for bicyclists.Typical com- muter bicyclist speeds are around 25 km/h (15 mph), so entering a roundabout designed for circulating traffic to flow at similar speeds should be safer compared with larger and faster roundabout designs. Bicyclists require particular attention in two-lane roundabout design, especially in areas with moderate to heavy bicycle traffic. As with pedestrians, one of the difficulties in accommodating bicyclists is their wide range of skills and comfort levels in mixed traffic. On single-lane roundabouts, bicyclists have the option of either mixing with traffic or using the roundabout like a pedestrian. The former option will likely be reasonably comfortable for experi- enced cyclists; however, less-experienced cyclists (including children) may have difficulty and discomfort mixing with vehicles and are more safely accommodated as pedestrians. Bike lanes through The complexity of vehicle interactions within a roundabout leaves a cyclist vulner- roundabouts should able, and for this reason, bike lanes within the circulatory roadway should never be never be used. used. On double-lane roundabouts, a bicycle path separate and distinct from the circulatory roadway is preferable, such as a shared bicycle-pedestrian path of suf- ficient width and appropriately marked to accommodate both types of users around the perimeter of the roundabout. While this will likely be more comfortable for the casual cyclist, tne experienced commuter cyclist will be significantly slowed down by having to cross as a pedestrian at each approach crossing and may choose to continue to traverse a double-lane roundabout as a vehicle. It may sometimes be possible to provide cyclists with an alternative route along another street or path that avoids the roundabout, which should be considered as part of overall network planning. The provision of alternative routes should not be used to justify compro- mising the safety of bicycle traffic through the roundabout because experienced cyclists and those with immediately adjacent destinations will use it. 2.2.3 Large vehicles Design roundabouts to Roundabouts should always be designed for the largest vehicle that can be reason- accommodate the largest ably anticipated (the "design vehicle"). For single-lane roundabouts, this may re- vehicle that can reasonably quire the use of a mountable apron around the perimeter of the central island to be expected. provide the additional width needed for tracking the trailer wheels. At double-lane roundabouts, large vehicles may track across the whole width of the circulatory roadway to negotiate the roundabout. In some cases, roundabouts have been �q; I Federal HighwayAdministration designed with aprons or gated roadways through the central island to accommo- date oversized trucks, emergency vehicles, or trains. 2.2.4 Transit Transit considerations at a roundabout are similar to those at a conventional inter- section. If the roundabout has been designed using the appropriate design vehicle, a bus should have no physical difficulty negotiating the intersection. To minimize passenger discomfort, if the roundabout is on a bus route, it is preferable that scheduled buses are not required to use a truck apron if present. Bus stops should be located carefully to minimize the probability of vehicle queues spilling back into the circulatory roadway.This typically means that bus stops located on the far side of the intersection need to have pullouts or be further downstream than the splitter island. Pedestrian access routes to transit should be designed for safety, comfort, and convenience. If demand is significant, such as near a station or terminus, pe- destrian crossing capacity should be accounted for. Roundabouts may provide opportunities for giving transit (including rai11 and emer- gency vehicles priority as can be done at signalized intersections. This may be provided using geometry, or signals. For example, these could include an exclusive right-turn bypass lane or signals holding entering traffic while the transit vehicle enters its own right-of-way or mixed traffic. The roundabout can be supplemented by signals activated by a transit, emergency, or rail vehicle. Chapters 6, 7, and 8 provide more detail on transit treatments. 2.2.5 Emergency vehicles The passage of large emergency vehicles through a roundabout is the same as for other large vehicles and may require use of a mountable apron. On emergency response routes, the delay for the relevant movements at a planned roundabout should be compared with alternative intersection types and control. Just as they are required to do at conventional intersections, drivers should be educated not to enter a roundabout when an emergency vehicle is approaching on another leg. Once having entered, they should clear out of the circulatory roadway if possible, facilitating queue clearance in front of the emergency vehicle. Roundabouts provide emergency vehicles the benefit of lower vehicle speeds, which may make roundabouts safer for them to negotiate than signalized cross- ings. Unlike at signalized intersections, emergency vehicle drivers are not faced with through vehicles unexpectedly running the intersection and hitting them at high speed. 2.2.6 Rail crossings Rail crossings through or near a roundabout may involve many of the same design challenges as at other intersections and should be avoided if better alternatives exist. In retrofit, the rail track may be designed to pass through the central island, or across one of the legs. Queues spilling back from a rail blockage into the round- about can fill the circulatory roadway and temporarily prevent movement on any approach. However, to the extent that a roundabout approach capacity exceeds that of a signal at the same location, queues will dissipate faster.Therefore, a case- specific capacity and safety analysis is recommended. Section 8.2 addresses the design of at-grade rail crossings. Roundabouts: An Informational Guide • 2: Policy Considerations Public transit buses should not be forced to use a truck apron to negotiate a roundabout. Chapters 6-8 provide more detail on transit treatments. See Section 8.2 for information on designing roundabouts located near at-grade rail crossings. 2.3 Costs Associated with Roundabouts Many factors influence the amount of economic investment justified for any type of intersection. Costs associated with roundabouts include construction costs, engineering and design fees, land acquisition, and maintenance costs. Benefits may include reduced crash rates and severity, reduced delay, stops, fuel consump- tion, and emissions. Benefit-cost analysis is discussed further in Chapter 3. When comparing costs, it is often difficult to separate the actual intersection costs from an overall improvement project. Accordingly, the reported costs of installing roundabouts have been shown to vary significantly from site to site. A roundabout may cost more or less than a traffic signal, depending on the amount of new pave- ment area and the extent of other roadway work required. At some existing unsignalized intersections, a traffic signal can be installed without significant modi- fications to the pavement area or curbs. In these instances, a roundabout is likely to be more costly to install than a traffic signal, as the roundabout can rarely be constructed without significant pavement and curb modifications. Roundabouts may require more However, at new sites, and at signalized intersections that require widening at one pavement area at the intersection, or more approaches to provide additional turn lanes, a roundabout can be a compa- comparod to a traffic signal, but rable or less expensive alternative. While roundabouts typically require more pave- less on the approaches and exits. ment area at the intersection, they may require less pavement width on the up- stream approaches and downstream exits if multiple turn lanes associated with a signalized intersection can be avoided. The cost savings of reduced approach road- way widths is particularly advantageous at interchange ramp terminals and other intersections adjacent to grade separations where wider roads may result in larger bridge structures. In most cases, except potentially for a mini-roundabout, a round- about is more expensive to construct than the two-way or all-way stop-controlled intersection alternatives. Recent roundabout projects in the United States have shown a wide range in re- ported construction costs. Assuming "1998 U.S. Dollars" in the following examples, costs ranged from $10,000 for a retrofit application of an existing traffic circle to $500,000 for a new roundabout at the junction of two State highways. National Cooperative Highway Research Program (NCHRP) Synthesis 264 (3) reports that the average construction cost of 14 U.S. roundabouts, none being part of an inter- change, was approximately $250,000. This amount includes all construction ele- ments, but does not include land acquisition. The cost of maintaining traffic during Higher costs are typically incurred when a substantial amount of rea�ignment, grad- construction of a roundabout retrofit ing, or drainage work is required.The cost of maintaining traffic during construction can be relatively high. tends to be relatively high for retrofitting roundabouts.This expense is due mainly to the measures required to maintain existing traffic flow through the intersection while rebuilding it in stages. Other factors contributing to high roundabout costs are large amounts of landscaping in the central and splitter islands, extensive sign- ing and lighting, and the provision of curbs on all outside pavement edges. Operating and maintenance costs of roundabouts are somewhat higher than for other unsignalized intersections, but less than those for signalized intersections. In addition, traffic signals consume electricity and require periodic service (e.g., bulb replacement, detector replacement, and periodic signal retiming). Operating costs for a roundabout are generally limited to the cost of illumination (similar to signalized alternatives, but typically more than is required for other unsignalized intersections). IFederal HighwayAdministration Maintenance includes regular restriping and repaving as necessary, as well as snow removal and storage in cold climates (these costs are also incurred by conventional intersections). Landscaping may require regular maintenance as well, including such things as pruning, mowing, and irrigation system maintenance.To the extent that roundabouts reduce crashes compared with conventional intersections, they will reduce the number and severity of incidents that disrupt traffic flow and that may require emergency service. 2.4 Legal Considerations The legal environment in which roundabouts operate is an important area for juris- dictions to consider when developing a roundabout program or set of guidelines. The rules of the road that govern the operation of motor vehicles in a given State can have a significant influence on the way a roundabout operates and on how legal issues such as crashes involving roundabouts are handled. Local jurisdictions that are interested in developing a roundabout program need to be aware of the governing State regulations in effect. The following sections discuss several of the important legal issues that should be considered. These have been based on the provisions of the 1992 Uniform Vehicle Code (UVC) (8), which has been adopted to varying degrees by each State, as well as the rules of the road, and commentaries thereof, from the United Kingdom (9) and Australia (10, 11). Note that the informa- tion in the following sections does not constitute specific legal opinion; each juris- diction should consult with its attorneys on specific legal issues. 2.4.1 Definition of "intersection" The central legal issue around which all other issues are derived is the fundamental relationship between a roundabout and the legal definition of an "intersection:' A roundabout could be legally defined one of two ways: • As a single intersection; or • As a series of T-intersections. The UVC does not provide clear guidance on the appropriate definition of an inter- section with respect to roundabouts. The UVC generally defines an "intersection" as the area bounded by the projection of the boundary lines of the approaching roadways (UVC §1-132a). It also specifies that where a highway includes two road- ways 9.1 m(30 ft) or more apart, each crossing shall be regarded as a separate intersection (UVC §1-132b).This may imply that most circular intersections should be regarded as a series ofT-intersections.This distinction has ramifications in the interpretation of the other elements identified in this section. This guide recommends that a roundabout be specifically defined as a single inter- section, regardless of the size of the roundabout. This intersection should be de- fined as the area bounded by the limits of the pedestrian crossing areas around the perimeter of a single central island. Closely spaced roundabouts with multiple cen- tral islands should be defined as separate intersections, as each roundabout is typically designed to operate independently. Roundabouts: An Informational Guide • 2: Policy Considerations It is recommended that roundabouts be defined as a single intersection: the area bounded by the limits of the pedestrian crossing areas. �,. 2.4.2 Right-of-way between vehicles Because of yield-to-the-right laws, The UVC specifies that "when two vehicles approach or enter an intersection from yield signs and lines must be used on different highways at approximately the same time, the driver of the vehicle on the roundabout entries to assign right-of- left shall yield the right-of-way to the vehicle on the right" (UVC § 11-401). This runs way to the circulatory roadway. contrary to the default operation of a roundabout, which assigns the right-of-way to the vehicle on the left and any vehicle in front. This requires the use of yield signs and yield lines at all approaches to a roundabout to clearly define right-of-way. This guide recommends that right-of-way at a roundabout be legally defined such that an entering vehicle shall yield the right-of-way to the vehicle on the left (France passed such a law in 19841. This definition does not change the recommendation for appropriately placed yield signs and yield lines. 2.4.3 Required lane position at intersections At a typical intersection with multilane approaches, vehicles are required by the UVC to use the right-most lane to turn right and the left-most lane to turn left, unless specifically signed or marked lanes allow otherwise (e.g., double left-turn lanes) (UVC §11-601). Because multilane roundabouts can be used at intersections with more than four legs, the concept of "left turns" and "right turns" becomes more difficult to legally define. The following language (10) is recommended: Recommended lane assignments: Unless official traffic control devices indicate otherwise, drivers must make lane Exit less than halfway, use the right choices according to the following rules: Iane. Exit more than halfway, use the If a driver intends to exit the roundabout less than halfway around it, the right left lane. Exit exactly halfway, use • lane must be used. either lane. • If a driver intends to exit the roundabout more than halfway around it, the left lane must be used. The Australian Traffic Act (10) gives no guidance for straight through movements (movements leaving the roundabout exactly halfway), and the general Australian practice is to allow drivers to use either lane unless signed or marked otherwise. On multilane roundabouts where the intersecting roadways are not at 90-degree angles or there are more than four legs to the roundabout, special consideration should be given to assisting driver understanding through advance diagrammatic guide signs or lane markings on approaches showing the appropriate lane choices. 2.4.4 Priority within the circulatory roadway For multilane roundabouts, the issue of priority within the circulatory roadway is important. Any vehicle on the inner track on the circulatory roadway (e.g., a vehicle making a left turn) will ultimately cross the outer track of the circulatory roadway to exit. This may cause conflicts with other vehicles in the circulatory roadway. Consistent with its lack of treatment of roundabouts, the UVC does not provide clear guidance on priority within the circulatory roadway of a roundabout. In gen- eral, the UVC provides that all overtaking should take place on the left (UVC §11- 303). However, the UVC also specifies the following with respect to passing on the right (UVC §11-304a): �;, I Federal HighwayAdministration The driver of a vehicle may overtake and pass upon the right of another vehic/e on/y under the following conditions. 1. When the vehicle overtaken is making or about to make a/eft turn; 2. Upon a roadway with unobstructed pavement of sufficient width for two or more lines of vehicles moving /awful/y in the direction being trave/ed by the overtaking vehicle. A case could be made that this provision applies to conditions within a circulatory roadway of a multilane roundabout. Under the definition of a roundabout as a single intersection, a vehicle making a left turn could be overtaken on the right, even though the completion of the left turn requires exiting on the right. International rules of the road vary considerably on this point.The United Kingdom, for example, requires drivers to "watch out for traffic crossing in front of you on the roundabout, especially vehicles intending to leave by the next exit. Show them consideration:' (9, §125)This is generally interpreted as meaning that a vehicle at the front of a bunch of vehicles within the circulatory roadway has the right-of-way, regardless of the track it is on, and following vehicles on any track must yield to the front vehicle as it exits. Australia, on the other hand, does not have a similar state- ment in its legal codes, and this was one of the factors that led Australians to favor striping of the circulatory roadway in recent years. Further research and legal ex- ploration need to be performed to determine the effect of this legal interpretation on driver behavior and the safety and operation of multilane roundabouts. For clarity, this guide makes the following recommendations: • Overtaking within the circulatory roadway should be prohibited. • Exiting vehicles should be given priority over circulating vehicles, provided that the exiting vehicle is in front of the circulating vehicle. 2.4.5 Pedestrian accessibility The legal definition of a roundabout as one intersection or a series of intersections also has implications for pedestrians, particularly with respect to marked and un- marked crosswalks. A portion of the UVC definition of a crosswalk is as follows: ". . and in the absence of a sidewalk on one side of the roadway, that part of a roadway included within the extension of the lateral lines of the existing sidewalk at right angles to the centerline" (UVC §1-112�a11. Under the definition of a round- about as a series of T-intersections, this portion of the definition could be inter- preted to mean that there are unmarked crosswalks between the perimeter and the central island at every approach. The recommended definition of a roundabout as a single intersection simplifies this issue, for the marked or unmarked cross- walks around the perimeter as defined are sufficient and complete. In all States, drivers are required to either yield or stop for pedestrians in a cross- walk (however, this requirement is often violated, and therefore it is prudent for pedestrians not to assume that this is the casel. In addition, the provisions of the ADA also apply to roundabouts in all respects, including the design of sidewalks, crosswalks, and ramps. Under the ADA, accessible information is required to make the existing public right-of-way an accessible program provided by State and local governments (28 CFR 35.150). Any facility or part of a facility that is newly con- structed by a State or local government must be designed and constructed so that Recommendations: No overtaking within the circulatory roadway, and exiting vehicles in front of other circulating vehicles have priority when exiting. Roundabouts: An Informational Guide • 2: Policy Considerations � gg A recent survey found negative public attitudes towards roundabouts before construction, but positive attitudes following construction. g it is readily accessible to and usable by people with disabilities (28 CFR 35.151(a)). Alterations to existing facilities must include modifications to make altered areas accessible to individuals with disabilities (28 CFR 735.151 (bl). Current guidelines do not specifically address ways to make roundabouts acces- sible. Nonetheless, these provisions mean providing information about safely cross- ing streets in an accessible format, including at roundabouts. At a minimum, de- sign information should provide for: • Locating the crosswalk; • Determining the direction of the crosswalk; • Determining a safe crossing time; and • Locating the splitter island refuge. 2.4.6 Parking Many States prohibit parking within a specified distance of an intersection; others allow parking right up to the crosswalk. The degree to which these laws are in place will govern the need to provide supplemental signs and/or curb markings showing parking restrictions. To provide the necessary sight distances for safe crossings to occur, this guide recommends that parking be restricted immediately upstream of the pedestrian crosswalks. The legal need to mark parking restrictions within the circulatory roadway may be dependent on the definition of a roundabout as a single intersection or as a series ofT-intersections. Using the recommended definition of a roundabout as a single intersection, the circulatory roadway would be completely contained within the intersection, and the UVC currently prohibits parking within an intersection (UVC § 11-1003). 2.5 Public Involvement Public acceptance of roundabouts has often been found to be one of the biggest challenges facing a jurisdiction that is planning to install its first roundabout. With- out the benefit of explanation or first-hand experience and observation, the public is likely to incorrectly associate roundabouts with older, nonconforming traffic circles that they have either experienced or heard about. Equally likely, without adequate education, the public (and agencies alike) will often have a natural hesitation or resistance against changes in their driving behavior and driving environment. In such a situation, a proposal to install a roundabout may initially experience a negative public reaction. However, the history of the first few roundabouts installed in the United States also indicates that public attitude toward roundabouts im- proves significantly after construction. A recent survey conducted of jurisdictions across the United States (3) reported a significant negative public attitude toward roundabouts prior to construction (68 percent of the responses were negative or very negative), but a positive attitude after construction �73 percent of the responses were positive or very positive). Federal HighwayAdministration A wide variety of techniques have been used successfully in the United States to Public meetings, videos and inform and educate the public about new roundabouts. Some of these include brochures, and media public meetings, informational brochures and videos, and announcements in the announcements are some of newspaper or on television and radio. A public involvement process should be the ways to educate the public initiated as soon as practical, preferably early in the planning stages of a project about new roundabouts. while other intersection forms are also being considered. 2.5.7 Public meetings Public meetings can be a good forum for bringing the public into the design pro- cess.This allows early identification of potential problems and helps to gain overall acceptance throughout the process. Public input may be useful at various stages in the planning process: data collection, problem definition, generation of design alternatives, selection of preferred alternatives, detailed design, go/no-go decision, construction/opening, and landscape maintenance. Many jurisdictions require or recommend public meetings with the affected neighborhood or businesses prior to approval of the project by elected officials. Even if such meetings are not re- quired, they can be helpful in easing concerns about a new form of intersection for a community. 2.5.2 Informational brochures A number of agencies, including the Maryland State Highway Administration and the City of Montpelier, Vermont, have used informational brochures to educate the public about roundabouts in their communities. Brochures have also been pre- pared for specific projects. Exhibit 2-6 shows examples from the brochures pre- pared for the I-70Nail Road roundabouts in Vail, Colorado, and theTowson Round- about inTowson, Maryland.These brochures include drawings or photographic simu- lations of the proposed roundabout. The brochures also typically include general information on roundabouts (what roundabouts are, where they can be found, and the types of benefits that can be expected). Sometimes they also include instruc- tions on how to use the roundabout as a motorist, bicyclist, and pedestrian. The Towson brochure included additional information on the business association in the area, the streetscape policy of the county, and information on the construction phases of the roundabout. Roundabouts: An Informational Guide • 2: Policy Considerations �!�'�� ExFeibit 2-6. Examples of informational brochures. � . _ I (a) Vail, CO �, : � � 1 (b)Towson, MD O_ SLOw oOwN p� upan eM�'. Spetdt ot 15 mph a kss are edcquete. o �� an w�r Rwndebo�R. Oncc Insldt, Go nolstop vou Iwe Vie A�K-ot-wnr � � LOOR for Yar destlrotlon �lyn. �i Um RandeboiR � • • Evw�d de�kxtlon r O � Remernbc �o ux you, Qm sh,�Ws• � �" � �uss roint onR . � �, ��m—�•� � �• � �«� �e. ON A �IC�L[t ' � � Use mc seme vehkukrmovemenb. T" � � „��o,o�� (,�t�i �: °. �.,.. r�wsonrsu.5iri ti� "�� ;'„ �,� ��L?��ro�� ;� i� sl i .� � �� . � . 5 . , .�'�'„ �,,.�. " � �� 42 � Federal HighwayAdministration 2.5.3 Informational videos A number of agencies and consulting firms have prepared videos to inform the public about roundabouts.These videos are typically 10 to 15 minutes in length and include footage of existing roundabouts and narration about their operational and safety characteristics. These videos have been successfully used at public meet- ings as an effective means of introducing the public to roundabouts. 2.5.4 Media announcements Given the new nature of a roundabout in many communities, the local media (news- paper, radio, and television) is likely to become involved. Such interest often occurs early in the process, and then again upon the opening of the roundabout. Radio reading services, telephone information services, and publications intended pri- marily for individuals with disabilities should be used to communicate with per- sons who are visually impaired when a roundabout is proposed and when it opens. 2.6 Education One of the important issues facing a State considering the implementation of round- abouts is the need to provide adequate driver, cyclist, and pedestrian education.To clarify the following tips and instructions, user education should begin by using simple exhibits such as those in Chapter 1 to familiarize them with the basic physi- cal features of a roundabout intersection. Users should also familiarize themselves with the instructions for all other modes so that they understand the expectations of each other. The following sections provide instructional material and model lan- guage for drivers, cyclists, and pedestrians that can be adapted to drivers manuals. These have been adapted from similar rules of the road and drivers manuals used for roundabouts in the United Kingdom (9), Australia (10), and the State of Victoria, Australia (11). 2.6.1 Driver education 2.6.1.1 Approaching the roundabout On approaching a roundabout, decide as early as possible which exit you need to take and get into the correct lane (refer to the section below on "Turning at round- abouts"1. Reduce your speed. Bicyclists are vehicles and need to share the lane at intersections.Therefore, allow bicycles to enter the roadway from any bicycle lane. The law gives pedestrians the right-of-way in a crosswalk. Yield to pedestrians waiting to cross or crossing on the approach. Watch out for and be particularly considerate of people with disabilities, children, and elderly pedestrians. Always keep to the right of the splitter island (either painted or raised) on the approach to the roundabout. 2.6.1.2 Entering ihe rounda6out Upon reaching the roundabout yield line, yield to traffic circulating from the left unless signs or pavement markings indicate otherwise. Do not enter the round- about beside a vehicle already circulating within the roundabout, as a vehicle near the central island may be exiting at the next exit. Watch out for traffic already on the roundabout, especially cyclists and motorcyclists. Do not enter a roundabout when an emergency vehicle is approaching on another leg; allow queues to clear in front of the emergency vehicle. Roundabouts: An Informational Guide • 2: Policy Considerations The following sample instructions assume that readers have already seen introductory material on roundabouts, such as the brochures depicted in the previous section. 2.6.1.3 Within the roundabout Within a roundabout, do not stop except to avoid a collision; you have the right-of- way over entering traffic. Always keep to the right of the central island and travel in a counterclockwise direction. Where the circulatory roadway is wide enough to allow two or more vehicles to travel side-by-side, do not overtake adjacent vehicles who are slightly ahead of yours as they may wish to exit next. Watch out for traffic crossing in front of you on the roundabout, especially vehicles intending to leave by the next exit. Do not change lanes within the roundabout except to exit. When an emergency vehicle is approaching, in order to provide it a clear path to turn through the roundabout, proceed past the splitter island of your exit before pulling over. 2.6.1.4 Exiting the roundabout Maintain a slow speed upon exiting the roundabout. Always indicate your exit us- ing your right-turn signal. For multilane roundabouts, watch for vehicles to your right, including bicycles that may cross your path while exiting, and ascertain if they intend to yield for you to exit. Watch for and yield to pedestrians waiting to cross, or crossing the exit leg. Watch out for and be particularly considerate of people with disabilities, children, and elderly pedestrians. Do not accelerate until you are beyond the pedestrian crossing point on the exit. 2.6.1.5 Turning at roundabouts Unless signs or pavement markings indicate otherwise: When turning right or exiting at the first exit around the roundabout, use the following procedure: — Turn on your right-turn signal on the approach. — If there are multiple approach lanes, use only the right-hand lane. — Keep to the outside of the circulatory roadway within the roundabout and continue to use your right-turn signal through your exit. — When there are multiple exit lanes use the right-hand lane. • When going straight ahead (i.e., exiting halfway around the roundabout), use the following procedure (see Exhibit 2-7): — Do not use any turn signals on approach. — If there are two approach lanes, you may use either the left— or right-hand approach lanes. — When on the circulatory roadway, turn on your right-turn signal once you have passed the exit before the one you want and continue to use your right- turn signal through your exit. — Maintain your inside (left) or outside (right) track throughout the roundabout if the circulatory roadway is wide.This means that if you entered using the inner (left) lane, circulate using the inside track of the circulatory roadway and exit from here by crossing the outside track. Likewise, if you entered using the outer (right) lane, circulate using the outside track of the circulatory roadway and exit directly from here. Do not change lanes within the roundabout ex- cept when crossing the outer circulatory track in the act of exiting. Federal HighwayAdministration '�" I Source: The HighwayCode IUK) (9�, converted to righ± �,c — When exiting the circulatory roadway from the inside track, watch out on the outside track for leading or adjacent vehicles that continue to circulate around the roundabout. — When exiting the circulatory roadway from the outside track, yield to leading or adjacent vehicles that are exiting into the same lane. • When turning left or making a U-turn (i.e., exiting more than halfway around the roundabout), use the following procedure (see Exhibit 2-81: — Turn on your left turn signal. — If there are multiple approach lanes, use only the left-hand lane. — Keep to the inner (left) side of the circulatory roadway (nearest the central island�. — Continue to use your left-turn signal until you have passed the exit before the one you want, and then use your right-turn signal through your exit. — When exiting from a multilane roundabout from the inside part of the circula- tory roadway, use only the inner lane on the exit (the lane nearest the splitter island�. Watch out on the outside part of the circulatory roadway for leading or adjacent vehicles that continue to circulate around the roundabout. Roundabouts: An Informational Guide • 2: Policy Considerations � Exhibit 2-7. Driving straight through a roundabout. 45 Exhibit 2-8. Turning left at a roundabout. Source: The Highway Code (UK) (9), converted to right-hand drive • When in doubt about lane choice (especially for roundabouts with legs at angles other than 90'/z►, use the following general rules to determine which lane you should be in (unless signs or pavement markings indicate otherwisel: — If you intend to exit the roundabout less than halfway around it, use the right lane. — If you intend to exit the roundabout more than halfway around it, use the left lane. 2.6.1.6 Motorcyclists and 6icyclists Watch out for motorcyclists and bicyclists. Give them plenty of room and show due consideration. Bicyclists may enter the approach roadway from a bicycle lane. Bicyclists will often keep to the right on the roundabout; they may also indicate left to show they are continuing around the roundabout. It is best to treat bicyclists as other vehicles and not pass them while on the circulatory roadway. Motorcyclists should not ride across the mountable truck apron next to the central island, if present. 2.6.1.7 Large vehicles When car drivers approach a roundabout, do not overtake large vehicles. Large vehicles (for example, trucks and buses) may have to swing wide on the approach or within the roundabout. Watch for their turn signals and give them plenty of room, especially since they may obscure other conflicting users. 46 � Federal HighwayAdministration To negotiate a roundabout, drivers of large vehicles may need to use the full width of the roadway, including mountable aprons if provided. They should be careful of all other users of the roundabouts and, prior to entering the roundabout, satisfy themselves that other users are aware of them and will yield to them. 2.6.2 Bicyclist education Bicyclists should likewise be educated about the operating characteristics of round- abouts. Well-designed, low-speed, single-lane roundabouts should not present much difficulty to bicyclists. They should enter these roundabouts just as they enter a stop sign or signal controlled intersection without auxiliary lanes (the bike lane terminates on the approach to these intersections, too). On the approach to the entry, a bicyclist should claim the lane. Right-turning cyclists should keep to the right side of the entry lane; others should be near the center of the lane. Cyclists have three options upon approaching a roundabout: Travel on the circulatory roadway of the roundabout like motorists. When using a double-lane roundabout as a vehicle, obey all rules of the road for vehicles using roundabouts. However, you may feel safer approaching in the right-hand lane and keeping to the right in the roundabout (rather like making two through movements to turn left at a signalized intersection). If you do keep to the right, take extra care when crossing exits and signal left to show you are not leaving. Watch out for vehicles crossing your path to leave or join the roundabout. Watch out for large vehicles on the roundabout, as they need more space to maneuver. It may be safer to wait until they have cleared the roundabout. Or, If you are unsure about using the roundabout, dismount and exit the approach lane before the splitter island on the approach, and move to the sidewalk. Once on the sidewalk, walk your bicycle like a pedestrian. Or, Some roundabouts may have a ramp that leads to a widened sidewalk or a shared bicycle-pedestrian path that runs around the perimeter of the round- about. If a ramp access is provided prior to the pedestrian crossing, you may choose to ramp up to curb level and traverse the sidewalk or path while acting courteously to pedestrians. A ramp may also be provided on the exit legs of a roundabout to reenter the roadway, after verifying that it is safe to do so. 2.6.3 Pedestrian education Pedestrians have the right-of-way within crosswalks at a roundabout; however, pedestrians must not suddenly leave a curb or other safe waiting place and walk into the path of a vehicle if it is so close that it is an immediate hazard.This can be problematic if the design is such that a disabled pedestrian cannot accurately de- termine the gap. Specific education beyond these general instructions should be provided for disabled pedestrians to use any information provided for them. • Do not cross the circulatory roadway to the central island. Walk around the perimeter of the roundabout. Use the crosswalks on the legs of the roundabout. If there is no crosswalk marked on a leg of the roundabout, cross the leg about one vehicle-length away (7.5 m[25 ft1) from the circulatory roadway of the roundabout. Locate the wheelchair ramps in the curbs.These are built in line with a grade-level opening in the median island. This opening is for pedestrians to wait before crossing the next roadway. Roundabouts: An Informational Guide • 2: Policy Considerations I 4?'° Roundabouts are typically designed to enable pedestrians to cross one direc- tion of traffic at a time. Look and listen for approaching traffic. Choose a safe time to cross from the curb ramp to the median opening (note that although you have the right-of-way, if approaching vehicles are present, it is prudent to first satisfy yourself that conflicting vehicles have recognized your presence and right to cross, through visual or audible cues such as vehicle deceleration or driver communicationl. If a vehicle slows for you to cross at a two-lane round- about, be sure that conflicting vehicles in adjacent lanes have done likewise before accepting the crossing opportunity. • Most roundabouts provide a raised median island halfway across the roadway; wait in the opening provided and choose a safe time to cross traffic approaching from the other direction. 2.7 References 1. Brown, M. TRL State of the Ari Reviev�The Design of Roundabouts. Lon- don: HMSO, 1995. 2. Alphand, F., U. Noelle, and B. Guichet. "Roundabouts and Road Safety: State of the Art in France" In Intersections withoutTraffic Signals ll, Springer-Verlag, Germany (W. Brilon, ed.), 1991, pp. 107-125. 3. Jacquemart, G. Synthesis of Highway Practice 264: Modern Roundabout Prac- tice in ihe United States. National Cooperative Highway Research Program. Washington, D.C: National Academy Press, 1998. 4. Department ofTransport �United Kingdom). "Killing Speed and Saving Lives" As reported in Oregon Department ofTransportation, Oregon Bicycle and Pe- destrian P/an, 1995. 5. Garder, P The Modern Roundabouts: The SensibleAlternative for Maine. Maine Department ofTransportation, Bureau of Planning, Research and Community Services, Transportation Research Division, 1998. 6. Niederhauser, M.E., B.A. Collins, and E.J. Myers. "The Use of Roundabouts: Comparison with Alternate Design Solution" Compendium of Technical Pa- pers, 67th Annual Meeting, Institute ofTransportation Engineers. August 1997. 7. Federal Highway Administration (FHWA). Older Driver Highway Design Hand- book. Publication No. FHWA-RD-97-135. Washington, D.C.: FHWA, January 1998. 8. National Committee on UniformTraffic Laws and Ordinances (NCUTLO). Uni- form Vehicle Code and Model Traffic Ordinance. Evanston, Illinois: NCUTLO, 1992. 9. Department of Transport (United Kingdom►. The Highway Code. Department ofTransport and the Central Office of Information for Her Majesty's Stationery Office, 1996. 10. Australia. TrafficAct, Part 6A, 1962. 11. VicRoads. Uictorian Traffic Handbook, Fourth Edition. Melbourne, Australia: Roads Corporation, 1998. 3 ��' '.' I Federal HighwayAdministration Planning 3.1 Planning Steps 3.2 Considerations of Context 3.2.1 Decision environments 3.2.2 Site-specific conditions 3.3 Number of Entry Lanes 3.3.1 Single- and double-lane roundabouts 3.3.2 Mini-roundabouts 3.4 Selection Categories 3.4.1 Community enhancement 3.4.2 Traffic calming 3.4.3 Safety improvement 3.4.4 Operational improvement 3.4.5 Special situations 3.5 Comparing Operational Performance of Alternative I ntersection Types 3.5.1 Two-way stop-control alternative 3.5.2 All-way stop-control alternative 3.5.3 Signal control alternative 3.6 Space Requirements 3.7 Economic Evaluation 3.7.1 Methodology 3.7.2 Estimating benefits 3.7.3 Estimation of costs 3.8 References 51 53 53 54 55 56 56 58 58 58 59 62 63 64 64 65 67 69 70 73 73 75 76 Exhibit 3-1. Exhibit 3-2. Exhibit 3-3. Exhibit 3-4. Exhibit 3-5. Exhibit 3-6. Exhibit 3-7. Exhibit 3-8. Exhibit 3-9. Exhibit 3-10. Exhibit 3-71. Exhibit 3-12. Exhibit 3-13. Exhibit 3-14. Exhibit 3-75. Exhibit 3-16. Exhibit 3-17. Exhibit 3-78. Exhibit 3-19. Maximum daily service volumes for a four-leg roundabout Planning-level maximum daily service volumes for mini-roundabouts. Example of community enhancement roundabout. Example of traffic calming roundabouts. Comparison of predicted rural roundabout injury crashes with ruraITWSC intersections. Model comparison of predicted injury crashes for single-lane and double-lane roundabouts with rural or urban signalized intersections. Average delay per vehicle at the MUTCD peak hour signal warrant threshold (excluding geometric delay). Comparison ofTWSC and single-lane roundabout capacity. Sample hourly distribution of traffic. Annual savings in delay of single-lane roundabout versus AWSC, 50 percent of volume on the major street. Annual savings in delay of single-lane roundabout versus AWSC, 65 percent of volume on the major street. Delay savings for roundabout vs. signal, 50 percent volume on major street. Delay savings for roundabout vs. signal, 65 percent volume on major street. Assumptions for spatial comparison of roundabouts and comparable conventional intersections. Area comparison: Urban compact roundabout vs. comparable signalized intersection. Area comparison: Urban single-lane roundabout vs. comparable signalized intersection. Area comparison: Urban double-lane roundabout vs. comparable signalized intersection. Area comparison: Urban flared roundabout vs. comparable signalized intersection. Estimated costs for crashes of varying levels of severity. 57 57 59 60 61 61 63 65 66 67 67 69 69 70 71 71 72 72 74 �= I Federal HighwayAdministration Chapter s p�anning Chapter 1 presented a range of roundabout categories, and suggested typical daily service volume thresholds below which four-leg roundabouts may be expected to operate, without requiring a detailed capacity analysis. Chapter 2 introduced round- about performance characteristics, including comparisons with other intersection forms and control, which will be expanded upon in this chapter.This chapter covers the next steps that lead up to the decision to construct a roundabout with an ap- proximate configuration at a specific location, preceding the detailed analysis and design of a roundabout. By confirming that there is good reason to believe that roundabout construction is feasible and that a roundabout offers a sensible method of accommodating the traffic demand, these planning activities make unnecessary the expenditure of effort required in subsequent chapters. Planning for roundabouts begins with specifying a preliminary configuration. The configuration is specified in terms of the minimum number of lanes required on each approach and, thus, which roundabout category is the most appropriate basis for design: urban or rural, single-lane or double-lane roundabout. Given sufficient space, roundabouts can be designed to accommodate high traffic volumes.There are many additional levels of detail required in the design and analysis of a high-capacity, multi-lane roundabout that are beyond the scope of a planning level procedure. Therefore, this chapter focuses on the more common questions that can be answered using reasonable assumptions and approximations. Feasibility analysis requires an approximation of some of the design parameters and operational characteristics. Some changes in these approximations may be necessary as the design evolves. A more detailed methodology for performing the operational evaluation and geometric design tasks is presented later in Chapters 4 and 6 of this guide, respectively. 3.1 Planning Steps The following steps may be followed when deciding whether to implement a round- about at an intersection: • Step 1: Consider the context. What are there regional policy constraints that must be addressed? Are there site-specific and community impact reasons why a roundabout of any particular size would not be a good choice? (Section 3.2) • Step 2: Determine a preliminary lane configuration and roundabout category based on capacity requirements (Section 3.3). Exhibit 3-1 will be useful for mak- ing a basic decision on the required number of lanes. If Exhibit 3-1 indicates that more than one lane is required on any approach, refer to Chapters 4 and 6 for the more detailed analysis and design procedures. Otherwise, proceed with the planning procedure. • Step 3: Identify the selection category (Section 3.4). This establishes why a roundabout may be the preferred choice and determines the need for specific information. Roundabouts: An Informational Guide • 3: Planning Planning determines whether a roundabout is even feasible, before expending the effort required in subsequent steps. Some of the assumptions and approximations used in planning may change as the design evolves, but are sufficient at this stage to answer many common questions. �`� ` Suggested contents of a roundabout selection study report. ��! • Step 4: Perform the analysis appropriate to the selection category. If the selec- tion is to be based on operational performance, use the appropriate compari- sons with alternative intersections (Section 3.5). Step 5: Determine the space requirements. Refer to Section 3.6 and Appendix B for the right-of-way widths required to accommodate the inscribed circle di- ameter. Determine the space feasibility. Is there enough right-of-way to build it? This is a potential rejection point. There is no operational reason to reject a roundabout because of the need for additional right-of-way; however, right-of-way acquisition introduces administrative complications that many agencies would preferto avoid. • Step 6: If additional space must be acquired or alternative intersection forms are viable, an economic evaluation may be useful (Section 3.7). The results of the steps above should be documented to some extent.The level of detail in the documentation will vary among agencies and will generally be influ- enced by the size and complexity of the roundabout. A roundabout selection study report may include the following elements: • It may identify the selection category that specifies why a roundabout is the logical choice at this intersection; • It may identify current or projected traific control or safety problems at the inter- section if the roundabout is proposed as a solution to these problems; • It may propose a configuration, in terms of number of lanes on each approach; • It may demonstrate that the proposed configuration can be implemented feasi- bly and that it will provide adequate capacity on all approaches; and • It may identify all potential complicating factors, assess their relevance to the location, and identify any mitigation efforts that might be required. Agencies that require a more complete or formal rationale may also include the following additional considerations: • It may demonstrate institutional and community support indicating that key in- stitutions (e.g., police, fire department, schools, etc.) and key community lead- ers have been consulted; • It may give detailed performance comparisons of the roundabout with alterna- tive control modes; • It may include an economic analysis, indicating that a roundabout compares favorably with alternative control modes from a benefit-cost perspective; and • It may include detailed appendices containing traffic volume data, signal, or all-way stop control (AWSC) warrant analysis, etc. None of these elements should be construed as an absolute requirement for docu- mentation. The above list is presented as a guide to agencies who choose to pre- pare a roundabout study report. Federal HighwayAdministration 3.2 Considerations of Context 3.2.7 Decision environments There are three somewhat different policy environments in which a decision may be made to construct a roundabout at a specific location. While the same basic analysis tools and concepts apply to all of the environments, the relative impor- tance of the various aspects and observations may differ, as may prior constraints that are imposed at higher policy levels. A new roadway system: Fewer constraints are generally imposed if the location under consideration is no*, a part of an existing roadway system. Right-of-way is usually easier to acquire or commit. Other intersection forms also offer viable alter- natives to roundabouts. There are generally no field observations of site-specific problems that must be addressed.This situation is more likely to be faced by devel- opers than by public agencies. The first roundabout in an area: The first roundabout in any geographic area requires an implementing agency to perform due diligence on roundabouts regard- ing their operational and design aspects, community impacts, user needs, and public acceptability. On the other hand, a successfully implemented roundabout, especially one that solves a perceived problem, could be an important factor in gaining support for future roundabouts at locations that could take advantage of the potential benefits that roundabouts may offer. Some important considerations for this decision environment include: • Effort should be directed toward gaining community and institutional support for the selection of a site for the first roundabout in an area. Public acceptance for roundabouts, like any new roadway facility, require agency staff to under- stand the potential issues and communicate these effectively with the impacted community; • An extensive justification effort may be necessary to gain the required support; • A cautious and conservative approach may be appropriate; careful consider- ation should be given to conditions that suggest that the benefits of a round- about might not be fully realized. Collecting data on current users of the facility can provide important insights regarding potential issues and design needs; • A single-lane roundabout in the near-term is more easily understood by most drivers and therefore may have a higher probability of acceptance by the motor- ing public; • The choice of design and analysis procedures could set a precedent for future roundabout implementation; therefore, the full range of design and analysis alternatives should be explored in consultation with other operating agencies in the region; and • After the roundabout is constructed, evaluating its operation and the public re- sponse could provide documentation to support future installations. Retrofit to an existing intersection in an area where roundabouts have already gained acceptance:This environment is one in which a solution to a site-specific problem is being sought. Because drivers are familiar with roundabout operation, a less intensive process may suffice. Double-lane roundabouts could be considered, and the regional design and evaluation procedures should have already been agreed Will the roundabout be... • Part of a new roadway7 • The first in an area? • A retrofit of an existing intersection? The first roundabout in an area requires greater education and justification efforts. Single-lane roundabouts will be more easily understood initially than multilane roundabouts. Roundabouts: An Informational Guide • 3: Planning I� Site-specific factors that may significantly influence a roundabout's design. upon.The basic objectives of the selection process in this case are to demonstrate the community impacts and that a roundabout will function properly during the peak period within the capacity limits imposed by the space available; and to de- cide whether one is the preferred alternative. If the required configuration involves additional right-of-way, a more detailed analysis will probably be necessary, using the methodology described in Chapter 4. Many agencies that are contemplating the construction of their first roundabout are naturally reluctant to introduce complications, such as double-lane, yield- controlled junctions, which are not used elsewhere in their jurisdiction. It is also a common desire to avoid intersection designs that require additional right-of-way, because of the effort and expense involved in right-of-way acquisition. Important questions to be addressed in the planning phase are therefore: Will a minimally configured roundabout (i.e., single-lane entrances and circula- tory roadway) provide adequate capacity and performance for all users, or will additional lanes be required on some legs or at some future time? • Can the roundabout be constructed within the existing right-of-way, or will it be necessary to acquire additional space beyond the property lines? • Can a single-lane roundabout be upgraded in the future to accommodate growth? If not, a roundabout alternative may require that more rigorous analysis and design be conducted before a decision is made. 3.2.2 Site-specific conditions Some conditions may preclude a roundabout at a specific location. Certain site-related factors may significantly influence the design and require a more de- tailed investigation of some aspects of the design or operation. A number of these factors (many of which are valid for any intersection type) are listed below: • Physical or geometric complications that make it impossible or uneconomical to construct a roundabout.These could include right-of-way limitations, utility con- flicts, drainage problems, etc. • Proximity of generators of significant traffic that might have difficulty negotiat- ing the roundabout, such as high volumes of oversized trucks. • Proximity of other traffic control devices that would require preemption, such as railroad tracks, drawbridges, etc. • Proximity of bottlenecks that would routinely back up traffic into the roundabout, such as over-capacity signals, freeway entrance ramps, etc.The successful op- eration of a roundabout depends on unimpeded flow on the circulatory road- way. If traffic on the circulatory roadway comes to a halt, momentary intersec- tion gridlock can occur. In comparison, other control types may continue to serve some movements under these circumstances. • Problems of grades or unfavorable topography that may limit visibility or compli- cate construction. • Intersections of a major arterial and a minor arterial or local road where an unac- ceptable delay to the major road could be created. Roundabouts delay and de- flect all traffic entering the intersection and could introduce excessive delay or speed inconsistencies to flow on the major arterial. �.; I Federal HighwayAdministration Heavy pedestrian or bicycle movements in conflict with high traffic volumes. (These conflicts pose a problem for all types of traffic control. There is very little experience on this topic in the U.S., mostly due to a lack of existing roundabout sites with heavy intermodal conflicts). Intersections located on arterial streets within a coordinated signal network. In these situations, the level of service on the arterial might be better with a signal- ized intersection incorporated into the system. Chapter 8 deals with system considerations for roundabouts. The existence of one or more of these conditions does not necessarily preclude the installation of a roundabout. Roundabouts have, in fact, been built at locations that exhibit nearly all of the conditions listed above. Such factors may be resolved in several ways: • They may be determined to be insignificant at the specific site; • They may be resolved by operational modeling or specific design features that indicate that no significant problems will be created; • They may be resolved through coordination with and support from other agen- cies, such as the local fire department; and • In some cases, specific mitigation actions may be required. All complicating factors should be resolved prior to the choice of a roundabout as the preferred intersection alternative. The effect of a particular factor will often depend on the degree to which round- abouts have been implemented in the region. Some conditions would not be ex- pected to pose problems in areas where roundabouts are an established form of control that is accepted by the public. On the other hand, some conditions, such as heavy pedestrian volumes, might suggest that the installation of a roundabout be deferred until this control mode has demonstrated regional acceptance. Most agen- cies have an understandable reluctance to introduce complications at their first roundabout. 3.3 Number of Entry Lanes A basic question that needs to be answered is how many entry lanes a roundabout would require to serve the traffic demand.The capacity of a roundabout is clearly a critical parameter and one that should be checked at the outset of any feasibility study. Chapter 4 offers a detailed capacity computation procedure, mostly based on experiences in other countries. Some assumptions and approximations have been necessary in this chapter to produce a planning-level approach for deciding whether or not capacity is sufficient. Since this is the first of several planning procedures to be suggested in this chap- ter, some discussion of the assumptions and approximations is appropriate. First, traffic volumes are generally represented for planning purposes in terms of Aver- age Daily Traffic (ADT), or Average Annual Daily Traffic (AADT). Traffic operational analyses must be carried out at the design hour level. This requires an assumption of a K factor and a D factor to indicate, respectively, the proportion of the AADT Roundabouts: An Informational Guide • 3: Planning I g� The volume-to-capacity ratio of any roundabout leg is recommended not to exceed 0.85. assigned to the design hour, and the proportion of the two-way traffic that is as- signed to the peak direction. All of the planning-level procedures offered in this chapter were based on reasonably typical assumed values for K of 0.1 and D of 0.58. There are two site-specific parameters that must be taken into account in all com- putations. The first is the proportion of traffic on the major street. For roundabout planning purposes, this value was assumed to lie between 0.5 and 0.67. All analy- ses assumed a four-leg intersection. The proportion of left turns must also be con- sidered, since left turns affect all traffic control modes adversely. For the purposes of this chapter, a reasonably typical range of left turns were examined. Right turns were assumed to be 10 percent in all cases. Right turns are included in approach volumes and require capacity, but are not included in the circulating volumes down- stream because they exit before the next entrance. The capacity evaluation is based on values of entering and circulating traffic vol- umes as described in Chapter 4. The AADT that can be accommodated is conser- vatively estimated as a function of the proportion of left turns, for cross-street volume proportions of 50 percent and 67 percent. For acceptable roundabout op- eration, many sources advise that the volume-to-capacity ratio on any leg of a roundabout not exceed 0.85 (1, 2).This assumption was used in deriving the AADT maximum service volume relationship. 3.3.1 Single- and double-lane roundabouts The resulting maximum service volumes are presented in Exhibit 3-1 for a range of left turns from 0 to 40 percent of the total volume.This range exceeds the normal expectation for left turn proportions.This procedure is offered as a simple, conser- vative method for estimating roundabout lane requirements. If the 24-hour vol- umes fall below the volumes indicated in Exhibit 3-1, a roundabout should have no operational problems at any time of the day. It is suggested that a reasonable approximation of lane requirements for a three-leg roundabout may be obtained using 75 percent of the service volumes shown on Exhibit 3-1. If the volumes exceed the threshold suggested in Exhibit 3-1, a single-lane or double-lane roundabout may still function quite well, but a closer look at the actual turning movement volumes during the design hour is required.The procedures for such analysis are presented in Chapter 4. 3.3.2 Mini-roundabouts Mini-roundabouts are distinguished from traditional roundabouts primarily by their smaller size and more compact geometry.They are typically designed for negotia- tion speeds of 25 km/h 115 mph). Inscribed circle diameters generally vary from 13 m to 25 m(45 ft to 80 ft). Mini-roundabouts are usually implemented with safety in mind, as opposed to capacity. Peak-period capacity is seldom an issue, and most mini-roundabouts operate on residential or collector streets at demand levels well below their capacity. It is important, however, to be able to assess the capacity of any proposed intersection design to ensure that the intersection would function properly if constructed. At very small roundabouts, it is reasonable to assume that each quadrant of the circulatory roadway can accommodate only one vehicle at a time. In other words, �i81 I Federal HighwayAdministration � � a vehicle may not enter the circulatory roadway unless the quadrant on both sides of the approach is empty. Given a set of demand volumes for each of the 12 stan- dard movements at a four-leg roundabout, it is possible to simulate the roundabout to estimate the maximum service volumes and delay for each approach. By mak- ing assumptions about the proportion of left turns and the proportion of cross street traffic, a general estimate of the total entry maximum service volumes of the round- about can be made, and is provided in Exhibit 3-2. AADT maximum service vol- umes are represented based on an assumed K value of 0.10. Note that these volumes range from slightly more than 12,000 to slightly less than 16,000 vehicles per day.The maximum throughput is achieved with an equal proportion of vehicles on the major and minor roads, and with low proportions of left turns. so,000 50,000 0 0 40,000 Y H Q 30,000 a E � E 20,000 'x m � 10,000 p' I 0% 10% 20% 30% 40% LeftTurn Percentage �• 1 Lane (50% Minor) 1 Lane (33% Minor) —� 2 Lanes (50% Minor) �+— 2 Lanes (33% Minor) is,000 is,000 � ia,000 � r � i2,000 a •� 10,000 m a �j 8,000 F- Q� 6,000 Q 4,000 2,000 0 10% 30% 50% Percent LeftTurns -A-25% CrossTraffic f50% CrossTraffic Roundabouts: An Informational Guide • 3: Planning Exhibit 3-1. Maximum daily service volumes for a four-leg roundabout. For three-leg roundabouts, use 75 percent of the maximum AADT volumes shown. Exhibit 3-2. Planning-level maximum daily service volumes for mini-roundabouts. 57 3.4 Selection Categories There are many locations at which a roundabout could be selected as the preferred traffic control mode. There are several reasons why this is so, and each reason creates a separate selection category. Each selection category, in turn, requires different information to demonstrate the desirability of a roundabout. The principal selection categories will be discussed in this section, along with their information requirements. A wide range of roundabout policies and evaluation practices exists among operat- ing agencies within the U.S. For example, the Florida Department ofTransportation requires a formal "justification report" to document the selection of a roundabout as the most appropriate traffic control mode at any intersection on their State high- way system. On the other hand, private developers may require no formal rational- ization of any kind. It is interesting to note that the Maryland Department ofTrans- portation requires consideration of a roundabout as an alternative at all intersec- tions proposed for signalization. It is reasonable that the decision to instail a roundabout should require approxi- mately the same level of effort as the alternative control mode. In other words, if a roundabout is proposed as an alternative to a traffic signal, then the analysis effort should be approximately the same as that required for a signal. If the alternative is stop sign control, then the requirements could be relaxed. The following situations present an opportunity to demonstrate the desirability of installing a roundabout at a specific location. 3.4.1 Community enhancement Roundabouts have been proposed as a part of a community enhancement project and not as a solution to capacity problems. Such projects are often located in com- mercial and civic districts, as a gateway treatment to convey a change of environ- ment and to encourage traffic to slow down. Traffic volumes are typicaliy well be- low the thresholds shown in Exhibit 3-1; otherwise, one of the more operationally oriented selection categories would normally be more appropriate. The planning focus for Roundabouts proposed for community enhancement require minimal analysis as a community enhancement traffic control device. The main focus of the planning procedure should be to dem- roundabouts should be to onstrate that they would not introduce traffic problems that do not exist currently. demonstrate that they will not Particular attention should be given to any complications that would imply either create traffic problems that do operational or safety problems. The urban compact category may be the most not now exist. appropriate roundabout for such applications. Exhibit 3-3 provides an example of a roundabout installed primarily for community enhancement. 3.4.2 Traffic calming The decision to install a roundabout for traffic calming purposes should be sup- ported by a demonstrated need for traffic calming along the intersecting roadways. Most of the roundabouts in this category will be located on local roads. Examples of conditions that might suggest a need for traffic calming include: Conditions that traffic calming • Documented observations of speeding, high traffic volumes, or careless driving roundabouts may address. activities; 58 I Federal HighwayAdministration Naples, FL • Inadequate space for roadside activities, or a need to provide slower, safer con- ditions for non-automobile users; or New construction (road opening, traffic signal, new road, etc.) which would po- tentially increase the volumes of "cut-through" traffic. Capacity should be an issue when roundabouts are installed for traffic calming purposes only because traffic volumes on local streets will usually be well below the level that would create congestion. If this is not the case, another primary selection category would probably be more suitable.The urban mini-roundabout or urban compact roundabout are most appropriate for traffic calming purposes. Ex- hibit 3-4 provides an example of roundabouts installed primarily for traffic calming. 3.4.3 Safety improvement The decision to install a roundabout as a safety improvement should be based on a demonstrated safety problem of the type susceptible to correction by a round- about. A review of crash reports and the type of accidents occurring is essential. Examples of safety problems include: Exhibit 3-3. Example of community enhancement roundabout. High rates of crashes involving conflicts that would tend to be resolved by a Safety issues that roundabouts roundabout (right angle, head-on, left/through, U-turns, etc.); may help correct. High crash severity that could be reduced by the slower speeds associated with roundabouts; Roundabouts: An Informational Guide • 3: Planning I 59 Exhibit 3-4. Example of traffic calming roundabouts. Naples, FL Site visibility problems that reduce the effectiveness of stop sign control (in this case, landscaping of the roundabout needs to be carefully consideredl; and • Inadequate separation of movements, especially on single-lane approaches. Chapter 5 should be consulted for a more detailed analysis of the safety character- istics of roundabouts.There are currently a small number of roundabouts and there- fore a relatively small crash record data base in the U.S.Therefore, it has not been possible to develop a national crash model for this intersection type. Roundabout crash prediction models have been developed for the United Kingdom (3). Crash models for conventional intersections in the United States are available (4, 51. AI- though crash data reporting may not be consistent between the U.K. and the U.S., comparison is plausible.The two sets of models have a key common measure of effectiveness in terms of injury and fatal crash frequency. Therefore, for illustrative purposes, Exhibit 3-5 provides the resuits of injury crash prediction models for various ADT volumes of roundabouts versus ruraITWSC in- tersections (6).The comparison shown is for a single-lane approach, four-leg round- about with single-lane entries, and good geometric design. For the TWSC rural intersection model, the selected variables include rolling terrain, the main road as major collector, and a design speed of 80 km/h (50 mph). Rural roundabouts may experience approximately 66 percent fewer injury crashes than rural TWSC inter- sections for 10,000 entering ADT and approximately 64 percent fewer crashes for 20,000 ADT At urban roundabouts, the reduction will probably be smaller. Also for illustration, Exhibit 3-6 provides the results of injury crash prediction mod- els for various average daily traffic volumes at roundabouts versus rural and urban signalized intersections (6).The selected variables of the crash model for signalized (urban/suburban) intersections include multiphase fully-actuated signal, with a speed of 80 km/h (50 mph) on the major road. The 20,000 entering ADT is applied to single-lane roundabout approaches with four-legs. The 40,000 ADT is applied to double-lane r�ndabout approaches without flaring of the roundabout entries. In comparison to signalized intersections, roundabouts may experience approximately g0 � Federal HighwayAdministration 3.50 �I 3.00 _ � .X i � � 2.50 X� / _� d / ' � � 2.00 - --- ! - - . C i v� . d ^ � C�i 1.50 �'_ _ —..__' a T j %� �� i.00 �; X i , � --�-----• oso �- .- _ • � — -« o.00 _� _ --, 0 0.05 0.1 0.15 0.2 0.25 0.3 0.35 ADT Minor/ADT I-x- TWSC 110,000 ADTI -X-TWSC 120,000 ADT) -p- Roundabout (70,000 ADT) t Roundabout (20,000 ADT) SOUrCe: (6) 3.50 - �X---X---X 3.00 I —.. v= � ._ _ . _._ ._ .. v �� ' � � �� — _� _ _� _. _• 2.50 I' — . _ _. _._ _ � ; 9 � 200 _ .X ' x- .� � a ,.eo � X—_X ,.00 �—� 0.50 I .__X____...X_..___.X 1 o.00 i 0 0.1 01 0.3 0.4 0.5 0.6 ---x� � Fiural Intarsection �20,000 ADTI -�- .— Urban Intersection (20,000 ADT� �X • Urban Intersection 100,000 ADT� � —�� Rounda6out�20.000ADT1 � • Roundaboutl60p00ADT� Source: (6) 33 percent fewer injury crashes in urban and suburban areas and 56 percent fewer crashes in rural areas for 20,000 entering ADT. For 40,000 entering ADT this reduc- tion may only be about 15 percent in urban areas. Therefore, it is likely that round- about safety may be comparable to signalized intersections at higher ADT (greater than 50,000). These model comparisons are an estimation of inean crash frequency or average safety performance from a random sample of four-leg intersections from different countries and should be supplemented by engineering judgment and attention to safe design for all road users. Roundabouts:An Informational Guide • 3: Planning Exhibit 3-5. Comparison of predicted roundabout injury crashes with ruraITWSC intersections. Roundabouts have fewer annual injury crashes than rural two-way stop-controlled intersections, and the total number of crashes at roundabouts is relatively insensitive to minor street demand volumes. Exhibit 3-6. Comparison of predicted injury crashes for single-lane and double-lane roundabouts with rural or urban signalized intersections. Roundabouts have fewer injury accidents per year than signalized intersections, particulady in rural areas. At volumes greater than 50,000 ADT, urban roundabout safety may be comparable to that of urban signalized intersections. 61' General delay and capacity comparisons between round- abouts and other forms of intersection control. 3.4.4 Operational improvement A roundabout may be considered as a logical choice if its estimated performance is better than alternative control modes, usually either stop or signal control. The performance evaluation models presented in the next chapter provide a sound basis for comparison, but their application may require more effort and resources than an agency is prepared to devote in the planning stage. To simplify the selec- tion process, the following assumptions are proposed for a planning-level compari- son of control modes: 1. A roundabout will always provide a higher capacity and lower delays than AWSC operating with the same traffic volumes and right-of-way limitations. 2. A roundabout is unlikely to offer better performance in terms of lower overall delays thanTWSC at intersections with minor movements (including cross street entry and major street left turns) that are not experiencing, nor predicted to experience, operational problems underTWSC. 3. A single-lane roundabout may be assumed to operate within its capacity at any intersection that does not exceed the peak-hour volume warrant for signals. 4. A roundabout that operates within its capacity will generally produce lower de- lays than a signalized intersection operating with the same traffic volumes and right-of-way limitations. The above assumptions are documented in the literature (7) or explained by the analyses in Section 3.5. Collectively, they provide a good starting point for further analysis using procedures in Chapter 4. Although a roundabout may be the optimal control type from a vehicular operation standpoint, the relative performance of this control alternative for other modes should also be taken into consideration, as explained in Chapter 4. 3.4.4.1 Roundabout performance at flow thresholds for peak hour signal warrants There are no warrants for roundabouts included in the Manual of Uniform Traffic Control Devices (MUTCD) (8), and it may be that roundabouts are not amenable to a warranting procedure. In other words, each roundabout should be justified on its own merits as the most appropriate intersection treatment alternative. It is, how- ever, useful to consider the case in which the traffic volumes just meet the MUTCD warrant thresholds for traffic signals. For purposes of this discussion, the MUTCD peak hour warrant will be applied with a peak hour factor (PHF) of 0.9. Thus, the evaluation will reflect the performance in the heaviest 15 minutes of the peak hour. Roundabout delays were compared with the corresponding values forTWSC, AWSC, and signals. A single-lane roundabout was assumed because the capacity of a single lane roundabout was adequate for all cases at the MUTCD volume warrant thresholds. SIDRA analysis software was used to estimate the delay for the vari- ous control alternatives because SIDRA was the only program readily available at the time this guide was developed that modeled all of the control alternatives (9). The MUTCD warrant thresholds are given in terms of the heaviest minor street volume and sum of the major street volumes. Individual movement volumes may be obtained from the thresholds by assuming a directional factor, D, and left turn proportions. A"D" factor of 0.58 was applied to this example. Left turns on all approaches were assumed to be 10 to 50 percent of the total approach volume. In 62 I Federal HighwayAdministration determining the MUTCD threshold volumes, two lanes were assumed on the ma- jor street and one lane on the minor street. Based on these assumptions, the average delays per vehicle for signals and round- abouts are presented in Exhibit 3-7.These values represent the approach delay as perceived by the motorist.They do not include the geometric delay incurred within the roundabout. It is clear from this figure that roundabout control delays are sub- stantially lower than signal delays, but in neither case are the delays excessive. Similar comparisons are not presented forTWSC, because the capacity for minor street vehicles entering the major street was exceeded in all cases at the signal L a� > N > m m G ar o� m a� � ¢ zo 18 16 14 12 10 600 700 800 900 1000 1100 1200 1300 1400 1500 Total Major Street Volume (veh/h) -♦- Signal (10% left turns) f Signal (50% left turns) Roundabout (10% left tums) �E- Roundabout (50% left tums) warrant thresholds. AWSC was found to be feasible only under a limited range of conditions: a maximum of 20 percent left turns can be accommodated when the major street volume is low and only 10 percent can be accommodated when the major street volume is high. Note that the minor street volume decreases as the major street volume increases at the signal warrant threshold. This analysis of alternative intersection performance at the MUTCD peak hour vol- ume signal warrant thresholds indicates that the single-lane roundabout is very competitive with all other forms of intersection control. 3.4.5 Special situations It is important that the selection process not discourage the construction of a round- about at any location where a roundabout would be a logical choice. Some flexibil- ity must be built into the process by recognizing that the selection categories above are not all-inclusive.There may still be other situations that suggest that a round- about would be a sensible control choice. Many of these situations are associated with unusual alignment or geometry where other solutions are intractable. Exhibit 3-7. Average delay per vehicle at the MUTCD peak hour signal warrant threshold (exclud- ing geometric delay). Roundabout approach delay is relatively insensitive to total major street volume, but is sensitive to the left-turn percentage. Roundabouts: An Informational Guide • 3: Planning � 63 3.5 Comparing Operational Performance of Alternative Inter- section Types If a roundabout is being considered for operational reasons, then it may be compared with other feasible intersection control alternatives such asTWSC, AWSC, or sig- nal control.This section provides approximate comparisons suitable for planning. 3.5.1 Two-way stop-control altemative The majority of intersections in the U.S. operate underTWSC, and most of those intersections operate with minimal delay.The installation of a roundabout at aTWSC intersection that is operating satisfactorily will be difficult to justify on the basis of performance improvement alone, and one of the previously described selection categories is likely to be more appropriate. The two most common problems atTWSC intersections are congestion on the Roundabouts may offer an minor street caused by a demand that exceeds capacity, and queues that form on effective solution atTWSC the major street because of inadequate capacity for left turning vehicles yielding to intersections with heavy left turns opposing traffic. Roundabouts may offer an effective solution to traffic problems at from the major street. TWSC intersections with heavy left turns from the major route because they pro- vide more favorable treatment to left turns than other control modes. "T" intersec- tions are especially good candidates in this category because they tend to have higher left turning volumes. Roundabouts work better On the other hand, the problems experienced by low-volume cross street traffic at when the proportion of minor TWSC intersections with heavy through volumes on the major street are very dif- street traffic is higher. ficult to solve by any traffic control measure. Roundabouts are generally not the solution to this type of problem because they create a significant impediment to the major movements. This situation is typical of a residential street intersection with a major arterial. The solution in most cases is to encourage the residential traffic to enter the arterial at a collector road with an intersection designed to ac- commodate higher entering volumes.The proportion of traffic on the major street is an important consideration in the comparison of a roundabout with a conven- tional four-leg intersection operating underTWSC. High proportions of minor street traffic tend to favor roundabouts, while low proportions favorTWSC. An example of this may be seen in Exhibit 3-8, which shows the AADT capacity for planning purposes as a function of the proportion of traffic on the major street.The assumptions in this exhibit are the same as those that have been described previ- ously in Section 3.3. Constant proportions of 10 percent right turns (which were ignored in roundabout analysis) and 20 percent left turns were used for all move- ments. As expected, the roundabout offers a much higher capacity at lower propor- tions of major street traffic. When the major and minor street volumes are equal, the roundabout capacity is approximately double that of theTWSC intersection. It is interesting to note that the two capacity values converge at the point where the minor street proportion becomes negligible. This effect confirms the expectation that a roundabout will have approximately the same capacity as a stop-controlled intersection when there is no cross street traffic. 64 � Federal HighwayAdministration 30,000 25,000 � zo,000 .� a A � 15,000 c a a io,000 5,000 � 50% 60% 70% 80% 90% Major StreetTraffic Proportion -�TWS �-Roundabout 3.5.2 All-way stop-control altemative When cross street traffic volumes are heavy enough to meet the MUTCD warrants for AWSC control, roundabouts become an especially attractive solution because of their higher capacities and lower delays. The selection of a roundabout as an alternative to AWSC should emphasize cost and safety considerations, because roundabouts always offer better performance for vehicles than AWSC, given the same traffic conditions. Roundabouts that are proposed as alternatives to stop control would typically have single-lane approaches. A substantial part of the benefit of a roundabout compared to an all-way stop inter- section is obtained during the off-peak periods, because the restrictive stop con- trol applies for the entire day.The MUTCD does not permit stop control on a part-time basis. The extent of the benefit will depend on the amount of traffic at the intersec- tion and on the proportion of left turns. Left turns degrade the operation of all traffic control modes, but they have a smaller effect on roundabouts than on stop signs or signals. The planning level analysis that began earlier in this chapter may be extended to estimate the benefits of a roundabout compared to AWSC. Retaining the previous assumptions about the directional and temporal distribution factors for traffic vol- umes (i.e., K=0.1, D=0.58), it is possible to analyze both control modes throughout an entire 24-hour day. Only one additional set of assumptions is required. It is necessary to construct an assumed hourly distribution of traffic throughout the day that conforms to these two factors. A reasonably typical sample distribution for this purpose is illustrated in Exhibit 3-9, which would generally represent inbound traffic to employment centers, because of the larger peak in the AM period, accompanied by smaller peaks in the noontime and PM periods. Daytime off-peak periods have 4 percent of the AADT per hour, and late-night off-peak periods (midnight to 6 AM) have 1 percent. Exhibit 3-8. Comparison ofTWSC and single-lane roundabout capacity. Roundabout capacity decreases as the proportion of minor street entering traffic decreases. Roundabouts andTWSC intersections have about the same capacity when the minor street proportion is less than 70 percent. A substantial part of the delay- reduction benefit of roundabouts, compared toAWSC intersections, comes during off-peak periods. Roundabouts: An Informational Guide • 3: Planning I 65 Exhibit 3-9. Sample hourly distribution of traffic. 12 10 � 8 c � 6 � d ° 4 d a 2 0 00 00 00 00 00 100 �oo �oo ^oo goa 100 �oo ;� �� . �. �. � , ' �. ' ti ti --- -- � , — _ ----- ' . --- - — ' �. - � . . , • _ . - r�, __ _ , . . . . . � , � . . . . _ . ----�_ �� - —- � � – - — - — — — — � Time Ending The outbound direction may be added as a mirror image of the inbound direction, keeping the volumes the same as the inbound during the off-peak periods and applying the D factor of 0.58 during the AM and PM peaks. This distribution was used in the estimation of the benefits of a roundabout compared to the AWSC mode. It was also used later for comparison with traffic signal operations. For pur- poses of estimating annual delay savings, a total of 250 days per year is assumed. This provides a conservative estimate by eliminating weekends and holidays. The comparisons were performed using traffic operations models that are described in Chapter 4 of this guide.The SIDRA model was used to analyze both the round- about and AWSC operation, because SIDRA was the only model readily available at the time this guide was developed that treated both of these types of control. SIDRA provides an option to either include or omit the geometric delay experi- enced within the intersection. The geometric delay was included for purposes of estimating annual benefits. It was excluded in Section 3.4.4.1 that dealt with driver-perceived approach delay. The results of this comparison are presented in Exhibit 3-10 and Exhibit 3-11 in terms of potential annual savings in delay of a single-lane roundabout over an AWSC intersection with one lane on all approaches, as a function of the proportion of left turning traffic for single-lane approaches for volume distributions of 50 percent and 65 percent on the major street, respectively. Each exhibit has lines representing 10 percent, 25 percent, and 33 percent left turn proportions. Note that the potential annual benefit is in the range of 5,000 to 50,000 vehicle-hours per year. The benefit increases substantially with increasing AADT and left turn proportions. The comparison terminates in each case when the capacity of the AWSC operation is exceeded. No comparisons were made beyond 18,000 AADT, because AWSC operation is not practical beyond that level. 66 I Federal HighwayAdministration so,000 � 50,000 r r d � � ao,000 0 «� c+ � 30,000 x T m 0 20,000 �o ' c Q 10,000 0 so,oao y 50,000 t t d � 40,000 c 0 � 9 30,000 w � > � Q 20,000 io 7 C a ia,000 0 10, 000 12, 000 14, 000 16, 000 18, 000 AADT —6— 10 % left turns f 25% left turns —!— 33% left turns io,000 iz,000 ia,000 is,000 ia,000 AADT -�-10% leftturns �-25% leftturns —�33% leftturns 3.5.3 Signal control altemative When traffic volumes are heavy enough to warrant signalization, the selection pro- cess becomes somewhat more rigorous. The usual basis for selection here is that a roundabout will provide better operational performance than a signal in terms of stops, delay, fuel consumption, and pollution emissions. For planning purposes, this may generally be assumed to be the case provided that the roundabout is operating within its capacity.The task then becomes to assess whether any round- about configuration can be made to work satisfactorily. If not, then a signal or grade separation are remaining alternatives. As in the case of stop control, inter- sections with heavy left turns are especially good roundabout candidates. Roundabouts: An Informational Guide • 3: Planning Exhibit 3-70. Annual savings in delay of single-lane roundabout versus AWSC, 50 percent of volume on the major street. The delay-reduction benefit of roundabouts, compared to AWSC, increases as left-tum volumes, major street proportion, and AADT increase. Exhibit 3-11. Annual savings in delay of single-lane roundabout versus AWSC, 65 percent of volume on the major street. 8x The graphical approximation presented earlier for capacity estimation should be useful at this stage. The results should be considered purely as a planning level estimate, and it must be recognized that this estimate will probably change during the design phase. Users of this guide should also consult the most recent version of the Highway Capacity Manual (HCM) (10) as more U.S. data and consensus on modeling U.S. roundabout performance evolves. As in the case of AWSC operations, some of the most important benefits of a roundabout compared to a traffic signal will accrue during the off-peak periods.The comparison of delay savings discussed previously has therefore been extended to deal with traffic signals as well as stop signs. The same temporal distribution of traffic volumes used for the roundabout-AWSC comparison was assumed. The signal timing design was prepared for each of the conditions to accommodate traffic in the heaviest peak period. The traffic actuated controller was allowed to respond to fluctuations in demand during the rest of the day using its own logic. This strategy is consistent with common traffic engineering practice. All approaches were considered to be isolated and free of the influence of coordinated systems. Left turn protection was provided for the whole day for all approaches with a vol- ume cross-product (i.e., the product of the left turn and opposing traffic volumes) of 60,000 or greater during the peak period. When left turn protection was pro- vided, the left turns were also allowed to proceed on the solid green indication (i.e., protected-plus-permitted operation). The results of this comparison are presented in Exhibit 3-12 for 50 percent major street traffic and Exhibit 3-13 for 65 percent major street traffic. Both cases include AADT values up to 34,000 vehicles per day. Single-lane approaches were used for both signals and roundabouts with AADTs below 25,000 vehicles per day.Two-lane approaches were assumed beyond that point. All signalized approaches were as- sumed to have left turn bays. Benefits may continue to accrue beyond the 34,000 AADT level but the design parameters for both the signal and the roundabout are much more difficult to gen- eralize for planning level analyses. When AADTs exceed 34,000 vehicles per day, performance evaluation should be carried out using the more detailed procedures presented in Chapter 4 of this guide. The selection of a roundabout as an alternative to signal control will be much sim- pler if a single-lane roundabout is estimated to have adequate capacity. If, on the other hand, it is determined that one or more legs will require more than one entry lane, some preliminary design work beyond the normal planning level will generally be required to develop the roundabout configuration and determine the space re- quirements. 68 I Federal HighwayAdministration 45,000 > ao,000 r y 35,000 > � 30,000 �i � 25,000 ¢ � zo,000 d � 15,000 m 0 � 10,000 ¢ 5,000 0 35,000 � 30,000 > r y 25,000 > c ° zo,000 .� v' OC 15,000 > m d c to,000 A c Q 5,000 0 10,000 13,000 16,000 19,000 22,000 25,000 28,000 31,000 34,000 AADT �-10% leftturns f25% leftturns t33% leftturns TWO-LANE ---I 10,000 13,000 16,000 19,000 22,000 25,000 28,000 31,000 34,000 AADT t10% lefttums -�25% lefttums -�33% lefttums 1 3.6 Space Requirements Roundabouts that are designed to accommodate vehicles larger than passenger cars or small trucks typically require more space than conventional intersections. However, this may be more than offset by the space saved compared with turning lane requirements at alternative intersection forms. The key indicator of the re- quired space is the inscribed circle diameter. A detailed design is required to deter- mine the space requirements at a specific site, especially if more than one lane is needed to accommodate the entering and circulating traffic. This is, however, an- other case in which the use of assumptions and approximations can produce Exhibit 3-12. Delay savings for roundabout vs. signal, 50 percent volume on major street. When volumes are evenly split between major and minor approaches, the delay savings of roundabouts versus signals are especially notable on two-lane approaches with high left turn proportions. Exhibit 3-'13. Delay savings for roundabout vs. signal, 65 percent volume on major street. When the major street approaches dominate, roundabout delay is lower than signal delay, particulaAy at the upper volume limit for single-lane approaches and when there is a high proportion of left turns. The design templates in Appendix B may be used to determine initial space requirements for the appropri- ate roundabout category. Roundabouts: An Informational Guide • 3: Planning � 89 Exhibit 3-74. Assumptions for spatial comparison of roundabouts and comparable conventional intersections. preliminary values that are adequate for planning purposes. For initial space re- quirements, the design templates in Appendix B for the most appropriate of the six roundabout categories for the specific site may be consulted. One important question is whether or not the proposed roundabout will fit within the existing property lines, or whether additional right-of-way will be required. Four examples have been created to demonstrate the spatial effects of comparable intersection types, and the assumptions are summarized in Exhibit 3-14. Note that there are many combinations of turning volumes that would affect the actual lane configurations and design storage lengths. Therefore, these examples should not be used out of context. Roundabout Type Conventional Intersection Main Street Side Street Main Street Side Street Category Approach Lanes Approach Lanes Approach Lanes Approach Lanes Urban compact 1 1 1 1 Urban single-lane 1 Urban double-lane 2 Urban double-lane 1 flared to 2 with flaring Note: LT = left turn 1 + LT pocket 2 + LT pocket 2 + LT pocket 1 + LT pocket 1 + LT pocket Although roundabouts typically As can be seen in Exhibit 3-15 through Exhibit 3-18, roundabouts typically require require more area at the junction more area at the junction than conventional intersections. However, as capacity compared to conventional needs increase the size of the roundabout and comparable conventional (signal- intersections, they may not need as ized) intersection, the increase in space requirements are increasingly offset by a much area on the approaches. reduction in space requirements on the approaches.This is because the widening or flaring required for a roundabout can be accomplished in a shorter distance than is typically required to develop left turn lanes and transition tapers at conventional intersections. As can be seen in Exhibit 3-18, flared roundabouts offer the most potential for reducing spatial requirements on the approaches as compared to conventional in- tersections. This effect of providing capacity at the intersections while reducing lane requirements between intersections, known as "wide nodes and narrow roads;' is discussed further in Chapter 8. 3.7 Economic Evaluation Economic evaluation is an important part of any public works planning process. For roundabout applications, economic evaluation becomes important when compar- 70 I Federal HighwayAdministration LEGEND f �Area required for roundabout � but not for signal 1 Area required for signal but not for roundabout � � i LEGEND i .Area required for roundabout � but not for signel ;: �: i: Area required for signal but not for roundabout �: ... ;. . �� ._ .............................................. . p . . � _ .... . . ,. ......A �� .... ,: : _..�..._..... ._.___ : ::. <:::: o' _ �: � Exhibit 3-75. Area comparison: Urban compact roundabout vs. comparable signalized intersection. Exhibit 3-16. Area comparison: Urban single-lane roundabout vs. comparable signalized intersection. Roundabouts: An Informational Guide • 3: Planning I 7� Exhibit 3-17. Area comparison: Urban double-lane roundabout vs. comparable signalized intersection. Exhibit 3-18. Area comparison: Urban flared roundabout vs. comparable signalized intersection. Urban flared roundabouts in particular illustrate the "wide nodes, narrow roads" concept discussed further in Chapter 8. 72 � Federal HighwayAdministration ing roundabouts against other forms of intersections and traffic control, such as comparing a roundabout with a signalized intersection. The most appropriate method for evaluating public works projects of this type is usually the benefit-cost analysis method.The following sections discuss this method as it typically applies to roundabout evaluation, although it can be generalized for most transportation projects. 3.7.7 Methodology The benefit-cost method is elaborated on in detail in a number of standard refer- ences, including the ITE Transportation Planning Handbook (11) and various Ameri- can Association of State Highway and Transportation Officials (AASHTO) publica- tions (12, 13). The basic premise of this method of evaluation is to compare the incremental benefit between two alternatives to the incremental costs between the same alternatives. Assuming Alternatives A and B, the equation for calculating the incremental benefit-cost ratio of Alternative B relative to Alternative A is given in Equation 3-1. Benefitse — BenefitsA e/CB A = CosrsB - CosrsA (3-1 � Benefit-cost analysis typically takes two forms. For assessing the viability of a number of alternatives, each alternative is compared individually with a no-build alternative. If the analysis for Alternative A relative to the no-build alternative indi- cates a benefit-cost ratio exceeding 1.0, Alternative A has benefits that exceed its costs and is thus a viable project. For ranking alternatives, the incremental benefit-cost ratio analysis is used to com- pare the relative benefits and costs between alternatives. Projects should not be ranked based on their benefit-cost ratio relative to the no-build alternative. After eliminating any alternatives that are not viable as compared to the no-build alterna- tive, alternatives are compared in a pair-wise fashion to establish the priority be- tween projects. Since many of the input parameters may be estimated, a rigorous analysis should consider varying the parameter values of key assumptions to verify that the rec- ommended alternative is robust, even under slightly varying assumptions, and under what circumstances it may no longer be preferred. 3.7.2 Estimating benefits Benefits for a public works project are generally comprised of three elements: safety benefits, operational benefits, and environmental benefits. Each benefit is typically quantified on an annualized basis and so is readily usable in a benefit-cost analysis.The following sections discuss these in more detail. Rank altematives based on their incremental benefit-cost ratio, not on their ratio relative to the no-build alternative. Benefits consist of: • Safety benefits • Operational benefits • Environmental benefits Roundabouts: An Informational Guide • 3: Planning I 7'3 ' Exhibit 3-19. Estimated costs for crashes of varying levels of severity. 3.7.2.1 Safety benefits Safety benefits are defined as the assumed savings to the public due to a reduc- tion in crashes within the project area.The general procedure for determining safety benefits is as follows: • Quantify the existing safety history in the study area in terms of a crash rate for each level of severity (fatal, injury, property damage). This rate, expressed in terms of crashes per million entering vehicles, is computed by dividing the num- ber of crashes of a given severity that occurred during the "before" period by the number of vehicles that entered the intersection during the same period. This results in a"before" crash rate for each level of severity. • Estimate the change in crashes of each level of severity that can be reasonably expected due to the proposed improvements. As documented elsewhere in this guide, roundabouts tend to have proportionately greater reductions in fatal and injury crashes than property damage crashes. • Determine a new expected crash rate (an "after" crash rate) by multiplying the "before" crash rates by the expected reductions. It is best to use local data to determine appropriate crash reduction factors due to geometric or traffic con- trol changes, as well as the assumed costs of various severity levels of crashes. • Estimate the number of "after" crashes of each level of severity for the life of the project by multiplying the "after" crash rate by the expected number of entering vehicles over the life of the project. • Estimate a safety benefit by multiplying the expected number of "after" crashes of each level of severity by the average cost of each crash and then annualizing the result. The values in Exhibit 3-19 can provide a starting point, although local data should be used where available. Crash Severity Death (per death) Injury (per injury) Property Damage Only (per crash) Source: National Safety Council (14) 3.7.2.2 Operational benefits Economic Cost (7997 dollars) $980,000 $34,100 $6,400 Quantify operational benefits The operational benefits of a project may be quantified in terms of the overall in terms of vehicle-hours reduction in person-hours of delay to the public. Delay has a cost to the public in of delay. terms of lost productivity, and thus a value of time can typically be assigned to changes in estimated delay to quantify benefits associated with delay reduction. The calculation of annual person-hours of delay can be performed with varying levels of detail, depending on the availability of data. For example, the vehicle-hours of delay may be computed as follows. The results should be converted to person-hours of delay using appropriate vehicle-occupancy factors (including tran- sit), then adding pedestrian delay if significant. ?4' I Federal HighwayAdministration • Estimate the delay per vehicle for each hour of the day. If turning move- ments are available for multiple hours, this estimate can be computed di- rectly. If only the peak hour is available, the delay for an off-peak hour can be approximated by proportioning the peak hour turning movements by total entering vehicles. Determine the daily vehicle-hours of delay by multiplying the estimated de- lay per vehicle for a given hour by the total entering vehicles during that hour and then aggregating the results over the entire day. If data is available, these calculations can be separated by day of week or by weekday, Satur- day, and Sunday. • Determine annual vehicle-hours of delay by multiplying the daily vehicle-hours of delay by 365. If separate values have been calculated by day of week, first determine the weekday vehicle-hours of delay and then multiply by 52.1 1365 divided by 7). It may be appropriate to use fewer than 365 days per year because the operational benefits will not usually apply equally on all days. 3.7.2.3 Environmenta/ benefits The environmental benefits of a project are most readily quantified in terms of reduced fuel consumption and improved air quality. Of these, reductions in fuel consumption and the benefits associated with those reductions are typically the simplest to determine. One way to determine fuel consumption is to use the same procedure for esti- mating delay, as described previously. Fuel consumption is an output of several of the models in use today, although the user is cautioned to ensure that the model is appropriately calibrated for current U.S. conditions. Alternatively, one can estimate fuel consumption by using the estimate of annual vehicle-hours of delay and then multiplying that by an assumed fuel consumption rate during idling, expressed as liters per hour (gallons per hour) of idling. The resulting estimate can then be converted to a cost by assuming an average cost of fuel, expressed in dollars per liter (dollars per gallonl. 3.7.3 Estimation of costs Costs for a public works project are generally comprised of two elements: capi- talized construction costs and operations and maintenance (O&M) costs. AI- though O&M costs are typically determined on an annualized basis, construc- tion costs are typically a near-term activity that must be annualized. The follow ing sections discuss these in more detail. 3.7.3.1 Construction costs Construction costs for each alternative should be calculated using normal pre- liminary engineering cost estimating techniques. These costs should include the costs of any necessary earthwork, paving, bridges and retaining walls, sign- ing and striping, illumination, and signalization. Roundabouts: An Informational Guide • 3: Planning `��g To convert construction costs into an annualized value for use in the benefit-cost analysis, a capital recovery factor (CRF) should be used, shown in Equation 3-2. This converts a present value cost into an annualized cost over a period of n years using an assumed discount rate of i percent. i(1 + i)^ CRF = i(1 + i)�– 1 where: i = discount rate n = number of periods (years) 3.7.3.2 Operation and maintenance (O&MJ costs (3-2) Operation and maintenance costs vary significantly between roundabouts and other Roundabout O&M costs are forms of intersection control beyond the basic elements. Common elements in- typically slightly higher than clude signing and pavement marking maintenance and power for illumination, if signalized intersections for: provided. • Illumination • Signing Roundabouts typically have a slightly higher illumination power and maintenance • Pavement marking costs compared to signalized or sign-controlled intersections due to a larger num- • Landscaping ber of illumination poles. Roundabouts have slightly higher signing and pavement marking maintenance costs due to a higher number of signs and pavement mark- ings. Roundabouts also introduce additionai cost associated with the maintenance of any landscaping in and around the roundabout. Signalized intersections have considerable additional cost associated with power Signalized intersections also have for the traffic signal and maintenance costs such as bulb replacement, detection O&M costs for: maintenance, etc. Power costs vary considerably from region to region and over • Signal power time and should be verified locally. For general purposes, an annual cost of $3,000 • Bulb replacement for providing power to a signalized intersection is a reasonable approximation. • Detection maintenance 3.8 References 1. Austroads. Guide toTratfic Engineering Practice, Part 6—Roundabouts. Sydney, Australia: Austroads, 1993. 2. Brilon, W., N. Wu, and L. Bondzio. "Unsignalized Intersections in Germany—A State of the Art 1997.' In Proceedings of the Third International Symposium on Intersections withoutTraffic Signals led: M. Kyte), Portland, Oregon, U.S.A. Uni- versity of Idaho, 1997. 3. Maycock, G., and R.D. Hall. Crashes at four-arm roundabouts.TRRL Laboratory Report LR 1120. Crowthorne, England: Transport and Road Research Labora- tory, 1984. 4. Vogt, A. Crash Models for Rura/ Intersections: 4-Lane by2-Lane Stop-Controlled and 2-Lane by 2-Lane Signalized. Washington, D.C.: Federal Highway Adminis- tration, 1999. 5. Bauer, K.M., and D.W. Harwood. Siatistical Models of Ai-Grade Intersection Crashes. Report No. FHWA-RD-99-094. Washington, D.C.: Federal HighwayAd- ministration, 1999. ��;, I Federal HighwayAdministration 6. Bared, J.G., and K. Kennedy. "Safety Impacts of Roundabouts;' Chapter 28, TheTraffic SafetyToolbox: A Primer onTraffic Safety, Institute ofTransportation Engineers, 2000. 7. Florida Department of Transportation. Florida Roundabout Guide. Florida De- partment of Transportation, March 1996. 8. Federal Highway Administration (FHWA). Manua/ on Uniform Traffic Control Devices. Washington, D.C.: FHWA, 1988. 9. Ak�elik, R., and M. Besley. SIDRA 5 User Guide. Melbourne, Australia: Austra- lian Road Research Board, January 1999. 10. Transportation Research Board. HighwayCapacityManual. Special Report209. Washington, D.C.:Transportation Research Board, National Research Council, July 1999 (draftl. 11. Institute of Transportation Engineers. TransportaTion Planning Handbook (J. Edwards, Jr., ed.). Englewood Cliffs, N.J.: Prentice Hall, 1992. 12. American Association of State Highway Officials (AASHO). A Policy on Design of Urban Highways and Arteria/ Streets. Washington, D.C.: AASHO, 1973. 13. American Association of State Highway &Transportation Officials (AASHTO). A Manua/ on User BenefitAna/ysis of Highway and Bus Transit Improvements. Washington, D.C.: AASHTO, 1977. 14. National Safety Council. Accident Facts, 1998 Edition. Roundabouts: An Informational Guide • 3: Planning I 77 4.1 4.2 4.3 4.4 4.5 4.6 Operation Traffic Operation at Roundabouts 4.1.1 Driver behavior and geometric elements 4.1.2 Concept of roundabout capacity Data Requirements Capacity 4.3.1 Single-lane roundabout capacity 4.3.2 Double-lane roundabout capacity 4.3.3 Capacity effect of short lanes at flared entries 4.3.4 Comparison of single-lane and double-lane roundabouts 4.3.5 Pedestrian effects on entry capacity 4.3.6 Exit capacity Performance Analysis 4.4.1 Degree of saturation 4.4.2 Delay 4.4.3 Queue length 4.4.4 Field observations Computer Software for Roundabouts References Exhibit 4-1. Conversion factors for passenger car equivalents (pce) Exhibit 4-2. Traffic flow parameters. Exhibit 4-3. Approach capacity of a single-lane roundabout. Exhibit 4-4. Approach capacity of a double-lane roundabout. 82 82 83 83 86 86 88 88 89 90 91 91 92 92 94 96 96 98 84 85 87 88 Exhibit 4-5. Capacity reduction factors for short lanes. 89 Exhibit 4-6. Capacity comparison of single-lane and double-lane roundabouts. 89 Exhibit 4-7. Capacity reduction factor M for a single-lane roundabout assuming pedestrian priority. 90 Exhibit 4-8. Capacity reduction factor M for a double-lane roundabout assuming pedestrian priority. 91 Exhibit 4-9. Control delay as a function of capacity and entering flow. 93 Exhibit 4-10. 95th-percentile queue length estimation. 95 Exhibit 4-11. Summary of roundabout software products for operational analysis. 97 �g',; I Federal Highway Administration Chapter 4 Operation This chapter presents methods for analyzing the operation of an existing or planned roundabout.The methods allow a transportation analyst to assess the operational performance of a facility, given information about the usage of the facility and its geometric design elements. An operational analysis produces two kinds of esti- mates: (1) the capacity of a facility, i.e., the ability of the facility to accommodate various streams of users, and (2) the level of performance, often measured in terms of one or more measures of effectiveness, such as delay and queues. The Highway Capacity Manual (1) (HCM) defines the capacity of a facility as "the maximum hourly rate at which persons or vehicles can reasonably be expected to traverse a point or uniform section of a lane or roadway during a given time period under prevailing roadway, traffic, and control conditions" While capacity is a spe- cific measure that can be defined and estimated, level of service (LOS) is a qualita- tive measure that "characterizes operational conditions within a traffic stream and their perception by motorists and passengers:' To quantify level of service, the HCM defines specific measures of effectiveness for each highway facility type. Control delay is the measure of effectiveness that is used to define level of service at intersections, as perceived by users. In addition to control delay, all intersections cause some drivers to also incur geometric delays when making turns. A systems analysis of a roadway network may include geometric delay because of the slower vehicle paths required for turning through intersections. An example speed profile is shown in Chapter 6 to demonstrate the speed reduction that results from geo- metric delay at a roundabout. While an operational analysis can be used to evaluate the performance of an exist- ing roundabout during a base or future year, its more common function in the U.S. may be to evaluate new roundabout designs. This chapter: • Describes traffic operations at roundabouts; • Lists the data required to evaluate the performance of a roundabout; • Presents a method to estimate the capacity of five of the six basic round- about configurations presented in this guide; � Describes the measures of effectiveness used to determine the performance of a roundabout and a method to estimate these measures; and • Briefly describes the computer software packages available to implement the capacity and performance analysis procedures. Appendix A provides background information on the various capacity relationships. Roundabouts produce both control delay and geometric delay. Roundabouts: An Informational Guide • 4: Operation I�� ' Approach speed is governed by: • Approach roadway width • Roadway curvature • Approach volume 4.7 Traffic Operation at Roundabouts 4.7.1 Driver behavior and geometric elements A roundabout brings together conflicting traffic streams, allows the streams to safely merge and traverse the roundabout, and exit the streams to their desired directions.The geometric elements of the roundabout provide guidance to drivers approaching, entering, and traveling through a roundabout. Drivers approaching a roundabout must slow to a speed that will allow them to safely interact with other users of the roundabout, and to negotiate the round- about. The width of the approach roadway, the curvature of the roadway, and the volume of traffic present on the approach govern this speed. As drivers approach the yield line, they must check for conflicting vehicles already on the circulating roadway and determine when it is safe and prudent to enter the circulating stream. The widths of the approach roadway and entry determine the number of vehicle streams that may form side by side at the yield line and govern the rate at which vehicles may enter the circulating roadway. The size of the inscribed circle affects the radius of the driver's path, which in turn determines the speed at which drivers travel on the roundabout. The width of the circulatory roadway determines the number of vehicles that may travel side by side on the roundabout. The British (2), French (31, and German (4) analytical procedures are based on em- pirical relationships that directly relate capacity to both traffic characteristics and roundabout geometry.The British empirical relationships reveal that small sublane changes in the geometric parameters produce significant changes in capacity. For instance, if some approaches are flared or have additional short lanes, these provide considerably more capacity for two reasons. First, wider entries require wider circulatory roadway widths. This provides for more opportunities for the cir- culatory traffic to bunch together, thus increasing the number of acceptable oppor- tunities to enter, thereby increasing capacity. Second, the typical size of groups of drivers entering into acceptable opportunities in the circulatory traffic is quite small, so short lanes can be very effective in increasing group sizes, because the short lane is frequently able to be filled. The British (2) use the inscribed circle diameter, the entry width, the approach (road) half width, the entry radius, and the sharpness of the flare to define the performance of a roundabout. The sharpness of the flare, S, is a measure of the rate at which the extra width is developed in the entry flare. Large values of 5 correspond to short, severe flares, and small values of Scorrespond to long, gradual flares (51. Geometric elements that affect The results of the extensive empirical British research indicate that approach half entry capacity include: width, entry width, average effective flare length and entry angle have the most • Approach half width significant effect on entry capacity. Roundabouts fit into two general classes: those • Entry width with a small inscribed circle diameter of less than 50 m(165 ft.) and those with a • Entry angle diameter above 50 m.The British relationships provide a means of including both of • Average effective flare these roundabout types. The inscribed circle diameter has a relatively small effect length for inscribed diameters of 50 m(165 ft) or less. The entry radius has little effect on capacity provided that it is 20 m(65 ft) or more.The use of perpendicular entries (70 ��" Federal HighwayAdministration �� I degrees or more) and small entry radii (less than 15 m[50 ft]) will reduce capacity. The presence of the geometric parameters in the British and French models allow designers to manipulate elements of their design to determine both their opera- tional and safety effects. German research has not been able to find the same influence of geometry, although this may be due to the relatively narrow range of geometries in Germany (4). Thus, the geometric elements of a roundabout, together with the volume of traffic desiring to use a roundabout at a given time, may determine the efficiency with which a roundabout operates. 4.1.2 Concept of roundabout capacity The capacity of each entry to a roundabout is the maximum rate at which vehicles can reasonably be expected to enter the roundabout from an approach during a given time period under prevailing traffic and roadway (geometric) conditions. An operational analysis considers a precise set of geometric conditions and traffic flow rates defined for a 15-minute analysis period for each roundabout entry. While con- sideration of Average Annual DailyTraffic volumes (AADT) across all approaches is useful for planning purposes as provided in Exhibit 1-13 and Chapter 3, analysis of this shorter time period is critical to assessing the level of performance of the roundabout and its individual components. The capacity of the entire roundabout is not considered, as it depends on many terms. However, Exhibit 1-13 provides threshold average daily traffic volumes for the various categories of roundabouts, assuming four legs. Below these thresh- olds, a four-legged roundabout with roadways intersecting perpendicularly should have adequate capacity (provided the traffic volumes are reasonably balanced and the geometry does not deviate substantially from those shown on the design tem- plates in Exhibits 1-7 through 1-12). The focus in this chapter on the roundabout entry is similar to the operational analysis methods used for other forms of unsignalized intersections and for signalized intersections. In each case, the capac- ity of the entry or approach is computed as a function of traffic on the other (con- flicting) approaches, the interaction of these traffic streams, and the intersection geometry. For a properly designed roundabout, the yield line is the relevant point for capacity analysis. The approach capacity is the capacity provided at the yield line. This is determined by a number of geometric parameters in addition to the entry width. On multilane roundabouts it is important to balance the use of each lane, because otherwise some lanes may be overloaded while others are underused. Poorly de- signed exits may influence driver behavior and cause lane imbalance and conges- tion at the opposite leg. 4.2 Data Requirements The analysis method described in this chapter requires the specification of traffic volumes for each approach to the roundabout, including the flow rate for each di- rectional movement. Volumes are typically expressed in passenger car vehicles per hour (vph), for a specified 15-minute analysis period. To convert other vehicle types to passenger car equivalents (pce), use the conversion factors given in Exhibit 4-1. Roundabouts: An Informational Guide • 4: Operation Perpendicular entries and small entry radii reduce capacity; inscribed circle diameters of 50 m(165 ft) or less have little effect on capacity. Roundabout capacity defined. Operational analyses consider 75-minute volumes, as opposed to the daily volumes used in planning analyses. The approach capacity is the capacity provided at the yield line. Different size vehicles have different capacity impacts; passenger cars are used as the basis for comparison. $3. I Exhibit 4-7. Conversion factors forpassengercarequivalents (pce1. Passenger Car VehicleType Equivalent (pce) Car 1.0 Single-unit truck or bus 1.5 Truck with trailer 2.0 Bicycle or motorcycle 0.5 Source: 16), (7) Traffic volume data for an urban roundabout should be collected for each directional movement for at least the morning and evening peak periods, since the various movements, and thus approach and circulating volumes, may peak at different times. At rural roundabouts, the analyst should check the requirements of the agency with the jurisdiction of the site.The reader is referred to the Manual ofTransporta- tion Engineering Studies (8) for a complete discussion of traffic volume data collec- tion methods. Typically, intersection volume counts are made at the intersection stop bar, with an observer noting the number of cars that pass that point over a specified time period. However, particularly with respect to cases in which de- mand exceeds capacity (when queues do not dissipate within the analysis period), it is important to note that the stop bar counts reflect only the volume that is served, not the demand volume. In this case, care must be taken to collect data upstream of the end of a queue so that true demand volumes are available for analysis. Entry flow and circulating flow The relationship between the standard origin-to-destination turning movements at for each approach are the an intersection and the circulating and entry flows at a roundabout is important, yet volumes of interest for is often complicated to compute, particularly if an intersection has more than four roundabout capacity analysis, approaches. For conventional intersctions, traffic flow data are accumulated by di- rather than turning rectional turning movement, such as for the northbound left turn. For roundabouts, movement volumes. however, the data of interest for each approach are the entry flow and the circulat- ing flow. Entry flow is simply the sum of the through, left, and right turn move- ments on an approach. Circulating flow is the sum of the vehicles from different movements passing in front of the adjacent uptstream splitter island. At existing roundabouts, these flows can simply be measured in the field. Right turns are included in approach volumes and require capacity, but are not included in the circulating volumes downstream because they exit before the next entrance. Determining circulating volumes as a function of turning movement volumes. For proposed or planned four-legged roundabouts, Equations 4-1 through 4-4 can be applied to determine conflicting (circulating) flow rates, as shown graphically in Exhibit 4-2. VEB,circ VWB,LT + VSB,LT + V SB,TH + VNB,U-Nrn + VWB,U-turn + VSB,U-tum VWB,circ VEB,L7+ VNB,L7+ VNB,TH+ VSB,U-tum + VEB,U-Nm + VNB,U-tum VNB,circ VE@,LT + VEB,TH + VSB,LT + VWB,U-Nrn + VSB,U-turn + VEB,U-turn VSB,circ VWB,LT+ VWB,TH+ VNB,L7+ VEB,U-tum+ VNB,U-Nm + VWB,U-Nrn (4-1) (4-2) (4-3) (4-4) ��!;; I Federal Highway Administration �HF- � 7 mmm m yt� V1 N .�j�.J s G��G ��'�9 � NORTH � �� c � � WB,RT �� WB,TH EB,U� � WB,UT EB,L T� EB,TH �♦ EB,RT � tie G��G %c � 1 ��e� rm �� Z mmm =ZZ For existing roundabouts, when approach, right-turn, circulating, and exit flows are counted, directional turning movements can be computed as shown in the follow- ing example. Equation 4-5 shows the through movement flow rate for the east- bound approach as a function of the entry flow rate for that approach, the exit flow rate for the opposing approach, the right turn flow rate for the subject approach, the right turn flow rate for the approach on the right, and the circulating flow rate for the approach on the right. Other through movement flow rates can be esti- mated using a similar relationship. VEB,TH VEB,entry + VWB,exit - VEB,RT - VNB,RT - VNB,circ (4-5) The left turn flow rate for an approach is a function of the entry flow rate, the through flow rate, and the right turn flow rate for that same approach, as shown in Equation 4-6. Again, other movements' flows are estimated using similar equa- tions. VEB,LT VEB,entry - VEB,TH - VEB,R7 (4-6) While this method is mathematically correct, it is somewhat sensitive to errors and inconsistencies in the input data. It is important that the counts at all of the loca- tions in the roundabout be made simultaneously. Inconsistencies in the data from counts taken on different days can produce meaningless results, including nega- tive volumes. At a minimum, the sum of the entering and exiting volumes should be checked and adjustments should be made if necessary to ensure that the same amount of traffic enters and leaves the roundabout. Exhibit 4-2. Traffic flow parameters. ;�.�. Roundabouts: An Informational Guide • 4: Operation � '�, Roundabout approach capacity is dependent on the conflicting circulating flow and the roundabout's geometric 4.3 Capacity The maximum flow rate that can be accommodated at a roundabout entry de- pends on two factors: the circulating flow on the roundabout that conflicts with the entry flow, and the geometric elements of the roundabout. elements. When the circulating flow is low, drivers at the entry are able to enter the round- about without significant delay. The larger gaps in the circulating flow are more useful to the entering drivers and more than one vehicle may enter each gap. As the circulating flow increases, the size of the gaps in the circulating flow decrease, and the rate at which vehicles can enter also decreases. Note that when comput- ing the capacity of a particular leg, the actual circulating flow to use may be less than demand flows, if the entry capacity of one leg contributing to the circulating flow is less than demand on that leg. Roundabouts should be The geometric elements of the roundabout also affect the rate of entry flow. The designed to operate at no more most important geometric element is the width of the entry and circulatory road- than 85 percent of their ways, or the number of lanes at the entry and on the roundabout. Two entry lanes estimated capacity. Beyond this permit nearly twice the rate of entry flow as does one lane. Wider circulatory road- threshold, delays and queues ways allow vehicles to travel alongside, or follow, each other in tighter bunches and vary significantly from their so provide longer gaps between bunches of vehicles. The flare length also affects mean values. the capacity. The inscribed circle diameter and the entry angle have minor effects on capacity. As at other forms of unsignalized intersection, when traffic flows on an approach exceed approximately 85 percent of capacity, delays and queue lengths vary sig- nificantly about their mean values (with standard deviations of similar magnitude as the means). For this reason, the analysis procedures in some countries (Austra- lia, Germany, and the United Kingdom), and this guide, recommend that round- abouts be designed to operate at no more than 85 percent of their estimated ca- pacity. As performance data become available for roundabouts designed according to the procedures in this guide in the United States, they will provide a basis for develop- ment of operational performance procedures specifically calibrated for U.S. condi- tions. Therefore, analysts should consult future editions of the Highway Capacity Manual. 4.3.1 Single-lane roundabout capacity Exhibit 4-3 shows the expected capacity for a single-lane roundabout for both the urban compact and urban/rural single-lane designs.The exhibit shows the variation of maximum entry flow as a function of the circulating flow on the roundabout.The calculation of the circulating flow was described previously. The capacity forecast shown in the chart is valid for single-lane roundabouts with inscribed circle diam- eters of 25 m to 55 m(80 ft to 180 ft).The capacity forecast is based on simplified British regression relationships in Appendix A, which may also be derived with a gap-acceptance model by incorporating limited priority behavior. � I Federal Highway Administration Note that in any case, the flow rate downstream of the merge point (between the entry and the next exit) should not be allowed to exceed 1,800 veh/h. Exceeding this threshold may indicate the need for a double-lane entry. The urban compact design is expected to have a reduced capacity, but has signifi- cant benefits of reduced vehicle speeds through the roundabout (per the German equations in Appendix A). This increases safety for pedestrians and bicyclists com- pared with the larger single lane roundabouts. Mini-roundabout capacities may be approximated using the daily maximum service volumes provided for them in Chap- ter 3, but in any case should not exceed the capacity of the urban compact design. Circulating flow should not exceed 1,800 veh/h at any point in a single-lane roundabout. Exit flows exceeding 1,200 veh/h may indicate the need for a double-lane exit. Exhibit 4-3. Approach capacity of a single-lane roundabout. The slope of the upper line changes because circulating flow downstream from a roundabout entry should not exceed 1,800 veh/h. Roundabouts: An Informational Guide • 4: Operation I g� Exhibit 4-4. Approach capacity of a double-lane roundabout. When flared approaches are used, the circulatory road width must be widened. See Appendix A for further information on the effects of short lanes at flared entries. 4.3.2 Double-lane roundabout capacity Exhibit 4-4 shows the expected capacity of a double-lane roundabout that is based on the design templates for the urban/rural double-lane roundabouts. The capacity forecast shown in the chart is valid for double-lane roundabouts with inscribed circle diameters of 40 m to 60 m(130 ft to 200 ft).The capacity forecast is based on simplified British regression relationships in Appendix A, which may also be de- rived with a gap-acceptance model by incorporating limited priority behavior. Larger inscribed diameter roundabouts are expected to have slightly higher capacities at moderate to high circulating flows. 2800 zaoo t L 2��0 N > 3 o �soo LL � Ly �2�0 � E soo 'x m � 400 . � 0 400 800 1200 1600 2000 2400 2800 3200 3600 Circulatory Flow (veh/h) 4.3.3 Capacity effect of short lanes at flared entries By flaring an approach, short lanes may be added at the entry to improve the perfor- mance. If an additional short lane is used, it is assumed that the circulatory road width is also increased accordingly. The capacity of the entry is based on the as- sumption that all entry lanes will be effectively used. The capacity is given by the product of the appropriate factor in Exhibit 4-5 and the capacity of a two-lane round- about in Exhibit 4-4. Refer to Appendix A for a derivation of these factors (9). Federal Highway Administration Exhibit 4-5. Capacity reduction Number of vehicle spaces in Factor (applied to double-lane factors for short lanes. the short lane, n� approach capacity) 0* 1 2 4 6 8 10 0.500 0.707 0.794 0.871 0.906 0.926 0.939 *Used for the case of a single lane entry to a double-lane roundabout. 4.3.4 Comparison of single-lane and double-lane roundabouts Exhibit 4-6 shows a comparison of the expected capacity for both the single-lane and double-lane roundabouts. Again, it is evident that the number of lanes, or the size of the entry and circulating roadways, has a significant effect on the entry capacity. The use of short lanes can nearly double approach capacity, without requiring a two-lane roadway prior to the roundabout. Exhibit 4-6. Capacity comparison of single-lane and double-lane roundabouts. Roundabouts: An Informational Guide • 4: Operation I 89 Exhibit 4-7. Capacity reduction factor M for a single-lane roundabout assuming pedestrian priority. The effects of conflicting pedestrians on approach capacity decrease as conflicting vehicular volumes increase, as entering vehicles become more likely to have to stop regardless of whether pedestrians are present. 4.3.5 Pedestrian effects on entry capacity Pedestrians crossing at a marked crosswalk that gives them priority over entering motor vehicles can have a significant effect on the entry capacity. In such cases, if the pedestrian crossing volume and circulating volume are known, the vehicular capacity should be factored (multiply by 11� according to the relationship shown in Exhibit 4-7 or Exhibit 4-8 for single-lane and double-lane roundabouts, respectively. Note that the pedestrian impedance decreases as the conflicting vehicle flow in- creases.The Highway Capacity Manual (1) provides additional guidance on the ca- pacity of pedestrian crossings and should be consulted if the capacity of the cross- walk itself is an issue. Reduction factor M [-] 1.00 0.95 0.90 0.85 0.80 0.75 0.70 so��e: ��o� 0 100 200 300 400 500 600 700 800 900 circular flow rate qk [pcu/h] 90 I Federal Highway Administration �� Reduction factor M [-] 1.00 0.95 10 0.90 0.85 0.80 0.75 I n �n p 200 400 600 800 1000 1200 �4uu circular flow rate qk [pc�] so��e ��o� 4.3.6 Exit capacity An exit flow on a single lane of more than 1,400 veh/h, even under good operating conditions for vehicles (i.e., tangential alignment, and no pedestrians and bicyclists) is difficult to achieve. Under normal urban conditions, the exit lane capacity is in the range of 1,200 to 1,300 veh/h. Therefore, exit flows exceeding 1,200 veh/h may indicate the need for a double-lane exit (11). 4.4 Performance Analysis Three performance measures are typically used to estimate the performance of a given roundabout design: degree of saturation, delay, and queue length. Each mea- sure provides a unique perspective on the quality of service at which a roundabout will perform under a given set of traffic and geometric conditions. Whenever pos- sible, the analyst should estimate as many of these parameters as possible to obtain the broadest possible evaluation of the performance of a given roundabout design. In all cases, a capacity estimate must be obtained for an entry to the round- about before a specific performance measure can be computed. Roundabouts: An Informational Guide • 4: Operation Exhibit M8. Capacity reduction factor M for a double-lane roundabout assuming pedestrian priority. Key performance measures for roundabouts: • Degree of saturation • Delay • Queue length 91 4.4.1 Degree of saturation Degree of saturation is the ratio of the demand at the roundabout entry to the capacity of the entry. It provides a direct assessment of the sufficiency of a given design. While there are no absolute standards for degree of saturation, the Austra- lian design procedure suggests that the degree of saturation for an entry lane should be less than 0.85 for satisfactory operation. When the degree of saturation ex- ceeds this range, the operation of the roundabout will likely deteriorate rapidly, particularly over short periods of time. Queues may form and delay begins to in- crease exponentially. 4.4.2 Delay Delay is a standard parair�eter used to measure the performance of an intersec tion. The Highway Capacity Manual (1) identifies delay as the primary measure of effectiveness for both signalized and unsignalized intersections, with level of ser- vice determined from the delay estimate. Currently, however, the Highway Capac- ity Manua/ only includes control delay, the delay attributable to the control device. Control delay is the time that a driver spends queuing and then waiting for an acceptable gap in the circulating flow while at the front of the queue. The formula for computing this delay is given in Equation 4-7 (12, based on 13; see also 14). Exhibit 4-9 shows how control delay at an entry varies with entry capacity and circulating flow. Each curve for control delay ends at a volume-to-capacity ratio of 1.0, with the curve projected beyond that point as a dashed line. d_ 3600 + 900T x �X - 1+ Cm,X Cm,x 3600 vX z VX — 1 + Cm,x Cm,x �,,,,X 450T where: d= average control delay, sec/veh; vx = flow rate for movement x, veh/h; cm, = capacity of movement x, veh/h; and T= analysis time period, h(T= 0.25 for a 15-minute period). (4-7) s2 Federal Highway Administration so 50 �„ 40 L d > v y 30 T tC p 20 10 0 400 800 1200 1600 2000 2400 Capacity Entering flow (veh/h) — 400 veh/h -- 800 veh/h — 1200 veh/h °-°° 1600 veh/h --°° 2000 veh/h -^�^ 2400 veh/h Note that as volumes approach capacity, control delay increases exponentially, with small changes in volume having large effects on delay. An accurate analysis of delay under conditions near or over saturation requires consideration of the follow- ing factors: • The effect of residual queues. Roundabout entries operating near or over capac- ity can generate significant residual queues that must be accounted for be- tween consecutive time periods. The method presented above does not ac- count for these residual queues. These factors are accounted for in the delay formulae developed by Kimber and Hollis (151; however, these formulae are difficult to use manually. • The metering etfect of upstream oversaturated entries. When an upstream en- try is operating over capacity, the circulating volume in front of a downstream entry is less than the true demand. As a result, the capacity of the downstream entry is higher than what wou�d be predicted from analyzing actual demand. For most design applications where target degrees of saturation are no more than 0.85, the procedures presented in this section are sufficient. In cases where it is desired to more accurately estimate performance in conditions near or over capac- ity, the use of software that accounts for the above factors is recommended. Geometric delay is the additional time that a single vehicle with no conflicting flows spends slowing down to the negotiation speed, proceeding through the in- tersection, and accelerating back to normal operating speed. Geometric delay may Exhibit 4-9. Control delay as a function of capacity and entering flow. Roundabouts: An Informational Guide • 4: Operation I 93 be an important consideration in network planning (possibly affecting route travel times and choices) or when comparing operations of alternative intersection types. While geometric delay is often negligible for through movements at a signalized or stop-controlled intersection, it can be more significant for turning movements such as those through a roundabout. Calculation of geometric delay requires an esti- mate of the proportion of vehicles that must stop at the yield line, as well as knowl- edge of the roundabout geometry as it affects vehicle speeds during entry, nego- tiation, and exit. Procedures for calculating the number of stops and geometric delay are given in the Australian design guide (16). 4.4.3 Qusue length Queue length is important when assessing the adequacy of the geometric design of the roundabout approaches. The average queue length (L vehicles) can be calculated by Little's rule, as shown in Equation 4-8 (17): L = v • d / 3600 where: v= entry flow, veh/h d = average delay, seconds/veh '� : Average queue length is equivalent to the vehicle-hours of delay per hour on an approach. It is useful for comparing roundabout performance with other intersec- tion forms, and other planning procedures that use intersection delay as an input. For design purposes, Exhibit 4-10 shows how the 95th-percentile queue length varies with the degree of saturation of an approach (18, 19).The xaxis of the graph is the degree of saturation, or the ratio of the entry flow to the entry capacity. Individual lines are shown for the product ofT and entry capacity.To determine the 95th-percentile queue length during time T enter the graph at the computed de- gree of saturation. Move vertically until the computed curve line is reached. Then move horizontally to the left to determine the 95th-percentile queue length. Alter- natively, Equation 4-8 can be used to approximate the 95th-percentile queue. Note that the graph and equation are only valid where the volume-to-capacity ratio im- mediately before and immediately after the study period is no greater than 0.85 (in other words, the residual queues are negligible). 94 Federal HighwayAdministration 14-9) z C6001 rC X 1 Q95 = 900T � X-1 + 1- c X)+ m 150T m X ( 3600) m,x m,x where: Q95= 95th percentile queue, veh, v= flow rate for movement x, veh/h, cmX= capacity of movement x, veh/h, and T= analysis time period, h(0.25 for 15-minute period). Source: (19) Exhibit 410. 95th-percentile queue length estimation. Roundabouts:An Informational Guide • 4: Operation I'�, Points to consider for a qualitative assessment of roundabout performance. 4.4.4 Field observations The analyst may evaluate an existing roundabout to determine its performance and whether changes to its design are needed. Measurements of vehicle delay and queuing can be made using standard traffic engineering techniques. In addition, the analyst can perform a qualitative assessment of the roundabout performance. The following list indicates conditions for which corrective design measures should be taken (20). If the answers to these questions are negative, no corrective actions need be taken. • Do drivers stop unnecessarily at the yield point? • Do drivers stop unnecessarily within the circulating roadway? � Do any vehicles pass on the wrong side of the central island? • Do queues from an external bottleneck back up into the roundabout from an exit road? • Does the actual number of entry lanes differ from those intended by the de- sign? • Do smaller vehicles encroach on the truck apron? • Is there evidence of damage to any of the signs in the roundabout? • Is there any pedestrian activity on the central island? • Do pedestrians and cyclists fail to use the roundabout as intended? • Are there tire marks on any of the curb surfaces to indicate vehicle contact? • Is there any evidence of minor accidents, such as broken glass, pieces of rim, etc., on the approaches or the circulating roadway? • Is there any gravel or other debris collected in nontraveled areas that could be a hazard to bicycles or motorcyclists? • Are the vehicle speeds appropriate? 4.5 Computer Software for Roundabouts While the analytical procedures of different countries are not very complex, they are repetitive and time consuming, so most of these procedures have been imple- mented in software. A summary of current (as of 1999) software products and the analytical procedures that they implement is presented in Exhibit 4-11.The reader is also advised to consult the latest version of the U.S. Highway Capacity Manual. While the procedures provided in this chapter are recommended for most applica- tions covered by this guide, models such as ARCADY, RODEL, SIDRA, KREISEL, or GIRABASE may be consulted to determine the effects of geometric parameters, particularly for multilane roundabouts outside the realm of this guide, or for fine- tuning designs to improve performance. Note that many of these models repre- sent different underlying data or theories and will thus produce different results. Chapter 8 provides some information on microscopic simulation modeling which may be useful alternatives analysis in systems context. Federal Highway Administration Name Scope Application and nualities (7999 versions) ARCADY All configurations British method (50 percent confidence limits). Capacity, delay, and queuing. Includes projected number of crashes per year. Data were collected at extensive field studies and from experiments involving drivers at temporary roundabouts. Empirical relationships were de- veloped from the data and incorporated into ARCADY. This model reflects British driving behavior and British roundabout designs. A prime attribute is that the capacities it predicts have been measured. RODEL All configurations British method (user-specified confidence limits). Capacity, delay, and including multiple queuing. Includes both an evaluation mode (geometric parameters roundabout specified) and a design mode (performance targets specifiedl. Includes interactions a crash prediction model. RODEL uses the British empirical equa- tions. It also assists the user in developing an appropriate roundabout for the traffic conditions. SIDRA HCS-3 KREISEL All configurations Australian method, with analytical extensions. Capacity, delay, queue, and other control fuel, and environmental measures. Also evaluates two-way stop-con- types trolled, all-way stop controlled, and signalized intersections. It also gives roundabout capacities from U.S. HCM 1997 and German pro- cedures. SIDRA is based on gap acceptance processes. It uses field data for the gap acceptance parameters to calibrate the model.There has been limited field evaluation of the results although experience has shown that the results fitAustralian and U.S. single-lane (21) round- about conditions satisfactorily. An important attribute is that the user can alter parameters to easily reflect local driving. Single-lane U.S. HCM 1997 method. Limited to capacity estimation based on roundabouts entering and circulating volume. Optional gap acceptance parameter with a limited values provide both a liberal and conservative estimate of capacity. range of The data used to calibrate the models were recorded in the U.S. The volumes two curves given reflect the uncertainty from the results. The upper- bound average capacities are anticipated at most roundabouts. The lower bound results reflect the operation that might be expected until roundabouts become more common. All configurations Developed in Germany. Offers many user-specified options to imple- ment the full range of procedures found in the literature from U.S. (including this chapter), Europe, Britain, and Australia. KREISEL gives the average capacity from a number of different procedures. It pro- vides a means to compare these procedures. GIRABASE All configurations French method. Capacity, delay, and queuing projections based on regression. Sensitive to geometric parameters. Gives average val- ues. Roundabouts: An Informational Guide • 4: Operation Exhibit 4-11. Summary of roundabout software products for operational analysis. 4.6 References 1. Transportation Research Board. HighwayCapacityManual. Special Report209. Washington, D.C.:Transportation Research Board, National Research Council, July 1999 (draft). 2. Kimber, R.M. The traffic capacity of roundabouts.TRRL Laboratory Report LR 942. Crowthorne, England:Transport and Road Research Laboratory, 1980. 3. Guichet, B. "Roundabouts In France: Development, Safety, Design, and Ca- pacity:' in Proceedings of iheThird International Symposium on Iniersections WithoutTraffic Signals (M. Kyte, ed.), Portland, Oregon, U.S.A. University of Idaho, 1997. 4. Brilon, W., N. Wu, and L. Bondzio. "Unsignalized Intersections in Germany- A State of the Art 1997.' In Proceedings of theThird International Symposium on Intersections withoutTraffic Signa/s (ed: M. Kyte), Portland, Oregon, U.S.A. University of Idaho, 1997. 5. Ourston & Doctors, Inc. Roundabout Design Guidelines. 1995. 6. Jessen, G.D. Ein Richtlinienvorschlag fur die Behandlung der Leistungsfahigkeit von KnotenpunkTen ohne Signalregelung (A guideline suggested for capacity calculations for unsignalized intersections). Strassenverkehrstechnik, Nr. 7/8, 1968. 7. Harders, J. Grenz- und Folgezeitlucken als Grundlage fur die Berechnung der Leistungsfahigkeit von Landstrassen (Critical gaps and follow up times or ca- pacity calculations at rural roads). Schriftenreihe Strassenbau und Strassenverkehrstechnik, Vol. 216, 1976. 8. Institute of Transportation Engineers. Manual of Transportation Engineering Studies (H.D. Robertson, J.E. Hummer, and D.C. Nelson, ed.). Englewood Cliffs, N.J.: Prentice-Hall, 1994. 9. Wu, N. "Capacity of Shared/Short Lanes at Unsignalized Intersections" In Proceedings of the Third International Symposium on Intersections without Traffic Signals (ed: M. Kyte), Portland, Oregon, U.S.A. University of Idaho, 1997. 10. Brilon, W., B. Stuwe, and 0. Drews. Sicherheit und Leistungsfahigkeit von Kreisverkehrsplatzen (Safety and Capacity of Roundabouts). Research Report. Ruhr-University Bochum, 1993. 11. Brilon, W. Letter to Principal Investigator. September 18, 1999. 12. Transportation Research Board. HighwayCapacityManual. Special Report209. Washington, D.C.:Transportation Research Board, National Research Council, 1994. 13. Ak�elic, R., and R.J.Troutbeck. "Implementation of the Australian roundabout analysis method in SIDRA:' In Highway Capacity and Level of Service: Pro- ceedings of the International Symposium on Highway Capacity (U. Brannolte, ed.l, Karlsruhe, Germany. Rotterdam, Germany: Balkema Publisher, 1991, pp. 17-34. � I Federal Highway Administration 14. Transportation Research Board. Review of International Practices Used to Evaluate Unsignalized Intersections. Transportation Research Circular 468. Washington, D.C.:Transportation Research Board, National Research Council, April 1997. 15. Kimber, R.M. and E.M. Hollis. Trafficqueuesanddelaysatroadjunctions.TRRL Laboratory Report LR 909. Crowthorne, England:Transport and Road Research Laboratory, 1979. 16. Austroads. Guide toTraffic Engineering Practice, Part 6—Roundabouts. Sydney, Australia: Austroads, 1993. 17. Little, J.D.C. A Proof of the Queueing Formula L= W��,. Operations Research 9, S. 383-387, 1961. 18. Heidemann, D. "Queue lengths and waiting-time distributions at priority inter- sections" In Transportation Research 8, Vol 25B, (4) pp. 163-174, 1991. 19. Wu, N. 'An Approximation for the Distribution of Queue Lengths at Unsignalized Intersections" In Proceedings of the Second International Symposium on High- wayCapacityled. R. Ak�elik), Sydney, Australia. Australian Road Research Board, 1994. 20. Florida Department of Transportation. Florida Roundabout Guide. Florida De- partment of Transportation, March 1996. 21. Flannery, A., L. Elefteriadou, P. Koza, and J. McFadden. "Safety, delay and capacity of single-lane roundabouts in the United States:' In Transportation Research Record 1646. Washington, D.C.:Transportation Research Board, Na- tional Research Council, 1998, pp. 63-70. Roundabouts: An Informational Guide • 4: Operation I� i Safety 5.1 Introduction 5.2 Conflicts 5.2.1 Vehicle conflicts 5.2.2 Pedestrian conflicts 5.2.3 Bicycle conflicts 5.3 Crash Statistics 5.3.1 Comparisons to previous intersection treatment 5.3.2 Collision types 5.3.3 Pedestrians 5.3.4 Bicyclists 5.4 Crash Prediction Models 5.5 References Exhibit 5-1. Vehicle conflict points for "T" Intersections with single-lane approaches. Exhibit 5-2. Vehicle conflict point comparison for intersections with single-lane approaches. Exhibit 5-3. Improper lane-use conflicts in double-lane roundabouts. Exhibit 5-4. Improper turn conflicts in double-lane roundabouts. Exhibit 5-5. Vehicle-pedestrian conflicts at signalized intersections. Exhibit 5-6. Vehicle-pedestrian conflicts at single-lane roundabouts. Exhibit 5-7. Bicycle conflicts at conventional intersections (showing two left-turn options). 103 104 105 108 110 111 111 113 117 120 122 125 105 106 107 108 109 109 � Exhibit 5-8. Exhibit 5-9. Exhibit 5-10. Exhibit 5-71. Exhibit 5-12. Exhibit 5-13. Exhibit 5-14. Exhibit 5-15. Exhibit 5-16. Exhibit 5-17. Exhibit 5-18. Bicycle conflicts at roundabouts. Average annual crash frequencies at 11 U.S. intersections converted to roundabouts. Mean crash reductions in various countries. Reported proportions of major crash types at roundabouts. Comparison of collision types at roundabouts. Graphical depiction of collision types at roundabouts. Crash percentage per type of user for urban roundabouts in 15 towns in western France. British crash rates for pedestrians at roundabouts and signalized intersections. Percentage reduction in the number of crashes by mode at 181 converted Dutch roundabouts. British crash rates (crashes per million trips) for bicyclists and motorcyclists at roundabouts and signalized intersections. A comparison of crashes between signalized and roundabout intersections in 1998 in 15 French towns. 0 111 112 112 113 114 115 116 117 117 120 120 ��. I Federal HighwayAdministration Chapter 5 Safety Roundabouts may improve the safety of intersections by eliminating or altering con- flict types, by reducing speed differentials at intersections, and by forcing drivers to decrease speeds as they proceed into and through the intersection. Though round- about crash records in the United States are limited, the experiences of other coun- tries can be used to help design roundabouts in this country. Understanding the sensitivity of geometric element parameters, along with the crash experience, will assist the designer in optimizing the safety of all vehicle occupants, pedestrians, and bicyclists. 5.1 Introduction Many studies have found that one of the benefits of roundabout installation is the improvement in overall safety performance. Several studies in the U.S., Europe, and Australia have found that roundabouts perform better in terms of safety than other intersection forms (1, 2, 3, 4). In particular, single-lane roundabouts have been found to perform better than two-way stop-controlled (TWSC) intersections in the U.S. (5). Although the frequency of reported crashes is not always lower at roundabouts, the reduced injury rates are usually reported (6). Safety is better at small and medium capacity roundabouts than at large or multilane roundabouts (1, 7). While overall crash frequencies have been reduced, the crash reductions are most pronounced for motor vehicles, less pronounced for pedestrians, and equivocal for bicyclists, de- pending on the study and bicycle design treatments (4, 6, 7). Crash statistics for various user groups are reported in Section 5.3. The reasons for the increased safety level at roundabouts are: • Roundabouts have fewer conflict points in comparison to conventional intersec- tions. The potential for hazardous conflicts, such as right angle and left turn head-on crashes is eliminated with roundabout use. Single-lane approach round- abouts produce greater safety benefits than multilane approaches because of fewer potential conflicts between road users, and because pedestrian crossing distances are short. • Low absolute speeds associated with roundabouts allow drivers more time to react to potential conflicts, also helping to improve the safety performance of roundabouts. � Since most road users travel at similar speeds through roundabouts, i.e., have low relative speeds, crash severity can be reduced compared to some tradition- ally controlled intersections. • Pedestrians need only cross one direction of traffic at a time at each approach as they traverse roundabouts, as compared with unsignalized intersections.The conflict locations between vehicles and pedestrians are generally not affected by the presence of a roundabout, although conflicting vehicles come from a more defined path at roundabouts (and thus pedestrians have fewer places to check for conflicting vehicles). In addition, the speeds of motorists entering and exiting a roundabout are reduced with good design. As with other crossings Roundabouts may improve intersection safety by: • Eliminating or altering conflicts • Decreasing speeds into and through the intersection • Decreasing speed differentials Roundabouts: An Informational Guide • 5: Safety I fip$ Conflict points occur where one vehicle path crosses, merges or diverges with, or queues behind the path of another vehicle, pedestrian, or bicycle. requiring acceptance of gaps, roundabouts still present visually impaired pe- destrians with unique challenges, as described in Chapter 2. For the design of a new roundabout, safety can be optimized not only by relying on recorded past performance of roundabouts in general, but primarily by applying all design knowledge proven to impact safety. For optimum roundabout safety and operational performance the following should be noted: Minimizing the number of potential conflicts at any geometric feature should reduce the multiple vehicle crash rate and severity. Minimizing the potential relative speed between two vehicles at the point of conflict will minimize the multiple vehicle crash rate and severity (it may also optimize capacity). To reduce the potential relative speed between vehicles, either the absolute speeds of both vehicles need to be reduced or the angle between the vehicle paths needs to be reduced. Commuter bicyclist speeds can range from 20 to 25 km/h (12 to 15 mph) and designs that constrain the speeds of motor vehicles to similar values will minimize the relative speeds and improve safety. Lower absolute speeds will also assist pedestrian safety. Limiting the maximum change in speed between successive horizontal geo- metric elements will minimize the single vehicle crash rate and severity. 5.2 Conflicts The frequency of crashes at an intersection is related to the number of conflictpoints at an intersection, as well as the magnitude of conflicting flows at each conflict point. A conflict point is a location where the paths of two motor vehicles, or a vehicle and a bicycle or pedestrian queue, diverge, merge, or cross each other. Besides conflicts with other road users, the central island of a roundabout pre- sents a particular hazard that may result in over-representation of single-vehicle crashes that tend to occur during periods of low traffic volumes. At cross intersec- tions, many such violations may go unrecorded unless a collision with another vehicle occurs. Conflicts can arise from both The following sections present a variety of conflicts among vehicles, bicycles, and legal and illegal maneuvers; pedestrians. Both legal conflicts (queuing at an intersection, merging into a traific many of the most serious stream) and conflicts prohibited by law or by traffic control devices (failure to yield crashes are caused by failure to to pedestrians, running a stop sign) have been included for completeness. Even observe traffic control devices. though traffic control devices can significantly reduce many conflicts, they can not eliminate tnem entirely due to violations of those devices. Many of the most seri- ous crashes are caused by such violations. As with crash analyses, conflict analyses are more than the simple enumeration of the number of conflicts. A conflict analysis should account for the following fac- tors: • Existence of conflict point; '(�! I Federal HighwayAdministration • Exposure, measured by the product of the two conflicting stream volumes at a given conflict point; • Severity, based on the relative velocities of the conflicting streams (speed and angle); and • Vulnerability, based on the ability for a member of each conflicting stream to survive a crash. 5.2.1 Vehicle conflicts 5.2.1.1 Single-lane roundabouts Exhibit 5-1 presents a diagram of vehicle-vehicle conflict points for a traditional three-leg ("T") intersection and a three-leg roundabout. As the figure shows, the number of vehicle-vehicle conflict points for roundabouts decreases from nine to six for three-leg intersections. Note that these diagrams do not take into account the ability to separate conflicts in space (through the use of separate left or right turning lanes) or time (through the use of traffic control devices such as stop signs or traffic signals). _!—=^=0�� e— .� v ;Oi; � � � � � DIvC�yiny O Merging O Crossing Exhibit 5-2 presents similar diagrams for a traditional four-leg ("X" or "cross") inter- section and a four-leg roundabout. As the figure shows, the number of vehicle- vehicle conflict points for roundabouts decreases from 32 to 8 for four-leg intersec- tions. Roundabouts: An Informational Guide • 5: Safety Roundabouts bring the simplicity of a "T" intersection to intersections with more than three legs. Exhibit 5-7. Vehicle conflict points for "T" Intersections with single-lane approaches. �. Exhibit 5-2. Vehicle conflict point comparison for intersec- tions with single-lane ap- proaches. A four-leg single-lane round- about has 75% fewer vehicle conflict points—compared to a conventionalintersection. Crossing conflicts are the most severe and carry the highest public cost. I � o � --- --- a o � o • Diverging O Merging O Crossing Conflicts can be divided into three basic categories, in which the degree of severity varies, as follows: Queuing conflicts. These conflicts are caused by a vehicle running into the back of a vehicle queue on an approach. These types of conflicts can occur at the back of a through-movement queue or where left-turning vehicles are queued waiting for gaps. These conflicts are typically the least severe of all conflicts because the collisions involve the most protected parts of the vehicle and the relative speed difference between vehicles is less than in other conflicts. Merge and diverge conflicis.These conflicts are caused by the joining or separat- ing of two traffic streams. The most common types of crashes due to merge conflicts are sideswipes and rear-end crashes. Merge conflicts can be more se- vere than diverge conflicts due to the more likely possibility of collisions to the side of the vehicle, which is typically less protected than the front and rear of the vehicle. • Crossing conflicts. These conflicts are caused by the intersection of two traffic streams. These are the most severe of all conflicts and the most likely to involve injuries orfatalities.Typical crash types are right-angle crashes and head-on crashes. As Exhibit 5-1 and Exhibit 5-2 show, a roundabout reduces vehicular crossing con- flicts for both three- and four-leg intersections by converting all movements to right turns. Again, separate turn lanes and traffic control (stop signs or signalization) can often reduce but not eliminate the number of crossing conflicts at a traditional intersection by separating conflicts in space and/or time. However, the most se- vere crashes at signalized intersections occur when there is a violation of the traf- fic control device designed to separate conflicts by time (e.g., a right-angle colli- sion due to running a red light, and vehicle-pedestrian collisions). Therefore, the ability of single-lane roundabouts to reduce conflicts through physical, geometric features has been demonstrated to be more effective than the reliance on driver obedience of traffic control devices. '��; I Federal HighwayAdministration 5.2.1.2 Double-lane roundabouis In general, double-lane roundabouts have some of the same safety performance characteristics as their simpler single-lane counterparts. However, due to the pres- ence of additional entry lanes and the accompanying need to provide wider circu- latory and exit roadways, double lane roundabouts introduce additional conflicts not present in single-lane roundabouts. This makes it important to use the mini- mum required number of entry, circulating and exit lanes, subject to capacity con- siderations. For example, according to United Kingdom roundabout crash models, for a 10,000 entering Average DailyTraffic (ADT►, flaring the entry width from one to two lanes is likely to increase injury crashes by 25 percent (81. The number of vehicular and pedestrian conflicts points in both conventional inter- sections and roundabouts increases considerably when they have additional ap- proach lanes. The designer is encouraged to graphically determine conflicts for a particular location, as this information can raise awareness of design issues and may be useful in public presentations. The types of conflicts present in multilane roundabouts that do not exist in single- lane roundabouts occur when drivers use the incorrect lane or make an improper turn. These types of conflicts are depicted in Exhibit 5-3 and Exhibit 5-4, respec- tively. While these types of conflicts can also be present in other intersection forms, they can be prevalent with drivers who are unfamiliar with roundabout operation. The conflicts depicted in Exhibit 5-4, in particular, can be created by not providing a proper design geometry that allows vehicles to travel side-by-side throughout the entire roundabout (see Chapter 61. Crashes resulting from both types of conflicts can also be reduced through proper driver education. Double-lane roundabouts have some of the same safety perFormance characteristics as single-lane roundabouts, but introduce additional conflicts. Incorrect lane use and incorrect turns are multilane roundabout conflicts that do not exist in single-lane roundabouts. Exhibit 5-3. Improper lane-use conflicts in double-lane roundabouts. Roundabouts: An Informationai Guide • 5: Safety I°+��'�' Exhibit 5-4. Improper turn conflicts in double-lane roundabouts. Improper � righ� turn � by Vehicle B v ♦ \i � � � � � --- i � \\�--- + � ♦ � � ---- � � - i % � • i % i :� � � � � \ " � Improper ��.:-'.,:�'//�/ left[urn by Vehicle D � I � � ' � � � I I As with single-lane roundabouts, the most severe vehicular crossing conflicts are eliminated and replaced by less severe merging conflicts.The additional conflicts unique to multilane roundabouts are generally low-speed sideswipe conflicts that typically have low severity. Therefore, although the number of conflict points increases at multilane roundabouts when compared to a single lane roundabouts, the overall severity of conflicts is generally less than alternative intersection control. 5.2.2 Pedestrian conflicts Vehicle-pedestrian conflicts can be present at every intersection, even those with minimal pedestrian volume.The following sections examine pedestrian conflicts at signalized intersections and at roundabouts. Signalized intersections offer the opportunity to reduce the likelihood of pedes- trian-vehicle conflicts through the use of signal phasing that allows only a few movements to move legally at any given time. Exhibit 5-5 summarizes the typical pedestrian conflicts present on one approach to a signalized intersection. As the exhibit shows, a pedestrian crossing at a typical signalized intersection (permitted or protected-permitted left turns, right turns on red allowed) faces four potential vehicular conflicts, each coming from a different direction: • Crossing movements on red (typically high-speed, illegal) • Right turns on green (legal) • Left turns on green (legal for protected-permitted or permitted left turn phasing) • Right turns on red (typically legal) Types of pedestrian crossing conflicts present at signalized In terms of exposure, the illegal movements should be accorded a lower weight intersections. than legal conflicts. However, they may be accorded an offsetting higher weight in terms of severity. For an intersection with four single-lane approaches, this results in a total of 16 pedestrian-vehicle conflicts. ��; I Federal HighwayAdministration Pedestrians at roundabouts, on the other hand, face two conflicting vehicular move- ments on each approach, as depicted in Exhibit 5-6: • Conflict with entering vehicles; and • Conflict with exiting vehicles. At conventional and roundabout intersections with multiple approach lanes, an ad- ditional conflict is added with each additional lane that a pedestrian must cross. r � `. J O Vehicle/Pedestrian Conflicts • Vehicle/Vehicle Conflicts Exhibit 5-5. Vehicle-pedestrian conflicts at signalized intersec- tions. The direction conflicting vehicles will arrive from is more predictable for pedestrians at roundabouts. Exhibit 5-6. Vehicle-pedestrian conflicts at single-lane round- abouts. Roundabouts: An Informational Guide • 5: Safety I��; Exhibit 5-7. Bicycle conflicts at conventional intersections (showing two left-turn options►. 5.2.3 Bicycle conflicts Bicycles face similar conflicts as motor vehicles at both signalized intersections and roundabouts. However, because bicyclists typically ride on the right side of the road between intersections, they face additional conflicts due to overlapping paths with motor vehicles. Conflicts unique to bicyclists occur on each approach to con- ventional four-leg intersections, as depicted in Exhibit 5-7 (showing left turns like motor vehicles or left turns like pedestrians). � Conflicts in common t— Bicycle with motor vehicles Motor Vehicle � Conflicts unique +♦. Pedestrian to bicycles eicycles can be provided with At roundabouts, bicycles may be provided the option of traveling as a vehicle or as the option of traveling as either a pedestrian. As a result, the conflicts experienced by bicyclists are dependent on a vehicle or a pedestrian how they choose to negotiate the roundabout, as shown in Exhibit 5-8. When trav- through a roundabout. eling as a vehicle at a single-lane roundabout, an additional conflict occurs at the point where the bicyclist merges into the traffic stream; the remainder are similar to those for motor vehicles. At double-lane and larger roundabouts where bicycles are typically traveling on the outside part of the circulatory roadway, bicyclists face a potential conflict with exiting vehicles where the bicyclist is continuing to circu- late around the roundabout. Bicyclists may feel compelled to "negotiate" the circle (e.g., by indicating their intentions to drivers with their arms) while avoiding con- flicts where possible. Bicyclists are less visible and therefore more vulnerable to the merging and exiting conflicts that happen at double-lane roundabouts. When traveling as a pedestrian, an additional conflict for bicyclists occurs at the point where the bicyclist gets onto the sidewalk, at which point the bicyclist continues around the roundabout like a pedestrian. On shared bicycle-pedestrian paths or on sidewalks, if bicyclists continue to ride, additional bicycle-pedestrian conflicts occur wherever bicycle and pedestrian movements cross (not shown on the exhibit). ,z, ��;; I Federal HighwayAdministration Bicyclist traveling as vehicle Bicyclist traveling as vehicles � Conflicts in common t— Bicycle with motor vehides �_ Motor Vehicle � Conflicts unique �r� Pedestrian to bicycles 5.3 Crash Statistics This section summarizes the overall safety performance of roundabouts in various countries (including the U.S.) and then examines the detailed collision types expe- rienced in France and Queensland, Australia. Pedestrian and bicycle crash statis- tics are discussed separately, including design issues for visually impaired pedes- trians. 5.3.1 Comparisons to previous intersectian treatment Exhibit 5-9 shows the crash frequencies (average annual crashes per roundabout) experienced at eleven intersections in the U.S. that were converted to roundabouts. As the exhibit shows, both types of roundabouts showed a reduction in both injury and property-damage crashes after installation of a roundabout. It should be noted that due to the small size of the data sample, the only result that is statistically significant is the injury crash reduction for small and moderate roundabouts. Exhibit 5-8. Bicycle conflicts at roundabouts (showing two left-turn options�. Bicycle-pedestrian conflicts can also occur on shared pathways adjacent to the roundabout. Roundabouts: An Informational Guide • 5: Safety I 11°'�' Exhibit 5-9. Average annual crash frequencies at 11 U.S. intersections converted to roundabouts. Exhibit 5-10. Mean crash reductions in various countries. Type of Roundabout Sites Small/Moderate' 8 Large2 3 Total 11 Before Roundabout Total Inj.' PDO° 4.8 2.0 2.4 21.5 5.8 15.7 9.3 3.0 6.0 Roundabout PercentChange5 Total Inj. PDO Total Inj. PDO 2.4 0.5 1.6 -51 % 73% -32°/a 15.3 4.0 11.3 -29% -31 % -10% 5.9 1.5 4.2 -37% -51 % -29% Notes: 1. Mostly single-lane roundabouts with an inscribed circle diameter of 30 to 35 m(100 to 115 ft1. 2. Multilane roundabouts with an inscribed circle diameter greater than 50 m(165 ftl. 3.Inj. = Injury crashes 4. PDO = Property Damage Only crashes 5. Only injury crash reductions for small/moderate roundabouts were statisticaliy significant. Source: 191 Compared to results from Australia, France, and the United Kingdom, these crash frequencies are quite high. Annual crash frequencies in France, Australia, and United Kingdom of 0.15, 0.6, and 3.31 injury crashes per roundabout, respectively, have been reported (1, 10).The reader should note that the UK has many high-volume, multilane roundabouts. In spite of the higher frequencies, injury crash rates, which account for traffic vol- ume exposure, are significantly lower at U.S. roundabout sites. In a recent study of eight single-lane roundabouts in Maryland and Florida, the injury crash rate was found to be 0.08 crashes per million entering vehicles (51. By comparison, the injury crash rate was reported to be 0.045 crashes per million entering vehicles in France and 0.275 crashes per million entering vehicles in the United Kingdom (1, 10). Experiences in the United States show a reduction in crashes after building a round- about of about 37 percent for all crashes and 51 percent for injury crashes. These values correspond with international studies with much larger sample sizes, as shown in Exhibit 5-10. Country Australia France Germany Netherlands United Kingdom United States Source: (21, France: 111) Mean Reduction (%) All Crashes Injury Crashes 41 -61% 45-87% 57-78% 36% 47% 37% 25 - 39°/a 51% � �, � Federal HighwayAdministration �.n�. The findings of these studies show that injury crashes are reduced more dramati- cally than crashes involving property damage only. This again is in part due to the configuration of roundabouts, which eliminates severe crashes such as left turn, head-on, and right angle collisions. Most of these studies also show that crash reduction in rural areas is much higher than in urban areas. Note that the geometry of many studied sites may not necessarily conform to Caveats for comparing the good roundabout design. Improved design principles, such as an emphasis on achiev- results of crash studies. ing consistent speeds, may result in better safety performance. It should also be noted that these crash reductions are generally for sites where roundabouts were selected to replace problem intersections. Therefore, they do not necessarily rep- resent a universal safety comparison with all other intersection types. Collisions at roundabouts tend to be less severe than at conventional intersec- tions. Most crashes reported at roundabouts are a result of drivers failing to yield on entry, referred to as entering-circulating crashes. In addition, rear-end collisions and single vehicle crashes have been reported in many studies. Exhibit 5-11 shows the percentage of the three main crash types reported in different countries. Country Australia France Germany Switzerland Type of Crash' Crash Type of Entering- Single Description Roundabout circulating Rear-end Vehicle All crashes Single and multilane Injury crashes Single and multilane All crashes Single lane All crashes Single and multilane United Kingdom Injury crashes Single and multilane 51 % 22% 37 % 13 °/a 30% 28% 46% 13% 18% 28% 17% 35% 20-71% 7-25% 8-30% 1. Percentages do not necessarily sum to 100% because only three major crash categories are shown. Source: (10) 5.3.2 Collision types It is instructive for designers to examine details of collision types and location at roundabouts. Statistics are available for roundabouts designed according to local practices in France, Queensland (Australial, and the United Kingdom. It should be noted that the reported frequencies are to some extent related to the specific design standards and reporting processes used in these countries. Exhibit 5-12 presents a summary of the percentage of crashes by collision type. The numbered items in the list correspond to the numbers indicated on the dia- grams given in Exhibit 5-13 as reported in France. The French data illustrate colli- sion types for a sample of 202 injury crashes from 179 urban and suburban round- abouts in France for the period 1984-1988 (12). For comparison purposes, data Exhibit 5-11. Reported proportions of major crash types at roundabouts. Roundabouts: An Informational Guide • 5: Safety I�� from Queensland, Australia (13) and the United Kingdom (1 � have been superim- posed onto the same classification system. The results in Exhibit 5-12 are instructive for a number of reasons: • A variety of collision types can take place at roundabouts. A designer should be aware of these collision types when making decisions about alignment and location of fixed objects. It is recommended that these collision types be adopted as conflict types in the U.S. to conduct traffic conflict analysis and report crashes at roundabouts. � Although reporting methodologies may vary somewhat, crash experience var- ies from country to country. This may be due to a combination of differences in driver behavior, and design features. Exhibit 5-72. Comparison of collision types at roundabouts. Collision Type 1. Failure to yield at entry (entering-circulating) 2. Single-vehicle run off the circulatory roadway 3. Single vehicle loss of control at entry 4. Rear-end at entry 5. Circulating-exiting 6. Pedestrian on crosswalk 7. Single vehicle loss of control at exit 8. Exiting-entering 9. Rear-end in circulatory roadway 10. Rear-end at exit 11. Passing a bicycle at entry 12. Passing a bicycle at exit 13. Weaving in circulatory roadway 14. Wrong direction in circulatory roadway 15. Pedestrian on circulatory roadway 16. Pedestrian at approach outside crosswalk Other collision types Other sideswipe crashes Clueensland United France (Australia) Kingdom' 36.6% 50.8% 71.1 % 16.3% 10.4% 8.2%2 11.4% 5.2% z 7.4% 16.9% 7.0%3 5.9% 6.5% 5.9% 3.5%° 2.5% 2.6% z 2.5% 0.5% 1.2% 1.0% 0.2% 1.0 % 1.0 % 2.5% 2.0% 1.0% 3.5% ° 1.0% ° 2.4% 10.2% 1.6 % Notes: 1. Data are for "small" roundabouts (curbed central islands > 4 m[13 ft] diameter, relatively large ratio of inscribed circle diameter to central island size) 2. Reported findings do not distinguish among single-vehicle crashes. 3. Reported findings do not distinguish among approaching crashes. 4. Reported findings do not distinguish among pedestrian crashes. Sources: France (121, Australia (13), United Kingdom (1) �� I Federal HighwayAdministration � v� O , O- � / Y�� /r source Is, m 6%ii _m i I�. i m 11��18 ' ► �:.- \ Exhibit 5-73. Graphical depiction of collision types at roundabouts. Roundabouts: An Informational Guide • 5: Safety I 115 Exhibit 5-74. Crash percent- age per type of user for urban roundabouts in 15 towns in western France. Three of the predominant types of collision are: (1) failures to yield at entry to circulating vehicles, (2) single vehicle run-off the circulatory roadway, and (3) single vehicle run-into the central island. A more recent crash study (14) confirmed a high proportion of single vehicle crashes: 49 percent in rural areas, versus 21 percent in urban areas. According to crash models from the United Kingdom, single vehicle crashes range between 20 and 40 percent depending on traffic and design charac- teristics of sites. In the United Kingdom models, separation by urban and rural areas is not provided. To reduce the severity of single vehicle crashes, special attention should be ac- corded to improving visibility and avoiding or removing any hard obstacles on the central island and splitter islands in both urban and rural environments. A French study (14) identified a number of major obstacles that caused fatalities and injuries: trees, guardrail, concrete barriers, fences, walls, piers, sign or light poles, land- scaping pots or hard decorative objects, and steep cross-slopes on the central island. In rural areas, the benefit of lighting has not yet been quantified. In France, only 36 percent of the rural sites are lighted. At these sites, 46 percent of all crashes, and 49 percent of single vehicle crashes occur at night (14). The French study �7) in 15 towns of 202 urban roundabout crashes compared with all crossroads reported the percentage of crashes by user type, as shown in Ex- hibit 5-14. The percentage of crashes concerning pedestrians was similar to all crossroads. However, the percentage of crashes involving bicycles and mopeds was larger-15.4 percent for urban crossroads overall versus 24.2 percent for round- abouts, i.e., almost 60 percent more. User Pedestrians Bicycles Mopeds Motor cycles Cars Utility vehicles Heavy goods vehicles Bus/coach Miscellaneous Total Source: (71 6.3 % 3.7% 11.7% 7.4% 65.7 % 2.0% 2.0% 0.8 % 0.4 % 100.0% Roundabou� 5.6% 73% 16.9% 4.8 % 61.2 % 0.6 % 3.0% 0.6% 0.0 % 100.0% 116 I Federal HighwayAdministration 5.3.3 Pedestrians As was described previously, vehicular injury crashes normally decrease when round- abouts are installed at an existing intersection. The safety benefits of roundabouts have been found to generally carry over to pedestrians as well, as shown in British statistics of Exhibit 5-15.This may be due to the reduced speeds at roundabouts as compared with the previous intersection forms. Pedestrian Crashes Intersection Type per MillionTrips Mini-roundabout 0.31 Conventional roundabout 0.45 Flared roundabout 0.33 Signals 0.67 Source: (1, 15) For pedestrians, the risk of being involved in a severe collision is lower at round- abouts than at other forms of intersections, due to the slower vehicle speeds. Likewise, the number of conflict points for pedestrians is lower at roundabouts than at other intersections, which can lower the frequency of collisions. The splitter island between entry and exit allows pedestrians to resolve conflicts with entering and exiting vehicles separately. A Dutch study of 181 intersections converted to roundabouts (4) found reductions (percentage) in all pedestrian crashes of 73 percent and in pedestrian injury crashes of 89 percent. In this study, all modes shared in the safety benefits to greater (passenger cars) or lesser extents (bicycles), as shown in Exhibit 5-16. Mode Passengercar Moped Bicycle Pedestrian Total Source: (4) All Crashes 63 % 34% 8% 73% 51% Injury Crashes 95% 63 % 30% 89% 72% Exhibit 5-15. British crash rates for pedestrians at roundabouts and signalized intersections. Exhibit 5-16. Percentage reduction in the number of crashes by mode at 181 converted Dutch roundabouts. Roundabouts: An Informational Guide • 5: Safety I�?� Zebra-stripe markings are A risk analysis of 59 roundabouts and 124 signalized intersections was carried out recommended at most on crash data in Norway between 1985 and 1989. Altogether, 33 crashes involving roundabouts to indicate personal injury were recorded at the 59 roundabouts. Only 1 of these crashes pedestrian crossings. involved a pedestrian, compared with the signalized intersections, where pedestri- ans were involved in 20 percent of the personal injury crashes (57 of 287 injury crashes) (161. Further, there is no quantitative evidence of increased safety for pedestrians at roundabouts with striped (zebra) crossings, where pedestrians have priority.There- fore, striped crossings have generally not been used in other countries. However, in the U.S., it is recommended that all crosswalks be striped except at rural loca- tions with low pedestrian volumes. Although this is not their intended function, striped crosswalks may further alert approaching drivers to a change in their appro- priate speed near the yield point. Safety of visually impaired Crash data have not been collected to indicate whether a pedestrian has a disabil- pedestrians at roundabouts ity, and no studies have focused specifically on the safety of visually impaired pe- requires further research. destrians at roundabouts. This is an area requiring further research. 5.3.3.1 Information access for b/ind or visually impaired pedestrians Challengesthatroundabouts Roundabout crossing skills may be difficult for disabled pedestrians to perform pose to visually impaired without assistance. For example, audible pedestrian-activated signals may be con- pedestrians. sidered on an approach, although this treatment is not typical. Any leg of any round- about could be equipped with a pedestrian-activated signal at the pedestrian cross- ing, if a balanced design requires providing assistance to pedestrians at that loca- tion. For example, motorized volume that is too heavy at times to provide a suffi- cient number of gaps acceptable for pedestrians may warrant a pedestrian signal equipped with audible devices to assist people with visual disabilities. When crossing a roundabout, there are several areas of difficulty for pedestrians who are blind or visually impaired. It is desirable that a visually impaired pedestrian with good travel skills should be able to arrive at an unfamiliar intersection and cross it with pre-existing skills and without special, intersection-specific training. Round- abouts pose problems at several points of the crossing experience, from the per- spective of their access to information: • The first task of the visually impaired pedestrian is to locate the crosswalk.This can be difficult if the roundabout is not properly landscaped and if the curb edge of the ramp is not marked with a detectable warning surface (see Chapter 6). The crosswalk direction must also be unambiguous. • Depending upon whether the visually impaired pedestrian is crossing the round- about in a clockwise or counterclockwise direction, they must listen for a safe gap to cross either the entrance or exit lane(s).The primary problem is the sound of traffic on the roundabout, which may mask the sound of cars approaching the ��'`, � Federal HighwayAdministration crosswalk. While crossing the exit lane poses the greater hazard to the pedes- trian who is visually impaired because of the higher speed of the vehicles, cross- ing the entrance may also pose significant problems. Entering traffic, while slower, may also be intimidating as it may not be possible to determine by sound alone whether a vehicle has actually stopped or intends to stop. Sighted pedestrians often rely upon communication through eye contact in these situations; how- ever, that is not a useful or reliable technique for the pedestrian who is visually impaired. Both these problems are further exacerbated at roundabouts with multilane entrances and exits. In these roundabouts, a stopped car in the near lane may mask the sounds of other traffic. It may also block the view of the driver in the far lane of the cane or guide dog of a person who is visually im- paired who begins to cross (this is also a problem for children and people using wheelchairs on any crossing of a multilane road). • The third task is locating the splitter island pedestrian refuge. If this refuge is not ramped, curbed, or equipped with detectable warnings, it is not detectable by a pedestrian who is visually impaired. • Crossing the remaining half of the crossing �see the second bullet above). • Locating the correct walkway to either continue their path or locate the adjacent crosswalk to cross the next leg of the roundabout. Unless these issues are addressed by a design, the intersection is "inaccessible" and may not be permissible under the ADA. Chapters 6 and 7 provide specific suggestions to assist in providing the above information. However, more research is required to develop the information jurisdictions need to determine where round- abouts may be appropriate and what design features are required for people with disabilities. Until specific standards are adopted, engineers and jurisdictions must rely on existing related research and professional judgment to design pedestrian features so that they are usable by pedestrians with disabilities. Possible design remedies for the difficulties faced by pedestrians include tight en- tries, raised speed tables with detectable warnings, treatments for visually im- paired pedestrians to locate crosswalks, raised pavement markers with yellow flash- ing lights to alert drivers of crossing pedestrians, pedestrian crossings with actu- ated signals set sufficiently upstream of the yield line to minimize the possibility of exiting vehicle queues spilling back into the circulatory roadway (6). However, the safety of these treatments at roundabouts has not been tested in the United States. Chapters 6 and 7 provide suggestions on designing roundabouts to accommodate persons with disabilities. Roundabouts: An Informational Guide • 5: Safety I��; Exhibit 5-17. British crash rates (crashes per million trips) for bicyclists and motorcyclists at roundabouts and signalized intersections. Exhibit 5-18. A comparison of crashes between signalized and roundabout intersections in 1998 in 15 French towns. 5.3.4 Bicyclists As shown in Exhibit 5-17, at British roundabouts bicyclists fare worse in terms of crashes at roundabouts than at signalized intersections. Intersection Type Bicyclists Motorcyclists Mini-roundabout 3.11 2,37 Conventional roundabout 2.91 2.67 Flared roundabout Z85 2.37 Signals 1.75 2.40 Source: (1, 15) A French study (7) compared the crashes in 1988 in 15 towns in the west of France at both signalized intersections and roundabouts, as shown in Exhibit 5-18. The conclusions from the analysis were: • There were twice as many injury crashes per year at signalized intersections than at roundabouts; • Two-wheel vehicles were involved in injury crashes more often (+77 percent) at signalized intersections than on roundabouts; • People were more frequently killed and seriously injured per crash �+25 per- cent) on roundabouts than at signalized intersections; • Proportionally, two-wheel vehicle users were more often involved in crashes (16 percent) on roundabouts than at signalized intersections. Furthermore, the con- sequences of such crashes were more serious. Number of crossroads Number of personal injuries Number of crashes involving 2-wheel vehicles Personal injury crashes/year/crossroad 2-wheel vehicle crashes/year/crossroad Crashes to 2-wheel vehicles per 100 crashes Serious crashes/year/crossroad Serious crashes to 2-wheel vehicles/year/crossroad Serious crashes/100 crashes Serious crashes to 2-wheel vehicles/100 crashes to a 2-wheel vehicle Source: 171 Signalized Crossroads Roundabouts 1, 238 794 278 0.64 0.23 35.0 0.14 0.06 21.9 27.0 179 59 28 0.33 0.13 40.7 0.089 0.045 27.1 33.3 �� I Federal HighwayAdministration All European countries report that a more careful design is necessary to enhance bicyclists' safety.The type of bicycle crashes depends on the bicycle facilities pro- vided at the roundabout. If there are no bicycle facilities, or if there is a bike lane on the outer area of the circulatory roadway, crashes typically occur between entering cars and circulating bicyclists as well as between cars heading into an exit and circulating bicyclists. Improperly placed signs on the splitter island may also be a contributing factor. As a result, most European countries have the following policies: • Avoid bike lanes on the outer edge of the circulatory roadway. • Allow bicyclists to mix with vehicle traffic without any separate facility in the circulatory roadway when traffic volumes are low, on single lane roundabouts operating at lower speeds (e.g., up to 8,000 vehicles per day in the Netherlands 14))• Introduce separated bicycle facilities outside the circulatory roadway when ve- hicular and bicycle volumes are high.These separated bicycle facilities cross the exits and entries at least one car length from the edge of the circulatory road- way lane, adjacent to the pedestrian crossings. In some countries, bicyclists have priority over entering and exiting cars, especially in urban areas (e.g., Ger- many). Other countries prefer to give priority to car traffic showing a yield sign to bicyclists (e.g., Netherlands). The latter solution (i.e., separate bicycle facili- ties with vehicular traffic priority at the crossing points) is the standard solution for rural areas in most European countries. Speed is a fundamental risk factor in the safety of bicyclists and pedestrians.Typi- cal bicyclist speeds are in the range of 20 to 25 km/h (12 to 15 mph), and designs that constrain the speeds of vehicles to similar values will minimize the relative speeds and thereby improve safety. Design features that slow traffic such as tight- ening entry curvature and entry width, and radial alignment of the legs of a round- about, such as with the urban compact design, are considered safe treatments for bicyclists (17). In the Netherlands, a 90 percent decrease in injury crashes was experienced with separate bicycle paths around roundabouts where bicyclists do not have right-of- way at the crossings (17). A bicycle crash prediction model from Sweden has been validated against data for Swedish, Danish, and Dutch roundabouts (18). The model provides reasonable re- sults for roundabouts with up to 12,000 vehicles per day and 4,000 bicycles per day.The model tends to over-predict crashes (i.e., is conservative) for roundabouts carrying more than 12,000 vehicles per day that are also designed with separate bicycle paths with crossings on the approach legs. It is calibrated for crossroad intersections as well as roundabouts. To obtain the expected cycling crashes per year at roundabouts, the value derived from the general junction model is factored by 0.71, implying that bicycle crashes at roundabouts are 71 percent less frequent than at junctions in general. However, the reader is cautioned when extrapolating European bicycling experience to the U.S., as drivers in Europe are more accus- tomed to interacting with bicyclists. Typical European practice is to provide separated bicycle facilities outside the circulatory roadway when vehicular and bicycle volumes are high. Roundabouts: An Informational Guide • 5: Safety I 1iG�' 5.4 Crash Prediction Models Crash prediction models have Crash prediction models have been developed for signalized intersections in the not been developed for U.S. U.S., as discussed previously in Chapter 3. However, no crash prediction models roundabouts. exist yet for U.S. roundabouts and driver behavior. Given the relatively recent intro- duction of roundabouts to the U.S. and driver unfamiliarity with them, crash predic- tion models from other countries should be used cautiously. As reported earlier in Section 5.3, crash statistics vary from country to country, both in terms of magni- tude and in terms of collision types. Consequently, the application of a crash pre- diction model from another country may not accurately predict crash frequencies at U.S. locations. Nonetheless, these crash prediction models from other coun- tries can be useful in understanding the relative effects of various geometric fea- tures on the number of crashes that might be expected. The user is thus cautioned to use these models only for comparative purposes and for obtaining insights into the refinement of individual geometric elements, not to use them for predicting absolute numbers of crashes under U.S. conditions. Crash models relating crash frequency to roundabout characteristics are available from the United Kingdom.The sample consisted of 84 four-leg roundabouts of all sizes, small to large and with various number of approach lanes and entry lanes (flared or parallel entries) (1). Approach speeds were also evenly represented be- tween 48 to 64 km/h �30 to 40 mph) and 80 to 113 km/h (50 to 70 mph). Crash data were collected for periods of 4 to 6 years, a total of 1,427 fatal, serious, and slight injuries only. The proportion of crashes with one casualty was 83.7 percent, and those with two casualties was 12.5 percent.The models are based on generalized linear regression of the exponential form, which assumes a Poisson distribution. Their goodness of fit is expressed in terms of scaled deviations that are moder- ately reliable. No additional variables, other than those listed below, could further improve the models significantly (see also (8)). The British crash prediction equations (1), for each type of crash are listed in Equa- tions 5-1 through 5-5. Note that these equations are only valid for roundabouts with four legs. However, the use of these models for relative comparisons may still be reasonable. Entry-Circulating: (5-1) A=0.052Q°'Q04exp(-4L�e+0.14e-0.007ev— � +0.2Pm-0.0161 1+ exp(4R — 7) where: A= personal injury crashes (including fatalities) per year per roundabout approach; Qe = entering flow (1,OOOs of vehicles/day) Q� = circulating flow (1,OOOs of vehicles/day) Ce = entry curvature = 1 /Re e = entry width (m) v = approach width (m) R= ratio of inscribed circle diameter/central island diameter P = proportion of motorcycles (%) B= angle to next leg, measured centerline to centerline (degrees) 1�" I Federal HighwayAdministration Approaching: A=0.0057Q''exp(2(Z'e-0.1e) (5-2) where: A= personal injury crashes (including fatalities) per year at roundabout approach or leg; Qe = entering flow (1,OOOs of vehicles/day) Ce = entry curvature = 1 /Re Re = entry path radius for the shortest vehicle path (m) e = entry width (m) SingleVehicle: A=0.0064Q°8exp(25Ce+0.2v-45Ca) (5-3) where: A= personal injury crashes (including fatalities) per year at roundabout approach or leg Qe = entering flow (1,OOOs of vehicles/day) Ce = entry curvature = 1 /Re Re = entry path radius for the shortest vehicle path (m) V = approach width (m) C = approach curvature = 1/Ra Ra = approach radius (m), defined as the radius of a curve between 50 m (164 ft) and 500 m(1,640 ft) of the yield line Other (Vehicle): A=0.0064Qe8exp(25Ce+0.2v-45Ca) (5-4) where: A= personal injury crashes (including fatalities) per year at roundabout approach or leg QeC = product Qe' Q� Qe = entering flow (1,OOOs of vehicles/day) Q� = circulating flow (1,OOOs of vehicles/day) Pm = proportion of motorcycles Pedestrian: A= 0.029Q p5 (5-5) where: A= personal injury crashes (including fatalities) per year at roundabout approach or leg QeP = product (Qe + Qe1�. QP Qe = entering flow (1,OOOs of vehicles/day) QeX = exiting flow (1,OOOs of vehicles/day) QP = pedestrian crossing flow (1,OOOs of pedestrians/day) According to the U.K. crash models, the major physical factors that were statisti- cally significant are entry width, circulatory width, entry path radius, approach cur- vature, and angle between entries. Some of the effects of these parameters are as follows: • Entry widih: For a total entry flow of 20,000 vehicles per day, widening an entry from one lane to two lanes is expected to cause 30 percent more injury crashes. At 40,000 vehicles per day, widening an entry from two lanes to three lanes will cause a 15 percent rise in injury crashes. Moreover, the models could not take into account the added hazard to bicyclists and pedestrians who will have to travel longer exposed distances. (8) Roundabouts: An Informational Guide • 5: Safety ,��; • Circulatory width: Widening the circulatory roadway has less impact on crashes than entry width. Crashes are expected to rise about 5 percent for a widening of two meters. (8) • Entry path radius: Entry-circulating collision type increases with entry path ra- dius (for the fastest path), while single vehicle and approach collision types decrease. For a double-lane approach, an optimum entry path radius is 50 to 70 m (165 to 230 ft). (8) • Approach curvature: Approach curvature is safer when the approach curve is to the right and less so when the curve is to the Ieft.This implies that a design is slightly safer when reverse curves are provided to gradually slow drivers before entry. For a double-lane approach roundabout with entering flow of 50,000 ve- hicles per day, changing a straight approach to a right-turning curve of 200 m (650 ft) radius reduces crash frequency by 5 percent. (8) Maximize angles between • Angle between eniries: As the angle between entries decreases, the frequency entries. of crashes increases. For example, an approach with an angle of 60 degrees to the next leg of the roundabout increases crash frequency by approximately 35 percent over approaches at 90-degree angles. Therefore, the angle between entries should be maximized to improve safety. An approach suggested in Australia (13) differs from the British approach in that the independent variables are based on measures related to driver behavior. For in- stance, the collision rate for single vehicle crashes was found to be: and ASp = 1.64 x 1�12 x Q' "x L x(S+4SJ"z/R' 91 (5-6) A�= 1J9x 109xQos,xLx(S+OSJ,ss�Ro.sS (5-7) where: ASP the number of single vehicle crashes per year per leg for vehicle path segments prior to the yield line. Asa = the number of single vehicle crashes per year per leg for vehicle path segments after the yield line. Q= the average annual daily traffic in the direction considered—one way traffic only (veh/d) L= the length of the driver's path on the horizontal geometric element (m). S= the 85th-percentile speed on the horizontal geometric element (km/h►. 4S = the decrease in the 85th-percentile speed at the start on the horizon- tal geometric element (km/h). This indicates the speed change from the previous geometric element. R= the vehicle path radius on the geometric element (m�. These equations demonstrate a direct relationship between the number of crashes, overall speed magnitudes, and the change in speed between elements.Therefore, this equation can be used to estimate the relative differences in safety benefits between various geometric configurations by estimating vehicle speeds through the various parts of a roundabout. *�; I Federal HighwayAdministration 5.5 References 1. Maycock, G., and R.D. Hall. Crashes at four-arm roundabouts.TRRL Laboratory Report LR 1120. Crowthorne, England: Transport and Road Research Labora- tory, 1984. 2. Garder, P The Modern Roundabouts: The Sensible Alternative for Maine. Maine Department of Transportation, Bureau of Planning, Research and Community Services, Transportation Research Division, 1998. 3. Brilon, W. and B. Stuwe. "Capacity and Design ofTraffic Circles in Germany" In Transportation Research Record 1398. Washington, D.C.:Transportation Research Board, National Research Council, 1993. 4. Schoon, C.C., and J. van Minnen. Accidents on Roundabouts: ll. Second study into the road hazard presented by roundabouts, particularly with regard to cy- clisis and moped riders. R-93-16. The Netherlands: SWOV Institute for Road Safety Research, 1993. 5. Flannery, A. andT.K. Datta. "Modern Roundabouts andTraffic Crash Experience in the United States:' In Transportation Research Record 1553. Washington, D.C.: Transportation Research Board, National Research Council, 1996. 6. Brown, M. TRL State of the Art Review-The Design of Roundabouts. London: HMSO, 1995. 7. Alphand, F, U. Noelle, and B. Guichet. "Roundabouts and Road Safety: State of the Art in France:' In Intersections without Traffic Signals ll, Springer-Verlag, Germany (W. Brilon, ed.), 1991, pp. 107-125. 8. Bared, J.G., and K. Kennedy. "Safety Impacts of Modern Roundabouts;' Chapter 28, The Traffic SafetyToolbox: A Primer on Traffic Safety, Institute of Transporta- tion Engineers, 2000. 9. Jacquemart, G. Synthesis of Highway Practice 264: Modern Roundabout Prac- tice in the United States. National Cooperative Highway Research Program. Wash- ington, D.C: National Academy Press, 1998. 10. Brilon, W. and L. Bondzio. White Paper: Summary of International Statistics on Roundabout Safety (unpublished), July 1998. 11. Guichet, B. "Roundabouts In France: Development, Safety, Design, and Capac- ity:' In Proceedings of ihe Third International Symposium on Intersections With- outTraffic Signals (M. Kyte, ed.), Portland, Oregon, U.S.A. University of Idaho, 1997. 12. Centre d'Etude des Transports Urbains (CETUR). "Safety of Roundabouts in Urban and Suburban Areas:' Paris, 1992. 13. Arndt, O. "Road Design IncorporatingThree Fundamental Safety Parameters" TechnologyTransfer Forum 5 and 6,TransportTechnology Division, Main Roads Department, Queensland, Australia, August 1998. 14. SETRA/CETE de I'Ouest. "Safety Concerns on Roundabouts" 1998. Roundabouts: An Informational Guide • 5: Safety ��; 15. Crown, B. 'An Introduction to Some Basic Principles of U.K. Roundabout De- sign:' Presented at the ITE District 6 Conference on Roundabouts, Loveland, Colorado, October 1998. 16. Seim, K. "Use, Design and Safety of Small Roundabouts in Norway:' In "Inter- sections Without Traffic Signals II° Springer-Verlag, Germany (W. Brilon, ed.), 1991, pp.270-281. 17. Van Minnen, J. "Safety of Bicyclists on Roundabouts Deserves Special Atten- tion" SWOV Institute of Road Safety Research in the Netherlands, Research Activities 5, March 1996. 18. Brude, U., and J. Larsson. The Safety of Cyclists at Roundabouts—A Compari- son Beiween Swedish, Danish and Dutch Results. Swedish National Road and Transport Research Institute (VTI), Nordic Road & Transport Research No. 1, 1997. ��; I Federal HighwayAdministration 6.7 6.2 6.3 Geometric Design I ntroduction 6.1.1 Geometric elements 6.1.2 Design process General Design Principles 6.2.1 Speeds through the roundabout 6.2.2 Design vehicle 6.2.3 Nonmotorized design users 6.2.4 Alignment of approaches and entries Geometric Elements 6.3.1 Inscribed circle diameter 6.3.2 Entry width 6.3.3 Circulatory roadway width 6.3.4 Central island 6.3.5 Entry curves 6.3.6 Exit curves 6.3.7 Pedestrian crossing location and treatments 6.3.8 Splitter islands 6.3.9 Stopping sight distance 6.3.10 Intersection sight distance 6.3.11 Vertical considerations 6.3.12 Bicycle provisions 130 130 130 132 132 142 144 144 145 145 147 149 150 152 154 155 157 159 161 164 167 6.4 6.5 6.6 6.7 Exhibit 6-1. Exhibit 6-2. Exhibit 6-3. Exhibit 6-4. Exhibit 6-5. Exhibit 6-6. Exhibit 6-7. Exhibit 6-8. Exhibit 6-9. Exhibit 6-10. Exhibit 6-17. Exhibit 6-12. Exhibit 6-13. Exhibit 6-14 Exhibit 6-15. Exhibit 6-76. Exhibit 6-17. Exhibit 6-18. Exhibit 6-19. Exhibit 6-20. 6.3.13 Sidewalk treatments 6.3.14 Parking considerations and bus stop locations 6.3.15 Right-turn bypass lanes Double-Lane Roundabouts 6.4.1 The natural vehicle path 6.4.2 Vehicle path overlap 6.4.3 Design method to avoid path overlap Rural Roundabouts 6.5.1 Visibility 6.5.2 Curbing 6.5.3 Splitter islands 6.5.4 Approach curves Mini-Roundabouts References Basic geometric elements of a roundabout. Roundabout design process. Sample theoretical speed profile (urban compact roundabout). Recommended maximum entry design speeds. Fastest vehicle path through single-lane roundabout. Fastest vehicle path through double-lane roundabout. Example of critical right-turn movement. Side friction factors at various speeds (metric units). Side friction factors at various speeds (U.S. customary units). Speed-radius relationship (metric units). Speed-radius relationship (U.S. customary units). Vehicle path radii. Approximated Rq values and corresponding R� values (metric units). Approximated Ra values and corresponding R, values (U.S. customary units). Through-movement swept path of WB-15 (WB-50) vehicle. Left-turn and right-turn swept paths of WB-15 (WB-50) vehicle Key dimensions of nonmotorized design users. Radial alignment of entries. Recommended inscribed circle diameter ranges. Approach widening by adding full lane. 168 169 170 172 172 174 174 176 177 177 177 178 179 181 131 131 133 133 134 135 135 137 137 138 138 139 141 141 143 143 144 145 146 148 '�;�; I Federal HighwayAdministration Exhibit 6-21. Exhibit 6-22. Exhibit 6-23. Exhibit 6-24. Exhibit 6-25. Exhibit 6-26. Exhibit 6-27. Exhibit 6-28. Exhibit 6-29. Exhibit 6-30. Exhibit 6-31. Exhibit 6-32. Exhibit 6-33. Exhibit 6-34. Exhibit 6-35. Exhibit 6-36. Exhibit 6-37. Exhibit 6-38. Exhibit 6-39. Exhibit 6-40. Exhibit 6-41. Exhibit 6-42. Exhibit 6-43. Exhibit 6-44. Exhibit 6-45. Exhibit 6-46. Exhibit 6-47. Exhibit 6-48. Exhibit 6-49. Exhibit 6-50. Approach widening by entry flaring. Minimum circulatory lane widths for two-lane roundabouts. Example of central island with a traversable apron. Single-lane roundabout entry design. Single-lane roundabout exit design. Minimum splitter island dimensions. Minimum splitter island nose radii and offsets. Design values for stopping sight distances. Approach sight distance. Sight distance on circulatory roadway. Sight distance to crosswalk on exit. Intersection sight distance. Computed length of conflicting leg of intersection sight triangle. Sample plan view. Sample approach profile. Sample central island profile. Typical circulatory roadway section. Typical section with a truck apron. Possible provisions for bicycles. Sidewalk treatments. Example of right-turn bypass lane. Configuration of right-turn bypass lane with acceleration lane. Configuration of right-turn bypass lane with yield at exit leg. Sketched natural paths through a double-lane roundabout. Path overlap at a double-lane roundabout. One method of entry design to avoid path overlap at double-lane roundabouts. Alternate method of entry design to avoid path overlap at double-lane roundabouts. Extended splitter island treatment. Use of successive curves on high speed approaches. Example of mini-roundabout. � 150 151 153 154 157 158 159 160 160 161 162 163 164 165 165 166 166 168 169 170 171 172 173 174 175 175 178 179 180 Roundabouts: An Informational Guide • 6: Geometric Design I 3� Chapter 6 Geometric Design 6.1 Introduction Roundabout design Designing the geometry of a roundabout involves choosing between trade-offs of involves trade-offs among safety and capacity. Roundabouts operate most safely when their geometry forces safety, operations, traffic to enter and circulate at slow speeds. Horizontal curvature and narrow pave- aod accommodating ment widths are used to produce this reduced-speed environment. Conversely, large vehicles. the capacity of roundabouts is negatively affected by these low-speed design ele- ments. As the widths and radii of entry and circulatory roadways are reduced, so also the capacity of the roundabout is reduced. Furthermore, many of the geomet- ric parameters are governed by the maneuvering requirements of the largest ve- hicles expected to travel through the intersection. Thus, designing a roundabout is a process of determining the optimal balance between safety provisions, opera- tional performance, and large vehicle accommodation. Some roundabout features are While the basic form and features of roundabouts are uniform regardless of their uniform, while others vary location, many of the design techniques and parameters are different, depending depending on the location and on the speed environment and desired capacity at individual sites. In rural environ- size of the roundabout. ments where approach speeds are high and bicycle and pedestrian use may be minimal, the design objectives are significantly different from roundabouts in ur- ban environments where bicycle and pedestrian safety are a primary concern. Ad- ditionally, many of the design techniques are substantially different for single-lane roundabouts than for roundabouts with multiple entry lanes. This chapter is organized so that the fundamental design principles common among all roundabout types are presented first. More detailed design considerations spe- cific to multilane roundabouts, rural roundabouts, and mini-roundabouts are given in subsequent sections of the chapter. 6.1.1 Geometric elements Exhibit 6-1 provides a review of the basic geometric features and dimensions of a roundabout. Chapter 1 provided the definitions of these elements. 6.1.2 Design process Roundabout design is an The process of designing roundabouts, more so than other forms of intersections, iterative process. requires a considerable amount of iteration among geometric layout, operational analysis, and safety evaluation. As described in Chapters 4 and 5, minor adjust- ments in geometry can result in significant changes in the safety and/or opera- tional performance. Thus, the designer often needs to revise and refine the initial layout attempt to enhance its capacity and safety. It is rare to produce an optimal geometric design on the first attempt. Exhibit 6-2 provides a graphical flowchart for the process of designing and evaluating a roundabout. �� Federal HighwayAdministration a:.. :. Ciroulatory roadway width / ' � Exit width — width�re ��.;:. .. � _ �� b� O ��.�'00 � �,�' _ � . �� ,; , :...'.. .`, npProach Mndth Entry width Apron • • �� Splitter island r CeMral island � Entry radius / �.. , � .. .... - � � � � � y Identify �j v Roundabout a F As Potential Q rn Design Option � F- — — -��- — — — — — — — — — — — — — — — — — — — — — — — — — — — — ZEvaluate Z Appropriateness Z 4-.._ _�--_—.�-_ _----- y— — — — — � � � — � — — — — � Z p Preliminary Detailed H. Capacity perFormanceAnalysis a Anal sis ¢ W O. � - �� _ _ � � � �.. .. _ _ � � _ _ _ _ _ .. � � _ _ � _ ~ � Initial Adjustas Necessary � W Layout Adjustas Necessary O� W � _ _ �.. � _ _ � _ _ _ _ � � � � _ _ � � � PerformSafetyAudit � Check ReviewSafe Li h�t�ininanS�triping, Safety ofFinal � Landsca�ePlans LL Parameters P d GeometricPlan � Z JQ �7 Signing, Adjustas Z w Striping,Lighting, Necessary ii o Landscapmg,an Constructior� Stagi� Roundabouts: An Informational Guide • 6: Geometric Design Exhibit 6-1. Basic geometric elements of a roundabout. Exhibit 6-2. Roundabout design process. Because roundabout design is such an iterative process, in which small changes in geometry can result in substantial changes to operational and safety performance, it may be advisable to prepare the initial layout drawings at a sketch level of detail. Although it is easy to get caught into the desire to design each of the individual components of the geometry such that it complies with the specifications pro- vided in this chapter, it is much more important that the individual components are compatible with each other so that the roundabout will meet its overall perfor- mance objectives. Before the details of the geometry are defined, three funda- mental elements must be determined in the preliminary design stage: 1.The optimal roundabout size; 2. The optimal position; and 3.The optimal alignment and arrangement of approach legs. This section describes the fundamental design principles common among all cat- egories of roundabouts. Guidelines for the design of each geometric element are provided in the following section. Further guidelines specific to double-lane round- abouts, rural roundabouts, and mini-roundabouts are given in subsequent sections. Note that double-lane roundabout design is significantly different from single-lane roundabout design, and many of the techniques used in single-lane roundabout design do not directly transfer to double-lane design. The most critical design objective Because it has profound impacts on safety, achieving appropriate vehicular speeds is achieving appropriate vehicular through the roundabout is the most critical design objective. A well-designed round- speeds through the roundabout. about reduces the relative speeds between conflicting traffic streams by requiring vehicles to negotiate the roundabout along a curved path. 6.2.1.1 Speed profiles Exhibit 6-3 shows the operating speeds of typical vehicles approaching and nego- tiating a roundabout. Approach speeds of 40, 55, and 70 km/h (25, 35, and 45 mph, respectively) about 100 m(325 ft) from the center of the roundabout are shown. Deceleration begins before this time, with circulating drivers operating at approxi- mately the same speed on the roundabout.The relatively uniform negotiation speed of all drivers on the roundabout means that drivers are able to more easily choose their desired paths in a safe and efficient manner. 6.2.1.2 Design speed Increasing vehicle path International studies have shown that increasing the vehicle path curvature de- curvature decreases relative creases the relative speed between entering and circulating vehicles and thus usu- speeds between entering and ally results in decreases in the entering-circulating and exiting-circulating vehicle circulating vehicles, but also crash rates. However, at multilane roundabouts, increasing vehicle path curvature increases side friction between creates greater side friction between adjacent traffic streams and can result in adjacent traffic streams in more vehicles cutting across lanes and higher potential for sideswipe crashes (2). multilane roundabouts. Thus, for each roundabout, there exists an optimum design speed to minimize crashes. �� I Federal HighwayAdministration Recommended maximum entry design speeds for roundabouts at various inter- section site categories are provided in Exhibit 6-4. Exhibit 6-3. Sample theoretical speed profile (urban compact roundabout). Exhibit 6-4. Recommended Recommended Maximum maximum entry design speeds. Site Category Entry Design Speed Mini-Roundabout 25 km/h (15 mph) Urban Compact 25 km/h (15 mph) Urban Single Lane 35 km/h (20 mph) Urban Double Lane 40 km/h (25 mph) Rural Single Lane 40 km/h (25 mph) Rural Double Lane 50 km/h (30 mph) Roundabouts: An Informational Guide • 6: Geometric Design I��; 6.2.1.3 Uehicle paihs Roundabout speed is deter- To determine the speed of a roundabout, the fastest path allowed by the geometry mined by the fastest path is drawn. This is the smoothest, flattest path possible for a single vehicle, in the allowed by the geometry. absence of other traffic and ignoring all lane markings, traversing through the en- try, around the central island, and out the exit. Usually the fastest possible path is the through movement, but in some cases it may be a right turn movement. A vehicle is assumed to be 2 m(6 ft) wide and to maintain a minimum clearance of 0.5 m(2 ft) from a roadway centerline or concrete curb and flush with a painted edge line (2). Thus the centerline of the vehicle path is drawn with the following distances to the particular geometric features: • 1.5 m(5 ft) from a concrete curb, • 1.5 m(5 ftl from a roadway centerline, and • 1.0 m(3 ft) from a painted edge line. Through movements are usually Exhibits 6-5 and 6-6 illustrate the construction of the fastest vehicle paths at a the fastest path, but sometimes single-lane roundabout and at a double-lane roundabout, respectively. Exhibit 6-7 right turn paths are more provides an example of an approach at which the right-turn path is more critical critical. than the through movement. Exhibit 6-5. Fastest vehicle path through single-lane roundabout. I Federal HighwayAdministration ,� � � , � , � � � _ � , � � E � o ` � F � x � E N \ � � � ��, � i' i il i i i � � � E � o ` � F h / i' � i i i i i i � � --------- C � 3 '� � � � u� � /,� � � � — � 1.Om(3 Roundabouts: An Informational Guide • 6: Geometric Design Exhibit 6-6. Fastest vehicle path through double-lane roundabout. Exhibit 6-7. Example of critical right-turn movement. ��;: As shown in Exhibits 6-5 and 6-6, the fastest path for the through movement is a series of reverse curves (i.e., a curve to the right, followed by a curve to the left, followed by a curve to the right). When drawing the path, a short length of tangent should be drawn between consecutive curves to account for the time it takes for a driver to turn the steering wheel. It may be initially better to draw the path free- hand, rather than using drafting templates or a computer-aided design (CAD) pro- gram. The freehand technique may provide a more natural representation of the way a driver negotiates the roundabout, with smooth transitions connecting curves and tangents. Having sketched the fastest path, the designer can then measure the minimum radii using suitable curve templates or by replicating the path in CAD and using it to determine the radii. The entry path radius should The design speed of the roundabout is determined from the smallest radius along not be significantly larger than the fastest allowable path. The smallest radius usually occurs on the circulatory the circulatory radius. roadway as the vehicle curves to the left around the central island. However, it is important when designing the roundabout geometry that the radius of the entry path (i.e., as the vehicle curves to the right through entry geometry) not be signifi- cantly larger than the circulatory path radius. Draw the fastest path for all The fastest path should be drawn for all approaches of the roundabout. Because roundabout approaches. the construction of the fastest path is a subjective process requiring a certain amount of personal judgment, it may be advisable to obtain a second opinion. 6.2.1.4 Speed-curve relationship The relationship between travel speed and horizontal curvature is documented in the American Association of State Highway andTransportation Officials' document, A Policy on Geometric Design of Highways and Streets, commonly known as the Green Book (4�. Equation 6-1 can be used to calculate the design speed for a given travel path radius. V= 127R(e+f) (6-1a, metric) where: V= Design speed, km/h R = Radius, m e = superelevation, m/m f = side friction factor V= 15R(e+f) (6-1b, U.S. customary) where: V= Design speed, mph R = Radius, ft e = superelevation, ft/ft f = side friction factor Superelevation values are usually assumed to be +0.02 for entry and exit curves and -0.02 for curves around the central island. For more details related to superelevation design, see Section 6.3.11. Values for side friction factor can be determined in accordance with the AASHTO relation for curves at intersections (see 1994 AASHTO Figure III-19 (4)). The coeffi- cient of friction between a vehicle's tires and the pavement varies with the vehicle's speed, as shown in Exhibits 6-8 and 6-9 for metric and U.S. customary units, respectively. ��;: I Federal HighwayAdministration a.so 0.50 0 0.40 U N LL C � 0.30 U ll N � 0.2� � 0.10 0.00 70 o.so 0.50 0 0.40 �i m � c � 0.30 .� 'C LL N 9 0.2� N 0.10 0.00 5 20 30 40 50 60 Speed (km/h) 10 15 20 25 30 35 40 Speed (mph) Exhibit 6-8. Side friction factors at various speeds (metric units►. Exhibit 6-9. Side friction factors at various speeds (U.S. customary unitsl. Roundabouts: An Informational Guide • 6: Geometric Design I�t�'� Exhibit 6-70. Speed-radius relationship (metric units). Exhibit 6-11. Speed-radius relationship (U.S. customary units.) Using the appropriate friction factors corresponding to each speed, Exhibits 6-10 and 6-11 present charts in metric and U.S. customary units, respectively, showing the speed-radius relationship for curves for both a+0.02 superelevation and -0.02 superelevation. so 50 40 t E � 30 � d m a N 20 10 ao 35 30 L 25 a E 9 20 d w a y 15 10 5 0 0 20 40 60 80 100 120 Radius (m) -e=+0.02 - - e=-0.02 0 0 50 100 150 200 250 300 350 400 Radius (ft) - e=+0.02 - - e=-0.02 �;�g3 I Federal HighwayAdministration 6.2.1.5 Speed consistency In addition to achieving an appropriate design speed for the fastest movements, another important objective is to achieve consistent speeds for all movements. Along with overall reductions in speed, speed consistency can help to minimize the crash rate and severity between conflicting streams of vehicles. It also sim- plifies the task of inerging into the conflicting traffic stream, minimizing critical gaps, thus optimizing entry capacity.This principle has two implications: The relative speeds between consecutive geometric elements should be minimized; and 2. The relative speeds between conflicting traffic streams should be minimized. As shown in Exhibit 6-12, five critical path radii must be checked for each ap- proach. R,, the entry path radius, is the minimum radius on the fastest through path prior to the yield line. RZ, the circulating path radius, is the minimum radius on the fastest through path around the central island. R3, the exii path radius, is the minimum radius on the fastest through path into the exit. R4, the left-turn path radius, is the minimum radius on the path of the conflicting left-turn move- ment. R5, the right-turn path radius, is the minimum radius on the fastest path of a right-turning vehicle. It is important to note that these vehicular path radii are not the same as the curb radii. First the basic curb geometry is laid out, and then the vehicle paths are drawn in accordance with the procedures described in Sec- tion 6.2.1.3. Roundabouts: An Informationai Guide • 6: Geometric Design Exhibit 6-12. Vehicle path radii. ,;�:�i On the fastest path, it is desirable for R� to be smaller than Rz, which in turn should be smaller than R3.This ensures that speeds will be reduced to their lowest level at the roundabout entry and will thereby reduce the likelihood of loss-of-control crashes. It also helps to reduce the speed differential between entering and circulating traf- fic, thereby reducing the entering-circulating vehicle crash rate. However, in some cases it may not be possible to achieve an R� value less than RZ within given right- of-way or topographic constraints. In such cases, it is acceptable for R� to be greater than Rz, provided the relative difference in speeds is less than 20 km/h (12 mphl and preferably less than 10 km/h (6 mph). The natural path of a vehicle is At single-lane roundabouts, it is relatively simple to reduce the value of R� . The the path that a driver would curb radius at the entry can be reduced or the alignment of the approach can be take in the absence of other shifted further to the left to achieve a slower entry speed (with the potential for conflicting vehicles. higher exit speeds that may put pedestrians at risk). However, at double-lane round- abouts, it is generally more difficult as overly small entry curves can cause the natural path of adjacent traffic streams to overlap. Path overlap happens when the geometry leads a vehicle in the left approach lane to naturally sweep across the right approach lane just before the approach line to avoid the central island. It may also happen within the circulatory roadway when a vehicle entering from the right- hand lane naturally cuts across the left side of the circulatory roadway close to the central island. When path overlap occurs at double-lane roundabouts, it may re- duce capacity and increase crash risk.Therefore, care must be taken when design- ing double-lane roundabouts to achieve ideal values for R�, RZ, and R3. Section 6.4 provides further guidance on eliminating path overlap at double-lane roundabouts. The exit radius, R3, should not be less than R� or RZ in order to minimize loss-of- control crashes. At single-lane roundabouts with pedestrian activity, exit radii may still be small (the same or slightly larger than RZ) in order to minimize exit speeds. However, at double-lane roundabouts, additional care must be taken to minimize the likelihood of exiting path overlap. Exit path overlap can occur at the exit when a vehicle on the left side of the circulatory roadway (next to the central island) exits into the right-hand exit lane. Where no pedestrians are expected, the exit radii should be just large enough to minimize the likelihood of exiting path overlap. Where pedestrians are present, tighter exit curvature may be necessary to ensure suffi- ciently low speeds at the downstream pedestrian crossing. The radius of the conflicting left-turn movement, R4, must be evaluated in order to ensure that the maximum speed differential between entering and circulating traf- fic is no more than 20 km/h (12 mph).The left-turn movement is the critical traffic stream because it has the lowest circulating speed. Large differentials between entry and circulating speeds may result in an increase in single-vehicle crashes due to loss of control. Generally, RQ can be determined by adding 1.5 m(5 ft) to the central island radius. Based on this assumption, Exhibits 6-13 and 6-14 show ap- proximate R4 values and corresponding maximum R� values for various inscribed circle diameters in metric and U.S. customary units, respectively. 1+�1 I Federal HighwayAdministration Finally, the radius of the fastest possible right-turn path, R5, is evaluated. Like R�, the right-turn radius should have a design speed at or below the maximum design speed of the roundabout and no more than 20 km/h (12 mph) above the conflicting RQ design speed. Inscribed Circle Diameter (m) Single-Lane Roundabout 30 35 40 45 Double-Lane Roundabout 45 50 55 60 65 70 Inscribed Circle - Diameter (m) Single-Lane Roundabout 100 115 130 150 Double-Lane Roundabout 150 165 180 zoo 215 230 Approximate R4Value Maximum R�Value Radius Speed Radius Speed (m) (km/h) (m) (km/h) � m m m , m m � � � � 21 23 25 26 24 25 27 28 29 30 54 61 69 73 65 69 78 83 88 93 41 43 45 46 44 45 47 48 49 50 Approximate R4Value Maximum R�Value Radius Speed Radius Speed (ft) (mph) (ft) (mph) 35 45 55 65 50 60 65 75 85 90 � m m m 1 m m � m � � 165 185 205 225 205 225 225 250 275 275 25 26 27 28 27 28 28 29 30 30 Exhibit 6-13. Approximated RQ values and corresponding R� values �metric units�. Exhibit 6-14. Approximated RQ values and corresponding R� values (U.S. customary units). Roundabouts: An Informational Guide • 6: Geometric Design I 1�L1' 6.2.2 Design vehicle The design vehicle dictates many Another important factor determining a roundabout's layout is the need to ac- of the roundabouts dimensions. commodate the largest motorized vehicle likely to use the intersection.The turn- ing path requirements of this vehicle, termed hereafter the design vehicle, will dictate many of the roundabout's dimensions. Before beginning the design pro- cess, the designer must be conscious of the design vehicle and possess the appropriate vehicle turning templates or a CAD-based vehicle turning path pro- gram to determine the vehicle's swept path. The choice of design vehicle will vary depending upon the approaching roadway types and the surrounding land use characteristics.The local or State agency with jurisdiction of the associated roadways should usually be consulted to identify the design vehicle at each site. The AASHTO A Policy on Geometric Design of Highways and Streets provides the dimensions and turning path requirements for a variety of common highway vehicles (4). Commonly, WB-15 (WB-50) ve- hicles are the largest vehicles along collectors and arterials. Larger trucks, such as WB-20 (WB-67) vehicles, may need to be addressed at intersections on inter- state freeways or State highway systems. Smaller design vehicles may often be chosen for local street intersections. In general, larger roundabouts need to be used to accommodate large vehicles while maintaining low speeds for passenger vehicles. However, in some cases, land constraints may limit the ability to accommodate large semi-trailer combina- tions while achieving adequate deflection for small vehicles. At such times, a truck apron may be used to provide additional traversable area around the central island for large semi-trailers.Truck aprons, though, provide a lower level of opera- tion than standard nonmountable islands and should be used only when there is no other means of providing adequate deflection while accommodating the de- sign vehicle. Exhibits 6-15 and 6-16 demonstrate the use of a CAD-based computer program to determine the vehicle's swept path through the critical turning movements. 1A$r I Federal HighwayAdministration Exhibit 6-75. Through- movement swept path of WB-15 (WB-50) vehicle. Exhibit 6-16. Left-turn and right-turn swept paths of WB-15 (WB-50) vehicle. Roundabouts: An Informational Guide • 6: Geometric Design � i�i�f 6.2.3 Nonmotorized design users Like the motorized design vehicle, the design criteria of nonmotorized potential roundabout users (bicyclists, pedestrians, skaters, wheelchair users, strollers, etc.) should be considered when developing many of the geometric elements of a round- about design.These users span a wide range of ages and abilities that can have a significant effect on the design of a facility. The basic design dimensions for various design users are given in Exhibit 6-17 (5). Exhibit 6-77. Key dimensions of nonmotorized design users. User Bicycles Length Minimum operating width Dimension Affected Rou�dabout Features 1.8 m(5.9 ft) Splitter island width at crosswalk 1.5 m(4.9 ft) Bike lane width Lateral clearance on each side 0.6 m(2.0 ft) Pedestrian (walking) Width Wheelchair Minimum width Operating width Person pushing stroller Length Skaters Typical operating width Source: (5) 1.0 m (3.3 ft) to obstructions 0.5 m (1.6 ft) Shared bicycle-pedestrian path width Sidewalk width, crosswalk width 0.75 m(2.5 ft) Sidewalk width, crosswalk width 0.90 m(3.0 ft) Sidewalk width, crosswalk width 1.70 m(5.6 ft) Splitter island width at crosswalk 1.8 m(6 ft) Sidewalk width 6.2.4 Alignment of approaches and entries Roundabouts are optimally located In general, the roundabout is optimally located when the centerlines of all approach when all approach centerlines legs pass through the center of the inscribed circle.This location usually allows the pass through the center of the geometry to be adequately designed so that vehicles will maintain slow speeds inscribed circle. through both the entries and the exits. The radial alignment also makes the central island more conspicuous to approaching drivers. If it is not possible to align the legs through the center point, a slight offset to the left (i.e., the centerline passes to the left of the roundabout's center point) is ac- ceptable. This alignment will still allow sufficient curvature to be achieved at the entry, which is of supreme importance. In some cases (particularly when the in- scribed circle is relatively small►, it may be beneficial to introduce a slight offset of the approaches to the left in order to enhance the entry curvature. However, care must be taken to ensure that such an approach offset does not produce an exces- sively tangential exit. Especially in urban environments, it is important that the exit �A�; I Federal HighwayAdministration geometry produce a sufficiently curved exit path in order to keep vehicle speeds low and reduce the risk for pedestrians. It is almost never acceptable for an approach alignment to be offset to the right of the roundabout's center point. This alignment brings the approach in at a more tangential angle and reduces the opportunity to provide sufficient entry curvature. Vehicles will be able to enter the roundabout too fast, resulting in more loss-of- control crashes and higher crash rates between entering and circulating vehicles. Exhibit 6-18 illustrates the preferred radial alignment of entries. In addition, it is desirable to equally space the angles between entries. This pro- vides optimal separation between successive entries and exits. This results in op- timal angles of 90 degrees for four-leg roundabouts, 72 degrees for five-leg round- abouts, and so on. This is consistent with findings of the British accident prediction models described in Chapter 5. Aiignment Offset Left � + � Approech Centerline \ \ ACCEPTABLE Radiai Alignment Alignment Offset Right � + + i i Approach Centerline /� ApproechCerMerline PREFERRED UNACCEPTABLE This section presents specific parameters and guidelines for the design of each geometric element of a roundabout. The designer must keep in mind, however, that these components are not independent of each other.The interaction between the components of the geometry is far more important than the individual pieces. Care must be taken to ensure that the geometric elements are all compatible with each other so that the overall safety and capacity objectives are met. The inscribed circle diameter is the distance across the circle inscribed by the outer curb (or edge) of the circulatory roadway. As illustrated in Exhibit 6-1, it is the sum of the central island diameter (which includes the apron, if present) and twice the circulatory roadway. The inscribed circle diameter is determined by a number of design objectives.The designer often has to experiment with varying diameters before determining the optimal size at a given location. Roundabouts: An Informational Guide • 6: Geometric Design Approach alignment should not be offset to the right of the roundabouYs center point. Exhibit 6-78. Radial alignment of entries. ��ss' For a single-lane roundabout, At single-lane roundabouts, the size of the inscribed circle is largely dependent the minimum inscribed circle upon the turning requirements of the design vehicle. The diameter must be large diameter is 30 m(10o ft) to enough to accommodate the design vehicle while maintaining adequate deflection accommodate a WB-15 (WB-5o) curvature to ensure safe travel speeds for smaller vehicles. However, the circula- vehicle. tory roadway width, entry and exit widths, entry and exit radii, and entry and exit angles also play a significant role in accommodating the design vehicle and provid- ing deflection. Careful selection of these geometric elements may allow a smaller inscribed circle diameter to be used in constrained locations. In general, the in- scribed circle diameter should be a minimum of 30 m(100 ft) to accommodate a WB-15 (WB-50) design vehicle. Smaller roundabouts can be used for some local street or collector street intersections, where the design vehicle may be a bus or single-unit truck. For a double-lane roundabout, At double-lane roundabouts, accommodating the design vehicle is usually not a the minimum inscribed circle constraint. The size of the roundabout is usually determined either by the need to diamter is 45 m(75o ft). achieve deflection or by the need to fit the entries and exits around the circumfer- ence with reasonable entry and exit radii between them. Generally, the inscribed circle diameter of a double-lane roundabout should be a minimum of 45 m(150 ft). In general, smaller inscribed diameters are better for overall safety because they help to maintain lower speeds. In high-speed environments, however, the design of the approach geometry is more critical than in low-speed environments. Larger inscribed diameters generally allow for the provision of better approach geometry, which leads to a decrease in vehicle approach speeds. Larger inscribed diameters also reduce the angle formed between entering and circulating vehicle paths, thereby reducing the relative speed between these vehicles and leading to reduced enter- ing-circulating crash rates (2).Therefore, roundabouts in high-speed environments may require diameters that are somewhat larger than those recommended for low-speed environments. Very large diameters (greater than 60 m[200 ft]), how- ever, should generally not be used because they will have high circulating speeds and more crashes with greater severity. Exhibit 6-19 provides recommended ranges of inscribed circle diameters for various site locations. Exhibit 6-19. Recommended inscribed circle diameter ranges. Site Category Mini-Roundabout Urban Compact Urban Single Lane Urban Double Lane Rural Single Lane Rural Double Lane Typical Design Vehicle Single-UnitTruck Single-Unit Truck/Bus WB-15 (WB-50) WB-15 (WB-50) WB-20 (WB-67) WB-20 (WB-67) * Assumes 90-degree angles between entries and no more than four legs. Inscribed Circle Diameter Range" 13-25m (45-80 ft) 25-30m (80-100 ft) 30-40m (100-130 ft) 45-55m (150-180 ft) 35-40m (115-130 ft) 55-60m (180-200 ft) � I Federal HighwayAdministration 6.3.2 Entry width Entry width is the largest determinant of a roundabout's capacity. The capacity of an approach is not dependent merely on the number of entering lanes, but on the total width of the entry. In other words, the entry capacity increases steadily with incremental increases to the entry width.Therefore, the basic sizes of entries and circulatory roadways are generally described in terms of widih, not number of lanes. Entries that are of sufficient width to accommodate multiple traffic streams (at least 6.0 m[20 ft]) are striped to designate separate lanes. However, the circu- latory roadway is usually not striped, even when more than one lane of traffic is expected to circulate (for more details related to roadway markings, see Chapter 7). As shown in Exhibit 6-1, entry width is measured from the point where the yield line intersects the left edge of the traveled-way to the right edge of the traveled- way, along a line perpendicular to the right curb line. The width of each entry is dictated by the needs of the entering traffic stream. It is based on design traffic volumes and can be determined in terms of the number of entry lanes by using Chapter 4 of this guide. The circulatory roadway must be at least as wide as the widest entry and must maintain a constant width throughout. To maximize the roundabout's safety, entry widths should be kept to a minimum. The capacity requirements and performance objectives will dictate that each entry be a certain width, with a number of entry lanes. In addition, the turning require- ments of the design vehicle may require that the entry be wider still. However, larger entry and circulatory widths increase crash frequency. Therefore, determin- ing the entry width and circulatory roadway width involves a trade-off between capacity and safety.The design should provide the minimum width necessary for capacity and accommodation of the design vehicle in order to maintain the highest level of safety.Typical entry widths for single-lane entrances range from 4.3 to 4.9 m(14 to 16 ft); however, values higher or lower than this range may be required for site-specific design vehicle and speed requirements for critical vehicle paths. When the capacity requirements can only be met by increasing the entry width, this can be done in two ways: By adding a full lane upstream of the roundabout and maintaining parallel lanes through the entry geometry; or 2. By widening the approach gradually (flaring) through the entry geometry. Exhibit 6-20 and Exhibit 6-21 illustrate these two widening options. Entry width is the largest determinant of a roundabout's capacity. Entry widths should be kept to a minimum to maximize safety while achieving capacity and performance objectives. Roundabouts: An Informational Guide • 6: Geometric Design I 447 Exhibit 6-20. Approach widening by adding full lane. Exhibit 6-21. Approach widening by entry flaring. Flare lengths should be As discussed in Chapter 4, flaring is an effective means of increasing capacity at least 25 m in urban areas and without requiring as much right-of-way as a full lane addition. While increasing the 4o m in rural areas. length of flare increases capacity, it does not increase crash frequency. Conse- quently, the crash frequency for two approaches with the same entry width will be essentially the same, whether they have parallel entry lanes or flared entry de- signs. Entry widths should therefore be minimized and flare lengths maximized to achieve the desired capacity with minimal effect on crashes. Generally, flare lengths should be a minimum of 25 m(80 ft) in urban areas and 40 m(130 ft) in rural areas. However, if right-of-way is constrained, shorter lengths can be used with notice- able effects on capacity (see Chapter 4). I Federal HighwayAdministration ��. In some cases, a roundabout designed to accommodate design year traffic vol- umes, typically projected 20 years from the present, can result in substantially wider entries and circulatory roadway than needed in the earlier years of operation. Because safety will be significantly reduced by the increase in entry width, the designer may wish to consider a two-phase design solution. In this case, the first- phase design would provide the entry width requirements for near-term traffic vol- umes with the ability to easily expand the entries and circulatory roadway to ac- commodate future traffic volumes.The interim solution should be accomplished by first laying out the ultimate plan, then designing the first phase within the ultimate curb Iines.The interim roundabout is often constructed with the ultimate inscribed circle diameter, but with a larger central island and splitter islands. At the time additional capacity is needed, the splitter and central islands can be reduced in size to provide additional widths at the entries, exits, and circulatory roadway. 6.3.3 Circulatory roadway width The required width of the circulatory roadway is determined from the width of the entries and the turning requirements of the design vehicle. In general, it should always be at least as wide as the maximum entry width (up to 120 percent of the maximum entry width) and should remain constant throughout the roundabout (3►. 6.3.3.1 Single-lane roundabouts At single-lane roundabouts, the circulatory roadway should just accommodate the design vehicle. Appropriate vehicle-turning templates or a CAD-based computer program should be used to determine the swept path of the design vehicle through each of the turning movements. Usually the left-turn movement is the critical path for determining circulatory roadway width. In accordance with AASHTO policy, a minimum clearance of 0.6 m(2 ft) should be provided between the outside edge of the vehicle's tire track and the curb line. AASHTO Table III-19 (1994 edition) pro- vides derived widths required for various radii for each standard design vehicle. In some cases (particularly where the inscribed diameter is small or the design vehicle is large) the turning requirements of the design vehicle may dictate that the circulatory roadway be so wide that the amount of deflection necessary to slow passenger vehicles is compromised. In such cases, the circulatory roadway width can be reduced and a truck apron, placed behind a mountable curb on the central island, can be used to accommodate larger vehicles. However, truck aprons gener- ally provide a lower level of operation than standard nonmountable islands. They are sometimes driven over by four-wheel drive automobiles, may surprise inatten- tive motorcyclists, and can cause load shifting on trucks.They should, therefore, be used only when there is no other means of providing adequate deflection while accommodating the design vehicle. 6.3.3.2 Double-lane roundabouts At double-lane roundabouts, the circulatory roadway width is usually not governed by the design vehicle. The width required for one, two, or three vehicles, depend- ing on the number of lanes at the widest entry, to travel simultaneously through the roundabout should be used to establish the circulatory roadway width. The Roundabouts: An Informational Guide • 6: Geometric Design Two-phase designs allow for small initial entry widths that can be easily expanded in the future when needed to accommodate greater traffic volumes. Truck aprons generally provide a lower level of operations, but may be needed to provide adequate deflection while still accommodating the design vehicle. combination of vehicle types to be accommodated side-by-side is dependent upon the specific traffic conditions at each site. If the entering traffic is predominantly passenger cars and single-unit trucks (AASHTO P and SU vehicles), where semi- trailer traffic is infrequent, it may be appropriate to design the width for two pas- senger vehicles or a passenger car and a single-unit truck side-by-side. If semi- trailer traffic is relatively frequent (greater than 10 percent�, it may be necessary to provide sufficient width for the simultaneous passage of a semi-trailer in combina- tion with a P or SU vehicle. Exhibit 6-22 provides minimum recommended circulatory roadway widths for two- lane roundabouts where semi-trailer traffic is relatively infrequent. Exhibit 6-22. Minimum circulatory lane widths for �nscribed Circle two-lane roundabouts. Diameter 45 m (150 ft) 50 m (165 ft) 55 m (180 ft) 60 m (200 ft) 65 m (215 ft) 70 m (230 ft) Minimum Circulatory Lane Width" 9.8 m (32 ft) 9.3 m (31 ft) 9.1 m (30 ft) 9.1 m (30 ft) 8.7 m (29 ft) 8.7 m (29 ft) Central Island Diameter 25.4 m (86 ft) 31.4 m (103 ft) 36.8 m (120 ft) 41.8m(140ft) 4Z6 m (157 ft) 52.6 m (172 ft) * Based on 1994 AASHTOTable III-20, Case III(A) �4�. Assumes infrequent semi-trailer use (typically less than 5 percent of the total trafficl. Refer to AASHTO for cases with higher truck percentages. 6.3.4 Central island The central island of a roundabout is the raised, nontraversable area encompassed by the circulatory roadway; this area may also include a traversable apron. The island is typically landscaped for aesthetic reasons and to enhance driver recogni- tion of the roundabout upon approach. Central islands should always be raised, not depressed, as depressed islands are difficult for approaching drivers to recognize. In general, the central island should be circular in shape. A circular-shaped central island with a constant-radius circulatory roadway helps promote constant speeds around the central island. Oval or irregular shapes, on the other hand, are more difficult to drive and can promote higher speeds on the straight sections and re- duced speeds on the ares of the oval.This speed differential may make it harder for entering vehicles to judge the speed and acceptability of gaps in the circulatory traffic stream. It can also be deceptive to circulating drivers, leading to more loss- of-control crashes. Noncircular central islands have the above disadvantages to a rapidly increasing degree as they get larger because circulating speeds are higher. Oval shapes are generally not such a problem if they are relatively small and speeds are low. Raindrop-shaped islands may be used in areas where certain movements do not exist, such as interchanges (see Chapter 8), or at locations where certain turning movements cannot be safely accommodated, such as roundabouts with one approach on a relatively steep grade. �� I Federal HighwayAdministration As described in Section 6.2.1, the size of the central island plays a key role in determining the amount of deflection imposed on the through vehicle's path. How- ever, its diameter is entirely dependent upon the inscribed circle diameter and the required circulatory roadway width (see Sections 6.3.1 and 6.3.3, respectively). Therefore, once the inscribed diameter, circulatory roadway width, and initial entry geometry have been established, the fastest vehicle path must be drawn though the layout, as described in Section 6.2.1.3, to determine if the central island size is adequate. If the fastest path exceeds the design speed, the central island size may need to be increased, thus increasing the overall inscribed circle diameter. There may be other methods for increasing deflection without increasing the inscribed diameter, such as offsetting the approach alignment to the left, reducing the entry width, or reducing the entry radius.These treatments, however, may preclude the ability to accommodate the design vehicle. In cases where right-of-way, topography, or other constraints preclude the ability to expand the inscribed circle diameter, a mountable apron may be added to the outer edge of the central island. This provides additional paved area to allow the over-tracking of large semi-trailer vehicles on the central island without compro- mising the deflection for smaller vehicles. Exhibit 6-23 shows a typical central is- land with a traversable apron. Where aprons are used, they should be designed so that they are traversable by trucks, but discourage passenger vehicles from using them.They should generally be 1 to 4 m(3 to 13 ft) wide and have a cross slope of 3 to 4 percent away from the central island. To discourage use by passenger vehicles, the outer edge of the apron should be raised a minimum of 30 mm (1.2 in) above the circulatory road- way surface (6). The apron should be constructed of colored and/or textured paving Leeds, IV1D Exhibit 6-23. Example of central island with a traversable apron. Roundabouts: An Informational Guide • 6: Geometric Design � 151 materials to differentiate it from the circulatory roadway. Care must be taken to ensure that delivery trucks will not experience load shifting as their rear trailer wheels track across the apron. Issues regarding landscaping and other treatments within the central island are discussed in Chapter 7 In general, roundabouts in rural environments typically need larger central islands than urban roundabouts in order to enhance their visibility and to enable the design of better approach geometry (2). 6.3.5 Entry curves As shown in Exhibit 6-1, the entry curves are the set of one or more curves along the right curb (or edge of pavement) of the entry roadway leading into the circula- tory roadway. It should not be confused with the entry path curve, defined by the radius of the fastest vehicular travel path through the entry geometry (R� on Exhibit 6-12). The entry radius is an important factor in determining the operation of a round- about as it has significant impacts on both capacity and safety. The entry radius, in conjunction with the entry width, the circulatory roadway width, and the central island geometry, controls the amount of deflection imposed on a vehicle's entry path. Larger entry radii produce faster entry speeds and generally result in higher crash rates between entering and circulating vehicles. In contrast, the operational performance of roundabouts benefits from larger entry radii. As described in Chap- ter 4, British research has found that the capacity of an entry increases as its entry radius is increased (up to 20 m[65 ft1, beyond which entry radius has little effect on capacity. The entry curve is designed curvilinearly tangential to the outside edge of the circulatory roadway. Likewise, the projection of the inside (left) edge of the entry roadway should be curvilinearly tangential to the central island. Exhibit 6-24 shows a typical roundabout entrance geometry. The primary objective in selecting a radius for the entry curve is to achieve the speed objectives, as described in Section 6.2.1. The entry radius should first pro- duce an appropriate design speed on the fastest vehicular path. Second, it should desirably result in an entry path radius (R�) equal to or less than the circulating path radius (Rz) (see Section 6.2.1.5). 152 I Federal HighwayAdministration 6.3.5.1 Entry curves af sing/e-lane roundabouts For single-lane roundabouts, it is relatively simple to achieve the entry speed objectives. With a single traffic stream entering and circulating, there is no con- flict between traffic in adjacent lanes. Thus, the entry radius can be reduced or increased as necessary to produce the desired entry path radius. Provided suffi- cient clearance is given for the design vehicle, approaching vehicles will adjust their path accordingly and negotiate through the entry geometry into the circula- tory roadway. Entry radii at urban single-lane roundabouts typically range from 10 to 30 m(33 to 98 ft). Larger radii may be used, but it is important that the radii not be so large as to result in excessive entry speeds. At local street roundabouts, entry radii may be below 10 m(33 ft) if the design vehicle is small. At rural and suburban locations, consideration should be given to the speed dif- ferential between the approaches and entries. If the difference is greater than 20 km/h (12 mph), it is desirable to introduce approach curves or some other speed reduction measures to reduce the speed of approaching traffic prior to the entry curvature. Further details on rural roundabout design are provided in Section 6.5. 6.3.5.2 Entry curves at dou6/e-lane roundabouts At double-lane roundabouts, the design of the entry curvature is more compli- cated. Overly small entry radii can result in conflicts between adjacent traffic streams.This conflict usually results in poor lane utilization of one or more lanes and significantly reduces the capacity of the approach. It can also degrade the safety performance as sideswipe crashes may increase. Techniques and guide- lines for avoiding conflicts between adjacent entry lanes at double-lane round- abouts are provided in Section 6.4. Exhibit 6-24. Single-lane roundabout entry design. Roundabouts: An Informational Guide • 6: Geometric Design I�I�' Exhibit 6-25. Single-lane roundabout exit design. 6.3.6 Exit curves Exit curves usually have larger radii than entry curves to minimize the likelihood of congestion at the exits. This, however, is balanced by the need to maintain low speeds at the pedestrian crossing on exit. The exit curve should produce an exit path radius (R3 in Exhibit 6-12) no smaller than the circulating path radius (Rz). If the exit path radius is smaller than the circulating path radius, vehicles will be traveling too fast to negotiate the exit geometry and may crash into the splitter island or into oncoming traffic in the adjacent approach lane. Likewise, the exit path radius should not be significantly greater than the circulating path radius to ensure low speeds at the downstream pedestrian crossing. The exit curve is designed to be curvilinearly tangential to the outside edge of the circulatory roadway. Likewise, the projection of the inside (left) edge of the exit roadway should be curvilinearly tangential to the central island. Exhibit 6-25 shows a typical exit layout for a single-lane roundabout. !�4` Federal HighwayAdministration 6.3.6.1 Exit curves at sing/e-lane roundabouts At single-lane roundabouts in urban environments, exits should be designed to enforce a curved exit path with a design speed below 40 km/h (25 mph) in order to maximize safety for pedestrians crossing the exiting traffic stream. Generally, exit radii should be no less than 15 m(50 ft). However, at locations with pedes- trian activity and no large semi-trailer traffic, exit radii may be as low as 10 to 12 m (33 to 39 ftl. This produces a very slow design speed to maximize safety and comfort for pedestrians. Such low exit radii should only be used in conjunction with similar or smaller entry radii on urban compact roundabouts with inscribed circle diameters below 35 m(115 ft). In rural locations where there are few pedestrians, exit curvature may be de- signed with large radii, allowing vehicles to exit quickly and accelerate back to traveling speed. This, however, should not result in a straight path tangential to the central island because many locations that are rural today become urban in the future.Therefore, it is recommended that pedestrian activity be considered at all exits except where separate pedestrian facilities (paths, etc.) or other restric- tions eliminate the likelihood of pedestrian activity in the foreseeable future. 6.3.6.2 Exit curves at doub/e-lane roundabouts As with the entries, the design of the exit curvature at double-lane roundabouts is more complicated than at single-lane roundabouts.Techniques and guidelines for avoiding conflicts between adjacent exit lanes at double-lane roundabouts are provided in Section 6.4. 6.3.7 Pedestrian crossing location and treatments Pedestrian crossing locations at roundabouts are a balance among pedestrian convenience, pedestrian safety, and roundabout operations: Pedestrian convenience: Pedestrians want crossing locations as close to the intersection as possible to minimize out-of-direction travel.The further the cross- ing is from the roundabout, the more likely that pedestrians will choose a shorter route that may put them in greater danger. Pedestrian safety: Both crossing location and crossing distance are important. Crossing distance should be minimized to reduce exposure of pedestrian-ve- hicle conflicts. Pedestrian safety may also be compromised at a yield-line cross- walk because driver attention is directed to the left to look for gaps in the circulating traffic stream. Crosswalks should be located to take advantage of the splitter island; crosswalks located too far from the yield line require longer splitter islands. Crossings should also be located at distances away from the yield line measured in increments of approximate vehicle length to reduce the chance that vehicles will be queued across the crosswalk. Pedestrian crossing locations must balance pedestrian convenience, pedestrian safety, and roundabout operations. Roundabouts: An Informationai Guide • 6: Geometric Design I�g�; Roundabout operations: Roundabout operations (primarily vehicular) can also be affected by crosswalk locations, particularly on the exit. A queuing analysis at the exit crosswalk may determine that a crosswalk location of more than one vehicle length away may be required to reduce to an acceptable level the risk of queuing into the circulatory roadway. Pedestrians may be able to distinguish exiting vehicles from circulating vehicles (both visually and audibly) at crosswalk locations further away from the roundabout, although this has not been con- firmed by research. With these issues in mind, pedestrian crossings should be designed as follows: • The pedestrian refuge should be a minimum width of 1.8 m(6 ft) to adequately provide shelter for persons pushing a stroller or walking a bicycle (see Section 6.2.31. • At single-lane roundabouts, the pedestrian crossing should be located one ve- hicle-length (7.5 m[25 ft1) away from the yield line. At double-lane roundabouts, the pedestrian crossing should be located one, two, or three car lengths (ap- proximately 7.5 m, 15 m, or 22.5 m[25 ft, 50 ft, or 75 ft1) away from the yield line. • The pedestrian refuge should be designed at street level, rather than elevated to the height of the splitter island.This eliminates the need for ramps within the refuge area, which can be cumbersome for wheelchairs. • Ramps should be provided on each end of the crosswalk to connect the cross- walk to other crosswalks around the roundabout and to the sidewalk network. • It is recommended that a detectable warning surface, as recommended in the Americans with Disabilities Act Accessibility Guidelines (ADAAG) §4.29 (De- tectable Warnings), be applied to the surface of the refuge within the splitter Detectable warning surfaces island as shown in Exhibit 6-26. Note that the specific provision of the ADAAG should be applied within the requiring detectable warning surface at locations such as ramps and splitter pedestrian refuge. islands (defined in the ADAAG as "hazardous vehicle areas") has been sus- pended until July 26, 2001 (ADAAG §4.29.5). Where used, a detectable warning surface shall meet the following requirements (71: - The detectable warning surface shall consist of raised truncated domes with a nominal diameter of 23 mm (0.9 in), a nominal height of 5 mm (0.2 in), and a nominal center-to-center spacing of 60 mm (2.35 in). - The detectable warning surface shall contrast visually with adjoining sur- faces, either light-on-dark or dark-on-light. The material used to provide contrast shall be an integral part of the walking surface. The detectable warning surface shall begin at the curb line and extend into the pedestrian refuge area a distance of 600 mm (24 in).This creates a minimum 600-mm (24-in) clear space between detectable warning sur- faces for a minimum splitter island width of 1.8 m(6 ft) at the pedestrian crossing.This is a deviation from the requirements of (suspended) ADAAG §4.29.5, which requires a 915-mm (36-in) surface width. However, this deviation is necessary to enable visually impaired pedestrians to distin- guish the two interfaces with vehicular traffic. In urban areas, speed tables (flat-top road humps) could be considered for wheel- chair users, provided that good geometric design has reduced absolute vehicle ��; I Federal HighwayAdministration speeds to less than 20 km/h (12 mph) near the crossing. Pedestrian crossings across speed tables must have detectable warning material as described above to clearly delineate the edge of the street. Speed tables should generally be used only on streets with approach speeds of 55 km/h (35 mph) or less, as the introduc- tion of a raised speed table in higher speed environments may increase the likeli- hood of single-vehicle crashes and is not consistent with the speed consistency philosophy presented in this document. 6.3.8 Splitter islands Splitter islands (also called separator is/ands or median islands) should be provided on all roundabouts, except those with very small diameters at which the splitter island would obstruct the visibility of the central island.Their purpose is to provide shelter for pedestrians (including wheelchairs, bicycles, and baby strollers), assist in controlling speeds, guide traffic into the roundabout, physically separate enter- ing and exiting traffic streams, and deter wrong-way movements. Additionally, splitter islands can be used as a place for mounting signs (see Chapter 7). The splitter island envelope is formed by the entry and exit curves on a leg, as shown previously in Exhibits 6-24 and 6-25. The total length of the island should generally be at least 15 m(50 ft) to provide sufficient protection for pedestrians and to alert approaching drivers to the roundabout geometry. Additionally, the splitter island should extend beyond the end of the exit curve to prevent exiting traffic from accidentally crossing into the path of approaching traffic. Exhibit 6-26 shows the minimum dimensions for a splitter island at a single- lane roundabout, including the location of the pedestrian crossing as discussed in Section 6.3.7. � f i � � � � � � � � � i i � � // �` i � � i (`rl,•,•/ .� 7.5m (25ft) I � 15.Om (50ft) 3.Om (10ft) 4. m (15ft) I I I�- See Detail "A' i Detectable warning I surface DETAIL "A" Roundabouts: An Informatio�al Guide • 6: Geometric Design mm (2q in) n (6 ft) nin. Splitter islands perform multiple functions and should generally be provided. Exhibit 6-26. Minimum splitter island dimensions. �e�� Larger splitter islands enhance While Exhibit 6-26 provides minimum dimensions for splitter islands, there are safety, but require that the benefits to providing larger islands. Increasing the splitter island width results in inscribed circie diameter be greater separation between the entering and exiting traffic streams of the same increased. leg and increases the time for approaching drivers to distinguish between exiting and circulating vehicles. In this way, larger splitter islands can help reduce confu- sion for entering motorists. A recent study by the Queensland Department of Main Roads found that maximizing the width of splitter islands has a significant effect on minimizing entering/circulating vehicle crash rates (2). However, increasing the width of the splitter islands generally requires increasing the inscribed circle diameter. Thus, these safety benefits may be offset by higher construction cost and greater land impacts. Exhibit 6-27. Minimum splitter island nose radii and offsets. Standard AASHTO guidelines for island design should be followed for the splitter island. This includes using larger nose radii at approach corners to maximize island visibility and offsetting curb lines at the approach ends to create a funneling effect. The funneling treatment also aids in reducing speeds as vehicles approach the roundabout. Exhibit 6-27 shows minimum splitter island nose radii and offset di- mensions from the entry and exit traveled ways. � Offset 1.0 m(3 ft)—� r�set 0.5 m(1.5 ft)/ R=1.Om(3ft) Offset 1.0 m (3 down to 0.3 m (1 R=0.3m(1 ft) R=0.6m(2ft) / i i / R=0.3m(1ft) R=0.3m(tft) Offset 1.0 m (3 ft) down to 0.3 m(1 ft) "!l381 I Federal HighwayAdministration 6.3.9 Stopp�ng sight distance Stopping sight distance is the distance along a roadway required for a driver to perceive and react to an object in the roadway and to brake to a complete stop before reaching that object. Stopping sight distance should be provided at every point within a roundabout and on each entering and exiting approach. National Cooperative Highw a ces (8)rc e comme ds t eRormula g ve�nOn E�quat on nation of Stopping Sight Dist 6-2 for determining stopping sight distance (presented in metric units, followed by a conversion of the equation to U.S. customary units). 2 (6-2a, metric) d=10.278)lt)lV)+0.039 a where: d = stopping sight distance, m; t = perception-brake reaction time, assumed to be 2.5 s; �- initial speed, km/h; and a = driver deceleration, assumed to be 3.4 m/sz. z d=(1.468)Itl(V)+1.087 a where: d= stopping sight distance, ft; t - perception-brake reaction time, assumed to be 2.5 s; �- initial speed, mph; and a = driver deceleration, assumed to be 11.2 ft/sz. Exhibit 6-28 gives recommended stopping sight distances for design, as computed from the above equations. Sqeed (km/h) 10 20 30 40 50 60 70 80 90 100 Computed pistance" (m) ----- 8.1 18.----- ----- 31.2 ---- 462 63.------ ------ 83.0 104.-------- ------ 129.0 ____------- 155.5 ------ 184.2 * Sqeed (mph) 10 15 20 25 30 35 40 45 50 55 Comquted Distance" (ft) 46.4 77.0 112.4 152.7 1978 24Z8 302.7 362. 42Z2 496.7 Assumes 2.5 s perception-braking time, 3.4 m/s2 (11.2 ft/szl driver deceleration Roundabouts: An Informational Guide • 6: Geometric Design Exhibit 6-28• Design values for stopping sight distances. is39 At least three critical types of locations should be checked for stopping sight distance. Exhibit 6-29. Approach sight distance. Exhibit 6-30. Sight distance on circulatory roadway. Stopping sight distance should be measured using an assumed height of driver's eye of 1,080 mm (3.54 ft) and an assumed height of object of 600 mm (1.97 ft) in accordance with the recommendations to be adopted in the next AASHTO "Green Book" (8). At roundabouts, three critical types of locations should be checked at a minimum: � Approach sight distance (Exhibit 6-29); • Sight distance on circulatory roadway (Exhibit 6-301; and • Sight distance to crosswalk on exit (Exhibit 6-31). Forward sight distance at entry can also be checked; however, this will typically be satisfied by providing adequate stopping sight distance on the circulatory roadway itself. ., ' LE�END d DNtanca nlatad to�toppInp ; p�ht dl�tana u�d droulatory �� Federal HighwayAdministration 6.3.70 Intersection sight distance Intersection sight distance is the distance required for a driver without the right of way to perceive and react to the presence of conflicting vehicles. Intersection sight distance is achieved through the establishment of adequate sight lines that allow a driver to see and safely react to potentially conflicting vehicles. At roundabouts, the only locations requiring evaluation of intersection sight distance are the en- tries. Intersection sight distance is traditionally measured through the determination of a sight triangle.This triangle is bounded by a length of roadway defining a limit away from the intersection on each of the two conflicting approaches and by a line con- necting those two limits. For roundabouts, these "legs" should be assumed to follow the curvature of the roadway, and thus distances should be measured not as straight lines but as distances along the vehicular path. Intersection sight distance should be measured using an assumed height of driver's eye of 1,080 mm (3.54 ft) and an assumed height of object of 1,080 mm (3.54 ft) in accordance with the recommendations to be adopted in the next AASHTO "Green Book" (4). Exhibit 6-32 presents a diagram showing the method for determining intersection sight distance. As can be seen in the exhibit, the sight distance "triangle" has two conflicting approaches that must be checked independently. The following two subsections discuss the calculation of the length of each of the approaching sight limits. Exhibit 6-31. Sight distance to crosswalk on exit. Roundabout entries require adequate intersection sight distance. Roundabouts: An Informational Guide • 6: Geometric Design I#$!�_ Exhibit 6-32. Intersection sight distance LEOEND d, Enterinp strsam dlstence d, Ciroulatinp etnam diatence � � ' 6.3.10.1 Length of approach /eg of sight triang/e The length of the approach leg of the sight triangle should be limited to 15 m(49 ft). British research on sight distance determined that excessive intersection sight distance results in a higher frequency of crashes.This value, consistent with Brit- ish and French practice, is intended to require vehicles to slow down prior to entering the roundabout, which allows them to focus on the pedestrian crossing prior to entry. If the approach leg of the sight triangle is greater than 15 m(49 ft), it may be advisable to add landscaping to restrict sight distance to the minimum requirements. 6.3.10.2 Length of conflicting leg of sight triangle A vehicle approaching an entry to a roundabout faces conflicting vehicles within the circulatory roadway.The length of the conflicting leg is calculated using Equation 6-3: b = 0.278 (Vmalo� 1(t� ) where: b V ma/or r� b =1.4681 Vma;o, ) (t� ) where: b V ma�or t� (6-3a, metric) = length of conflicting leg of sight triangle, m = design speed of conflicting movement, km/h, discussed below = critical gap for entering the major road, s, equal to 6.5 s (6-3b, U.S. customary) = length of conflicting leg of sight triangle, ft = design speed of conflicting movement, mph, discussed below = critical gap for entering the major road, s, equal to 6.5 s Federal HighwayAdministration Two conflicting traffic streams should be checked at each entry: • Entering stream, comprised of vehicles from the immediate upstream entry. The speed for this movement can be approximated by taking the average of the entry path speed (path with radius R� from Exhibit 6-12) and the circulating path speed (path with radius RZ from Exhibit 6-12). • Circulaiing stream, comprised of vehicles that entered the roundabout prior to the immediate upstream entry. This speed can be approximated by taking the speed of left turning vehicles (path with radius Ra from Exhibit 6-12). The critical gap for entering the major road is based on the amount of time required for a vehicle to turn right while requiring the conflicting stream vehicle to slow no less than 70 percent of initial speed. This is based on research on critical gaps at stop-controlled intersections, adjusted for yield-controlled conditions (9). The criti- cal gap value of 6.5 s given in Equation 6-3 is based on the critical gap required for passenger cars, which are assumed to be the most critical design vehicle for inter- section sight distance. This assumption holds true for single-unit and combination truck speeds that are at least 10 km/h (6 mph) and 15 to 20 km/h (9 to 12 mph) slower than passenger cars, respectively. Conflicting Approach Speed Computed (km/h) Distance (m) f��] 25 30 35 40 36.1 45.2 54.2 63.2 72.3 Conflicting Approach Speed Computed (mph) Distance (ft) 10 95.4 15 143.0 20 190.1 25 30 238.6 286.3 In general, it is recommended to provide no more than the minimum required intersection sight distance on each approach. Excessive intersection sight distance can lead to higher vehicle speeds that reduce the safety of the intersection for all road users (vehicles, bicycles, pedestrians). Landscaping can be effective in re- stricting sight distance to the minimum requirements. Note that the stopping sight distance on the circulatory roadway (Exhibit 6-30) and the intersection sight distance to the circulating stream (Exhibit 6-32) imply restric- tions on the height of the central island, including landscaping and other objects, within these zones. In the remaining central area of the central island, higher land- scaping may serve to break the forward vista for through vehicles, thereby contrib- uting to speed reduction. However, should errant vehicles encroach on the central island, Chapter 7 provides recommended maximum grades on the central island to minimize the probability of the vehicles rolling over, causing serious injury. Roundabouts: An Informational Guide • 6: Geometric Design Exhibit 6-33. Computed length of conflicting leg of intersection sight triangle. Providing more than the minimum required intersection sight distance can lead to higher speeds that reduce intersection safety. �� 7 [ Exhibit 6-34. Sample plan view. 6.3.11 Vertical considerations Elements of vertical alignment design for roundabouts include profiles, superelevation, approach grades, and drainage. 6.3.11.1 Profiles The vertical design of a roundabout begins with the development of approach road- way and central island profiles. The development of each profile is an iterative pro- cess that involves tying the elevations of the approach roadway profiles into a smooth profile around the central island. Generally, each approach profile should be designed to the point where the ap- proach baseline intersects with the central island. A profile for the central island is then developed which passes through these four points (in the case of a four- legged roundabout).The approach roadway profiles are then readjusted as neces- sary to meet the central island profile. The shape of the central island profile is generally in the form of a sine curve. Examples of how the profile is developed can be found in Exhibits 6-34, 6-35, and 6-36, which consist of a sample plan, profiles on each approach, and a profile along the central island, respectively. Note that the four points where the approach roadway baseline intersects the central island baseline are identified on the central island profile. �� Federal HighwayAdministration Ciroulato Centrallsland Circulato Roadway-� i� �i �--Roadway Proposed Ground Existing L +2.00% -2.o0°/a� Ground Profile: A Street Proposed Ground Existing Ground r U i0 .30% � w Sag @ 3 � 3 Curve� � VeRical '� '�° WCurve V¢ Central Island V¢ � cL, Proposed B p Proposed y � Ground 1 Ground u'S 1 Y -o.sa°io I -o.3a°i -t.asio `° -1.45% � +0.52% -0.64% �- +2.00% -2.00% Profile: B Street OX See plan view for match point locations Existing Ground Exhibit 6-35. Sample approach profile. Exhibit 6-36. Sample central island profile. Roundabouts: An Informational Guide • 6: Geometric Design I{�jigi Negative superelevation (- 2%) should generally be used for the circulatory roadway. Exhibit 6-37. Typical circulatory roadway section. Exhibit 6-38. Typical section with a truck apron. 6.3.11.2 Superelevation As a general practice, a cross slope of 2 percent away from the central island should be used for the circulatory roadway. This technique of sloping outward is recommended for four main reasons: • It promotes safety by raising the elevation of the central island and improving its visibility; � It promotes lower circulating speeds; � It minimizes breaks in the cross slopes of the entrance and exit lanes; and • It helps drain surface water to the outside of the roundabout (2, 6). The outward cross slope design means vehicles making through and left-turn move- ments must negotiate the roundabout at negative superelevation. Excessive nega- tive superelevation can result in an increase in single-vehicle crashes and loss-of- load incidents for trucks, particularly if speeds are high. However, in the intersec- tion environment, drivers will generally expect to travel at slower speeds and will accept the higher side force caused by reasonable adverse superelevation (10). Exhibit 6-37 provides a typical section across the circulatory roadway of a round- about without a truck apron. Exhibit 6-38 provides a typical section for a round- about with a truck apron. Where truck aprons are used, the slope of the apron should be 3 to 4 percent; greater slopes may increase the likelihood of loss-of-load incidents. Central island area �— Mountable curb Barrier curb Normal pavement • slope -2�0 outward Central island area Mountable curb (optional) rConcrete truck apron slope �% to -4% outward Mountable curb Nortnal pavement • slope -2°k outward Bartier curb �'' I Federal HighwayAdministration 6.3.1L3 Locaiing roundabouts on grades It is generally not desirable to locate roundabouts in locations where grades through the intersection are greater than four percent. The installation of round- abouts on roadways with grades lower than three percent is generally not prob- lematic (6). At locations where a constant grade must be maintained through the intersection, the circulatory roadway may be constructed on a constant-slope plane. This means, for instance, that the cross slope may vary from +3 percent on the high side of the roundabout (sloped toward the central island) to -3 per- cent on the low side (sloped outward). Note that central island cross slopes will pass through level at a minimum of two locations for roundabouts constructed on a constant grade. Care must be taken when designing roundabouts on steep grades. On approach roadways with grades steeper than -4 percent, it is more difficult for entering drivers to slow or stop on the approach. At roundabouts on crest vertical curves with steep approaches, a driver's sight lines will be compromised, and the round- about may violate driver expectancy. However, under the same conditions, other types of at-grade intersections often will not provide better solutions. Therefore, the roundabout should not necessarily be eliminated from consideration at such a location. Rather, the intersection should be relocated or the vertical profile modi- fied, if possible. 6.3.11.4 Drainage With the circulatory roadway sloping away from the central island, inlets will generally be placed on the outer curbline of the roundabout. However, inlets may be required along the central island for a roundabout designed on a constant grade through an intersection. As with any intersection, care should be taken to ensure that low points and inlets are not placed in crosswalks. If the central island is large enough, the designer may consider placing inlets in the central island. 6.3.12 Bicycle provisions With regard to bicycle treatments, the designer should strive to provide bicy- clists the choice of proceeding through the roundabout as either a vehicle or a pedestrian. In general, bicyclists are better served by treating them as vehicles. However, the best design provides both options to allow cyclists of varying de- grees of skill to choose their more comfortable method of navigating the round- about. To accommodate bicyclists traveling as vehicles, bike lanes should be terminated in advance of the roundabout to encourage cyclists to mix with vehicle traffic. Under this treatment, it is recommended that bike lanes end 30 m(100 ft) up- stream of the yield line to allow for merging with vehicles (11). This method is most successful at smaller roundabouts with speeds below 30 km/h (20 mph), where bicycle speeds can more closely match vehicle speeds. To accommodate bicyclists who prefer not to use the circulatory roadway, a wid- ened sidewalk or a shared bicycle/pedestrian path may be provided physically separated from the circulatory roadway (not as a bike lane within the circulatory Roundabouts: An Informational Guide • 6: Geometric Design Avoid locating roundabouts in areas where grades through the intersection are greater than 4%. Terminate bicycle lanes prior to a roundabout. 1 �9' Ramps leading to a shared roadway). Ramps or other suitable connections can then be provided between this pathway can be used to sidewalk or path and the bike lanes, shoulders, or road surface on the approaching accommodate bicyclists and departing roadways. The designer should exercise care in locating and design- traveling as pedestrians. ing the bicycle ramps so that they are not misconstrued by pedestrians as an un- marked pedestrian crossing. Nor should the exits from the roadway onto a shared path allow cyclists to enter the shared path at excessive speeds. Exhibit 6-39 illus- trates a possible design of this treatment.The reader is encouraged to refer to the AASHTO Guide for Development of Bicycle Facilities (12) for a more detailed dis- cussion of the design requirements for bicycle and shared-use path design. Exhibit 6-39. Possible provisions for bicycles. Sidewalk Landscape strip Bike lane �'� Ramp up for bicycle Shared path Ramp down , . ; � for bicycle ' -^-�—..� , ., ; � � � -—�- � � . ; •.; •.•. •: a s< � 15 m(50 ft) 15 m(50 ft) taper min. Sidewalk or shared path ��:: � �� 1, 6.3.13 Sidewalk treatments Set badc sidewalks 1.5 m(5 ft) Where possible, sidewalks should be set back from the edge of the circulatory from the circulatory roadway roadway in order to discourage pedestrians from crossing to the central island, where possible. particularly when an apron is present or a monument on the central island. Equally important, the design should help pedestrians with visual impairments to recog- nize that they should not attempt to cross streets from corner to corner but at designated crossing points. To achieve these goals, the sidewalk should be de- signed so that pedestrians will be able to clearly find the intended path to the crosswalks. A recommended set back distance of 1.5 m(5 ft) (minimum 0.6 m[2 ft]) should be used, and the area between the sidewalk and curb can be planted with low shrubs or grass (see Chapter 7). Exhibit 6-40 shows this technique. ��! I Federal HighwayAdministration �— Landscape strip (1.5 m [5 (t] desired width) - (0.6 m [2 it] minimum width) �11 s .: • . • . ,..• � i .•:•��. i �' • a � Wider sidewalk to accommodate both bicycles and pedestrians (3 m [10 it] width) ADA-compliant remps 6.3.14 Parking considerations and bus stop locations Parking or stopping in the circulatory roadway is not conducive to proper round- about operations and should be prohibited. Parking on entries and exits should also be set back as far as possible so as not to hinder roundabout operations or to impair the visibility of pedestrians. AASHTO recommends that parking should end at least 6.1 m(20 ft) from the crosswalk of an intersection (4). Curb exten- sions or "bulb-outs" can be used to clearly mark the limit of permitted parking and reduce the width of the entries and exits. For safety and operational reasons, bus stops should be located as far away from entries and exits as possible, and never in the circulatory roadway. • Near-side stops: If a bus stop is to be provided on the near side of a round- about, it should be located far enough away from the splitter island so that a vehicle overtaking a stationary bus is in no danger of being forced into the splitter island, especially if the bus starts to pull away from the stop. If an approach has only one lane and capacity is not an issue on that entry, the bus stop could be located at the pedestrian crossing in the lane of traffic. This is not recommended for entries with more than one lane, because vehicles in the lane next to the bus may not see pedestrians. • Far-side stops: Bus stops on the far side of a roundabout should be constructed with pull-outs to minimize queuing into the roundabout. These stops should be located beyond the pedestrian crossing to improve visibility of pedestrians to other exiting vehicles. Roundabouts: An Informational Guide • 6: Geometric Design Exhibit 6-40. Sidewalk treatments. 46� 6.3.15 Right-turn bypass lanes Right-tum bypass lanes can be In general, right-turn bypass lanes (or right-turn slip lanes) should be avoided, espe- used in locations with minimal cially in urban areas with bicycle and pedestrian activity. The entries and exits of pedestrian and bicycle activity bypass lanes can increase conflicts with bicyclists.The generally higher speeds of to improve capacity when heavy bypass lanes and the lower expectation of drivers to stop increases the risk of right-turning traffic exists. collisions with pedestrians. However, in locations with minimal pedestrian and bi- cycle activity, right-turn bypass lanes can be used to improve capacity where there is heavy right turning traffic. Exhibit 6-47. Example of right-turn bypass lane. The provision of a right-turn bypass lane allows right-turning traffic to bypass the roundabout, providing additional capacity for the through and left-turn movements at the approach. They are most beneficial when the demand of an approach ex- ceeds its capacity and a significant proportion of the traffic is turning right. How- ever, it is important to consider the reversal of traffic patterns during the opposite peak time period. In some cases, the use of a right-turn bypass lane can avoid the need to build an additional entry lane and thus a larger roundabout.To determine if a right-turn bypass lane should be used, the capacity and delay calculations in Chapter 4 should be performed. Right-turn bypass lanes can also be used in loca- tions where the geometry for right turns is too tight to allow trucks to turn within the roundabout. Exhibit 6-41 shows an example of a right-turn bypass lane. 17�," I Federal HighwayAdministration There are two design options for right-turn bypass Ianes.The first option, shown in Exhibit 6-42, is to carry the bypass lane parallel to the adjacent exit roadway, and then merge it into the main exit lane. Under this option, the bypass lane should be carried alongside the main roadway for a sufficient distance to allow vehicles in the bypass lane and vehicles exiting the roundabout to accelerate to comparable speeds. The bypass lane is then merged at a taper rate according to AASHTO guidelines for the appropriate design speed. The second design option for a right-turn bypass lane, shown in Exhibit 6-43, is to provide a yield-controlled entrance onto the adja- cent exit roadway. The first option provides better operational performance than the second does. However, the second option generally requires less construction and right-of-way than the first. The option of providing yield control on a bypass lane is generally better for both bicyclists and pedestrians and is recommended as the preferred option in urban areas where pedestrians and bicyclists are prevalent. Acceleration lanes can be problematic for bicyclists because they end up being to the left of accelerating motor vehicles. In addition, yield control at the end of a bypass lane tends to slow motorists down, whereas an acceleration lane at the end of a bypass lane tends to promote higher speeds. The radius of the right-turn bypass lane should not be significantly larger than the radius of the fastest entry path provided at the roundabout.This will ensure vehicle speeds on the bypass lane are similar to speeds through the roundabout, resulting in safe merging of the two roadways. Providing a small radius also provides greater �__ ..,.a„�+.��.,� ��nr, must cross the right-turn slip lane. �aic�y �v� p,.,� �- — — _ Acceleration Taper length length based on AASHTO guidelines I Taper length based on local or state criteria (typically 40 to 90 m(130 to 300 ft]) Roundabouts: An Informational Guide • 6: Geometric Design Right-turn bypass lanes can merge back into the main exit roadway or provide a yield- controlled entrance onto the main exit roadway. Exhibit 6-42. Configuration of right-turn bypass lane with acceleration lane. �`J�; Exhibit 6-43. Configuration of right-turn bypass with yield at exit leg. 6.4 Double-Lane Roundabouts While the fundamental principles described above apply to double-lane roundabouts as well as single-lane roundabouts, designing the geometry of double-lane round- abouts is more complicated. Because multiple traffic streams may enter, circulate through, and exit the roundabout side-by-side, consideration must be given to how these adjacent traffic streams interact with each other. Vehicles in adjacent entry lanes must be able to negotiate the roundabout geometry without competing for the same space. Otherwise, operational and/or safety deficiencies can occur. 6.4.1 The natural vehicle path As discussed in Section 6.2.1, the fastest path through the roundabout is drawn to ensure the geometry imposes sufficient curvature to achieve a safe design speed. This path is drawn assuming the roundabout is vacant of all other traffic and the vehicle cuts across adjacent travel lanes, ignoring all lane markings. In addition to evaluating the fastest path, at double-lane roundabouts the designer must also evaluate the natura/ vehicle paths.This is the path an approaching vehicle will natu- rally take, assuming there is traffic in all approach lanes, through the roundabout geometry. �{�,�;; I Federal HighwayAdministration As two traffic streams approach the roundabout in adjacent lanes, they will be forced to stay in their lanes up to the yield line. At the yield point, vehicles will continue along their natural trajectory into the circulatory roadway, then curve around the central island, and curve again into the opposite exit roadway. The speed and orientation of the vehicle at the yield line determines its natural path. If the natural path of one lane interferes or overlaps with the natural path of the adjacent lane, the roundabout will not operate as safely or efficiently as possible. The key principle in drawing the natural path is to remember that drivers cannot change the direction of their vehicle instantaneously. Neither can they change their speed instantaneously. This means that the natural path does not have sudden changes in curvature; it has transitions between tangents and curves and between consecutive reversing curves. Secondly, it means that consecutive curves should be of similar radius. If a second curve has a significantly smaller radius than the first curve, the driver will be traveling too fast to negotiate the turn and may lose control of the vehicle. If the radius of one curve is drawn significantly smaller than the radius of the previous curve, the path should be adjusted. To identify the natural path of a given design, it may be advisable to sketch the natural paths over the geometric layout, rather than use a computer drafting program or manual drafting equipment. In sketching the path, the designer will naturally draw transitions between consecutive curves and tangents, similar to the way a driver would negotiate an automobile. Freehand sketching also enables the designer to feel how changes in one curve affect the radius and orientation of the next curve. In general, the sketch technique allows the designer to quickly obtain a smooth, natural path through the geometry that may be more difficult to obtain using a computer. Exhibit 6-44 illustrates a sketched natural path of a vehicle through a typical double- lane roundabout. Exhibit 6-44. Sketched natural paths through a double-lane roundabout. Roundabouts: An Informational Guide • 6: Geometric Design I�� Exhibit 6-45. Path overlap at a double-lane roundabout. �,i!A;i 6.4.2 Vehicle path overlap Vehicle path overlap occurs when the natural path through the roundabout of one traffic stream overlaps the path of another.This can happen to varying degrees. It can reduce capacity, as vehicles will avoid using one or more of the entry lanes. It can also create safety problems, as the potential for sideswipe and single-vehicle crashes is increased.The most common type of path overlap is where vehicles in the left lane on entry are cut off by vehicles in the right lane, as shown in Exhibit 6-45. 6.4.3 Design method to avoid path overiap Achieving a reasonably low design speed at a double-lane roundabout while avoid- ing vehicle path overlap can be difficult because of conflicting interaction between the various geometric parameters. Providing small entry radii can produce low en- try speeds, but often leads to path overlap on the entry, as vehicles will cut across lanes to avoid running into the central island. Likewise, providing small exit radii can aid in keeping circulating speeds low, but may result in path overlap at the exits. 6.4.3.1 Entry curves At double-lane entries, the designer needs to balance the need to control entry speed with the need to minimize path overlap. This can be done a variety of ways that will vary significantly depending on site-specific conditions, and it is thus inap- propriate to specify a single method for designing double-lane roundabouts. Re- gardless of the specific design method employed, the designer should maintain the overall design principles of speed control and speed consistency presented in Section 6.2. One method to avoid path overlap on entry is to start with an inner entry curve that is curvilinearly tangential to the central island and then draw parallel alignments to determine the position of the outside edge of each entry lane. These curves can range from 30 to 60 m(100 to 200 ft) in urban environments and 40 to 80 m(130 to 260 ft) in rural environments.These curves should extend approximately 30 m(100 Federal HighwayAdministration ft) to provide clear indication of the curvature to the driver. The designer should check the critical vehicle paths to ensure that speeds are sufficiently low and con- sistent between vehicle streams.The designer should also ensure that the portion of the splitter island in front of the crosswalk meets AASHTO recommendations for minimum size. Exhibit 6-46 demonstrates this method of design. Another method to reduce entry speeds and avoid path overlap is to use a small- radius (generally 15 to 30 m[50 to 100 ft]) curve approximately 10 to 15 m(30 to 50 ft) upstream of the yield line. A second, larger-radius curve (or even a tangent) is then fitted between the first curve and the edge of the circulatory roadway. In this way, vehicles will still be slowed by the small-radius approach curve, and they will be directed along a path that is tangential to the central island at the time they reach the yield line. Exhibit 6-47 demonstrates this alternate method of design. Exhibit 6-46. One method of entry design to avoid path overlap at double-lane roundabouts. Exhibit 6-47. Alternate method of entry design to avoid path overlap at double-lane roundabouts. d n� Roundabouts: An Informational Guide • 6: Geometric Design ��y. +,« As in the case of single-lane roundabouts, it is a primary objective to ensure that the entry path radius along the fastest path is not substantially larger than the circulating path radius. Referring to Exhibit 6-12, it is desirable for R, to be less than or approximately equal to RZ. At double-lane roundabouts, however, R, should not be excessively small. If R� is too small, vehicle path overlap may result, reducing the operational efficiency and increasing potential for crashes. Values for R, in the range of 40 to 70 m(130 to 230 ft) are generally preferable.This results in a design speed of 35 to 45 km/h (22 to 28 mph). The entry path radius, R, , is controlled by the offset between the right curb line on the entry roadway and the curb line of the central island (on the driver's left). If the initial layout produces an entry path radius above the preferred design speed, one way to reduce it is to gradually shift the approach to the left to increase the offset; however, this may increased adjacent exit speeds. Another method to reduce the entry path radius is to move the initial, small-radius entry curve closer to the circu- latory roadway.This will decrease the length of the second, larger-radius curve and increase the deflection for entering traffic. However, care must be taken to ensure this adjustment does not produce overlapping natural paths. 6.4.3.2 Exit curves To avoid path overlap on the exit, it is important that the exit radius at a double-lane roundabout not be too small. At single-lane roundabouts, it is acceptable to use a minimal exit radius in order to control exit speeds and maximize pedestrian safety. However, the same is not necessarily true at double-lane roundabouts. If the exit radius is too small, traffic on the inside of the circulatory roadway will tend to exit into the outside exit lane on a more comfortable turning radius. At double-lane roundabouts in urban environments, the principle for maximizing pedestrian safety is to reduce vehicle speeds prior to the yield and maintain similar (or slightly lower) speeds within the circulatory roadway. At the exit points, traffic will still be traveling slowly, as there is insufficient distance to accelerate signifi- cantly. If the entry and circulating path radii (R, and Rz, as shown on Exhibit 6-12) are each 50 m(165 ft), exit speeds will generally be below 40 km/h (25 mph) re- gardless of the exit radius. To achieve exit speeds slower than 40 km/h (25 mph), as is often desirable in envi- ronments with significant pedestrian activity, it may be necessary to tighten the exit radius. This may improve safety for pedestrians at the possible expense of increased vehicle-vehicle collisions. 6.5 Rural Roundabouts Roundabouts located on rural roads often have special design considerations be- cause approach speeds are higher than urban or local streets and drivers generally do not expect to encounter speed interruptions.The primary safety concern in rural locations is to make drivers aware of the roundabout with ample distance to com- fortably decelerate to the appropriate speed. This section provides design guide- lines for providing additional speed-reduction measures on rural roundabout ap- proaches. Federal HighwayAdministration 'i7e I 6.5.1 Visibility Perhaps the most important element affecting safety at rural intersections is the visibility of the intersection itself. Roundabouts are no different from stop-controlled or signalized intersections in this respect except for the presence of curbing along roadways that are typically not curbed. Therefore, although the number and sever- ity of multiple-vehicle collisions at roundabouts may decrease (as discussed previ- ously), the number of single-vehicle crashes may increase. This potential can be minimized with attention to proper visibility of the roundabout and its approaches. Where possible, the geometric alignment of approach roadways should be con- structed to maximize the visibility of the central island and the general shape of the roundabout. Where adequate visibility cannot be provided solely through geomet- ric alignment, additional treatments (signing, pavement markings, advanced warn- ing beacons, etc.) should be considered (see Chapter 7). Note that many of these treatments are similar to those that would be applied to rural stop-controlled or signalized intersections. 6.5.2 Curbing On an open rural highway, changes in the roadway's cross-section can be an effec- tive means to help approaching drivers recognize the need to reduce their speed. Rural highways typically have no outside curbs with wide paved or gravel shoul- ders. Narrow shoulder widths and curbs on the outside edges of pavement, on the other hand, generally give drivers a sense they are entering a more urbanized set- ting, causing them to naturally slow down. Thus, consideration should be given to reducing shoulder widths and introducing curbs when installing a roundabout on an open rural highway. Curbs help to improve delineation and to prevent "corner cutting;' which helps to ensure low speeds. In this way, curbs help to confine vehicles to the intended design path. The designer should carefully consider all likely design vehicles, in- cluding farm equipment, when setting curb locations. Little research has been per- formed to date regarding the length of curbing required in advance of a rural round- about. In general, it may be desirable to extend the curbing from the approach for at least the length of the required deceleration distance to the roundabout. 6.5.3 Splitter islands Another effective cross-section treatment to reduce approach speeds is to use longer splitter islands on the approaches (10). Splitter islands should generally be extended upstream of the yield bar to the point at which entering drivers are ex pected to begin decelerating comfortably. A minimum length of 60 m(200 ft) is recommended (10). Exhibit 6-48 provides a diagram of such a splitter island design. The length of the splitter island may differ depending upon the approach speed. The AASHTO recommendations for required braking distance with an alert driver should be applied to determine the ideal splitter island length for rural roundabout approaches. A further speed-reduction technique is the use of landscaping on the extended splitter island and roadside to create a"tunnel" effect. If such a technique is used, the stopping and intersection sight distance requirements (sections 6.3.9 and 6.3.10) will dictate the maximum extent of such landscaping. Roundabout visibility is a key design element at rural locations. Curbs should be provided at all rural roundabouts. Extended splitter islands are recommended at rural locations. Roundabouts: An Informational Guide • 6: Geometric Design I 1i7 Exhibit 6-48. Extended splitter island treatment. 6.5.4 Approach curves Roundabouts on high-speed roads (speeds of 80 km/h [50 mph] or higher), despite extra signing efforts, may not be expected by approaching drivers, resulting in er- ratic behavior and an increase in single-vehicle crashes. Good design encourages drivers to slow down before reaching the roundabout, and this can be most effec- tively achieved through a combination of geometric design and other design treat- ments (see Chapter 7). Where approach speeds are high, speed consistency on the approach needs to be addressed to avoid forcing all of the reduction in speed to be completed through the curvature at the roundabout. The radius of an approach curve (and subsequent vehicular speeds) has a direct impact on the frequency of crashes at a roundabout. A study in Queensland, Aus- tralia, has shown that decreasing the radius of an approach curve generally de- creases the approaching rear-end vehicle crash rate and the entering-circulating and exiting-circulating vehicle crash rates (see Chapter 5). On the other hand, de- creasing the radius of an approach curve may increase the single-vehicle crash rate on the curve, particularly when the required side-friction for the vehicle to maintain its path is too high. This may encourage drivers to cut across lanes and increase sideswipe crash rates on the approach curve (2). One method to achieve speed reduction that reduces crashes at the roundabout while minimizing single-vehicle crashes is the use of successive curves on ap- proaches.The study in Queensland, Australia, found that by limiting the change in 85th-percentile speed on successive geometric elements to 20 km/h (12 mph�, the crash rate was reduced. It was found that the use of successive reverse curves prior to the roundabout approach curve reduced the single-vehicle crash rate and the sideswipe crash rate on the approach. It is recommended that approach speeds immediately prior to the entry curves of the roundabout be limited to 60 km/h (37 mph) to minimize high-speed rear-end and entering-circulating vehicle crashes. ,r�� r� �+�� I Federal HighwayAdministration Exhibit 6-49 shows a typical rural roundabout design with a succession of three curves prior to the yield line. As shown in the exhibit, these approach curves should be successively smaller radii in order to minimize the reduction in design speed between successive curves. The aforementioned Queensland study found that shifting the approaching roadway laterally by 7 m(23 ft) usually enables adequate curvature to be obtained while keeping the curve lengths to a minimum. If the lateral shift is too small, drivers are more likely to cut into the adjacent lane (2). Equations 6-4 and 6-5 can be used to estimate the operating speed of two-lane rural roads as a function of degree of curvature. Equation 6-6 can be used similarly for four-lane rural roads (13). Two-lane rural roads: V85 =103.66 —1.95D, D >_ 3° V85=97.9,D<3° (6-4) (6-5) where: V85 = 85th-percentile speed, km/h (1 km/h = 0.621 mph); and D= degree of curvature, degrees = 1746.38 / R R= radius of curve, m Four-lane rural roads: V85 =103.66 —1.95 D .. where: V85 = 85th-percentile speed, km/h (1 km/h = 0.621 mph); and D= degree of curvature, degrees = 1746.38 / R R= radius of curve, m 6.6 Mini-Roundabouts As discussed in Chapter 1, a mini-roundabout is an intersection design alternative that can be used in place of stop control or signalization at physically constrained intersections to help improve safety problems and excessive delays at minor ap- proaches. Mini-roundabouts are not traffic calming devices but rather are a form of roundabout intersection. Exhibit 6-50 presents an example of a mini-roundabout. A series of progressively sharper curves on a high-speed roundabout approach helps slow traffic to an appropriate entry speed. Exhibit 6-49. Use of successive curves on high speed approaches. Mini-roundabouts are not recommended where approach speeds are greater than 50 km/h (30 mph►, nor in locations with high U-tuming volumes. Roundabouts: An Informational Guide • 6: Geometric Design I��! Exhibit 6-50. Example of a mini-roundabout. Mini-roundabouts should only be considered in areas where all approaching road- ways have an 85th-percentile speed of less than 50 km/h (30 mphl. In addition, mini-roundabouts are not recommended in locations in which high U-turn traffic is expected, such as at the ends of street segments with access restrictions. Mini- roundabouts are not well suited for high volumes of trucks, as trucks will occupy most of the intersection when turning. The central island of a The design of the central island of a mini-roundabout is defined primarily by the mini-roundabout should be requirement to achieve speed reduction for passenger cars. As discussed previ- clear and conspicuous. ously in Section 6.2, speed reduction for entering vehicles and speed consistency with circulating vehicles are important.Therefore, the location and size of the cen- tral island are dictated by the inside of the swept paths of passenger cars that is needed to achieve a maximum recommended entry speed of 25 km/h (15 mph). The central island of a mini-roundabout is typically a minimum of 4 m(13 ft) in diameter and is fully mountable by large trucks and buses. Composed of asphalt, concrete, or other paving material, the central island should be domed at a height of 25 to 30 mm per 1 m diameter (0.3 to 0.36 in per 1 ft diameter), with a maximum height of 125 mm (5 in) (14). Although fully mountable and relatively small, it is essential that the central island be clear and conspicuous (14, 151. Chapter 7 pro- vides a sample signing and striping planing plan for mini-roundabout. The outer swept path of passenger cars and large vehicles is typically used to define the location of the yield line and boundary of each splitter island with the circulatory roadway. Given the small size of a mini-roundabout, the outer swept path of large vehicles may not be coincident with the inscribed circle of the round- about, which is defined by the outer curbs. Therefore, the splitter islands and yield line may extend into the inscribed circle for some approach geometries. On the other hand, for very small mini-roundabouts, such as the one shown in Exhibit 6- 50, all turning trucks will pass directly over the central island while not encroaching on the circulating roadway to the left which may have opposing traffic. In these cases, the yield line and splitter island should be set coincident with the inscribed �� I Federal HighwayAdministration 6.7 References 1. Department ofTransport of Northrhine-Westfalia, Germany. Empfehlungen zum Einsatz und zur Gestaltung von Mini-Kreisverkehrsplaetzen (Guidelines for the Use and Design of Mini-Roundaboutsl. Dusseldorf, Germany, 1999. 2. Queensland Department of Main Roads (QDMR). Relationships between Round- about Geometry and Accident Rates. Queensland, Australia: Infrastructure De- sign of theTechnology Division of QDMR, April 1998. 3. Department ofTransport (United Kingdoml. Geometric Design of Roundabouts. TD 16/93. September 1993. 4. American Association of State Highway andTransportation Officials (AASHTO). A Policy on Geometric Design of Highways and Streets. Washington, D.C.: AASHTO, 1994. 5. Pein, W.E. Trail lntersection Design Guidelines. Prepared for State Bicycle/Pedes- trian Program, State Safety Office, Florida Department of Transportation. High- way Safety Research Center, University of North Carolina, September 1996. 6. Service d'EtudesTechniques des Routes et Autoroutes (SETRA-Center forTech- nical Studies of Roads and Highways). Amenagement des Carrefours Interurbains sur les Routes Principales (Design of Rural Intersections on Major Roads). Minis- try ofTransport and Housing, December 1998. 7. Americans with Disabilities Act Accessibility Guidelines for Buildings and Facili- ties (ADAAG). 36 CFR Part 1191. As amended through January 1998. 8. Fambro, D.B., et al. NCHRP Report 400: Determination of Stopping Sight Dis- tances. National Cooperative Highway Research Program,Transportation Research Board, National Research Council. Washington, D.C.: National Academy Press, 1997. 9. Harwood, D.W., et al. NCHRP Report 383: Interseciion Sight Distances. National Cooperative Highway Research Program,Transportation Research Board, National Research Council. Washington, D.C.: National Academy Press, 1996. 10. Austroads. Guide io Traffic Engineering Practice, Part 6-Roundabouts. Sydney, Australia: Austroads, 1993. 11. Florida Department ofTransportation. Florida Roundabout Guide. Florida Depart- ment ofTransportation, March 1996. 12. American Association of State Highway and Transportation Officials (AASHTO). Guide for Development of Bicycle Facilities. Washington, D.C.: AASHTO, 1991. 13. Krammes, R., et al. Horizontal Alignment Design Consistency for RuralTwo-Lane Highways. Publication No. FHWA-RD-94-034. Washington, D.C.: Federal High- way Administration, January 1995. 14. Sawers, C. Mini-roundabouts: Getting them right!. Canterbury, Kent, United King- dom: Euro-Marketing Communications, 1996. 15. Brilon, W., and L. Bondzio. Untersuchung von Mini-Kreisverkehrsplaetzen (Inves- tigation of Mini-Roundabouis). Ruhr-University Bochum, Germany, 1999. Roundabouts: An Informational Guide • 6: Geometric Design I t81 Traffic Design and Landscaping 7.1 Signing 7.1.1 Relationship with the Manual on Uniform Traffic Control Devices 7.1.2 Regulatory signs 7.1.3 Warning signs 7.1.4 Guide signs 7.1.5 Urban signing considerations 7.1.6 Rural and suburban signing considerations 7.1.7 Mini-roundabout signing considerations 7.2 Pavement Markings 7.2.1 Relationship with the Manual on Uniform Traffic Conirol Devices 7.2.2 Approach and entry pavement markings 7.2.3 Circulatory roadway pavement markings 7.2.4 Mini-roundabout pavement markings 7.3 Illumination 7.3.1 Need for illumination 7.3.2 Standards and recommended practices 7.3.3 General recommendations 7.3.4 Clear zone requirements 7.4 Work Zone Traffic Control 7.4.1 Pavement markings 7.4.2 Signing 7.4.3 Lighting Roundabouts: An InfoYmational Guide • 7:Traffic Design and Landscaping 185 185 186 188 191 192 194 195 197 197 197 200 201 202 202 203 204 205 205 205 205 206 1'83 7.4.4 Construction staging 7.4.5 Public education 7.5 Landscaping 7.5.1 Advantages 7.5.2 Central island landscaping 7.5.3 Splitter island and approach landscaping 7.5.4 Maintenance 7.6 References Exhibit 7-1. Exhibit 7-2. Exhibit 7-3. Exhibit 7-4. Exhibit 7-5 Exhibit 7-6. Exhibit 7-7. Exhibit 7-8. Exhibit 7-9. Exhibit 7-10. Exhibit 7-11. Exhibit 7-12. Exhibit 7-13. Exhibit 7-14. Exhibit 7-15. Exhibit 7-16. Exhibit 7-17. Exhibit 7-18. Exhibit 7-19. Exhibit 7-20. Exhibit 7-21. Exhibit 7-22. Exhibit 7-23. Exhibit 7-24. YIELD sign �R1-2). ONE WAY sign (R6-1 R). KEEP RIGHT sign (R4-7). Lane-use control signing for roundabouts with double-lane entries. Lane-use control signing for roundabouts with heavy turning traffic. Circular Intersection sign (W2-6). Advisory speed plate (W13-1�. Roundabout Ahead sign. YIELD AHEAD sign (W3-2a). Large Arrow sign (W1-6). Chevron plate (W1-8a). Pedestrian Crossing sign (W11-2a�. Examples of advance destination guide signs. Exit guide sign (D1-1 �. Sample signing plan for an urban roundabout. Sample signing plan for a rural roundabout. Examples of speed reduction treatments. Sample signing plan for a mini-roundabout. Examples of yield lines. Approach pavement markings. Sample pavement marking plan for a mini-roundabout. Illumination of a roundabout. Recommended street illumination levels. Landscaping of the central island. 206 207 207 207 208 208 209 209 .. :. .. � :• .• .. .� 190 190 191 192 193 194 195 196 198 199 201 202 204 208 �� I Federal HighwayAdministration Chapter 7 Traffic Design and Landscaping This chapter presents guidelines on the design of traffic elements, illumination, and landscaping associated with roundabouts. The design of these elements is critical in achieving the desired operational and safety features of a roundabout, as well as the desired visibility and aesthetics.This chapter is divided into the follow- ing sections: � Signing; • Pavement Markings; • Illumination; • Work ZoneTraffic Control; and • Landscaping. 7.1 Signing The overall concept for roundabout signing is similar to general intersection sign- ing. Proper regulatory control, advance warning, and directional guidance are re- quired to avoid driver expectancy related problems. Signs should be located where they have maximum visibility for road users but a minimal likelihood of even mo- mentarily obscuring pedestrians as well as motorcyclists and bicyclists, who are the most vulnerable of all roundabout users. Signing needs are different for urban and rural applications and for different categories of roundabouts. 7.1.1 Relationship with the Manual on Uniform Traffic Control Devices The Manual on UniformTraffic Control Devices for Streets and Highways (MUTCD) (1) and Standard Highway Signs (2), as well as local applicable standards, govern the design and placement of signs. To the extent possible, this guide has been prepared in accordance with the 1988 edition of the MUTCD. However, round- abouts present a number of new signing issues that are not addressed in the 1988 edition. For this reason, a number of new signs or uses for existing signs have been introduced that are under consideration for inclusion in the next edition of the MUTCD. Until such signs or uses are formally adopted, these recommendations should be considered provisional and are subject to MUTCD Section 1 A-6, "Manual Changes, Interpretations and Authority to Experiment" The following signs and applications recommended below are subject to these conditions: • Use of YIELD signs on more than one approach to an intersection (Section 7.1.2.1); • Long chevron plate (Section 7.1.2.2); • Roundabout Ahead sign (Section 71.3.1); • Advance diagrammatic guide signs (Section 7.1.4.1); and • Exit guide signs (Section 7.1.4.2). Signing, striping, illumination, and landscaping are the critical finishing touches for an effectively functioning roundabout. I�� Roundabouts: An Informational Guide • 7:Traffic Design and Landscaping 7.1.2 Regulatory signs A number of regulatory signs are appropriate for roundabouts and are described below. 7.1.2.1 YIELD sign YIELD signs are required on all AYIELD sign (R1-2�, shown in Exhibit 7-1, is required at the entrance to the round- approaches. about. For single-lane approaches, oneYIELD sign placed on the right side is suffi- cient, although a secondYlELD sign mounted in the splitter island on the left side of the approach may be used. For approaches with more than one lane, the de- signer should placeYlELD signs on both the left and right sides of the approach. This practice is consistent with the recommendations of the MUTCD on the loca- tion of STOP andYIELD signs on single-lane and multilane approaches (MUTCD, §2B-9).To prevent circulating vehicles from yielding unnecessarily, the face of the yield sign should not be visible from the circulatory roadway. YIELD signs may also be used at the entrance to crosswalks on both the entry and exit legs of an ap- proach. However, the designer should not use both YIELD signs and Pedestrian Crossing signs (see Section 7.1.3.5) to mark a pedestrian crossing, as the yield signs at the roundabout entrance may be obscured. Exhibit 7-1. YIELD sign (R1-2�. ONE WAY signs establish the direction of traffic flow within the roundabout. Exhibit 7-2. ONE WAY sign (R6-1 R). Exhibit 7-3. KEEP RIGHT sign (R4-7►. YIELD 7.1.2.2 ONE WAY sign ONE WAY signs (R6-1 R) may be used in the central island opposite the entrances. An example is shown in Exhibit 7-2.The ONE WAY sign may be supplemented with chevron signs to emphasize the direction of travel within the circulatory roadway (see Section 7.1.3.4). At roundabouts with one-way streets on one or more approaches, the use of a regulatory ONE WAY sign may be confusing. In these cases, a Large Arrow warn- ing sign (see Section 7.1.3.3) may be used. 7.1.2.3 KEEP RIGHT sign KEEP RIGHT signs (R4-7 or text variations R4-7a and R4-7b) should be used at the nose of all nonmountable splitter islands. This sign is shown in Exhibit 7-3. For small splitter islands, aType 1 object marker may be substituted for the KEEP RIGHT sign.This may reduce sign clutter and improve the visibility of theYIELD sign. � ��` I Federal HighwayAdministration 7.1.2.4 Lane-use control signs For roundabouts with multiple entry lanes, it can often be conf �� a d right mover drivers to know which lanes to use for the various left, throug ments.There is no international consensus on the effectiveness of lane-use signs and/or pavement markings. The designation of lanes on entry to a roundabout is directly related to a number of factors: ht-turning • • Traffic volume ba�en�ore tha�naooetlaneltto handlellt eeexpec ed demand (see traffic may req Chapter 4). Exit lane requirements. In 9 ndle the expec ed exit volume This Imaa not clorbe- the minimum required to ha osite side of the roundabout spond with the number of entry lanes on the opp that would use the exit as through vehicles (see Chapter 4). � The rules of the road. Driverst �ill have anaequal p umbernof aece vli glelanes on lanes entering a roundabou exit on the far side of the roundabout (see Chapter 2). Lane-use control signs are 9 exitamatches t�hel n mber of entry lanesr as shownng lanes for through vehicles on Exhibit 7-4. Lane-use control signs should be used only for the following con i tions: • Where only a single exit la ne lu erdesig ations should be made toendicat nthat ing through movements, la an entry lane drops an a turoac�h s flar d f om oneXtobtwo�anessat�ohe round- clude cases where a pP about. • Where left- or right-t �han one nght�-eu n lanelfoacapacrty rea�sons (see Exh'bit 7-5) left-turn lane or more The use of a left-turn-only lanee of designationhhasnworkedXSUbcessfullbennother confusing to drivers. This typ est that it will not work in the United countries, and there is no evidence to sugg States. However, given the 9ese ecommendedythat do ble-olane ro andaboutstbe United States at this time, designed to avoid the use of lane-use control signs wherever possible, at least unti drivers become more accustomed to driving roundabouts. Lane-use control signs are generally not recommended. '��? Roundabouts: An Informational Guide • 7:Traffic Desi9n and Landscapin9 Exhibit 7-4. Lane-use control signing for roundabouts with double-lane entries. Exhibit 7-5. Lane-use control signing for roundabouts with heavy turning traffic. 7.1.3 Warning signs A number of warning signs are appropriate for roundabouts and are described be- Iow.The amount of warning a motorist needs is related to the intersection setting and the vehicular speeds on approach roadways. The specific placement of warn- ing signs is governed by the applicable sections of the MUTCD. Federal HighwayAdministration 7.1.3.1 Circular Intersection sign A Circular Intersection sign (W2-6) may be installed on each approach in advance of the roundabout. This sign, given in Exhibit 7-6, is proposed as part of the next edition of the MUTCD. When used, it is recommended that this sign be modified to reflect the number and alignment of approaches. It is also recommended that an advisory speed plate (W13-1) be used with this sign, as shown in Exhibit 7-7. The speed given on the advisory speed plate should be no higher than the design speed of the circulatory roadway, as determined in Chapter 6. An alternative to the Circular Intersection sign, called a Roundabout Ahead sign, has been proposed and is shown in Exhibit 7-8. The rationale for this sign is given in Appendix C. At a minimum it is recommended that the Roundabout Ahead sign be used in place of the Circular Intersection sign at mini-roundabouts (see Section 7.1.7). 7.1.3.2 YIELD AHEAD sign Exhibit 7-6. Circular Intersection sign (W2-61. Exhibit 7-7. Advisory speed plate �W13-1�. Exhibit7-8. Roundabout Ahead sign. AYIELD AHEAD sign (W3-2 or W3-2a) should be used on all approaches to a round- YIE�D AHEAD signs warn drivers about in advance of the yield sign.These signs provide drivers with advance warn- of the upcomingYlELD sign. ing that a YIELD sign is approaching. The preferred symbolic form of this sign is shown in Exhibit 7-9. Exhibit 7-9. YIELD AHEAD sign (W3-2a1. Roundabouts: An Informational Guide • 7:Traffic Design and Landscaping I'�� Exhibit 7-70. Large Arrow sign (W1-6). Chevron plates can be especially useful for nighttime visibility for sites without illumination. Exhibit 7-11. Chevron plate (W1-8a). Exhibit 7-12. Pedestrian Crossing sign (W11-2a►. 7.1.3.3 Large Arrow sign A Large Arrow sign with a single arrow pointing to the right (W1-6) should be used in the central island opposite the entrances, unless a regulatory ONE-WAY sign has been used. The Large Arrow sign is shown in Exhibit 7-10. 7.1.3.4 Chevron Plate The Large Arrow may be supplemented or replaced by a long chevron board (W1- 8a, as proposed in the next edition of the MUTCD) to emphasize the direction of travel within the circulatory roadway. 7.1.3.5 Pedestrian Crossing Pedestrian Crossing signs (W11-2a) may be used at pedestrian crossings within a roundabout at both entries and exits. Pedestrian Crossing signs should be used at all pedestrian crossings at double-lane entries, double-lane exits, and right-turn bypass lanes. This sign is shown in Exhibit 7-12. The use of Pedestrian Crossing signs is dependent on the specific laws of the governing state. If the crosswalk at a roundabout is not considered to be part of the intersection and is instead considered a marked midblock crossing, Pedestrian Crossing signs are required. Where installed, Pedestrian Crossing signs should be located in such a way to not obstruct view of the YIELD sign. �' I Federal HighwayAdministration 7.1.4 Guide signs Guide signs are important in providing drivers with proper navigational informa- tion.This is especially true at roundabouts where out-of-direction travel may disori- ent unfamiliar drivers. A number of guide signs are appropriate for roundabouts and are described below. 7.1.4.1 Advance destination guide signs Advance destination guide signs should be used in all rural locations and in urban/ suburban areas where appropriate. The sign should be either a destination sign using text (D1-3) or using diagrams. Examples of both are shown in Exhibit 7-13. Diagrammatic signs are preferred because they reinforce the form and shape of the approaching intersection and make it clear to the driver how they are expected to navigate the intersection. Advance destination guide signs are not necessary at local street roundabouts or in urban settings where the majority of traffic tends to be familiar with the site. Leeds, MD Lothian, MD Taneytown, MD Long Beach, CA The circular shape in a diagrammatic sign provides an important visual cue to all users of the roundabout. Exhibit 7-13. Examples of advance destination guide signs. Diagrammatic Style (Preferred) Roundabouts: An Informational Guide • 7:Traffic Design and Landscaping I�1". 7.1.4.2 Exit guide signs Exit guide signs reduce the Exit guide signs (D1-1) are recommended to designate the destinations of each potential for disorientation. exit from the roundabout.These signs are conventional intersection direction signs or directional route marker assemblies and can be placed either on the right-hand side of the roundabout exit or in the splitter island. An example is shown in Exhibit 7-14. Exhibit 7-14. Exit guide sign (D1-1 �. 71.4.3 Route confirmation signs For roundabouts involving the intersection of one or more numbered routes, route confirmation assemblies should be installed directly after the roundabout exit.These provide drivers with reassurance that they have selected the correct exit at the roundabout. These assemblies should be located no more than 30 m(100 ft) be- yond the intersection in urban areas and 60 m(200 ft) beyond the intersection in rural areas. 7.1.5 Urban signing considerations 7he designer needs to balance the The amount of signing required at individual locations is largely based on engineer- need for adequate signing ing judgment. However, in practice, the designer can usually use fewer and smaller with the tendency to use signs in urban settings than in rural settings. This is true because drivers are gener- too many signs. ally traveling at lower vehicular speeds and have higher levels of familiarity at urban intersections.Therefore, in many urban settings the advance destination guide signs can be eliminated. However, some indication of street names should be included in the form of exit guide signs or standard street name signs. Another consider- ation in urban settings is the use of minimum amounts of signing to avoid sign clutter. A sample signing plan for an urban application is shown in Exhibit 7-15. �gg I Federal HighwayAdministration Exhibit 7-15. Sample signing plan for an urban roundabout. Roundabouts:An Informational Guide • 7:Traffic Design and Landscaping I�; Rural signing needs to be more conspicuous than urban signing due to higher approach speeds. Exhibit 7-16. Sample signing plan for a rural roundabout. 7.1.6 Rural and suburban signing considerations Rural and suburban conditions are characterized by higher approach speeds. Route guidance tends to be focused more on destinations and numbered routes rather than street names. A sample signing plan for a rural application is shown in Exhibit 7-16. � ♦ �,, j so�m � I..._ Ceartoss ��..�.�... I � Pike � � .�� -�'� � �� 8� $dS � , � �� $dK � � �� p) � ' I Federal HighwayAdministration In cases where high speeds are expected (in excess of 80 km/h [50 mph]) and the These speed reduction treatments normal signage and geometric features are not expected to produce the desired can apply to all intersection reduction in vehicle speeds, the following measures may also be considered (ex- types, not just roundabouts. amples of some of these treatments are given in Exhibit 7-17): • Large advance warning signs; � Addition of hazard identification beacons to approach signing; • Use of rumble strips in advance of the roundabout; • Pavement marking across pavement; and • Use of speed warning signs.These can be triggered by speeds exceeding an acceptable threshold. Warning beacons. Leeds, MD Speed warning signs. Leeds, MD Rumble strips. Cearfoss, MD 7.1.7 Mini-roundabout signing considerations Due to their small size and unique features, mini-roundabouts require a somewhat different signing treatment than the larger urban roundabouts. The principal differ- ences in signing at mini-roundabouts as compared to other urban roundabouts are the following: • The central island is fully mountable. Therefore, no ONE WAY signs, Large Ar- row signs, or chevrons can be located there. It is recommended that the direc- tion of circulation be positively indicated through the use of pavement mark- ings, as discussed in Section 7.2.4. • The splitter islands are either painted or are fully mountable. Therefore, KEEP RIGHT signs are not appropriate for mini-roundabouts. Exhibit 7-17. Examples of speed reduction treatments. Roundabouis: An Informational Guide • 7:Traffic Design and Landscaping I �gg, Exhibit 7-18. Sample signing plan for a mini-roundabout. • Typically, advance directional guide signs and exit guide signs are unnecessary, given the size of the mini-roundabout and the nature of the approach roadways (generally low-speed local streetsl. However, standard street name signs (D3) should be used. The Roundabout Ahead warning sign discussed in Section 7.1.3.1 should be used on each approach in advance of theYIELD sign.The Circular Intersection warning gives no indication of the direction of circulation required at the mini- roundabout. Exhibit 7-18 gives a sample signing plan for a mini-roundabout. 198 I Federal HighwayAdministration 7.2 Pavement Markings Typical pavement markings for roundabouts consist of delineating the entries and the circulatory roadway. 7.2.1 Relationship with the Manual on Uniform Traffic Control Devices As with signing, the MUTCD (1) and applicable local standards govern the design and placement of pavement markings. Roundabouts present a number of new pavement marking issues that are not addressed in the 1988 edition of the MUTCD. For this reason, a number of new pavement markings or uses for existing pave- ment markings have been introduced that are under consideration for inclusion in the next edition of the MUTCD. Until such pavement markings or uses are formally adopted, these recommendations should be considered provisional and are sub- ject to MUTCD Section 1A-6, "Manual Changes, Interpretations and Authority to Experiment:' The following pavement markings and applications recommended below are sub- ject to these conditions: • YIELD lines (Section (7.2.2.1); and � SymbolicYlELD legend (Section 7.2.2.2). 7.2.2 Approach and entry pavement markings Approach and entry pavement markings consist of yield lines, pavement word and symbol markings, and channelization markings. In addition, multilane approaches require special attention to pavement markings. The following sections discuss these in more detail. 7.2.2.1 Yield lines Yield lines should be used to demarcate the entry approach from the circulatory Yield lines provide a visual separation roadway. Yield lines should be located along the inscribed circle at all roundabouts between the approach and the except mini-roundabouts (see Section 7.2.4). No yield lines should be placed to circulatory roadway. demarcate the exit from the circulatory roadway. The MUTCD currently provides no standard for yield Iines.The recommended yield line pavement marking is a broken line treatment consisting of 400-mm (16-in) wide stripes with 1-m (3-ft) segments and 1-m (3-ft) gaps.This type of yield line is the simplest to install. Alternatively, several European countries use a yield line marking consisting of a series of white triangles (known as "shark's teeth"1. These markings tend to be more visible to approaching drivers. Exhibit 7-19 presents examples of broken line and "shark's teeth" yield line applications.The "shark's teeth" ahead of the broken line has been recommended for adoption in the next edition of the MUTCD. Roundabouts: An Informational Guide • 7:Traffic Design and Landscaping "Shark's teeth" provide more visual "punch" but require a new template for installation. t51? Exhibit 7-19. Examples of yield lines. Broken line. Leeds, MD "Shark's teeth:' Lothian, MD 7.2.2.2 Pavement word and symbol markings Pavement word markings are In some cases, the designer may want to consider pavement word or symbol less effective in rainy or markings to supplement the signing and yield line marking. This typically consists especially snowy climates. of the wordYlELD painted on the entrance to the roundabout immediately prior to the yield line. These markings should conform to the standards given in the appro- priate section of the MUTCD (§36-201. Alternatively, some European countries paint a symbolic yield sign upstream of the yield line. This treatment has the advantage of being symbolic; however, such a treatment has not seen widespread use in the United States to date. 7.2.2.3 Lane-use conTrol markings If lane-use control signing has been used to designate specific lane use on an approach with more than one lane, it is recommended that corresponding arrow legends be used within each lane. See Section 7.1.2.4 for more discussion of the use of lane-use controls. 7.2.2.4 Approach markings Typically, pavement markings are provided around raised splitter islands and right- turn bypass islands to enhance driver recognition of the changing roadway. Channelization markings shall be yellow when to the left of the traffic stream and white when to the right of the traffic stream. For a roundabout splitter island, pave- ment markings shall be yellow adjacent to the entry and exit and white adjacent to the circulatory roadway. Exhibit 7-20 presents a recommended pavement marking plan for the channelization on a typical single-lane approach to a roundabout. Op- tionally, edge stripes may end at the points of the splitter islands, ailowing the curbs themselves to provide edge delineation. Raised pavement markers are Raised pavement markers are generally recommended for supplementing pavement useful supplements to markings. These have the benefit of additional visibility at night and in inclement pavement markings. weather. However, they increase maintenance costs and can be troublesome in areas requiring frequent snow removal. In addition, raised pavement markers should not be used in the path of travel of bicycles. '1�8' I Federal HighwayAdministration �� 200 mm (8 in) -i solid white 200 mm (8 in) -� solid white White le end � (optionai� 600mmx3m� (24inx10ft) Zebra crosswalk, 600 mm (24 in) spacing (typical) 200 mm (8 in) solid yellow, 5 m (20 ft) spacing � �� — � � �/ 1 � / '��,� � � !j ► ��.. _ ■�► 1 i. 200 mm (8 in) solid yellow 300 mm (12 in) broken white 1 m 3 ft stripe, 1 m 3 ft gap White le end (optional� 200 mm (8 in) solid yeilow 200 mm 8 in) broken w ite 200 mm (8 in) solid white For small splitter islands (in area less than 7 m2 [75 ft21, the island may consist of pavement markings only. However, where possible, curbed splitter islands should be used. 7.2.2.5 Pedestrian crosswalk markings Pedestrian crosswalk markings should generally be installed at all pedestrian cross- ing locations within roundabouts in urban locations. Because the crosswalk at a roundabout is located away from the yield line, it is important to channelize pedes- trians to the appropriate crossing Iocation.These markings should not be construed as a safety device, as data from other countries suggest that the presence of markings has no appreciable effect on pedestrian safety. Rather, markings provide guidance for pedestrians in navigating a roundabout and provide a visual cue to drivers of where pedestrians may be within the roadway. The use of crosswalk markings in this manner is consistent with published recommendations (3). Marked crosswalks are generally not needed at locations where the crosswalk is distin- guished from the roadway by visually contrasting pavement colors and textures. A crosswalk marking using a series of lines parallel to the flow of traffic (known as a"zebra crosswalk") is recommended. These lines should be approximately 0.3 m to 0.6 m(12 in to 24 in) wide, spaced 0.3 m to 1.0 m(12 in to 36 in) apart, and span the width of the crosswalk (similar to the recommendations in MUTCD §3B-181. Crosswalk markings should be installed across both the entrance and exit of each leg and across any right turn bypass lanes. The crosswalk should be aligned with Exhibit 7-20. Approach pavement markings. Zebra crosswalks provide an important visual cue for drivers and pedestrians. Roundabouts: An Informational Guide • 7:Traffic Design and Landscaping I�g� Circulatory pavement maricings are generally not recommended. the ramps and pedestrian refuge in the splitter island and have markings that are generally perpendicular to the flow of vehicular traffic. The zebra crosswalk has a number of advantages over the traditional transverse crosswalk marking in roundabout applications: • Because the crosswalk at a roundabout is set back from the yield line, the zebra crosswalk provides a higher degree of visibility. • The zebra crosswalk is distinct from traditional transverse crosswalk markings typically used at signalized intersections, thus alerting both drivers and pedes- trians that this intersection is different from a signalized intersection. • The zebra crosswalk is also less likely to be confused with the yield line than a transverse crosswalk. • Although the initial cost is somewhat higher, the zebra crossing may require less maintenance due to the ability to space the markings to avoid vehicle tire tracks. In rural locations where pedestrian activity is expected to be minimal, pedestrian crosswalk markings are optional. Pedestrian crosswalk markings should not be used at roundabouts without illumination (see Section 7.3 for an identification of these cases) because the headlights of vehicles may not be sufficient to illuminate a pedestrian in time to avoid a collision (41. Regardless of whether the crosswalk is marked, all roundabouts with any reasonable possibility of pedestrian activity should have geometric features to accommodate pedestrians as described in Chapter 6. In addition to pavement markings, flashing warning lights mounted in the pave- ment and activated by a pedestrian push button or other method may be consid- ered. These are not part of the current MUTCD and thus must be treated as an experimental traffic control device (see Section 72.1 �. 7.2.2.6 Bike /ane markings Bicycle striping treatments should be used when an existing (or proposed) bike lane is part of the roadway facility. Exhibit 7-20 shows a recommended treatment for bike lanes on an approach to a roundabout. 7.2.3 Circulatory roadway pavement markings In general, lane lines should not be striped within the circulatory roadway, regard- less of the width of the circulatory roadway. Circulatory lane lines can be mislead- ing in that they may provide drivers a false sense of security. Bike lanes within the In addition, bike lane markings within the circulatory roadway are not recommended. roundabout are The additional width of a bike lane within the circulatory roadway increases vehicu- not recommended. lar speed and increases the probability of motor vehicle-cyclist crashes. Bicyclists should circulate with other vehicles, travel through the roundabout as a pedestrian on the sidewalk, or use a separate shared-use pedestrian and bicycle facility where provided. 200 I Federal HighwayAdministration 7.2.4 Mini-roundabout pavement markings Mini-roundabouts require pavement marking treatments that are somewhat differ- ent from other urban roundabouts. The following pavement marking treatments are recommended for mini-roundabouts. • Pavement marking arrows should be provided in the circulatory roadway in front of each entry to indicate the direction of circulation. As noted in the discussion of signing treatments (Section 7.1.7�, no signs can be placed in the fully mount- able central island. � At a minimum, the edges of the mountable central island and splitter islands should be painted to improve their visibility. A sample pavement marking plan for a mini-roundabout is given in Exhibit 7-21. White curved arrow legend � C � � 600mmX3m� (24 in X 10 ft) crosswalk, 600 mm (24 in spacing (typical; Q� � � � � � � Edge of island: � yelfow, 200 mm (8 in) � minimum width . � Q �� -� � � �- 300 mm (12 in) broken whfte, 1 m 3 ft stripe, I' 1 m 3 ft gap White legend (optional) mm 8 in) minimum rw e ge of island Exhibit 7-21. Sample pavement marking plan for a mini-roundabout. Roundabouts: An Informational Guide • 7:Traffic Design and Landscaping I 20'1 Exhibit 7-22. Illumination of a roundabout. 7.3 Illumination For a roundabout to operate satisfactorily, a driver must be able to enter the round- about, move through the circulating traffic, and separate from the circulating stream in a safe and efficient manner.To accomplish this, a driver must be able to perceive the general layout and operation of the intersection in time to make the appropriate maneuvers. Adequate lighting should therefore be provided at all roundabouts. Exhibit 7-22 shows an example of an illuminated roundabout at night. Loveland, CO 7.3.1 Need for illumination The need for illumination varies somewhat based on the location in which the round- about is located. 7.3.1.1 Urban conditions In urban settings, illumination should be provided for the following reasons: • Most if not all approaches are typically illuminated. • Illumination is necessary to improve the visibility of pedestrians and bicyclists. 7.3.1.2 Suburban conditions For roundabouts in suburban settings, illumination is recommended. For safety reasons, illumination is necessary when: • One or more approaches are illuminated. • An illuminated area in the vicinity can distract the driver's view. • Heavy nighttime traffic is anticipated. 202 I Federal HighwayAdministration Continuity of illumination must be provided between illuminated areas and the roundabout itself (5). An unlit roundabout with one or more illuminated approaches is dangerous. This is because a driver approaching on an unlit approach will be attracted to the illuminated area(s) and may not see the roundabout. 7.3.1.3 Rural conditions For rural roundabouts, illumination is recommended but not mandatory. If there is no power supply in the vicinity of the intersection, the provision of illumination can be costly. When lighting is not provided, the intersection should be well signed and marked so that it can be correctly perceived by day and night. The use of reflective pavement markers and retroreflective signs (including chevrons supplement- ing the ONE-WAY signs) should be used when lighting cannot be installed in a cost-effective manner. Where illumination can be provided, any raised channelization or curbing should be illuminated. In general, a gradual illumination transition zone of approximately 80 m (260 ft) should be provided beyond the final trajectory changes at each exit (5).This helps drivers adapt their vision from the illuminated environment of the round- about back into the dark environment of the exiting roadway, which takes approxi- mately 1 to 2 seconds. In addition, no short-distance dark areas should be allowed between two consecutive illuminated areas (51. 7.3.2 Standards and recommended practices The following standards and recommended practices should be consulted in com- pleting the lighting plan: AASHTO, An Information Guide for Roadway Lighting (6). This is the basic guide for highway lighting. It includes information on warranting conditions and de- sign criteria. AASHTO, Standard Specifications for Structural Supports for Highway Signs, Luminaires and Traffic Signals (7). This specification contains the strength re- quirements of the poles and bracket arms for various wind loads, as well as the frangibility requirements. All luminaire supports, poles, and bracket arms must comply with these specifications. IES RP-8: The American National Standard Practice for Roadway Lighting (8). This Recommended Practice, published by the Illuminating Engineering Soci- ety, provides standards for average-maintained illuminance, luminance, and small target visibility, as well as uniformity of lighting. Recommended illumination levels for streets with various classifications and in various areas are given in Exhibit 7-23. Roundabouts: An Informational Guide • 7:Traffic Design and Landscaping I�►"3 Exhibit 7-23. Recommended street illumination levels. Street Classification Arterial Collector Local Definitions: Commercial Intermediate Residentiai Area Classification Commercial Intermediate Residential Commercial Intermediate Residential Commercial Intermediate Residential Average Maintained Illuminance Values 17 Ix (1.7 fc) 13 Ix (1.3 fc) 9 Ix (0.9 fc) 12 Ix (1.2 fc) 9 Ix (0.9 fc) 6 Ix (0.6 fc) 9 Ix (0.9 fc) 7 Ix (OJ fc) 4 Ix (0.4 fc) Illuminance Uniformity Ratio (Averageto Minimum) 3 to 1 4 to 1 . . A business area of a municipality where ordinarily there are many pedestrians during night hours.This definition applies to densely developed business areas outside, as well as within, the central part ot a municipality.The area contains land use which attracts a relatively heavy volume of nighttime vehicular and/or pedestrian traffic on a frequent basis. Those areas of a municipality often with moderately heavy nighttime pedestrian activity such as in blocks having libraries, community recreation centers, large apartment build- ings, industrial buildings, or neighborhood retail stores. A residential development, or a mixture of residential and small commercial establish- ments, with few pedestrians at night. Note: Values in table assume typical asphalt roadway surface (pavement classification R2 or R3). Consult the IES document for other pavement surfaces. Source: Illuminating Engineering Society RP-8 (8) 7.3.3 General recommendations The primary goal of illumination is to ensure perception of the approach and mutual visibility among the various categories of users.To achieve this, the following fea- tures are recommended: The overall illumination of the roundabout should be approximately equal to the sum of the illumination levels of the intersecting roadways. If the approaching roadways have been designed to the illumination levels given in Exhibit 7-23, this may result in illumination levels at the roundabout ranging from 9 Ix (0.8 fc) for roundabouts at the intersection of local streets in residential areas to 36 Ix (3.4 fc) for roundabouts at the intersection of arterials in commercial areas. Local illumination standards should also be considered when establishing the illumination at the roundabout to ensure that the lighting is consistent. • Good illumination should be provided on the approach nose of the splitter is- lands, at all conflict areas where traffic is entering the circulating stream, and at all places where the traffic streams separate to exit the roundabout. Lighting from the central island • It is preferable to light the roundabout from the outside in towards the center. causes vehicles to be backlit and This improves the visibility of the central island and the visibility of circulating thus less visible. vehicles to vehicles approaching to the roundabout. Ground-level lighting within the central island that shines upwards towards objects in the central island can improve their visibility. � I Federal HighwayAdministration • Special consideration should be given to lighting pedestrian crossing and bi- cycle merging areas. 7.3.4 Clear zone requirements As discussed in Chapter 5, the proportion of single-vehicle crashes at roundabouts is high compared to other intersection types. This is because roundabouts consist of a number of relatively small-radii horizontal curves for each traveled path through the roundabout. Drivers travel on these curves with quite high values of side fric- tion, particularly at roundabouts in higher speed areas. Single-vehicle crashes, which predominantly involve out-of-control vehicles, increase with an increased amount of side friction. Because of the relatively high number of out-of-control vehicles, it is desirable to have adequate amounts of clear zone where there are no roadside hazards on each side of the roadway. Lighting supports and other poles should not be placed within small splitter islands or on the right-hand perimeter just downstream of an exit point. Lighting poles should be avoided in central islands when the island diameter is less than 20 m(65 ft). The reader should refer to the AASHTO Roadside Design Guide for a more detailed discussion of clear zone requirements (9). 7.4 Work ZoneTraffic Control During the construction of a roundabout it is essential that the intended travel path be clearly identified.This may be accomplished through pavement markings, sign- ing, delineation, channelizing devices, and guidance from police and/or construc- tion personnel, depending on the size and complexity of the roundabout. Care should be taken to minimize the channelizing devices so that the motorist, bicy- clist, and pedestrian has a clear indication of the required travel path. Each installa- tion should be evaluated separately, as a definitive guideline for the installation of roundabouts is beyond the scope of this guide. Refer to Part 6 of the MUTCD for requirements regarding work zone traffic control. 7.4.1 Pavement markings The pavement markings used in work zones should be the same layout and dimen- sion as those used for the final installation. Because of the confusion of a work area and the change in traffic patterns, additional pavement markings may be used to clearly show the intended direction of travel. In some cases when pavement markings cannot be placed, channelizing devices should be used to establish the travel path. 7.4.2 Signing The signing in work zones should consist of all necessary signing for the efficient movement of traffic through the work area, preconstruction signing advising the pub- Construction signing for a roundabout should follow the MUTCD standard. Roundabouts: An Informational Guide • 7:Traffic Design and Landscaping I�� lic of the planned construction, and any regulatory and warning signs necessary for the movement of traffic outside of the immediate work area.The permanent round- about signing should be installed where practicable during the first construction stage so that it is available when the roundabout is operable. Permanent signing that cannot be installed initially should be placed on temporary supports in the proposed location until permanent installation can be completed. 7.4.3 Lighting Permanent lighting, as described in Section 7.3, should be used to light the work area. If lighting will not be used, pavement markings, as described in Section 7.2, should be used. 7.4.4 Construction staging Constn,ction staging should be As is the case with any construction project, before any work can begin, all traffic considered during the siting of control devices should be installed as indicated in the traffic control plan or recom- the roundabout, especially if it mended typical details.This traffic control shall remain in place as long as it applies must be built under traffic. and then be removed when the message no longer applies to the condition. Prior to work that would change the traffic patterns to that of a roundabout, certain peripheral items may be completed. This would include permanent signing (cov- ered), lighting, and some pavement markings. These items, if installed prior to the construction of the central island and splitter islands, would expedite the opening of the roundabout and provide additional safety during construction. When work has commenced on the installation of the roundabout, it is desirable that it be completed as soon as possible to minimize the time the public is faced with an unfinished layout or where the traffic priority may not be obvious. If pos- sible, all work, including the installation of splitter islands and striping, should be done before the roundabout is open to traffic. If it is necessary to leave a roundabout in an uncompleted state overnight, the splitter islands should be constructed before the central island. Any portion of the roundabout that is not completed should be marked, delineated, and signed in such a way as to clearly outline the intended travel path. Pavement markings that do not conform to the intended travel path should be removed. It is highly desirable to detour traffic for construction of a roundabout. This will significantly reduce the construction time and cost and will increase the safety of the construction personnel. If it is not possible to detour all approaches, detour as many approaches as possible and stage the remainder of the construction as follows: 1. Install and cover proposed signing. 2. Construct outside widening if applicable. 3. Reconstruct approaches if applicable. ��; I Federal HighwayAdministration 4. Construct splitter islands and delineate the central island. At this point the signs should be uncovered and the intersection should operate as a roundabout. 5. Finish construction of the central island. 7.4.5 Public education It is important to educate the public whenever there is a change in traffic patterns. Public education during It is especially important for a roundabout because a roundabout will be new to construction is as important as most motorists. The techniques discussed in Chapter 2 can be applied during the the public education effort construction period. The following are some specific suggestions to help alleviate during the planning process. initial driver confusion. • Hold public meetings prior to construction; • Prepare news releases/handouts detailing what the motorist can expect be- fore, during, and after construction; • Install variable message signs before and during construction; • Use Travelers Advisory Radio immediately prior to and during construction to disseminate information on "How to drive;' etc.; and • Install signing during and after construction that warns of changed traffic patterns. 7.5 Landscaping This section provides an overview of the use of landscaping in the design of a roundabout. 7.5.7 Advantages Landscaping in the central island, in splitter islands (where appropriate), and along the approaches can benefit both public safety and community enhancement. The landscaping of the roundabout and approaches should: • Make the central island more conspicuous; • Improve the aesthetics of the area while complementing surrounding streetscapes as much as possible; • Minimize introducing hazards to the intersection, such as trees, poles, walls, guide rail, statues, or large rocks; • Avoid obscuring the form of the roundabout or the signing to the driver; • Maintain adequate sight distances, as discussed in Chapter 6; • Clearly indicate to the driver that they cannot pass straight through the intersec- tion; • Discourage pedestrian traffic through the central island; and • Help blind and visually impaired pedestrians locate sidewalks and crosswalks. Landscaping is one of the distinguishing features that gives roundabouts an aesthetic advantage over traditional intersections. Roundabouts: An Informational Guide • 7:Traffic Design and Landscaping I�'�, 7.5.2 Central island landscaping The central island landscaping can enhance the safety of the intersection by mak- ing the intersection a focal point and by lowering speeds. Plant material should be selected so that sight distance (discussed in Chapter 6) is maintained, including consideration of future maintenance requirements to ensure adequate sight dis- tance for the life of the project. Large, fixed landscaping (trees, rocks, etc.) should be avoided in areas vulnerable to vehicle runoff. In northern areas, the salt toler- ance of any plant material should be considered, as well as snow storage and removal practices. In addition, landscaping that requires watering may increase the likelihood of wet and potentially slippery pavement. Exhibit 7-24 shows the recommended placement of landscaping within the central island. The slope of the central island should not exceed 6:1 per the requirements of the AASHTO Roadside Design Guide (9). Avoid items in the central island Where truck aprons are used in conjunction with a streetscape project, the pave- that might tempt peopie to take ment should be consistent with other streetscape elements. However, the mate- a closer look. rial used for the apron should be different than the material used for the sidewalks so that pedestrians are not encouraged to cross the circulatory roadway. Street furniture that may attract pedestrian traffic to the central island, such as benches or monuments with small text, must be avoided. If fountains or monuments are be- ing considered for the central island, they must be designed in a way that will enable proper viewing from the perimeter of the roundabout. In addition, they must be located and designed to minimize the possibility of impact from an errant vehicle. Exhibit 7-24. Landscaping of the central island. 7.5.3 Splitter island and approach landscaping In general, unless the splitter islands are very large or long, they should not contain trees, planters, or light poles. Care must be taken with the landscaping to avoid obstructing sight distance, as the splitter islands are usually located within the critical sight triangles (see Chapter 6). ,�l�� I Federal HighwayAdministration Landscaping on the approaches to the roundabout can enhance safety by making the intersection a focal point and by reducing the perception of a high-speed through traffic movement. Plant material in the splitter islands (where appropriate) and on the right and left side of the approaches can help to create a funneling effect and induce a decrease in speeds approaching the roundabout. Landscaping in the cor- ner radii will help to channelize pedestrians to the crosswalk areas and discourage pedestrians from crossing to the central island. 7.5.4 Maintenance A realistic maintenance program should be considered in the design of the land- scape features of a roundabout. It may be unrealistic to expect a typical highway agency to maintain a complex planting plan. Formal agreements may be struck with local civic groups and garden clubs for maintenance where possible. Liability issues should be considered in writing these agreements. Where there is no inter- est in maintaining the proposed enhancements, the landscape design should con- sist of simple plant materials or hardscape items that require little or no mainte- nance. 7.6 References 1. Federal Highway Administration (FHWA). Manual on Uniform Traffic Contro/ De- vices. Washington, D.C.: FHWA, 1988. 2. Federal Highway Administration (FHWA). Standard Highway Signs. Washing- ton, D.C.: FHWA, 1979. 3. Smith, S.A., and R.L. Knoblauch. "Guidelines for the Installation of Crosswalk Markings" In Transportation Research Record 1141. Transportation Research Board, National Research Council, Washington, D.C., 1987. 4. Herms, B.F. "Some Visual Aspects of Pedestrian Crosswalks:' In Proceedings, 22nd California Streetand Highway Conference, Institute ofTransportation and Traffic Engineering, University of California, Los Angeles, January 1970. 5. Centre d'Etudes sur les Reseaux les Transports, I'Urbanisme et les construc- tions publiques (CERTU). L'Eclairage des Carrefours a Sens Giratoire (The lllumi- nation of Roundabout lnte�sections). Lyon, France: CERTU, 1991. 6. American Association of State Highway andTransportation Officials (AASHTO). An lnformation Guide for Roadway Lighting. Washington, D.C.: AASHTO, 1985. 7. American Association of State Highway andTransportation Officials (AASHTO). Standard Specifications for Structural Supporis for Highway Signs, Luminaires andTraffic Signals. Washington, D.C.: AASHTO, 1994. 8. Illuminating Engineering Society (IES). American National Standard Practice for Roadway Lighting. Standard RP-8. December 1982. 9. American Association of State Highway andTransportation Officials (AASHTO). Roadside Design Guide. Washington, D.C.: AASHTO, 1989. Roundabouts: An Informational Guide • 7:Traffic Design and Landscaping Ensure that whatever landscaping is installed, it will be maintained. �08 8.1 8.2 8.3 8.4 8.5 8.6 8.7 System Considerations Traffic Signals at Roundabouts 8.1.1 Metered entrance 8.1.2 Nearby vehicular and pedestrian signals 8.1.3 Full signalization of the circulatory roadway At-Grade Rail Crossings Closely Spaced Roundabouts Roundabout Interchanges 8.4.1 Two-bridge roundabout interchange 8.4.2 One-bridge roundabout interchange 8.4.3 Analysis of roundabout interchanges 8.4.4 Geometric design parameters Roundabouts in an Arterial Network 8.5.1 Platooned arrivals on roundabout approaches 8.5.2 Roundabout departure pattern 8.5.3 Wide nodes and narrow roads Microscopic Simulation 8.6.1 How to use simulation 8.6.2 Examples of simulation models References 213 214 214 215 215 217 219 219 220 222 223 223 224 224 225 227 227 228 229 Exhibit 8-1. Exhibit 8-2. Exhibit 8-3. Exhibit 8-4. Exhibit 8-5. Exhibit 8-6. Exhibit 8-7. Exhibit 8-8. Exhibit 8-9. Exhibit 8-10. Exhibit 8-11, Rail crossing treatments at roundabouts. Methods for accommodating a rail crossing adjacent to a roundabout. Example of closely spaced offsetT-intersections with roundabouts. Through bypass lanes at staggeredT-intersections. Two-bridge roundabout interchange. Examples of two-bridge roundabout interchanges. Examples of one-bridge roundabout interchanges with circular central islands. One-bridge roundabout interchange with raindrop-shaped central islands. Roundabouts in an arterial network. Wide nodes and narrow roads. Summary of simulation models for roundabout analysis. 216 217 218 218 219 220 221 222 223 226 228 � Q„� �_' w I Federal HighwayAdministration Chapter 8 System Considerations Roundabouts have been considered as isolated intersections in most other inter- national roundabout guides and publications. However, roundabouts may need to fit into a network of intersections, with the traffic control functions of a roundabout supporting the function of nearby intersections and vice versa.The purpose of this chapter is to provide some guidance on potentially difficult, but not uncommon, circumstances or constraints. Many countries whose initial design and driver experience was with isolated round- abouts have since extended their application to transportation system design and operation.This chapter addresses the appropriate use of roundabouts in a roadway network context and the benefits obtained. Since the design of each roundabout should generally follow the principles of isolated roundabout design, the discus- sion is at a conceptual and operational level and generally complements the plan- ning of isolated roundabouts discussed in Chapter 3. In many cases, site-specific issues will determine the appropriate roundabout design elements. To establish some fundamental understanding for subsequent discussion, three design issues at an isolated roundabout are presented. First, this chapter will de- scribe the requirements and effects of signal control of one or more legs of a roundabout, as well as the entire roundabout. It is noted that fully signalized round- abouts are not desirable. Next, modified designs that incorporate at-grade rail cross- ings are discussed. It is noted that intersections with rail lines passing through them or near them are not desirable. However, these situations do occur and would then need to be analyzed. Building upon this understanding, the next sections address design and perfor- mance of two closely spaced roundabouts and the specific application to round- about interchanges.This is followed by issues pertaining to the use of roundabouts on an arterial or network that may include or replace coordinated signalized inter- sections. Finally, the role of microscopic simulation models in assisting with analy- sis of these system effects is reviewed. 8.1 Traffic Signals at Roundabouts Although yield control of entries is the default at roundabouts, when necessary, traffic circles and roundabouts have been signalized by metering one or more en- tries, or signalizing the circulatory roadway at each entry. Roundabouts should never be planned for metering or signalization. However, unexpected demand may dic- tate the need after installation. Each of these will be discussed in turn. In the first case, entrance metering can be implemented at the entrance or some distance upstream. This chapter considers roundabouts as they relate to other elements of the transportation system, including other intersections. Roundabouts: An Informational Guide •& System Considerations I 8.1.1 Metered entrance Roundabouts should not be Roundabouts operate effectively only when there are sufficient longer and accept- planned for metering or able gaps between vehicles in the circulatory lanes. If there is a heavy movement signalization unless of circulating drivers, then entering drivers at the next downstream entry may not unexpected demand dictates be able to enter.This situation occurs most commonly during the peak periods, and this need after installation. the performance of the roundabout can be greatly improved with entrance metering. Nearby intersections or pedestrian crossing signals can also meter traffic, but not as effectively as direct entrance metering. The concept of entrance metering at roundabouts is similar to ramp metering on freeways. A convenient sign is a changeable one that reads "Stop on red signal" and shows the usual yield sign for a roundabout otherwise. The sign would also include a yellow and red signal above the sign.The operation of the sign would be to show drivers the roundabout sign, display the yellow light and the sign "Stop on red signal;' and finally display the red light and the same text sign. This would cause entering vehicles to stop and allow the vehicles at the downstream entrance to proceed. A queue length detector on the downstream entrance may be used to indicate to the signal controlier when the metering should be activated and deacti- vated. Once on the circulatory roadway, vehicles are not stopped from leaving the roundabout. 8.1.2 Nearby vehicular and pedestrian signals Another method of inetering is the use, with appropriate timing, of a nearby up- stream signalized intersection or a signalized pedestrian crossing on the subject approach road. Unlike pure entry metering, such controls may stop vehicies from entering and leaving the roundabout, so expected queue lengths on the round- about exits between the metering signal and the circulatory roadway should be compared with the proposed queuing space. Because of additional objectives and constraints, metering by upstream signals is generally not as effective as direct entrance metering. However, a signalized pe- destrian crossing may be desirable on its own merits. More than one entrance can be metered, and the analyst needs to identify operational states and evaluate each one separately to provide a weighted aggregate performance measure. When disabled pedestrians and/or school children are present at a high-volume site, a pedestrian-actuated traffic signal could be placed 20 to 50 m(65 to 165 ft) from the yield line. This longer distance than at an unsignalized crossing may be required because the vehicle queues downstream of the roundabout exit will be longer. The trade-offs for any increased distance requirement are increased walk- ing distances and higher exiting vehicle speeds. An analysis of signal timing will be needed to minimize queuing of vehicles into the roundabouts. IFederal HighwayAdministration 8.7.3 Full signalization of the circulatory roadway Full signalization that includes control of circulating traffic at junctions with major entrances is possible at large-diameter multilane traffic circles or rotaries that have adequate storage space on the circulatory roadway. The double-lane roundabout dimensions resulting from the design criteria recommended in this guide may pre- clude such possibilities. As stated previously, full signalization should in any case only be considered as a retrofit alternative resulting from unanticipated traffic de- mands. Other feasible alternatives should also be considered, such as flaring criti- cal approaches, along with the associated widening of the circulatory roadway; converting a large-diameter rotary to a more compact modern roundabout form; or converting to a conventional signalized intersection. This guide recommends that signalizing roundabouts to improve capacity be considered only when it is the most cost-effective solution. Traffic signals at fully signalized rotaries should be timed carefully to prevent queu- ing on the circulatory roadway by ensuring adequate traffic progression of circulat- ing traffic and especially critical movements. Introducing continuous or part-time signals on the circulatory roadway requires careful design of geometry, signs, lane markings, and signal timing settings, and literature on this specific topic should be consulted (1, 2►. 8.2 At-Grade Rail Crossings Locating any intersection near an at-grade railroad crossing is generally discour- aged. However, roundabouts are sometimes used near railroad-highway at-grade crossings. Rail transit, including stations, have successfully been incorporated into the medians of approach roadways to a roundabout, with the tracks passing through the central island. In such situations, the roundabout either operates partially dur- ing train passage, or is completely closed to allow the guided vehicles or trains to pass through. The treatment of at-grade rail crossings should follow primarily the recommendations of the Manual on UniformTraffic Control Devices (MUTCD) (3). Another relevant reference is the FHWA Railroad-Highway Grade Crossing Hand- book (4). There are essentially two ways in which rails can interact with a roundabout, as shown in Exhibit 8-1: • Through the center; or • Across one leg in close proximity to the roundabout. Full signalization of the circulatory roadway requires careful coordination and vehicle progression. Roundabouts: An Informational Guide • 8: System Considerations I��;$p In either case, traffic must not be forced to stop on the tracks. A new intersection should not be designed with railroad tracks passing through the center of it. How- ever, on occasions, the rail line passes through an existing intersection area. The traffic engineer might be faced with a decision whether to change the intersection type to a roundabout or to grade-separate the crossing. A gated rail crossing through the center of a roundabout can be accommodated in two ways.The first method is to prevent all vehicular traffic from entering the round- about. The second method is to prevent traffic from crossing the tracks while still allowing some movements to occur. This latter method will have lower delays and queues, but it may be more confusing and less safe. A gated rail crossing adjacent to a roundabout can be accommodated in two ways, as shown in Exhibit 8-2: Closing only the leg with the � Method A: Closure only at rail crossing. This method prohibits vehicles from rail crossing may work if crossing the rails but still allows vehicles to enter and leave the circulatory road- queues are not anticipated to way.This method allows for many of the movements through the roundabout to back into the continue to run free, if a queue does not build to the point of impeding circula- circulatory roadway. tion within the roundabout. A queuing analysis should be performed using the expected volume crossing the rails and the expected duration of rail crossing to determine the likelihood that this blockage will occur. In general, this method works better than Method B if there is sufficient separation between the round- about and the rail crossing. If blockage is anticipated, the designer should choose Method B. Exhibit &1. Rail crossing treatments at roundabouts. Method 8: Closure at rail crossing and at most entries to the roundabout. This method closes all entries to the roundabout except for the entry nearest the rail crossing.This allows any vehicles in the roundabout to clear prior to the arrival of the train. In addition, a gate needs to be provided on the approach to the rail crossing exiting the roundabout to protect against possible U-turns in the round- about. This causes increased queuing on all approaches but is generally safer than Method A when there is insufficient storage capacity between the round- about and rail crossing. � /1 ,� (a) Center Crossing (not desirable) � � � (b) Approach Crossing � f ,R I Federal HighwayAdministration 1 I� / �. / � / \ / � I � �� /� � � � I � IJ � � y / � / � � ♦ � ♦ � � � i � (a) Closure only at rail crossing (b) Closure at rail crossing and at most entries to roundabout 8.3 Closely Spaced Roundabouts It is sometimes desirable to consider the operation of two or more roundabouts in close proximity to each other. In these cases, the expected queue lengths at each roundabout become important. Exhibit 8-3 presents an example of closely spaceci T-intersections.The designer should compute the 95th-percentile queues for each approach to check that sufficient queuing space is provided for vehicles between the roundabouts. If there is insufficient space, then drivers will occasionally queue into the upstream roundabout and may cause it to lock. Exhibit 8-2. Methods for accommodating a rail crossing adjacent to a roundabout. Roundabouts: An Informational Guide • 8: System Considerations I 217 Exhibit 8-3. Example of closely spaced offset T-intersection with roundabouts. Closely spaced roundabouts may have a traffic calming effect on the major road. Exhibit 8-4. Through bypass lanes at staggered Tintersections. Option A (roundabout precedes bypass) is preferred. France (5) Closely spaced roundabouts may improve safety by "calming" the traffic on the major road. Drivers may be reluctant to accelerate to the expected speed on the arterial if they are also required to slow again for the next close roundabout. This may benefit nearby residents. When roundabouts are used at offset T-intersections, there is an opportunity to bypass one through lane direction on the major road at each roundabout. Exhibit 8-4 presents sketches of through bypass lanes for the two basic types of offset T-intersection configurations. In both cases, through traffic in each direction needs to negotiate only one roundabout, and capacity is therefore typically improved.The weaving section should be analyzed both for capacity and for safety through an evaluation of the relative speeds of the weaving vehicles. 218 � Federal HighwayAdministration Of the two arrangements shown in Exhibit 8-4, Option A(roundabout precedes bypass) is preferred. The roundabout offers a visual cue to drivers to slow in Ar- rangement A and encourages slower (and therefore safer) driving through the two roundabouts. If Option B(bypass precedes roundabout) is used, the merges and diverges could occur at higher speeds. It may be appropriate in this case to omit the bypass lane and pass all through traffic through both roundabouts. Another advantage of Option A is that there would be less queuing of traffic on the road space between the roundabouts. Note that when conventional T-intersections are used, Option A is less preferable than Option B due to the need to provide interior storage space for left turns in Option A. Therefore, roundabouts may be a satisfactory solution for cases like Option A. 8.4 Roundabout Interchanges Freeway ramp junctions with arterial roads are potential candidates for roundabout intersection treatment. This is especially so if the subject interchange typically has a high proportion of left-turn flows from the off-ramps and to the on-ramps during certain peak periods, combined with limited queue storage space on the bridge crossing, off-ramps, or arterial approaches. In such circumstances, roundabouts operating within their capacity are particularly amenable to solving these problems when compared with other forms of intersection control. 8.4.1 Two-bridge roundabout interchange There are two basic types of roundabout interchanges.The first is a large diameter roundabout centered over or under a freeway. The ramps connect directly into the roundabout, as do the legs from the crossroad. This is shown in Exhibit 8-5. Source. Based on 16) Exhibit &5. Two-bridge roundabout interchange. The freeway may go either over or under the circulatory roadway. Roundabouts: An Informational Guide • 8: System Considerationa I 279 6chibit 8-6. Examples of two-bridge roundabout interchanges. This type of interchange requires two bridges. If the roundabout is above the free- way as shown in Exhibit 8-5, then the bridges may be curved. Alternatively, if the freeway goes over the roundabout then up to four bridges may be required. The number of bridges will depend on the optimum span of the type of structure com- pared with the inscribed diameter of the roundabout island and on whether the one bridge is used for both freeway directions or whether there is one bridge for each direction. The road cross-section will also influence the design decision. Ex- hibit 8-6 shows an example from the United Kingdom.The designer should decide if the expected speeds of vehicles at larger roundabouts are acceptable. A50/Heron Cross, United Kingdom (mirrored to show right-hand-side driving) 8.4.2 One-bridge roundabout interchange The second basic type uses a roundabout at each side of the freeway and is a specific application of closely spaced roundabouts discussed in the previous sec- tion. A bridge is used for the crossroad over the freeway or for a freeway to cross over the minor road. Again, two bridges may be used when the freeway crosses over the minor road. One-bridge roundabout This interchange form has been used successfully in some cases to defer the need interchanges have been to widen bridges. Unlike signalized ramps that may require exclusive left-turn lanes successfully used to defer the across the bridge and extra queue storage, this type of roundabout interchange need for bridge widening. exhibits very little queuing between the intersections since these movements are almost unopposed. Therefore, the approach lanes across the bridge can be mini- mized. The actual roundabouts can have two different shapes or configurations. The first configuration is a conventional one with circular central islands. This type of con- figuration is recommended when it is desirable to allow U-turns at each round- about or to provide access to legs other than the cross street and ramps. Examples from the United Kingdom and France are shown in Exhibit 8-7 220 I Federal HighwayAdministration ;;� -�: • - :r�% � rr � C G�" �.i'� � � _�. r ^^, �� , . . . � '�KI x�..�,.,.at .. "� .::� �a� ;�:..-.. _ ,�,�. r �, . . � '� — �. � �r� ! � ,, .. � . , � �� . � ��n .� �' 'K . � _ �, ;,, �__ � _ ,��C...., g"`w k �„',� � = _ . I „ • ' - "" � ��w�,�.*�, , _ � .r.• ' � *�' T �° . I ._. �<� � y�,,;�"��' t.. . � . - �.. . �"tl� ,�,:.... < . w _: i .. - I .�r„ France Exhibit 8-7. Examples of one-bridge roundabout interchanges with circular central islands. Exhibit 8-7 (continued). Examples of one-bridge roundabout interchanges with circular central islands. Roundabouts: An Informational Guide • 8: System Considerations I 227 Raindrop central islands make The second configuration uses raindrop-shaped central islands that preclude some wrong-way movements more turns at the roundabout.This configuration is best used when ramps (and not front- difficult, but require navigating age roads) intersect at the roundabout. A raindrop central island can be considered two roundabouts to to be a circular shape blocked at one end. In this configuration, a driver wanting to make a U-tum. make a U-turn has to drive around both raindrop-shaped central islands. This con- figuration has an additional advantage in that it makes wrong-way turns into the off-ramps more difficult. On the other hand, drivers do not have to yield when approaching from the connecting roadway between the two roundabouts. If the roundabout is designed poorly, drivers may be traveling faster than they should to negotiate the next roundabout safely.The designer should analyze relative speeds to evaluate this alternative. On balance, if the length of the connecting road is short, this design may offer safety advantages. Exhibit 8-8 provides an example of this type of interchange configuration. Exhibit 8-8. One-bridge roundabout interchange with raindrop-shaped central islands. Interstate 70/Avon Road, Avon, CO 8.4.3 Analysis of roundabout interchanges The traffic performance evaluation of the roundabout interchange is the same as for a single conventional roundabout. The maximum entry capacity is dependent on the circulatory flow and the geometry of the roundabouts. The evaluation pro- cess is included in Chapter 4. Roundabouts produce more The benefits and costs associated with this type of interchange also follow those random headways on ramps for a single roundabout. A potential benefit of roundabout interchanges is that the than signalized intersections, queue length on the off-ramps may be less than at a signalized intersection. In resulting in smoother merging almost all cases, if the roundabout would operate below capacity, the performance behavior on the freeway. of the on-ramp is likely to be better than if the interchange is signalized. The head- way between vehicles leaving the roundabout along the on-ramp is more random than when signalized intersections are used.This more random ramp traffic allows for smoother merging behavior on the freeway and a slightly higher performance at the freeway merge area compared with platooned ramp traffic from a signalized intersection. ZZg � Federal HighwayAdministration The traific at any entry is the same for both configurations. The entry capacity is the same and the circulating flow is the same for the large single roundabout (Ex hibit 8-6) and for the second configuration of the two teardrop roundabout system (Exhibit 8-8). Note that the raindrop form may be considered and analyzed as a single large roundabout as in the circular roundabout interchange, but with a "pinched" waistline across or under one bridge rather than two.The relative perfor- mance of these systems will only be affected by the geometry of the roundabouts and islands.The system with the two circular roundabouts will have a slightly differ- ent performance depending upon the number of U-turns. 8.4.4 Geometric design parameters The design parameters are not restrained by any requirement here.They are only constrained by the physical space available to the designer and the configuration selected. The raindrop form can be useful if grades are a design issue since they remove a potential cross-slope constraint on the missing circulatory road segments. If there are more roads intersecting with the interchange than the single cross road, then two independent circular roundabouts are likely to be the best solution. 8.5 Roundabouts in an Arterial Network In order to understand how roundabouts operate within a roadway system, it is important to understand their fundamental arrival and departure characteristics and how they may interact with other intersections. Exhibit 8-9 gives an example of a series of roundabouts along an arterial street. Avon Road, Avon, CO Exhibit &9. Roundabouts in an arterial network. The Avon Road network consists of five roundabouts (all pictured)—two at the interchange ramp terminals and three along the arterial south of the freeway. Roundabouts: An Informational Guide • 8: System Considerations I�3 8.5.1 Platooned amvals on roundabout approaches Signalized intersections close The performance of a roundabout is affected by its proximity to signalized intersec- to roundabouts produce gaps tions. If a signalized intersection is very close to the roundabout, it causes vehicles in traffic that can be used by to enter the roundabout in closely spaced platoons; more importantly, it results in minor street traffic to enter the regular periods when no vehicles enter. These latter periods provide an excellent major street. opportunity for traffic on the next downstream entry to enter. Since the critical gap is larger than the follow-up time, a roundabout becomes more efficient when the vehicles are handled as packets of vehicles rather than as isolated vehicles. When the signalized intersection is some distance from the roundabout, then the vehicles' arrival patterns have fewer closely spaced platoons. Platoons tend to dis- perse as they move down the road. The performance of a roundabout will be re- duced under these circumstances when compared with a close upstream signal. If arrival speeds are moderate, then few longer gaps allow more drivers to enter a roundabout than a larger number of shorter gaps. If arrival speeds are low, then there are more opportunities for priority-sharing (where entering and circulating vehicles alternate) and priority-reversals (where the circulating vehicles tend to yield to entering vehicles) between entering and circulating traffic streams, and the influence of platoon dispersal is not as marked. 8.5.2 Roundabout departure pattern Traffic leaving a roundabout tends to be more random than if another type of inter- section control were used. A roundabout may therefore affect the performance of other unsignalized intersections or driveways more than if the intersection was signalized. However, as this traffic travels further along the road downstream of the roundabout, the faster vehicles catch up to the slower vehicles and the propor- tion of platooning increases. In the case of a well-defined platoon from an upstream signalized intersection arriving at a downstream unsignalized intersection just after a well-defined platoon arrives from the other direction, it may be difficult for the minor street drivers at this unsignalized intersection to enter the link. If, on the other hand, one of these signalized intersections were to be replaced by a roundabout, then the effect of the random traffic from the roundabout might be relatively advantageous. Under these conditions, more dispersed platoons (or random) traffic could assist drivers enter- ing along the link at the unsignalized intersection. Even one circulating vehicle in If a roundabout is used in a network of coordinated signalized intersections, then it a roundabout will result in a may be difficult to maintain the closely packed platoons required. If a tightly packed platoon breaking down. platoon approached a roundabout, it could proceed through the roundabout as long as there was no circulating traffic or traffic upstream from the left. Only one circu- lating vehicle would result in the platoon breaking down. Hence, the use of round- abouts in a coordinated signalized network needs to be evaluated carefully. One possibility for operating roundabouts within a signal network is to signalize the major approaches of the roundabout and coordinate them with adjacent upstream and downstream signalized intersections. 224 I Federal HighwayAdministration Another circumstance in which a roundabout may be advantageous is as an alter- native to signal control at a critical signalized intersection within a coordinated net- work. Such intersections are the bottlenecks and usually determine the required cycle length, or are placed at a signal system boundary to operate in isolated actu- ated mode to minimize their effect on the rest of the surrounding system. If a roundabout can be designed to operate within its capacity, it may allow a lowering of the system cycle length with resultant benefits to delays and queues at other intersections. Because roundabouts accommodate U-turns more easily than do signals, they may also be useful as an access management tool. Left-turn exits from driveways onto an arterial which may currently experience long delays and require two-stage left- turn movements could be replaced with a simpler right turn, followed by a U-turn at the next roundabout. 8.5.3 Wide nodes and narrow roads The ultimate manifestation of roundabouts in a system context is to use them in lieu of signalized intersections. Some European cities such as Nantes, France, and some Australian cities have implemented such a policy. It is generally recognized that intersections (or nodes), not road segments (or links), are typically the bottle- necks in urban roadway networks. A focus on maximizing intersection capacity rather than widening streets may therefore be appropriate. Efficient, signalized intersections, however, usually require that exclusive turn lanes be provided, with sufficient storage to avoid queue spillback into through lanes and adjacent inter- sections. In contrast, roundabouts may require more right-of-way at the nodes, but this may be offset by not requiring as many basic lanes on the approaches, relative to signalized arterials. This concept is demonstrated in Exhibit 8-10. Analysis tools, such as those provided in Chapter 4, should be used to evaluate the arterial or network.These may be supplemented by appropriate use of microscopic simulation models as discussed next. Supplemental techniques to increase the capacity of critical approaches may be considered if necessary, such as bypass lanes, flaring of approaches and tapering of exits, and signalization of some round- about approaches. Roundabouts as an access management tool. Roundabouts may require more right-of-way at intersections, but may also allow fewer lanes (and less right-of-way) between intersections. Roundabouts: An Informational Guide • 8: System Considerations I�,t" �? Exhibit 8-70. Wide nodes and narrow roads. �� I Federal HighwayAdministration 8.6 Microscopic Simulation Microscopic simulation of traffic has become a valuable aid in assessing the system performance of traffic flows on networks, as recognized by the Highway Capacity Manual Z000 (7). Analysis of many of the treatments discussed in this chapter may benefit from the use of appropriate simulation models used in conjunction with ana- lytic models of isolated roundabouts discussed in Chapter 4. These effects include more realistic modeling of arrival and departure profiles, time-varying traffic patterns, measurement of delay, spatial extent and interaction of queues, fuel consumption, emissions, and noise. However, the user must carefully select the appropriate mod- els and calibrate the model for a particular use, either against field data, or other validated analytic models. It would also be advisable to check with others to see if there have been any problems associated with the use of the model. 8.6.1 How to use simulation Microscopic simulation models are numerous and new ones are being developed, while existing models are upgraded frequently. Each model may have particular strengths and weaknesses.Therefore, when selecting a model, analysts should con- sider the following: • Should a simulation model be used, or is an isolated analytic roundabout model sufficient? • What are the model input requirements, are they sufficient, and how can they be provided or estimated? • What outputs does the model provide in animated, graphical, or tabular form? • What special features of the model are pertinent to the problem being addressed? • Does the user manual for the simulation model specifically address modeling a roundabout? • How sensitive is the model to various geometric parameters? • Is there literature on the validation of this model for evaluating roundabouts? • Is there sufficient information available on the microscopic processes being used by the model such as car following, gap acceptance, lane changing, or steering? (The availability of animation can assist in exposing model logic.) • Are relevant past project examples available? When a simulation model is used, the analyst is advised to use the results to make relative comparisons of the differences between results from changing conditions, and not to conclude that the absolute values found from the model are equivalent to field results. It is also advisable to perform a sensitivity analysis by changing selected parameters over a range and comparing the results. If a particular parameter is found Roundabouts: An Informational Guide •& System Considerations I��; Simulation results are best used for relative comparisons, rather than relying on absolute values produced by the model. Exhibit 8-1t Summary of simulation models for roundabout analysis. Name Scope CORSIM to affect the outcomes significantty, then more attention should be paid to accu- rate representation and calibration of this parameter. Finally, the analyst should check differences in results from using different random number seeds. If the dif- ferences are large, then the simulation time should be increased substantially. 8.6.2 Examples of simulation models Five commercially available microscopic simulation models are CORSIM, Integra- tion, Simtraffic, Paramics, and VISSIM. The first three are North American models; Paramics is from Scotland, and VISSIM is from Germany. The following sections present a brief overview of each model. Since software packages (and simulation models in particular) are in constant development, the user is encouraged to con- sult the most current information available on each model. Notes (1999 versions) Urban streets, freeways FHWA has been investigating modifications that may be required for CORSIM to adequately model controls such as stop and yield control at roundabouts through gap acceptance logic. In this research, roundabouts have been coded as a circle of four yield-controlledT-intersections. The effect of upstream signals on each approach and their relative offsets has also been reported (8). Integration Urban streets, freeways Integration has documented gap acceptance logic for permitted movements at signal-, yield-, and stop-controlled intersections. As with CORSIM, Integration requires coding a roundabout simply as a series of short links and nodes with yield control on the entrances. Simtraffic Urban streets Simtraffic is a simulation model closely tied to the signal timing software package Synchro. Simtraffic has the capability to model unsignalized intersections and thus may be suitable for modeling roundabouts. However, no publications to date have demonstrated the accuracy of Simtraffic in modeling roundabout operations. Paramics Urban streets, freeways Paramics has been used in the United Kingdom and internationally for a wide range of simulation projects. It has been specifically compared with ARCADY in evaluating roundabouts (9).The model has a coding feature to automatically code a roundabout intersection at a generic node, which may then be edited. The model has been used in the United Kingdom for a number of actual roundabout evaluations.The model specifically employs a steering logic on the circulatory roadway to tradc a vehicle from an entry vector to a target exit vector (10). VISSIM Urban streets, transit networks VISSIM is widely used in Germany for modeling urban road and transit networks, including roundabouts. Roundabout examples are provided with the software, including explicit modeling of transit and pedestrians. Modeling a roundabout requires detailed coding of link connectors, control, and gap acceptance parameters (11). IFederal HighwayAdministration 8.7 References 1. Brown, M. TRL State of theArt Review—The Design of Roundabouts. London: HMSO, 1995. 2. Hallworth, M.S. "Signalling Roundabouts:' In Traffic Engineering + Control, Vol. 33, No. 6, June 1992. 3. Federal Highway Administration (FHWA). Manual on Uniform Traffic Control Devices. Washington, D.C.: FHWA, 1988. 4. Federal Highway Administration. Railroad-Highway Grade Crossing Handbook, 2nd edition. Report number FHWA-TS-86-215, September 1986. 5. Centre D'Etudes sur les Reseaux, IesTransports, I'Urbanisme, et les Construc- tions Publiques (CERTU) (Center for Studies onTransportation Networks, Urban Planning, and Public Works). Carrefours Urbains (Urban lntersections) Guide. Lyon, France: CERTU, January 1999. 6. Department ofTransport (United Kingdom). Geometric Design of Roundabouts. TD 16/93. September 1993. 7. Transportation Research Board. Highway Capacity Manual. Special Report 209. Washington, D.C.: Transportation Research Board, National Research Council, July 1999 (draft). 8. Courage, K.G. "Roundabout Modeling in CORSIM" Presented at theThird Inter- national Symposium on Intersections withoutTraffic Signals, Portland, Oregon, U.S.A., 1997. 9. Paramics, Ltd. "Comparison of Arcady and Paramics for Roundabout Flows" Version 0.3. August 23, 1996. 10.Duncan, G. "ParamicsTechnical Report: Car-Following, Lane-Changing and Junc- tion Modelling" Edinburgh, Scotland: Quadstone, Ltd., 1997. 11. Innovative Transportation Concepts, LLC. VISSIM—User Manual. Program Ver- sion 2.32-2.36. November 10, 1997. Roundabouts: An Informational Guide • 8: System Considerations �, Glossary 85th-percentile speed—a speed value obtained from a set of field-measured speeds where only 15 percent of the observed speeds are greater (source: HCM 20001. AADT—see average annual daily iraffic. A AASHO—American Association of State Highway Officials. Predecessor to AASHTO. AASHTO—American Association of State Highway andTransportation Officials. accessible—describes a site, building, facility, or portion thereof that complies with the Ameri- cans with Disabilities Act Accessibility Guidelines (source: ADAAGI. accessible route—a continuous, unobstructed path connecting all accessible elements and spaces of a building or facility. Exterior accessible routes may include parking access aisles, curb ramps, crosswalks at vehicular ways, walks, ramps, and lifts (source: ADAAG). accident—see crash. ADA—Americans with Disabilities Act. ADAAG—Americans with Disabilities Act Accessibility Guidelines. all-way stop control—all approaches at the intersections have stop signs where all drivers must come to a complete stop. The decision to proceed is based in part on the rules of the road, which suggest that the driver on the right has the right-of-way, and also on the traffic conditions of the other approaches (source: HCM 2000). angle, entry—see entry angle. approach—the portion of a roadway leading into a roundabout. approach capacity—the capacity provided at the yield line during a specified period of time. approach curvature—a series of progressively sharper curves used on an approach to slow traffic to a safe speed prior to reaching the yield line. approach road half-width—term used in the United Kingdom regression models. The ap- proach half width is measured at a point in the approach upstream from any entry flare, from the median line or median curb to the nearside curb along a line perpendicular to the curb. See also approach width. (source: UK Geometric Design of Roundabouts) approach speed—the posted or 85th-percentile speed on an approach prior to any geometric or signing treatments designed to slow speeds. approach width—the width of the roadway used by approaching traffic upstream of any changes in width associated with the roundabout. The approach width is typically no more than half the total roadway width. apron—the mountable portion of the central island adjacent to the circu/atory roadway. Used in smaller roundabouts to accommodate the wheel tracking of large vehicles. average annual daily traffic—the total volume passing a point or segment of a highway facility in both directions for one year divided by the number of days in the year (source: HCM 2000). average effective flare length—term used in the United Kingdom regression models. De- fined by a geometric construct and is approximately equivalent to the length of flare that can be effectively used by vehicles. (source: UK Geometric Design of Roundabouts) AWS�see all-way stop control. back of queue—the distance between the yield line of a roundabout and the tarthest reach of B an upstream queue, expressed as a number of vehicles.The vehicles previously stopped at the front of the queue may be moving (adapted from HCM 2000). Roundabouts: An Informational Guide • Glossary I�� benefit-cost analysis—a method of economic evaluation that uses the benefit-cost ratio as the measure of effectiveness. benefit-cost ratio—the difference in benefits between an alternative and the no-build sce- nario, divided by the difference in costs between the alternative and the no-build scenario. See also incremental benefit-cost ratio. bulb-out—see curb extension. C capacity—the maximum sustainable flow rate at which persons or vehicles can be reason- ably expected to traverse a point or uniform segment of a lane or roadway during a specified time period under a given roadway, geometric, traffic, environmental, and control conditions. Usually expressed as vehicles per hour, passenger cars per hour, or persons per hour (source: HCM 20001. capacity, approach—see approach capacity. capacity, roundabout—see roundabout capacity. capital recovery factor—a factor that converts a present value cost into an annualized cost over a period of n years using an assumed discount rate of i percent. central islanc�the raised area in the center of a roundaboutaround which traffic circulates. CFR—Code of Federal Regulations. channelization—the separation or regulation of conflicting traffic movements into definite paths of travel by traffic islands or pavement marking to facilitate the safe and orderly move- ments of both vehicles and pedestrians (source: 1994 AASHTO Green Bookl. circle, inscribe�see inscribed circle. circular intersection—an intersection that vehicles traverse by circulating around a central island. circulating flow—see circulating vo/ume. circulating path radius—the minimum radius on the fastest through path around the central island. circulating traffic—vehicles located on the circulatory roadway. circulating volume—the total volume in a given period of time on the circulatory roadway immediately prior to an entrance. circulatory roadway—the curved path used by vehicles to travel in a counterclockwise fash- ion around the central island. circulatory roadway width—the width between the outer edge of the circu/atory roadway and the central island, not including the width of any apron. circulating speed—the speed vehicles travel at while on the circulatory roadway. community enhancement roundabout—a roundabout used for aesthetic or community enhancement reasons, rather than as a solution to traffic problems. When used, often located in commercial and civic districts. conflict point—a location where the paths of two vehicles, or a vehicle and a bicycle or pedestrian, merge, diverge, cross, or queue behind each other. conflict, crossing—see crossing conflict. conflict, diverge—see diverge conflict. conflict, merge—see merge conflict. conflict, queuing—see queuing conflict. conflicting flows—the two paths that merge, diverge, cross, or queue behind each other at a conflict point. control delay—delay experienced by vehicles at an intersection due to movements at slower speeds and stops on approaches as vehicles move up in the queue. �3�. eI Federal HighwayAdministration crash—a collision between a vehicle and another vehicle, a pedestrian, a bicycle, or a fixed object. crash frequency—the average number of crashes at a location per period of time. crash rate—the number of crashes at a location or on a roadway segment, divided by the number of vehicles entering the location or by the length of the segment. CRF—see capita/ recovery factor. crossing conflict—the intersection of two traffic streams, including pedestrians. Crossing conflicts are the most severe type of conflict. curb eutension—the construction of curbing such that the width of a street is reduced. Often used to provide space for parking or a bus stop or to reduce pedestrian crossing distances. curb ramp—a short ramp cutting through a curb or built up to it (source: ADAAG). curvature, approach—see approach curvature. D factor—the proportion of the two-way traffic assigned to the peak direction. D deflection—the change in trajectory of a vehicle imposed by geometric features of the road- way. degree of saturation—see volume-to-capacity ratio. delay—additional travel time experienced by a driver, passenger, or pedestrian beyond what would reasonably be desired for a given trip. delay, control—see control de/ay. delay, geometric—see geometric delay. demand flow—the number of vehicles or persons that would like to use a roadway facility during a specified period of time. departure width—the width of the roadway used by departing traffic downstream of any changes in width associated with the roundaboui. The departure width is typically no more than half the total roadway width. design user—any user (motorized or nonmotorized) that can be reasonably be anticipated to use a facility. design vehicle—the largest vehicle that can reasonably be anticipated to use a facility. detectable warning surfac�a standardized surtace feature built in or applied to walking surfaces or other elements to warn visually impaired people of hazards on a circulation path (source: ADAAG). diameter, inscribed circl�see inscribed circle diameter. distance, set-back—see set-back distance. diverge conflict—the separation of two traffic streams, typically the least severe of all con- flicts. double-lane roundabout—a roundabout that has at least one entry with two lanes, and a circulatory roadwaythat can accommodate more than one vehicle traveling side-by-side. downstream—the direction toward which traffic is flowing (source: HCM 2000). entering traffic—vehicles located on a roundaboutentrance. E entering volume—the total volume in a given period of time on an entrance to a roundabout. entry angl�term used in the United Kingdom regression models. It serves as a geometric proxy for the conflict angle between entering and circulating streams and is determined through a geometric construct. (source: UK Geometric Design of Roundabouts) entry flar�the widening of an approach to multiple lanes to provide additional capacity at the yield line and storage. entry flow—see entering volume. Roundabouts: An Informational Guide • Glossary entry path curvature—term used in the United Kingdom to describe a measure of the amount of entry deflection to the right imposed on vehicles at the entry to a roundabout. lsource: UK Geometric Design of Roundabouts) entry path radius—the minimum radius on the fastest through path prior to the yield line. entry radius—the minimum radius ot curvature of the outside curb at the entry. entry speed—the speed a vehicle is traveling at as it crosses the yield line. entry width—the width of the entry where it meets the inscribed circle, measured perpen- dicularly from the right edge of the entry to the intersection point of the left edge line and the inscribed circle. entry, perpendicular—see perpendicular entry. exit path radius—the minimum radius on the fastest through path into the exit. exit radius—the minimum radius of curvature of the outside curb at the exit. exit width—the width of the exit where it meets the inscribed circ/e, measured perpendicu- larly from the right edge of the exit to the intersection point of the left edge line and the inscribed circ/e. exiting traffic—vehicles departing a roundabout by a particular exit. extended splitter island—see splitter island, extended. F FHWA—Federal HighwayAdministration. flare—see entry flare. flare, entry—see entry flare. flow, circulating—see circulating volume. flow, demand—see demand flow. flow, entry—see entry volume. flows, conflicting—see conflicting flows. G geometric delay—the delay caused by the alignment of the lane or the path taken by the vehicle on a roadway or through an intersection. geometric design—a term used in this document to describe the design of horizontal and vertical alignment and cross-sectional elements of a roadway. give way—term used in the United Kingdom and Australia for yield. "give way" rule—rule adopted in the United Kingdom in November 1966 which required that all vehicles entering a roundabout give way, or yield, to circulating vehicles. H HCM—Highway Capacity Manual. IES—Illuminating Engineers Society. incremental benefit-cost rati�the difference in benefits between two alternatives, divided by the difference in costs between the two alternatives. See also benefit-cost ratio. inscribed circle—the circle forming the outer edge of the circulatory roadway. inscribed circle diameter—the basic parameter used to define the size of a roundabout, measured between the outer edges of the circulatory roadway. It is the diameter of the larg- est circle that can be inscribed within the outline of the intersection. interchange—a grade-separated junction of two roadways, where movement from one road- way to the other is provided for. y�ij; Federal HighwayAdministration intersection—an at-grade junction of two or more roadways. intersection sight distance—the distance required for a driver without the right-of-way to perceive and react to the presence of conflicting vehicles. island, central—see centra/ island. island, median—see splitter is/and. island, separator—see splitter island. island, splitter—see splitter island. ITE—Institute ofTransportation Engineers. K factor—the proportion of the AADT assigned to the design hour. K left-turn path radius—the minimum radius on the fastest path of the conflicting left-turn L movement. level of servic�a qualitative measure describing operational conditions within a traffic stream, generally described in terms of service measures such as speed and travel time, freedom to maneuver, traffic interruptions, comfort, and convenience. line, yield—see yield line. locking—stoppage of traffic on the circulatory roadway caused by queuing backing into the roundabout from one of the exits, resulting in traffic being unable to enter or circulate. LOS—see /eve/ of service. maximum service volum�the maximum hourly rate at which vehicles, bicycles, or per- M sons can be reasonably expected to traverse a point or uniform section of a roadway during an hour under specific assumed conditions while maintaining a designated level of service. (source: HCM 2000) measures of effectiveness—a quantitative parameter whose value is an indicator of the performance of a transportation facility or service from the perspective of the users of the facility or service. median island—see splitter island. merge conflict—the joining of two traffic streams. mini-roundabout—small roundabouts used in low-speed urban environments. The central island is fully mountable, and the splitter islands are either painted or mountable. model, crash prediction—see crash prediction model. modem roundabout—a term used to distinguish newer circu/ar intersections conforming to the characteristics of roundabouts from older-style rotaries and traffic circles. m.o.e.—see measures of effectiveness. mountable—used to describe geometric features that can be driven upon by vehicles with- out damage, but not intended to be in the normal path of traffic. multilane roundabout—a roundabout that has at least one entry with two or more lanes, and a circulatory roadway that can accommodate more than one vehicle traveling side-by- side. MUTCD—Manual on UniformTraffic Control Devices. neighborhood traffic circle—a circular intersection constructed at the intersection of two N local 5treets for traffic calming and/or aesthetic purposes.They are generally not channelized, may be uncontrolled or stop-controlled, and may allow left turns to occur left (clockwise) of the central island. Roundabouts: An Informational Guide • Glossary �; nonconforming traific circle—see traffic circle. nontraversable—see raised. O O&M costs—operations and maintenance costs. P peak hourfactor—the hourly volume during the maximum-volume hour of the day divided by the peak 15-minute flow rate within the peak hour; a measure of traffic demand fluctuation within the peak hour. pedestrian refuge--an at-grade opening within a median island that allows pedestrians to safely wait for an acceptable gap in traffic. perpendicular entry—an entry angle of 70 degrees or more. PHF—see peak hour facior. platoon—a group of vehicles or pedestrians traveling together as a group, either voluntarily or involuntarily because of signal control, geometrics, or other factors. point, conflict—see conflici point. priority—the assignment of righi-of-wayto a particular traffic stream or movement. progression, signal—see signal progression. Q queue—a line of vehicles, bicycles, or persons waiting to be served by the system in which the flow rate from the front of the queue determines the average speed within the queue. Slowly moving vehicles or persons joining the rear of the queue are usually considered a part of the queue.The internal queue dynamics may involve a series of starts and stops. (source: HCM 2000) queuing conflict—a conflict that arises within a traffic stream between a lead vehicle and a following vehicle, when the lead vehicle must come to a stop. R radius, circulating path—see circulating path radius. radius, entry—see entry radius. radius, entry path—see entry path radius. radius, exit—see exit radius. radius, exit path—see exit path radius. radius, left-tum path—see left-turn path radius. radius, right-turn path—see right-turn path radius. raised—used to describe geometric features with a sharp elevation change that are not in- tended to be driven upon by vehicles at any time. ramp, wheelchair—see wheelchair ramp. refuge, pedestrian—see pedestrian refuge. right-of-way—(1) an intersection user that has priorityover other users. (2) Land owned by a public agency for transportation uses. right-tum bypass lan�-a lane provided adjacent to, but separated from, the circulatory roadway, that allows right-turning movements to bypass the roundabout. Also known as a right-turn slip lane. right-tum path radius—the minimum radius on the fastest path of a right-turning vehicle. right-tum slip lane—see right-turn bypass lane. roadway, circulatory—see circulatory roadway. ;� I Federal HighwayAdministration *:. rotary—a term used particularly in the Eastern U.S. to describe an older-style circular inter- section that does not have one or more of the characteristics of a roundabout.They often have large diameters, often in excess of 100 m(300 ft1, allowing high travel speeds on the circula- tory roadway. Also known as a traffic circle. roundabout—a circular intersection with yield control of all entering traffic, channelized ap- proaches, counter-clockwise circulation, and appropriate geometric curvature to ensure that travel speeds on the circulatoryroadwayare typically less than 50 km/h (30 mph). roundabout capacity—the maximum number of entering vehicles that can be reasonably expected to be served by a roundaboutduring a specified period of time. roundabout, community enhancement—see community enhancement roundabout. roundabout, modern—see modern roundabout. roundabout, multilane—see multilane roundabout. roundabout, rural double-lan�see rural double-lane roundabout. roundabout, rural single-lane—see rural single-lane roundabout. roundabout, single lane—see single-lane roundabout. roundabout, urban compact—see urban compact roundabout. roundabout, urban single-lane—see urban single-lane roundabout. rural double-lane roundabout—a roundabout located in a rural area that has at least one entry with two lanes, and a circulatory roadwaythat can accommodate more than one vehicle traveling side-by-side. They incorporate approach curvature to slow entering traffic to a safe speed. rural single-lane roundabout—a roundabout located in a rural area that has single lanes on all entries and one circulatory Iane.This form typically has larger diameters and more tangen- tial exits than urban forms. separator island—see median island. service volum�the hourly rate at which vehicles, bicycles, or persons can be reasonably expected to traverse a point or uniform section of a roadway during an hour under specific assumed conditions. See also maximum service volume. (Adapted from HCM 2000) set-back distanc�the distance between the edge of the circulatory roadway and the side- walk. sharpness of flar�a measure of the rate at which extra width is developed in the entry flare. (source: UK Geometric Design of Roundabouts) sight distance, intersection—see intersection sight distance. sight distance, stopping—see stopping sight distance. sight triangl�an area required to be free of obstructions to enable visibility between con- flicting movements. signal progression—the use of coordinated traffic signals along a roadway in order to mini- mize stops and delay to through traffic on the major road. single-lane roundabout—a roundaboutthat has single lanes on all entries and one circula- tory lane. speed table—an extended, flat-top road hump sometimes used at pedestrian crossings to slow traffic and to provide a better visual indication of the crosswalk location. speed, approach—see approach speed. speed, circulating—see circulating speed. speed, entry—see entry speed. S I �� - Roundabouts: An Informational Guide • Glossary splitter island—a raised or painted area on an approach used to separate entering from exit- ing traffic, deflect and slow entering traffic, and provide storage space for pedestrians cross- ing that intersection approach in two stages. Also known as a median island or a separator island. splitter island, extended—a raised splitter island that begins some distance upstream of the pedestrian crossing to separate entering and exiting traffic. A design feature of rural round- abouts. stopping sight distanc�the distance along a roadway required for a driver to perceive and react to an object in the roadway and to brake to a complete stop before reaching that object. T traffic calming—geometric treatments used to slow traffic speeds or to discourage the use of a roadway by nonlocal traffic. traffic circle—a circular intersection that does not have one or more of the characteristics of a roundaboui. Also known as a rotary. traffic circle, neighborhood—see neighborhood traffic circle. traffic circle, nonconforming—see traffic circle. traffic design—a term used in this document to describe the design of traffic control devices, including signing, pavement markings, and construction traffic control. traffic, circulating—see circulating traffic. traffic, entering—see entering traffic. truck apron—see apron. two-stage crossing—a process in which pedestrians cross a roadway by crossing one direc- tion of traffic at a time, waiting in a pedestrian refuge between the two traffic streams if necessary before completing the crossing. two-way stop-control—stop signs are present on the approach(es) of the minor street. Driv- ers on the minor street or drivers turning left from the major street wait for a gap in the major street traffic in order to complete a maneuver. TWS�see two-way stop control. U U-turn—a turning movement at an intersection in which a vehicle departs the intersection using the same roadway it used to enter the intersection. upstream—the direction from which traffic is flowing (source: HCM 2000). urban compact roundabout—a small roundaboui with a raised central is/and and splitter is/ands, with perpendicular approaches that require vehicles to make a distinct right turn into the circulatory roadway urban double-lane roundabout—an urban roundabout with at least one entry with two lanes, and a circulaiory roadwaythat can accommodate more than one vehicle traveling side- by-side. They have similar speed characteristics as urban single-lane roundabouts. urban single-lane roundabout—a roundaboutwith single lane entries on all legs and one circulatory lane. Entries are less perpendicular than the urban compact roundabout, allowing somewhat higher speeds with higher capacities. UVC—UniformVehicle Code. V vehicle, design—see design vehicle. volume, circulating—see circulating volume. volume, entering—see entering volume. volume, service—see service volume. volume-to-capacity ratio—the ratio of flow rate to capacity for a transportation facility. �.;, I Federal HighwayAdministration wheelchair ramp—see curb ramp. w width, approach—see approach width. width, circulatory roadway—see circulatory roadway width. width, departure—see departure width. width, entry—see entry width. width, exit—see exit width. yield—an intersection control in which controlled traffic must stop only if higher prioritytraffic Y is present. yield line—a pavement marking used to mark the point of entry from an approach into the circu/atory roadway and generally marked along the inscribed circ/e. If necessary, entering traffic must yield to circu/ating traffic before crossing this line into the circulatory roadway. zebra crossing—a crossing marked by transverse white stripes where vehicles are required Z to yield to pedestrians. Roundabouts: An Informational Guide • Glossary I� Bibliography 5.1 U.S. References American Association of State Highway Officials (AASHO). A Policy on Design of Urban High- ways andArterial Streets. Washington, D.C.: AASHO, 1973. American Association of State Highway andTransportation Officials (AASHTO). Guide for De- velopment of Bicycle Facilities. Washington, D.C.: AASHTO, 1991. —. An Information Guide for Roadway Lighting. Washington, D.C.: AASFffO, 1985. —. A Manual on User BenefitAnalysis of Highway and BusTransit Improvements. Washing- ton, D.C.: AASHTO, 1977. —. A Policy on Geometric Design of Highways and Streets. Washington, D.C.: AASHTO, 1994. —. Roadside Design Guide. Washington, D.C.: AASHTO, 1989. —. Standard Specifications for Structural Supports for Highway Signs, Luminaires and Traffic Signals. Washington, D.C.: AASHTO, 1994. Americans with Disabilities ActAccessibility Guidelines for Buildings and Facilities (ADAAG). 36 CFR Part 1191. As amended through January 1998. Federal Highway Administration (FHWA). Manual on Uniform Traffic Contro/ Devices. Wash- ington, D.C.: FHWA, 1988. —. O/der Driver Highway Design Handbook. Publication No. FHWA-RD-97-135. Washington, D.C.: FHWA, January 1998. —. Standard Highway Signs. Washington, D.C.:, FHWA, 1979. —. Railroad-Highway Grade Crossing Handbook, 2nd edition. Report number FHWA-TS-86- 215, September 1986. . Illuminating Engineering Society (IES). American National Standard Practice forRoadwayLight- ing. Standard RP-8. December 1982. Institute of Transportation Engineers. Manual of Transportation Engineering Studies (H.D. Robertson, J.E. Hummer, and D.C. Nelson, ed.). Englewood Cliffs, N.J.: Prentice-Hall, 1994. —. Transportation Planning Handbook (J. Edwards, Jr., ed.). Englewood Cliffs, New Jersey: Prentice Hall, 1992. National Committee on UniformTraffic Laws and Ordinances (NCUTLO). UniformVehicle Code and ModelTraffic Ordinance. Evanston, Illinois: NCUTLO, 1992. Pein, W.E. Trail lnterseciion Design Guidelines. Prepared for State Bicycle/Pedestrian Program, State Safety Office, Florida Department ofTransportation. Highway Safety Research Center, University of North Carolina. September 1996. �� Federal HighwayAdministration � ��"� I Transportation Research Board. Highway Capacity Manual. Special Report 209. Washington, D.C.:Transportation Research Board, National Research Council, 1994. —. HighwayCapacity Manual. Special Report 209. Washington, D.C.:Transportation Research Board, National Research Council, July 1999 (draft). 5.2 Roundabout Design Guides 5.2.1 United States Florida Department ofTransportation. Florida Roundabout Guide. Florida Department ofTrans- portation, March 1996 Maryland Department ofTransportation. Roundabout Design Guidelines. State of Maryland Department ofTransportation, State HighwayAdministration, 1995. Ourston & Doctors, Inc. Roundabout Design Guidelines. 1995. 5.2.2 Australia/New Zealand Australia/New Zealand Standard. Road lighting. Part 1.3: Vehicular traffic (Category V) light- ing—Guide to design, installation, operation and maintenance. Report no. AS/NZS 1158.1.3:1997. Published jointly by Homebush, New South Wales (Australia): Standards Australia and Wellington (New Zealand): Standards New Zealand. 1997 Austroads. Guide to Traffic Engineering Practice, Part 6—Roundabouts. Sydney, Australia: Austroads, 1993. Queensland Department of Main Roads (QDMR), Road Planning and Design Guidelines (Draft), Chapter 12, Section 12.4—Roundabouts. Brisbane, Australia: QDMR, 1999. Queensland Department of Main Roads (QDMR). Relationships between Roundabout Geom- etryandAccident Rates. Queensland, Australia: Infrastructure Design of theTechnology Divi- sion of QDMR, April 1998. Roads and Traffic Authority (RTA), New South Wales (Australia). Roundabouts—Geometric Design Method. January 1997. Roundabouts: A Design Guide, National Association of Australian State Road Authorities, 1986. 5.2.3 Germany Small Roundabouts: Recommendations forApplication and Design, Nordrhein-Westfalen De- partment of City Development andTraffic (MSV), prepared by Werner Brilon, Ruhr-University Bochum; translated from German by Daniel J. Parrish, 1993. Haller, et al. Merkb/att fur die Anlage von k/einen Kreisverkehrsplatzen ( Guideline for the Con- struction of Small Roundabouts). Cologne, Germany: Forschungsgesellschaft fur Stra3en- und Verkehrswesene. V., August 1998. Department ofTransport of Northrhine-Westfalia, Germany. Empfehlungen zum Einsatz und zur Gestaltung von Mini-Kreisverkehrsplaetzen ( Guidelines for the Use and Design of Mini- Roundaboutsl. Dusseldorf, Germany, 1999. Roundabouts: An Informational Guide • Bibliography I ��' 5.2.4The Netherlands C.R.O.W. Eenheid in rotondes (Uniformity in roundabouts). Publication 126. Ede, The Nether- lands: C.R.O.W., March 1998. Centrum voor Regelgeving en Onderzoek in de Grond-, Water- en Wegenbouw en de Verkeerstechniek (C.R.O.WI. Rotondes (Roundabouts). Ede,The Netherlands: C.R.O.W. De- cember 1993. 5.2.5 United Kingdom Department of Transport (United Kingdom). Geometric Design of Roundabouts. TD 16/93. September 1993. Sawers, C. Mini-roundabouts: Getting them right!. Canterbury, Kent, United Kingdom: Euro- Marketing Communications, 1996 5.2.6 France Service d'EtudesTechniques des Routes et Autoroutes (SETRA—Center forTechnical Studies of Roads and Highways). Amenagement des Carrefours Interurbains sur les Routes Principales (De- sign of Rural Intersections on Major Roadsl. Ministry ofTransport and Housing, December 1998. Centre d'Etudes sur les Reseaux, IesTransports, I'Urbanisme et les constructions publiques (CERTU). L'Eclairage des Carrefours a Sens Giratoire (The Illumination of Roundabout Inter- sections). Lyon, France: CERTU, 1991. Centre d'Etudes sur les Reseaux, IesTransports, I'Urbanisme, et les Constructions Publiques CarRefours Urbainsrl Urban In�te srection ) G�de. Lyonr FranceaCERTUI, anuar ylgggWorks). 5.2.7 Spain Ministerio de Fomento. Recomendaciones sobre glorietas (Recommendations on roundabouts). Ministerio de Fomento, Direccion General de Carreteras, 1996. 5.3 Books and Reporis 5.3.1 United States Bauer, K.M., and D.W. Harwood. Statistical Models ofAt-Grade Intersection Crashes. Report No FHWA-RD-99-094. Washington, D.C.: Federal Highway Administration, 1999. Fambro, D.B., et al. NCHRP Report 400: Determination of Stopping Sight Distances. National Cooperative Highway Research Program,Transportation Research Board, National Research Council. Washington, D.C.: National Academy Press, 1997. Garder, P. The Modern Roundabouts: The Sensible Alternative for Maine. Maine Department ofTransportation, Bureau of Planning, Research and Community Services,Transportation Re- search Division, 1998. Glauz, W.D., and D.J. Migletz. NCHRP Report 219: Application ofTratfic ConflictAnalysis at Intersections. National Cooperative Highway Research Program,Transportation Research Board, National Research Council. Washington, D.C.: National Academy Press, 1980. Federal HighwayAdministration �` I Harwood, D.W., etal. NCHRPReport383: Intersection SightDistances. National Cooperative Highway Research Program,Transportation Research Board, National Research Council. Wash- ington, D.C.: National Academy Press, 1996. Institute ofTransportation Engineers. Use of Roundabouts, prepared by ITETechnical Council Committee 5B-17, February 1992. Jacquemart, G. Synthesis of Highway Practice 264: Modern Roundabout Practice in the United States. 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"Snow at Roundabouts" Maryland DOT "Modern Roundabouts" ��; Federal HighwayAdministration Appendix A Operational Analysis Formulas This appendix presents the assumptions used to develop the graphs and charts in the operational analysis presented in Chapter 4. A.1 Single-Lane Roundabout A.1.1 Equations Qe=k(F—f�Q�), f�Q��F = 0, f�Q� > F where: Qe= entry capacity, pce/h Q�= circulating flow, pce/h k=1-0.00347(�-30)-0.978� �-0.05J r F = 303xZ f� =0.210to(1+0.2x2) to =1 + 0.5 1+exp D-60 10 e—v x2 =v+1+2S S_ 1.6(e—v) I' where: e= entry width, m v= approach half width, m 1' = effective flare length, m S= sharpness of flare, m/m D= inscribed circle diameter, m � = entry angle, degrees r = entry radius, m � (A-2) (A-3) (A-4) (A-5) (A-6) (A-7) Roundabouts: An Informational Guide • Appendix A: Operational Analysis Formulas I��1r For design purposes, when e= v then /' is effectively zero. However, setting /'= 0 results in S being undefined.Therefore a non-zero value of /'has been selected. When e= v, any non-zero value of 1'results in S= 0 and xZ= v. For design purposes, when e= v then I' is effectively zero. However, setting /'- 0 results in S being undefined.Therefore a non-zero value of 1'has been selected. When e= v, any non-zero value of /'results in S=OandxZ-v. A.7.2 Parameter assumptions D=40m re=20m � = 30 degrees v=4m e=4m I' = 40 m S_ 1.61e—v) _ 1.6(4-4) _� 1' 40 to =1 + � D — 60 —1.4404 1+exp 10 x —v+ e—� =4+ 4-4 =4 Z 1+25 1+2(0) F = 303xZ = 303(4) =1212 f� = 0.210 ip (1 + 0.2 xZ )= 0. 5447 k =1-0.00347 (�-30)-0.978 � � —0.05J =1 r A.1.3 Final equation Qe =1212 — 0.5447 Q� A.2 Double-Lane Roundabout A.2.1 Equations See Section A.1.1. A.2.2 Parameter assumptions D=55m r =20m e � = 30 degrees v=8m e=8m I' = 40 m � �:, � Federal HighwayAdministration S_ 1.6(e—v) _ 1.6(8-8) =0 1' 40 tp=1+ �D-60 —1.3112 1 + exp 10 x v+ e—v _8+ 8-8 =8 z 1+2S 1+2(0) F = 303xz = 303(81= 2424 f� = 0.210tp(1+0.2x2) = 0.7159 k=1— 0.00347 (� — 30) — 0.978 � �— 0.05 J=1 r A.2.3 Final equation Qe = 2424 — 0.7159 Q� A.3 Urban Compact Roundabout .. The capacity curve for the urban compact roundabout is based on the capacity curves developed for roundabouts in Germany with single-lane entries and a single- lane circulatory roadway.This equation, developed by Brilon, Wu, and Bondzio is as follows: Qe =1218-0.74Q� where: Qe = entry capacity, pce/h Q = circulating flow, pce/h � . � Roundabouts: An Informational Guide • Appendix A: Operational Analysis Formulas I�� A.4 Short Lanes The effect of short lanes (flare) on capacity has been documented by Wu (3). Page 321 of Wu's paper states that for a right flared approach, kf, nght — �F d9nr+i ( X+ X ) F d9nr+� + XnF d9nr+1 L T R Dropping some subscripts, k= 1 n+1 (XLr�n+1 +,XR�n+1 � (A-12) Noting that the capacities of each lane are the same and that the flows are the same (that is, the entries are constantly fed with vehicles), this gives: 1 k — x n+1 �- �/ L with x�T = xR. Capacity qmax is then pmaX = k Qi where q� is flow in lane i and q�=q2 2q qmax — n+1 r X �/ L (A-13) (A-14) (A-15) qmaxZ is the capacity of a two-lane roundabout, the capacity of each entry lane is qmax�/2 and this is equal to the flow, q, divided by the degree of saturation, x. p max 2 �I maz n+� � � The results of Equation A-16 can be compared with the results from the British equations.TheTRL equations are listed above.The results are listed for four circu- lating flow conditions: 500 veh/h,1000 veh/h, 1500 veh/h, and 2000 veh/h. ; I Federal HighwayAdministration n 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 Q� - 500 veh/h Q� 1000 veh/h Q� 1500 veh/h TRL Wu TRL Wu TRL Wu 940 940 668 668 395 395 1447 1461 1151 1208 855 955 1636 1640 1321 1356 1006 1072 1737 1737 1411 1436 1086 1135 1799 1799 1468 1487 1136 1175 1841 1841 1506 1522 1170 1203 1872 1871 1534 1547 1195 1223 1896 1895 1555 1566 1214 1238 1914 1913 1571 1581 1229 1250 1929 1928 1585 1594 1240 1260 1941 1940 1596 1604 1250 1268 1951 1950 1605 1612 1258 1274 1960 1959 1612 1619 1265 1280 1967 1966 1619 1626 1271 1285 1974 1973 1625 1631 1276 1289 1979 1978 1630 1636 1281 1293 1984 1983 1635 1640 1285 1296 1989 1988 1639 1644 1288 1299 1993 1992 1642 1647 1292 1302 1996 1996 1645 1650 1294 1304 2000 1999 1648 1653 1297 1306 2066 2066 1708 1708 1350 1350 2500 Z000 1500 i000 500 0 � 5 10 15 20 Number of vehicle spaces, n n�=2000 veh/h TRL Wu 123 123 559 702 691 787 761 834 805 864 835 884 857 899 873 910 886 919 896 926 905 932 912 936 918 941 923 944 928 947 931 950 935 952 938 955 941 957 943 958 946 960 992 992 • TRL 500 veh/h — Wu 500 veh/h ° TRL 1000 veh/h °� Wu 1000 veh/h • TRL 1500 veh/h — Wu 1500 veh/h � TRL 2000 veh/h "°`° Wu 2000 veh/h F�chibit Ar7. Tabular comparison of TRL and Wu short-lane methodologies. Exhibit A-2. Graphical comparison of TRL and Wu short-lane methodologies. Roundabouts: An Informational Guide • Appendix A: Operational Analysis Formulas �, A.5 References Kimber, R.M. The tratfic capacity of roundabouts. TRRL Laboratory Report LR 942. Crowthorne, England: Transport and Road Research Laboratory, 1980. Brilon , W., N. Wu, and L. Bondzio. "Unsignalized Intersections in Germany—A State of the Art 1997." In Proceedings of theThird International Symposium on Intersections withoutTraffic Signals (ed: M. Kyte1, Portland, Oregon, U.S.A. Uni- versity of Idaho, 1997. Wu, N. "Capacity of shared/short lanes at unsignalized intersections:' In Proceedings of theThird International Symposium on Intersections withoutTraf- fic Signals (ed: M. Kyte�, Portland, Oregon, U.S.A. University of Idaho, 1997. w I Federal HighwayAdministration Appendix B Example Roundabout Designs The purpose of this Appendix is to provide examples for each of the six roundabout categories. Exhibit B-1 lists typical inscribed circle diameter ranges for each round- about category. Note that the flared-entry roundabout uses the same range of inscribed circle diameters as the double-lane roundabouts. Note that the dimen- sions of roundabouts may vary considerably within each category, depending on site-specific characteristics, including number of legs, approach angles, design vehicle requirements, and so on. Refer to Chapter 6 for more discussion of specific dimensions. Exhibit B-1. Typical inscribed circle diameter ranges by roundabout category. Site Category Mini-roundabout Urban compact Urban single lane Urban double lane Rural single lane Rural double lane Inscribed Circle Diameter Range 13-25 m (45-80 ft) 25-30 m (80-100 ft) 30-40 m (100-130 ft) 45-55 m (150-180 ft) 35-40 m (115-130 ft) 55-60 m (180-200 ft) The following pages show examples for each of the roundabout categories: • Exhibit B-2: Typical mini-roundabout. • Exhibit B-3: Typical urban compact roundabout. • Exhibit B-4: Typical urban single-lane roundabout. • Exhibit B-5: Typical urban double-lane roundabout. • Exhibit B-6: Typical flared-entry roundabout. • Exhibit B-7: Typical rural single-lane roundabout. • Exhibit B-8: Typical rural double-lane roundabout. Roundabouts: An Informational Guide • Appendix B• Example Roundabout Designs I '� Exhibit B-2. Example of a typical mini-roundabout. :, I Federal Highway Administration �� Exhibit B3. Example of a typical urban compact roundabout. Roundabouts: An Informational Guide • Appendix B• Example Roundabout Designs � 2�8 F�chibit B-4. Example of a typical single-lane roundabout. �; I Federal Highway Administration Exhibit B5. Example of typical urban double-lane roundabout. Roundabouts: An Informational Guide • Appendix B: Example Roundabout Designs � 267 F�chibit B-6. Example of a typical flared-entry roundabout. �,; I Federal Highway Administration Exhibit B-7. Example of a typical rural single-lane roundabout. Roundabouts: An Informational Guide • Appendix B: Example Roundabout Designs I�- Exhibit B-8. Example of a typical rural double-lane roundabout. �+E° I Federal Highway Administration Appendix C MUTCD Recommendation The purpose of this Appendix is to provide the rationale behind recommended deviations from the current (1988 edition) or proposed (2000 edition) Manual on Uniform Traffic Control Devices (MUTCD). The following devices are discussed: • YIELD Sign • Roundabout Ahead Sign C.1 Yeld Sign The proposed use of theYIELD sign in the Guide is generally consistent with the MUTCD. However, the MUTCD contains language that generally discourages the use ofYIELD signs for controlling the major flow at an intersection and the use of YIELD signs on more than one approach (MUTCD, §2B-8).This language predates the consideration of roundabouts and should be modified in the next edition of the M UTCD. C.2 Roundabout Ahead Sign As an alternative to the Circular Intersection sign, a Roundabout Ahead sign has been proposed.This sign, along with a supplemental advisory speed plate (W13-1), is shown in Exhibit C-1. � �� 0 M.P.H. This sign should be used on all approaches to a roundabout. The purpose of a Roundabout Ahead sign is to convey to a driver that the driver is approaching an intersection with the form of a roundabout.The intent of this sign is to be similar in function to the other intersection warning signs (e.g., CROSS ROAD (W2-1) signs), for example, which convey that the driver is approaching intersections of those forms. Unlike those signs, however, the Roundabout Ahead sign is recommended for all roundabouts, not just visually obscured locations. C.2.1 Need The 1988 edition of the MUTCD provides no sign related to roundabouts.The clos- est applicable sign is theYIELD AHEAD sign, either in word message or symbolic form (W3-2 or W3-2a, respectively). While this sign is necessary for indicating an upcoming traffic control device, it does not provide any information to the driver that the upcoming yield sign is for a roundabout. Driver behavior, lane assignments, Exhibit G7. Roundabout Ahead sign with advisory speed plate (W13-1). • endix C: MUTCD Recommendations 285 Roundabouts: An Informational Guide App and driver expectation are much different for roundabouts than for traditional yield- controlled locations (typically low-volume streets or right-turn bypass lanes). Iden- tification that a roundabout is upcoming is particularly important for multilane ap- proaches so that drivers can anticipate and move into the proper lane in advance of the roundabout. Therefore, some indication that a driver is approaching a round- about is essential, especially given the relative rarity of roundabouts in the United States. The National Committee on UniformTraffic Control Devices (NCUTCD) has adopted the Circular Intersection sign shown in Exhibit C-2, and this sign is being consid- ered for adoption by FHWA. Exhibit C-2. Circular Intersection sign. C.2.2 Existing Practice Exhibit C3. Sample of existing RoundaboutAhead signs in United States. Bradenton Beach, FL (a) Mary Esther, FL (b) Mary Esther, FL (c) Lisbon, MD (d) Leeds, MD (e) Lothian, MD (f) Naples, FL (g) West Boca Raton, FL (h) Due to the lack of a standard Roundabout Ahead sign, jurisdictions in the U.S. have experimented with a variety of warning signs, sometimes with multiple varia- tions within the same jurisdiction. Examples of these are shown in Exhibit C-3. As can be seen from the figure, the lack of standardization from jurisdiction to juris- diction is evident. 266 Federal HighwayAdministration International practice varies from country to country but is generally more consis- tent than current U.S. practice. Sign shapes and coloration vary depending on the standards of that country, but the one consistent feature is a simple ring of arrows, oriented to the direction of traffic flow. Examples from the United Kingdom and Australia are given in Exhibit C-4. r� �� United Kingdom Australia C.2.3 Recommendation Based on a review of existing signs in the U.S. and current international practice, a recommended Roundabout Ahead sign was developed, as presented previously in Exhibit C-1. This sign is similar in concept to those shown in (b), (cl, and (j) of Exhibit C-3 and is shown fully dimensioned in Exhibit C-5. This sign has been developed based on the following criteria: • The recommended sign is symbolic, consistent with current MUTCD practice. • The recommended sign uses the internationally recognized circular ring of ar- rows to represent a roundabout and is almost an exact mirror image of the sign used in Australia (Exhibit C-4). � The recommended sign gives advanced notice of the proper direction of circu- lation. The NCUTCD-adopted sign in Exhibit C-2 does not convey this informa- tion and could give the driver the incorrect impression that the circulatory road- way is bidirectional. Exhibit C-3 (continued). (i) Santa Barbara, CA (j) Tallahassee, FL (k) Taneytown, MD (1) Tavares, FL (m) Vail, CO (n) WestVail, CO Exhibit G4. Sample of Roundabout Ahead signs used internationally. Roundabouts: An Informational Guide • Appendix C: MUTCD Recommendations I 267 Exhibit G5. Dimensions of RoundaboutAhead sign. • The recommended sign can be used for roundabouts with any number of legs, including intersections with one-way approaches. Many of the signs in Exhibit C-3 and the NCUTCD-recommended sign in Exhibit C-2 are unique to four-leg roundabouts with legs at right angles and would be inappropriate for round- abouts with three or five legs, for example. • The recommended sign can be supplemented by an advisory speed plate. An advisory speed plate would not be appropriate for aYIELD AHEAD sign because of the need for the driver to proceed only when clear. • The recommended sign is simple with no extraneous or distracting elements to confuse a driver. Some of the signs in Exhibit C-3 are perhaps too complex for higher speed environments. • Mini-roundabouts cannot be easily signed to show the proper direction of circu- Iation.The recommended sign provides guidance to the driver as to the proper direction of circulation. USE FHWA � ay. � DIMENSIONS IN MILLIMETERS A B C D E F 900 16 22 56 250 40 1200 19 31 75 333 53 DIMENSIONS IN INCHES A B C D E F 36 5/S 7/8 2 1/4 10 1 5 48 3/4 1 7/4 3 13 1/4 2 1 D IN—REf �W (RE 268 I Federal HighwayAdministration • er rlvers: . Roundabouts: An Informational Guide CC Mtg OS-06-04, Item #7.2 Traffic Calming Reference Highlighted Topics: Older Drivers: Page 31 Emergency Vehicles: Page 35 Cost: Page 36 Legal: Page 37 Right-of-Way: Page 3 8 Emer enc Vehicles: P 35 g Y g Roundabouts: An Informational Guide CC Mtg OS-06-04, Item #7.2 Traffic Calming Reference Highlighted Topics: Older Drivers: Page 31 Emergency Vehicles: Page 35 Cost: Page 36 Legal: Page 37 Right-of-Way: Page 3 8 Cost: P 3 6 g Roundabouts: An Informational Guide CC Mtg OS-06-04,,Item #7.2 Traffic Calming Reference Highlighted Topics: Older Drivers: Page 31 Emergency Vehicles: Page 35 Cost: Page 36 Legal: Page 37 Right-of-Way: Page 38 Le al: P 37 g g Roundabouts: An Informational Guide CC Mtg OS-06-04, Item #7.2 Traffic Calming Reference Highlighted Topics: Older Drivers: Page 31 Emergency Vehicles: Page 35 Cost: Page 36 Legal: Page 37 Right-of-Way: Page 3 8 Ri ht-of-Wa : P 38 g y g Roundabouts: An Informational Guide CC Mtg OS-06-04, Item #7.2 Traffic Calming Reference Highlighted Topics: Older Drivers: Page 31 Emergency Vehicles: Page 35 Cost: Page 36 Legal: Page 37 Right-of-Way: Page 3 8