Background and Overview

Implementing regulations under Title II of the Americans with Disabilities Act (1) and other statutes require that new construction and alterations are accessible to, and useable by, people with disabilities. In recent years, with the development of guidelines for the public right-of-way, concerns have been raised about the accessibility of roundabouts to persons with severe visual impairments (2) and subsequent research has tended to support those concerns. For instance, Guth, et al. (3) have shown that blind pedestrians require about 3 more seconds than sighted pedestrians to detect naturally occurring gaps in traffic, and that this requirement markedly reduces the number of gaps available to blind pedestrians at roundabouts with moderate to high traffic volume. Nor can blind pedestrians rely on motorists to yield to them. Inman et al. (4) found that at one double lane roundabout, only 14 percent of motorists yielded to blind pedestrians using a long cane or a guide dog. Furthermore, those investigators found that on 10 percent of trials, the blind pedestrians incorrectly identified that both lanes of a double-lane roundabout were blocked by stopped vehicles, when in fact, only one lane was blocked. Geruschat and Hassan (5) reported on a number of factors that can influence motorists’ yielding rate. They found that drivers are more likely to yield at roundabout entrances than exits and when: (1) speeds are lower, (2) the pedestrian is more aggressive, and (3) when the pedestrian has a long cane or guide dog. At a roundabout entrance where measured speeds were about 10 mi/h, almost all drivers yielded to a pedestrian who had one foot into the street and carried a long cane. At a roundabout exit where measured speeds were about 20 mi/h yielding rates to an apparently blind pedestrian were less than 15 percent.

Thus, it appears that many double lane roundabouts are not accessible to pedestrians who are blind. Vehicles are unlikely to yield to these pedestrians, naturally occurring gaps may be rare, and many roundabouts – in particular multilane roundabouts – with pedestrian facilities, do not provide cues that enable pedestrians who rely on traffic sounds to reliably detect gaps that result when vehicles yield to them. For these reasons, draft guidelines developed by the U.S. Access Board (6), would require some form of signalization at new multi-lane roundabout pedestrian crossings.

ROUNDABOUT OVERVIEW

As defined by the Federal Highway Administration (FHWA), modern roundabouts are circular intersections with specific traffic control and design features (7). These features include yield control at entry, channelized approaches, and geometric approach curvature (deflection) to induce entering traffic to slow to the design speed of the circulatory roadway. Figure 1 illustrates the typical locations for crosswalks at roundabouts in the U.S. One end of each crosswalk terminates on a splitter island so that the pedestrian crosses only one direction of traffic at a time. The crosswalks are set back from the intersection to minimize conflicts with turning vehicles.* Traffic is forced to travel on a curved path, which typically minimizes vehicle speed to between 20 and 30 mi/h.


Figure 1. Photo.  Illustration of a single-lane roundabout with crosswalks.  This is a engineering drawing of a standard single lane roundabout.  The circulatory roadway, entrance, and exit are marked and identified.  The crosswalk and splitter islands are also labeled and identified at locations away from the circulatory roadway.

Figure 1. Illustration of single-lane roundabout with crosswalks.

Roundabouts are appearing with increasing frequency in the United States, primarily because of their benefits to traffic operations and safety. Compared to conventional intersections, potential roundabout benefits identified in the FHWA informational guide (7) include: less vehicle delay, fewer crashes, and fewer serious and fatal injuries in crashes, both for vehicle occupants and for pedestrians.

* It has been pointed out that setting crosswalks back at roundabout is opposite of the policy at traditional intersections where the crosswalks are as close as practicable to the intersection. This apparent contradiction results in part from the fundamental difference between roundabouts and traditional intersections. At roundabouts traffic flow is continuous and there is no pedestrian phase. At traditional traffic device controlled intersections, priority usually alternates between conflicting approaches (i.e., with traffic signal control) or remains with the predominate approach (e.g., with two-way stop control). At roundabouts, placing the crosswalk at the edge of the inscribed circle (juxtaposed to the circular roadway) would expose pedestrians to nearly continuous traffic that approaches from both the side and rear. At the entrance drivers would need to split their attention between possible pedestrians approaching the right and vehicles approaching from the left. Moving the crosswalk back from the circular roadway eliminates the threat to pedestrians from vehicles that approach from the rear and places pedestrians in the drivers’ forward field of vision. At controlled traditional intersections pedestrians can take advantage of the traffic control to obtain a gap, an option not generally available at U.S. roundabouts, and drivers can scan for pedestrians while they are stopped for the control. The right-turn-on-red prohibition when pedestrians are present is intended to eliminate the conflict in which drivers must attend to both pedestrians on their right and approaching vehicles on their left. When roundabouts are signalized, there may be some advantage to moving crosswalks to be proximal to the circular roadway and this is done at fully signalized roundabouts (see Figure 5 for an example in France). However, fully signalized roundabouts are much larger than the “modern roundabouts” currently being built in the U.S., which do not have sufficient space to store vehicles in the circular roadway without stopping traffic flow in all directions and thus eliminating the cost and efficiency benefits that are the hallmark advantages of modern roundabouts.