A roundabout (also called a traffic circle, road circle, rotary, rotunda or island) is a type of circular intersection or junction in which road traffic is permitted to flow in one direction around a central island, and priority is typically given to traffic already in the junction.[1][2]

Modern roundabouts observe various design rules to increase safety. Compared to stop signs, traffic signals, and earlier forms of roundabouts, modern roundabouts reduce the likelihood and severity of collisions greatly by reducing traffic speeds and minimizing T-bone and head-on collisions.[3] Variations on the basic concept include integration with tram and/or train lines, two-way flow, higher speeds and many others.

Traffic exiting the roundabout comes from one direction, rather than three, simplifying the pedestrian's visual environment. Traffic moves slowly enough to allow visual engagement with pedestrians, encouraging deference towards them. Other benefits include reduced driver confusion associated with perpendicular junctions and reduced queuing associated with traffic lights. They allow U-turns within the normal flow of traffic, which often are not possible at other forms of junction. Moreover, since vehicles on average spend less time idling at roundabouts than at signalled intersections, using a roundabout potentially leads to less pollution.[4][5] When entering vehicles only need to give way, they do not always perform a full stop; as a result, by keeping a part of their momentum, the engine will produce less work to regain the initial speed, resulting in lower emissions. Research has also shown that slow moving traffic in roundabouts makes less noise than traffic that must stop and start, speed up and brake.[6]

Modern roundabouts were first standardised in the UK in 1966 and were found to be a significant improvement over previous traffic circle and rotaries. Since then they have spread and modern roundabouts are commonplace throughout the world.[2]:2 Half of the world's roundabouts are in France (more than 30,000 as of 2008), although the United Kingdom has more as a proportion of the road than any other country.[7]

NonUK Roundabout 8 Cars
Movement within a roundabout in right-hand traffic; note the anticlockwise circulation
UK Roundabout 8 Cars
Movement within a roundabout in left-hand traffic; note the clockwise circulation
Colombo Galle Face Roundabout
Roundabout in the centre of Colombo, Sri Lanka


Circular junctions existed before roundabouts, including the Circus in the city of Bath, Somerset, England, completed in 1768, part of a world heritage site; the 1899 Brautwiesenplatz in Görlitz, Germany;[8] the 1907 Place de l'Étoile around the Arc de Triomphe in Paris; the 1904 Columbus Circle in Manhattan; and several circles within Washington, D.C. The operating and entry characteristics of these circles differ considerably from modern roundabouts. French architect Eugène Hénard was designing one-way circular intersections as early as 1877.[9] American architect William Phelps Eno favored small traffic circles. He designed New York City's famous Columbus Circle, which was built in 1905. In 1907, architect John McLaren designed one of the first American roundabouts for both autos and streetcars (trams) in the Hanchett Residence Park in what is now San Jose, California.[10] The first British circular junction was built in Letchworth Garden City in 1909. Its centre originally was intended partly as a traffic island for pedestrians.[11][12] It was featured in the film The World's End. In the early 20th century, numerous traffic circles were constructed in the United States, particularly in the northeast. Examples include a circle in Atherton, California.[13] Other circular intersections were subsequently built in the United States, though many were large diameter 'rotaries' that enabled high speed merge and weave maneuvers. They may control entering traffic by stop signs or traffic lights. Many older traffic circles allow entry at higher speeds without deflection, or require a stop and a 90-degree turn to enter.

These designs were doomed to failure for two primary reasons. The first is that it takes a large diameter circle to provide enough room for merging at speed. Although some of these circles were huge (many were in excess of 100 meters or 300 feet in diameter), they were not large enough for high-speed merging. Secondly, giving priority to entering traffic means that more vehicles can enter the circulatory roadway than it can handle. The result is congestion within the circle which could not clear without police intervention.

The experience with traffic circles and rotaries in the US was almost entirely negative, characterised by high accident rates and congestion problems. By the mid 1950s, construction of traffic circles and rotaries had ceased entirely. The experience with traffic circles in other countries was not much better until the development of the modern roundabout in the United Kingdom during the 1960s.

Widespread use of the modern roundabout began when the UK's Transport Research Laboratory engineers re-engineered and standardised circular intersections during the 1960s. Frank Blackmore led the development of the "Priority Rule" and subsequently invented the mini-roundabout[14][15] to overcome capacity and safety limitations. The priority rule was found to improve traffic flow by up to 10%.[16] The design became mandatory in the United Kingdom for all new roundabouts in November 1966. This give-way requirement has been the law in New York state since the 1920s.

In the United States modern roundabouts emerged in the 1990s. Municipalities introducing new roundabouts often are met with some degree of public resistance, just as in the United Kingdom in the 1960s. As of December 2015 there are about 4800 of these modern roundabouts in the United States. As an example, Washington State contains about 120 roundabouts as of October 2016, all having been built since 1997 with more planned.[17]

United States surveys show that negative public opinion reverses as drivers gain experience with roundabouts. American confusion at how to enter and especially how to exit a roundabout was the subject of mockery such as featured in the film European Vacation and the television series The Simpsons. By 2011, however, some 3,000 roundabouts had been established, with that number growing steadily.[18][19] A 1998 survey of municipalities found public opinion 68% opposed prior to construction; changing thereafter to 73% in favour.[20] A 2007 survey found public support ranging from 22% to 44% prior to construction, and several years after construction was 57% to 87%.[21] The first modern roundabout in the United States was constructed in Summerlin, Nevada in 1990.[22] This roundabout occasioned dismay from residents, and a local news program said about it, "Even police agree, [roundabouts] can be confusing at times."[23]

As of the beginning of the twenty-first century, roundabouts were in widespread use in Europe. For instance, in 2010 France had more than 30,000 roundabouts.[18]

Letchworth Roundabout 1909

The United Kingdom's first roundabout (1909) in Letchworth Garden City

South-Yarmouth-MA-US rotary plaque

National Register of Historic Places plaque on the first traffic circle in the United States, at the intersection of River and Pleasant streets in Yarmouth, Massachusetts

Thomas-Circle Washington-DC 1922

Thomas Circle in Washington, D.C., 1922


Small roundabout in Barzio, Italy


Roundabout signs in Linköping, Sweden

Rondell - Ystad-2017

Roundabout under construction in Ystad 2017.

Jakarta Bundaran HI

The Hotel Indonesia Roundabout in Jakarta, Indonesia

DeSoto Fountain in Coral Gables 20100321

DeSoto Fountain sits in the center of a traffic circle in the City of Coral Gables, Florida. The arterial, DeSoto Boulevard, has unrestricted right of way, while the intersecting streets are controlled by stop signs.

Place Charles-de-Gaulle from the Arc de Triomphe, July 2001

Traffic 10-abreast traverses the Place de l'Étoile. This traffic circle surrounds the Arc de Triomphe at the intersection of ten two-way and two one-way streets. It has no lane markings.

La Minerva de Guadalajara 02

The Minerva Roundabout is one of the most famous landmarks of Guadalajara, Mexico.

Modern roundabout

Zeichen 215 - Kreisverkehr, StVO 2000
Europe (right-hand traffic); in the UK a similar sign, with the arrows reversed, is used at mini roundabouts.
The US, Canada and Mexico (right-hand traffic); a similar sign is used in Ireland (with directions reversed).
UK traffic sign 510
UK (left-hand traffic)
Australia R1-3
Australia and New Zealand (left-hand traffic)

A "modern roundabout" is a type of looping junction in which road traffic travels in one direction around a central island and priority is given to the circulating flow. Signs usually direct traffic entering the circle to slow and to give way to traffic already on it.[24][25]

Because low speeds are required for traffic entering roundabouts, they are physically designed to slow traffic entering the junction to improve safety, so that the roads typically approach the junction radially; whereas rotaries are frequently designed to try to increase speeds, and thus have roads that enter the traffic circle tangentially.

Because of the requirement for low speeds, roundabouts usually are not used on controlled-access highways, but may be used on lower grades of highway such as limited-access roads. When such roads are redesigned to take advantage of roundabouts, traffic speeds must be reduced via tricks such as curving the approaches.

Many traffic circles have been converted to modern roundabouts, including the former Kingston traffic circle in New York and several in New Jersey.[26][27] Others have been converted to signalised intersections, such as the Drum Hill Rotary in Chelmsford, Massachusetts, which is now six lanes wide and controlled by four separate intersections.[28]


The word roundabout dates from early 20th century United Kingdom.[1]

In U.S. dictionaries the terms roundabout, traffic circle, road circle and rotary are synonyms.[29]

The U.S. Department of Transportation adopted the term modern roundabout to distinguish those that require entering drivers to give way to others. This article follows that convention and refers to other types as traffic circles or rotaries. Many old traffic circles remain in the northeastern US.[30] Some modern roundabouts are elongated to encompass additional streets, but traffic always flows in a loop.

In the United States, traffic engineers typically use the term rotary for large scale circular junctions between expressways or controlled-access highways. Rotaries typically feature high speeds inside the circle and on the approaches.[31]

In New England, traffic circles are generally called rotaries and the traffic that is already driving in the rotary always has the right of way. For examples of where this is specified, in Massachusetts "Any operator of a vehicle entering a rotary intersection shall yield the right-of-way to any vehicle already in the intersection."[32] In Rhode Island entering vehicles "Yield to vehicles in the roundabout."[33]

In Massachusetts older circular intersections are called rotaries and the state enforces that restriction.

The term traffic circle is not used in the United Kingdom, where most circular junctions meet the technical criteria for modern roundabouts. However, in some parts of the English Midlands, such as in Birmingham, roundabouts are commonly called "islands", which conflicts with the more generic use of the term "island" as a structure to divide traffic flow, and can cause confusion.

In the Channel Islands a third type of roundabout, known as "Filter in Turn", exists. Here approaching drivers neither yield to traffic on the roundabout, as normal, nor have priority over it (traffic circle), but take it in turns to enter from each. Almost all of Jersey's roundabouts are of this type.[34]

In the Philippines, the term rotunda or rotonda is used in referring to roundabouts.

Operation and design

The fundamental principle of modern roundabouts is that entering drivers give way to traffic within the roundabout without the need for traffic signals. Conversely, older traffic circles typically require circling drivers to give way to entering traffic. Roundabouts may also have an interior lane.[35] Generally, exiting directly from an inner lane of a multi-lane roundabout is permitted, given that the intersecting road has as many lanes as the roundabout. By contrast, exiting from an inner lane of an older traffic circle is usually not permitted and traffic must first move into the outside lane.

Vehicles circulate around the central island in one direction at speeds of 25–40 km/h (15–25 mph). In left-hand traffic countries they circulate clockwise (looking from above); in right-hand traffic, anticlockwise.

Multi-lane roundabouts are typically less than 75 metres (250 ft) in diameter;[36] older traffic circles and roundabout interchanges may be considerably larger. Roundabouts are roughly the same size as signalled intersections of the same capacity.

Design criteria include:

  • Right-of-way: Whether entering or circling vehicles have the right of way. The New Jersey Driver's Manual recommends that, in the absence of flow control signs, traffic yields based on "historically established traffic flow patterns",[37] and there are no set rules.[38] In New England,[39] Washington, D.C. and New York State,[40] entering traffic yields, as is the norm in virtually all countries outside of the U.S.
  • Angle of entry: Angles range from glancing (tangential) that allow full-speed entry to 90 degree angles (perpendicular).[41]
  • Traffic speed: High entry speeds (over 30 mph or 48 km/h) require circulating vehicles to yield, often stopping, which lowers capacity and increases crash rates compared to modern roundabouts.[42]
  • Lane changes: Allowed or not
  • Diameter: The greater the traffic, the larger the circle.[41]
  • Island function: Parking, parks, fountains, etc.[41]


Roundabout at Leiden University Medical Center in the Netherlands, with modern art animals on the central island, and an apron that can be used by large trucks

Modern roundabouts feature a central island and sometimes pedestrian islands at each entry or exit.


La fontaine des trois Grâces, 1860
A fountain dominates this roundabout in Aix-en-Provence, France

The central island may be surrounded by a truck apron that is high enough to discourage drivers from crossing over it, but low enough to allow wide or long vehicles to navigate the roundabout. The island may provide a visual barrier, to alert approaching drivers to the presence of the roundabout, and to encourage drivers to focus on the traffic in the path of the circle. A visual barrier significantly reduces the accident rate.[43] Otherwise, vehicles anywhere in or near the circle can cause those entering to stop and wait for them to pass, even if they are opposite, which unnecessarily reduces traffic flow. The barrier may be a landscaped mound, a raised wall, a tree or tall shrubs. Road signage or flagpoles may be erected at the top of a landscaped mound.

Some communities use the island for monuments, the display of large public art or for a fountain. Pedestrians may be prohibited from crossing the circling lane(s). Access to the central island requires an underpass or overpass for safety.

Roundabouts have attracted art installations around the world:


This roundabout in Shanghai, China, has a pedestrian bridge in the form of another, raised roundabout.

For larger roundabouts, pedestrian islands at each entry/exit encourage drivers to slow and prepare to enter the circle. They also provide a refuge where pedestrians may pause mid-crossing.

Pedestrian crossing

Pedestrian crossings at each entry/exit may be located at least one full car length outside the circle. The extra space allows pedestrians to cross behind vehicles waiting to enter the circle, and to allow exiting vehicles to stop for pedestrians without obstruction. Each pedestrian crossing may traverse a pedestrian island for protection that also forces drivers to slow and begin to change direction, encouraging slower, safer speeds. On the island, the pedestrian crossing may become diagonal, to direct the gaze of those crossing into exiting traffic.


Physically separated bikeways best protect cyclists.[54][54][55][56] Less optimally, terminating cycle lanes well before roundabout entrances requires cyclists to merge into the stream of motor traffic, but keeps cyclists in full view of drivers, at some cost in motor vehicle speed. Cyclists may also be permitted to use pedestrian crossings.

Traditional cycle lanes increase vehicle/bicycle collisions. When exiting, a motorist must look ahead to avoid colliding with another vehicle or with pedestrians on a pedestrian crossing. As the intersection curves away from the exit, the path of an exiting vehicle is relatively straight, and so the motorist may often not slow substantially. To give way to a cyclist on the outside requires the exiting motorist to look toward the rear, to the perimeter. Other vehicles can obstruct the driver's view in this direction, complicating the motorist's task. The more frequent requirements for motorists to slow or stop reduce traffic flow. A 1992 study[57] found that the risk to cyclists is high in all such intersections, but much higher when the junction has a marked bicycle lane or sidepath around its perimeter.[58][59] Cycle lanes were installed at Museum Road, Portsmouth, but were replaced by a narrowed carriageway to encourage lane sharing.

The roundabout at the Brown Road/202 interchange adopts a U.S.-recommended design.[60] On-street pavement markings direct cyclists to enter the sidewalk at the end of the bike lane. Cyclists who choose to travel on the wide sidewalk, cross roundabout arms perpendicularly, well outside the circle. A pedestrian island allows pedestrians and cyclists to cross one lane at a time.

Fietsotonde Hovenring Eindhoven

The Hovenring bicycle roundabout in the Netherlands is an innovative design, completely separating bicycles from vehicular traffic.

Roundabout cyclelanes

Cycle lanes on St. John's roundabout in Newbury, Berkshire, England.

Okay to enter sidewalk

Pavement markings invite cyclists to enter sidewalk on approach to roundabout in Mesa, Arizona. Cyclists are still permitted to use the roundabout like any other vehicle.

Bicyclist in roundabout

Cyclists can choose to ride on the sidewalk on far right, or in main lanes of this roundabout in Mesa, Arizona.

Capacity and delays

Traffic approaching Chiverton Cross roundabout in Cornwall, UK

The capacity of a roundabout varies based on entry angle, lane width, and the number of entry and circulating lanes. As with other types of junctions, operational performance depends heavily on the flow volumes from various approaches. A single-lane roundabout can handle approximately 20,000–26,000 vehicles per day, while a two-lane design supports 40,000 to 50,000.[55]

Under many traffic conditions, a roundabout operates with less delay than signalised or all-way stop approaches. Roundabouts do not stop all entering vehicles, reducing both individual and queuing delays. Throughput further improves because drivers proceed when traffic is clear without waiting for a signal to change.

Roundabouts can increase delays in locations where traffic would otherwise often not be required to stop. For example, at the junction of a high-volume and a low-volume road, traffic on the busier road would stop only when cross traffic was present, otherwise not having to slow for the roundabout. When the volumes on the roadways are relatively equal, a roundabout can reduce delays, because half of the time a full stop would be required. Dedicated left turn signals (in countries where traffic drives on the right) further reduce throughput.

Roundabouts can reduce delays for pedestrians compared to traffic signals, because pedestrians are able to cross during any safe gap rather than waiting for a signal. During peak flows when large gaps are infrequent, the slower speed of traffic entering and exiting can still allow crossing, despite the smaller gaps.

Studies of roundabouts that replaced stop signs and/or traffic signals found that vehicle delays were reduced 13–89 percent and the proportion of vehicles that stopped was reduced 14–56 percent. Delays on major approaches increased as vehicles slowed to enter the roundabouts.[5]

Roundabouts have been found to reduce carbon monoxide emissions by 15–45 percent, nitrous oxide emissions by 21–44 percent, carbon dioxide emissions by 23–37 percent and hydrocarbon emissions by 0–42 percent. Fuel consumption was reduced by an estimated 23–34 percent.[5]

Capacity modelling

Major research on roundabout capacity has been carried out in multiple countries. Software can help calculate capacity, delay and queues. Packages include ARCADY, Rodel, Highway Capacity Software and Sidra Intersection. ARCADY and Rodel are based on the Transport Research Laboratory mathematical model. The TRL approach is derived from empirical models based on geometric parameters and observed driver behaviour with regard to lane choice. Sidra Intersection software includes roundabout capacity models developed in Australia and the US.

Research on Australian roundabouts was conducted in the 1980s at the Australian Road Research Board (ARRB).[61] Its analytical capacity and performance models differ from the TRL model significantly, following a lane-based gap-acceptance theory including geometric parameters.

Research on U.S. roundabouts sponsored by the Transportation Research Board (TRB) and Federal Highway Administration (FHWA) culminated in a capacity model that was included in the Highway Capacity Manual (HCM) Edition 6[62] and the TRB-FHWA Roundabout Informational Guide (NCHRP Report 672).[63] The HCM Edition 6 model is based on lane-based gap-acceptance theory. A recent NCHRP survey of US state transport agencies found that Sidra Intersection is the most widely used software tool in the US for roundabout analysis.[64]


Roundabout intersection diagram
A comparison of possible collision points on a roundabout versus a traditional intersection
2008 03 12 - UMD - Roundabout viewed from Art Soc Bldg 4
Small modern roundabout in the United States, where vehicles are driven on the right
Roundabout in the United States with separated side lanes. Vehicles entering the roundabout give way to vehicles in the roundabout. As of March 2009 the road at upper left carries 10,400 vehicles per weekday.
A typical trunk road roundabout in the UK at Carland Cross on the A30 in Cornwall. There is a free-flow lane for the A30 towards Bodmin (nearest the camera).

Statistically, modern roundabouts are safer for drivers and pedestrians than both traffic circles and traditional intersections.[65] Roundabouts are safer than both traffic circles and junctions—experiencing 39% fewer vehicle collisions, 76% fewer injuries and 90% fewer serious injuries and fatalities (according to a study of a sampling of roundabouts in the United States, when compared with the junctions they replaced).[66] Some larger roundabouts take foot and bicycle traffic through underpasses or alternate routes. Clearwater Beach, Florida's multi-lane roundabout has reduced its previously high cyclist death rate to zero since its construction.

At junctions with stop signs or traffic lights, the most serious accidents are right-angle, left-turn or head-on collisions where vehicles move fast and collide at high impact angles, e.g. head-on. Roundabouts virtually eliminate those types of crashes. Instead, most crashes are glancing blows at low angles of impact.[67][68]

An analysis[69] of the New Zealand national crash database[70] for the period 1996–2000 shows that 26% of cyclists reported injury crashes happened at roundabouts, compared to 6% at traffic signals and 13% at priority controlled junctions. The New Zealand researchers propose that low vehicle speeds, circulatory lane markings and mountable centre aprons for trucks can reduce the problem.[71]

The most common roundabout crash type for cyclists, according to the New Zealand study, involves a motor vehicle entering the roundabout and colliding with a cyclist who already is travelling around the roundabout (50%+ of cyclist/roundabout crashes in New Zealand fall into this category). The next most common crash type involves motorists leaving the roundabout colliding with cyclists who are continuing farther around the perimeter. Designs that have marked perimeter cycle lanes were found to be even less safe, suggesting that in roundabouts, cyclists should occupy a vehicle lane or a separate path rather than a special lane. The researchers advised that drivers be forbidden from overtaking cyclists (as well as other vehicles) while in the circle.

Vision-impaired pedestrians

Poorly designed walkways increase risks for the vision-impaired, because it is more difficult than at a signalised intersection to audibly detect whether there is a sufficient gap in traffic to cross safely. At a signalised intersection, traffic comes to a stop, and an audible sound can be generated to indicate that it is time to cross.[72]

This issue has led to a conflict in the United States between the vision-impaired and civil engineering communities. One solution is to provide manually-operated pedestrian crossing signals at each entry. This increases construction and operation costs, and requires some way to disrupt traffic long enough for the pedestrian to cross (such as a HAWK beacon) that defeats the purpose of the roundabout. Signalisation also increases delays for most pedestrians during periods of light traffic, since pedestrians need to wait for a signal to change before (legally) crossing.[73]

Signalised pedestrian crossings are normally used on large-diameter roundabout interchanges rather than small-diameter modern roundabouts.

Types of circular intersections

Large roundabouts such as those used at motorway junctions typically have two to six lanes and may include traffic lights to regulate flow.

Some roundabouts have a divider, or subsidiary deflection island, by means of which is provided a "free flow" segregated left (or right) turn lane (for the UK see Design Manual for Roads and Bridges TD 51/03) between traffic moving between two adjacent roads, and traffic within the roundabout, enabling drivers to bypass the roundabout.

Gyratory system

The term "gyratory" (for example, Hanger Lane gyratory) is sometimes used in the United Kingdom for a large circular intersection with non-standard lane markings or priority arrangements, or when there are significant lengths of carriageway between the entry arms, or when buildings occupy the central island.[74]

In the 21st century several of the gyratory systems in London have been removed, including Tottenham Hale[75] and Elephant & Castle.

Smaller, small or mini- roundabouts

As the overall or external size of a roundabout (in the UK referred to as the Inscribed Circle Diameter – ICD) is reduced, so the maximum practicable (and prescribed) diameter for the central island is also reduced, whilst the width of the circulatory carriageway increases (due to the greater width of vehicle swept path at smaller turning radii). In most cases this results in it being too easy – certainly when traffic is light relative to capacity – for drivers to traverse the roundabout at relatively high speed, with scant regard for road markings or the potential dangers to self or conflicts with other road users. To mitigate this risk, a proportion of the circulatory carriageway – an annulus around the central island – is segregated from general use by demarcation lines and differentiated from the outer annulus of carriageway by a combination of slightly raised surface, adverse crossfall, contrasting colours and textures and demarcating lines. The effect of this is to discourage drivers from taking a more direct path through the roundabout, their line of least resistance being more tightly curved (and therefore slower) but more bearable. The inner annulus provides for the trailing axles of longer or articulated vehicles to sweep across the inner annulus, which is therefore known as an over-run area (in UK usage), truck apron, or mountable apron.

The smaller the roundabout, the more such mitigation measures are likely to be abused – the less effective they will be. In the UK the minimum size for roundabouts with raised islands is 28 metre diameter ICD with a 4-metre diameter island. This threshold being driven primarily by vehicle geometry – which is globally relatively consistent – rather than driver behaviour, it is adopted in other jurisdictions too. Below this minimum size, the mini-roundabout prevails.


After developing the offside priority rule, Frank Blackmore, of the UK's Transport Research Laboratory, turned his attention to the possibility of a roundabout that could be built at sites lacking room for a conventional roundabout.[76]

A mini-roundabout in the United Kingdom, where a painted white circle is used for the centre. The arrows show the direction of traffic flow.

Mini-roundabouts can be a painted circle or a low dome but must be fully traversable by vehicles. Motorists can drive over them when there is no other traffic, but it is dangerous to do so otherwise. Once the practice is established it may be difficult to discourage. Mini-roundabouts use the same right-of-way rules as standard roundabouts, but produce different driver behaviour. Mini-roundabouts are sometimes grouped in pairs (a double mini-roundabout) or in "chains", simplifying navigation of otherwise awkward junctions. In some countries road signs distinguish mini-roundabouts from larger ones.

Mini-roundabouts are common in the UK, Ireland and Hong Kong (particularly on Hong Kong Island), as well as Irapuato in Mexico. Kemptville, Ontario, had the record for the most roundabouts in Ontario (with a record of three on one highway) until they recently began to become more prominent throughout many cities of the province at major intersections.

In the UK and also in other jurisdictions that have adopted mini-roundabouts, to drive across the central disc or dome when it is practicable to avoid it is an offence. Vehicles are required to treat the painted circle as if it were a solid island and drive around it.[77] Some local authorities paint double white lines around the circle to indicate this, but these require permission from the Secretary of State for Transport. The central dome also must be able to be overrun by larger vehicles.

In the UK – and also in other highway jurisdictions – the maximum size for a mini roundabout is 28 metre ICD (inscribed circle diameter).

Raindrop roundabouts

Dupli kružni tok, Zavrtnica
A hybrid raindrop roundabout in Zagreb, Croatia, 45°48′33″N 15°59′55″E / 45.809296°N 15.998648°E. These two roundabouts are more akin to a "magic roundabout" since the left turns need not drive through both of them.

These roundabouts do not form a complete circle and have a raindrop or teardrop shape. They appear at U.S. Interstate interchanges to provide a free-flowing left turn to the on-ramps and eliminating the need for turn signals and lanes. Since the entry and exit slip roads are one-way, a complete circle is unnecessary. This means that drivers entering the roundabout from the bridge do not need to give way, and that prevents queuing on narrow, two-lane bridges. These roundabouts have been used at dumbbell roundabout junctions, replacing traffic signals that are inefficient without a turning lane. Several junctions along Interstate 70 near Avon, Colorado use teardrop roundabouts.[78]

Balcony roundabout

A balcony roundabout is just an elevated roundabout. They are constructed in such a way that vulnerable road users can go underneath the roundabout and choose the direction they want to go. Footpaths and cycle paths along the different roads connect to the square under the roundabout. Vulnerable road users do not interfere with other traffic on the roundabout, making them much safer for them.

Turbo roundabouts

A much applied Dutch turbo roundabout design

In the Netherlands, Belgium, the United Kingdom, Finland, Spain, Poland, Hungary, Slovenia, the Czech Republic, and North Macedonia a relatively new type of two-lane roundabout designs is emerging, called "turbo roundabouts". These designs require motorists to choose their direction before entering the roundabout, thereby eliminating many conflicting paths and choices on the roundabout itself, so that traffic safety is increased, as well as speed and capacity. These designs, seen from above, typically result in a spiralling flow of traffic, giving them the collective name of turbo roundabouts. As a minor drawback turbo roundabouts are often marked out such that a U-turn by means of the roundabout is not possible for drivers approaching on certain arms.

Several variations of turbo roundabouts exist. They are frequently designed for the intersection of a major road crossing a road with less traffic.

An early application of the principle was a six-arm and therefore relatively large (and fast) non-circular roundabout at Stairfoot, Barnsley, South Yorkshire, which was given spiral marking about 1984. At that time the method was considered experimental and needed special consents from central authorities. The turbo roundabout was formally developed in 1996 in the Netherlands by Lambertus Fortuijn, a researcher from the Delft University of Technology.[79] Similar roundabouts, with spiralling lane markings, have been used for many years in the UK e.g. the A176/A127 (eastbound) at Basildon, Essex (51°33′41″N 0°27′11″E / 51.561399°N 0.452934°E). However it was not until 1997 that the UK's national highway authorities published guidance (DMRB TA-78/97) that in effect endorsed use of spiral markings in certain circumstances.

Turbo roundabouts can be built with raised lane separators (common in the Netherlands[80]) or with lane markings only. The use of raised lane separators prevents road users from switching (thereby reducing conflicts) but can make maneuvering for large vehicles more difficult.

According to simulations, a two-lane roundabout with three exits should offer 12–20% greater traffic flow than a conventional, three-lane roundabout of the same size. The reason is reduced weaving that makes entering and exiting more predictable. Because there are only ten points of conflict (compared with 8 for a conventional single lane roundabout, or between 32 and 64 with traffic signal control), this design is often safer as well. Research and experiments show that traffic accidents are reduced by 72% on turbo roundabouts compared to multi-lane roundabouts, which have 12 points of conflict.[81] Research at Windesheim University also shows that turbo roundabouts reduce accidents including casualties by some 75% when compared to regular intersections, and by 61% compared to single-lane roundabouts.[82] The same research made it very clear that it is safer for cyclists not to have priority over motor vehicles on the roundabout, than to have it.[82] At least 70 have been built in the Netherlands, while many turbos (or similar, lane splitting designs) can be found in southeast Asia.[83] Multi-lane roundabouts in the United States of America are typically required to be striped with spiral markings,[84] as most states follow the federal Manual on Uniform Traffic Control Devices.


Opatovice nad Labem kruhový objezd from air K2 -1
Motorway junction with roundabout in the Czech Republic 50°08′21″N 15°47′21″E / 50.13923°N 15.789149°E

Roundabouts are generally not appropriate for placement on motorway or freeway mainlines because the purpose of such facilities is to provide for uninterrupted traffic flow. However, roundabouts are often used for the junction between the slip roads (ramps in North America) and the intersecting road. A single roundabout, grade separated from the mainlines, may be used to create a roundabout interchange. This type of junction is common in the UK and Ireland. Alternatively, separate roundabouts also may be used at the slip road intersections of a diamond interchange to create what often is referred to as a "dumbbell interchange", which is increasingly common in both Europe and North America due to its reduced need for wide or multiple bridges.

An additional use of roundabouts for high-speed junctions is the 3-level stacked roundabout—this is a roundabout interchange where both of the roadway mainlines are grade separated. In the United Kingdom, the M25/A3, M8/M73 and A1(M)/M18 interchanges are examples of this type. These junctions, however, have less capacity than a full free-flow interchange. A similar design to this is the three-level diamond interchange.

Most junctions on Dublin's M50 motorway C-road were built using a standard roundabout interchange. The traffic volume of several of these junctions increased to a level higher than the capacity such roundabouts can accommodate, and in turn have been converted into partially or fully free flowing interchanges. One example is the Red Cow interchange. In Northern Ireland, the junction between the M1 and M12 (Craigavon connector motorway) is via a standard roundabout with a raised centre, three onslips and three offslips, and two lanes.

In the city of Malmö, Sweden, a roundabout connects two motorways, E22 from Lund, and the Inner ring road.

In the Netherlands, A6 motorway and A7 motorway used to cross near Joure using a roundabout until October 2017, when the junction was turned into a full Y-interchange.[85] The junction between the A200 and the A9 uses a 3-level stacked roundabout. Near Eindhoven (the Leenderheide junction), the junction for the A2 uses a roundabout. An overpass was built for the A67 from Antwerp to Germany.

Rotary interchanges operate with traffic circles rather than roundabouts. Rotary interchanges are common in New England, particularly in the state of Massachusetts, but a European example of a rotary interchange may be found in Hinwil, Switzerland.

Signalised roundabouts

Old Market Roundabout, Bristol
A major signal-controlled roundabout interchange in central Bristol, England. Vehicles drive on the left, and vehicles in the roundabout are stopped by traffic lights to allow other vehicles to enter, while an underpass permits straight-through traffic to bypass the roundabout entirely.

A signalised roundabout is one where one or more entry is controlled by traffic signals, rather than by assumed priority. For each signalised entry there will also be a signalised stopline immediately upstream on the circulatory section. The signals prevent blocking on the roundabout, and balance and improve traffic capacity.[86]

Examples include the M50 in Dublin, the Cherry Street roundabout in Kowloon, Hong Kong , Sheriffhall Roundabout in Edinburgh, Scotland, and many of the roundabouts along the Paseo de la Reforma in Mexico City.

"Magic" roundabouts/ring junctions

"Magic roundabouts" direct traffic in both directions around the central island. They are officially known as "ring junctions". The first magic roundabout was constructed in 1972 in Swindon, Wiltshire, United Kingdom, designed by Frank Blackmore,[87] inventor of the mini-roundabout. The roundabout joins five roads and consists of a two-way road around the central island, with five mini-roundabouts meeting the incoming roads.

The name derives from the popular children's television series, The Magic Roundabout, and is considered "magic" because traffic flows in both clockwise and anticlockwise directions. This is achieved by surrounding the main island with one smaller roundabout per entry/exit street. This pattern directs traffic in the usual clockwise (in LHT installations) or counter-clockwise (in RHT installations) manner around each mini-roundabout. Exiting the mini-roundabouts, traffic may proceed around the central island either in the usual direction (via the outer loop), or in the inverse direction (the inner loop). The arrangement offers multiple paths between feeder roads. Drivers typically choose the shorter, most fluid route. Although the safety record is good,[88] many drivers find this system intimidating, and some drivers go to great lengths to avoid them.[89][90][91]

Similar systems are found in the Moor End roundabout in Hemel Hempstead (Hertfordshire), which has six intersections; in High Wycombe (Buckinghamshire),[92] the Denham Roundabout in Denham (Buckinghamshire), the Greenstead Roundabout in Colchester (Essex), "The Egg" in Tamworth (Staffordshire) and the Hatton Cross Roundabout in London.[93]

Churchbridge Junction in Staffordshire is a magic gyratory. This type of junction is similar to a magic roundabout, except that the constituent roundabouts are connected by longer lengths of roadway.[94]

Magicroundabout hemel

Line drawing of the roundabout "Magic Roundabout" at Hemel Hempstead illustrating the concept and the reverse (anticlockwise) flow of the inner lane


Tram roundabouts, which are found in many countries, merge roundabouts for individual vehicles with tram lines. Large areas are needed for tram roundabouts that include a junction between tram lines. Such systems often contain tram stops.

Tram rails usually cross roundabouts in the center. This requires traffic lights or special signalling granting the trams priority. However, there are also roundabouts where trams and vehicles use the same lane. Some roundabouts have a tram stop on their island.

In inner Melbourne, particularly in the inner suburban area of South Melbourne, where the tram network is extensive, tram tracks always pass through the central island, with drivers required to give way to vehicles approaching from their right and to trams approaching from right-angles.

The Haymarket roundabout between Royal Parade and Elizabeth Street contains a tram-stop, pedestrian crossings, three entering tram lines, traffic signals to stop vehicular traffic at each crossing point when a tram is due, service roads and a pedestrian crossing.

Brussels tram roundabouts employ multiple configurations. At the Barrière de St-Gilles/Bareel St-Gillis, tram tracks form a circle in the carriageway, while Verboekhoven and Altitude Cent/Hoogte Honderd have reserved tram tracks inside the roundabout. At Place Stéphanie/Stefaniaplein, they go straight through the center, with a slip track up the Chaussée de Charleroi/Charleroisesteenweg, while at Montgomery they tunnel underneath.

In Dublin, Ireland, the Red Cow interchange at the N7/M50 junction is grade-separated and is signal-controlled with secondary lanes (separate from the main roundabout) for those making left turns. The junction, the busiest in Ireland, had tram lines added to it with the opening of the Luas system in 2004. The tracks pass across one carriageway of the N7, and across the southern M50 sliproads. Trams pass every five minutes at rush hour. The roundabout was replaced with a grade-separated free flowing junction.

Gothenburg, Sweden has a tram roundabout and tram stop at Korsvägen (the Crossroad). It carries heavy vehicular traffic and about one tram or bus per minute passes in several directions. This is further complicated by separated rights-of-way for trams and buses and the fact that it is one of the busiest interchanges in the city. Another one is located at Mariaplan in the inner suburb of Majorna. The trams makes a right turn, giving the roundabout an odd design.

In Warsaw, trams typically cross straight through roundabouts, and have junctions in the center of them. In Wrocław, Poland, trams pass through the Powstańców Śląskich Roundabout, stopping in the roundabout (north-headed track).

The Silesian tram network in Poland has two tram roundabouts. In the city centre of Katowice, the tram line passes through the center of the Ziętka Roundabout in a north-south alignment, with a tram stop in the center of the circle.[a] In Będzin, unusually, the tram junction itself forms a circular roundabout, with trams going around the circle; there are tram stops immediately outside the roundabout on each branch.

In Vítězné náměstí (Victory Square) in Prague, Czech Republic, a tramway crosses the carriage way of the roundabout at three places. Entering as well as leaving trams give way to vehicles. In the years 1932–42 trams circulated much like vehicles.[95]

In Kiev, Ukraine an interchange of two "fast tram" lines is below a roundabout.

Oslo, Norway also has many roundabouts with tram tracks passing through; for example at Bislett, Frogner plass, Sinsen, Solli plass, Carl Berners plass and Storo.

In Wolverhampton, England, the Midland Metro tram passes through the centre of a roundabout on approach to its terminus at St. Georges. This also happens in New Addington on the Tramlink on Old Lodge Lane at the junction to King Henry's Drive.

In Sheffield, England the Sheffield Supertram systems crosses two major roundabouts. At the Brook Hill roundabout near Sheffield University, the tramway passes underneath the roundabout in a subway, while at Park Square in the city centre it travels above the roundabout on bridges and viaducts with a junction in the central island.

A roundabout in southern Zagreb, Croatia features tram tracks passing through, curving at a 90° angle, as well as a full tram mini-roundabout inside the middle road island. In Croatia, where tram tracks enter the road without traffic lights, trams have the highest right of way and other non-emergency vehicles are required to yield.

In Salt Lake City, Utah a light rail line on the south side of the University of Utah crosses a roundabout where Guardsman Way meets South Campus Drive. Like virtually all rail crossings in the United States, both crossings in the circle are equipped with boom barriers.

In Kassel, Germany, Lines 4 and 8 pass through the center of the roundabout at Platz der Deutschen Einheit. The tram stops are in the center of the roundabout. Roundabout traffic is controlled by traffic lights. Pedestrian access is via subway and street level crossings at the lights.

In Bremen, Germany, tram lines 8 and 6 pass through the center of the roundabout "Am Stern" east of the main railway station. They enter from the west and exit in a northeastern direction thus making a slight bend within the roundabout. Both stations are situated on the north-eastern edge of the roundabout. Traffic is controlled by two-colour traffic lights inside the roundabout.

In Antalya, Turkey, there are four tram roundabouts; while the tram line is grade-separated from two of them, named Anadolu and Çallı.

In Oldham, England, the Metrolink line to Rochdale crosses a roundabout that was originally built as part of a town centre bypass. The whole road level had to be lowered to enable the tram overhead power wire to pass under the bypass flyover. The trams have priority and the traffic lights change accordingly as a tram approaches. A "throughabout" was also added to enable traffic heading in one direction onto the bypass to avoid being held by the tram.


In Jensen Beach, Florida, the main line of the Florida East Coast Railway running north-south bisects the two-lane roundabout at the junction of Jensen Beach Boulevard running east–west. It hosts three other roads and the service entrance to a large shopping plaza. Boom barriers line the railway crossings. The landscaped central island bisected by the tracks was originally curbed/kerbed, but 18-wheelers had trouble negotiating the roundabout, so the curbs were replaced with painted concrete strips. The roundabout was built in the early 2000s and improved traffic flow, although long freight trains often cause delays.[96][97]

Two roundabouts in the Melbourne metropolitan area, Highett, Victoria[98] and Brighton,[99] have heavy rail crossing the roundabout and through the inner circle. Boom barriers protect the railway from oncoming traffic at the appropriate points in the roundabout.

At the Driescher Kreisel[100] in Bergisch Gladbach, Germany, a railway serving a nearby paper factory crosses a roundabout located next to a shopping centre and pedestrian zone. The flow of traffic and pedestrians is governed by 14 barriers, 22 traffic lights and 8 loudspeakers. The barriers close three times daily for 7 minutes to allow trains to pass.

In New Zealand's South Island, two roundabouts join major roads where a railway cuts through. One is at the intersection between State Highway 1 (as Sinclair Street and Main Street from the east) and Main Street (from the west), Park Terrace and Redwood Street in the city of Blenheim. Here the Main North Line bisects the roundabout and separates Park Terrace and Main Street eastbound from the rest of the roundabout.[101] The other roundabout is located at Kumara Junction on the West Coast, where the Hokitika Branch separates State Highway 6 southbound from SH 6 northbound and SH 73.[102] Both roundabouts are controlled by flashing red lights, with additional boom barriers at the Blenheim roundabout.

Hamburger roundabout/throughabout/cut-through

These resemble a typical roundabout but are signalised and have a straight-through section of carriageway for one of the major routes. The hamburger name derives from the fact that the plan view resembles the cross-section through a hamburger. The United Kingdom has examples on the A580 East Lancashire Road in St Helens, on Haydock Island in Merseyside[103] (which also features the M6 passing overhead), and on the Astley/Boothstown border.[104] More examples are the A6003 at Kettering, the A538 near Manchester Airport, the "Showcase" junction on A329 at Winnersh, Berkshire[105] and the A63/A1079 Mytongate junction in Hull. Examples also exist in Bracknell, Hull,[106] Bramcote in Nottinghamshire and Reading, as well as on the N2/M50 intersection in Dublin, Ireland. In Perth, Western Australia, one is found at the intersection of The Strand, Morley and Alexander Drives.[107] Throughabouts are very common in Spain, where they are called raquetas (Spanish for "[tennis] racket") or glorieta/rotonda partida ("split roundabout").[108]

A more advanced and safer version of a hamburger roundabout is a roundabout interchange, separating the straight roadway and using underpasses or overpasses to cross the roundabout itself.



Throughabout Rotonde Verkeersbord 3

Throughabout road sign in the Netherlands 51°51′02″N 5°49′54″E / 51.850517°N 5.831576°E

Bicycle-pedestrian roundabouts

Roundabout Levane
This old traffic circle became a modern roundabout in Levane, Tuscany

The same features that make roundabouts attractive for roadway junctions led to their use at junctions of multi-use trails. The University of California, Davis[109] and Stanford University, as well as the Cape Cod and Old Colony rail trails have bicycle-pedestrian roundabouts.

Roundabouts are used on off-road bicycle trails in Florida, Colorado, Alaska, and Wisconsin.[110][111][112]

An elevated roundabout is located in Eindhoven, serving pedestrian and bicycle traffic only, above the main conventional roadway intersection. It is known as the Hovenring.

See also


  1. ^ There is also a branch line immediately north of the roundabout going west, and an additional tram stop on that branch.


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External links

A41 road

The A41 is a major trunk road in England that links London and Birkenhead, although it has now in parts been superseded by motorways. It passes through or near various towns and cities including Watford, Kings Langley, Hemel Hempstead, Aylesbury, Solihull, Birmingham, West Bromwich, Wolverhampton, Newport, Whitchurch, Chester and Ellesmere Port.

It follows part of the line of the old Roman road, Akeman Street and the eighteenth century Sparrows Herne turnpike.

With the opening of the M40 extension in 1990 from junction 8 – linking with the M42 near Birmingham – much of the route was downgraded in importance. The sections between Bicester, Oxfordshire and the M42 near Solihull, West Midlands have been re-classified B4100, A4177 and A4141.

A45 road

The A45 is a major road in England. It runs east from Birmingham past the National Exhibition Centre and the M42, then bypasses Coventry and Rugby, where it briefly merges with the M45 until it continues to Daventry. It then heads to Northampton and Wellingborough before running north of Rushden and Higham Ferrers and terminating at its junction with the A14 road in Thrapston.

Prior to the construction of the M6 motorway it was the main route from the Midlands to Ipswich and to the Haven ports. When the A1-M1 link road section of the current A14 opened in 1994 most of the A45 to the east of Cambridge was re-designated as the A14 and some sections to the west were downgraded to B-roads (including the B645 between Higham Ferrers and St Neots).

A46 road

The A46 is a major A road in England. It starts east of Bath, Somerset and ends in Cleethorpes, Lincolnshire, but it does not form a continuous route. Large portions of the old road have been lost, bypassed, or replaced by motorway development. Between Leicester and Lincoln the road follows the course of the Roman Fosse Way, but between Bath and Leicester, two cities also linked by the Fosse Way, it follows a more westerly course.

A6 road (England)

The A6 is one of the main historic north–south roads in England. It currently runs from Luton in Bedfordshire to Carlisle in Cumbria, although it formerly started at a junction with the A1 at Barnet. It is the fourth longest numbered road in Britain, behind only the A1, A38 and A30.

Running north-west from Luton, the road travels through Bedford, bypasses Rushden, Kettering and Market Harborough, continues through Leicester, Loughborough, Derby and Matlock before going through the Peak District to Bakewell, Buxton, Stockport, Manchester, Salford, Pendleton, Irlams o' th' Height, Pendlebury, Swinton, Wardley, Linnyshaw, Walkden, Little Hulton, Bolton, Chorley, Preston, Lancaster, Kendal and Penrith before reaching Carlisle.

South of Derby, the road is paralleled by the M1 motorway, between Manchester and Preston the M6 and M61 motorways approximate its course, and from Preston to its northern terminus in Carlisle it is paralleled by the M6 only. Between Derby and Manchester the A6 follows a completely different routing to the motorway network, crossing the Peak District rather than going around it. Because of these duplications, the A6 is less important than it was formerly.

Diamond interchange

A diamond interchange is a common type of road junction, used where a freeway crosses a minor road.

Handy Cross roundabout

Handy Cross roundabout is a major road interchange at Handy Cross, High Wycombe, Buckinghamshire; the junction for High Wycombe, the M40 motorway and the A404 dual-carriageway. It is the terminus of the A4010 which runs to Aylesbury.

Jalan Mambong–Sejingkat

Jalan Mambong–Sejingkat, Sarawak State Route 13, is a major highway in Kuching and Samarahan Division, Sarawak, Malaysia.

M606 motorway

The M606 is a short stretch of motorway in West Yorkshire, England. Called the Bradford Spur motorway, the M606 leaves the M62 motorway at junction 26, near Cleckheaton, and heads into Bradford, to join the A6177 Bradford Ring Road. It is officially named the "Bradford South Radial Motorway" and was opened in 1973.

Malaysia Federal Route 500

Federal Route 500 (formerly Sabah State Route SA3) is a 163-kilometre (101 mi) federal highway in Sabah, Malaysia, connecting Kota Kinabalu to Tenom. It serves as the main highway from Kota Kinabalu to towns and villages in the Interior Division of Sabah. Federal Route 500 is one of the five highways in Sabah crossing the Crocker Range; the Tamparuli-Ranau Highway, Kimanis-Keningau Highway and Jalan Tenom-Sipitang are the other three and the new highway, Interior North–South Highway.

While the original Route SA3 is longer, only the section between Kota Kinabalu to Tenom is recommissioned as a federal highway; the section between Tenom to Paal retains its state highway code, while the remaining section from Paal to Kuala Tomani was renumbered as Route SA33 after Jalan Tenom-Sipitang was completed in 2007 and was commissioned as part of Sabah State Route SA3.

N27 road (Ireland)

The N27 road is a national primary road in Ireland forming a route from Cork city centre to Cork Airport.

The route runs out of the city centre along the following route: Michael Collins Bridge, Custom House Street, Éamon De Valera Bridge, Albert Street and Old Market Road. The bridges are across the two diverged parts of the River Lee which flow around the city centre. The South Link Road was opened to traffic in May 1985. By the mid 1990s, the road surface of the South Link Road had fallen into a state of disrepair. Between 1998 and 1999, a new road surface was laid down along the entire distance of this route. The South Link Road brings the N27 from the city centre area out to the N40 Cork South Ring Road at the Kinsale Road Roundabout, a three lane signal-controlled non-symmetrical roundabout (with 5 exits) that has been upgraded to a grade-separated interchange in relatively recent times, and referred to as the Magic Roundabout. The southern exit of this roundabout is the Kinsale Road, or Airport Road, and carries the N27 out to the airport. The section of the N27 between the Kinsale Road Roundabout and Farmer's Cross was improved during the mid to late 1990s. In 2005, this route section received further improvements. The route terminates at the Airport Road Roundabout. The western exit at this roundabout is the only main access into the airport itself. There are now plans to construct a secondary access route to Cork Airport.

N40 road (Ireland)

The N40 road (commonly known as the Cork South Ring Road) is a national primary road in Cork City, Ireland, which forms an orbital route around the south side of the city, linking the N22 at Ballincollig to the N25 at the Dunkettle Interchange. The present N40 was created on 23 February 2012 via statutory instrument. The newly designated N40 was formed from parts of both the N22 and N25. It is intended that once the Cork North Ring Road is completed, that the N40 will comprise a complete orbital route of Cork city.

Pearl Roundabout

The GCC Roundabout, known as Pearl Roundabout or Lulu Roundabout (Arabic: دوار اللؤلؤ(ة)‎ Dawwār al-luʾluʾ(ah), "Roundabout of the pearl(s)") was a roundabout located near the financial district of Manama, Bahrain. The roundabout was named after the pearl monument that previously stood on the site and was destroyed on March 18, 2011 by government forces as part of a crackdown on protesters during the Bahraini uprising of 2011.

R443 road (Ireland)

The R443 road is a regional road in Ireland, which forms the northern and western part of an orbital route around the town of Tullamore. The southern and eastern part is formed by the N52 Tullamore bypass. The R443 commences at a roundabout junction with the N52/N80. From here it travels along Clonminch Road (former N80) and O'Moore Street; it then joins the R421 (former N52) for a distance of 400 metres along Cormac Street. The road then continues along the "Western Relief Road" along the western edge of the town. It has roundabout junctions with the R420 Clara Road (former N80) and the R421 Arden Road (former N52) in addition to other roundabouts for industrial, retail and residential estates. The road terminates at a roundabout with the N52 Tullamore bypass on the northern side of the town.

The total length of the road is 8.2km.

Roundabout (song)

"Roundabout" is a song by the English progressive rock band Yes from their fourth studio album Fragile, released in November 1971. It was written by singer Jon Anderson and guitarist Steve Howe and produced by the band and Eddy Offord. The song originated when the band were on tour and travelled from Aberdeen to Glasgow, and went through many roundabouts on the way.

The song was released as an edited single in the US in January 1972 with "Long Distance Runaround", another track from Fragile, as the B-side. It peaked at number 13 on the Billboard Hot 100 and number 10 on the Cash Box Top 100 singles charts. In 1973, Anderson and Howe won a BMI Award for writing the song.

Roundabout Theatre Company

The Roundabout Theatre Company is a leading non-profit theatre company based in Midtown Manhattan, New York City, affiliated with the League of Resident Theatres.

Roundabout interchange

A roundabout interchange is a type of interchange between a controlled access highway, such as a motorway or freeway, and a minor road. The slip roads to and from the motorway carriageways converge at a single roundabout, which is grade-separated from the motorway lanes with bridges.

Studio 54

Studio 54 is a former nightclub and currently a Broadway theatre, located at 254 West 54th Street, between Eighth Avenue and Broadway in Midtown Manhattan, New York City. The building, originally built as the Gallo Opera House, opened in 1927, after which it changed names several times, eventually becoming CBS radio and television Studio 52.

In the late 1970s, at the peak of the disco dancing and music trend, the building was renamed after its location and became a world-famous nightclub. The nightclub founders spent hundreds of thousands of dollars on professional lighting design and kept many of the former TV and theatrical sets, and in the process created a unique dance club that became famous for its celebrity guest lists, restrictive (and subjective) entry policies (based on one's appearance and style), and open club drug use. Founded and created by Steve Rubell and Ian Schrager in 1977, it was sold in 1980 to Mark Fleischman, who reopened the club after it had been shut down following Rubell and Schrager's convictions on charges of tax evasion. In 1984, Fleischman sold the club, which continued to operate until 1986.

Since November 1998, the site has served as a venue for productions of the Roundabout Theatre Company and retains the name Studio 54. A separate restaurant and nightclub, Feinstein's/54 Below, operates in the basement of the building.

The Magic Roundabout

The Magic Roundabout is an English-language children's television programme that ran from 1965 to 1977. It used the video of the French stop motion animation show Le Manège enchanté, but with completely different scripts and characters.

The French series, created by Serge Danot with the help of Ivor Wood and Wood's French wife, Josiane, was broadcast from 1964 to 1974 on ORTF (Office de Radiodiffusion Télévision Française). The BBC originally rejected translating the series because it was "charming... but difficult to dub into English", but later produced a version of the series using the French footage with new English-language scripts that bore little relation to the original storylines. This version, written and narrated by Eric Thompson, was broadcast in 441 five-minute-long episodes from 18 October 1965 to 25 January 1977. It proved a great success and attained cult status, and when in October 1966 it was moved from the slot just before the evening news to an earlier children's viewing time, adult viewers complained to the BBC.

West Cross Route

The West Cross Route (WCR) is a 0.75 miles (1.21 km)-long dual carriageway section of the A3220 route in central London in The Royal Borough of Kensington and Chelsea, with a small part being shared with borderlining borough Hammersmith and Fulham. It runs north-south between the northern elevated roundabout junction with the western end of Westway (A40) and the southern Holland Park Roundabout. It opened in 1970, together with Westway.

The WCR was formerly the M41 motorway. Its status was downgraded to an A-road in 2000 when responsibility for trunk roads in Greater London was transferred from the Highways Agency to the Greater London Authority. Approximately halfway along the road's length a new junction was built to serve the Westfield London shopping development. The WCR was originally the designation for the western section of Ringway 1, the innermost circuit of the London Ringways network, a complex and comprehensive plan for a network of high-speed roads circling central London designed to manage and control the flow of traffic within the capital. The road would have run from Battersea to Harlesden and would have paralleled the National Rail West London Line as an elevated road. Although the road no longer has motorway status, pedal cycles are prohibited by a sign at Holland Park roundabout.

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