, at
Putrajaya, Malaysia 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 where there are significant lengths of carriageway between the entry arms, or when buildings occupy the central island. In the 21st century several gyratory systems in London have been removed, including Tottenham Hale and
Elephant and Castle.
Smaller, small and mini-roundabouts , Canada As the overall or external size of a roundabout (in the UK referred to as the Inscribed Circle Diameter – ICD) is reduced, 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 the 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 the carriageway by a combination of a 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 is 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.
Mini-roundabouts 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. Mini-roundabouts can incorporate 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. 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. 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 (inscribed circle diameter) for a mini roundabout is 28 metres (30 yards).
Raindrop roundabouts These roundabouts do not form a complete circle and have a "
raindrop" or "
teardrop" shape. They have also been used at
bowtie intersections, replacing traffic signals that are inefficient without a turning lane. In addition to their use at intersections, raindrop roundabouts are also used in
dogbone interchanges (described
below).
Balcony roundabout A balcony roundabout is just an elevated roundabout. They are constructed in such a way that vulnerable road users can cross underneath the roundabout. Footpaths and cycle paths along the different roads connect to the square under the roundabout. Vulnerable road users do not interfere with motorised traffic on the roundabout, reducing the risk of collision.
Turbo roundabouts In the
Netherlands,
Belgium,
Bosnia and Herzegovina,
the United Kingdom,
Finland,
Spain,
Poland,
Hungary,
Slovenia,
Slovakia, the
Czech Republic,
North Macedonia,
Croatia,
Germany, and the U.S. states of
Alabama,
California, and
Florida, 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. One minor drawback is that 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 consent 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. Similar roundabouts, with spiralling lane markings, have been used for many years in the UK e.g. the A176/A127 (eastbound) at
Basildon, Essex (). However, it was not until 1997 that the UK's national highway authorities published guidance (DMRB TA-78/97) that in effect endorsed the use of spiral markings in certain circumstances. Turbo roundabouts can be built with raised lane separators (common in the Netherlands) or with lane markings only. The use of raised lane separators prevents road users from weaving (thereby reducing conflicts) but can make manoeuvring more difficult for large vehicles. 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. 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. 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.
Motorways , Czech Republic 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 (called
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. A variation of the dumbbell interchange, often called a "
dogbone interchange", occurs when the roundabouts do not form a complete circle but are instead raindrop roundabouts (described
above). This configuration reduces conflicts between vehicles entering the raindrop roundabouts from the ramps, reducing queueing and delays, compared with the dumbbell interchange. 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. 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. Near
Liège, Belgium, the Cheratte interchange between the
A3/E40 and
A25/E25 functions partially as a roundabout, with through traffic allowed to continue without entering the junction and traffic changing between motorways required to use the roundabout. 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 , 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. Examples include the M50 in Dublin; the Cherry Street roundabout in
Kowloon, Hong Kong; Sheriffhall Roundabout in Edinburgh, Scotland; Newton Circus in
Singapore; and many of the roundabouts along the
Paseo de la Reforma in
Mexico City. An evolution of the signalised roundabout has been proposed recently. It is based in avoiding stops by eliminating conflict points in roundabouts. This proposed new paradigm (SYROPS) forms platoons of vehicles (e.g. 2 x 3 cars) that arrive at the roundabout with speed identical to the average circulation speed in the roundabout and within the time interval (visualised as a rotating priority sector) assigned to his entrance, avoiding all the conflicts of passage and with it the stops and accelerations required in standard and in signalled roundabouts. Signalling signage is with lights for human drivers and optionally wireless for connected and autonomous vehicles.
Magic roundabouts and ring junctions "Magic" roundabouts (also known as "ring junctions") direct traffic in both directions around the central island. The
first magic roundabout was constructed in 1972 in
Swindon, Wiltshire, United Kingdom, designed by
Frank Blackmore, 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, many drivers find this system intimidating, and some drivers go to great lengths to avoid them. Similar systems to the Swindon design found elsewhere in the United Kingdom include the
Plough Roundabout in
Hemel Hempstead, Hertfordshire (which has six intersections);
Denham Roundabout in
Denham, Buckinghamshire;
Greenstead Roundabout in
Colchester, Essex;
Hatton Cross Roundabout in London, outside
Hatton Cross tube station; and the
Abbey Way Gyratory in
High Wycombe, Buckinghamshire.
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. Magic Roundabout Schild db.jpg|The
Swindon Magic Roundabout Swindon_magic_roundabout.svg|Map with traffic direction and two routes from Fleming Way to Queen's Drive
Dutch-style roundabouts for bicycles and pedestrians in
Oslo,
tramways cross the roundabout ,
Melbourne Trams Tram roundabouts, which are found in many countries, combine roundabouts for individual vehicles with tram lines. Large areas are needed for tram roundabouts that include a junction between tram lines. Tramways usually cross the centre of the roundabout. At busy junctions, this requires traffic lights or special signalling granting the trams priority. However, there are also roundabouts where trams and vehicles share the carriageway. Some roundabouts have a tram stop on the island. • In France, tram roundabouts commonly have radii between 14 and 22 metres, although some have radii outside this range. • In some cities, the tramway bisects the roundabout. The French considers that the mix of priorities makes these confusing and difficult to understand: a traditional modern roundabout gives the priority to the central ring, while tram roundabouts give priority to the central ring but higher priority still to the tramway. This generates many collisions of cars and trams, between 7 and 10 for each tram roundabout in France between 2006 and 2015 (between 0.37 and 1.01 per year). • In
Kyiv, 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
West Midlands Metro tram passes through the centre of a roundabout on the approach to its terminus at
St Georges. This also happens in
New Addington in
Croydon on the
Tramlink north of
King Henry's Drive tram stop 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 priority 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 centre of the roundabout at Platz der Deutschen Einheit. The tram stops are in the centre 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 centre 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.
Railways railway bisects the /Main Street roundabout in
Blenheim, New Zealand. 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
kerbed, but
18-wheelers had trouble negotiating the roundabout, so the kerbs 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. Two roundabouts in the Melbourne metropolitan area,
Highett and
Hampton, 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. As a part of the
Level Crossing Removal Project, the roundabout at Highett will be removed and replaced with a rail overpass by 2029. At the Driescher Kreisel 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 (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. The other roundabout is located at
Kumara Junction on the
West Coast, where the
Hokitika Branch separates southbound from SH 6 northbound and . Both roundabouts are controlled by flashing red lights, with additional boom barriers at the Blenheim roundabout.
Through roundabout Also known as a hamburger roundabout, these junctions 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 (which also features the M6 passing overhead), and on the Astley/Boothstown border. More examples are the
A6003 at
Kettering, the
A538 near
Manchester Airport, the "Showcase" junction on A329 at Winnersh, Berkshire and the A63/A1079 Mytongate junction in Hull. Examples also exist in
Bracknell, Hull, 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
Alexander Drive,
Morley Drive and The Strand. Throughabouts are very common in Spain, where they are called
raquetas (Spanish for
racket") or
glorieta/rotonda partida ("split roundabout"). Throughabout.svg|Throughabout Throughabout Rotonde Verkeersbord 3.jpg|Throughabout road sign in the Netherlands E37 AlexanderDr-MorleyDr sign.jpg|Throughabout road sign in Australia
Only bicycle-pedestrian roundabouts 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 and
Stanford University, as well as the
Cape Cod and
Old Colony rail trails have bicycle-pedestrian roundabouts. A roundabout along the
Clear Creek Trail in
Bloomington, Indiana, connects the main
trail to its
spur. Roundabouts are used on off-road bicycle trails in
Florida,
Colorado,
Alaska, and
Wisconsin. 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 ==