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Bus rapid transit (BRT) is a broad term given to a variety of transportation systems that, through improvements to infrastructure, vehicles and scheduling, attempt to use buses to provide a service that is of a higher quality than an ordinary bus line. Each BRT system uses different improvements, although many improvements are shared by many BRT systems. The goal of such systems is to at least approach the service quality of rail transit while still enjoying the cost savings of bus transit. The expression BRT is mainly used in North America; in Europe and Australia, it is often called a busway, while elsewhere, one may speak of quality bus or simply bus service while raising the quality.

Bus rapid transit takes part of its name from rapid transit which describes a high-capacity rail transport system with its own right-of-way, its alignment often being elevated or running in tunnels, and typically running long trains at short headways of a few minutes. Because of the name similarity one tends to associate the merits of rapid transit also with the newer BRT expression. BRT encompasses a broad variety of modes, including those known or formerly known as express buses, limited busways and rapid busways and even BHNS in France (Bus à Haut Niveau de Service).

Ironically, the term bus rapid transit does not refer to the speed of BRT buses. Typical transit speeds of BRT systems range from 12 to 30 miles per hour (19 to 48 km/h) which compares well with surface running LRT.^[1]

Main BRT features

These bus systems can come in a variety of forms, from dedicated busways that have their own rights-of-way (e.g., Ottawa's Transitway or the Pittsburgh MLK East Busway) to bus services that utilize HOV lanes and dedicated freeway lanes (e.g., Honolulu's CityExpress) to limited stop buses on pre-existing routes.

An ideal bus rapid transit service would be expected to include most of the following features:

Bus only, grade-separated (or at-grade exclusive) right-of-way : The main feature of a BRT system is having dedicated bus lanes which operate separate from all other traffic modes. This allows buses to operate at a very high level of reliability since only professional motorists are allowed on the busway. A side benefit of this are lower construction costs since busways can be engineered to tighter standards and still remain safe compared to a roadway open to non-professional drivers.
- Such a right of way may be elevated; on rare occasions, the right of way may be a modified rail right of way,
- A bus street or transit mall can be created in an urban center by dedicating all lanes of a city street to the exclusive use of buses,
- Low-cost infrastructure elements that can increase the speed and reliability of bus service include bus turnouts, bus boarding islands, and curb realignments.
Comprehensive coverage : In addition to using dedicated busways, BRTs can also take advantage of existing roadways in cities that already have a comprehensive road network for private automobiles. Service can be made more time efficient and reliable than a standard bus system by taking advantage of bus priority methods.
Serves a diverse market with high-frequency all day service : A BRT network with comprehensive coverage can serve a diverse market (all income ranges) by moving people from their current location to their destination with high frequency and reliability while maintaining a high level of customer experience. As with any transit system, if any of these benefits are taken out of the equation, or do not provide better service than other modes of transit, the network will not be able to serve as diverse a market or offer high-frequency service without heavy subsidy.
Bus priority / bus lanes : Preferential treatment of buses at intersections can involve the extension of green time or actuation of the green light at signalized intersections upon detection of an approaching bus. Intersection priority can be particularly helpful when implemented in conjunction with bus lanes or streets, because general-purpose traffic does not intervene between buses and traffic signals.
Vehicles with tram-like characteristics : [1] RUZway]

Recent technological developments such as bi-articulated buses and guided buses have benefited the set up of BRT systems. The main developments are:

- Improved riding quality (guided buses, electronic drivetrain control smoothing the operation),
- Increased capacity (bi-articulated or double decker),
- Reduced operating costs (hybrid electric power train).
A specific image with a brand name : (Viva, Max, TransMilenio...) and specific stations with state of the art features, automatic vending machines...
Off-bus fare collection : Conventional on board collection of fares slows the boarding process, particularly when a variety of fares is collected for different destinations and/or classes of passengers. An alternative would be the collection of fares upon entering an enclosed bus station or shelter area prior to bus arrivals (similar to how fares are collected at a kiosk before entering a subway system). This system would allow passengers to board through all doors of a stopped bus.
Bus stop of the Rede Integrada de Transporte (RIT) in Curitiba, Brazil.
Level boarding : Many BRT systems also use low floor buses (or high level platforms with high floor buses) to speed up passenger boardings and enhance accessibility.
Stations : High quality BRT systems also feature significant investment in enclosed stations which may incorporate attractive sliding glass doors, staffed ticket booths & information booths, and other more standard features listed here such as off-bus fare collection (sometimes through turnstiles), and level boarding. This style of station is particularly prevelant in Latin America, while most North American systems tend to use open platform stops, or shelter-style platform stops.

Acceptance of BRT may increase using trolley-buses, because of the lower gaseous and noise emissions. The price penalty of installing overhead lines can be repaid over a longer period by the savings from centrally generated electricity^{[citation needed]}.

Controversies

Opponents of bus rapid transit initiatives argue that BRT is not an effective replacement for light rail or subway services. They argue that in order for BRT to have greatest effect, it must have its own right-of-way requiring space and often construction costs. A regular bus service would share the road with cars; a BRT service operating in mixed traffic would be subject to the same congestion, delays, and jarring and swaying rides as do ordinary city buses. Furthermore, signal priority systems, which are often the sole factor differentiating BRT from regular limited-stop bus service (most notably in Los Angeles' extensive "Rapid" system), might cause severe disruptions to traffic flow on major cross streets. Opponents argued that this merely redistributes, rather than reduces, the traffic congestion problems that BRT systems are designed to alleviate. On the other hand, many light rail systems also utilize signal priority system and railroad-style crossing gates (with long cycle times) to speed up service as well, and in the same time both BRT and light rail get more persons across a road junction than car traffic. The widespread belief that the most effective method of solving traffic congestion problems is to discourage private car usage and the preferential treatment of buses in intersections, along with the conversion of some roads to exclusive bus right-of-ways, will help.

Also, the original system designed in Curitiba, Brazil, aimed to channel development along the BRT corridor. Retrofitting such a system in cities that have a different pattern of development may not be adequate to address the issues in those cities, or in most cases may be an aid for politicians to 'eco-wash' their stay in office. The original system is also part of a three street network that does not impede road width or road accessibility for traditional usage. It does not affect the character of the street, and clearly, that is the success story of Curitiba. Having dedicated lanes on narrow roads may adversely affect activity on those roads, and could lead to a situation like Howard St in Baltimore which has dedicated Light Rail lanes, but is increasingly treated like a backyard or a corridor for movement, and its distinct lack of character undermines its neighborhood. Another prime example of a disastrous effect of BRT has been in New Delhi. One of its most prime, widest main roads started having huge traffic pileups ever since the BRT was inaugurated in 2008. However, it should be noted that much of the controversy arises from the wide range of definitions of BRT.

Comparison with other forms of mass transit

BRT attempts to combine the advantages of a metro system (exclusive right-of-way to improve punctuality and frequency) with the advantages of a bus system (low construction and maintenance costs, does not require exclusive right-of-way for entire length, at least at the beginning).

Compared to standard bus service BRT systems with dedicated right-of-way and thus an increased average transport speed can provide more passenger-miles with the same number of rolling stock and personnel. They also offer the prospect of a more fluent ride than a normal bus immersed in stop-and-go traffic.

It is simplistic to use calculations to predict the capacity of BRT and normal buses and say typical buses are 12 metres (40 feet) long, articulated buses 18 metres (60 feet). The maximum length for a street-running tram consist (in Germany) is 75 metres (about 250 feet). Light rail systems running in-street are limited to one city block in length, unless, as in Sacramento, CA, they are allowed to obstruct intersections when stopped. Metro trains can be 240 m (about 800 feet) long.

With similar dwell times in stations the capacity of rail systems would scale with the length of the train. For instance, a light rail system running on two-minute headways with 200-passenger cars operating as single units could carry 6,000 passengers per hour. It should theoretically therefore carry 12,000 passengers per hour with two-car trains, and 24,000 per hour with four-car trains. In practice real world delays multiply and headways become disrupted causing a practical limitation of around 12 to 19,000^[2]

Effects and Comparison with LRT

The best source of information capacity comes from a study that actually stood at the side of the road and counted passengers. As quoted in.^[3] a survey by the UK Transport Research Laboratory revealed:

Exhibit 3-22: Maximum Observed Peak Hour Bus Flows, Capacities, and Passenger Flows at Peak Load Points on Transitways

Measured Peak Hour Passenger Flow (Passengers / Hour)

Designated Lane: Ankara, Istanbul, Abidjan 7,300 – 19,500

Designated Lanes with Feeders Curitiba, Brazil 13,900 – 24,100

Designated Lanes with Bus Ordering (Travelling in Clusters) Porto Alegre 17,500 – 18,300

Designated Lanes with Overlapping Routes, Passing at Stations and Express Routes

Belo Horizonte, São Paulo 15,800-20,300

However, many BRT systems such as OC Transpo Transitway, Ottawa and South-East Busway, Brisbane are based on multiple bus routes sharing a common dedicated busway to bypass congestion, especially to/from a central business district. In this form, the BRT system passenger capacity is limited by vehicle capacity times vehicle headway of the busway. As buses can operate at headways as low as 10 seconds between vehicles (compared to at least one minute headways for rail vehicles), actual busway capacity can reach passenger rail capacities. At the high end, the Lincoln Tunnel XBL bus lane carries 62,000 commuters in the 4 hour morning peak, more than any Light Rail Line. However, this lane has no stops in it. Stops increase the headway and limit a BRT lane to about 10,000 passengers per hour, even with passing lanes in the stations. Note that this is still five times the number carried in the automobiles in a congested freeway lane.

Many agencies make a clear distinction between a pure BRT, which is in exclusive lanes, and a more compromised form in mixed traffic. For example, the Los Angeles Orange Line runs entirely in an exclusive lane and therefore achieves speed and reliability comparable to rail. Because it is functionally equivalent to rail, the Los Angeles County Metropolitan Transportation Authority presents this line as part of its rail transit system, distinct from its "Rapid" lines, which run in mixed traffic.

The typical diesel engine on the bus causes noticeable levels of air pollution, noise and vibrations. Through developing buses as hybrid vehicles and the use of new forms of trolleybus BRT designers hope to increase ride quality and decrease pollution. As the energy use for acceleration is proportional to the vehicle mass, electric traction allows lighter vehicles, faster acceleration and energy that can be fed back into batteries or the grid through regenerative brakes. Regenerative braking is standard on modern rail systems.

In contrast to BRT, both Light Rail and rapid transit require the placement of rails for the whole line. The tram usually avoids the high additional costs for the engineering structures like tunnels that need to be built for metros. Rail tends to provide a smoother ride and is known to attract significantly higher passenger numbers than road-based systems.

Many BRT designers have used the need to construct power conduit systems as an argument against Light Rail, but a new proposal, known as ultra light rail, would have trams carry their own power, much like a bus, at a significant energy savings due to lack of rolling resistance.

In larger towns and cities, such as Essen, Germany and Pittsburgh, USA, it is common for a right of way exclusive to public transport to be used by both light rail and buses.

BRT in metro tunnels

A special issue arises in the use of bus vehicles in metro structures. Since the areas where the demand for an exclusive bus right-of-way is apt to be in dense downtown areas where an above-ground structure may be unacceptable on historic, logistic, or environmental grounds, use of BRT in fully underground tunnels may not be avoidable.

Since buses are almost universally operated by internal combustion engines, bus metros raise ventilation issues similar to those of tunnels. In the case of tunnels, powerful fans typically exchange air through ventilation structures on the surface, but are usually placed in a location as remote as possible from occupied areas to minimize the effects of noise and concentrated pollution.

A straightforward way to deal with this is to use electrical propulsion in tunnels and, in fact, Seattle in its Metro Bus Tunnel and Boston in Phase II of its Silver Line are using this method in their respective BRTs. In the case of Seattle, dual-mode (electric/diesel electric) buses manufactured by Breda were used until 2004, with the center axle driven by electric motors obtaining power from a trolley wire through a trolley pole in the subway, and with the rear axle driven by a conventional diesel powertrain on freeways and streets. Boston is using a similar approach, after initially using electric trolleybuses to provide service pending delivery of the dual mode vehicles in 2005. In 2004, Seattle replaced its "Transit Tunnel" fleet with diesel-electric hybrid buses, which operate similarly to hybrid cars outside the tunnel and in a low-noise, low-emissions "hush mode" (in which the diesel engine operates but does not exceed idle speed) when underground.

The necessity for providing electric power in these environments brings the capital and maintenance costs of such routes closer to light rail and raises the question of building light rail instead. In Seattle, the downtown transit tunnel retrofitted for conversion to a shared hybrid-bus and light-rail facility in preparation for Seattle's Central Link Light Rail line to be operating in 2009.

Bus rapid transit systems

For a list of the transit systems around the world, see list of bus rapid transit systems.

Implementation

References

^ Characteristics of BRT, page ES-5
^ [GARDNER G, RUTTER JC and F KUHN, The performance and potential of light rail transit in developing cities. TRI, Project Report No. PR69, Transport Research Laboratory, Crowthorne, UK 1994]
^ Characteristics of BRT, page ES-5

Gardner, G., Cornwell, P., and Cracknell, J., The Performance of Busway Transit in

Developing Cities, Transport and Road Research Laboratory Research Report 329, Department of Transport, Crowthorne, Berkshire, United Kingdom, 1991

External links

[1] Characteristics of BRT, page ES-5

[2] [GARDNER G, RUTTER JC and F KUHN, The performance and potential of light rail transit in developing cities. TRI, Project Report No. PR69, Transport Research Laboratory, Crowthorne, UK 1994]

[3] Characteristics of BRT, page ES-5

[1]

[2]

[3]

@@ Line 47: / Line 47: @@
 With similar dwell times in stations the capacity of rail systems would scale with the length of the train. For instance, a light rail system running on two-minute headways with 200-passenger cars operating as single units could carry 6,000 passengers per hour. It should theoretically therefore carry 12,000 passengers per hour with two-car trains, and 24,000 per hour with four-car trains. In practice real world delays multiply and headways become disrupted causing a practical limitation of around 12 to 19,000<ref> [GARDNER G, RUTTER JC and F KUHN, The performance and potential of light rail transit in developing cities. TRI, Project Report No. PR69, Transport Research Laboratory, Crowthorne, UK 1994] </ref>
-==BRT's futuristic system in India ==
+== Effects and Comparison with LRT ==
-BRT in new concept is working like LRT too as there were such types of Buses were under development with Multimodal Transit system is best alternative and which may be one leap ahead version with more flexibility and there is no need to interchange by commuters but whole vehicle interchanges its travelling mode which is never ever introduced any wherer in the world which is going to develop in INDIA by Innovative Transport and Vehicle Development[http://www.geocities.com/solartransit/index.html][www.geocities.com/solartransit/index.html] in SURAT city in Guajrat state.In near future prototype with test and demontration track will be commisioned.
 The best source of information capacity comes from a study that actually stood at the side of the road and counted passengers. As quoted in.<ref>[http://www.nbrti.org/docs/pdf/Characteristics_BRT_Decision-Making.pdf Characteristics of BRT, page ''ES-5'']</ref>  a survey by the UK Transport Research Laboratory revealed:

v t e Bus rapid transit
Standard
Vehicles	Articulated bus Bi-articulated bus Guided Bus Guided Light Transit Trolleybus
Systems (List)	Automatic vehicle location Bus priority Bus lane BRT creep Passenger information system Proof-of-payment
See also	Light rail People mover Premetro Rubber-tyred metro Tram Translohr
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v t e Public transport
Bus service	Bus driver list Bus rapid transit Charabanc Circle route Cross-city route Express bus Guided bus Intercity bus driver Marshrutka Open top bus Pesero Public light bus Rail replacement bus Share taxi/Taxibus Shuttle bus Transit bus Trolleybus
Rail	Passenger rail terminology glossary Airport rail link Cable car Commuter rail Circle route Cross-city route Elevated railway Funicular Heavy rail Heritage railway Heritage streetcar High-speed rail Higher-speed rail Horsecar Inter-city rail Interurban Light rail Maglev Medium-capacity rail system Monorail Narrow-gauge railway People mover Platform screen doors Railbus Metro/Rapid Transit Rubber-tyred metro Regional rail Street running Suspension railway Tram Tram-train
Vehicles for hire	Auto rickshaw taxi Boda boda Combination bus Cycle rickshaw Demand-responsive transport Microtransit Paratransit Dollar van Dolmuş Gondola Hackney carriage Jeepney Limousine Motorcycle taxi Marshrutka Nanny van Personal rapid transit Pesero Public light bus Pulled rickshaw Share taxi Songthaew Taxi Tuk tuk
Carpooling	Car jockey Flexible carpooling Real-time ridesharing Slugging Vanpool
Ship	Cable ferry Ferry Hovercraft Hydrofoil Ocean liner Vaporetto Water taxi
Cable	Aerial tramway Cable ferry Cable railway Elevator Funicular Gondola lift bicable tricable Inclined elevator
Building transport	Elevator Escalator Moving walkway Inclined elevator
Other transport	Airline Airliner Carsharing Bicycle-sharing Scooter-sharing Elevator Escalator Horse-drawn vehicle Hyperloop Inclined elevator Moving walkway Personal transporter Robotaxi Shweeb Slope car Trackless train Vactrain
Locations	Airport Bus bulb Bus garage Bus lane Bus stand Bus station Bus stop Bus turnout (bus bay) Dry dock Ferry terminal Hangar Harbor Interchange station Kassel kerb Layover Metro station Park and ride Port Queue jump Taxicab stand Train station Tram stop Transit mall Transport hub
Ticketing and fares	Automated fare collection Bus advertising Contract of carriage Dead mileage Exit fare Fare avoidance Fare capping Fare evasion Farebox recovery ratio Free public transport Free travel pass Integrated ticketing Manual fare collection Money train Paid area Penalty fare Proof-of-payment Reduced fare program Smart cards (CIPURSE, Calypso) Ticket machine Transfer Transit pass
Routing	Circle route Cross-city route Network length Non-revenue track Radial route Transport network
Facilities	Checked baggage First class Sleeper Standing passenger Travel class
Scheduling	Bus bunching Clock-face scheduling Headway Night (owl) service On-time performance Public transport timetable Short turn
Politics	Airport security Complete streets Green transport hierarchy Rail subsidies Security Street hierarchy Transit district Transit police Transit-oriented development (TOD) Transportation authority Transportation demand management Transportation planning
Technology and signage	Destination sign Passenger information system Platform display Timetable
Other topics	Boarding Bus rapid transit creep Crush load Destination sign Dwell time Hail and ride Land transport Outline of transport Passenger load factor Public good Request stop Service Sustainable transport Timing point Transit map Transport economics Micromobility
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