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'''By Mark Kinnucan'''
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'''Bus rapid transit''' ('''BRT''') is a term applied to a variety of [[public transport]] systems using [[bus]]es to provide faster, more efficient service than an ordinary bus line. Often this is achieved by making improvements to existing infrastructure, vehicles and scheduling. The goal of these systems is to approach the service quality of [[rail transit]] while still enjoying the cost savings and flexibility of bus transit.<ref name="BRT Defined">[http://www.mta.info/mta/planning/sbs/whatis.htm What is Bus Rapid Transit?] Select Bus Service website, NY Metropolitan Transit Authority. Retrieved 2010-3-12</ref> The expression '''BRT''' is mainly used in the Americas; in India, it is called '''BRTS''' (the additional 'S' stands for system); in Europe and Australia, it is often called a '''busway''', while elsewhere, it may be called a '''quality bus.''' Although [[Indonesia]]'s bus system was not the first version of BRT, it has the longest routes as of 2012 with more than {{convert|200|km}} overall, including {{convert|170|km}} in the capital city of [[Jakarta]], and it has been implemented at least in six Indonesian cities.
   
:Several years ago I went to Ottawa, [[Canada]], to attend a conference. I decided to take [[public transportation]] from the airport downtown. The available public transportation turned out to be a bus. However, much to my surprise and delight, the bus did not head out onto the highway for the trip into town. Instead, it maneuvered onto a kind of roadway I had never seen before. It was a dedicated road just for buses. The stops along it looked like the stops for commuter rail systems. In fact the whole set-up looked just like a light rail system, except that what was running on it wasn’t trains, but buses. On rubber tires.The best part was when my bus got downtown. Since it was, after all, a regular city bus, it just drove off the dedicated road (which, I learned, the Ottawans called a “transitway”) onto the downtown city streets. The whole thing, I decided, was the neatest thing since sliced bread.
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== Etymology ==
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'''Bus rapid transit''' takes part of its name from rail [[rapid transit]], which describes a high-capacity urban public-transit system with its own [[Right-of-way (transportation)|right-of-way]], multiple-car trains at short [[headway]]s, and longer stop spacing than traditional streetcars and buses. '''BRT''', however, uses buses on a wide variety of rights-of-way, including mixed traffic, dedicated lanes on surface streets, and busways completely separated from traffic.
   
:What I had stumbled onto in Ottawa is one of North America’s premier examples of a relatively new concept in urban transportation, called bus rapid transit (BRT). The basic idea of BRT is to combine the speed and convenience of rail transit with the flexibility, range, and lower [[cost]] of buses. Even more than the speed and convenience, BRT systems strive to capture the “feel” of rail. Some of this is accomplished through the way BRT systems are designed, and some of it is accomplished through the way they are marketed.
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Typical transit speeds of BRT systems range from {{convert|17|to|30|mph}}, which can compare with surface running [[light rail]].<ref name="nbrti.org">[http://www.nbrti.org/docs/pdf/Characteristics_BRT_Decision-Making.pdf Characteristics of BRT for decision making.] page ES-5. Federal Transit Administration (August 2004).</ref>
   
:The fundamental idea of BRT is to replicate rail’s greater travel speeds and greater spacing of stations. (Notice that they’re “stations,” not “stops.” That’s part of the marketing: this is a transit system, not a bus route.) Greater running speeds are most easily accomplished through dedicated roadways, as in Ottawa. On regular roads, running speed is increased through preemption of traffic lights. Other common features of BRT include distinctive vehicles, advance collection of fares (no lines at the farebox), and attractive stations with level boarding.
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==History==
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{{expand section|date=July 2011}}
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The first BRT system in the world was the [[Rede Integrada de Transporte]] (RIT, translated as "Integrated Transportation Network"), implemented in [[Curitiba]], [[Brazil]] in 1974.<ref>{{cite web|url=http://www.itdp.org/documents/20110526ITDP_USBRT_Report-HR.pdf|title=Recapturing Global Leadership in Bus Rapid Transit - A Survey of Select U.S. Cities|publisher=[[Institute for Transportation and Development Policy]]|date=May 2011|accessdate=2011-06-07}} pp. 5</ref><ref name=Cervero>{{Citation | last = Cervero | first = Robert | year = 1998 | title = The Transit Metropolis| pages = 265–296 | publisher = Island Press, Washington, D.C. | id = ISBN 1-55963-591-6 Chapter 10/Creating a Linear City with a Surface Metro: Curitiba Brazil}}</ref>
   
:The [[New York]] area’s latest contribution to BRT is [[New York City]]’s Bx12 “Select Bus Service” line, which is slated to begin running between northern Manhattan and the Bronx in June. Long Island’s lower population density makes BRT more of a challenge here. Nonetheless, projects have been proposed in both Nassau and Suffolk. In Nassau, a BRT line was proposed in the Nassau Hub Major Investment Study, completed in 2006. The next phase of the Nassau Hub project, carrying out environmental impact studies, is scheduled to begin later this year. No concrete progress has been made to date in Suffolk, but the idea of a BRT line along the Route 110 corridor was presented at last October’s Long Island Mayors'and Supervisors' Institute on Community Design.
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==Main features==
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[[File:JakartaTransjakartaBusspurInDerJalanSudirman.jpg|thumb|Separated lane for [[TransJakarta]] buses in [[Jakarta]], Indonesia]]
   
:[[Long Island]] needs innovative transportation alternatives.With its tremendous flexibility,BRT merits serious consideration in transportation planning for the Island.
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BRT systems come in a variety of forms, such as dedicated ''busways'' with their own rights-of-way (such as [[Ottawa]]'s [[Ottawa Transitway|Transitway]] or [[Pittsburgh]]'s [[Martin Luther King Jr. East Busway]]), bus services using ''[[High-occupancy vehicle lane|HOV]] lanes'', dedicated ''[[freeway]] lanes'' (such as [[Honolulu]]'s CityExpress) and [[limited stop]] buses on pre-existing routes.
   
(Entree to information on the Web about BRT can be found at http://www.tstc.org/issues/brt.html and at http://www.calstart.org/programs/brt/new/index.php?p=programs)
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An ideal bus rapid transit service would be expected to include most of the following features:
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* '''Bus only, grade-separated (or at-grade exclusive) right-of-way''': A dedicated [[bus lane]] allows the bus to operate separately, without interference from other modes of traffic. Although buses have a long turning radius, dedicated busways can be engineered to tighter standards than an open roadway, reducing construction costs while still assuring safe operation.
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** A bus-only right-of-way may be elevated, depressed, or routed through a tunnel. An abandoned rail right-of-way is sometimes used.
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** A [[transit mall]] or ''bus street'' can be created in city centers by dedicating all lanes of a city street to the exclusive use of buses.
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** Low-cost infrastructure elements that can increase the speed and reliability of bus service in lanes shared with general traffic include [[Bus bulb]]s, boarding islands, and curb realignments.
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It must be noted that the public will not regard the bus line as "rapid transit" unless the majority of the route is on a right of way that is rarely congested due to the volume of general traffic sharing the right of way.
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* '''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 large numbers of people between locations quickly and reliably throughout the day, while maintaining a comfortable riding experience.<ref name="BRT Defined" /> These characteristics are essential to satisfying the demands of a diverse market or offering high-frequency service without heavy subsidy.
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[[File:Quito Trole 06 2011 1933.jpg|thumb|The [[Trolleybuses in Quito|Quito trolleybus system]] has lines running on exclusive BRT lanes with underpass crossings.]]
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* '''[[Bus priority]]''': Preferential treatment of buses at signalized intersections can involve the extension of green time and/or allowing the bus to proceed sooner, out of turn, relative to the normal sequence of signal phases. Intersection priority is most effective when implemented in conjunction with ''bus lanes'' or ''bus streets'', since general traffic served by a different traffic signal phase can hold up buses in the same lane.
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* '''Vehicles with tram-like characteristics''': Recent technological developments such as [[bi-articulated bus]]es and [[guided bus]]es have benefited the set-up of BRT systems. The main developments are:
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** Improved riding quality (Use of [[guided bus]] and [[Powertrain Control Module|powertrain control]] technologies for smoother operation),
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** Increased capacity ([[Articulated bus|articulated]] and [[double-decker bus|double-decker]]),
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** Reduced operating costs ([[hybrid electric]] powertrain).
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* '''A specific image with a brand name''': (e.g. ''Viva, Max, TransMilenio, Metropolitano, Select'') marking stops and stations as well as the buses.<ref>[http://www.mta.info/mta/planning/sbs/faqs.htm What is Select Bus Service?] NYC Metropolitan Transit Authority. Retrieved 2010-3-12</ref> The system's brand identity contributes to its attractiveness as an alternative to driving cars.<ref>[http://www.nbrti.org/docs/pdf/Characteristics_BRT_Decision-Making.pdf Characteristics of BRT for decision making.] page ES-8. Federal Transit Administration (August 2004).</ref>
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* '''Off-bus fare collection''': Conventional [[on-board fare collection]] slows the boarding process, particularly when different fares are collected for different destinations and/or classes of passengers. Some BRT systems collect fares upon entering an enclosed [[bus station]] or shelter area prior to bus arrivals (similar to fare collection at a kiosk prior to entering a subway system). This allows passengers to board quickly through all doors of a stopped bus.
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*'''Level boarding''': Many BRT systems also use [[low-floor bus]]es (or higher boarding platforms level with the floor of buses without low floors) to speed passenger boardings and enhance accessibility to disabled passengers.
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[[File:BusesDelhiDTC.jpg|thumb|[[Delhi]] BRTS]]
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*'''Stations''': High-quality BRT systems feature significant investment in enclosed stations which may incorporate attractive sliding glass doors, staffed ticket booths, information booths, and other more standard features listed above. This style of station is seen throughout Colombia, in ([[Bogotá]]'s [[TransMilenio]], [[Cali]]'s [[Masivo Integrado de Occidente|MIO]], Bucaramanga's [[Metrolinea]], Pereira's [[Megabús]]) and in most other Latin American BRT systems developed in the last decade.{{when|date=July 2011}} This design is also used in [[Johannesburg|Johannesburg's]] [[Rea Vaya]].<ref>[http://www.reavaya.org.za/ Rea Vaya]</ref> The term "station" is more flexibly applied in North America and ranges from enclosed waiting areas ([[Ottawa]] and [[Cleveland]]), to large open-sided shelters ([[Los Angeles]]), to simple signposts.
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All of the above characteristics were noted as features of Bogotá's [[TransMilenio]], described as a "model BRT system" in the National Bus Rapid Transit Institute's May 2006 report. TransMilenio serves Bogotá with high-capacity [[articulated]] buses, which passengers can board through three doors. [[Bi-articulated bus]]es are also now used on the busiest routes. A [[smart card]] system is used for off-board fare collection. Nevertheless, despite moving 45,000 ppdph, Transmilenio faces huge problems (especially during peak hours), in terms of not being quite organized, nor having the necessary capacity for handling the high passenger volume, a situation not being limited to peak hours only, but at most times along the day.<ref name="NBRTI report">[http://www.nbrti.org/docs/pdf/Bogota%20Report_Final%20Report_May%202006.pdf "Applicability of Bogotá's TransMilenio BRT System to the United States"] NBRTI (May 2006). Retrieved 2010-03-15.</ref>
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In some cities and large towns, such as [[Amsterdam]], [[Essen]] (Germany), [[Pittsburgh]], and [[Seattle]], it is common for a right of way exclusive to public transport to be shared by both light rail and buses, and in some cases taxis.
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==Comparison with other forms of mass transit==
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BRT attempts to combine the advantages of a rail system (notably a partially or completely dedicated right-of-way, which greatly improves punctuality and reliability) with the advantages of a bus system (low construction and way maintenance costs, low vehicle costs, right-of-way not required for entire length, and the ability of feeder bus services to join a trunk busway). In Latin America and cities in Asia, the BRT service is usually compared to metro-quality rail, and normally results in consistently similar enclosed stations featuring smartcard turnstiles and level-platform boarding. In North America, the BRT is usually compared to LRT-quality rail, and typically results in open-air shelters with ticket-dispenser machines, or even just curbside signposts difficult to distinguish from other roadside visual clutter.
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===Comparison with conventional bus routes===
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When available, the dedicated right-of-way lanes of BRT systems allow them an increased average vehicle speed bypassing traffic congestion, to provide more passenger miles with the same number of vehicles and personnel than conventional bus services. A smoother ride can also be expected, because the BRT is not immersed in stop-and-go traffic. BRT services usually feature higher frequency service than conventional routes; Latin American systems rely heavily on short headways to achieve their ridership capacity.
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But when compared to normal bus service in mixed traffic, addition of BRT dedicated lanes requires wider roads or reduction of mixed traffic lanes.
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=== Comparison with light rail ===
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Primary considerations in choosing between light rail and bus rapid transit systems are the differences in construction costs, operating costs, capacity, adaptability and image.
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Proponents of light rail point out that the operating costs of BRT are not necessarily lower than light rail. The typically larger light rail vehicles enjoy reduced labor costs per passenger, and the unit capital cost per passenger can be lower than a BRT system.<ref>[http://www.lightrailnow.org/facts/fa_brt007.htm Bus Rapid Transit or Quality Bus Reality Check] Light Rail Now! (January 22, 2004). Retrieved 2010-03-29</ref>
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In contrast to BRT, light rail and [[tram]] systems require the placement of rails for the entire line. The tram usually avoids the high additional costs for engineering structures, such as tunnels, that need to be built for metro rail systems. Properly maintained rail tends to provide a smoother ride, making it more attractive to riders than road-based systems.
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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 (pph). Theoretically, this same system should carry 12,000 pph with two-car trains, and 24,000 pph with four-car trains. In practice, real-world delays and headway disruptions cause a practical limitation of around 12,000 to 19,000 pph for light rail systems.<ref>G. Gardner, J. C. Rutter and F. Kuhn (1994). ''The performance and potential of light rail transit in developing cities.'' Project Report No. PR69. Transport Research Laboratory, Crowthorne, UK.</ref>
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A survey by the UK Transport Research Laboratory reported the following peak passenger flows (passengers per hour) for BRT transitways. These were based on actual verifiable counts in real world conditions:<ref>[http://www.nbrti.org/docs/pdf/Characteristics_BRT_Decision-Making.pdf Characteristics of BRT for decision making.] Exhibit 3-22: "Maximum observed peak hour bus flows, capacities, and passenger flows at peak load points on transitways". Federal Transit Administration (August 2004).</ref>
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* Designated Lane: [[Ankara]], [[Istanbul]], [[Abidjan]] 7,300 – 19,500
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* Designated Lanes with Feeders [[Curitiba]], [[Brazil]] 13,900 – 24,100
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* Designated Lanes with Bus Ordering (Travelling in Clusters) [[Porto Alegre]] 17,500 – 18,300
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* Designated Lanes with Overlapping Routes, Passing at Stations and Express Routes [[Belo Horizonte]], [[São Paulo]] 15,800 - 20,300
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* [[TransMilenio]], [[Bogotá]] 35,000 - 40,000<ref>[http://camara.ccb.org.co/documentos/1935_Foro_TransMilenio_Fase_III_-TM_SA.pdf Foro TransMilenio Fase III]</ref>
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Many BRT systems, such as Ottawa's [[Ottawa Transitway|OC Transpo]] and Brisbane's [[South-East Busway, Brisbane|South-East Busway]], 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's passenger capacity is limited by vehicle capacity multiplied by 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. In the NBRTI's May 2006 report, average headways of 13 seconds at busy intersections were observed in the TransMilenio BRT system.<ref name="NBRTI report" />
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At the high end of capacity, the XBL, or [[bus lane|express bus lane]], at [[New Jersey Route 495]] and the [[Lincoln Tunnel]] between [[New Jersey]] and [[New York City]] carries 62,000 pph in the 4-hour morning peak, more than any light rail line.<ref>{{cite web|url=http://www.apta.com/resources/reportsandpublications/Documents/APTABrochure_v28%20FINAL.pdf |title=Public Transportation: Moving America Forward |author=[[American Public Transit Association]] (APTA) |publisher=APTA |date= |accessdate=2012-04-26}} ''See p. 6''</ref> However, this lane serves no intermediate stops, and normally runs without any interruption in flow. Furthermore, a very large multi-story [[Port Authority Bus Terminal]] is required to accept and dispatch passengers in hundreds of buses. Intermediate stops increase the headway, and limit a BRT lane to about 10,000 pph, even with passing lanes in the stations. This is still five times the number carried in the automobiles of a congested freeway lane. At its busiest point, Brisbane's South-East Busway currently has the capacity for in excess of 15,000 pph per direction.<ref>[http://www.brisbane.qld.gov.au/BCC:BASE::pc=PC_2698 Lord Mayor's Mass Transit Taskforce Report 2007], Brisbane City Council.</ref>
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Many agencies make a clear distinction between a pure BRT, which operates in exclusive lanes, and a more compromised form in mixed traffic. For example, the [[LACMTA Orange Line|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 an integral part of its rail transit system, distinct from its "[[Metro Rapid|Rapid]]" lines, which run in mixed traffic.
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== Cost ==
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The capital costs of implementing BRT lines can be lower than up-front costs of constructing LRT lines. A study by the United States [[Government Accountability Office]] found that the average capital cost per mile for busways was $13.5 million while light rail average costs were $34.8 million.<ref>{{cite web|url=http://www.gao.gov/new.items/d01984.pdf|title=Bus Rapid Transit Shows Promise|author=GAO|date=September 2001|publisher=GAO|accessdate=2011-03-16}}</ref> However, a huge range of capital costs can be seen, as BRT lines can cost anywhere from $200,000—$55 million per mile, while LRT lines can range from $12.4—$118.8 million per mile.{{Citation needed|date=August 2010}} The total investment varies considerably due to factors such as cost of the roadway, station structures, park-and-ride facilities, traffic signal systems and vehicles.
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The costs of a running a BRT system is about $13.49 a mile and the total cost for a year of expenditure is $987.80 according to a study done by the GAO. Running a BRT system is much less expensive than running a light rail system. The BRT is also much less expensive than a trolley system.<ref>{{cite web|url=http://www.gao.gov/new.items/d01984.pdf|title=Bus Rapid Transit Shows Promise|author=GAO|date=September 2001|publisher=GAO|accessdate=2012-04-29}}</ref>
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==Environmental problems==
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[[File:Mettis_BRT_Metz.jpg|thumb|The bi-articulated BRT of [[Metz]] uses a diesel-electric hybrid driving system, developed by Belgian [[Van Hool]] manufacturer.<ref>{{cite web|url=http://www.vanhool.be/ENG/highlights/vanhoolpresentst.html|title=Van Hool presents the ExquiCity Design Mettis.|date= |accessdate=5 June 2012 }}</ref>]]
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The typical diesel engine on the bus causes noticeable levels of [[air pollution]], [[noise]] and vibration. With [[hybrid vehicles]] and the new forms of [[trolleybus]], BRT designers hope to increase ride quality and decrease pollution. Since the energy used for acceleration is proportional to the vehicle mass, electric traction allows lighter vehicles, faster acceleration, and ability to feed energy back into [[battery (electricity)|batteries]] or the power grid through [[regenerative brakes]]. Regenerative braking has also become standard on many modern rail systems.
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A BRT system can use trolleybuses to lower gaseous and noise emissions. The price penalty of installing [[overhead lines]] could be offset by the system's environmental benefits potential for savings from centrally generated electricity, especially in cities where electricity is less expensive than other power sources. In addition, most trolleybus applications can be converted to light rail with the only extra expense being the laying and maintenance of tram tracks in the street.
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===In tunnels or tunnel systems===
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[[Image:Seattle Metro Bus Tunnel Pioneer Square Station.jpg|thumb|right|[[Metro Bus Tunnel]] in [[Seattle]], [[Washington (U.S. state)|Washington]].]]
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A special issue arises in the use of bus vehicles in [[rapid transit|metro transit]] structures. Since the areas where the demand for an exclusive bus right-of-way are 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.
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Since buses are usually powered by [[internal combustion engine]]s, bus metros raise ventilation issues similar to those of [[tunnel]]s. 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.
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A straightforward way to deal with this is to use [[internal combustion engine]]s with lower emissions. The 2008 Euro V [[European emission standards]] set a limit on [[carbon monoxide]] from heavy-duty [[diesel engine]]s of 1.5 g/kWh. This is one third that of the 1992 Euro I standard. As a result, less forced ventilation will be required in tunnels to achieve the same air quality.
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A more complex alternative is electrical propulsion in tunnels. [[Seattle]] in its [[Metro Bus Tunnel (Seattle)|Metro Bus Tunnel]], and [[Boston]] in Phase II of its [[Silver Line (MBTA)|Silver Line]] are using this method in their BRTs. In the case of Seattle, [[Dual-mode bus|dual-mode]] (''electric/diesel electric'') buses manufactured by Breda were used until 2004, with the center axle driven by [[electric motor]]s obtaining power from a [[Overhead lines|trolley wire]] through a [[trolley pole]] in the subway, and with the rear axle driven by a conventional [[Diesel engine|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 car]]s 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.<ref>{{cite web|url=http://metro.kingcounty.gov/am/vehicles/bustech.html|title=Downtown Seattle Transit Tunnel and Changing Bus Technology|author=Metro Online|date=December 14, 2007|publisher=King County Metro|accessdate=2010-07-13}}</ref><ref>{{cite web|url=http://world.nycsubway.org/us/boston/silver.html|title=MBTA Silver Line|author=Duncan Allen|year=2005|publisher=www.nycsubway.org|accessdate=2010-07-13}}</ref>
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The need to provide electric power in these underground environments brings the capital and maintenance costs of such routes closer to those of light rail, and raises the question of building light rail instead. In Seattle, the downtown transit tunnel was retrofitted for conversion to a shared hybrid-bus and light-rail facility in preparation for Seattle's Central [[Link Light Rail]] line, which opened in July 2009.
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== Think Tanks and Blogs ==
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In the USA there are at least three think-tanks directly involved in lobbying for BRT systems:
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* [[National Bus Rapid Transit Institute]] (NBRTI) — established by the US Federal Government in January 1991, and housed at the [[Center for Urban Transportation Research]] (CUTR) at the [[University of South Florida]]
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* [[Bus Rapid Transit Policy Center]] (BRTPC) — promotes BRT technology over light rail
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* [[Institute for Transportation and Development Policy]] (ITDP) — a non-governmental organization focussed on sustainable transport including promoting BRT systems in developing countries
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The objectivity of the work of CUTR and at least one of its employees has been questioned.<ref>{{cite news |author=Michael Van Sickler|publisher=St. Petersburg Times|location=Florida| date=November 28, 2009|title=One of rail's biggest critics gets millions to study and promote alternatives|url=http://www.tampabay.com/news/one-of-rails-biggest-critics-gets-millions-to-study-and-promote/1054927|accessdate=2010-03-10}}.</ref>
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[[EMBARQ - The WRI Center for Sustainable Transport|EMBARQ]], The [[World Resources Institute]]'s Center for Sustainable Transport supports the development of BRT and often posts news related to BRT on the [http://thecityfix.com TheCityFix blog network].
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The [[Streetsblog]] series of blogs and [[Streetfilms]] videoblog also are frequent proponents of BRT.
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===Bus Rapid Transit Planning Guide===
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In June 2007, the [[Institute for Transportation and Development Policy|Institute for Transportation and Development Policy (ITDP)]] published the ''BRT Planning Guide'' with support from the [[United Nations Environment Programme]], the [[Deutsche Gesellschaft für Internationale Zusammenarbeit]], the [[Hewlett Foundation]], and Viva Cities. The guide draws from the extensive BRT design experience of [[Latin America]]n [[public transport planning|transit planners]], and aims to disseminate this information in cities looking to design and implement BRT systems of their own.<ref>[http://www.itdp.org/index.php/news_events/news_detail/brt_guide/ "Planning Guide for Bus Rapid Transit Published"]. Institution for Transportation & Development Policy (June 16, 2007).</ref> The guide is currently available in English, Spanish, Portuguese, and Chinese, and is free for download in [[.pdf]] format from [[Institute for Transportation and Development Policy|ITDP's]] website.<ref>[http://www.itdp.org/documents/Bus%20Rapid%20Transit%20Guide%20-%20complete%20guide.pdf Complete BRT Planning Guide (English)] ITDP (June 2007).</ref>
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===Characteristics of Bus Rapid Transit===
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In the U.S.A., a report [http://www.nbrti.org/CBRT.html “Characteristics of Bus Rapid Transit for Decision-Making” (CBRT)] was prepared by the [http://www.nbrti.org National Bus Rapid Transit Institute] located at the [http://www.cutr.usf.edu Center for Urban Transportation Research]. It provides transportation planners and decision-makers with basic information and data to support the development and evaluation of bus rapid transit (BRT) concepts. This report describes the physical, operational, cost, performance and potential benefits of BRT's.
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==List of systems==
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{{Main|List of bus rapid transit systems}}
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==Implementation by country==
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{{Main|Implementation of bus rapid transit by country}}
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== See also ==
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{{Portal|Sustainable development|Buses}}
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{{multicol}}
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* [[Busways in Brisbane]]
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* [[Bus rapid transit in New Jersey]]
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* [[Express bus service]]
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* [[Guided busway]]
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* [[Quality Bus Corridor]]
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* [[Queue jump]]
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{{multicol-break}}
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* [[Straddling bus]]
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* [[Sustainable transportation]]
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* [[Transit bus]]
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* [[Traffic engineering (transportation)]]
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==References==
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{{Reflist|30em}}
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==External links==
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{{Commons category}}
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* [http://www.nbrti.org/ The National BRT Institute]
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* [http://www.its.umn.edu/Research/ProjectDetail.html?id=2001046 BRT Technologies: Assisting Drivers Operating Buses on Road Shoulders]. University of Minnesota Center for Transportation Studies, Department of Mechanical Engineering
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* [http://www.gobrt.org Bus Rapid Transit Policy Center]
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* [http://brtdata.org Global BRT Data] Database of Bus Rapid Transit systems around the world
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* [http://www.itdp.org/index.php/microsite/brt_planning_guide/ Bus Rapid Transit Planning Guide] (available for download in pdf) Institute for Transportation & Development Policy
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* [http://www.itdp.org/documents/BRT_English_REVISED2_FINAL_LR.pdf The BRT Standard 1.0] [[Institute for Transportation and Development Policy]] (2012)
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* [http://www.brt.cl Across Latitudes and Cultures Bus Rapid Transit] An international Centre of Excellence for BRT development
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* [http://www.gao.gov/new.items/d01984.pdf "Bus Rapid Transit Shows Promise"] U.S. General Accounting Office
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* {{cite web|url=http://www.motorworld.com.cn/buses/brt/pdf/China-en.pdf|title=BRT in China|author=Wang Fengwu and James Wang|publisher=Public Transport International|date=April 2004|accessdate=2010-03-10}}
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* [http://www.trb.org/news/blurb_detail.asp?ID=1698 ''Bus Rapid Transit, Volume 1: Case Studies in Bus Rapid Transit''] Transportation Research Board
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* [http://trb.org/news/blurb_detail.asp?id=2264 ''Bus Rapid Transit, Volume 2: Implementation Guidelines''] Transportation Research Board
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* [http://www.trb.org/news/blurb_detail.asp?id=2326 ''Transit Capacity and Quality of Service Manual''] Transportation Research Board
  +
*{{cite journal | last = Levinson | first = Herbert S. | coauthors = | title = Bus Rapid Transit: An Overview | journal =Journal of Public Transportation | volume = 5 | issue = 2 | publisher = | location = | year = 2002 | url = http://www.nctr.usf.edu/jpt/pdf/JPT%205-21%20Levinson.pdf}}
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*{{cite web | title = Ask the Experts – Developing a BRT Project | publisher = Cambridge Systematics | date = | url = http://www.camsys.com/kb_experts_brt.htm}}
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*{{cite web | title = Characteristics of Bus Rapid Transit | work = | publisher = National Bus Rapid Transit Association | year = 2009 | url = http://www.nbrti.org/CBRT.html}}
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*{{cite paper | last = Vincent | first = William | coauthors = Lisa Callaghan Jerram | title =Bus Rapid Transit and Transit Oriented Development: Case Studies on Transit Oriented Development Around Bus Rapid Transit Systems in North America and Australia | publisher = Breakthrough Technologies Institute | location = Washington, DC | date = April 2008 | url = http://www.crcog.org/publications/TransportationDocs/NBHBusway/2010/BRT-TOD-Report.pdf}}
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;Country specific
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* [http://www.dimts.in/more_aboutbrt.html Delhi BRT System] Delhi Transit.
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* [http://citytransport.info/OBahn.htm Bus Priority Systems], a web page about the guided busway system, including its use underground in Essen, Germany.
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* [http://www.itdp.org/documents/20110526ITDP_USBRT_Report-HR.pdf Recapturing Global Leadership in Bus Rapid Transit - A Survey of Select U.S. Cities] (available for download in pdf) Institute for Transportation & Development Policy (May 2011)
 
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{{Carpool}}
 
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Revision as of 20:33, January 14, 2013

Bus rapid transit (BRT) is a term applied to a variety of public transport systems using buses to provide faster, more efficient service than an ordinary bus line. Often this is achieved by making improvements to existing infrastructure, vehicles and scheduling. The goal of these systems is to approach the service quality of rail transit while still enjoying the cost savings and flexibility of bus transit.[1] The expression BRT is mainly used in the Americas; in India, it is called BRTS (the additional 'S' stands for system); in Europe and Australia, it is often called a busway, while elsewhere, it may be called a quality bus. Although Indonesia's bus system was not the first version of BRT, it has the longest routes as of 2012 with more than 200 kilometres (120 mi) overall, including 170 kilometres (110 mi) in the capital city of Jakarta, and it has been implemented at least in six Indonesian cities.

Etymology

Bus rapid transit takes part of its name from rail rapid transit, which describes a high-capacity urban public-transit system with its own right-of-way, multiple-car trains at short headways, and longer stop spacing than traditional streetcars and buses. BRT, however, uses buses on a wide variety of rights-of-way, including mixed traffic, dedicated lanes on surface streets, and busways completely separated from traffic.

Typical transit speeds of BRT systems range from 17 to 30 miles per hour (27 to 48 km/h), which can compare with surface running light rail.[2]

History

{{#invoke:Message box|ambox}} The first BRT system in the world was the Rede Integrada de Transporte (RIT, translated as "Integrated Transportation Network"), implemented in Curitiba, Brazil in 1974.[3][4]

Main features

File:JakartaTransjakartaBusspurInDerJalanSudirman.jpg
Separated lane for TransJakarta buses in Jakarta, Indonesia

BRT systems come in a variety of forms, such as dedicated busways with their own rights-of-way (such as Ottawa's Transitway or Pittsburgh's Martin Luther King Jr. East Busway), bus services using HOV lanes, dedicated freeway lanes (such as Honolulu's CityExpress) and 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: A dedicated bus lane allows the bus to operate separately, without interference from other modes of traffic. Although buses have a long turning radius, dedicated busways can be engineered to tighter standards than an open roadway, reducing construction costs while still assuring safe operation.
    • A bus-only right-of-way may be elevated, depressed, or routed through a tunnel. An abandoned rail right-of-way is sometimes used.
    • A transit mall or bus street can be created in city centers 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 in lanes shared with general traffic include Bus bulbs, boarding islands, and curb realignments.

It must be noted that the public will not regard the bus line as "rapid transit" unless the majority of the route is on a right of way that is rarely congested due to the volume of general traffic sharing the right of way.

  • 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 large numbers of people between locations quickly and reliably throughout the day, while maintaining a comfortable riding experience.[1] These characteristics are essential to satisfying the demands of a diverse market or offering high-frequency service without heavy subsidy.
File:Quito Trole 06 2011 1933.jpg
The Quito trolleybus system has lines running on exclusive BRT lanes with underpass crossings.
  • Bus priority: Preferential treatment of buses at signalized intersections can involve the extension of green time and/or allowing the bus to proceed sooner, out of turn, relative to the normal sequence of signal phases. Intersection priority is most effective when implemented in conjunction with bus lanes or bus streets, since general traffic served by a different traffic signal phase can hold up buses in the same lane.
  • Vehicles with tram-like characteristics: Recent technological developments such as bi-articulated buses and guided buses have benefited the set-up of BRT systems. The main developments are:
  • A specific image with a brand name: (e.g. Viva, Max, TransMilenio, Metropolitano, Select) marking stops and stations as well as the buses.[5] The system's brand identity contributes to its attractiveness as an alternative to driving cars.[6]
  • Off-bus fare collection: Conventional on-board fare collection slows the boarding process, particularly when different fares are collected for different destinations and/or classes of passengers. Some BRT systems collect fares upon entering an enclosed bus station or shelter area prior to bus arrivals (similar to fare collection at a kiosk prior to entering a subway system). This allows passengers to board quickly through all doors of a stopped bus.
  • Level boarding: Many BRT systems also use low-floor buses (or higher boarding platforms level with the floor of buses without low floors) to speed passenger boardings and enhance accessibility to disabled passengers.
File:BusesDelhiDTC.jpg
Delhi BRTS
  • Stations: High-quality BRT systems feature significant investment in enclosed stations which may incorporate attractive sliding glass doors, staffed ticket booths, information booths, and other more standard features listed above. This style of station is seen throughout Colombia, in (Bogotá's TransMilenio, Cali's MIO, Bucaramanga's Metrolinea, Pereira's Megabús) and in most other Latin American BRT systems developed in the last decade.[when?] This design is also used in Johannesburg's Rea Vaya.[7] The term "station" is more flexibly applied in North America and ranges from enclosed waiting areas (Ottawa and Cleveland), to large open-sided shelters (Los Angeles), to simple signposts.

All of the above characteristics were noted as features of Bogotá's TransMilenio, described as a "model BRT system" in the National Bus Rapid Transit Institute's May 2006 report. TransMilenio serves Bogotá with high-capacity articulated buses, which passengers can board through three doors. Bi-articulated buses are also now used on the busiest routes. A smart card system is used for off-board fare collection. Nevertheless, despite moving 45,000 ppdph, Transmilenio faces huge problems (especially during peak hours), in terms of not being quite organized, nor having the necessary capacity for handling the high passenger volume, a situation not being limited to peak hours only, but at most times along the day.[8]

In some cities and large towns, such as Amsterdam, Essen (Germany), Pittsburgh, and Seattle, it is common for a right of way exclusive to public transport to be shared by both light rail and buses, and in some cases taxis.

Comparison with other forms of mass transit

BRT attempts to combine the advantages of a rail system (notably a partially or completely dedicated right-of-way, which greatly improves punctuality and reliability) with the advantages of a bus system (low construction and way maintenance costs, low vehicle costs, right-of-way not required for entire length, and the ability of feeder bus services to join a trunk busway). In Latin America and cities in Asia, the BRT service is usually compared to metro-quality rail, and normally results in consistently similar enclosed stations featuring smartcard turnstiles and level-platform boarding. In North America, the BRT is usually compared to LRT-quality rail, and typically results in open-air shelters with ticket-dispenser machines, or even just curbside signposts difficult to distinguish from other roadside visual clutter.

Comparison with conventional bus routes

When available, the dedicated right-of-way lanes of BRT systems allow them an increased average vehicle speed bypassing traffic congestion, to provide more passenger miles with the same number of vehicles and personnel than conventional bus services. A smoother ride can also be expected, because the BRT is not immersed in stop-and-go traffic. BRT services usually feature higher frequency service than conventional routes; Latin American systems rely heavily on short headways to achieve their ridership capacity.

But when compared to normal bus service in mixed traffic, addition of BRT dedicated lanes requires wider roads or reduction of mixed traffic lanes.

Comparison with light rail

Primary considerations in choosing between light rail and bus rapid transit systems are the differences in construction costs, operating costs, capacity, adaptability and image.

Proponents of light rail point out that the operating costs of BRT are not necessarily lower than light rail. The typically larger light rail vehicles enjoy reduced labor costs per passenger, and the unit capital cost per passenger can be lower than a BRT system.[9]

In contrast to BRT, light rail and tram systems require the placement of rails for the entire line. The tram usually avoids the high additional costs for engineering structures, such as tunnels, that need to be built for metro rail systems. Properly maintained rail tends to provide a smoother ride, making it more attractive to riders than road-based systems.

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 (pph). Theoretically, this same system should carry 12,000 pph with two-car trains, and 24,000 pph with four-car trains. In practice, real-world delays and headway disruptions cause a practical limitation of around 12,000 to 19,000 pph for light rail systems.[10]

A survey by the UK Transport Research Laboratory reported the following peak passenger flows (passengers per hour) for BRT transitways. These were based on actual verifiable counts in real world conditions:[11]

Many BRT systems, such as Ottawa's OC Transpo and Brisbane's South-East Busway, 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's passenger capacity is limited by vehicle capacity multiplied by 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. In the NBRTI's May 2006 report, average headways of 13 seconds at busy intersections were observed in the TransMilenio BRT system.[8]

At the high end of capacity, the XBL, or express bus lane, at New Jersey Route 495 and the Lincoln Tunnel between New Jersey and New York City carries 62,000 pph in the 4-hour morning peak, more than any light rail line.[13] However, this lane serves no intermediate stops, and normally runs without any interruption in flow. Furthermore, a very large multi-story Port Authority Bus Terminal is required to accept and dispatch passengers in hundreds of buses. Intermediate stops increase the headway, and limit a BRT lane to about 10,000 pph, even with passing lanes in the stations. This is still five times the number carried in the automobiles of a congested freeway lane. At its busiest point, Brisbane's South-East Busway currently has the capacity for in excess of 15,000 pph per direction.[14]

Many agencies make a clear distinction between a pure BRT, which operates 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 an integral part of its rail transit system, distinct from its "Rapid" lines, which run in mixed traffic.

Cost

The capital costs of implementing BRT lines can be lower than up-front costs of constructing LRT lines. A study by the United States Government Accountability Office found that the average capital cost per mile for busways was $13.5 million while light rail average costs were $34.8 million.[15] However, a huge range of capital costs can be seen, as BRT lines can cost anywhere from $200,000—$55 million per mile, while LRT lines can range from $12.4—$118.8 million per mile.[citation needed] The total investment varies considerably due to factors such as cost of the roadway, station structures, park-and-ride facilities, traffic signal systems and vehicles.

The costs of a running a BRT system is about $13.49 a mile and the total cost for a year of expenditure is $987.80 according to a study done by the GAO. Running a BRT system is much less expensive than running a light rail system. The BRT is also much less expensive than a trolley system.[16]

Environmental problems

File:Mettis BRT Metz.jpg
The bi-articulated BRT of Metz uses a diesel-electric hybrid driving system, developed by Belgian Van Hool manufacturer.[17]

The typical diesel engine on the bus causes noticeable levels of air pollution, noise and vibration. With hybrid vehicles and the new forms of trolleybus, BRT designers hope to increase ride quality and decrease pollution. Since the energy used for acceleration is proportional to the vehicle mass, electric traction allows lighter vehicles, faster acceleration, and ability to feed energy back into batteries or the power grid through regenerative brakes. Regenerative braking has also become standard on many modern rail systems.

A BRT system can use trolleybuses to lower gaseous and noise emissions. The price penalty of installing overhead lines could be offset by the system's environmental benefits potential for savings from centrally generated electricity, especially in cities where electricity is less expensive than other power sources. In addition, most trolleybus applications can be converted to light rail with the only extra expense being the laying and maintenance of tram tracks in the street.

In tunnels or tunnel systems

File:Seattle Metro Bus Tunnel Pioneer Square Station.jpg
Metro Bus Tunnel in Seattle, Washington.

A special issue arises in the use of bus vehicles in metro transit structures. Since the areas where the demand for an exclusive bus right-of-way are 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 usually powered 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 internal combustion engines with lower emissions. The 2008 Euro V European emission standards set a limit on carbon monoxide from heavy-duty diesel engines of 1.5 g/kWh. This is one third that of the 1992 Euro I standard. As a result, less forced ventilation will be required in tunnels to achieve the same air quality.

A more complex alternative is electrical propulsion in tunnels. Seattle in its Metro Bus Tunnel, and Boston in Phase II of its Silver Line are using this method in their 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.[18][19]

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

Think Tanks and Blogs

In the USA there are at least three think-tanks directly involved in lobbying for BRT systems:

The objectivity of the work of CUTR and at least one of its employees has been questioned.[20]

EMBARQ, The World Resources Institute's Center for Sustainable Transport supports the development of BRT and often posts news related to BRT on the TheCityFix blog network.

The Streetsblog series of blogs and Streetfilms videoblog also are frequent proponents of BRT.

Bus Rapid Transit Planning Guide

In June 2007, the Institute for Transportation and Development Policy (ITDP) published the BRT Planning Guide with support from the United Nations Environment Programme, the Deutsche Gesellschaft für Internationale Zusammenarbeit, the Hewlett Foundation, and Viva Cities. The guide draws from the extensive BRT design experience of Latin American transit planners, and aims to disseminate this information in cities looking to design and implement BRT systems of their own.[21] The guide is currently available in English, Spanish, Portuguese, and Chinese, and is free for download in .pdf format from ITDP's website.[22]

Characteristics of Bus Rapid Transit

In the U.S.A., a report “Characteristics of Bus Rapid Transit for Decision-Making” (CBRT) was prepared by the National Bus Rapid Transit Institute located at the Center for Urban Transportation Research. It provides transportation planners and decision-makers with basic information and data to support the development and evaluation of bus rapid transit (BRT) concepts. This report describes the physical, operational, cost, performance and potential benefits of BRT's.

List of systems

Implementation by country

See also


References

  1. 1.0 1.1 What is Bus Rapid Transit? Select Bus Service website, NY Metropolitan Transit Authority. Retrieved 2010-3-12
  2. Characteristics of BRT for decision making. page ES-5. Federal Transit Administration (August 2004).
  3. Recapturing Global Leadership in Bus Rapid Transit - A Survey of Select U.S. Cities. Institute for Transportation and Development Policy (May 2011). Retrieved on 2011-06-07. pp. 5
  4. Cervero, Robert (1998), The Transit Metropolis, Island Press, Washington, D.C., pp. 265–296, ISBN 1-55963-591-6 Chapter 10/Creating a Linear City with a Surface Metro: Curitiba Brazil 
  5. What is Select Bus Service? NYC Metropolitan Transit Authority. Retrieved 2010-3-12
  6. Characteristics of BRT for decision making. page ES-8. Federal Transit Administration (August 2004).
  7. Rea Vaya
  8. 8.0 8.1 "Applicability of Bogotá's TransMilenio BRT System to the United States" NBRTI (May 2006). Retrieved 2010-03-15.
  9. Bus Rapid Transit or Quality Bus Reality Check Light Rail Now! (January 22, 2004). Retrieved 2010-03-29
  10. G. Gardner, J. C. Rutter and F. Kuhn (1994). The performance and potential of light rail transit in developing cities. Project Report No. PR69. Transport Research Laboratory, Crowthorne, UK.
  11. Characteristics of BRT for decision making. Exhibit 3-22: "Maximum observed peak hour bus flows, capacities, and passenger flows at peak load points on transitways". Federal Transit Administration (August 2004).
  12. Foro TransMilenio Fase III
  13. American Public Transit Association (APTA). Public Transportation: Moving America Forward. APTA. Retrieved on 2012-04-26. See p. 6
  14. Lord Mayor's Mass Transit Taskforce Report 2007, Brisbane City Council.
  15. GAO (September 2001). Bus Rapid Transit Shows Promise. GAO. Retrieved on 2011-03-16.
  16. GAO (September 2001). Bus Rapid Transit Shows Promise. GAO. Retrieved on 2012-04-29.
  17. Van Hool presents the ExquiCity Design Mettis.. Retrieved on 5 June 2012.
  18. Metro Online (December 14, 2007). Downtown Seattle Transit Tunnel and Changing Bus Technology. King County Metro. Retrieved on 2010-07-13.
  19. Duncan Allen (2005). MBTA Silver Line. www.nycsubway.org. Retrieved on 2010-07-13.
  20. Michael Van Sickler (November 28, 2009). "One of rail's biggest critics gets millions to study and promote alternatives". Florida: St. Petersburg Times. http://www.tampabay.com/news/one-of-rails-biggest-critics-gets-millions-to-study-and-promote/1054927. Retrieved 2010-03-10. .
  21. "Planning Guide for Bus Rapid Transit Published". Institution for Transportation & Development Policy (June 16, 2007).
  22. Complete BRT Planning Guide (English) ITDP (June 2007).

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