Bus Rapid Transit: Picking Out the Pieces

Bus Rapid Transit: Picking Out the Pieces

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  American Journal ofHumanities and Social Sciences Research (AJHSSR) 2025 A J H S S R J o u r n a l P a g e | 256 American Journal of Humanities and Social Sciences Research (AJHSSR) e-ISSN : 2378-703X Volume-09, Issue-04, pp-256-267 www.ajhssr.com Research Paper Open Access Bus Rapid Transit: Picking Out the Pieces James T. Jarzab (International Development, College of Arts and Sciences, University of Southern Mississippi, USA) ABSTRACT: Various African, Latin American, and other cities have embraced Bus Rapid Transit (BRT) as a key component of their transit operations and infrastructural investments. Conceptually, BRT was operational in several cities during the 1990s, with components deployed by transit operators worldwide. The BRT systems have reduced urban travel times, transport costs and other social and economic aspects of the built urban environment. Despite implementation and operational difficulties BRT expansion is underway in several metropolitan areas in the face of institutional and financial constraints. Rapid urbanization plagues many developing countries, and urban infrastructure expansion generally lags population growth in all but the most developed polities. In general, current resources need to be used more efficiently and effectively. BRT has shown that the service form can successfully improve urban mobility and make inroads toward mitigating congestion as well as, possibly, promoting energy conservation as well as reducing vehicular emissions. The relatively high capital and operating costs of full specification facilities as are heavily promoted by purported BRT standards appear-- in many instances-- unwarranted and capital excessive. An opportunity exists to identify alternative ways of serving the needs of public transit customers. Historically, the burgeoning population in cities created value and spurred economic development with urbanization and economic growth proceeding apace; urbanization in the “Global South” is unfolding differently with populations and the demand for urban services exploding in advance of economic development. Many polities and their urbanized areas can neither raise sufficient domestic revenue nor borrow adequate capital of any source, thus being unable to make the investments needed to respond to inadequate urban infrastructure and services. These metropolitan complexes require cost-effective and efficient commuting opportunities to better serve their constituents. KEYWORDS: Bus, Effectiveness, Infrastructure, Operations, Traffic, Transit, Priority I. INTRODUCTION In retrospect, it is surprising that results of an earlier analysis should have taken so long to be brought to publication. The delay was purely accidental; prepared to accompany a presentation at a major Intelligent Transportation System conference, the initial paper covering bus signal priority (BSP) for rubber-tired vehicles in transit revenue service in “Silicon Valley” never was published as intended. The sponsoring organization for the conference determined that publishing full proceedings was not financially prudent and, as a result, only presentation files were distributed to attendees. The research on bus signal priority remains of interest, as BRT development has proceeded. Though dated, the results continue to be valid. Technology has progressed to the point that, if anything, the actual benefits today compared to those reported earlier are likely to prove functionally superior to the capabilities of the current generation of traffic signal control and vehicle monitoring equipment. Therefore, this document has been prepared taking into consideration some intervening research and addresses other aspects of BRT technology while formally publishing the bus signal priority results. The primary bus signal priority results reported in this paper with respect to mixed-traffic transit operations are over twenty years old. However, Bus Rapid Transit (BRT) has been deployed extensively on a worldwide basis, particularly in the "Global South". With capital still relatively scarce, efficiency and effectiveness of government expenditure are the rules. BRT has fulfilled much of its promise to, in effect, stretch the public sector transportation budget. Early in the progression of economic thought, economists focused on the concept of society benefiting from the cumulative behavior of the market. In other words, the cumulative selfish behavior of individuals would result in the maximization of societal benefits. “Welfarism in this sense therefore requires making a distinction between the information needed to establish the welfare of individuals (which might, of course, depend on the welfare of others if people are altruistic), on which social welfare is assumed to depend, from other information, which should be ignored on the ground that it does not affect any one, or at least does not affect them in any relevant way”[1] . However, it became clear that the market— composed primarily of transactions for private goods— while accounting for most economic activity did not, indeed, could not account for some goods and services as
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  American Journal ofHumanities and Social Sciences Research (AJHSSR) 2025 A J H S S R J o u r n a l P a g e | 257 well as related extra-market issues. Pure public goods have difficulty yielding revenue in a traditional manner for retail and so private markets do not attain generally reach optimality[2] . That said, pure public goods are relatively rarely encountered. Public transit-- at least from the standpoint of most economists without a political agenda-- is not in any sense a pure public good; the public good is generally available to all individuals whether they have paid for it or not, and public transit operations traditionally charge fares. Public transit was initially employed because urban development proved superior for most sectors of economic activity except agriculture, and job creation drew populations to the cities. The overwhelming need proved to be the expansion of the effective size of the urban area. Walking to distant intraurban destinations was difficult and time consuming, other modes of transportation proved uneconomic for the masses, and technological advancements made the economies of scale of public transportation attractive for investors, and public transit utilities resulted. Progressive political policies increasingly called for regulation of utilities, especially as industries that were “natural monopolies” underwent wholesale consolidation[3] . Over time the technologies for private transportation allowed even lower middle-class households to own automobiles, often reducing the attractiveness of urban public transit systems. Declining demand reduced the profitability of privately owned public transit operators facing the contributing factor of inefficient regulatory practices delaying financial relief for struggling operators, and the prospect of public transport service shutdown instigated government involvement in efforts to resuscitate services perceived as lifelines for various segments of the population. There are always members of society that will use a public good and will pay for it but there are also members of society that will use the good though unable or unwilling to help pay for it; these are considered “free riders”. There are others that pay for it but are unwilling or unable to use it. It may be appropriate to consider this last group as customers as well. This final group of customers-- taxpayers and/or those otherwise beyond the reach of the operator-- have quite different expectations for the service, especially with respect to cost-effectiveness and efficiency, than those that regularly commute on public transit. II. Infrastructure: Role of Investment Infrastructure is often defined as something akin to the fundamental physical systems of an organized unit of private or public enterprise; the term is commonly invoked when referring to the production of public goods and quasi-public goods. Investment in infrastructure is often costly and capital-intensive but can be vital to economic development. Projects related to infrastructure improvements may be funded publicly, privately, or through a combination or hybrid construction. These projects may be diverse in nature, as well as vary in scale, but they are commonly heavily publicized by their sponsors and promoted by those benefiting because of the size of investment that is devoted to these projects and the commitment these projects represent[4] . This is true of most infrastructure and not limited to transportation; communication and power transmission networks, sewage and potable water treatment facilities and-- to some extent-- school system components and public investments of similar ilk are typically included. More than half of the world's population now lives in cities. Cities are progenitors of growth and need to be livable and inclusive. Cities attract and foster the further development of businesses while offering the prospect of efficient delivery of acceptable transport, housing, potable water, and sanitation. These businesses generate jobs and often, consequently, tend to provide an improved quality of life for citizens. One of the most interesting aspects of infrastructure is that-- even in developed economies-- the infrastructural project scope is often characterized by numerous small project elements undertaken by qualified contractors for a prescribed price. Historically the public sector is the primary benefactor of highly visible infrastructure[5] , though the actual delivery of infrastructure can involve many resources and multiple providers over an extended period. These tend to use technology commensurate with the contractor’s capabilities, having oversight and coordination handled by project management firms specifically engaged for the task; the results are intended to yield a complete project of value to the sponsor and its clients within the resource limits of the project. Financing infrastructure directly or with one or more public–private partnerships (PPPs) of various types for utilities are generally subject to public oversight (exercised by reviewing appointed or elected authorities)[6] . Infrastructures provide networks both physical and ephemeral and can generate unanticipated outcomes. There are many constituencies that might be adversely affected by infrastructural project implementation along with those that benefit both in the short- and long-term; all must be given due consideration in the planning, programming, implementation and operation processes. For the most part, beneficiaries are predominately in urban areas and enjoy improved access to public services, while those more adversely affected live and work in rural communities[7] . As an example, a rationale for discussing public goods is that one element-- the Global Positioning System (GPS)-- is a significant component of an application potentially beneficial to BRT and a public good.
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  American Journal ofHumanities and Social Sciences Research (AJHSSR) 2025 A J H S S R J o u r n a l P a g e | 258 The GPS project was initiated by the United States in 1973 to overcome the limitations of previous navigation systems. Ironically influenced by a military program known as TRANSIT, since then it has developed into a worldwide radio navigation system with a practical capability of permitting users to locate positions on Earth with an error in accuracy of less than one meter. GPS is freely available for civilian use as a common good and is owned and operated by the United States government, which reserves the right to modify the service or its availability at any time for any reason or no reason at all. Though there is generally a capital cost associated with the acquisition of equipment used to access and process GPS data, this equipment often provides multiple functions to the user. The transmissions from GPS satellites are freely available worldwide; these transmissions cannot generally be received in tunnel sections, though electronic technologies exist that can provide artificial signals in most “broadcast blind” environments. GPS information has allowed the development of low-cost fleet and traffic management tools far beyond mere positional status. Change is continuous. Despite persistent change over time, much of the land form and many of the natural core characteristics and values remain and are expected to appear unaltered. Thus, the contradictions of change and consistency cause some to ponder the value of development even though the historical record is clearly in favor of change. 2.1 Public Transit Most public-- not necessarily in terms of ownership but with respect to intended clientele-- transport systems operate along predetermined routes with set boarding and alighting points corresponding to a prearranged timetable, though these boarding and alighting locations have been established possibly absent physical improvements[8] . The timetable is generally thought of being for the convenience of potential users, but its primary purpose is for the service operator to schedule personnel and equipment. Public transport trips, in general, include the customer partaking in multiple modes of travel like initially accessing or transferring between services on foot with timetables providing information essential for attracting customers; often these transfers result in unappealing travel delays to customers while sometimes inflating operating revenues. Public transit operators tend to focus on several criteria to estimate the usability of different types of public transport and its overall appeal. The criteria applied are speed, comfort, safety, cost, proximity of service to points of travel origin, timeliness and/or frequency of service and point-to-point efficiency. Operating speeds are often predetermined and enforced by labor contracts; bus operations in mixed traffic on arterial streets, for example, travel at speeds about half that of accompanying general traffic flows[9] . Motive power for public transport has varied over time. Waterborne services used wind and biological power sources including human, equine and bovine effort. Electric motors continue to provide power to ferrous-tired vehicles (and some buses) from wayside electrified rails and wired sources. Hydrocarbon fueled engines are currently the primary source of energy for public transit operation, while some fuel cell pilot programs have been implemented and a variety of prototypes using alternative fuels or energy storage have been attempted. Today, many public transit services worldwide are provided by diesel powered motor coaches or buses, with most of these operating on highways in mixed traffic. These vehicles stop at designated service points, usually disgorging and accepting passengers at curbside if operating on highways. Other services include the earliest public transport types, ships and ferries, operating on water courses; in urbanized areas, these vessels dock at dedicated terminals. Though not generally recognized, such ferrous-tired operations-- the hallmark of rail services-- of various types also stop at designated service points, and if electrified and grade-separated most having fully- or partially improved stations that provide level boarding opportunities and limited passenger amenities; many streetcar operations forego level boarding. Electric streetcars-- in fact, most ferrous-tired vehicles-- are often capable of carrying heavier passenger loads than buses, primarily because their passenger cabin is larger; whether these load factors materialize has a great deal to do with market area characteristics, service efficiency and effectiveness and hence the long-term viability of the service. Ferrous-tired vehicles tend to take more time to start and stop than rubber-tired vehicles and are infamous for the devastating effects of their collisions. 2.2 Rapid Transit Rapid Transit is generally understood to provide public transportation at overall speeds faster than available transit alternatives; often, the same can be said of all practical alternatives. It should be noted that, for certain trips in some market areas like lower and midtown Manhattan of New York City, walking may be faster than using rapid transit for travel between origin and destination pairs[10] . Rapid transit systems are often on exclusive rights-of-way that are designated as being or are physically inaccessible to through traffic by pedestrians and/or other vehicles. The designation of a service as rapid transit is neither technology specific nor dependent; however, certain types of rapid transit have elicited archetypal responses from the public and are reflected in the success for attracting capital[11] .
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  American Journal ofHumanities and Social Sciences Research (AJHSSR) 2025 A J H S S R J o u r n a l P a g e | 259 Cost-effective services in one environment may prove prohibitively expensive if deployed in another; there is no technology application that is appropriate under all circumstances, no matter the assurances of industry salespeople. Line haul service provision can benefit from exclusive right of way in one instance but may not subsequently prove either cost-effective or efficient in general. Nostalgia is a poor reason to choose technology. Rapid transit service was established to provide efficient and cost-effective high-capacity public transportation within cities and metropolitan areas, moving large numbers of people quickly over relatively short distances[12] ; rapid transit was particularly attractive to residents and public officials in chronically overcrowded urban areas. Although anachronistic in some respects, rapid transit not only served existing high density urban areas but in some metropolitan areas helped create them. Several urban areas that experienced significant population growth-- and some, decline-- after the Second World War pursued the construction of rapid transit. Technologies initially considered state-of-the-art and developed in the 19th Century continue to enjoy advocates in the Twenty-first, and support industries have thrived accordingly[13] . Innovation in the public transit industry is often vendor drive, perhaps an indication of the inherent conservative nature of management in what might be considered a large “cottage industry”. 2.3.1 Rail Rapid Transit (RRT) Rail rapid transit (RRT) is a type of public transit service that gives the appearance-- or actually is-- operating on connected lengths of iron or steel within an urbanized area that has exclusive right of way below, above, and/or on the surface and so is capable of relatively high average operating speed; the capability is subject to modification based on operational rules. As with most transit, the name may— under certain circumstances-- prove to be a misnomer. For functional reasons, RRT can be distinguished from BRT based on adopted technology, though many similarities exist[14] . For example, in “Silicon Valley” Caltrans sometimes found it expedient to use bus signal priority software subroutines to manage light rail signal priority requests with traffic signals in its jurisdiction. As noted, RRT can have some characteristics like BRT; Paris, Montreal and Mexico City use rubber instead of ferrous tires and vehicle guidance may be provided by adjacent features of the infrastructure. The distinguishing aspect appears to be that vehicles in RRT configuration are limited to the support infrastructure as usually provided by ferrous tires and vehicle guidance trackage as well as the ability to access electric power of appropriate characteristics; BRT vehicles may be operated much like motor coaches outside the environment of the rapid transit facility while RRT vehicles are typically technological captives to the facility. Adopting this definition variant puts all monorails-- including, for example, the types exemplified by the Seattle Monorail and Wuppertaler Schwebebahn-- in the rail category. 2.2.2 Bus Rapid Transit (BRT) Research on BRT as the solution to urban transport problems in developing countries— particularly urban transport problems in the “Global South”-- it is obvious that a well-connected consortium of organizations is pushing an agenda, although unclear for what purpose. The Institute for Transportation & Development Policy {ITDP} has adopted one of the latest standards— that is, one among many proposed for the purpose-- with respect to BRT. The ITDP “standard”[15] is also a definition of what could comprise features of an effective BRT facility, at least as endorsed by an international advisory group. It cannot be claimed that strict adherence to the standard will guarantee a successful transportation facility operation, nor that failure to implement all aspects of the standard will preclude successful transportation facility operation. However, the ITDP standard provides a reasonable starting point for evaluating features of BRT. The BRT Standard has been criticized as a planning tool lacking context sensitivity. There are divided opinions on its use. It may be unfair to criticize the "Standard" out of hand; the document carries no legal standing and is, at best, a guideline with many elements having general applicability. Many professionals have noted that there are a variety of appropriate solutions to upgrade public transit service, and the publication of a "Standard" is no reason to forgo such improvements. The "Standard" may motivate some urban areas to enhance transit within prevailing financial and geo-political conditions. 2.2.3 Fundamentals As noted above, the ITDP "Standard" has much to offer as guidance and should be utilized as a reference tool by practitioners and the public; however, it does not necessarily represent a set of hard and fast rules for BRT facility development. One of the interesting aspects of the ITDP position is that spending more will generate superior benefits. There is a plethora of caveats that comes with that pronouncement; there is a basic assumption in the standard that a project sponsor has more to spend as an option and that such expenditure will result in sufficient benefits to justify the expenditure. In this case the investment capital in the "Global South" is particularly dear, and investment in BRT is still an expenditure of scarce resources and only one of
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  American Journal ofHumanities and Social Sciences Research (AJHSSR) 2025 A J H S S R J o u r n a l P a g e | 260 many competing demands for capital resources. In addition, the "Standard" considers the long-term maintenance costs of capital improvements; life cycle costing-- the procedure of compiling all the expenses the asset will incur over its lifespan-- allows for a better understanding of the cost to operate, and possibly renew, investments made in infrastructure[16] . Treating these components as suggestions is an appropriate approach to urban infrastructure provision in the metropolises of the "Global South"; this position is likely prudent in all applications. If feasible, many of the “Standard’s” features can enhance the customer travel experience, but– if considered-- their provision must be supported by evidence of positive benefit/cost relationships prior their inclusion as a parameter of a BRT facility. Fiscal integrity can be a paramount consideration; sponsors should determine whether a decision is worthwhile by aggregating the potential rewards expected from an installation and deducting the associated costs. Right of way management is very important and redolent with trade-offs. Dedicated bus-only lanes may make for faster travel but cannot ensure that buses are never delayed due to traffic congestion. Enforcement of BRT access exclusivity is expensive and in certain instances may be unavoidable. Technological improvements in traffic signal management can be employed to provide virtual bus lanes for BRT operation where property acquisition is difficult, and options are limited. It is helpful to the public to rely on commonplace traffic control devices and signage to avoid accidental right-of-way violations as well as the confusion resulting from unfamiliar traffic management techniques that lead to traffic congestion. Providing exclusive corridors away from vehicle curb-side parking areas minimizes opportunities to coordinate advanced traffic management techniques and is a somewhat puzzling aspect of the "Standard". Space for passenger facilities are at a premium in most urban areas. BRT alignments that incorporate far-side boarding areas at traffic signals with bus bulges allow space for shelters, in addition to sales machinery for fare instruments as well as passenger information devices. In addition, space needs to be available for transfers among vehicles and ancillary activities like shopping. The service design should be reflected in the station layout, not the reverse. Prohibiting turns for traffic across the bus lane reduces delays caused to buses by turning traffic; prohibiting such turns is a measure for moving buses through intersections although possibly an interruption of general traffic flow. It is important to recognize that mixed traffic operations often suffer when such schemes are implemented. Prohibiting delivery drivers from blocking traffic benefits all vehicles in the traffic platoon. This, of course, may not be a consideration in exclusive facility operation, though at grade crossings may not be fully eliminated depending on the facility design and available financial resources. However, queue jump lanes- - apart from those distant from boarding areas-- have generated mixed experiences and are of relatively low cost-effectiveness. Where practical, the station platform should be at level with the floor of the bus for quick and easy boarding. This may also make BRT more accessible for wheelchairs, disabled passengers, strollers and carts, facilitating boarding and alighting with minimal delays. It must be noted that such a modification may make it difficult for the BRT vehicles to service “last mile” destinations. A major advantage of BRT is the ability of vehicles to leave the exclusive facility and serve local destinations in “branch” configurations. Given the financial difficulties experienced in the urban "Global South", branch infrastructures is hardly a cost-effective or efficient improvement strategy to pursue. 2.2.4 Fare Treatment Transit fares are problematic, and peculiar to local norms. Access to transportation in urban areas everywhere, but particularly in the "Global South", needs to be affordable, reliable and safe. While transportation access can enhance opportunities for employment and other public services, the viability of these services needs to be addressed[17] . Using public transport as a mechanism for income redistribution is rife with difficulties and an ill-advised welfare strategy that often distorts labor markets; it is also possible to seriously distort economic development objectives and better mechanisms exist and are more effective. To be clear: for the most part, the fare structure will in a large measure define the BRT system income; however, advertising and sponsorship agreements have been proven to raise revenue. Careful consideration must be taken when defining the fare structure to have a cost-efficient system that considers the purchasing capacity of the users. Fare structures have been used as mechanisms of income redistribution; such use is quite inefficient and though sometimes politically appealing are ineffective mechanisms for attempting to achieve social equity. This is particularly true of the "Global South". Urban areas often lack adequate transportation infrastructure as well as basic services like potable water, sewer, environmentally sensitive waste disposal and inferior housing[18] . Even so, the private sector has often supplemented public investment when market opportunities exist; more importantly, private capital is often linked to entrepreneurial activity. For polities experiencing the commodity trap-- where managerial skills and investment opportunities tend to be similarly scarce-- public-private partnerships that suit local circumstances are attractive approaches to public service provision.
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  American Journal ofHumanities and Social Sciences Research (AJHSSR) 2025 A J H S S R J o u r n a l P a g e | 261 Fare payment at the station, instead of on the bus, can minimize the delay caused by passengers waiting to pay on board, though technologies are substantially reducing delays attributable to fare collection activities. However, any prepayment mechanism will likely be similarly effective, particularly if accompanied by efficient fare payment verification. Discounted pass programs fall into that category of fare purchases. Unfortunately, fare evasion is commonplace; it is advisable to ensure that neither service provision nor financial security suffer due to fare enforcement actions or the lack thereof. The ability of a public entity to act as revenue and safety guarantor brings benefits to many aspects of public transportation operations. Fare levels are a separate issue[19] . LAMTA set their rapid bus fares equivalent to local bus fare levels, reasoning that that the Board believed basic services should function as well as does the “Rapid” service. In most instances, price differentials as for premium services can be implemented for BRT if the customer values the difference it offers from basic service— product differentiation-- and the value distinction can be exploited by the service provider; much like produce, the value of the service disappears if not used by a customer because unsold seats have zero value. In simple terms, the cost function is a straight line since virtually all the costs to produce the service has been incurred; that is, once placed in service, the marginal cost for the service is zero. 2.2.5 Technology and Design ITDP appears to consider the above to be the “BRT Basics”; and to a great extent these foundational elements for BRT are consistent with other standards or guidelines proposed by different organizations, though other components ensuring that BRT is well designed for both transit operations and passengers benefit certainly exist. BRT corridor designs are best predicated by defining the specific services that should function with the assistance of the BRT infrastructure. BRT capacity and performance is a balance between supply of service and capacity of the roadway, stations, fare systems, policing and emergency services and--importantly-- demand for transportation between service points. If passengers do not know how to use the system and cannot stay informed about the operating status of the BRT, then no manner of good design will enhance its operation. Communicating with passengers about the system is vital for a BRT corridor to be effective. BRT cannot be considered a standalone project; it must be perceived as an integral component of the transportation system and function accordingly. BRT exists within the realm of many other infrastructural systems in urbanized areas (transportation and otherwise) and it must interact with them to increase transportation and, hence, job access for the public and ensure people can reach the BRT and, through it, their destinations. Though costs for the various project elements are relatively commonplace, and can be programmed accordingly, technological risks are greater and play an increased role in the uncertainty associated with the financial aspects of the implementation of the infrastructure. There is an even more confounding aspect of the interplay, some of which arises from the realization that certain features for enhancing the value of BRT are not unique to rapid transit applications but can be applied to public transit in general. Interestingly, there is plenty of evidence that BRT can function effectively without overt reliance on any specific technology[20] . This provides opportunities for the competitive bidding of equipment, both mobile and stationary. What is important for a successful BRT implementation is that it functions in a way beneficial to customers while being financially and operationally sustainable for the sponsoring organization. 2.2.6 Guided Buses The ITDP included various features in its BRT "Standard". It also identifies certain subsidiary features. While the ITDP BRT standard considers the features beyond the basic, they may prove critical to the viability of the BRT operation. There are many features that go beyond the basics, like control centers and long-range plans. These are important for all public transit operations, not just BRT. While their cost may be more easily buried in a BRT budget, any metropolitan area capable of supporting BRT can make excellent use of a regional transit operations center. Similarly, if a metropolitan system uses multiple service providers-- public and/or private-- facilities should be open to the use of these providers and managed by a central control facility. Logically that center should avoid operating in a parochial manner. A successful model for several aspects of this type of operation might be considered Great Britain’s “Network Rail”. Buses that operate in mixed traffic move slowly in urban environments because the services they provide were designed-- not for speed maximization-- but to shorten passenger walking distance, increase service coverage, and avoid buses bunching along the route; most transit services providing transportation in mixed traffic operate at speeds significantly below the general traffic flow, not purely out of convenience but as a result of historic choices among alternatives or misplaced priorities embedded in labor agreements. Rail vehicles operating similar services perform in similar fashions. Service designs are not intrinsically tied to vehicle operating characteristics, except that older technologies tend to exhibit greater limitations. Rail based
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  American Journal ofHumanities and Social Sciences Research (AJHSSR) 2025 A J H S S R J o u r n a l P a g e | 262 services-- either self-propelled or otherwise-- have no intrinsic advantage over rubber tired, self-propelled vehicles operating on concrete pavement under similar traffic conditions, as technology has intervened. There are also a few applications of guided buses; the technology has been used where the transit vehicle might encounter tight horizontal clearances. Variations of these mechanical and electronic types have been in revenue service with amusement park attractions as well as for certain European and Australian services. Guided buses can share road space with general traffic along most conventional roads. Guidance systems can be physical (Adelaide, Australia and Cambridgeshire, England) or electronic (a Global Positioning System (GPS) system in Minneapolis-Saint Paul, United States and an optical guidance system formerly in Caen, France); GPS has widely been used in demonstrations of lane assist technology, particularly where the vehicles are to be operated in lanes barely wider than the vehicles themselves and signal reception is optimal. There are four global satellite navigation systems currently in operation: Beidou (China), Galileo (EU), GLONASS (Russian Federation) and GPS (USA). Many rely on similar frequencies, and receivers capable of using multiple systems have been produced. While these and other regional systems vary in expected accuracy, all provide positional information of sufficient accuracy to locate a transit vehicle. It should be noted that communications with such transmissions may be lost under certain circumstances, and satellite-guided vehicles often require additional technological assistance to operate at tolerances obtainable with mechanical guidance. Even so, the overall expense of such GPS technologies has proven superior to the somewhat higher maintenance costs associated with mechanical systems and considerably more flexible in accommodating route adjustments. Given the number of manufacturers in the marketplace, guidance and location functions as noted below should be attainable from several vendors[21] . 2.2.7 Bus Signal Priority (BSP) Because of the limited industry experience with technology, a major purpose for this paper-- in fact, a primary concern-- is to highlight twenty-year-old findings-- at the time, groundbreaking-- of potential utility for BRT in the "Global South" and elsewhere. These findings are of potential interest because the findings are only of import if acted upon, and the same dearth of infrastructural capital that effect BRT deployment restricts the number of traffic signals operating in the "Global South". The ITDP BRT "Standard" considers the operational aspects of bus signal priority to be of little practical value or, perhaps, unproven. Regardless, it is important to explore the findings of the Santa Clara Valley Transportation Authority (VTA) and other transit applications with respect to BSP operations on arterial streets under revenue conditions along major arterial corridors[22] . Technological improvements, though most not initially intended for transit, abound in the marketplace. There are numerous technologies that allow the tracking of vehicles, access control, and fee collection; these technologies or variants thereof can facilitate access to BRT facilities by both private and public service providers and enhance facility safety and management in the bargain. Guided vehicles, as such, are neither necessary nor sufficient attributes for a BRT designation, though they offer considerable enhancements to public transportation operations in general if conditions are appropriate. Regardless of the operating procedures employed, all communications— wired and wireless-- should be encrypted and otherwise protected in public transport operations. The latency introduced to the communications stream by encryption-- typically minor in duration-- is far outweighed by the significant security wired and wireless encryption provides. As previously noted, buses that operate in mixed traffic tend to be slow in urbanized environments because the services they provide were designed in a manner that was intended to shorten passenger walking distance and to minimize bus bunching; most transit vehicles operating in revenue service offer transportation in mixed traffic operating at speeds significantly below that exhibited by the general traffic flow as a result of choosing options that reduce gross operating speeds. A scheme like connection protection uses real time data to examine the operating status of transit vehicle, holding one transit vehicle in order for a traveler on another to make a successful transfer; this and other practices of the transit industry slow service delivery at the expense of revenue and ridership and become a practice simply because transit historically cannot maintain schedules with the stochastic aspects of traffic flow and passenger demand[23] . In the 1990s there was a substantial planning initiative to hold transit vehicles to facilitate customer transfers, so long as closely timed transfers were possible according to published schedules. Obviously, if services run on time connection protection is not needed. Indeed, research indicates that many existing and potential customers find lack of schedule adherence and slow operation to be major obstacles to transit use. Connection protection would only further delay transit travel and as such the program fails to address at least one major problem from the customer standpoint. The actual problem is inherently the inability to increase transit vehicle operating speed while promoting schedule adherence. As proposed with connection protection the functional aspects of the solution remain in control of the transit provider, despite the negative effect of the Connection Protection on service performance and overall customer satisfaction. Connection Protection quietly disappeared from the U.S. Federal Transit Administration planning agenda as alternative technological approaches began to show promise, particularly when wireless communication advances continued to offer opportunities for improving transit
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  American Journal ofHumanities and Social Sciences Research (AJHSSR) 2025 A J H S S R J o u r n a l P a g e | 263 operating efficiencies. Most transit sponsors fail to see speed deficiencies as a problem needing to be addressed for their long-term survival, a glaring management omission. Numerous transit operators viewed speed enhancements as minor benefits from the technology, and saw minimal time, revenue, and ridership enhancements as a result. The purpose of employing BSP for buses is to allow the transit vehicles to maintain their position in the traffic signal generated platoon without harming general traffic operation. From an application standpoint traffic control signals are used to assign vehicle or pedestrian right-of-way in a manner that is equitable and facilitates overall traffic operations; properly designed, BSP need not interfere with that objective. However, the traffic signal operating software in a BRT application is integral to the BSP process. There is an important distinction to be made with respect to modifying traffic signal cycles. BSP, like emergency vehicle preemption (EVP), does not require a dedicated transit lane to be effective. Transit vehicles can operate successfully in a mixed traffic environment with BSP-- as explained in the following paragraphs-- and do so without adversely affecting general traffic or other transit operations; EVP is a lesser concern because of societal priorities. Obviously, with capital funding for traffic control equipment in short supply, priority can be effective if provided by personnel directing traffic; there is substantial evidence that priority for transit and preemption for first responders and important personages was a historic responsibility for traffic personnel. The two most common and beneficial BSP treatments follow. The normal vehicle identification mechanism (as only authorized vehicles generate calls for priority) is to have a transponder identify the BRT vehicle’s presence to the traffic controller prior to its arrival at the intersection. If detected during the green phase, and the green phase is nearing termination, then the green phase is extended. If the detection occurs prior to a green phase the green time is recalled more quickly than normal. Though there are other means of providing priority through the modification of signal cycles, situationally they occur less frequently and are thus less beneficial. BSP can also be employed to facilitate service operations at transportation centers. According to some traffic engineers, it is possible that EVP may be more disruptive to traffic signal operations than BSP. However, the policy decisions accompanying the application of EVP and BSP are of obvious importance to the public regardless of operating environment. For the tests in Silicon Valley the determination was made before any implementation to avoid BSP interference with pedestrian signal operations or EVP. Regardless, traffic control software in common use can mitigate the most adverse effects attributable to BSP on general traffic operations. Of course, were BSP to be ineffective for transit operations the discussion would be moot. VTA tested two technologies for BSP in the early 2000s-- and even earlier tested optical systems in preemption on the County expressway system-- on the arterial roadway known as the El Camino Real in Santa Clara County using traffic signal operating Caltrans’ C8 software. These technologies were chosen by Caltrans. The first technology tested was based on point detection, where existing traffic signal advanced detection loops and buses were equipped with short-range radio frequency identification (RFID) technology based on short range radio wave transmission to identify buses that were to be granted priority; RFID technology has been commercially available since the 1970s, and the technology had been deployed in revenue service previously in both Los Angeles and suburban Chicago. Approximately 200 meters-- actual distance varied by traffic signal installation, and the coaxial cable used for the loops is rated at a maximum effective range of 330 meters-before reaching the signalized intersection buses equipped with an undercarriage mounted transmitter would trigger a request for priority with the traffic signal being approached, which would then check its operating parameters and, if appropriate, would modify traffic signal operation to provide the bus with priority. The second detection technology in the test-- with the same C8 controller software-- used GPS-based technology that creates user defined detection trapezoids of approximately 300 meters by thirty meters activated by suitably equipped buses. As the installation of equipment in both instances was intended as a proof of concept, data collection was proactively monitored but limited to the corridor under evaluation; system performance was monitored using prevailing VTA procedures. It should be noted that optical systems have been tested and proven effective. Though effective, optical systems are not efficient; that is, at typical detection ranges optical systems are relatively inaccurate with respect to distance. VTA already used an Orbital GPS-based vehicle management system independent of the bus BSP systems that allowed verification of the operating data reported. It is important that independent performance verification existed, as vendor integrity was frequently questioned by competitors. Only transit operations were used to modify signal operation except for EVP and pedestrian requests being protected; arterial conditions were otherwise unchanged and all other traffic signal functions used existing traffic signal hardware and software. Traffic signal control hardware commonly has electronic inputs that separately identify EVP and BSP requests; the traffic signal software handles competing requests for attention based on its own operating parameters. In the first test corridor BSP improved operating speeds from 12.3 miles per hour to 15.1 miles per hour. In the second test corridor BSP improved operating speeds from 10.5 miles per hour to 13.6 miles per
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  American Journal ofHumanities and Social Sciences Research (AJHSSR) 2025 A J H S S R J o u r n a l P a g e | 264 hour. These corridors were typical for arterial operations though differed from each other markedly in terms of traffic volume, transit patronage and other characteristics. In both test corridors the return on investment from operating savings was less than two years, including system maintenance expenses; arterial mixed traffic operating speeds in both corridors were unaltered because of BSP as were overall traffic incident rates. Transit ridership increased in each corridor though system revenue changes were not significant. The passenger response was positive, and complaints from other vehicle operators failed to materialize. At minimum, arterial BRT operation was benign with respect to rapid transit success or failure. There is strong evidence that the staged completion of major BRT facilities could be a practical alternative to project delays caused by right-of-way acquisition difficulties and other facility development reasons. The value of BSP can hardly be considered inconsequential, although the details of each application and the magnitude of benefit are unique. However, this is not to say that all BSP applications are equal in effect; a traffic signal strategy that facilitates the movement of either buses or streetcars through traffic signal-controlled intersections is available in many configurations. Note that, although priority and preemption are often used synonymously, they are in fact different processes applied for different purposes. Utilizing similar equipment, BSP modifies the normal signal operation process to better accommodate transit vehicle operations, while EVP interrupts the normal traffic signal cycle progression for special purposes like approaching trains at grade crossings or to allow “first responders” relatively unhindered travel to the site of an emergency. Affected vehicle operators commonly report subpar detection range performance from optical EVP and BSP equipment-- a traditionally used technology-- and lack of detection range consistency; point detection and GPS- initiated preemption and BSP applications tend to provide superior performance. It is essential to recognize that current computer-aided intersection modeling tools will understate BSP system benefits if totaled over the full extent of a BRT corridor. Depending on many factors including-- though not limited to-- length of traffic corridor, signal interconnects, number of stops, boardings/alightings, number of signalized intersections, the BSP treatments and their benefits applied by the traffic signals as well as vehicle detection systems deployed in the BRT corridor may be understated twenty-five to 200 percent as opposed to benefits resulting from BSP at corridor intersections alone. The synergy of corridor-wide BSP deployment with respect to bus speed is considerable; however, the actual experienced synergy depends on the length of corridor, service demand with respect to boardings and alightings, the features of the controller software paradigm and the detection technology employed in the corridor. Many of the earliest applications of BSP were designed to maximize adherence to exogenously set schedules and thus were less likely to generate indicators of speed benefits and, ultimately, the attraction of additional demand for the service. Interestingly, the increase in speed combined with the schedule adherence capabilities were determined to result in substantial operating cost savings. 2.2.8 Last Mile Generally, “last mile” refers to the design and provision of travel services from a public transportation node to a passenger’s destination. The last mile for public transit describes the final delivery of customers to the acceptable proximity of their destinations after completing the line haul portion of their trip. Stop spacing, network structure, travel time, service reliability and frequency depend on assumptions about how far customers will be willing to walk. Last mile services tend to be costly to transit providers as they are to delivery services; historically, the “last mile” for transit was a walk of much less than a mile, often a distance of approximately one quarter of a mile. This distance is a function of perceived customer convenience, as potential customers often have alternatives to transit use. Generally, “last mile” refers to the design and provision of travel services from a public transportation node to a passenger’s destination. As in several industries, the cost of installing and maintaining associated capital infrastructure with respect to the last mile can only be amortized over that small group of customers in a neighborhood, compared to a plethora of customers served by the main service "trunks" of the network. There are many obstacles to cost- effective service delivery including cost recovery, operational efficiency and infrastructure adequacy. This difficulty has often caused mature rail rapid transit services to reduce branch line operations as cost saving measures. Bus systems tend to react in a similar fashion; in most cases, the last mile bus service can be effective with minimal support infrastructure if operating on schedule. In theory, buses heading to BRT facilities can collect passengers in neighborhoods and supplement mainline capacity on the BRT facility itself, avoiding much of the friction of passenger transfers between bus and rail. If allowed to use a BRT facility, independent operators can therefore concentrate on serving neighborhoods where they may have natural operating advantages and/or fewer competitors. Where privately owned transit operators compete with publicly owned service providers, the publicly owned service providers tend to frown on such action as private operators tend to select as being the best or most desirable service areas; that is, they have an incentive to serve more lucrative areas. This is not a problem unique to BRT services.
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  American Journal ofHumanities and Social Sciences Research (AJHSSR) 2025 A J H S S R J o u r n a l P a g e | 265 III. SIGNAL PRIORITY MODELING RESULTS The data generated by BSP equipment functioning on El Camino Real in Santa Clara County provides interesting evidence of the peculiar benefices of signal priority[24] . At the time-- the first decade of the Twenty- first Century-- there still were many unanswered questions about BRT and the role the mode might play in the mix of services available to the transit industry. Santa Clara County comprised the core of “Silicon Valley”. It had a population of over one million, was home to numerous high technology companies, hosted three major universities and a broad range of communities including those of highest income and lowest income (often in proximity). The tests were run on arterials with some of the highest Average Daily Traffic (ADT) in the region. The determination was made to present the data analysis as daily bidirectional benefit to operations for an average trip. The traffic signals in the analysis areas were coordinated, and signal operation was optimized prior to assessing bus signal priority operation in revenue service. Zones I and II were equipped with RFID technologies where vehicles were detected as they traversed existing coaxial cable detection loops. Zone III utilized GPS detection paired with two different signal controller models running different-- but functionally similar-- priority subroutines. Both Caltrans and the City of San Jose, California managed signal corridors within their respective jurisdictions. Caltrans managed traffic signals were generally operating beyond downtown San Jose, while the City of San Jose managed traffic signals within the downtown area, using more advanced signal hardware and software. Not surprisingly, BSP proved effective regardless of any operational differences among the systems. 3.1 Statistical Analysis: Zone I and Zone II Combined These zones extend from east to west along El Camino Real; the corridor runs along the far western end of El Camino Real in Santa Clara County, and all but the easternmost intersections are outside the corporate limits of San Jose. The corridor extends from Race Street to Castro Street, and abutting development becomes predominantly commercial moving from east to west. The arterial cross-section of El Camino Real varies but at the time of the demonstration the roadway configuration was of minimum design volume of 40,000 ADT. Bus- only lanes were not incorporated in the roadway design; except for BSP functionality traffic signal operation and hardware configurations were unaltered, even at the queue jump lane location. Dual function detector cards replaced single function detector cards in controller cabinets, but detector loops were otherwise unaltered. Traffic signal management was performed by Caltrans District 4; the hardware and software employed in each zone were identical. Zone One has two queue jump lanes that were found to provide little benefit to time savings, and Zone Two had no queue jump lanes. Vehicles serving VTA Route 22 were not provided with priority, while vehicles serving VTA Route 522 were given priority. The following statistical model presents the results of a simple linear regression. Note that the variable names have been altered from those found in the original analysis to ease understanding, and while TET is a continuous variable BSP is a binary variable: Dependent Variable: Trip Elapsed Time (TET) Independent Variable: Priority (BSP) Sample Size: 1356 R2 : .11713856 (TET) = 3726.4058 – 689.25385(BSP) T and F statistics are significant with P values <.0001 although it is likely some key variables have not been included in the model. While multivariate applicability is indicated, at the time of demonstration resources for more detailed modeling were unavailable. 3.2 Statistical Analysis: Zone III The corridor from west to east extends from Race Street along Santa Clara St. through downtown San Jose to Capitol and south to, and abutting development becomes predominantly commercial moving from east to west. The arterial cross-section varies but at the time of the demonstration the roadway configuration was of minimum design volume of 20,000 ADT, increasing as the corridor extends eastward. Bus-only lanes were not incorporated in the roadway design; apart from BSP functionality, traffic signal operation and hardware configurations were unaltered. Traffic signal management was performed by Caltrans District 4 and the City of San Jose Department of Transportation, each maintaining their own equipment. San Jose used dissimilar hardware and software from Caltrans in Zone III although functional parameters were similar; regardless, the detector equipment was identical. Zone III has no queue jump lanes.
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  American Journal ofHumanities and Social Sciences Research (AJHSSR) 2025 A J H S S R J o u r n a l P a g e | 266 Vehicles serving VTA Route 22 were not provided with priority, while vehicles serving VTA Route 522 were given priority. The following statistical model presents the results of a simple linear regression. Note that the variable names have been altered from those found in the original analysis to ease understanding, and while TET is a continuous variable BSP is a binary variable: Dependent Variable: Trip Elapsed Time (TET) Independent Variable: Priority (BSP) Sample Size: 1394 R2 : .33793625 (TET) = 1406.3572 – 323.42392(BSP) T and F statistics are significant with P values <.0001 although it is likely some key variables have not been included in the model. While multivariate applicability is indicated, at the time of demonstration resources for more detailed modeling were unavailable. IV. CONCLUSION BRT is considered a high-quality bus-based transit system that delivers fast and efficient service. Like rail rapid transit, facilities vary based on local needs, including financial capabilities to handle both capital and operating expenses. There are many ways to evaluate infrastructure, and interested individuals have an opinion on the purpose, effectiveness and limits of any aspect of such projects. BRT, as an infrastructural element, is operating or in development in cities large and small[25] . Some are components of networks; many are smaller, corridor-based projects. BRT is offering hope to the residents of the urban "Global South". Clearly, “Silicon Valley” is not typical of the conditions found in the “Global South”; however, as a test bed for the technology the location is quite appropriate. Interestingly, BRT harkens back to the aspirations of many professionals that were urged to get the most benefit possible from public expenditures. Transportation Systems Management (TSM) is a term that was once a mantra for transportation professionals in the United States, at least for a short period of time. A set of strategies focused on operational improvements to maximize the safety, mobility, and reliability of existing transportation infrastructure without adding significant new capacity, TSM was later to bear the undeserved sobriquet of “too small to matter”. When investment funds are difficult to come by, the opportunity to apply BRT and use BSP as TSM should rather be interpreted as “too substantive to miss”. Most metropolitan areas are faced with antiquated or otherwise inadequate infrastructure and services as the population exceeds the ability to deliver services that urban centers need for economic development. Several researchers have been intrigued with the potential of signal priority to benefit the public transit industry. Though not conclusive, there is evidence that benefits calculated through intersection modeling may significantly under forecast benefits from BSP in corridor deployments. Not all aspects of BRT are supported by interested parties; indeed, certain individuals have campaigned openly against improving public transportation in any way. However, improvements that foster development with minimal adverse consequences are few and far between and should be promoted. Developed nations can afford to take a chance on unproven technology. Less developed nations have little to no such flexibility. Less developed nations are sure to have fewer traffic signals as well, which will likely affect the overall magnitude of benefit from BSP. Regardless, BRT and BSP appear to have much more upside to most other transit technologies. Certainty is not a hallmark of infrastructural programming. It may be prudent to heed the advice of Hugh Keogh—with apologies to the Old Testament-- contained in the adage: “the race is not always to the swift, nor the battle to the strong, but that's the way to bet”. V. ACKNOWLEDGMENT A lengthy professional career brings with it an obligation to recognize many colleagues who have contributed to the development of this paper, in one form or another. The following individuals deserve recognition: Tunde Balvanyos, Bill Belmont, Randy Blankenhorn, Terry Brannon, Paul Chiu, Alan Danaher, Casey Emoto, Kevin Fehon, Nuria Fernandez, Ed Fok, Shanthi Ganji, Kal Goldberg, Brendon Hemily, Randy Iwaski, Matthew Jue, Tom Klimek, David Kobayashi, James Lau, Jim Lightbody, Leroy Kos, Wally Kos, James Lau, Cory LaVigne, Kai Leung, Eugene Maeda, David Man, Chuck Metalitz, Ho Nguyen, Shamus Misek, Robert Paaswell, John H. Paige, Robert Pauly, Dusty Powell, Bill Reynolds, Joseph St. Marie, Ashish Sen, Ron Shimizu, Mel Sierakowski, Sean Skehan, Siim Soot, Z. Sonja Sun, Kesti Susinskas, John Stokowski, Karthik Swamy, Sid Weseman, David Zavaterro and Wei-Bin Zhang. Even though this list is extensive the names of some deserving individuals are certain to be absent; rest assured, the omission is inadvertent.
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  American Journal ofHumanities and Social Sciences Research (AJHSSR) 2025 A J H S S R J o u r n a l P a g e | 267 Isaac Newton stood on the shoulders of giants. It has been a pleasure to stand shoulder-to-shoulder with these giants. REFERENCES [1] Backhouse, Roger E., Antoinette Baujard, Tamotsu Nishizawa. (2020). Revisiting the History of Welfare Economics. Lyon FR: HAL. p. 22. [2] Just, Richard E., Darrell L. Hueth, and Andrew Schmitz. (2008). Applied Welfare Economics. Cheltenham, UK: Edward Elgar. p. 707. [3] Hannah, Leslie. (2009). “100 Years of Government Control over Utilities”. Conference proceedings. Canberra: Australian Competition & Consumer Commission. p. 4. [4] Mouton, Morgan. (2021). “Worlding Infrastructure in the "Global South": Philippine Experiments and the Art of Being ‘Smart’”. Urban Studies. 58/3. pp. 621–638. [5] Wu, Weiping. (2024). “Infrastructure Investment and Finance in the "Global South": Private Participation and Its Determinants”. Public Finance and Management. 23/3. pp. 99-112. [6] Jamasb, Tooraj, Rabindra Nepal, and Govinda R. Timilsina. (2017). “A Quarter Century Effort Yet to Come of Age: A Survey of Electricity Sector Reform in Developing Countries”. The Energy Journal. 38/3. pp. 195–234. [7] Davis, Morris, and Sol Levine. (1967). “Toward a Sociology of Public Transit”. Social Problems. 15/1. pp. 84–91. [8] Rizzo, Matteo. (2015). “The Political Economy Of An Urban Megaproject: The Bus Rapid Transit Project In Tanzania”. African Affairs. 114/455. pp. 249–270. [9] Anderson, Michael L. (2014). “Subways, Strikes, and Slowdowns: The Impacts of Public Transit on Traffic Congestion”. The American Economic Review. 104/9. pp. 2763–2796.0). Revisiting the History of Welfare Economics. Lyon FR: HAL. p. 22. [10] Pushkarev, Boris Sergeevich & Jeffery M. Zupan. (1977). Public Transportation and Land Use Policy. Bloomington IN: Indiana University Press. p. 242. [11] Haynes, Kingsley, Carlos Ariera, Sarah Burhans and Nitin Pandit. (1995). “Fundamentals of Infrastructure Financing with Respect to ITS”. Built Environment (1978-) 21/4. pp. 246–254. [12] Ling, Shuai, Wandi Hu and Yongjie Zhang. (2016). “The Impact of Bus Priority Policies on Peak Commuters Behavior: An Agent-Based Modelling Perspective”. Filomat. 30/15. pp. 4101–4110. [13] Ryan, Sherry. (2005). “The Value of Access to Highways and Light Rail Transit: Evidence for Industrial and Office Firms.” Urban Studies. 42/4. pp. 751–764. [14] Koling, Adam, Wei-Bin Zhang, Kun Zhou and Huadong Meng. (2018). BRT Toolbox. Sacramento CA: Caltrans. p. 35. [15] Institute for Transportation and Development Policy (ITDP). 2016. About the Standard: What’s New in 2016? (White Paper). [16] Deb, Kaushik. (2000). “Private Investment and Policy Developments in Transport Sector”. Economic and Political Weekly. 35/15. pp. 1277–1282. [17] Basso, Leonardo J., and Hugo E. Silva. (2014). “Efficiency and Substitutability of Transit Subsidies and Other Urban Transport Policies”. American Economic Journal: Economic Policy. 6/4. pp. 1–33. [18] Mercier, Jean. (2009). “Equity, Social Justice, and Sustainable Urban Transportation in the Twenty- First Century”. Administrative Theory & Praxis. 31/2. pp. 145–163. [19] Chang, M., et. al. (2004). CHARACTERISTICS OF BUS RAPID TRANSIT FOR DECISION- MAKING. Washington DC: Federal Transit Administration. p. 301. [20] Jue, Matthew and James T. Jarzab. (2013). “Detection Range of Optical Emergency Vehicle Preemption System under Typical System Maintenance Conditions”. ITE Journal. 83/06. pp. 40-44. [21] Galicia, Luis D., et al. (2009). “Bus Rapid Transit Features and Deployment Phases for U.S. Cities”. Journal of Public Transportation. 12/2. pp. 23-38. [22] Li, Yue, et.al. (2008). Transit Signal Priority Research Tools. Springfield VA: National Technical Information Service. p. 178. [23] Advanced Traffic Management Systems Committee and Advanced Public Transportation Systems Committee of the ITS America. (2002). An Overview of Transit Signal Priority. Washington DC: ITS America. p. 25. [24] Jarzab, James T., et.al. (2009). Bus Signal Priority in Santa Clara County California (unpublished White Paper). p. 19. [25] Watson, Vanessa. (2013). “Planning and the ‘Stubborn Realities’ of ‘Global South-East’ Cities: Some Emerging Ideas”. Planning Theory. 12/1. pp. 81–100.