Not applicable.
Not applicable.
This invention is in the field of mass transit systems. Embodiments of this invention are more specifically directed to scheduling and operation of mass transit commuter rail systems.
For many years, citizens of major metropolitan areas throughout the world have relied on commuter rail systems, including surface rail and subways, as an important means of transportation. Because at-grade intersections with motor vehicles are avoided by subway trains, subway systems are especially attractive in densely populated cities. Currently, over two hundred cities in the world operate subway commuter rail systems, serving hundreds of millions of passengers each day.
Commuter rail systems in general, and subway systems in particular, are of course constrained to the physical locations of their tracks and stations. Trains cannot travel except along the rails, and do not stop for loading and unloading except at discrete stations along the railway. The construction cost of the infrastructure components of railways, rails, and stations is a primary determination in the overall size and complexity of a subway system, especially considering the excavation required to build a subway line within (and thus under) an existing city. Because of these constraints, and of the cost required to add lines or additional infrastructure, optimal utilization of the transportation capacity provided by the subway commuter rail system is a highly desirable goal. Underutilization of the subway system is a financial disaster, in that the huge infrastructure costs are not recouped; as such, subway commuter rail construction is often confined to routes that are capable of providing adequate ridership. But these infrastructure costs also inhibit additional capacity from being constructed, if demand for the subway system exceeds its capacity. As a result, many of the world's urban subway systems are overcrowded; indeed, the overcrowded subway systems in Seoul, Korea and Tokyo, Japan often receive worldwide publicity. My U.S. Pat. No. 5,176,082, issued Jan. 5, 1993, describes a passenger loading and unloading control system that provides one way of addressing this overcrowding problem, specifically by scheduling the number of passengers that may board individual train cars at a station according to the number of passengers that are already on those cars; a method of simultaneously loading and unloading passengers, in an orderly manner, is also described in my patent.
The constraint of high infrastructure construction costs is also reflected in passenger travel times. Commuter rail systems present the particular problem that passengers are free to board and exit the subway train at any station along the line. For example, a train that makes n stops along its line will have Σj=2n(j−1) possible individual passenger trips, with the particular trip made by a given passenger defined by the station at which the passenger boards (i.e., the trip origin) and the station at which the passenger chooses to exit the train (i.e., the destination). And, of course, ridership depends on the convenience provided by the subway, which in large part depends on the proximity of subway stations to passenger destinations. The subway system designer and operator is thus faced with a tradeoff between the number of stations along a line and the passenger travel time from origin to terminus. Specifically, while a larger number of stations along a line improves the proximity of the subway to a wide range of destinations, this larger number of stations will necessarily slow the passenger travel time of passengers that do not want to exit the train at a particular station.
One conventional approach to solving the two problems of overcrowded subway train systems and long passenger travel times is the use of express trains, which are trains that do not stop at every station along a line. In some of the larger subway systems, such as those in New York City, Paris, and Seoul, separate railways and station platforms are provided for the express and local trains, enabling the express trains to travel the route without being held up by the slower local trains that stop at each station. In these systems with separate express lines and stations, in which the express trains are not slowed by local trains and stops at local stations, those passengers that board at an express station, remain on an express train throughout their trip, and exit at an express station, have the optimum passenger travel time.
However, many passengers must ride a local train either to travel to an express station, or to travel from the express station to their desired destination, or both. If these passengers wish to take advantage of the express train service, they must make a transfer between the local and express lines at least once during their trip. The total travel time for these passengers thus includes not only the travel time while on the trains, but also the transfer time involved in changing trains at the express stations. One can consider this transfer time to be the sum of several components, including the boarding and deboarding times, the time required for the passenger to walk between the express and local platforms (typically on different subway levels), and also the time spent waiting for the “transfer-to” train to arrive at the station. Typically, the wait time dominates this transfer time, and can be considered as a random variable, with a mean value of about ½ the “headway” time of the “transfer-to” train.
By way of further background, it is known to synchronize the arrival and departure times of express trains at express stations with the arrival and departure times of local trains at those stations, during rush hour periods of the day. For example, the New York City subway system has been known to schedule their express subway service to minimize transfer times between express and local trains, at least during morning rush hour periods. In this way, the wait time that passengers spend waiting for the “transfer-to” train to arrive at the station is reduced.
As evident from this description, however, those subway systems or portions of subway systems that are limited to only a single track in each direction of travel have not been able to provide express service. In such systems, the ultimate speed of travel of an express train, which as such does not stop at local stations located between express stations, will eventually necessarily be limited by the speed of any local train that the express train catches up to along the route.
By way of further background, “side tracks” or “sidings” are used in some railway systems to allow a faster train to pass a stopped or slower train.
Side track facilities are typically more prevalent at surface rail stations than at subway stations, because the excavation cost etc. involved in adding a side track at a subway station is typically prohibitive. For example, as shown in
By way of further background, computer algorithms for optimizing the scheduling of trains are known in the art. U.S. Pat. No. 6,873,962 B1 describes an automated approach for scheduling departure times and velocities of trains traveling along a rail corridor, by deriving and optimizing a cost function that ensures that all intersections (trains meeting or passing one another) occur at locations at which side tracks are in place. U.S. Patent Application Publication No. US 2005/0234757 A1 describes an automated scheduling system for freight trains, in a railway system including side tracks to allow faster trains to pass slower or stopped trains. U.S. Patent Application Publication No. US 2005/0261946 A1 also describes a method and system for calculating a train schedule plan that operates by optimizing a cost function to minimize delays at crossing loops and lateness at key locations along train routes. U.S. Patent Application No. US 2008/0109124 A1 describes a train scheduling method in which placeholders (“virtual consists”) are used to improve the stability of the solution.
However, each of these conventional train scheduling methods and systems apply to the scheduling of trains that are not concerned with allowing passengers to board or de-board at intermediate stations along the route. In other words, these scheduling methods do not involve the problem of passenger transfer from one train to another, nor do they account for trains that allow for the payload to efficiently board and de-board at any particular stop along the route. In other words, these conventional scheduling methods and systems do not solve many of the important and dominant issues involved in commuter rail systems, particularly subway systems.
By way of further background, U.S. Pat. No. 1,604,932 describes a passenger train system in which passenger throughput is increased by providing trains that are longer than the available platforms. Some cars in the train stop at the platform of every station, while other cars in the train stop at the platform only at alternating stations. The cars and platforms are color-coded, so that the passengers are aware of the restrictions.
It is therefore an object of this invention to provide a system and method of operating a subway train system that optimizes the utilization of subway system resources including the subway tracks, subway stations, and subway trains, while substantially reducing passenger travel time for all passengers.
It is a further object of this invention to reduce passenger total travel time at minimal system cost, resulting in reduced overcrowding of subway trains by improving the passenger throughput rate of the system.
It is a further object of this invention to provide such a system and method that is adapted to new or existing two-track subway systems.
It is a further object of this invention to provide such a system and method of that enables express trains to operate on the same subway line as local trains, while enabling the express trains to reduce the travel times of the express passengers.
It is a further object of this invention to provide such a system and method in which passenger transfer times at express stations are minimized.
It is a further object of this invention to provide such a system and method in which express service is provided without requiring the construction of side tracks or other infrastructure at the express stations.
It is a further object of this invention to provide such a system and method that facilitates the changing of trains at express stations to provide passengers with the opportunity to further reduce their travel time in exchange for minimal effort on their part, indeed to reduce their travel time to such an extent that a passenger can travel along the route at an effective speed that is faster than the fastest subway train travels along that route.
It is a further object of this invention to minimize the time spent by an arriving train waiting for a train at the station to leave the station, while providing the additional convenience to passengers of extra stops along the express route.
Other objects and advantages of this invention will be apparent to those of ordinary skill in the art having reference to the following specification together with its drawings.
According to one aspect of this invention, the departures and velocities of express and local subway trains are synchronized so that the express train arrives at express stations at approximately the same time as the local service train that is ahead of the express train on the same track. A novel side track and transfer system is provided to allow the express train to pass the local train at the express station, and to allow passengers to transfer directly between the stopped local and express trains without deboarding to a platform and waiting at the platform.
According to another aspect of this invention, the departures and velocities of express and local subway trains are synchronized so that the express train arrives at express stations at approximately the same time as the local service train that is ahead of the express train on the same track. At the express station, one or more of the trains transform from providing local service to providing express service, so that the last of the trains to arrive at the express station at a given time transforms from an express train to a local train, with the first one of the trains arriving at that station at that time transforms from a local train to an express train. Each passenger remaining on one of the trains thus travels at express speeds for at least a portion of the trip.
According to another aspect of this invention, the synchronized trains arriving at an express station at approximately the same time are shuttled at the platform to allow passengers to transfer from a train that is transforming from express to local service, to a train that is transforming from local to express service. These passengers can thus travel at express speeds for all but the necessary local legs of their trip. Indeed, it is possible for these transferring passengers to arrive at their eventual destination after a travel time that is shorter than that of the fastest train along that route.
According to another aspect of this invention, the later-arriving of the synchronized trains arriving at an express station is scheduled so that it makes an additional stop along its express leg, thus minimizing time that it must wait for the earlier-arriving synchronized train to leave the express station while improving customer convenience.
a is a schematic diagram, in plan view, of a conventional train station with side tracks.
b through 1d are schematic diagrams, in plan view, of the operation of an embodiment of this invention in connection with a train station with side tracks.
a is a schematic illustration of a subway line in connection with which embodiments of the invention are applied.
b is a plot illustrating the relative travel velocities of an express train and a local train along the subway line of
a is an electrical diagram, in block form, illustrating a computer system for scheduling and managing subway trains on the subway line of
b is a flow diagram illustrating the operation of the system of
c and 3d are plots illustrating the relative travel velocities of express trains and local trains along the subway line of
e through 3h are snapshot views of the subway line of
a through 4c and 4e are schematic diagrams, in plan view, of an express subway station enabling physical passing and direct train-to-train passenger transfer according to an embodiment of the invention.
d is an elevation view of adjacent subway trains carrying out direct train-to-train passenger transfer according to the embodiment of the invention shown in
a through 5k are schematic diagrams, in plan view, of an express subway station enabling physical passing and direct train-to-train passenger transfer according to embodiments of the invention.
l through 5o are snapshot views at specific points in time in the operation of the subway line described in 4a through 4d, according to embodiments of this invention.
a through 7c are plots illustrating the operation of trains transforming between providing express service and local service along a subway line, according to embodiments of this invention.
d through 7g are snapshot views of the subway line of
a through 8c are schematic diagrams, in plan view, illustrating the operation of trains making a stop at an express station, according to an embodiment of the invention.
a through 9c are schematic diagrams, in plan view, illustrating the assignment of semi-express stations along an interval between express stations, according to an embodiment of the invention.
a through 10g are schematic diagrams, in plan view, illustrating the operation of trains making a stop at an express station, according to another embodiment of the invention.
a through 11c are schematic diagrams, in plan view, illustrating the operation of trains making a stop at an express station, according to another embodiment of the invention.
a through 12h are schematic diagrams, in plan view, illustrating the operation of trains making a stop at an express station, according to other embodiments of the invention.
a and 13b are plan and elevation views, respectively, of an express station at which the system of
c and 13d are views of the content of graphics displays at the station of
a through 14d are timeline plots illustrating train travel times as varying spatially along a subway line, according to embodiments of the invention.
a through 15d are timeline plots illustrating train travel times as varying spatially along a subway line and varying with the time of day, according to embodiments of the invention.
a through 16d are timeline plots illustrating train travel times as varying spatially along a subway line, varying with the time of day, and varying with the day of the week/month/year, according to embodiments of the invention.
This invention will be described in connection with its embodiments, as implemented into an urban commuter rail system in which at least a significant portion of the system is an underground subway system. These embodiments are described in this specification because it is contemplated that this invention will be especially beneficial when utilized in such an application. However, it is contemplated that this invention can also provide similar important benefits if implemented in other applications and environments. Accordingly, it is to be understood that the following description is provided by way of example only, and is not intended to limit the true scope of this invention as claimed.
a schematically illustrates the context of embodiments of this invention in connection with subway line SLINE, which travels from an origin to a terminus. For purposes of this contextual description, subway line SLINE will be discussed in connection with a single direction of travel (west to east in
b illustrates the theoretical travel time for an express train EXP and a local train LOC along subway line SLINE, in a single direction (e.g., west to east). The timing illustrated in
However, if subway line SLINE is essentially a two-track line, such that one railway track carries trains travelling in one direction and the other track carries trains travelling in the other direction, then the theoretical timing illustrated in
Because of this limitation, most conventional two-track lines in modern subway systems do not support express train service. Rather, every train along these conventional subway lines operates as a local train, and the passenger throughput and travel convenience are limited—every subway passenger must endure the time required for the train to make every local stop along his or her trip. Typically, the cost of providing side tracks as described above relative to
It has been discovered, according to this invention, that express subway service can be provided within a two-track system, in a manner that requires, at most, a much reduced cost relative to the cost of retrofitting stations to include conventional side tracks; in some embodiments of this invention, as will become apparent from the following description, express service can be provided in a subway system without incurring any construction or infrastructure costs. This invention thus provides important benefits to both the subway operator and the subway passenger community, such benefits including improved passenger throughput that results in reduced passenger travel times and reduced passenger overcrowding, improved utilization of existing subway infrastructure, and enhanced passenger autonomy in managing subway travel.
Synchronization of Express and Local Trains
As evident from the previous description, in order to provide reasonable express subway service on a two-track subway line (i.e., one track for each direction of travel), the ability of an express train to effectively pass a slower traveling local train must be provided. As mentioned above, it is contemplated that express subway trains may not actually be traveling at faster instantaneous velocities than local trains, but may instead travel at faster effective travel velocities because these express train do not stop at local (i.e., non-express) stations.
According to embodiments of the invention, express stations are periodically defined as locations along a subway line at which express subway trains and local subway trains both make stops, at which passengers may board and de-board both local and express trains, and at which passengers may transfer from a local train to an express train. Also according to embodiments of the invention, the scheduling of the express and local trains is synchronized relative to each other so that the faster-traveling express trains catch up to slower-traveling local trains at express stations only. And at those express stations, express trains are permitted to pass local trains, either physically or “virtually”, even though the subway line may be constructed as a two-track subway line with only one track provided for travel in each direction. The particular manner in which the physical or virtual passing of trains is carried out at these stations will be described in detail below in connection with the specific embodiments of this invention.
According to embodiments of this invention, the scheduling of the express and local trains to arrive effectively simultaneously at express stations is carried out by a computerized system that is constructed, programmed, and operated to accomplish that scheduling task.
As shown in
Network interface 26 of workstation 21 is a conventional interface or adapter by way of which workstation 21 accesses network resources on a network. In this embodiment of the invention, the network to which network interface 26 is coupled may be a local area network, or may be a wide-area network such as an intranet, a virtual private network, or the Internet. As shown in
As shown in
Of course, the particular memory resource or location at which persistent and temporary data, library 32, and program memory 34 physically reside can be implemented in various locations accessible to the computational resources of system 20. For example, data and program instructions may be stored in local memory resources within workstation 21, within server 30, or in memory resources that are network-accessible to these functions. In addition, each of the data and program memory resources can itself be distributed among multiple locations, as known in the art. It is contemplated that those skilled in the art will be readily able to implement the storage and retrieval of the applicable measurements, models, and other information useful in connection with this embodiment of the invention, in a suitable manner for each particular application.
According to this embodiment of the invention, program memory within system 20, whether within workstation 21 or within server 30, stores computer instructions that are executable by computational functions within central processing unit 25 and server 30, respectively, to carry out the functions described in this specification, by way of which the departure and operation of subway trains traveling along subway line SLINE are scheduled and managed. These computer instructions may be in the form of one or more executable programs, or in the form of source code or higher-level code from which one or more executable programs are derived, assembled, interpreted or compiled. Any one of a number of computer languages or protocols may be used, depending on the manner in which the desired operations are to be carried out. For example, these computer instructions may be written in a conventional high level language, either as a conventional linear computer program or arranged for execution in an object-oriented manner. These instructions may also be embedded within a higher-level application. For example, the scheduling and operation applications can reside entirely within program memory 34 of workstation 21, such that workstation 21 itself executes the method and processes described in this specification in connection with the embodiments of this invention, with server 30 performing network and data retrieval operations. According to another example, an executable web-based application can reside at program memory within server 30 and client computer systems such as workstation 21, receive inputs from the client system in the form of a spreadsheet, execute algorithms modules at a web server, and provide output to the client system in some convenient display or printed form, or output to trains and stations by way of signals communicated via interface 28. Other arrangements may of course also be constructed and operated within a system architecture such as that of system 20 shown in
Referring now to
The generalized flow diagram of
In this high-level description of
In process 36, computational resources within system 20 execute program instructions to define the number and frequency of express and local trains to be scheduled along subway line SLINE over time within a day, and as that schedule may vary from day to day. Similarly as process 34 described above, it is contemplated that process 36 is also carried out in an automated manner, for example by evaluating a cost function that expresses criteria involved in defining the numbers, lengths, and arrangement of express trains within the schedule. As will be evident from some embodiments of this invention described below, definition process 36 can include the defining of “group” subway trains, with the express portion substantially longer than the local portion. Constraints on the number of express trains are contemplated to depend on the various data elements described above and provided from data sources 33, 35, 37. Preferably and as described above, parameters representative of passenger throughput, passenger travel time, passenger comfort (i.e., avoiding overcrowded conditions), and subway train utilization, will be reflected in the cost function that is optimized in process 36. It is contemplated that those skilled in the art having reference to this specification will be able to apply conventional AI and other evaluation techniques to define the number and frequency of express trains for the current information relative to subway line SLINE, in this process 36.
Alternatively to processes 34, 36, the definition of express stations and the numbers and frequencies of express trains can instead be defined a priori by subway system management. While it is contemplated that such definition of these resources will, in general, not be optimized for all of the objectives of passenger throughput, passenger travel time, passenger comfort, and subway train utilization, and the like, the overall scheduling and operational process of this invention can still operate within such an environment to optimize these and other attributes within those constraints.
In process 38, computational resources within system 20 operate to derive a schedule for subway line SLINE over time, for the express stations defined in process 34 (or otherwise) and for the number and frequency of express trains defined in process 36 (or otherwise). According to embodiments of this invention, the schedule derived in process 38 synchronizes the operation of express and local trains so that express and local trains meet in time only at express stations. As mentioned above and as will be evident from the following description of embodiments of this invention, express stations allow for express trains to pass the slower-traveling local trains, either physically or virtually; conversely, at locations other than express stations along subway SLINE, an express train that catches up to a local train will have its travel time constrained by the speed of and stops made by the local train, at least until both trains reach the next express station. Optimal operation of subway line SLINE is thus contemplated to be achieved with express and local trains traveling in the same direction meeting only at express stations; in process 38, as a result, the departures and travel velocities of express trains will be defined in a manner that is synchronized with the schedule being followed by the local train that is ahead of the express train along subway line SLINE. It is contemplated that those skilled in the art having reference to this specification will be able to apply conventional AI and other evaluation techniques, for example by evaluating a cost function that expresses criteria involved in deriving the schedule, to define the operational schedule of subway line SLINE, including departure times and travel velocities, for the current information relative to subway line SLINE, in this process 38. In such an example, the cost function may express some measure related to passenger travel time along subway line SLINE, in an average, cumulative, or some other statistical sense, such that the schedule is derived, in process 38, by minimizing this measure of passenger travel time.
Referring to
According to embodiments of this invention, express trains EXP1 through EXP4 are synchronized with local trains LOC0 through LOC3 in the sense that express trains EXP1 through EXP4 catch up to local trains LOC0 through LOC3 only at express stations E0 through E3. For example, local train LOC1 leaves express station E0 at an earlier time (time t1) than express train EXP2 leaves express station E0 (time t2), yet both arrive at express station E1 at the same time (time t3). Similarly, express train EXP3 catches up to the next previous local train LOC0 at express station E2 (at time t4). The other trains traveling along subway line SLINE proceed in a similar manner. Of course, in order for the schedule of
While the time scale and distance scale are shown as constant along the axes in
d illustrates the case in which the distance (either in miles or in number of intervening local stops, or both) between express stations varies from interval to interval. For example, the time axis of
d illustrates this governing relationship, relative to local train LOC0. In this example, an express train leaves express station E0 at the end of each time interval Δt following time t=0, followed immediately by a local train as before. The interval velocity of local train LOC0 over the first express interval I1 will depend on various factors such as the instantaneous velocities at which local train LOC0 travels between stops, the stop time at each local station over the interval, and the like. In any event, the interval velocity of the next express train EXP1 over express interval I1 is governed by the interval velocity of local train LOC0 over that distance, such that express train EXP1 meets and passes local train LOC0 at express station E1 (pass point 1P10), and therefore leaves express station E1 before local train LOC0. Over the next shorter interval I2 from express station E1 to express station E2, local train LOC0 travels at its interval velocity, which in this example is slightly faster than its interval velocity over interval I1 (as evidenced by the slightly flatter line in the plot of
This operation of subway line SLINE according to embodiments of this invention can be further described in connection with the schematic views of subway line SLINE shown in
f illustrates subway line SLINE at the point in time at which local train L0 has reached express station E6. In other words, in time between that shown in
g illustrates the portion of subway line SLINE from express station E0 through express station E3, at the time corresponding to that shown in
In connection with this invention, scheduling process 38 derives a schedule in which express trains and local trains meet one another, when traveling in the same direction, only at express stations. It is contemplated that the manner in which scheduling process 38 is executed can readily define and optimize the schedule by selecting and modulating the departure times and travel velocities of the express trains as governed by the departure times and travel velocities of the local trains. Conventional computer operations are contemplated to be readily capable of performing such optimization, given the constraints presented by the synchronization requirements of embodiments of this invention. The manner in which express trains physically or virtually pass the local trains at each of the pass points P in
Referring back to
In process 40, the results of the final instance of process 38 are communicated to passengers. It is contemplated that process 40 can be carried out in various ways, including the generation of printed schedules, online schedules, push-transmissions to Internet-capable devices, and the like. It is also specifically contemplated, in connection with embodiments of this invention, that the derived schedule will be communicated to passengers, in process 40, by way of video displays at stations along subway line SLINE, and video displays on the trains themselves. To the extent that communication process 40 is performed electronically, for example to stations and trains, it is contemplated that system 20 will provide those communications via train/station interface 28 (
Also as shown in
System 20 and its operation, as described above in connection with
Conventional Side-Track Subway Station
According to an embodiment of the invention, the synchronized scheduling of express and local subway trains, as described above in connection with
b illustrates express station Ex at a point in time in which an earlier-arriving eastbound local train LOC0 has arrived at station Ex, and has switched over to side-track 4WE, at which time passengers may board and de-board local train LOC0 via platform 5WE. While local train LOC0 is stopped at platform 5WE in this manner, later arriving express train EXP0 arrives at platform 5WE along track 2WE, as shown in
Synchronization of the express and local train schedules so that express trains EXP catch up to local trains LOC only at express stations, as described above in connection with
Side-by-Side Subway Station
As described above in connection with
According to another embodiment of the invention, the express subway stations are constructed so that direct train-to-train passenger transfers are possible, reducing the duration of express station stop times and also minimizing the footprint of the express station (and thus the construction or retrofit cost). In addition, according to this embodiment of the invention, the ability for an express subway train to pass a local subway train, and to permit passengers to transfer directly between the local and express trains, is facilitated. As described above, the scheduling of the express and local trains is synchronized relative to each other so that the faster-traveling express trains catch up to slower-traveling local trains at express stations only; at those express stations, the express trains are permitted to pass local trains.
a through 4e illustrate an example of express subway station Ex on subway line SLINE constructed according to one embodiment of the invention in which passenger transfers occur at a location beyond the station platform.
b illustrates station Ex in operation, according to this embodiment of the invention, at a time that eastbound local train LOC0 and eastbound express train EXP0 are stopped at station Ex. In this example, local train LOC0 arrived at station Ex before express train EXP0, considering that the effective travel velocity of express train EXP0 is faster than that of local train LOC0 according to embodiments of this invention, as described above. Earlier-arriving local train LOC0 has pulled onto side-track 54e at station Ex, and has backed up (westward) by a small distance so that its trailing end is at or near the end of platform 50e (
As shown in
As shown in
d illustrates, by way of an elevation view, that local train car LOC0(n) is positioned sufficiently close to adjacent express train car EXP0,F(n) that passengers can easily step over separation distance Dsep between cars LOC0(n) and EXP0,F(n), and vice versa. It is contemplated that separation distance Dsep is on the order of the distance between platform 50e and cars in express train rear half EXP0,R. In any event, this separation distance Dsep is contemplated to be significantly smaller than separation distance Dtrv between trains passing in opposite directions on main tracks 52, 52w, as shown in
It is contemplated that the separation distance Dsep between adjacent trains LOC, EXP on one of main tracks 52 and its corresponding side track 54 can be significantly smaller than separation distance Dtrv between passing trains on main tracks 52, 54 because the relative speeds with which adjacent trains LOC, EXP are traveling in the same direction at the locations of side tracks 54 are at best quite slow. When trains LOC, EXP traveling in the same direction are adjacent to one another at the location of side track 54, one of the two trains (typically local train LOC) is necessarily stopped, and the other train (typically express train EXP) is either stopping, starting, or completely stopped itself. On the other hand, passing trains on main tracks 52e, 52w may be traveling at their full speeds when passing by one another, with their speeds relative to one another amounting to the sum of their individual instantaneous velocities (as they are passing in opposite directions). Accordingly, it is contemplated that station separation distance Dsep can be significantly smaller than passing separation distance Dtrv, enabling passenger transfer directly from train to train.
a through 5e illustrate the operation of subway line SLINE in connection with stops of express train EXP0 and local train LOC0 at express station Ex of the embodiment of the invention described above relative to
After the stop made by local train LOC0 at platform 50e in
It is useful at this point to consider the various passengers on board trains LOC0, EXP0 and other trains along subway line SLINE, with respect to their respective trips. Those passengers that board at a local station, remain on a local train throughout their trip, and exit at a local station will be referred to in this specification as “LLL” passengers (i.e., “local-local-local” passengers). Similarly, those passengers that board at an express station, remain on an express train throughout their trip, and exit at an express station will be referred to herein as “EEE” passengers (i.e., “express-express-express” passengers). In these embodiments of the invention in connection with side-by-side transfer, neither of the EEE or LLL passengers need make a transfer. Some passengers, however, will wish to take advantage of express train service even though embarking or disembarking at a local-only station. Those passengers who board at a local station, transfer at some point to an express train during their trip, and de-board at a local station, will be referred to herein as “LEL” passengers (i.e., “local-express-local” passengers). Other combinations are also possible, such as those passengers who board at an express station, travel at least one interval on an express train, but exit at a local station; these passengers will be referred to herein as “EEL” passengers (i.e., “express-express-local” passengers). “LEE” passengers of course board at a local station, transfer to an express train, and exit at an express station.
Referring again to
Once passenger transfer is completed, then express train EXP0 is allowed to leave express station Ex via main track 52e, while local train LOC0 remains stopped on side track 54e. This operation is illustrated in
As evident from
It is contemplated that the schedule generated by system 20 for local and express trains along subway line SLINE will in some way comprehend this limitation relative to the boarding and de-boarding of express trains EXP0, and transfers to and from local trains LOC. Of course, express trains EXP stopping at express station Ex may make two short stops: one stop with express train front half EXP0,F at platform 50e, and the second stop with express train rear half EXP0,R at platform 50e (indeed, one can contemplate a third stop, with express train rear half EXP0,R adjacent local train LOCo). However, it is contemplated that such multiple stops by express trains at each express station will add to the overall passenger travel time for both express and local passengers (especially considering that this additional time will occur at every express station), and is therefore disfavored.
Referring now to
The approach shown in
According to another embodiment of the invention, side track 56e is located on the “uptrack” side of platform 50e, to facilitate passenger movement as will now be described relative to
h illustrates the operation of express station Ex in serving stops for local train LOC0 and express train EXP0 in this embodiment of the invention. At the point in time shown in
In this embodiment of the invention, the efficiency of the stop at express station Ex for local train LOC0 is improved relative to that described above in connection with
In summary, the operation of express station Ex shown in
j and 5k illustrate the operation of the eastbound side of express station Ex with uptrack side track 56e in the case in which express train EXP0 is of twice the length of local train LOC0 and of platform 50e. In the state of operation shown in
In
This operation of subway line SLINE according to these embodiments of this invention can be further described in connection with the schematic views of subway line SLINE shown in
According to each of these embodiments of the invention, therefore, express train EXP0 can physically pass local train LOC0 at express station Ex, thus enabling express service over a single track on which local trains also operate. While flexibility in passenger movement is provided by these embodiments of the invention, it is useful for system 20 to assist passengers by way of at-station and on-train graphics displays instructing passengers regarding the portion of the train that they ought to board in order to carry out their desired transfers to and from express trains, for example in order to optimize travel to a particular destination station. It may be useful that such at-station and on-train displays illustrate visualizations of the entirety of subway line SLINE to show the approach and passing of local trains by express trains, to assist passenger understanding of this operation. Alternatively, or in addition, system 20 may also provide transfer and car assignment instructions in connection with point-to-point ticketing.
As evident in each of these embodiments of the invention, express station Ex is no wider (i.e., in the direction perpendicular to tracks 52) due to the presence of side tracks 54e or 56e, than that which is otherwise necessary to provide main tracks 52e, 52w and platforms 50e, 50w without side tracks. Accordingly, existing subway lines may be retrofitted by construction of side tracks 54 at its express stations, with much reduced excavation and construction costs than would be required to include conventional side tracks on opposite sides of the platform (as described above relative to
Local to Express Train “Transformation”
According to another embodiment of this invention, express and local subway trains traveling along the same two-track subway line SLINE are scheduled and operated to meet at express stations only, similarly as in the embodiments described above in which express trains physically pass the earlier-arriving local trains. According to this embodiment of the invention, however, express trains can be considered to “virtually” pass the local trains. This is accomplished by transforming individual trains from providing express service to providing local service, and vice versa, at express stations. In other words, the same physical train that provides local service over one interval between express stations is transformed to provide express service over the next interval between express stations; conversely, the same physical train that provides express service over one interval between express stations may be transformed to provide local service over the next interval between express stations.
In a general sense, according to this embodiment of the invention, a group of n trains (n≧2) traveling in the same direction arrive simultaneously at an express station along the two-track subway line SLINE. In this case, the earliest arriving train (or trains) will have been providing local service over the previous interval between express stations, and later arriving trains will have been providing express service over that interval, catching up to the local train at the express station according to the schedule. According to this embodiment of the invention, the last one or more of the express trains arriving at this express station (which, given the above description, mean the last one or more of the trains in this group of trains) provide local service over the next interval between express stations. The earliest arriving train (formerly providing local service) and perhaps one or more of the next-to-arrive trains at this express station provide express service over the next interval between express stations. Because of this transformation, the train that is providing local service is no longer at the head of the group of trains, but is at the tail—this local service train will not hold up the progress of the express trains that are now in front of it along subway line SLINE.
As evident from
In the example of
Meanwhile, train TRN3 leaves express station E0 at time t2, at which point it provides local service over the interval between stations E0 and E1. In doing so, train TRN3 travels at the slower local effective travel velocity Vloc, arriving at express station E1 at time t4, one time interval after train TRN2 arrived at express station E1. Over the next interval, between stations E1 and E2, train TRN3 transforms into an express train, traveling at express travel velocity Vexp, and arriving at express station E2 at time t5. Meanwhile, train TRN2 has provided local service, at effective local travel velocity Vloc, between express stations E1 and E2, reaching the next express station E2 at time t5. Because train TRN2 is ahead of train TRN3 on the track, train TRN3 essentially catches up to train TRN2 at express station E2, but cannot physically pass train TRN2. Instead, according to this embodiment of the invention, train TRN2 transforms into an express train at station E2, traveling at express travel velocity Vexp over the interval between express stations E2 and E3; train TRN3 transforms into a local train at station E2, providing local service over the interval between express stations E2 and E3 and traveling at local travel velocity Vloc.
The operation of trains TRN1, TRN2, TRN3 continues in this manner, along with those trains ahead of and following after these trains along subway line SLINE. In this example, each train traveling along two-track subway line SLINE alternates between providing local service and providing express service, from express interval to express interval. In effect, therefore, each train operates at a higher average travel velocity over the entire length of subway line SLINE, considering that each train does not make local stops over alternating express intervals (and may also travel at higher instantaneous velocities over those intervals, depending on the schedule and operator). The schedule generated and operated by the subway operator, for example through the use of system 20 and the process of
In the example of
As shown in
According to this embodiment of the invention, at express station E1 at time t=15 minutes, train T1 transforms from a local train into an express strain and train T2 transforms from an express train into a local train. As such, train T1 provides express service from express station E1, arriving at express station E2 at time t=20 minutes, and train T2 provides local service from express station E1, arriving at local station L2 at time t=20 minutes. Meanwhile, train T3 arrives at express station E1 at time t=20 minutes, having provided local service between express stations E0 and E1, immediately followed by train T4 which has been providing express service between express stations E0 and E1. Train T3 transforms into providing express service from express station E1, beginning at time t=20 minutes, and arrives at express station E2 at time t=25 minutes, immediately after train T2, which continued its local service from local station L2 until reaching express station E2 at that same time, but ahead of train T3. From this point forward, the sequence of operations essentially repeats (i.e., the status of trains T1, T2, T3 at time t=25 minutes matches that at time t=10 minutes).
This process of alternating between providing express service and providing local services continues over time, along two-track subway line SLINE, in this two-train group example. Each train alternates between providing express and local service in this manner, meeting up with the trains immediately ahead and behind at each express station, in the manner described above. As a result, each train travels at the higher effective express velocity (Vexp) for half of the express intervals, and at the slower effective local velocity (Vloc) for the other half of the express intervals. If the express intervals are of equal length, and if local velocity Vloc is one-half that of express velocity Vexp, then operation according to this two-train group approach provides a 25% reduction in the passenger travel time over subway line SLINE.
According to this embodiment of the invention, trains may transform according to more than two trains per “group”.
Train T7, which provided local service from express station E0, arrives at express station E1 at time t=25 minutes. Trains T8 and T9, which provided express service from express station E0, also arrive at express station E1 at that time, but remain behind train T7 on subway line SLINE. From express station E1, trains T7 and T8 provide express service, while trailing train T9 provides local service, stopping at local station L2 at time t=30 minutes, which in this example is the same time that trains T7 and T8 arrive at express station E2. Train T6, which provided local service from express station E1, also arrives at express station E2 at time t=30 minutes, at which time it transforms into providing express service along with train T7; train T8 provides local service from express station E2. The process continues in this manner, as shown in
In this example, each train travels at the effective express travel velocity Vexp for two out of every three express intervals, and travels at the effective local travel velocity Vloc over the third of those intervals. Under the assumptions of express intervals of equal length, and local velocity Vloc one-half that of express velocity Vexp, then operation according to this three-train group approach provides a 33% reduction in the passenger travel time over the length of subway line SLINE.
c illustrates the operation of subway line SLINE for the example in which the trains meet at express stations in groups of four, with the trailing train of that group providing local service over the next interval from express station. In this example, we will follow the group of four trains T6, T7, T8, T9, which leave express station E0 at time t=15 minutes. The trailing train T9 in this group provides local service over the interval from express station E0, stopping at local station L1 at time t=20 minutes, while trains T6, T7, T8 provide express service over that interval, arriving at express station E1 at time t=20 minutes. Train T5, having provided local service from express station E0, has arrived at express station E1 immediately prior to trains T6, T7, T8, at time t=20 minutes. As such, from the group of trains T5, T6, T7, T8 at express station E1 at time t=20 minutes, train T8 is the rear-most train of the group and thus will provide local service over the interval from express station E1, arriving at local station L2 at time t=25 minutes. Trains T5, T6, T7 all provide express service over this interval, arriving at express station E2 at time t=25 minutes, immediately after train T4. Meanwhile, train T9 continues at its local velocity, and arrives at express station E1 at time t=25 minutes.
This operation of trains T6, T7, T8, T9 and the other trains traveling along subway line SLINE at this time continues in this fashion. From time t=25, train T8 continues to provide local service and train T7 begins providing local service (from express station E2); meanwhile, trains T6 and T9 provide express service over their respective intervals. Eventually, at time t=40 minutes, the original group of four trains T6, T7, T8, T9 that we followed above from express station E0 arrive together again at express station E4, at time t=40 minutes, from which point the process repeats again, continuing over the length of subway line SLINE.
In this example, one train in every group of four trains is providing local service over an interval between express stations, while the other three trains are providing express service. With respect to a single train, each train operates at effective local travel velocity Vloc over every fourth interval between express stations, and operates at the effective express travel velocity Vexp over the other three intervals in that group of intervals. Under the assumptions of express intervals of equal length, and local velocity Vloc one-half that of express velocity Vexp, then operation according to this three-train group approach provides nearly a 40% reduction in the passenger travel time over the length of subway line SLINE.
In particular, it can be appreciated that the density of trains per unit distance along subway line SLINE can greatly decrease, for a given passenger throughput rate, through use of embodiments of this invention.
d illustrates a portion of subway line SLINE between express stations E0 and E6 in its conventional operation, in which every train operates as a local train. The distance intervals between the various express stations E0 through E6 are shown as uniform, for the sake of clarity; as discussed above, of course, this uniform interval is not a requirement in embodiments of this invention. In the case shown in
e shows subway line SLINE at a similar instant in time as that of
As described above, the subway operator can increase the density of trains to take further advantage of the improvement in efficiency, assuming that additional passenger demand is available. The snapshot of subway line SLINE shown in
Table 1 tabulates, for the trains in a given group, the intervals over which each train is providing express service and over which each train provides local service:
This Table 1 presumes that only one of the trains in a given group of trains provides local service, allowing the other trains in that group to operate at the faster effective express velocity Vexp. In each case, the last train in any group to leave any express station will provide local service over the next express interval; conversely, the first train to leave any express station will provide express service over the next express interval. In those cases in which the number of trains within a group is greater than two, optimum express service is attained by all trains in the group, except the last to leave the express station, providing express service over the next interval.
In each of the cases of
While the improvement in average train travel velocity increases as the number of trains per group increases, because a higher fraction of the trains are traveling at the faster express velocity Vexp than at the slower local velocity Vloc, the effective passenger travel time will decrease only if there are a sufficient number of passengers using the express service to support the number of express trains assigned. Accordingly, the selection of the number of trains assigned to each group depends on the relative passenger demand for express vs. local service. It is contemplated that system 20 of
a through 8c illustrate an optimum sequence by way of which trains may arrive at and depart an express station according to this embodiment of the invention. As evident from the foregoing description, train wait times constitute an important factor in the overall travel time of each passenger along subway line SLINE. According to this embodiment of the invention, in which a first train of a group arriving at an express station at the same time is transforming from local service to express service (such a train referred to herein as an “LE” train) while the last train in the same group of trains arriving at that express station is transforming from express service to local service (such a train referred to herein as an EL train), the later-arriving trains in the group can be forced to wait for the first train (the LE train) to leave the platform. Any time that elapses while the second and remaining trains are stopped at an express station short of the platform and waiting for the first train to leave is not only wasted travel time that lengthens the time of the overall trip, but is also annoyingly noticeable to the passengers on the stopped train. It is therefore beneficial to minimize such waiting time at the express stations.
a through 8c illustrate the operation of a three-train group, similar to that described above relative to
b illustrates a point in time later than that shown in
It is contemplated that system 20 can schedule and manage the velocities of trains T60, T62, T64 to optimize the efficiency of the stop of each train at platform 50. As such, the particular distances between trains T60, T62, T64 in this example shown in
If the later-arriving trains (trains T62, T64 in the example of
a illustrates an express interval along subway line SLINE between express stations E0 and E1. Local stations L1, L2, L3, L4 are located along this interval. At the point in time illustrated in
b illustrates a variation of this semi-express embodiment of the invention, for the case of a three-train group of trains T66, T68, T70 proceeding along the same interval. At the point in time shown in
c illustrates a similar example of semi-express operation, in connection with a four-train group. In this example, train T72 is the LE train, and has arrived at express station E1 after having provided local service along the interval. Train T74 is a train providing express service over the interval immediately following train T72, and will arrive at express station E1 just after train T72 has left. To more efficiently manage the arrival of train T74 at express station E1, train T74 has made one semi-express stop along the interval, at local station L4 in this example. Train T76 will be the next to arrive at express station E1 after train T74 and, in this case, will make one semi-express stop at station L3 (which is an earlier stop, west-to-east, along subway line SLINE than is station L4 at which train T74 makes a semi-express stop). Train T78 is the fourth train in this group, and will be the EL train at express station E1. Train T78 also makes a semi-express stop, at station L2 (which is earlier stop, west-to-east, than semi-express stations L3 and L4). Optionally, train T78 can make another semi-express stop along this interval, for example at local station L3, to further delay its arrival at express station E1 until after train T76 has left the station.
According to this embodiment of the invention, the addition of semi-express stops within an express interval provides additional flexibility in the scheduling of the arrival of express service trains at an express station. This additional flexibility enables productive use of any delay time involved in minimizing the wait time at an express station, by providing semi-express service at one or more stops along the express interval, thus providing both an additional train to passengers boarding at those stations, and in many cases providing a faster trip for those passengers to the next express station. It is contemplated that system 20 can incorporate such semi-express stops into the optimization that it carries out in connection with subway line SLINE, incorporating such factors as passenger demand and the like. In addition, the particular arrangement of semi-express stops can be altered from that shown in
Local to Express Train “Transformation” with “Passenger Relay”
In the embodiments of the invention described above, subway line SLINE and its express stations are operated in a first-in-first-out manner. In this approach, the first train of a group to arrive at an express station is the first to leave, making it impossible for a passenger to transfer from a later-arriving train in a group to an earlier-arriving train in that group. While benefits of this invention are still attained even with that complication, subway line SLINE and its trains can be operated in a manner that enables forward transfer of passengers in an efficient manner, according to other embodiments of this invention. As a result, not only can passengers more efficiently travel from any local station to any other local station, but as will become evident below, according to this embodiment of the invention, ambitious passengers are provided with the ability to travel nearly their entire trip at the faster express velocity, by making strategic forward-moving transfers at express stations.
According to these embodiments of the invention, the virtual passing provided by local to express train transformation, as described above in connection with
a through 10d illustrate the operation of trains T80, T82 in a two-train group, in making stops at platform 50 at express station Ex according to an embodiment of the invention in which passengers may make a forward train-to-train transfer. According to this embodiment of the invention, platform 50 is made accessible to passengers in the rear-most train of a group of trains before it is made accessible to the front-most train in that group. At the point in time shown in
For best efficiency, it is useful to control (or at least encourage) access to platform 50 during this initial stop so that only forward transfer passengers de-board rear-most train T82, and so that no passengers board or de-board front-most train T80.
Following the de-boarding by forward transfer passengers in
As shown in
e through 10g illustrate another implementation of this embodiment of the invention, in which the passenger relay is limited to a few forward cars of the arriving EL train, but in which passenger movement among the cars of a given train is permitted (and is physically possible, within the constraints of passenger loading within each train). With the constraint of intra-train passenger movement relaxed, the time required for passenger transfer and loading/unloading at express stations can be reduced.
Trains T80, T82 both back up after the operation of
Substantial time can be saved in the stops at express stations according to this implementation of
It is of course contemplated that variations on the manner in which the passenger relay process is enabled at each express station, including the number of rear-most cars to be aligned at each express station platform for a given passenger demand and train density, can vary from time-to-time during the day. Indeed, it is contemplated that the alignment of trains at express station platforms to permit passenger relay operations can be optimized by system 20 in its generation of the schedule and operational parameters within the overall process of
The passenger relay concept can be extended to train groups of more than two trains.
The operation of a stop at express station Ex for a two-train group of trains T90, T92 is illustrated in
In this approach illustrated in
d shows express station Ex at a first stage of the stop of LE train T90 and EL train T92, both of which have a length approximately of one-half the length of platform 50. In this first stage, train T90 occupies the front half of platform 50 and train T92 occupies the rear half of platform 50. At this time, as shown in
f illustrates another alternative to these two approaches, in which both transferring and relaying passengers move from train to train, allowing both the LE train and the EL train to make a single stop at express station Ex.
As discussed above, the number of trains per group can be increased during peak times, in order to improve passenger throughput and passenger travel times, without necessarily changing the schedule of local service, considering that local trains are the pacemakers along subway line SLINE. It is further contemplated that express service can be provided along subway line SLINE even if demand in off-peak times is very low, and it is further provided that transfers and passenger relay operation can be enabled even with that low passenger demand, as will now be described in connection with
In the alternative shown in
In each of these examples shown in
It is contemplated that system 20 will be able to comprehend the forward transfer option and processes, and to notify passengers of the option and the boarding (i.e., car assignment) and transfer procedures necessary to optimally use passenger relay for each passenger's specific journey. Graphics or video displays on the trains or at the stations can be driven by system 20 to advise passengers of these options and procedures, or system 20 can advise the passengers via the ticketing process (especially if point-to-point ticketing is used).
a through 13d show one example of the manner in which system 20 can communicate boarding and transfer instructions to passengers at a station of origin, and perhaps also at an express station at which a relay or express-to-local transfer is permitted. As shown in the plan view of
In addition, system 20 may alter the particular processes and stages implemented at the express stations from those described above in connection with
Regardless of whether the passengers make the forward transfers, because of the ability to travel at least part of the trip on subway line SLINE at express velocity Vexp, it is contemplated that the passenger travel time on subway line SLINE will be reduced for many, if not all, passengers according to this embodiment of the invention. It is also contemplated that the ability of system 20 according to this embodiment of the invention, in displaying schedules and train assignments, and perhaps individual tickets for specific station-to-station trips, can reduce confusion on the part of the subway passengers in navigating subway line SLINE, especially for commuting trips in which the passengers can become used to the best way to make their desired trips. Overall efficiency in the travel of many passengers, and in the utilization of the subway system including reduction in overcrowding by improving the passenger throughput, is therefore expected to be readily attained through use of this embodiment of the invention.
Schedule and Operational Optimization
Methodology
As described above relative to
A close relationship exists between a subway line system and the passenger volume on a given subway line, in that each depends on the other. The definition of a schedule for the subway line system, and particularly the optimization of that schedule, requires interacting the subway line system itself with the passenger volume on that line. Efficiency of the system in light of passenger demand is best served by defining applicable system parameters, and the characteristics of the passenger volume. According to embodiments of this invention, these parameters and characteristics can be analyzed in a manner corresponding to the following Table 2:
Table 2 summarizes performance characteristics for examples of embodiments of the invention described above. More specifically, the “Passing Technique” column groups the approaches of those methods into those in which express trains physically pass local trains at an express station, and those in which the passing is “virtual” in the sense that specific physical trains transform their service from local-to-express, and express-to-local, at express stations. The detailed description corresponding to each implementation is indicated by way of reference to its corresponding Figure or Figures. Various performance parameters for each individual implementation are shown in a normalized form, relative to conventional “local-only” service in which all trains on the subway line provide local service. In Table 2, the column “Trains per group” designates the number of trains in each group that meet at an express station; the column “Express trains per group” indicates the number of trains providing express service in each group, and each of these implementations assume a single local train in each group. The “Train length” column indicates the length of each train relative to a standard platform length. Based on those assumptions, the train density is indicated in the next column, referring to the number of trains physically present over each express interval.
Based on those assumptions, the remaining columns beginning with “Local train equivalent” are essentially calculated values. The column “Local train equivalent” is derived by considering the number of trains within an express interval are express trains (assumed to be traveling at twice the average travel velocity of a local train), in combination with the train density over an interval. In short, “Local train equivalent” is calculated as:
(Local train equivalent)=2+2*(Express trains per group)
This is because two local trains are present within each express interval at any given time. For example, a two-train group results in two local trains and one express train within an express interval at any given time; because the express train is traveling at twice the travel velocity as the local trains, the equivalent passenger capacity in terms of local-only trains is four. The column “Passenger throughput per train” reflects this same parameter in terms of the Local train equivalent divided by the Train density within the express interval.
The Theoretical passenger travel time savings column refers to the time that a passenger would save by virtue of the ability to travel at express travel velocities, relative to traveling via local-only service, and assuming no additional time required for physical or virtual passing at the express stations. For example, in two-train groups operated according to the physical passing technique, a passenger would be traveling at express travel velocity for the duration of his or her journey, in which case the travel time savings would be 50% (express travel velocity being twice local travel velocity). For two-train groups involving virtual passing (and no passenger relay), a passenger would be traveling at express travel velocity over alternating express intervals (i.e., about half the time), during which time his or her travel velocity would be twice that of the local travel velocity over the other intervals; this amounts to a 25% theoretical passenger travel time saving. And for two-train groups involving virtual passing with passenger relay, a passenger becomes able to travel at express velocities over the full duration of the journey, thus achieving the theoretical travel time saving of 50%.
It is contemplated that those skilled in the art can readily comprehend these performance criteria as summarized, by way of example, in Table 2. Among other conclusions, it can be seen from Table 2 that the physical passing techniques can theoretically attain a passenger travel time saving of 50%, as all express trains continue to provide express service, at express travel velocity, over the entire length of the journey. In addition, Table 2 summarizes that the passenger relay method applied to the virtual passing techniques can also attain this 50% theoretical passenger travel time saving. And as described above, the virtual passing techniques can be applied to existing subway lines, without requiring construction or excavation or other changes to infrastructure as necessary in the physical passing context.
As mentioned above, however, the theoretical passenger travel time saving assumes no time is involved in the passing operations at express stations. This is, of course, unrealistic for both the physical and virtual techniques, considering that time must be allotted for passenger transfer (local-to-express, and express-to-local). Table 2 includes the column “Passenger travel time saving”, which includes the effect of the delay time for passenger transfer at express stations, as will now be described.
As a concept, an understanding of the delay time required for passenger transfer is simple. However, it has been observed, in connection with this invention, that it is cumbersome to actually estimate this extra-train delay time (EDT) to any precision, because EDT depends on the passing method, on the number of trains in a group, and on other factors including train length relative to the platform length. More specifically, one must estimate the stop time for a local train at a local station (LSST), and the stop time for a local train at an express station (LEST); the difference between the local-train express-station stop time (LEST) and the average local train stop time (ALST) determined as the average local-train local-station stop time (LLST) over all of the express stations, which tends to be a stable quantity. The calculation of EDT differs between the physical passing and virtual passing methods. Under the physical passing case, in which local trains remain local and express trains remain express, the quantity LEST can be defined as the time elapsed between the arrival of the local train at the express station, and the departure time of that local train from the express station, assuming the number of trains per group exceeds one (i.e., at least one express train passes the local train at the express station). Under the virtual passing case, the quantity LEST is defined as the time elapsed from the LE train (i.e., the first train in the group) arriving at the express station and the departure of the EL train (i.e., the last train in the group). The quantity EDT for both cases is then defined as EDT=LEST−ALST.
Consistent with these definitions and based on the description of these passing methods in this specification, one can deduce that the quantity EDT will vary from one passing method to another, and also will vary with the length of the trains involved. Those variations in EDT will be reflected in the proximity of the “Passenger travel time saving” value to the “Theoretical passenger travel time saving” shown in Table 2 for the various operational methods. That proximity will result from the calculations of total passenger travel time over subway line SLINE, based on the schedules derived by system 20 in connection with scheduling process 38, as will now be described.
As described above, scheduling process 38 is executed by system 20 to derive and, if desired, modify the scheduling of trains along subway line SLINE in response to passenger data 33, train data 35, and station data 37, and according to the definition of certain stations and trains as express and local stations and trains, respectively. It is contemplated that scheduling process 38 will serve to optimize the derived and modified schedule according to a criteria selected by the subway system operator. It is further contemplated, according to this invention, that a particularly beneficial approach to scheduling process 38 is to optimize the schedule in order to minimize total passenger travel time over subway line SLINE. The passenger travel time being minimized may be that for a trip over the entire length of subway line SLINE, or alternatively may be a cumulative or average passenger travel time value taken over a typical population of passengers, or some other population. Fundamentally, this optimization of passenger travel time depends on a wide range of factors, including the particular passing method used (i.e., physical or virtual passing); the lengths of trains and platforms; the time of day; the type of day such as workday, weekend, or holiday; passenger demand by station; and the like. These additional factors are, in general, dependent on the characteristics of the subway system and the city being served, and as such can be considered as installation-dependent. For purposes of this description, however, it is believed useful to describe some of the factors involved in the optimization of the schedule from the standpoint of minimizing passenger travel time, as it is contemplated that this optimization will be an important goal of implementations of embodiments of this invention in practice.
For purposes of simplicity and clarity of this description, the above discussion summarized in the column “Theoretical passenger travel time savings” of Table 2 has been based on two assumptions: first, that the length of each train and the length of the platform at each station are each zero; and second, that all trains of a group arrive at and depart from each express station at the exact same time. In effect, the extra-train delay time (EDT) was assumed to be zero. Of course, in practice, those two assumptions do not hold.
In order for scheduling process 38 to actually minimize passenger travel time, according to embodiments of this invention, additional parameters are considered. For reference purposes, it is useful to consider the baseline operational times of a local-only train in traveling an express interval, including the time involved in making a stop at an express station. This local-only travel time (LETT) can be more accurately described as the difference between the time at which the local-only train arrives at express station Ec (e.g., the time at which the head car of this arriving eastbound train reaches the easternmost endpoint of platform 50e of
LEOT=LETT+ALST
This baseline local-only train operation time LEOT is also a factor in the operation of a group train according to embodiments of this invention described above, except that the group train express-station-interval operation time (GEOT) also requires consideration of the extra-train delay time (EDT) amounting to the additional delay time of a group train at an express station:
GEOT=LEOT+EDT
As mentioned above, EDT varies according to the passing method used, and also varies with the number of express trains within the group, such that EDT=EDT(m, j), where m refers to the passing method and j indicates the number of trains within a group. In any case, extra-train delay time EDT depends on such factors as the not-insignificant time required for the head of the train to move the length of the platform (the instantaneous velocity of the train being relatively slow, for safety reasons) and also the time required for the tail of a preceding train to clear the length of the platform as that train departs (the instantaneous velocity of that train also being relatively slow).
As discussed above, in the general sense, the local-only train operation time LEOT will spatially vary, being different for different express intervals:
LEOT1≠LEOT2≠LEOT3≠ . . .
An example of the spatial variation of train operational time for local-only trains, over six express intervals, is illustrated in
As evident from a comparison of
The above discussion uses average local station stop time ALST, which is constant over each express interval. However, in practice, it is contemplated that the local-only train stop time at each express station i (i.e., time LLSTi) will vary from express station to express station, because the time that a given train is stopped at a station in modern subway systems varies with the number of passengers boarding and de-boarding the train at that station. In short, the local-only train stop time LLSTi at express station Ei will vary with the time of day: longer during rush hours, and shorter during non-rush hours. Field observations from conventional subway lines indicate that the stop time of a local-only train at a station during rush hour can be several times longer than the stop time of the same train during non-rush hour. As such, proper determination of the average local station stop time ALST considers these spatial and temporal variations:
where τ is a variable corresponding to the time of day. In addition, it is also contemplated that the local-only travel time LETT may also vary with the time of day, as some extra-train delay time may occur at some local stations. The variation of these parameters with time of day r and among express intervals i is illustrated in
This variation of operational times with the time of day can be approached in various ways within scheduling process 38. For example, if the schedule is to be derived using operational times that are fixed (for scheduling purposes) over the day, then scheduling process 38 can be optimized by minimizing error FSOE(τ) defined by:
where the values
where the scheduled values GEOTi(τ) and TGOT(τ) as scheduled themselves vary with the time of day.
For example, if an average local-only stop time ALST(τ) is defined as that stop time at τ=8:00 am, then the error value FSOE(τ) evaluated at τ=8:00 am will be close to zero, but the error value FSOE(τ) evaluated at τ=11:00 am will be substantial. Conversely, if dynamic scheduling is used in scheduling process 38 to define the schedule at τ=8:00 am using the average local-only stop time ALST(τ=8:00 am), and to define the schedule at τ=11:00 am using the average local-only stop time ALST(τ=11:00 am), then the error DSOE(τ) will be much lower.
Scheduling process 38 can be further refined by applying a second dimension of temporal variation, considering the difference in passenger load from day-to-day. In other words, differences between normal workdays, weekends, and holidays, may be included within the optimization process, by considering parameter such as average local-only stop time ALST(τ,κ) to be defined not only with respect to time of day τ, but also with respect to day of the week (or month, or year, or both) κ.
The operation times described above refer to the train travel time along subway line SLINE. For the case of local-only train service, the passenger travel time is exactly the same as the train travel time. However, according to embodiments of this invention, the group train travel time is substantially longer than the passenger travel time for those passengers other than LLL passengers. According to the embodiments of this invention, one can consider the total passenger travel time TELP, for a passenger traveling on both local and express trains over subway line SLINE according to embodiments of this invention, to be:
T
ELP
=T
LT
+T
ETO
+PTO
where TLT is the total of the passenger travel times spent on local trains, where TET0 is the operation time of an express-service train within one of the train groups, and where PTO is the total extra train operation time involved in transferring passengers between local and express trains at an express station. But the travel time of the express train within a train group, over an express interval, according to embodiments of this invention is one-half that of the local-train travel time over that interval, namely LETT/2. Consequently, the express train operation time TET,i over express interval i can be defined as:
where GLSTi is the stop time of a local train in the group at the ith express station Ei, which amounts to the sum of the local-train stop time ALSTi and the extra-train delay time EDTi at that station.
One can then derive an express train travel time TETO from express station Ek to n stations down subway line SLINE from that station as:
This express train travel time TETO can then be used in the equation for total passenger travel time TELP, for a passenger traveling on both local and express trains over subway line SLINE according to embodiments of this invention. As such, the express station stop time GLSTi thus becomes incorporated into the express train travel time, which should simplify the analysis and optimization of passenger train travel time in scheduling process 38.
In addition, it has been discovered, in connection with this invention, that the characteristics of passenger travel time under the physical passing embodiments of this invention are different from those under the virtual passing embodiments of this invention. More specifically, for certain types of passengers, the total passenger travel time TELP under the virtual passing environment is shorter than that for passengers traveling via the physical passing embodiments of the invention. The local train is delayed at the express station in favor of the passing express train. In the case of the physical passing embodiments of this invention, the total passenger travel time TELP is expressed as:
T
ELP
=T
LT
+T
ETO
In addition, the local-train travel time TLT is a fixed value that is independent of the group train operation. Therefore, for purposes of optimization (i.e., minimization of passenger travel time), the only term of interest is the express interval travel time TETO. For EEE passengers (i.e., passengers with no local travel), the travel time TETO over n express intervals is expressed as:
where GLST is the stop time of a local train at an express station, taking place at each of the express stations encountered during the journey. For EEL or LEE passengers, who must make a local-to-express or express-to-local transfer at an express station, the travel time TETO over n express intervals is expressed as:
taking into account the extra instance of GLST for the local-to-express or express-to-local transfer. In this manner, the travel time TETO over n express intervals for LEL passengers amounts to:
taking into account the extra instance of GLST for the local-to-express or express-to-local transfer. Using analysis based on these considerations, it is contemplated that scheduling process 38 can accurately estimate passenger travel times, and apply those passenger travel times to the expected passenger volume along the subway line, including spatial and temporal variations in passenger volume as discussed above. That analysis can then be used in the optimization process as the schedule is derived, and modified in light of actual operational results.
As previously stated, the characteristics and calculation of extra-train delay time EDT differs between the physical passing and virtual passing methods. The extra-train delay time EDTP under the physical passing method is a function of the length LENGP of the platform at the express station, the length LENGT of the train stopping at that platform, the incoming train platform access time TPAT, and the departing train platform clearing time TPCT. For the case in which the train and platform are of the same length (LENGP=LENGT), the incoming train platform access time TPAT is defined as the time required for the head of an eastbound incoming train (for example) to travel from the east end of the platform to the west end. Similarly, the departing train platform clearing time TPCT is defined as the time required for the tail of a departing eastbound train (for example) to move from the east end of the platform to the west end. Of course, the times TPAT, TPCT are similarly defined for trains traveling in directions other than eastbound, relative to corresponding ends of the platform encountered.
For the physical passing method, the extra-train delay time EDTP is defined as:
EDTP=TPAT+TPCT+(j−1)*ALST
where j is the number of express trains within a group. In this case, referring to
For the virtual passing method, the extra-train delay time EDTV is defined as:
EDTV=j*ALST
again, where j is the number of express trains within a group. Under this method, no physical passing of trains occurs. Rather, an incoming train can arrive at the platform as soon as the tail of the departing train begins clearing the platform—there is no need for the arriving train to wait for the preceding train to clear the platform or track.
It has been observed, according to this invention, that the extra-train delay time EDT is not merely a concept—it is a real value, and can be estimated based on actual observed values of times TPAT, TPCT, ALST from existing local-only subway systems. For example, observations of the these times in the operation of various subway lines in Seoul, Korea on a selected workday are summarized in Table 3:
Line #9 is a four-track express and local train line, while lines #3 and #7 are two-track local-only subway lines. These observed measurements are the arithmetic mean of ten measurements each. In addition, it was observed that time ALST varies significantly with the time of day (τ).
Considering these factors, it has been observed that computation and minimization of passenger travel times under the virtual passing methods is substantially more complicated than according to the physical passing methods. This additional complication in the computation of the overall passenger travel time TELP according to the various virtual passing methods is because the passenger travel time is also a function of passenger travel patterns and of the number of express trains within a group of trains. For example, if an LEL passenger (traveling any number of express intervals via express service) follows a travel pattern that matches with the group train operation summarized in Table 1 above, then all LEL passengers aboard that pattern matching train can travel their entire journeys without any train transfers. These passengers can thus travel at the minimum passenger travel time TELP. For other passengers, the passenger travel time will vary not only with the factors discussed above, but can also vary according to which train within a given group that the passenger boards, the manner (and express station) at which passengers transfer between local and express service and thus the time involved in such transfers, and also the time involved in any passenger relay transfers. Indeed, in some systems, the passenger travel time can also vary according to which car within a given train is boarded by the passenger. However, modern computing systems such as system 20 are also contemplated to be fully capable of performing the appropriate calculations and optimizations, even in such relatively complex parameterization of the passenger travel time involved in the virtual passing methods, so long as the relevant parameters are measured, estimated, or otherwise provided.
It is also contemplated that other parameters and variables can enter into the determination of passenger travel times and the optimization of the schedules. For example, weather conditions above ground can affect passenger demand (e.g., more passengers travel by subway on rainy days than on sunny days, etc.); ticket pricing, special events, change in locations of businesses, and the like may also be taken into consideration. In this regard, it may be useful for system 20 to perform some sort of statistical analysis, such as analysis of variance and the like, to determine which parameters are of most importance in the optimization of passenger travel time, or such other parameters that are optimized in scheduling process 38.
Observations
The relative efficiencies of various approaches to the synchronized express and local trains, according to these embodiments of the invention, can thus be readily compared by system 20. For example, the embodiments of this invention utilizing side-tracks are expected to have a substantially different passenger transfer time than that of the virtual passing embodiments of this invention in which trains transform between providing express and local service. Of course, in those embodiments of the invention involving the transformation of trains between local and express service, the passenger travel time will be affected by the numbers of intervals that the passenger will be traveling at local travel velocities versus express travel velocities, the particular velocities of those intervals (see
In a general sense, based on qualitative analysis, it is contemplated that physical passing techniques will result in shorter passenger travel times than achievable by virtual passing techniques, for longer passenger journeys (in terms of the number of express intervals). Conversely, for shorter journeys, virtual passing techniques provide shorter passenger travel times. Of course, as mentioned above, the infrastructure cost of virtual passing techniques is much lower than that involved in enabling physical passing at express stations; in addition, greater flexibility is provided by the virtual passing techniques.
In this regard, analysis has shown, according to this invention, that for the embodiments of the invention in which a side track enables physical passing of local trains by express trains, as described above relative to
In addition, analysis has shown, according to this invention, that for these embodiments involving side-by-side transfers at express stations, that the express station passenger transfer time EDT is no longer for a four-train group of trains than it is for a three-train group of trains, but is substantially longer than (essentially twice as long as) the express station passenger transfer time EDT for two-train groups. In other words, the optimization cost for adding a fourth train to the number of trains in a group is relatively low. However, this analysis has shown that the express station passenger transfer time EDT involved for a five-train group of trains is much longer than that for a four-train group of trains, and should be avoided if at all possible.
In connection with the embodiments of this invention utilizing virtual passing at express stations, by way of transforming trains from providing local service to providing express service, and vice versa, analysis has shown that the express station passenger transfer time EDT can be minimized, and thus the overall passenger travel time minimized, also by selecting those stations at which the fewest number of passengers board and de-board express trains from outside of subway line SLINE as the express stations. In other words, use of the most lightly-used stations as express stations will optimize passenger travel times, for similar reasons as described above.
Also in connection with the embodiments of the invention in which virtual passing by transforming trains from local to express, and vice versa, overall passenger travel time can be minimized by maximizing the use of the express mode by as many passengers as possible, over as much of their respective trips as possible. One way in which this can be accomplished is the use of semi-express stations, such as described above relative to
Also in connection with the embodiments of the invention in which virtual passing by transforming trains from local to express, and vice versa, analysis has shown that maximization of the passenger express mode is improved by increasing the number of trains in a group, but at a cost of increased express station passenger transfer time EDT. A tradeoff therefore exists between the benefit of adding another train to the number of trains in a group, and this cost of increased time EDT. It has been found, through this analysis that, in many real-world cases, the use of three-train groups (two express trains for every local train) will be optimal, as it permits the greatest number of express passengers on the average without unduly lengthening the express station passenger transfer time EDT and thus the overall passenger travel time.
Other optimization techniques and concepts will become apparent to those skilled in the art having reference to this specification, upon applying embodiments of this invention to specific subway lines and systems, under real-world conditions.
Comparison of the various methods summarized in Table 2 above, and particularly the proximity with which the value in the column “Passenger travel time saving” approaches the value in the column “Theoretical passenger travel time saving”, can thus be made to determine the gains in efficiency obtained by the various methods and approaches. Of particular interest are the results of the shorter trains in the bottom-most rows of Table 2, corresponding to the virtual passing implementations described above in connection with
Also as evident in Table 2, the column labeled “Train group passenger throughput” contains values that vary among the various implementations. This value is defined, for purposes of Table 2, as the product of the number of trains per group with the average passenger throughput per train, and is normalized against the local-train only service of conventional two-track subway lines (1.0). This passenger throughput varies from a high of 6.4, for longer train groups of four trains (three of which are express trains) to a low of 0.25 for two-train groups with short trains (0.10 times the length of the platform). These variations in passenger throughput can be applied to variations in passenger demand over each day, week, and year.
In the examples considered in connection with Table 2 and as described above, a standard local-only headway is five minutes. To increase the throughput on such a local-only subway line with five minute headway by a factor of six, one must dispatch six local trains every five minutes. which amounts to a headway of about 0.833 minutes. In contrast, operation of a four-train group according to either of the physical or virtual passing techniques, this same throughput gain of 6.4 can be attained with a headway of 1.25 minutes, which is dramatically safer to operate. Of course, as mentioned above, the safety of such a system can be further increased by use of collision avoidance systems, electromagnetic braking, and other modern techniques.
Typically, most conventional existing local-only subway lines commonly operate with a standard dispatching interval of five to six minutes of headway, over the one-third of the working day deemed to be “rush hour”, at which peak passenger demand occurs. As mentioned above, to attain the factor-of-six throughput gain during such peak times, a local-only subway line must dispatch six times the number of trains (assuming the shortened headway is tolerable). In contrast, according to embodiments of this invention, this same throughput can be attained with fewer physical trains.
In addition, this throughput increase is also useful in off-peak times. Conventional train lines avoid unprofitable under-loading by reducing the frequency of service during off-peak times. Unfortunately, this has the effect of dramatically increasing passenger wait times at the stations, which makes subway travel less convenient and which thus often results in further reduction in passenger demand (and, conceivably, even further reductions in train frequency to compensate). In contrast, according to embodiments of the invention using the shorter trains, as summarized in the bottom-most rows of Table 2. As evident from those entries in Table 2, a group train with two shortened trains can effectively replace a single local-only train, while still providing nearly 50% reduction in passenger travel time. Indeed, it is contemplated that such short trains can be operated during most of the day on a vast majority of the two-track subway lines currently in use in the world, providing the advantages of reduced operating cost and reduced passenger travel time, while maintaining the same frequency of service as provided during peak times.
To efficiently manage these shortened train times, and indeed variations in train length over the day/week/year according to optimization determinations made by system 20 in light of passenger demand, it will be useful to implement modern coupling technologies in the trains, for example as currently in use in many airport trains and trams. Additional safety and operational technologies such as closed-circuit television monitoring and automated door opening and closing can provide further improvements in the overall flexibility and efficiency of operating a subway line while optimizing train length relative to passenger demand, in this manner.
It is further contemplated that modern and future transportation technologies such as collision avoidance systems and the like can be used to reduce train travel times, and thus passenger travel times. For example, the implementation of collision avoidance systems in the front and rear of each train can enable nearly bumper-to-bumper operation of subway line SLINE, as simultaneous or otherwise coordinated braking times can be enforced. Additional technologies such as electromagnetic track brakes and the like can also improve these train travel times by reducing braking times and distances.
In general, it is contemplated that the particular expressions and their evaluation, for optimization of such parameters as passenger travel time, throughput, infrastructure and rolling stock efficiency, and the like, can be readily derived and evaluated by system 20 for a given set of constraints or choices in the number and arrangement of stations, trains, and other infrastructure. It is also contemplated that statistical analysis of these parameters and their optimization based on passenger demand generally, passenger demand by time of day and day of the week, passenger demand by origin and destination station, and the like, can be incorporated into the optimization performed by system 20 in deriving, managing, and adjusting the subway schedule. It is also contemplated that those skilled in the art having reference to this specification will be readily able to carry out such optimization of passenger travel time, or optimization of other parameters important to the subway operator or its customers, without undue experimentation.
In any event, the embodiments of this invention described in this specification provide tremendous advantages in the construction and operation of subway train lines, particularly in urban areas for serving commuters and other passengers. These embodiments of this invention enable optimization of the operation of a two-track subway line, to provide improved passenger travel times and improved passenger throughput without requiring massive infrastructure costs, such as undue excavation and underground construction in building or rebuilding subway stations, or the construction costs of separate express rail lines. As a result, it is contemplated that the subway overcrowding now being experienced in many cities in the world can be reduced, at minimal additional expense. In addition, it is contemplated that these embodiments of the invention will provide great flexibility to the subway operator in scheduling and operating the subway lines, and flexible and beneficial options to many passengers in improving their travel experience. Furthermore, it is contemplated that feedback control and adjustment of the operation of the subway system will be enabled by application of these optimization techniques.
While this invention has been described according to its embodiments, it is of course contemplated that modifications of, and alternatives to, these embodiments, such modifications and alternatives obtaining the advantages and benefits of this invention, will be apparent to those of ordinary skill in the art having reference to this specification and its drawings. It is contemplated that such modifications and alternatives are within the scope of this invention as subsequently claimed herein.