Route capacity is the maximum number of vehicles, people, or amount of freight than can travel a given route in a given amount of time, usually an hour. It may be limited by the worst bottleneck in the system, [1] such as a stretch of road with fewer lanes. [2] Air traffic route capacity is affected by weather. [3] For a metro or a light rail system, route capacity is generally the capacity of each vehicle, times the number of vehicles per train, times the number of trains per hour (tph). In this way, route capacity is highly dependent on headway. Beyond this mathematical theory, capacity may be influenced by other factors such as slow zones, single-tracked areas, and infrastructure limitations, e.g. to useful train lengths.
Any assessment of the effectiveness of a transport network includes a calculation of what capacity is used, how it is used, and whether it is used effectively. For instance, overloaded routes may need to be upgraded, or capacity provided by other routes. Unused capacity can represent an opportunity to move more people or goods: as the capacity exists no additional investment is needed. [4] Many transport networks have unused capacity.
External factors affect route capacity in different ways. Severely overcrowded highways will reduce the capacity of bus services. Severe snowfalls will reduce the capacity of highways and freeways, and high winds will make landing and departing airports difficult. In many cases route capacity will vary day to day depending on external factors. Rail systems are more rarely affected by external factors.
Routes can become congested where only a fraction of routes can accept certain traffic types. For example, a road may have a low bridge that restricts the height of any trucks (lorries), or a rail line may be unable to accept wagons loaded beyond a certain axle load. This will result in any route that can accept a wider range of vehicles being congested, and other more restrictive routes be underutilised. Rail traffic between the US and Mexico is limited by the types of vehicles, especially grain wagons, and as 2009 the only routes that could accept newer rail wagons passed through Texas. [5]
Bottlenecks play a large role in determining route capacity. Along any route the capacity is limited to the point with the lowest capacity, and long routes may have their capacity compromised by one bottleneck. Where more vehicles enter a route than a single bottleneck can accept, then the route will be free of congestion at all points except at the bottleneck. For this reason bottlenecks are often the focus of transport improvement projects.
Route capacity is often calculated and applied in the management and design of rail systems. For railways with very high passenger loads, the maximum possible route capacity is an important factor. A common unit for route capacity is people per hour (pph), which can for metro style systems can be as high as 80,000.[ citation needed ] Route capacity can also be expressed as number of vehicles per hour, such as 16 trains per hour (tph). [6] Route capacities in rail lines with two tracks are almost always the same in either direction.
The maximum speed or average speed of rail traffic will have no impact on the route capacity where all train services are of the same type, and the stopping patterns are the same.[ citation needed ] Whilst slower trains will mean passengers take longer to reach their destination, the number of trains moving past a specific point will remain the same.[ citation needed ] Route capacity at a particular period of time can be observed by an observer standing on a station platform. A slower rail system will require more rolling stock to maintain a high throughput of trains. [7] The speed of traffic will affect the required headway between trains (it is not simply proportional to the speed) and will thus affect the route capacity.
In calculating route capacity it is important to consider practical considerations. [8] [9] Many railways will wish to operate at the maximum capacity for hours on any given day, and the theoretical capacity is not sustainable for more than a few trains.[ clarification needed ] A reduced level of capacity, which can be maintained for hours, is often calculated. [10] A railway that operates at close to the level of theoretical capacity for extended periods will have lower punctuality (fewer trains arriving when timetabled). [11]
Route capacity depends on the number of passengers using a system, if only because this will affect the length of station stops. Much of the route capacity in an existing rail system will be used for existing timetabled rail movements. This is described as used capacity. [12] What capacity remains to be allocated to additional trains is called available capacity. [13]
Increasing route capacity for a rail system requires substantial investment in infrastructure. Increasing route capacity for a railway from, for example, 12 trains per hour, to 20 per hour, can be a very substantial project requiring substantial budgets.
Rail capacity is often less affected by the weather than route capacity for aircraft. However it can be affected by e.g. snow blocking the line, or by buckled rails at high temperatures.
There are two main methods of calculating route capacity; using the method outlined in UIC 406, and by using headways. The International Union of Railways produces documents on a variety of rail related topics, and published a leaflet on rail capacity. This leaflet provides a method of calculating route capacity based on the creation of paths through a rail route. The number of paths for a "standard" train is created, and then the train paths added. The total number of trains that can potentially enter the route, and leave it, as well as the actual number, can then be determined. [14]
The classic formula for the calculation of a route capacity from a headway is:
(1) |
For example, a headway of 4 minutes (= 4/60 hours) translates into a route capacity of 15 trains per hour.
Route capacity is maximised for any rail system when all the rail traffic is the same type. Mixing different types of trains, or even different stopping patterns, will result in a substantial reduction of capacity. [15] Where different types of trains are mixed together this is sometimes called heterogeneity. [16] In this context different types of trains means those that are slower than other trains, for example, freight and passenger trains. Freight trains often accelerate and brake more slowly than passenger, and have lower top speeds. Also passenger trains that have different stopping patterns, such as a local all stops service, when mixed with a limited or express service, will result in a reduction of route capacity. Route capacity is not lost where all the trains on one route stop at all stations, but only where trains with different stopping patterns are mixed together.
Rail systems vary greatly in performance and route capacity, with metro systems having the highest capacity. Tram and light rail systems have in theory very high route capacities, but in practice many systems only achieve route capacities of 12 vehicles per hour. That said, Swanston Street in Melbourne achieves 50 trams per hour during the morning peak, an average of 72 seconds per tram. [17] For High Speed Rail a route capacity of up to 18 trains per hour may be possible. [18] In 1932 Sydney introduced a signalling system theoretically capable of 42 trains per hour (about every 85 seconds), but in practice only achieved 36 trains per hour during testing in the 50s. [19] In modern times, Punggol metro line in Singapore uses a moving block system to achieve a headway of 90 seconds, so the route capacity is 40 trains per hour. [20] The Moscow Metro achieves 40 trains an hour as well, additionally it has aimed to achieve 50 trains an hour in the future (a train every 72 seconds). Route capacity for a commuter rail system is typically around 12 to 16 trains per hour, which is lower than a metro, as the trains are longer, and the traffic is often mixed with other rail services such as freight and intercity trains. By contrast the Alameda Freight Corridor in Los Angeles has a route capacity of 150 freight trains per day, [21] which is high in comparison to other rail freight systems, but low compared to metros.
The route capacity of freight rail systems is often limited by the terminal to which the freight is heading. Large terminals will be able to accept more freight trains, but a route capacity of 15 freight trains per hour would be very unusual.
Stations in a railway system, and where train are required to stop to pick up or drop off passengers, serves to reduce the route capacity. This is particularly the case where trains of different stopping patterns are moving one after another through a rail system. Dwell time is the time taken from the opening of train doors at a station, to their closing again. Dwell times strongly influence route capacity in a rail system.
Many rail systems use a fixed block system for signalling. Moving block represents a new type of signalling that allows the reduction of headways, and an improvement of route capacity. [22] Moving block is a signalling principle that exists within a signalling system called automatic train protection. Many technical problems exist with the construction of any rail line that supports moving block, as this type of signalling system requires constant communication between signalling systems and trains, which is often achieved with a train radio system (but can be achieved other ways). Another problem is the signalling system needs to know the length of any train at all times, and so an engineering system is needed on all trains that can detect all carriages and wagons within the train.
Rail transport is a means of transport using wheeled vehicles running in tracks, which usually consist of two parallel steel rails. Rail transport is one of the two primary means of land transport, next to road transport. It is used for about 8% of passenger and freight transport globally, thanks to its energy efficiency and potentially high speed.
A train is a series of connected vehicles that run along a railway track and transport people or freight. Trains are typically pulled or pushed by locomotives, though some are self-propelled, such as multiple units or railcars. Passengers and cargo are carried in railroad cars, also known as wagons or carriages. Trains are designed to a certain gauge, or distance between rails. Most trains operate on steel tracks with steel wheels, the low friction of which makes them more efficient than other forms of transport. Many countries use rail transport.
Personal rapid transit (PRT), also referred to as podcars or guided/railed taxis, is a public transport mode featuring a network of specially built guideways on which ride small automated vehicles that carry few passengers per vehicle. PRT is a type of automated guideway transit (AGT), a class of system which also includes larger vehicles all the way to small subway systems. In terms of routing, it tends towards personal public transport systems.
Light rail is a form of passenger urban rail transit that uses rolling stock derived from tram technology while also having some features from heavy rapid transit.
The West Coast Main Line (WCML) is one of the most important railway corridors in the United Kingdom, connecting the major cities of London and Glasgow with branches to Birmingham, Manchester, Liverpool and Edinburgh. It is one of the busiest mixed-traffic railway routes in Europe, carrying a mixture of intercity rail, regional rail, commuter rail and rail freight traffic. The core route of the WCML runs from London to Glasgow for 400 miles (644 km) and was opened from 1837 to 1881. With additional lines deviating to Northampton, Birmingham, Manchester, Liverpool and Edinburgh, this totals a route mileage of 700 miles (1,127 km). The Glasgow–Edinburgh via Carstairs line connects the WCML to Edinburgh. However, the main London–Edinburgh route is the East Coast Main Line. Several sections of the WCML form part of the suburban railway systems in London, Coventry, Birmingham, Manchester, Liverpool and Glasgow, with many more smaller commuter stations, as well as providing links to more rural towns.
Bus rapid transit (BRT), also referred to as a busway or transitway, is a trolleybus, electric bus and public transport bus service system designed to have much more capacity, reliability, and other quality features than a conventional bus system. Typically, a BRT system includes roadways that are dedicated to buses, and gives priority to buses at intersections where buses may interact with other traffic; alongside design features to reduce delays caused by passengers boarding or leaving buses, or paying fares. BRT aims to combine the capacity and speed of a light rail transit (LRT) or mass rapid transit (MRT) system with the flexibility, lower cost and simplicity of a bus system.
The Train Protection & Warning System (TPWS) is a train protection system used throughout the British passenger main-line railway network, and in Victoria, Australia.
Skip-stop is a public transit service pattern which reduces travel times and increases capacity by having vehicles skip certain stops along a route. Originating in rapid transit systems, skip-stop may be also used in light rail and bus systems.
Urban rail transit is a wide term for various types of local rail systems providing passenger service within and around urban or suburban areas. The set of urban rail systems can be roughly subdivided into the following categories, which sometimes overlap because some systems or lines have aspects of multiple types.
Various terms are used for passenger railway lines and equipment; the usage of these terms differs substantially between areas:
The A Line is a light rail line in Los Angeles County, California. It is one of the six lines of the Los Angeles Metro Rail system, operated by the Los Angeles County Metropolitan Transportation Authority (Metro). The A Line serves 44 stations and runs east-west between Azusa and Pasadena, then north-south between Pasadena and Long Beach, interlining and sharing five stations with the E Line in Downtown Los Angeles. It operates for approximately 19 hours per day with headways of up to 8 minutes during peak hours. It runs for 48.5 miles (78.1 km), making it the world's longest light rail line since 2023.
Headway is the distance or duration between vehicles in a transit system. The minimum headway is the shortest such distance or time achievable by a system without a reduction in the speed of vehicles. The precise definition varies depending on the application, but it is most commonly measured as the distance from the tip of one vehicle to the tip of the next one behind it. It can be expressed as the distance between vehicles, or as time it will take for the trailing vehicle to cover that distance. A "shorter" headway signifies closer spacing between the vehicles. Airplanes operate with headways measured in hours or days, freight trains and commuter rail systems might have headways measured in parts of an hour, metro and light rail systems operate with headways on the order of 90 seconds to 20 minutes, and vehicles on a freeway can have as little as 2 seconds headway between them.
In public transportation, schedule adherence or on-time performance refers to the level of success of the service remaining on the published schedule. On time performance, sometimes referred to as on time running, is normally expressed as a percentage, with a higher percentage meaning more vehicles are on time. The level of on time performance for many transport systems is a very important measure of the effectiveness of the system.
The Follo Line is a 22-kilometre (14 mi) high-speed railway between Oslo and Ski, Norway.
A passenger train is a train used to transport people along a railroad line, as opposed to a freight train that carries goods. These trains may consist of unpowered passenger railroad cars hauled by one or more locomotives, or may be self-propelled; self propelled passenger trains are known as multiple units or railcars. Passenger trains stop at stations or depots, where passengers may board and disembark. In most cases, passenger trains operate on a fixed schedule and have priority over freight trains.
Passengers per hour per direction (p/h/d), passengers per hour in peak direction (pphpd) or corridor capacity is a measure of the route capacity of a rapid transit or public transport system.
Railway electrification in Iran describes the past and present electrification systems used to supply traction current to rail transport in Iran with a chronological record of development, a list of lines using each system, and a history and a technical description of each system.
In railway signalling, a moving block is a signalling block system where the blocks are defined in real time by computers as safe zones around each train. This requires both knowledge of the exact location and speed of all trains at any given time, and continual communication between the central signalling system and the train's cab signalling system. Moving block allows trains to run closer together while maintaining required safety margins, thereby increasing the line's overall capacity. It may be contrasted with fixed block signalling systems.
Communications-based train control (CBTC) is a railway signaling system that uses telecommunications between the train and track equipment for traffic management and infrastructure control. CBTC allows a train's position to be known more accurately than with traditional signaling systems. This can make railway traffic management safer and more efficient. Rapid transit system are able to reduce headways while maintaining or even improving safety.
A crush load is a level of passenger loading in a transport vehicle which is so high that passengers are "crushed" against one another. It represents an extreme form of passenger loading, and normally considered to be representative of a system with serious capacity limitations. Crush loads result from too many passengers within a vehicle designed for a much smaller number. Crush loaded trains or buses are so heavily loaded that for most passengers physical contact with several other nearby passengers is impossible to avoid.