The opening of London's steam-powered Metropolitan Railway in 1863 marked the beginning of rapid transit. Initial experiences with steam engines, despite the ventilation, were unpleasant. Experiments with pneumatic railways failed to achieve widespread adoption by cities. Electric traction was more efficient, faster and cleaner than steam and the natural choice for trains running through tunnels and proved superior for elevated services.

In 1890, the City & South London Railway was the first electric-powered rapid transit railway, which was also completely underground.[8] Prior to opening, the line would be called the "City and South London Subway", thus introducing the term Subway into railway terminology.[9] Both railways, along with others, eventually merged into the London Underground. The Liverpool Overhead Railway of 1893 was designed to use electric traction from the beginning.[10]​.

The technology spread quickly to other cities in Europe, the United States, Argentina and Canada, and some railways were converted from steam and others were designed to be electric from the beginning. Budapest, Chicago, Glasgow and New York City, all converted or specially designed and built electric rail services.[11]​.

Advances in technology have enabled new automated services. Hybrid solutions have also evolved, such as tram-train and pre-metro, which incorporate some of the features of rapid transit systems.[8]​ In response to cost, engineering considerations and topological challenges, some cities have chosen to build tram systems, particularly in Australia, where density in cities was low and suburbs tended to spread.[12]​ Since the 1970s, the viability of underground rail systems in Australian cities, particularly Sydney, has been increasing. and Melbourne, has been reconsidered and proposed as a solution to excess capacity. The first Sydney Metro line, Australia's first rapid transit system, opened in 2019.[13]​.

Since the 1960s, many new systems have been introduced in Europe, Asia, and Latin America.[14]​ In the 20th century, the majority of new expansions and systems are located in Asia, with China becoming the world leader in metro expansion, operating some of the largest and busiest systems while having nearly 60 cities that are operating, building, or planning a rapid transit system.[15]​[16]​.

Contenido

El transporte rápido se utiliza para el transporte local en ciudades , aglomeraciones y áreas metropolitanas para transportar a un gran número de personas, a menudo distancias cortas y con alta frecuencia . El alcance del sistema de tránsito rápido varía mucho entre ciudades, con varias estrategias de transporte.

Algunos sistemas pueden extenderse sólo hasta los límites del centro de la ciudad o hasta su anillo interior de suburbios con trenes que hacen paradas frecuentes en las estaciones. A los suburbios exteriores se puede llegar mediante una red de trenes de cercanías separada , donde las estaciones más espaciadas permiten velocidades más altas. En algunos casos, las diferencias entre el transporte rápido urbano y los sistemas suburbanos no están claras.

Los sistemas de tránsito rápido pueden complementarse con otros sistemas como trolebuses , autobuses regulares , tranvías o trenes de cercanías. Esta combinación de modos de tránsito sirve para compensar ciertas limitaciones del tránsito rápido, como paradas limitadas y largas distancias a pie entre puntos de acceso externos. Los sistemas de alimentación de autobuses o tranvías transportan a las personas a paradas de tránsito rápido.

Lines

Each rapid transit system consists of one or more lines or circuits. Each line has at least one specific route and trains stop at all or some of the stations on the line. Most systems operate multiple routes and distinguish them by colors, names, numbering, or a combination of these. Some lines may share tracks with each other for a portion of their route or operate solely on their own right-of-way. Often, a line through the city center branches into two or more branches in the suburbs, allowing for greater frequency of service downtown. This arrangement is used by many systems, such as the Copenhagen Metro, Milan Metro, Oslo Metro, Istanbul Metro, and New York City Subway.

Alternatively, there may be a single central terminal (often shared with the central railway station) or multiple interchange stations between lines in the city centre, for example on the Prague Metro. The London Underground and Paris Metro are densely built systems with a matrix of lines crisscrossing throughout cities. Chicago's 'L' has most of its lines converging on The Loop, the main business, financial and cultural area. Some systems have a circular line around the city center that connects with radially arranged outer lines, such as the Moscow Metro's Koltsevaya Line and Beijing Metro's Line 10.

The capacity of a line is obtained by multiplying the capacity of the cars, the length of the train and the frequency of the service. Heavy rapid transit trains may have six to twelve cars, while lighter systems may use four or fewer. The carriages have a capacity of 100 to 150 passengers, which varies according to the proportion of people sitting and standing: the more standing, the greater the capacity. The minimum time interval between trains is shorter for rapid transit than for mainline railroads due to the use of communications-based train control: the minimum interval can be as high as 90 seconds, but many systems typically use 120 seconds to allow for delay recovery. Typical capacity lines allow 1,200 people per train, which is 36,000 passengers per hour in each direction. However, much higher capacities are achieved in East Asia, with ranges of 75,000 to 85,000 people per hour achieved by MTR Corporation's urban lines in Hong Kong.

Network Topologies

Metro topologies are determined by a host of factors, including geographic barriers, existing or expected travel patterns, construction costs, policies, and historical limitations. A metro system is expected to serve an area of ​​land with a set of lines, consisting of shapes summarized as "I", "L", "U", "S" and "O" shapes or loops. Geographic barriers can cause critical points where transportation lines must converge (for example, to cross a body of water), which are potential sites of congestion but also offer an opportunity for transfers between lines. The circle lines provide good coverage, connecting between the radial lines and serving tangential journeys that would otherwise have to cross the typically congested core of the network. A rough grid pattern can offer a wide variety of routes while maintaining a reasonable speed and frequency of service.[17] A study of the world's 15 largest subway systems suggested a universal shape composed of a dense core from which branches radiate. [18]​.

Passenger information

Rapid transport operators tend to create solid brands, focused on their easy identification in the urban fabric and the desire to transmit speed, safety and authority.

A transit map is a topological map or schematic diagram used to show the routes and stations of a public transportation system. Its main components are color-coded lines to indicate each line or service, with named icons to indicate stations. Maps can show only rapid transit or include other forms of public transportation as well. Transit maps can be found on transit vehicles, on platforms and at station entrances, as well as on operators' websites. These help users understand the connections between different parts of the system; For example, they show interchange stations where passengers can transfer between lines. Unlike conventional maps, transit maps are usually not geographically precise, but instead emphasize connections between different stations. The graphical presentation can use straight lines and fixed angles, and often a fixed distance between stations, to simplify the visualization of the transportation network. This generally has the effect of compressing the distance between stations in the outer area of ​​the system and widening the distances between those near the center. In very touristy cities, it is common to see the main monuments reflected on maps, for easy identification by the tourist.

Some systems assign unique alphanumeric codes to each of their stations to help travelers identify them, briefly encoding information about the line you are on and your position on the line. For example, on the Singapore MRT, the Changi Airport MRT station has the alphanumeric code CG2, indicating its position as the second station on the Changi Airport branch of the East West Line. The Seoul Metro, on the other hand, uses only numbers. According to the line number, for example, Sinyongsan Station, it has station code 429. Being on Line 4, the first number is 4. The last 2 numbers are the station number on that line. Even so, this code is not unique since exchange stations usually have as many identifiers as lines. Thus, the Raffles Place MRT station, where the North South and East West lines meet, has two codes, NS26 and EW14. On other occasions, the identification system is independent of the line, thus allowing the stations to be numbered with a unique code for each one. like the Melbourne tram").

With the widespread use of the Internet and mobile phones around the world, transportation operators now use these technologies to present information to their users. In addition to online maps and schedules, some transportation operators offer real-time information that allows passengers to know when the next vehicle will arrive and expected travel times. The GTFS data format, standardized for transit information, allows many third-party software developers to produce web and smartphone application programs that provide passengers with personalized updates about specific transit lines and stations of interest.[17]​.

Safety and security

Rapid transit operators have often built strong brands, often focused on easy recognition (to enable quick identification even across the wide range of signs found in large cities), combined with a desire to communicate speed, safety and authority. In many cities there is a single corporate image for the entire transit authority, but rapid transit uses its own logo that adapts to the profile.

La mayoría de los trenes de ferrocarriles metropolitanos son de unidades de tren eléctricas, con longitudes de dos a más de diez coches. La electricidad para las motorizaciones eléctricas es provista por un tercer carril "Tercer riel (alimentación)") o catenaria "Catenaria (ferrocarril)"). Otro sistema de propulsión en algunos trenes es el motor lineal.

La mayoría circulan en vías férreas de acero convencionales, aunque algunos utilizan neumáticos de goma, como el Metro de Montreal. Los neumáticos de goma posibilitan circular por pendientes empinadas, pero generan mucho ruido, tienen mayores costes de mantenimiento y son menos eficientes energéticamente. También pierden la fricción cuando las condiciones climáticas son húmedas o heladas, estando limitado su uso en superficie en el Metro de Montreal.

El tamaño de la tripulación ha disminuido a través de la historia con algunos sistemas modernos con plena operación automática del tren (ATO) (como los sistemas VAL, SAET, el sistema de AnsaldoBreda o el SelTrac) que permiten el funcionamiento del tren sin conductor. Algunas redes que utilizan este sistema son el Metro de Copenhague, el Metro de Rennes, el Docklands Light Railway de Londres, las líneas 1 "Línea 1 (Metro de París)") y 14 "Línea 14 (Metro de París)") del Metro de París, las líneas 9, 10 y 11 del Metro de Barcelona, las líneas 4 "Línea 4 (Metro de São Paulo)"), 6 "Línea 6 (Metro de São Paulo)"), 15 "Línea 15 (Metro de São Paulo)") y 17 "Línea 17 (Metro de São Paulo)") del Metro de Sao Paulo y las líneas 3 y 6 del Metro de Santiago de Chile. Otros trenes siguen teniendo conductores, aun cuando su único papel es abrir y cerrar las puertas de los trenes en las estaciones, como el Tren Urbano de San Juan y el Metro de Santiago de Chile.

En algunos sistemas metropolitanos se utiliza el esquema de medición neta, como en el caso de España, para no derrochar electricidad.

La red del Metro de Tokio se compone de 13 líneas, sin incluir la red de trenes urbanos y suburbanos (cercanías) de Japan Railways (JR), entre la que vale destacar la línea Yamanote, la vía férrea de mayor tráfico y comunica los 23 distritos especiales de la urbe.

Trains

Most rapid transit trains are electric multiple units with lengths from three to more than ten cars.[19] Crew sizes have decreased throughout history, with some modern systems now running unmanned trains.[20] Other trains continue to have drivers, although their only role in normal operation is to open and close train doors at stations. Power is commonly delivered by third rail or overhead cables. The entire London Underground network uses the fourth rail and others use the linear motor for propulsion.[21]​.

Some urban railway lines are built with a loading gauge as large as that of the main railway lines; others are built to be smaller and have tunnels that restrict the size and sometimes the shape of the train compartments. An example is the London Underground, which has acquired the informal term "tube train" due to the cylindrical shape of its cabin.

In some cities, suburban rail networks consist of lines that operate different sizes and types of vehicles. Although these subnetworks are not usually connected by track, where necessary, rolling stock with a smaller loading gauge from one subnetwork can be transported along other lines that use larger trains.

Sometimes pneumatic rolling is used for uneven routes or continuous slopes, such as 10 of the 12 lines of the Mexico City Metro, or some of the Paris metro.

Tracks

Most rapid transit systems use standard gauge conventional railway tracks. Since underground tunnel tracks are not exposed to rain, snow, or other forms of precipitation, they are often fixed directly to the ground rather than resting on ballast, like normal train tracks.

driving force

Although initially the trains of what is now the London Underground were pulled by steam engines, virtually all tube trains, both now and historically, use electrical power and are built to operate as multiple units. Train power, known as traction power, generally takes one of two forms: an overhead line, suspended from poles or towers along the track or from tunnel structures or roofs, or a third rail mounted at track level and in contact with a sliding cable.

The practice of sending power via rails in the ground is primarily due to the limited overhead clearance of tunnels, which physically precludes the use of overhead cables. The use of overhead cables allows higher power supply voltages to be used. Although overhead cables are more likely to be used in subway systems without many tunnels, an example of which is the Shanghai Metro, overhead cables are used in some systems that are predominantly underground, such as in Barcelona, ​​Fukuoka, Hong Kong, Madrid and Shijiazhuang. Both overhead cable and third rail systems generally use the rails as the return conductor, but some systems use a separate fourth rail for this purpose. There are transit lines that make use of both rail and air power, with vehicles that can switch between the two, such as the Blue Line "Blue Line (Boston Subway)") in Boston.

Tunnels

Underground tunnels move traffic away from street level, avoiding delays caused by traffic congestion and leaving more land available for buildings and other uses. In areas of high land prices and dense land use, tunnels may be the only economical route for mass transportation. Cut and cover tunnels are built by excavating city streets, which are then rebuilt over the tunnel; Alternatively, tunnel boring machines can be used to excavate deep tunnels that lie lower in the bedrock. [28].

Construction of an underground subway is an expensive project and often takes place over several years. There are several different methods for building underground lines.

The world's deepest subway system was built in St. Petersburg, Russia, where in the swampy area, stable ground begins more than 50 meters (160 feet) deep.

Elevated railways

Elevated railroads are a cheaper and easier way to build an exclusive right-of-way without digging costly tunnels or creating barriers. Besides street-level railways, they may also be the only other feasible alternative due to considerations such as a high water table near the city surface increasing the cost or even preventing underground railways (e.g. Miami). Elevated guides were popular at the turn of the century, but fell out of favor; They came back into fashion in the last quarter century, often in combination with ductless systems. In the Santiago de Chile metro, parts of line 2 (inaugurated in 1978); line 5 (inaugurated in 1997); line 4 (inaugurated in 2005-06); and expansion of line 5 (inaugurated in 2011), have elevated tracks.

Variations

However, not all cities in the world can count on this type of transportation; in cities with weak soil (lack of consistency) and located in seismic zones, its cost would rise by almost 300% of what it would cost to build this in another city. The case of the Seville metro, because the water table was too high in addition to the type of marsh terrain, also represented an added technical difficulty.

Although there are urban railways whose route runs totally or partially on the surface, such as that of Maracaibo, the concept of "metro" is generally associated with underground railways, a solution that was progressively adopted by cities that had not originally adopted it, due to several reasons, among which may be the superiority in the order of aesthetic and environmental quality of the underground route, as well as the lack of available land or the cost of land in large cities.[22]​.

When the subway circulates under the open sky, the tracks are generally placed on metal or concrete platforms elevated about four or five meters above the ground,[23] so that the subway does not interfere with street traffic. However, its noise can be annoying to neighbors, so in some cities, such as São Paulo, acoustic barriers were installed to reduce the noise caused by the movement of trains.[24] In others, such as Santiago de Chile or Paris, the trains that circulate on metro lines that run partially under the open sky are equipped with cars running on tires, which provides considerable silence and running comfort. In others, such as Prague, or line 2 of the São Paulo Metro "Line 2 (São Paulo Metro)") the journey on the surface is carried out inside elevated tubes.

Since the electrification of railways, the subway has become a means of electric transportation throughout the world. In some cases the current is conducted by catenaries "Catenaria (railway)") above the train (sometimes rigid, as in Madrid, more efficient) and, in others, there are special tracks intended for this task on the sides of the route (as is the case, for example, of the London or Santiago subways).

In recent years, metropolitan railway system operators have embarked on the construction and operation of light rail lines, which due to their peculiar construction and operation characteristics are considered independent of conventional lines.

Metro networks have a high frequency that requires the installation of complex control systems that seek, among other objectives:

The most frequent protection and control systems are:

Multiple systems can be used at the same time. For example, metros running with an ATO self-driving system are typically continuously protected by an ATP system.

The opening of London's steam-powered Metropolitan Railway in 1863 marked the beginning of rapid transit. Initial experiences with steam engines, despite the ventilation, were unpleasant. Experiments with pneumatic railways failed to achieve widespread adoption by cities. Electric traction was more efficient, faster and cleaner than steam and the natural choice for trains running through tunnels and proved superior for elevated services.

In 1890, the City & South London Railway was the first electric-powered rapid transit railway, which was also completely underground.[8] Prior to opening, the line would be called the "City and South London Subway", thus introducing the term Subway into railway terminology.[9] Both railways, along with others, eventually merged into the London Underground. The Liverpool Overhead Railway of 1893 was designed to use electric traction from the beginning.[10]​.

The technology spread quickly to other cities in Europe, the United States, Argentina and Canada, and some railways were converted from steam and others were designed to be electric from the beginning. Budapest, Chicago, Glasgow and New York City, all converted or specially designed and built electric rail services.[11]​.

Advances in technology have enabled new automated services. Hybrid solutions have also evolved, such as tram-train and pre-metro, which incorporate some of the features of rapid transit systems.[8]​ In response to cost, engineering considerations and topological challenges, some cities have chosen to build tram systems, particularly in Australia, where density in cities was low and suburbs tended to spread.[12]​ Since the 1970s, the viability of underground rail systems in Australian cities, particularly Sydney, has been increasing. and Melbourne, has been reconsidered and proposed as a solution to excess capacity. The first Sydney Metro line, Australia's first rapid transit system, opened in 2019.[13]​.

Since the 1960s, many new systems have been introduced in Europe, Asia, and Latin America.[14]​ In the 20th century, the majority of new expansions and systems are located in Asia, with China becoming the world leader in metro expansion, operating some of the largest and busiest systems while having nearly 60 cities that are operating, building, or planning a rapid transit system.[15]​[16]​.

Contenido

El transporte rápido se utiliza para el transporte local en ciudades , aglomeraciones y áreas metropolitanas para transportar a un gran número de personas, a menudo distancias cortas y con alta frecuencia . El alcance del sistema de tránsito rápido varía mucho entre ciudades, con varias estrategias de transporte.

Algunos sistemas pueden extenderse sólo hasta los límites del centro de la ciudad o hasta su anillo interior de suburbios con trenes que hacen paradas frecuentes en las estaciones. A los suburbios exteriores se puede llegar mediante una red de trenes de cercanías separada , donde las estaciones más espaciadas permiten velocidades más altas. En algunos casos, las diferencias entre el transporte rápido urbano y los sistemas suburbanos no están claras.

Los sistemas de tránsito rápido pueden complementarse con otros sistemas como trolebuses , autobuses regulares , tranvías o trenes de cercanías. Esta combinación de modos de tránsito sirve para compensar ciertas limitaciones del tránsito rápido, como paradas limitadas y largas distancias a pie entre puntos de acceso externos. Los sistemas de alimentación de autobuses o tranvías transportan a las personas a paradas de tránsito rápido.

Lines

Each rapid transit system consists of one or more lines or circuits. Each line has at least one specific route and trains stop at all or some of the stations on the line. Most systems operate multiple routes and distinguish them by colors, names, numbering, or a combination of these. Some lines may share tracks with each other for a portion of their route or operate solely on their own right-of-way. Often, a line through the city center branches into two or more branches in the suburbs, allowing for greater frequency of service downtown. This arrangement is used by many systems, such as the Copenhagen Metro, Milan Metro, Oslo Metro, Istanbul Metro, and New York City Subway.

Alternatively, there may be a single central terminal (often shared with the central railway station) or multiple interchange stations between lines in the city centre, for example on the Prague Metro. The London Underground and Paris Metro are densely built systems with a matrix of lines crisscrossing throughout cities. Chicago's 'L' has most of its lines converging on The Loop, the main business, financial and cultural area. Some systems have a circular line around the city center that connects with radially arranged outer lines, such as the Moscow Metro's Koltsevaya Line and Beijing Metro's Line 10.

The capacity of a line is obtained by multiplying the capacity of the cars, the length of the train and the frequency of the service. Heavy rapid transit trains may have six to twelve cars, while lighter systems may use four or fewer. The carriages have a capacity of 100 to 150 passengers, which varies according to the proportion of people sitting and standing: the more standing, the greater the capacity. The minimum time interval between trains is shorter for rapid transit than for mainline railroads due to the use of communications-based train control: the minimum interval can be as high as 90 seconds, but many systems typically use 120 seconds to allow for delay recovery. Typical capacity lines allow 1,200 people per train, which is 36,000 passengers per hour in each direction. However, much higher capacities are achieved in East Asia, with ranges of 75,000 to 85,000 people per hour achieved by MTR Corporation's urban lines in Hong Kong.

Network Topologies

Metro topologies are determined by a host of factors, including geographic barriers, existing or expected travel patterns, construction costs, policies, and historical limitations. A metro system is expected to serve an area of ​​land with a set of lines, consisting of shapes summarized as "I", "L", "U", "S" and "O" shapes or loops. Geographic barriers can cause critical points where transportation lines must converge (for example, to cross a body of water), which are potential sites of congestion but also offer an opportunity for transfers between lines. The circle lines provide good coverage, connecting between the radial lines and serving tangential journeys that would otherwise have to cross the typically congested core of the network. A rough grid pattern can offer a wide variety of routes while maintaining a reasonable speed and frequency of service.[17] A study of the world's 15 largest subway systems suggested a universal shape composed of a dense core from which branches radiate. [18]​.

Passenger information

Rapid transport operators tend to create solid brands, focused on their easy identification in the urban fabric and the desire to transmit speed, safety and authority.

A transit map is a topological map or schematic diagram used to show the routes and stations of a public transportation system. Its main components are color-coded lines to indicate each line or service, with named icons to indicate stations. Maps can show only rapid transit or include other forms of public transportation as well. Transit maps can be found on transit vehicles, on platforms and at station entrances, as well as on operators' websites. These help users understand the connections between different parts of the system; For example, they show interchange stations where passengers can transfer between lines. Unlike conventional maps, transit maps are usually not geographically precise, but instead emphasize connections between different stations. The graphical presentation can use straight lines and fixed angles, and often a fixed distance between stations, to simplify the visualization of the transportation network. This generally has the effect of compressing the distance between stations in the outer area of ​​the system and widening the distances between those near the center. In very touristy cities, it is common to see the main monuments reflected on maps, for easy identification by the tourist.

Some systems assign unique alphanumeric codes to each of their stations to help travelers identify them, briefly encoding information about the line you are on and your position on the line. For example, on the Singapore MRT, the Changi Airport MRT station has the alphanumeric code CG2, indicating its position as the second station on the Changi Airport branch of the East West Line. The Seoul Metro, on the other hand, uses only numbers. According to the line number, for example, Sinyongsan Station, it has station code 429. Being on Line 4, the first number is 4. The last 2 numbers are the station number on that line. Even so, this code is not unique since exchange stations usually have as many identifiers as lines. Thus, the Raffles Place MRT station, where the North South and East West lines meet, has two codes, NS26 and EW14. On other occasions, the identification system is independent of the line, thus allowing the stations to be numbered with a unique code for each one. like the Melbourne tram").

With the widespread use of the Internet and mobile phones around the world, transportation operators now use these technologies to present information to their users. In addition to online maps and schedules, some transportation operators offer real-time information that allows passengers to know when the next vehicle will arrive and expected travel times. The GTFS data format, standardized for transit information, allows many third-party software developers to produce web and smartphone application programs that provide passengers with personalized updates about specific transit lines and stations of interest.[17]​.

Safety and security

Rapid transit operators have often built strong brands, often focused on easy recognition (to enable quick identification even across the wide range of signs found in large cities), combined with a desire to communicate speed, safety and authority. In many cities there is a single corporate image for the entire transit authority, but rapid transit uses its own logo that adapts to the profile.

La mayoría de los trenes de ferrocarriles metropolitanos son de unidades de tren eléctricas, con longitudes de dos a más de diez coches. La electricidad para las motorizaciones eléctricas es provista por un tercer carril "Tercer riel (alimentación)") o catenaria "Catenaria (ferrocarril)"). Otro sistema de propulsión en algunos trenes es el motor lineal.

La mayoría circulan en vías férreas de acero convencionales, aunque algunos utilizan neumáticos de goma, como el Metro de Montreal. Los neumáticos de goma posibilitan circular por pendientes empinadas, pero generan mucho ruido, tienen mayores costes de mantenimiento y son menos eficientes energéticamente. También pierden la fricción cuando las condiciones climáticas son húmedas o heladas, estando limitado su uso en superficie en el Metro de Montreal.

El tamaño de la tripulación ha disminuido a través de la historia con algunos sistemas modernos con plena operación automática del tren (ATO) (como los sistemas VAL, SAET, el sistema de AnsaldoBreda o el SelTrac) que permiten el funcionamiento del tren sin conductor. Algunas redes que utilizan este sistema son el Metro de Copenhague, el Metro de Rennes, el Docklands Light Railway de Londres, las líneas 1 "Línea 1 (Metro de París)") y 14 "Línea 14 (Metro de París)") del Metro de París, las líneas 9, 10 y 11 del Metro de Barcelona, las líneas 4 "Línea 4 (Metro de São Paulo)"), 6 "Línea 6 (Metro de São Paulo)"), 15 "Línea 15 (Metro de São Paulo)") y 17 "Línea 17 (Metro de São Paulo)") del Metro de Sao Paulo y las líneas 3 y 6 del Metro de Santiago de Chile. Otros trenes siguen teniendo conductores, aun cuando su único papel es abrir y cerrar las puertas de los trenes en las estaciones, como el Tren Urbano de San Juan y el Metro de Santiago de Chile.

En algunos sistemas metropolitanos se utiliza el esquema de medición neta, como en el caso de España, para no derrochar electricidad.

La red del Metro de Tokio se compone de 13 líneas, sin incluir la red de trenes urbanos y suburbanos (cercanías) de Japan Railways (JR), entre la que vale destacar la línea Yamanote, la vía férrea de mayor tráfico y comunica los 23 distritos especiales de la urbe.

Trains

Most rapid transit trains are electric multiple units with lengths from three to more than ten cars.[19] Crew sizes have decreased throughout history, with some modern systems now running unmanned trains.[20] Other trains continue to have drivers, although their only role in normal operation is to open and close train doors at stations. Power is commonly delivered by third rail or overhead cables. The entire London Underground network uses the fourth rail and others use the linear motor for propulsion.[21]​.

Some urban railway lines are built with a loading gauge as large as that of the main railway lines; others are built to be smaller and have tunnels that restrict the size and sometimes the shape of the train compartments. An example is the London Underground, which has acquired the informal term "tube train" due to the cylindrical shape of its cabin.

In some cities, suburban rail networks consist of lines that operate different sizes and types of vehicles. Although these subnetworks are not usually connected by track, where necessary, rolling stock with a smaller loading gauge from one subnetwork can be transported along other lines that use larger trains.

Sometimes pneumatic rolling is used for uneven routes or continuous slopes, such as 10 of the 12 lines of the Mexico City Metro, or some of the Paris metro.

Tracks

Most rapid transit systems use standard gauge conventional railway tracks. Since underground tunnel tracks are not exposed to rain, snow, or other forms of precipitation, they are often fixed directly to the ground rather than resting on ballast, like normal train tracks.

driving force

Although initially the trains of what is now the London Underground were pulled by steam engines, virtually all tube trains, both now and historically, use electrical power and are built to operate as multiple units. Train power, known as traction power, generally takes one of two forms: an overhead line, suspended from poles or towers along the track or from tunnel structures or roofs, or a third rail mounted at track level and in contact with a sliding cable.

The practice of sending power via rails in the ground is primarily due to the limited overhead clearance of tunnels, which physically precludes the use of overhead cables. The use of overhead cables allows higher power supply voltages to be used. Although overhead cables are more likely to be used in subway systems without many tunnels, an example of which is the Shanghai Metro, overhead cables are used in some systems that are predominantly underground, such as in Barcelona, ​​Fukuoka, Hong Kong, Madrid and Shijiazhuang. Both overhead cable and third rail systems generally use the rails as the return conductor, but some systems use a separate fourth rail for this purpose. There are transit lines that make use of both rail and air power, with vehicles that can switch between the two, such as the Blue Line "Blue Line (Boston Subway)") in Boston.

Tunnels

Underground tunnels move traffic away from street level, avoiding delays caused by traffic congestion and leaving more land available for buildings and other uses. In areas of high land prices and dense land use, tunnels may be the only economical route for mass transportation. Cut and cover tunnels are built by excavating city streets, which are then rebuilt over the tunnel; Alternatively, tunnel boring machines can be used to excavate deep tunnels that lie lower in the bedrock. [28].

Construction of an underground subway is an expensive project and often takes place over several years. There are several different methods for building underground lines.

The world's deepest subway system was built in St. Petersburg, Russia, where in the swampy area, stable ground begins more than 50 meters (160 feet) deep.

Elevated railways

Elevated railroads are a cheaper and easier way to build an exclusive right-of-way without digging costly tunnels or creating barriers. Besides street-level railways, they may also be the only other feasible alternative due to considerations such as a high water table near the city surface increasing the cost or even preventing underground railways (e.g. Miami). Elevated guides were popular at the turn of the century, but fell out of favor; They came back into fashion in the last quarter century, often in combination with ductless systems. In the Santiago de Chile metro, parts of line 2 (inaugurated in 1978); line 5 (inaugurated in 1997); line 4 (inaugurated in 2005-06); and expansion of line 5 (inaugurated in 2011), have elevated tracks.

Variations

However, not all cities in the world can count on this type of transportation; in cities with weak soil (lack of consistency) and located in seismic zones, its cost would rise by almost 300% of what it would cost to build this in another city. The case of the Seville metro, because the water table was too high in addition to the type of marsh terrain, also represented an added technical difficulty.

Although there are urban railways whose route runs totally or partially on the surface, such as that of Maracaibo, the concept of "metro" is generally associated with underground railways, a solution that was progressively adopted by cities that had not originally adopted it, due to several reasons, among which may be the superiority in the order of aesthetic and environmental quality of the underground route, as well as the lack of available land or the cost of land in large cities.[22]​.

When the subway circulates under the open sky, the tracks are generally placed on metal or concrete platforms elevated about four or five meters above the ground,[23] so that the subway does not interfere with street traffic. However, its noise can be annoying to neighbors, so in some cities, such as São Paulo, acoustic barriers were installed to reduce the noise caused by the movement of trains.[24] In others, such as Santiago de Chile or Paris, the trains that circulate on metro lines that run partially under the open sky are equipped with cars running on tires, which provides considerable silence and running comfort. In others, such as Prague, or line 2 of the São Paulo Metro "Line 2 (São Paulo Metro)") the journey on the surface is carried out inside elevated tubes.

Since the electrification of railways, the subway has become a means of electric transportation throughout the world. In some cases the current is conducted by catenaries "Catenaria (railway)") above the train (sometimes rigid, as in Madrid, more efficient) and, in others, there are special tracks intended for this task on the sides of the route (as is the case, for example, of the London or Santiago subways).

In recent years, metropolitan railway system operators have embarked on the construction and operation of light rail lines, which due to their peculiar construction and operation characteristics are considered independent of conventional lines.

Metro networks have a high frequency that requires the installation of complex control systems that seek, among other objectives:

The most frequent protection and control systems are:

Multiple systems can be used at the same time. For example, metros running with an ATO self-driving system are typically continuously protected by an ATP system.