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44-414: Automatic train control ( ATC ) is a general class of train protection systems for railways that involves a speed control mechanism in response to external inputs. For example, a system could effect an emergency brake application if the driver does not react to a signal at danger. ATC systems tend to integrate various cab signalling technologies and they use more granular deceleration patterns in lieu of

88-417: A brake application to reduce speed a penalty brake application is made automatically. Due to the more sensitive handling and control issues with North American freight trains, ATC is almost exclusively applied to passenger locomotives in both inter-city and commuter service with freight trains making use of cab signals without speed control. Some high-volume passenger railroads such as Amtrak , Metro North and

132-431: A low voltage current which was passed to the locomotive when a shoe came into contact with the ramp. A bell rang in the locomotive's cab to confirm the clear aspect, and the electric current kept the brakes from being applied. If the signal showed yellow (meaning the next signal would show red) the ramp was dead and a siren sounded in the cab. If the siren was not cancelled, the brakes would automatically be applied. After

176-469: A more severe penalty application that will bring the train to a stop. Neither system requires explicit speed control or adherence to a braking curve . The Union Pacific system requires an immediate brake application that cannot be released until the train's speed has been reduced to 40 mph (64 km/h) (for any train traveling above that speed). Then, the train's speed must be further reduced to no more than 20 mph (32 km/h) within 70 seconds of

220-430: A train ignores a red signal, the emergency brakes are applied and the locomotive's motors are shut down. Additionally, they often require the driver to confirm distant signals (e.g. CAWS ) that show stop or caution – failure to do so results in the train stopping. More advanced systems (e.g., PZB , and ZUB ) calculate a braking curve that determines if the train can stop before the next red signal, and if not they brake

264-729: Is a railway technical installation to ensure safe operation in the event of human error . The earliest systems were train stops, as still used by the New York City Subway , the Toronto subway , the London Underground , the Moscow Subway (only on the older lines) and the Berlin S-Bahn . Beside every signal is a moveable arm. If the signal is red, levers connected to valves on any passing train hit

308-487: Is also planned to be used on the soon to open Line 5 Eglinton line, however, Unlike on Line 1, the system on Line 5 will be supplied by Bombardier Transportation using its Cityflo 650 technology. The TTC plans to convert Line 2 Bloor-Danforth and Line 4 Sheppard to ATC in the future, subject to funding availability and being able to replace the current non-ATC compatible fleet on Line 2 with trains that are, with an estimated date of completion by 2030. ATC systems in

352-619: Is different from that of its neighbours. From 1978 until 1987, the Swedish ATC system was trialled in Denmark, and a new Siemens -designed ATC system was implemented between 1986 and 1988. In consequence of the Sorø railway accident , which occurred in April 1988, the new system was progressively installed on all Danish main lines from the early 1990s onwards. Some trains (such as those employed on

396-597: Is generally incompatible with ERTMS / ETCS (as in the case of the Bothnia Line which is the first railway line in Sweden to exclusively use ERTMS/ETCS), and with the aim of Trafikverket to eventually replace ATC-2 with ERTMS/ETCS over the next few decades, a Special Transmission Module (STM) has been developed to automatically switch between ATC-2 and ERTMS/ETCS. In 1906, the Great Western Railway in

440-676: Is however not used on the Copenhagen S-train commuter network, where another, incompatible safety system called HKT ( da:Hastighedskontrol og togstop ) had been in use from 1975–2022, as well as on the Hornbæk Line , which uses a much more simplified ATP system introduced in 2000. All aforementioned systems are gradually being replaced by the modern and worldwide CBTC signalling standard as of 2024. Bane NOR —the Norwegian government's agency for railway infrastructure—uses

484-660: The British Rail Automatic Warning System (AWS). Starting in 2017, the Toronto Transit Commission began the implementation of ATC on to Line 1 Yonge–University , at a cost of $ 562.3   million. Awarding the contract to Alstom in 2009, the TTC will be able to reduce the headway between trains on Line 1 during rush hours, and allow an increase in the number of trains operating on Line 1. Work would however not begin until

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528-508: The European Train Control System standard was developed. It offers different levels of functionality, ranging from simple to complex. This model allows adopters to meet the cost and performance requirements of disparate solutions, from the smallest to the largest. The European system has been in operation since 2002 and uses GSM digital radio with continuous connectivity. The newer systems use cab signalling, where

572-479: The Great Western Railway , although it would now be referred to as an automatic warning system (AWS) because the driver retained full command of braking. The term is especially common in Japan , where ATC is used on all Shinkansen (bullet train) lines, and on some conventional rail and subway lines, as a replacement for ATS. The accident report for the 2006 Qalyoub accident mentions an ATC system. In 2017, Huawei

616-480: The Long Island Rail Road require the use of speed control on freight trains that run on all or part of their systems. While cab signalling and speed control technology has existed since the 1920s, adoption of ATC only became an issue after a number of serious accidents several decades later. The Long Island Rail Road implemented its Automatic Speed Control system within its cab signalled territory in

660-767: The Senseki Line in 2011, followed by the Saikyō Line in 2017, and the Koumi Line in 2020. It is considered to be Japan's equivalent to ETCS Level 3 . Several subway lines in South Korea use ATC, in some cases enhanced with ATO. All lines use ATC. All lines are enhanced with ATO. Other than on Lines 1 and 2 (MELCO cars only), all lines use ATC. Line 2 (VVVF cars), Line 5 cars, Line 6 cars, Line 7 cars, and Line 8 cars have their ATC systems enhanced with ATO. Denmark's system of ATC (officially designated ZUB 123 )

704-628: The Åsta accident occurred in 2000, the implementation of DATC on the Røros Line was accelerated, and it became operational in 2001. In Sweden the development of ATC started in the 1960s (ATC-1), and was formally introduced in the early-1980s together with high-speed trains (ATC-2/Ansaldo L10000). As of 2008, 9,831 km out of the 11,904 km of track maintained by Swedish Transport Administration —the Swedish agency responsible for railway infrastructure—had ATC-2 installed. However, since ATC-2

748-580: The Øresundståg service and some X 2000 trains) have both the Danish and the Swedish systems, while others (e.g. ten of the ICE-TD trains) are fitted with both the Danish and the German systems. The ZUB 123 system is now considered by Banedanmark , the Danish railway infrastructure company, to be obsolete and the entire Danish rail network is expected to be converted to ETCS Level 2 by 2030. The ZUB 123 system

792-826: The 1950s after a pair of deadly accidents caused by ignored signals. After the Newark Bay Lift Bridge Disaster the state of New Jersey legislated use of speed control on all major passenger train operators within the State. While speed control is used on many passenger lines in the United States, in most cases it has been adopted voluntarily by the railroads that own the lines. Only three freight railroads, Union Pacific , Florida East Coast and CSX Transportation , have adopted any form of ATC on their own networks. The systems on both FEC and CSX work in conjunction with pulse code cab signals , which in

836-474: The ATC applies the brakes automatically when the train speed exceeds the speed limit, it cannot control the motor power or train stop position when pulling into stations. However, the automatic train operation (ATO) system can automatically control departure from stations, the speed between stations, and the stop position in stations. It has been installed in some subways. However, ATC has three disadvantages. First,

880-577: The Swedish system of ATC. Trains can therefore generally cross the border without being specially modified. However, unlike in Sweden, the ATC system used in Norway differentiates between partial ATC ( delvis ATC , DATC), which ensures that a train stops whenever a red signal is passed, and full ATC (FATC), which, in addition to preventing overshooting red signals, also ensures that a train does not exceed its maximum allowed speed limit. A railway line in Norway can have either DATC or FATC installed, but not both at

924-447: The UK developed a system known as "automatic train control". In modern terminology, GWR ATC is classified as an automatic warning system (AWS). This was an intermittent train protection system that relied on an electrically energised (or unenergised) rail between, and higher than, the running rails. This rail sloped at each end and was known as an ATC ramp and would make contact with a shoe on

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968-406: The United States are almost always integrated with existing continuous cab signalling systems. The ATC comes from electronics in the locomotive that implement some form of speed control based on the inputs of the cab signalling system. If the train speed exceeds the maximum speed allowed for that portion of track, an overspeed alarm sounds in the cab. If the engineer fails to reduce speed and/or make

1012-412: The arm, opening the brake line , applying the emergency brake, If the signal shows green, the arm is turned away from the levers and there is no contact. The Great Western Railway in the UK introduced its ' automatic train control ' system in the early years of the 20th century. Each distant signal had before it a ramp between the running rails. If the signal showed green, the ramp was energised with

1056-461: The braking pattern, while ensuring ride comfort. There is also an emergency braking pattern outside the normal braking pattern and the ATC system applies the emergency brakes if the train speed exceeds this emergency braking pattern. The digital ATC system has a number of advantages: To date, the following digital ATC systems are used: ATACS is a moving block ATC system similar to CBTC , developed by RTRI and first implemented by JR East on

1100-534: The case of CSX was inherited from the Richmond, Fredericksburg and Potomac railroad on its single main line. Union Pacific's was inherited on portions of the Chicago and Northwestern east–west main line and works in conjunction with an early two aspect cab signaling system designed for use with ATC. On CSX and FEC more restrictive cab signal changes require the engineer to initiate a minimum brake application or face

1144-540: The delivery of brand new trains with ATC compatibility and the retirement of older rolling stock that was not compatible with the new system. ATC was introduced in phases, beginning with a test on 4 November 2017 during regular service between Dupont and Yorkdale stations. It was first introduced in a permanent manner with the opening of the Toronto–York Spadina subway extension on 17 December 2017, between Vaughan and Sheppard West stations. Implementation of

1188-479: The driver failed to acknowledge this warning within a preset time, the brakes of the train would be applied. In testing, the GWR demonstrated the effectiveness of this system by sending an express train at full speed past a distant signal at caution. The train was brought safely to a stand before reaching the home signal. If the signal associated with the ramp was clear, the ramp was energised. The energized ramp would lift

1232-487: The headway cannot be increased due to the idle running time between releasing the brakes at one speed limit and applying the brakes at the next slower speed limit. Second, the brakes are applied when the train achieves maximum speed, meaning reduced ride comfort. Third, if the operator wants to run faster trains on the line, all the related relevant wayside and on-board equipment must be changed first. The following analogue systems have been used: The digital ATC system uses

1276-446: The initial cab signal drop. Failure to apply the brakes for these speed reductions will result in a penalty application. All three freight ATC systems provide the engineer with a degree of latitude in applying brakes in a safe and proper manner, since improper braking can result in a derailment or a runaway. None of the systems are in effect in difficult or mountainous terrain. Train protection system A train protection system

1320-464: The nationalisation of the railways in the UK in 1948, this system was later replaced by the magnetic induction " automatic warning system ". In inductive system, data is transmitted magnetically between the track and locomotive by magnets mounted beside the rails and on the locomotive. In the Integra-Signum system the trains are influenced only at given locations, for instance whenever

1364-434: The next train ahead is computed. The on-board memory also saves data on track gradients, and speed limits over curves and points. All this data forms the basis for ATC decisions when controlling the service brakes and stopping the train. In a digital ATC system, the running pattern creates determines the braking curve to stop the train before it enters the next track section ahead occupied by another train. An alarm sounds when

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1408-528: The rigid stops encountered with the older automatic train stop (ATS) technology. ATC can also be used with automatic train operation (ATO) and is usually considered to be the safety-critical part of a railway system. There have been numerous different safety systems referred to as "automatic train control" over time. The first experimental apparatus was installed on the Henley branch line in January 1906 by

1452-523: The same time. ATC was first trialled in Norway in 1979, after the Tretten train disaster , caused by a signal passed at danger (SPAD), occurred four years earlier. DATC was first implemented on the section Oslo S - Dombås - Trondheim - Grong between 1983 and 1994, and FATC was first implemented on the Ofoten Line in 1993. The high-speed Gardermoen Line has had FATC since its opening in 1998. After

1496-414: The shoe on the passing locomotive and cause a bell to sound on the footplate. If the system were to fail then the shoe would remain unenergised, the caution state; it therefore failed safe , a fundamental requirement of all safety equipment. The system had been implemented on all GWR main lines, including Paddington to Reading, by 1908. The system remained in use until the 1970s, when it was superseded by

1540-460: The signalling system to the onboard computer is continuous (e.g., LZB ). Prior to the development of a standard train protection system in Europe, there were several incompatible systems in use. Locomotives that crossed national borders had to be equipped with multiple systems. In cases where this wasn't possible or practical, the locomotives themselves had to be changed. To overcome these problems,

1584-531: The specific track section along the track circuit . When these signals are received on board, the train's current speed is compared with the speed limit and the brakes are applied automatically if the train is travelling too fast. The brakes are released as soon as the train slows below the speed limit. This system offers a higher degree of safety, preventing collisions that might be caused by driver error, so it has also been installed in heavily used lines, such as Tokyo's Yamanote Line and some subway lines. Although

1628-459: The system on to the remainder of the line was carried out during weekend closures and night time work when the subway would close. There were delays on the project, with deadlines for the complete conversion of Line 1 pushed back multiple times until 2022. ATC conversion was completed to Finch station on 24 September 2022. Converting all of Line 1 to ATC required the installation of 2,000 beacons, 256 signals, and more than one million feet of cable. ATC

1672-407: The track circuits to detect the presence of a train in the section and then transmits digital data from wayside equipment to the train on the track circuit numbers, the number of clear sections (track circuits) to the next train ahead, and the platform that the train will arrive at. The received data is compared with data about track circuit numbers saved in the train on-board memory and the distance to

1716-433: The train approaches the braking pattern and the brakes are applied when the braking pattern is exceeded. The brakes are applied lightly first to ensure better ride comfort, and then more strongly until the optimum deceleration is attained. The brakes are applied more lightly when the train speed drops to a set speed below the speed limit. Regulating the braking force in this way permits the train to decelerate in accordance with

1760-486: The train to brake. These systems are usually far more than automatic train protection systems; not only do they prevent accidents, they also actively support the train driver and detect blind spots around trains. Some systems are able to drive the train nearly automatically. ATACS Too Many Requests If you report this error to the Wikimedia System Administrators, please include

1804-447: The train. They require that the train driver enter the weight and the type of brakes into the onboard computer. One disadvantage of this kind of system is that the train cannot speed up before the signal if it has switched to green because the onboard computer's information can only be updated at the next magnet. To overcome that problem, some systems allow additional magnets to be placed between distant and home signals or data transfer from

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1848-487: The trains constantly receive information regarding their relative positions to other trains. The computer shows the driver how fast they may drive, instead of them relying on exterior signals. Systems of this kind are in common use in France , Germany and Japan , where the high speeds of the trains made it impossible for the train driver to read exterior signals, and distances between distant and home signals are too short for

1892-400: The underside of the passing locomotive. The ramps were provided at distant signals . A development of the design, intended for use at stop signals, was never implemented. If the signal associated with the ramp was at caution, the ramp would not be energised. The ramp would lift the shoe on the passing locomotive and start a timer sequence at the same time sounding a horn on the footplate. If

1936-537: Was contracted to install GSM-R partly to provide communication services to automatic train protection systems. In Japan, the Automatic Train Control (ATC) system was developed for high-speed trains like the Shinkansen , which travel so fast that the driver has almost no time to acknowledge trackside signals. Although the ATC system sends AF signals carrying information about the speed limit for

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