ATACS

Advanced Train Administration and Communications System (ATACS) is an

JR East on the Senseki Line in 2011. It uses radio communication rather than traditional signals, and works as a moving block system.^[1]

Communication between the train and the trackside equipment happens entirely through bidirectional radio communication. Radio base stations are placed at intervals of 2 to 3km and operates on four different frequency bands, used alternately to prevent inference.^[1] Radios operate in the 400 MHz frequency band, with data transmitted using TDMA access method with Reed–Solomon error correction at 9.6 kbps.^[2] The radio system are based on proprietary standards with encryption.^[3]

Ground equipment

Ground controller

The ground controller, being the main control unit of ground equipment, is responsible for the identification of train locations based on information received from the trains, route setting, control and interlocking, train interval regulation, and boundary control and train entry/exit handover.^[1]

Train existence supervision equipment

Connected to the ground controller, the train existence supervision equipment is responsible for controlling line occupation of trains.^[1] It also maintains safety in case of system failure and during recovery operations by using train identification assigned to each trains to track occupation even if other equipment is out of service.^[3]

System supervision equipment

The system supervision equipment monitors the operating status of the ATACS system and has functions to change settings such as temporary speed limits^[1] in increments of 5 km/h. The system supervision equipment is also responsible for setting track closures, setting single-line working, and routing maintenance vehicles.^[4]

Field controller

The field controller connects trackside equipment such as switches, level crossing equipment, radio stations, and detectors to the ground controller.^[1]

Onboard devices

Every train is equipped with an onboard device which is responsible for determining the train's position. For more precise position tracking, a balise is installed every kilometer. This information, along with the train length is periodically transferred to the ground equipment.^[1]^[4] Therefore, no track circuits or axle counters are necessary.

The onboard device is also responsible for calculating the brake intervention curve required to stop the train at the limit of the limited movement authority (LMA), the area in which the train is permitted to move. It takes the individual train's braking performance, track gradient, curve, and speed limit into consideration to perform this calculation.^[2]

Similar to earlier

Automatic Train Control systems, ATACS uses cab signalling. A cab display shows ATACS information required for driving, such as ^[1] the distance to limit of the LMA, the maximum allowable speed as permitted by the brake curve, and the route set.^[4]

Usage

ATACS is deployed on the following lines:

ATS-Ps as fallback)^[1]

Saikyō Line (Ikebukuro – Ōmiya, as replacement for ATC-6)^[6]
Koumi Line^[7]^[8]^[a]

Notes

^ Koumi Line's implementation is called ATS-P(R): a similar, but simplified system compared to ATACS.^[9]^[10]

References

^ ^a ^b ^c ^d ^e ^f ^g ^h ⁱ Hiura, Noboru. "Overview of the ATACS Radio Train Control System" (PDF). Retrieved December 12, 2020.
^
S2CID 113833233
.

^ ^a ^b "Safety Innovations Using Radio-based Train Control System" (PDF). Hitachi Review. 67 (7): 16–22. December 2018.
^ ^a ^b ^c 馬場, 裕一; 立石, 幸也; 森, 健司; 青柳, 繁晴; 武子, 淳; 齋藤, 信哉; 鈴木, 康明; 渡邊, 貴志 (2005). musen niyoru ressha seigyo shisutemu (ATACS) 無線による列車制御システム（ATACS） (PDF). JR EAST Technical Review (Technical report) (in Japanese). Vol. 12. pp. 40–51.
^ Stacy, Mungo. "ATACS – The Japanese Level 3?". RailEngineer. Retrieved December 12, 2020.
^ "埼京線への無線式列車制御システム（ＡＴＡＣＳ）の使用開始について" (PDF) (Press release) (in Japanese). East Japan Railway Company. 2017-10-03. Retrieved 2021-07-10.
^ https://www.nikkan.co.jp/articles/view/00418902
^ "小海線への無線式列車制御システムの導入決定のお知らせ" (PDF) (Press release) (in Japanese). East Japan Railway Company. Archived from the original (PDF) on 2020-09-17. Retrieved 2020-09-17.
^ Suzuki, Tetsuya; Kuroiwa, Atsushi (2020). Wireless Connections System for Regional Lines Train Control System 地方交通線向け列車制御用無線通信システム (PDF). 三菱電機技報 (Technical report) (in Japanese). Mitsubishi Electric. pp. 22–26. 94-9.
^ 宮川, 裕史; 池永, 真英; 北原, 知直; 今村, 覚; 岩村, 陽介 (2021-11-01). "ATS-P(R)車上装置の開発について-小海線地方交通線無線式列車制御システムの車上装置". 鉄道サイバネ・シンポジウム論文集 (in Japanese). 58. Japan Railway Engineers’ Association.

This Japanese rail transport related article is a stub. You can help Wikipedia by expanding it.

[11] Koumi Line's implementation is called ATS-P(R): a similar, but simplified system compared to ATACS.^[9]^[10]

[jreast-overview-atacs-1] ^ ^a ^b ^c ^d ^e ^f ^g ^h ⁱ Hiura, Noboru. "Overview of the ATACS Radio Train Control System" (PDF). Retrieved December 12, 2020.

[:0-2] 
S2CID 113833233
.

[:1-3] "Safety Innovations Using Radio-based Train Control System" (PDF). Hitachi Review. 67 (7): 16–22. December 2018.

[:2-4] 馬場, 裕一; 立石, 幸也; 森, 健司; 青柳, 繁晴; 武子, 淳; 齋藤, 信哉; 鈴木, 康明; 渡邊, 貴志 (2005). musen niyoru ressha seigyo shisutemu (ATACS) 無線による列車制御システム（ATACS） (PDF). JR EAST Technical Review (Technical report) (in Japanese). Vol. 12. pp. 40–51.

[rail-engineer-japanese-level-3-5] Stacy, Mungo. "ATACS – The Japanese Level 3?". RailEngineer. Retrieved December 12, 2020.

[6] "埼京線への無線式列車制御システム（ＡＴＡＣＳ）の使用開始について" (PDF) (Press release) (in Japanese). East Japan Railway Company. 2017-10-03. Retrieved 2021-07-10.

[7] ttps://www.nikkan.co.jp/articles/view/00418902

[8] "小海線への無線式列車制御システムの導入決定のお知らせ" (PDF) (Press release) (in Japanese). East Japan Railway Company. Archived from the original (PDF) on 2020-09-17. Retrieved 2020-09-17.

[9] Suzuki, Tetsuya; Kuroiwa, Atsushi (2020). Wireless Connections System for Regional Lines Train Control System 地方交通線向け列車制御用無線通信システム (PDF). 三菱電機技報 (Technical report) (in Japanese). Mitsubishi Electric. pp. 22–26. 94-9.

[10] 宮川, 裕史; 池永, 真英; 北原, 知直; 今村, 覚; 岩村, 陽介 (2021-11-01). "ATS-P(R)車上装置の開発について-小海線地方交通線無線式列車制御システムの車上装置". 鉄道サイバネ・シンポジウム論文集 (in Japanese). 58. Japan Railway Engineers’ Association.

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v t e Railway signalling
Block systems	Absolute block signalling Automatic block signaling Centralized traffic control Communications-based train control Direct traffic control European Train Control System Moving block Radio Electronic Token Block Token Track Warrant Control Train order operation
Signalling control	Block post Integrated Electronic Control Centre Interlocking Lever frame Rail operating centre Solid State Interlocking Westlock Interlocking
Signals	Application of railway signals Cab signalling North American railroad signals Railway semaphore signal
Train detection	Axle counter Track circuit Track circuit interrupter Treadle
Train protection	Advanced Civil Speed Enforcement System ALSN ASFA ATACS Automatic train control Automatic train operation Automatic train protection Automatic Train Protection (United Kingdom) Automatic train stop Automatic Warning System Automatische treinbeïnvloeding Balise Catch points Chinese Train Control System Cityflo 650 CBTC Continuous Automatic Warning System Contrôle de vitesse par balises EBICAB IIATS Integra-Signum Interoperable Communications Based Signaling Crocodile Linienzugbeeinflussung Positive Train Control Pulse code cab signaling Punktförmige Zugbeeinflussung RS4 Codici SelTrac Sistema Controllo Marcia Treno SACEM Slide fence Train automatic stopping controller Train Protection & Warning System Train stop Trainguard MT Transmission balise-locomotive Transmission Voie-Machine
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