European Rail Traffic Management System

European Rail Traffic Management System

ERTMS logo
Formation 1998/1999
Website www.ertms.net

The European Rail Traffic Management System (ERTMS) is the system of standards for management and interoperation of signalling for railways by the European Union (EU). It is conducted by the European Union Agency for Railways (ERA) and is the organisational umbrella for the separately managed parts of

The main target of ERTMS is to promote the interoperability of trains in EU. It aims to greatly enhance safety, increase efficiency of train transports and enhance cross-border interoperability of rail transport in Europe. This is done by replacing former national signalling equipment and operational procedures with a single new Europe-wide standard for train control and command systems.

The development process was started with the technical foundations for communication (GSM-R) and signalling (ETCS). Both are well established and in advanced public implementation worldwide. Now it begins to start attention for the 3rd part of ETML i.e. for fleet management or passenger information.

In October 2010 a logo was adopted for ERTMS, which oversees ETCS, an upright orange rectangle with rounded edges. The lower third shows "ertms" in lower-case sans-serif typeface, the upper two thirds 12 wide beams converging to a point on the right side, with two of the beams coming from the bottom, starting above the "e" and "s".[1]

History

In the mid of 1980s the International Union of Railways (UIC) and the European Rail Research Institute (ERRI) began search for a common European operation management for railways, titled ERTMS.[2] Today the development of ERTMS is steered by the ERA and driven by the Association of the European Rail Industry (UNIFE, Union des Industries Ferroviaires Européennes).

Until starting this effort there where (historical reasoned in national railway systems) in Europe

all influencing train communication in parts.

To illustrate this, long running trains like Eurostar or Thalys must have 6 to 8 different train protection systems.[3]

Technical targets of ERTMS are:[3]

In 1995 a development plan first mentioned the creation of the European Rail Traffic Management System.[4] In 1996 the first specification for ETCS followed in response to EU Council Directive 96/48/EC99[5] on interoperability of the trans-European high-speed rail system.

The functional specification of ETCS was announced In April 2000 as guidelines for implementation in Madrid.[6] In autumn 2000 the member states of EU voted for publication of this specifications as decision of the European Commission to get a preliminary security in law and planning. This was to give the foundation for testing applications in six member railways of the ERTMS Users Group.[7]

In 2002 the Union of Signalling Industry (UNISIG) published the SUBSET-026 defining the current implementation of ETCS signalling equipment together with GSM–R – this Class 1 SRS 2.2.2 (now called ETCS Baseline 2) was accepted by the European Commission in decision 2002/731/EEC as mandatory for high-speed rail and in decision 2004/50/EEC as mandatory for conventional rail.

In 2004 further development stalled for some reasons. While some countries (Austria, Spain, Switzerland) switched to ETCS with some benefit, German and French railway operators had already introduced proven and modern types of domestic train protection systems for high speed traffic, so they would gain no benefit. Furthermore, the introduction of ETCS Level 1 (like in Spain) proofed to be very expensive and nearly all implementations are delayed manyfold. The defined standards were comprehensive by political nature, but not exact in technical means. All players would protect their medium old investments until physically or economically constrained time of life. And some active players were willing to overcome the situation with a new Baseline definition, not suited for immediate action.

This situation caused the decision to focus more on the technical parts of ETCS and GSM-R as universal technical foundations of ERTMS. To master this situation, Karel Vinck was appointed in July 2005 as EU coordinator.

In 2005 was inked an Memorandum of Understanding on ERTMS by members of the European Commission, national railways and supplying industries in Brussels. According to this declaration ETCS was to be introduced in 10 to 12 years on a named part of the Trans-European Networks.[8] Following up was in April 2006 a conference in Budapest for the introduction of ERTMS, attended by 700 people.[9]

In July 2009, the European Commission announced that ETCS is now mandatory for all EU funded projects which include new or upgraded signalling and GSM-R is required when radio communications are upgraded.[10]

In April 2012 at the UIC ERTMS World Conference in Stockholm, Sweden, the Executive Director of the Community of European Railway and Infrastructure Companies (CER) called for an accelerated implementation of ERTMS in Europe.[11]

After definition of ETCS Baseline 3 in about 2010 and starting of implementation in multiple countries with Baseline 3 Release 2 in summer 2016, it is again possible to direct attention to operational management requirements of payloads. Big logistic companies like DB Cargo have the need to develop functional capabilities in the target scope of ETML,[12] which should be welcome for standardisation.

ERTMS implementation strategies

The deployment of the European Rail Traffic Management System means the installation of ETCS components on the lineside of the railways and the train borne equipment. Both parts are connected by GSM-R as the communication part. Various railway roll out strategies can be used. With the introduction of ETCS the infrastructure manager has to decide whether a line will be equipped only with ETCS or if there is a demand for a mixed signalling system with support for National Train Control (NTC). Currently, both 'clean' and mixed systems are being deployed in Europe and around the world.[13]

'Clean' ETCS operation

Many new ETCS lines in Europe are being created and then it may often be preferred to implement ETCS Level 1 or Level 2 only. With this implementation strategy the wayside signalling cost is kept to a minimum, but the vehicle fleet that operates on these lines will need to all be equipped with ETCS on board to allow operation. This is more suitable for new high-speed passenger lines, where new vehicles will be bought, less suitable if long-distance freight trains shall use it. Examples of 'clean' ETCS operation include HSL-Zuid in the Netherlands, TP Ferro international stretch (Sección Internacional / Section Internationale) Figueres [ES] – Perpignan [FR], Erfurt–Halle/Leipzig in Germany, among others. Also all ETCS railways in Sweden and Norway, since the ETCS and ATC balise frequencies are too close so that older trains would get faults when passing Eurobalises.

Mixed operation

Mixed operation is a strategy where the wayside signalling is equipped with both ETCS and a conventional Class B system. Often the conventional system is the legacy system used during the signalling upgrade program. The main purposes of introducing a mixed operation (mixed signalling system) are:

With mixed operation it is possible to run a line with both conventional and ETCS trains and to use the advantages of ETCS technology for the trains so equipped (e.g. higher speed or more trains on the line) but with the benefit that it is not necessary to equip the whole train fleet with ETCS simultaneously. Examples of ETCS in mixed operation include HSL 3 in Belgium where ETCS is mixed with national ATP system TBL or High-Speed Line Cordoba-Malaga in Spain[14] where ETCS is mixed with NTC of ASFA and LZB.

Operational principle of ETCS in mixed operation: NTC and ETCS Level 2

The principle of mixed level signalling is based on simple principles using bi-directional data exchange between the Radio Block Centre (RBC) and the interlocking systems. The operator sets a route and does not need to know if the route will be used for a Level NTC (former LSTM) only or a Level 2-equipped train. A route is locked based on the national principles by the interlocking system and the RBC is informed about the routes set. The RBC checks whether it is possible to allocate a train to the route and then informs the interlocking system that a train is allocated to the route. The interlocking system shows the ETCS white bar aspect to all signals along the route including the signal at the end of the route and sends no ATB-EG code to the track. The RBC sends a movement authority to the train if a Level 2 train is allocated to the route. Otherwise the signal shows the optical proceed aspect and the related ATB-EG code is sent to the track. As soon as a Level 2 train reports itself in rear of a route currently assigned for optical authorisation (e.g. after start of mission procedure or when the driver changes level from Level NTC to Level 2), the optical authorisation is automatically upgraded to a Level 2 movement authority. Consequently, a Level 2 movement authority is downgraded to an optical authorisation after a predefined time-out if the driver closes the cab or a fault is detected that restricts the movement authority (e.g. if the GSM-R radio coverage is unavailable.)

Companies

Companies developing ETCS systems include UNIFE/UNISIG members Alstom, Thales, AŽD Praha (cz), Ansaldo STS (now part of Hitachi), Siemens Mobility, Bombardier Transportation, CAF and MERMEC. GSM-R equipment is delivered by some companies like Nokia Networks, Kapsch, Huawei, Siemens Mobility and Funkwerk Kölleda (de).

Companies that provide testing solutions for ERTMS systems include: Comtest Wireless[15]

See also

References

  1. "ERTMS - The European Railway Traffic Management System".
  2. Schmied, Peter (2000). "ETCS-System auf der Strecke Wien – Budapest erfolgreich getestet.". Eisenbahn-Revue International (in German). 01/2000: 32.
  3. 1 2 Jacques Poré (2007), "ERTMS/ETCS – Erfahrungen und Ausblicke" (in German), Signal + Draht 99 (10): pp. 34–40, ISSN 0037-4997
  4. Warren Kaiser, Stein Nielson (14 March 2008). "The Core of ATP – Data Engineering". IRSE Technical Meeting "All About ATP" Sydney.|
  5. "Directive 96/48/EC99". 23 July 1996. amending Council Directive 96/48/EC on the interoperability of the trans-European high-speed rail system and Directive 2001/16/EC of the European Parliament and of the Council on the interoperability of the trans-European conventional rail system
  6. Meldung ERTMS-Spezifikation festgelegt. In: Eisenbahn-Revue International, Heft 6/2000, ISSN 1421-2811, S. 275.
  7. DB AG startet Versuche mit ETCS-Level 2. In: Eisenbahn-Revue International, Heft 4/2002, ISSN 1421-2811, S. 186–189.
  8. Meldung Absichtserklärung zu ERTMS. In: Eisenbahn-Revue International, Heft 5/2005, ISSN 1421-2811, S. 235.
  9. Peter Winter: UIC-Konferenz zur Einführung des European Rail Traffic Management Systems in Budapest. In: Eisenbahn-Revue International. Heft 6/2006, ISSN 1421-2811, S. 284–285.
  10. "EC sets out ERTMS deployment deadlines". Railway Gazette International. 31 July 2009.
  11. "Now or never for ERTMS in Europe, says Lochman". International Railway Journal. 25 April 2012. Retrieved 6 May 2012.
  12. - (2017-02-08). "Neues Digital Lab „ampulse“ im „House of Logistics & Mobility“ eingeweiht.". dbcargo.com (in German). DB Cargo AG. Retrieved 2017-02-09.
  13. ERTMS deployment map. UNIFE, Retrieved 2011-11-11
  14. ERTMS Online Newsletter. European Communities, March 2008, Retrieved 2011-12-29
  15. "Comtest Wireless". Comtest Wireless.
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