Improving the Reliability of a Train Positioning System through the

Use of Full Coverage Radio Communication Technologies

Performance Study of a TETRA Network to Transmit Position Information

Roberto Carballedo, Pablo Fernández, Unai Hernández Jayo and Asier Perallos

University of Deusto, Deusto Institute of Technology, Av. Universidades, 24, Bilbao, Spain

Keywords: Wireless Communications, Terrestrial Trunked Radio, Train Positioning System, Railway Industry.

Abstract: Today, it is common for trains to incorporate autonomous positioning systems based on geo-location

technologies similar to those used on road transportation. These positioning systems represent a cost

effective solution for railway companies operating in not evolved regions. Furthermore, these positioning

systems can enhance the reliability of positioning systems based on the occupation of the tracks (which are

most used in the most developed regions). Autonomous positioning systems calculate the position of the

train, but the position has to be sent from the train to the control center. GPRS/3G mobile technologies and

WiFi radio technologies are the most common technologies for transmitting the position to the control

centers. These technologies do not guarantee 100% coverage in certain areas such as tunnels or

mountainous regions. This paper presents the results of the tests on an autonomous positioning system to

add a new communications technology in order to increase its coverage. This technology is TETRA, which

is a radio technology that has been traditionally used for voice transmission, but it can be a good

complement to GPRS/3G when there is no coverage.

1 INTRODUCTION

Train positioning systems are a key element to

ensure the safety of the rail system. Most positioning

systems are based on electronic devices that are

installed on the tracks. These positioning systems

are very robust and reliable, but when they stop

working, security levels are significantly reduced. In

these situations the position of trains is done

manually by live-voice communication between

drivers and control centers. For this reason, in recent

years, there have been many initiatives to develop

backup positioning systems, in which the train

becomes the protagonist (Jiang et. al., 2010) (Bai-

Gen et. al., 2011). These positioning systems

calculate the position of the trains by means of

different position sources: GPS, MEMS gyroscope,

maps, ATP, odometer, etc. Once the position is

calculated, it is sent to the control center using a

wireless communications network, usually GPRS or

3G. The main limitations of these systems are the

coverage of mobile communications (tunnels,

overgrown or isolated areas, etc.), and the cost of the

communications (usually communications network

belongs to a private operator). To tackle this

limitation, this paper presents the results of tests

performed with a train positioning system in order to

improve reliability. The tests were focused on

evaluating the improvement achieved by

incorporating the TETRA as a backup channel in

situations where there is no GPRS/3G coverage.

The paper is organized in 5 sections: Section 2

details the potential of TETRA technology for

transmitting position information in the railways.

Section 3 explains the underlying details of the

positioning system and communications architecture

to send the position from the trains to the control

center. Section 4 shows the results of the tests; and

finally, the paper concludes with Section 5 which

details the conclusions and future lines of work.

2 TERRESTRIAL TRUNKED

RADIO FOR DATA

TRANSMISSION

TETRA (TErrestrial Trunked RAdio) is the

communications standard, defined in 1999 by the

323

Carballedo R., Fernández P., Hernández Jayo U. and Perallos A..

Improving the Reliability of a Train Positioning System through the Use of Full Coverage Radio Communication Technologies - Performance Study of a

TETRA Network to Transmit Position Information.

DOI: 10.5220/0004062003230328

In Proceedings of the International Conference on Signal Processing and Multimedia Applications and Wireless Information Networks and Systems

(WINSYS-2012), pages 323-328

ISBN: 978-989-8565-25-9

 2012 SCITEPRESS (Science and Technology Publications, Lda.)

European Telecommunications Standards Institute,

for a generation of digital radio products. The main

characteristics of TETRA are:

 It is an open standard air interface so it provides

real interoperability with other communication

systems.

 High spectrum efficiency with short bandwidth

that allows creating private workgroups of users and

high quality of services, for example at voice

communications.

 It can be used on all frequencies below 1000

MHz frequency bands for Private Mobile Radio

(PMR) and public safety applications are assigned

on a national basis.

 In the railway context it offers encrypted and

high-quality communications in noisy environments

and whatever the signal conditions, providing up to

28Kbps bit rate.

 It is a mature technology with several suppliers

of terminals.

At the beginning, TETRA was deployed to satisfy

the needs of the Private Mobile Radio (PMR), Public

Access Mobile Radio (PAMR), Land Mobile Radio

(LMR) and the public applications for security and

protection corps, guard coast, fire-fighter’s services

and ambulances. But later developments at the

standard allowed Package Data Optimized (PDO)

transmission mode and Short Data Services (SDS)

that is comparable with the Short Data Message

(SMS) of GSM.

Package Data Optimized is used by modern

systems to transmit voice message, electronic mail,

data interchange, and so on. In this regard,

Enhanced-PDO known as DAWS (Digital Advanced

Wireless Services) provides a 2Mbps bit rate to be

used in combination with UMTS in high mobility

scenarios as Railroad Digital Networks (Wenlong,

Haige and Hongjie, 2002).

Short Data Services are transmitted over the

control channel in a point-to-point or point-to-

multipoint format without any reception

acknowledgement. Two message formats are

available:

 Status messages that only with 16 bits can

represent 65,535 messages.

 User messages that use a variable package size

from 16 to 2,047 bits.

In Railroad Networks basic TETRA Short Data

Service for polling and transmitting GPS position in

Location Information Protocol (LIP) format can be

easily used with a high reliability in different

scenarios because SDS messages can be send

between subscribers, between subscriber and

dispatcher and subscriber and fixed host in the

network. Moreover, SDS messages can be sending

to individual subscribers or broadcasted on a number

of base stations to all subscribers using that base

station.

In the railroad applications TETRA works in

PDO or SDS modes. These systems are connection

oriented so the mobile node installed in the train

requires first a connection to a specific Base Station

to start the data transmission. As the train is a

moving node, fast handover techniques are needed

to maintain the node connected to the network. This

process produces a delay in the communication that

can break down the link and cause the failure of the

data transmission (Palit, Bickerstaff, and Langmaid,

2009). Moreover, railway networks may also suffer

from the following problems caused by the handover

applied techniques:

 Handover to a wrong cell, which has the same

main control channel frequency as a neighbour cell.

The Mobile Station (MS) then loses all sensible

neighbours as it gets information on neighbours to

the "wrong" cell.

 Cell dragging by an MS, where frequency reuse

is reduced by interference of the transmitting MS

with others that would otherwise be out of range.

3 POSITIONING SYSTEM

ARCHITECTURE

Our positioning system (Carballedo et al., 2010) is

organized conceptually into two functional blocks:

(1) the positioning system itself, and (2)

communications system. The positioning system is

responsible for calculating the position, while the

communications system sends the position from the

train to the control center. Then the particularities of

each are described.

3.1 Positioning System

Train positioning system is primary based on GPS

data. This system is able to generate train

positioning information applying a logical

approximation algorithm for matching railway lines

and GPS coordinates (Guan-Wei et al., 2009). To

generate the most accurate positioning information,

this system uses railway lines lengths (in kilometres)

and traffic signals positions. Based on this

information, the data extracted from the hardware

(GPS, MEMS gyroscope, maps, ATP and odometer)

WINSYS2012-InternationalConferenceonWirelessInformationNetworksandSystems

324

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Technologies-PerformanceStudyofaTETRANetworktoTransmitPositionInformation

325

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ImprovingtheReliabilityofaTrainPositioningSystemthroughtheUseofFullCoverageRadioCommunication

Technologies-PerformanceStudyofaTETRANetworktoTransmitPositionInformation

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whether the TETRA network is a valid alternative to

improve the reliability of the positioning system. For

this, a series of tests were done. The tests have been

focused on measuring the delay in sending the

position from the trains to central control. It has also

been counted the number of messages sent

successfully.

The results of the tests confirmed the initial

hypothesis. Therefore, TETRA technology is a good

alternative to increase the coverage of the

communications architecture.

In the future, efforts will focus on the integration

of the TETRA network in the current

communication system. To do this, we must modify

both the hardware and software of the

communications architecture. On the one hand, we

must connect two new TETRA stations to the router

that manages the communications between the train

and the control center. On the other hand, we must

define a scheme for selecting the right

communications technology (GPRS/3G or TETRA)

according to the existing coverage.

ACKNOWLEDGEMENTS

This work would not have been possible without the

collaboration of EuskoTren (which is a railway

company operating in the north of Spain), and

without funding from the industry department of the

Basque Government.

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