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CHAPTER XIX

MOBILE TRAIN RADIO COMMUNICATION - LTE

19.0 This chapter covers basic technical information of Long Term Evolution
(LTE), Evolved Packet Core (EPC) and LTE based Mobile Train Radio
Communication System. This document is based on Specifications of
LTE and FRMCS developed by 3rd Generation Partnership Project
(3GPP) and International Union of Railways (UIC).

19.1 With GSM, ERA and UIC added extra functionality and called it GSM
for Rail, GSM-R. So far the indication is that UIC will try a different
approach with LTE and try to get as much functionality into the regular
LTE standard, thereby not needing to add extra specific functionality for
railways. There are some indications that LTE will end up with more
functionality that is valuable to the railway industry than GSM did in its
time. The Mobile Train Radio Communication System with LTE
technology is in the development stage.

19.2 The International Union of Railways, UIC a global organization for
Railway has set up Future Rail Mobile Communications System
(FRMCS) project to prepare the necessary steps towards the
introduction of a successor of GSM-R. The Future Railway Mobile
Communication System - FRMCS has been prepared by UIC in order
to have a Mobile Train Communication System based on LTE.

19.3 Limitations of GSM-R:-

19.3.1 As the communication demands increased and the capabilities of
electronic devices evolved, it has become necessary to support data
communication as much as voice communication. GSM-R does not
provide packet-switched transmission. Therefore, data communication
must be delivered by Circuit-Switched Data (CSD), which cannot
assign the network resources based on the actual demand. This
means that data is transmitted over virtual circuits, just like voice
frames. Being bursty in nature, data sources send varying amounts of
data at irregular intervals. Such a bursty transmission does not fit well
into a fixed circuit provided by GSM-R. As a result, circuits are often
underutilized and network resources are wasted.

19.3.2 GSM-R is becoming an obsolete technology. The predicted
obsolescence of GSM-R is by 2030.

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19.4 LTE: Long Term Evolution:-

19.4.1 Long Term Evolution (LTE) is the latest family of mobile communication
standards (4G) developed by 3rd Generation Partnership Project
(3GPP). The main requirements for the new access network are high
spectral efficiency, high peak data rates, Short round trip time as well
as flexibility in frequency and bandwidth.

19.5 Components of Long Term Evolution (LTE):-

Fig.-1: Basic EPS Architecture with E-UTRAN Access (Source: 3GPP.org)

19.5.1 The key components of the LTE network sub-system are mentioned
below:

19.5.1.1 E-UTRAN: eNodeB (Equivalent of BSS in GSM-R)
(Evolved Universal Terrestrial Radio Access Network)

The Evolved NodeB (eNodeB) is the base station for LTE radio.
eNodeB is the RAN (Radio Access Network) node in the network
architecture that is responsible for radio transmission to and reception
from UEs( User Equipment) in one or more cells. The eNodeB is
connected to EPC nodes by means of an S1 interface. The eNodeB is
also connected to its neighbor eNodeBs by means of the X2 interface.

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 Fig. 2: LTE Architecture (Source: 3GPP.org)

19.5.1.2 Serving Gateway (S-GW):
The gateways (Serving GW and Packet Data Network GW) deal with
the user plane. They transport the IP data traffic between the User
Equipment (UE) and the external networks.

The Serving GW is the point of interconnect between the radio-side
and the EPC. As its name indicates, this gateway serves the UE by
routing the incoming and outgoing IP packets.

It is the anchor point for the intra-LTE mobility (i.e. in case of handover
between eNodeBs) and between LTE and other 3GPP accesses. It is
logically connected to the other gateway, the PDN GW.

19.5.1.3 Packet Data Network Gateway (PDN-GW):
The PDN GW is the point of interconnect between the EPC and the
external IP networks. The PDN GW routes packets to and from the
PDNs. The PDN GW also performs various functions such as IP
address / IP prefix allocation or policy control and charging. 3GPP
specifies these gateways independently but in practice they may be
combined in a single "box" by network vendors.

19.5.1.4 Mobility Management Entity (MME):
The MME deals with the control plane. It handles the signalling related
to mobility and security for E-UTRAN access. The MME is responsible
for the tracking and the paging of UE in idle-mode. It is the termination
point of the Non-Access Stratum (NAS).

19.5.1.5 Home Subscriber Server (HSS):

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 The HSS (for Home Subscriber Server) is a database that contains
user-related and subscriber-related information. It also provides
support functions in mobility management, call and session setup, user
authentication and access authorization.

19.5.1.6 Policy and Charging Rules Function (PCRF):
The Policy and Charging Rules Function (PCRF), is a combination of
the Charging Rules Function (CRF) and the Policy Decision Function
(PDF), and ensures the service policy and sends Quality of Service
(QoS) information for each session begun and accounting rule
information. These policies are enforced in the eNodeB.

19.5.1.7 Policy and Charging Enforcement Function (PCEF):
The Policy and Charging Enforcement Function (PCEF) performs
policy enforcement and service data flow detection, allowing data flow
through the implemented P-GW. It is also responsible for the QoS on
IP packets in the P-GW. The PCEF enforces rules that allow data
packets to pass through the gateway.

19.5.1.8 IP Multimedia Core Network Subsystem (IMS):
IMS is an all-IP system designed to assist mobile operators deliver next
generation interactive and interoperable services, cost-effectively, over
an architecture providing the flexibility of the Internet. These services
include voice, pictures, text and video, or any combination of these with
existing services. IMS has become the core component within 3G,
cable TV and next generation fixed telecoms networks which deliver
Internet Protocol multimedia to mobile users.

Fig.3: Non-roaming architecture of 3GPP Accesses (Source: 3GPP.org)

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19.6 Features of Long Term Evolution (LTE):-

19.6.1 LTE is fully packet-switched IP-based mobile communication standard
from 3GPP. Both real time services and datacom services will be
carried out by IP protocol. LTE network assigns the network resources
to users and applications depending on the actual transmission
demand.

19.6.2 LTE introduces a simplified core network called Evolved Packet Core
(EPC) with fewer elements than in the legacy standards.

19.6.3 The new access solution, LTE, is based on OFDMA (Orthogonal
Frequency Division Multiple Access) and in combination with higher
order modulation (up to 64QAM), large bandwidths (up to 20 MHz) and
spatial multiplexing in the downlink (up to 4x4) high data rates can be
achieved.

For the downlink, OFDMA (Orthogonal Frequency Division Multiple
Access) is used and for the uplink SC-FDMA (Single Carrier -
Frequency Division Multiple Access) is used which is also known as
DFT (Discrete Fourier Transform) spread OFDMA.

The new radio interface offers much higher spectral efficiency than any
other legacy mobile communication standard. Modulation and coding
schemes are dynamically chosen in LTE based on the radio conditions
and the traffic demand. The link adaptation mechanism allows the
network to balance between throughput and reliability of the radio
transmission.

Fig.-4: OFDMA and SC-FDMA (Source: 3GPP.org)

19.6.4 Frequency:
LTE is developed for a number of frequency bands – E-UTRA
operating bands- currently ranging from 450 MHz up to 5.925 GHz.
LTE supports both the time division duplex technology (TDD) as well
as frequency division duplex (FDD).

19.6.5 Spectral Flexibility:

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19.6.5.1 E-UTRA shall operate in spectrum allocations of different sizes,
including 1.4, 3, 5, 10, 15 and 20 MHz as per 3GPP/ETSI in both the
uplink and downlink. Operation in paired and unpaired spectrum are
supported.

19.6.5.2 The system shall be able to support content delivery over an
aggregation of resources including Radio Band Resources (as well as
power, adaptive scheduling, etc) in the same and different bands, in
both uplink and downlink and in both adjacent and non-adjacent
channel arrangements. A “Radio Band Resource” is defined as all
spectrum available to an operator.

19.6.6 Peak data rate (Spectral Efficiency):

19.6.6.1 Instantaneous downlink peak data rate of 100 Mb/s within a 20 MHz
downlink spectrum allocation (5 bps/Hz)

19.6.6.2 Instantaneous uplink peak data rate of 50 Mb/s (2.5 bps/Hz) within a
20MHz uplink spectrum allocation)

19.6.6.3 The highest theoretical peak data rate on the transport channel is 75
Mbps in the uplink, and in the downlink, using spatial multiplexing, the
rate can be as high as 300 Mbps.

19.6.7 Transmission Latency: The LTE (4G) supports low transmission
latency both in User plane and Control Plane. The time taken for data
to travel in the air interface between UEs (mobile) to eNodeB (base
station) is achieved to be less than 5 ms (User Plane) and time taken
for a UE to switch from standby IDLE state to ACTIVE state is less than
100 ms (Control Plane). The User Plane and Control Plane
transmission latency are further improved in the 5G system.

19.6.8 Control-plane capacity :
At least 200 users per cell should be supported in the active state for
spectrum allocations up to 5 MHz.

19.6.9 Mobility:

19.6.9.1 E-UTRAN should be optimized for low mobile speed from 0 to 15 km/h.

19.6.9.2 Higher mobile speed between 15 and 120 km/h should be supported
with high performance.

19.6.9.3 Mobility across the cellular network shall be maintained at speeds from
120 km/h to 350 km/h.

19.6.10 Coverage:

The Coverage i.e. Cell range depends on various factors like Cell edge
throughput requirement, available spectrum and spectrum efficiency

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 and mobility target etc. Approximate Cell ranges for 700 MHz LTE and
its Cell edge throughput are given below:-

700 MHz LTE Spectrum & cell range

Cell Edge User 512 256 128 64
Throughput (Kbps)

UL Cell Range (Km) 0.70 1.21 3.37 8.48

19.6.11 Enhanced Multimedia Broadcast Multicast Service (MBMS) :

19.6.11.1 While reducing terminal complexity: same modulation, coding, multiple
access approaches and UE bandwidth than for unicast operation.

19.6.11.2 Provision of simultaneous dedicated voice and MBMS services to the
user.

19.6.11.3 Available for paired and unpaired spectrum arrangements.

19.6.12 Co-existence and Inter-working with 3GPP Technology :

19.6.12.1 Co-existence in the same geographical area and co-location with
GERAN/UTRAN on adjacent channels.

19.6.12.2 E-UTRAN terminals supporting also UTRAN and/or GERAN operation
should be able to support measurement of, and handover from and to,
both 3GPP UTRAN and 3GPP GERAN.

19.6.12.3 The interruption time during a handover of real-time services between
E-UTRAN and UTRAN (or GERAN) should be less than 300 msec.

19.6.13 Architecture and migration :

19.6.13.1 Single E-UTRAN architecture

19.6.13.2 The E-UTRAN architecture shall be packet based, although provision
should be made to support systems supporting real-time and
conversational class traffic

19.6.13.3 E-UTRAN architecture shall minimize the presence of “single points of
failure”

19.6.13.4 E-UTRAN architecture shall support an end-to-end QoS

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19.6.13.5 Backhaul communication protocols should be optimized

19.6.14 Radio Resource Management requirements :

19.6.14.1 Enhanced support for end to end QoS

19.6.14.2 Efficient support for transmission of higher layers

19.6.14.3 Support of load sharing and policy management across different Radio
Access Technologies

19.6.15 Complexity :

19.6.15.1 Minimize the number of options

19.6.15.2 No redundant mandatory features

19.6.16 LTE is the latest family of mobile communication standards. Hence, it
has much lower obsolescence risk than any of the previous standards.

19.7 Mobile Train Radio Communication System (LTE) :-

Fig.5:- LTE Architecture

LTE for Railways consists of User Equipment, Evolved Universal
Terrestrial Radio Access Network, Evolved Packet Core, IP Multimedia
Subsystem (IMS)/ Session Initiation Protocol (SIP) Core and various
Applications/Solutions Servers on LTE. The LTE systems are
compatible with modern train automation systems like European Train
Control System (ETCS) or similar and also interoperable with other
legacy mobile communication systems such as GSM and UMTS.

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19.8 Communication Requirement of Railways through LTE (Future
Railway Mobile Communication System):-

This section looks at various Railway requirements/features as listed
by UIC and how it can be satisfied using the LTE based
architecture. Indian Railways may include its all other specific
requirements as implemented in GSM-R.

19.8.1 Users in FRMCS:

The following users are those identified to be users within this
document and may not be necessarily conclusive within FRMCS:-
Driver(s)
Controller(s)
Train staff:
o Train conductor(s)
o Catering staff
o Security staff
Trackside staff:
o Trackside maintenance personnel
o Shunting team member(s)
Railway staff (excl. all of above):
o Engine scheduler(s)
o RU operator(s)
o Catering scheduler(s)
o IM operator(s)
o Engineering personnel
Station manager(s)
o Station personnel
o Depot personnel
o Etc.
Members of the public:
o Passengers (on trains, on platforms, at stations, etc.)
o Other persons (on platforms, at level crossings, etc.)
Systems:
o ATC on-board system
o ATO on-board system
o On-board system
o Ground system
o Trackside warning system
o Trackside system
o Sensors along trackside
o Trackside elements controlling entities (such as, for example,
for level crossings)
o Applications (such as, for example, those for monitoring lone
workers, for remote controlling of elements)
Network operator
Public emergency operator

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19.8.2 Communication requirements:-

Critical: applications that are essential for train movements and
safety or a legal obligation, such as emergency communications,
shunting, presence, trackside maintenance, ATC, etc.
Performance: applications that help to improve the performance of
the railway operation, such as train departure, telemetry, etc.
Business: applications that support the railway business operation
in general, such as wireless internet, etc.

These are the following sub-sections which are in line with the UIC
FRMCS document.

Critical Communication Applications
Performance Communication Applications
Business Communication Applications
Critical Support Applications
Performance Support Applications
Business Support Applications

Fig.-6: Grouping of FRMCS Applications (Source: uic.org)

19.8.3 Critical Communication Applications:-

19.8.3.1 On-train outgoing voice communication from the driver towards the
controller(s) of the train:
The driver shall be able to initiate a voice communication to any
controller that was, is, or will be responsible for the movement of the
train.

19.8.3.2 On-train incoming voice communication from the controller towards a
driver:
An authorized controller shall be able to set up a voice communication
to a driver.

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19.8.3.3 Multi-train voice communication for drivers including ground user(s):
The driver shall be able to set up a voice communication with entitled
ground user(s) and/or other drivers. A ground user shall be able to set
up a voice communication with drivers and other entitled ground
user(s). The selection could be based on the location of the train, on
the track configuration, etc. using a functional identity. The voice
communication can be bi-directional or uni-directional.

19.8.3.4 Banking voice communication:
Drivers of different locomotives within the same train shall be able to
set up voice communication. During the ongoing voice communication
an entitled controller can connect to the communication without any
action of the driver(s). The driver is able to invite an entitled controller
to connect to the communication.
Note – the different locomotives within the same train may or may not
be coupled mechanically and/or electrically.

19.8.3.5 Trackside maintenance voice communication:
A trackside worker or controller shall be able to set up a voice
communication with other authorized users. The voice communication
can be bi-directional or unidirectional.

19.8.3.6 Shunting voice communication:
A shunting user shall be able to set up an uninterrupted voice
communication with other shunting users and/or with entitled
controller(s). The voice communication could be a user-to-user or
multi-user communication. The entitled controller and other shunting
users are addressed by the system automatically (for example, based
on location, operational situation etc.).

19.8.3.7 Public emergency call:
A user is able to make a public emergency call.

19.8.3.8 Ground to ground voice communication:
A ground user shall be able to set up voice communication to another
ground user.

19.8.3.9 Automatic train control communication:
The provision of a reliable communication bearer to support the
implementation of radio based ATC systems. The ATC system shall
have a reliable communication bearer in order to ensure efficient data
transfer between the on-board system and the ground system. (for
example ETCS L2/L3, CBTC, CTCS) , or between a train and other
trains or between a train and other trackside elements. This application
provides the communication bearer for this data,

19.8.3.10 Automatic train operation communication:
The ATO system shall have a reliable communication bearer in
order to ensure efficient data transfer between the on-board unit
and the ground system, or between a train and other trains or

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 between a train and other trackside elements. This application
provides the communication bearer for this data.
The ATO system components (on-board unit, the ground system or
other ATO entities in the trackside) may broadcast information to
other ATO system components.
This application may include real time video between the on-board
and the ground system (for example a train mounted front camera)
or between other ATO system components.

19.8.3.11 Data communication for Possession management:
The application shall support the processes involved in taking
possession of an area of railway infrastructure for engineering
purposes (for example for track maintenance).

19.8.3.12 Trackside maintenance warning system communication:
The trackside maintenance warning system shall be able to initiate
data communication to trackside maintenance workers in the
appropriate area.

19.8.3.13 Remote control of engines communication:
It shall be possible to set up data communication between an engine
and a ground based system in order to control the engine. The remote
driver can operate the engine via the ground system.

19.8.3.14 Monitoring and control of critical infrastructure:
It shall be possible to set up data communication between
infrastructure systems and a ground based or train based system in
order to monitor or control critical infrastructure such as train detection,
signals and indicators, movable infrastructure, level crossing elements,
including barrier controls vehicle sensors, lighting controls and alarms.

19.8.3.15 Railway emergency communication:
An authorized user shall be able to set up a railway emergency
communication to other users within an automatically configured area
or group, which is based upon the originator’s location or
characteristics and those users likely to be affected by the emergency

19.8.3.16 On-train safety device to ground communication:
Based on a critical situation in the train (for example, triggered by a
Driver Safety Device (DSD)), a voice and/or data communication is
automatically set up towards a ground user (controller or ground
system).

19.8.3.17 Public train emergency communication:
This application allows any entitled user involved in train operations
to alert, via a voice and/or data communication, the drivers of the
concerned trains of a safety related incident in the vicinity of railway
infrastructure; for example, at a platform environment or a level
crossing: a person falling from a platform or slipping between train

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 and platform or a car being stuck on a level crossing. An entitled
user in this case could be a member of the public.
The controller of the affected track/line(s) shall also be made aware
of the alert and shall be able to have voice communication with the
alert initiator.

19.8.3.18 Working alone:
The system shall be able to monitor the status (location, movements,
health, etc.) of a user working alone. Once the application is active, the
application can trigger voice and/or data communication applications
based on the status of the worker.

19.8.3.19 Voice Recording and access to the recorded data:
It shall be possible to enable the recording of, and access to,
communication content and the communication related data in order to
support analysis.

19.8.3.20 Data recording and access:
It shall be possible to enable the recording of, and access to,
communication content and the communication related data in order to
support analysis.

19.8.3.21 Shunting data communication:
A shunting user (e.g. the shunting leader) shall be able to set up an
uninterrupted data communication with other shunting users (e.g. the
driver) and/or with entitled controller(s)/traffic control system. The
purpose of this data communication is issuing request/commands and
confirmations related to shunting operation. The entitled controller and
other shunting users are addressed by the system automatically (for
example, based on location, operational situation etc.).

19.8.3.22 Train integrity monitoring data communication:
The train integrity monitoring system shall have a reliable
communication bearer in order to ensure safety related data be
transfered between the components monitoring train integrity. The
FRMCS system shall provide the communication bearer for this data
exchange.

19.8.3.23 Public emergency warning:
A user is able to receive a public emergency warning initiated by the
Public Safety Authority.

19.8.3.24 On-train outgoing voice communication from train staff towards a
ground user:
The train staff shall be able to initiate a voice communication to any
ground user.

19.8.3.25 On-train incoming voice communication from a ground user towards
train staff

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 A ground user shall be able to initiate a voice communication to train
staff.

19.8.3.26 Railway staff emergency communication:
An authorized user, is able to set up a railway staff emergency
communication to other users within an automatically configured area
or group. The area or group is based upon the originator’s location or
characteristics and includes those users likely to assist the originator
with the emergency.

19.8.3.27 Critical Real time video:
This application facilitates the data communication for real time
transmission of video images (“video images” may also refer to images
coming from other sources, e.g. lidar and/or radar sensors) for critical
railway operation. This includes the control of camera movements and
–zoom.

19.8.3.28 Critical Advisory Messaging services- safety related:
A user shall be able to send and/or receive critical messages, safety
related, like (predefined or any) text or pre-recorded voice messages to
instruct railway staff about the usage of the infrastructure (for example
speed restrictions, overriding of a stopping point). Messages can be
exchanged on user-to-user or on multi-user level.

19.8.3.29 Virtual Coupling data communication:
The Virtual Coupling system shall have a reliable communication
bearer in order to ensure that the safety related data is transferred
between the components making part of the Virtual Coupling system.
The FRMCS system provides the communication bearer for this data
exchange.

19.8.3.30 On-train wireless backbone communications:
The enabling of a train-wide communication network requires the
provision of a reliable communication bearer to support the
implementation of the Wireless Train Backbone (WLTB). The WLTB
shall have a reliable communication in order to ensure the efficient data
transfer between the on-train Wireless Train Backbone nodes of each
rolling stock element in a single train. The FRMCS system provides the
communication bearer for this data exchange.

19.8.3.31 Train parking protection:
An authorized user shall be able to store information about the
protection means of a parked train in a centralized application. The
information can be entered manually or be generated by a sensor.

19.8.4 Performance Communication Applications:-

19.8.4.1 Multi-train voice communication for drivers excluding ground user(s):

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 A driver shall be able to set up a voice communication to all drivers
within an automatically configured area that is based upon the
originator’s location.

19.8.4.2 On-train voice communication:
A member of the train staff shall be able to initiate a voice
communication with one or multiple other members of the train staff (of
the same train)

19.8.4.3 Lineside telephony:
A user shall be able to set up a voice communication to an entitled
controller via lineside telephony.

19.8.4.4 On-train voice communication towards passengers (public address):
A user shall be able to broadcast voice information to all
passengers of one or multiple trains.
The broadcasted information could be real-time or pre-recorded.

19.8.4.5 Station public address:
A user shall be able to broadcast vocal information to all
passengers at specific locations such as station concourses and
platforms.
The broadcast information could be real-time or pre-recorded.

19.8.4.6 Communication at stations and depots:
The station or depot user shall be able to set up a voice communication
with other user(s).

19.8.4.7 On-train telemetry communications:
It shall be possible to set up data communication between on-train
systems (on the same train or between 2 different trains) or between
on-train systems and a ground based system.

19.8.4.8 Infrastructure telemetry communications:
It shall be possible to set up data communication between
infrastructure systems and/or a ground based system (for example, to
support demand forecasting and response, equipment supervision
etc.).
Note: the data communication can be permanent or intermittent.

19.8.4.9 On-train remote equipment control:
A ground based system shall be able to initiate a data communication
to relevant on train systems for control purposes,

19.8.4.10 Monitoring and control of non-critical infrastructure:
It shall be possible to set up data communication between non-critical
infrastructure systems and railway staff or a ground based or an on-
board system in order to monitor and control those infrastructure
systems remotely.

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19.8.4.11 Non-critical Real time video:
This application facilitates the data communication for real time
transmission of video images for non-critical railway operation. This
includes the control of camera movements and –zoom.

19.8.4.12 Wireless on-train data communication for train staff:
Train staff shall be able to use intranet/internet services via a wireless
connection in a train.

19.8.4.13 Wireless data communication for railway staff on platforms:
It shall be possible for railway staff or railway systems to use
intranet/internet services via a wireless connection in railway areas (for
example platforms, station areas etc.).

19.8.4.14 Train driver advisory - train performance:
A user shall be able to set up data communication to provide advisory
information to the train driver in order to optimize the train journey (for
example Driver Advisory System (DAS), Traffic management (TM),
Power consumption management).

19.8.4.15 Train departure data communications:
A user shall be able to set up data communications with other involved
users to support the station departure processes.

19.8.4.16 Messaging services:
A user shall be able to send and receive non-critical messages like
text, recorded voice (for example voicemail), data, pictures, video.
Messages can be exchanged on user-to user or a user-to-multi user
level.

19.8.4.17 Transfer of data:
Transfer of recorded data for post-accident/incident analysis (for
example, CCTV, JRU, energy metering data), or any other data that
requires to be transferred between users, for example, data from train
staff, time table data.

19.8.4.18 Record and broadcast of information:
A user shall be able to record a voice or a video information that can
subsequently be transmitted to selected users based on their identity
and/or location.

19.8.4.19 Transfer of CCTV archives:
A user shall be able to bulk transfer CCTV archives between on-board
systems or between on-board system and a ground system.

19.8.4.20 Real time video call:
A user shall be able to setup a real time video call to other user(s).

19.8.4.21 Augmented reality data communication:

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 A user shall be able to setup an augmented reality data
communication to the ground system. The ground system overlays
information to the video stream presented to the user.
Once a user is connected to the ground system, the controller is
able to view the augmented reality images visible for the user.
The controller is able to add information (or guidance) via the
ground system in the augmented reality view which is visible to the
user.

19.8.5 Business Communication Applications :-

19.8.5.1 Information help point for public:
A member of the public shall be able to set up a voice communication
with the responsible ground user or train staff.

19.8.5.2 Emergency help point for public:
A member of the public shall be able to set up an emergency voice
communication that will be automatically routed to the most appropriate
ground user, train staff or driver.

19.8.5.3 Wireless internet on-train for passengers:
It shall be possible for passengers to use internet services via a
wireless connection in a train.

19.8.5.4 Wireless internet for passengers on platforms:
It shall be possible for passengers to use internet services via a
wireless connection in railway area(s) (for example platforms, station
area(s) etc.).

19.8.6 Critical Support Applications:-

19.8.6.1 Assured Voice Communication
The Assured Voice Communication application shall provide a clear
indication to the users as soon as an end-to-end voice communication
link is broken or as long as the end-to-end communication link is active.

19.8.6.2 Multi user talker control:
The system shall be able to limit the number of simultaneous talkers
in a multi-user voice communication.
An entitled user shall be able to select and de-select user(s) being
able to talk in a multi-user voice communication.

19.8.6.3 Role management and presence:
A user shall be able to register and deregister to one or more
functional identity/ies. A user is able to see which other functional
identities are present within a certain context (for example train,
region, communication group, Railway Emergency Communication,
etc.). Further it shall be possible for the user to identify at any time
the function / person who is talking (for example driver, train staff,
maintenance staff, platform staff, controller, etc.).

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 This application will be responsible for handling the railway role
management of the users including the identity registration and
deregistration processes.

19.8.6.4 Location services:
The system shall be able to store and provide the location of the
user(s) or devices.

19.8.6.5 Authorization of communication:
The system shall be configurable, so that access to voice and data
communications can be controlled through the use of identities.

19.8.6.6 Authorization of application:
The system shall be configurable, so that access to applications can be
controlled through the use of, for example: identity; user; user-to-user;
multi-user; location, etc. The system is able to authorize access to
applications.

19.8.6.7 QoS Class Negotiation:
The system shall be able to assign different QoS classes in order to
fulfill the level of communication quality required by the applications.

19.8.6.8 Safety application key management communication:
The applications on board shall be able to authenticate the source of
the messages received as a trusted source, and shall be able to detect
corruption of the messages received.

19.8.6.9 Assured data communication:
The assured data communication application shall provide a clear
indication to the users as soon as an end-to-end data communication
link is broken or as long as the end-to-end communication link is active.

19.8.6.10 Inviting-a-user messaging:
A user can send a message to another user(s) inviting him to join the
ongoing voice communication.

19.8.6.11 Arbitration:
The system shall be able to perform arbitration between
communications competing for the attention of the user.

19.8.7 Performance Support Applications:-

None applicable.

19.8.8 Business Support Applications:-

19.8.8.1 Billing information:
An entitled user shall be able to obtain information for any type of on-
network communication from the FRMCS system in order to be able to
generate bills.

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19.9 LTE System Architecture for Indian Railways:-

Installing an Ultra-high-speed LTE based communication corridor along
IR network would cater to the current and future data and voice needs
for Train-Ground and Train-Train communication for improved train
operations, passenger safety and passenger security services and
remote rail asset monitoring & management. The applications of LTE
can be classified under the following three broad categories:-

19.9.1 Passenger Safety & Service:

Advanced Signalling systems like European Train Control System
(ETCS) Level 2/Train Collision Avoidance System (TCAS).
Emergency communications from train to control, train to stations
and between train to train, etc.
Increased carrying capacity (throughput) Advanced signaling
systems allow more trains to run across a given point or segment of
the track which effectively increase the carrying capacity
(throughput) of the same fixed civil and electrical infrastructure.

19.9.2 Live surveillance camera feeds from trains will ensure security of
passengers coupled with video analytics, this can help in prevention
and detection of crime, not only in Indian Railways network but also
outside in the peripheral areas.

19.9.3 Internal improved Railway management:

Staff communication system.
Remote monitoring of Railways asset to improve their availability.

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 Fig.-7: LTE-R System Architecture for Indian Railways

19.9.4 Indian Railway envisages following applications/facilities which will fuel
growth in data usage on deploying LTE technology:

i) Indian Railway Automatic Train Protection System (IRATP)
through Train Collision Avoidance System (TCAS) which is planned for
up gradation to ETCS Level 2 in future or any other similar systems as
specified by Indian Railways.
ii) Mission Critical Push To Talk (MC PTT) application
iii) Video Surveillance System in locomotives for Level Crossing
Gate/ Tunnels/ Bridges.
iv) Onboard Passenger Information System (PIS) consisting of
passenger information display and passenger announcement system.
v) Internet of Things (IoT) based Asset reliability monitoring.
vi) Onboard Video Surveillance System (VSS) for Passenger
Security.
vii) Broadband Internet on Running Train (Onboard Wi-Fi facility
through LTE).

19.10 TRAI Frequency Band Allocation:-

5 MHz (paired) Spectrum in 700 MHz band (703-748 MHz Uplink &
758-803 MHz Downlink, also specified as Band 28 in 3GPP/ETSI
standards) has been allocated to Indian Railways for implementing
above services.

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19.11 LTE FDD System Throughput :-

No of MIMO All Transmission
SISO Transmit
Transmission Useabl 2x2 Mode
Mode/Syste e
m Bandwidth Resour Downli Uplink Uplink
Downlink Downlink
ce nk Peak Peak
Peak Peak
Block Peak (Mbps) (Mbps)
(Mbps) (Mbps)
(Mbps) 16 QAM 64 QAM
1.4 MHz 6 4.4 4.4 8.8 3 4.4
3 MHz 15 11.1 11.1 22.1 7.5 11.1
5 MHz 25 18.3 18.3 36.7 12.6 18.3
10 MHz 50 36.7 36.7 75 25.5 36.7
15 MHz 75 55.1 55.1 110 37.9 55.1
20 MHz 100 75 75 150 51 75

Table.-2: LTE FDD System Throughput

19.12 Uniform Numbering Scheme for Mobile Communication Network
for Indian Railways :-

A) All mobile users in the LTE network must be assigned a certain
addresses or identities in order to identify, authenticate and localize
them. The following numbers and identities are assigned for
administration of each mobile station in the network.
i) IMSI : International Mobile Subscriber Identity

The IMSI is a string of decimal digits, up to a maximum length of
15 digits, which identifies a unique subscription. The IMSI
consists of three fields: the mobile country code (MCC), the
mobile network code (MNC), and the mobile subscription
identification number (MSIN).

▪ Mobile country code (MCC): The MCC is the first field of
the IMSI and is three digits in length and identifies a
country.
▪ Mobile network code (MNC): The MNC is the second field
of the IMSI, it is two or three digits in length and is
administered by the respective national numbering plan
administrator.
▪ Mobile subscription identification number (MSIN): The
MSIN is the third field of the IMSI, it is up to 10 digits in
length, and is administered by the relevant MNC
assignee to identify individual subscriptions.

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 Fig.-8 : Structure and Format of IMSI (Source ITU)

ii) MS ISDN : Mobile Subscriber International Subscriber Directory
Number

Mobile Station/Subscriber International Subscriber Directory
Number (MSISDN) is a number (Mobile Phone Number) used to
identify a mobile phone number internationally.

The MSISDN composition follows the international ISDN
numbering plan with the following structure:

▪ Country Code (CC), up to three digits;
▪ National Destination Code (NDC), typically two or three
digits;
▪ Subscriber Number (SN), a maximum of 10 digits.

The structure of the MSISDN will then be as shown in figure:

Fig.-9 : Number Structure of MSISDN (Source 3GPP)

RDSO has approved and issued Uniform Numbering Scheme for
Mobile Communication Network (GSM-R) for Indian Railways. The
same scheme shall be applicable for LTE.

The IMSI and MSISDN for Indian Railway shall be as below:-

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 Fig.-10 : IMSI

Fig.-11 : MSISDN

19.14 Adaptation of LTE on Indian Railways:-

Indian Railway is migrating from GSM-R to LTE for Railway Automation
System and Broadband Services. It is proposed that the future projects
of Railway Automation System and Broadband Services may be

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 designed with LTE. It is also required that LTE system proposed for
Indian Railways should be fit for bearer network for TCAS/ETCS Level
2/3 for desired speed.

-x-x-x-

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