Practical LTE based security forces PMR networks / Arnaud Henry-Labordere.

Format:

Book

Author/Creator:

Henry-Labordère, A., author.

Series:

River Publishers Series in Security and Digital Forensics Series

Language:

English

Subjects (All):

Mobile communication systems--Security measures.

Mobile communication systems.

Physical Description:

1 online resource (356 pages).

Edition:

1st ed.

Place of Publication:

Denmark : River Publishers, [2018]

Summary:

It can be used as a reference or textbook, with many detailed call flows and traces being included. The author, who has also a long teaching career in Operations Research, provides mathematical models for the optimization of tactical network federations, multicast coverage and allocation of preemptive priorities to PMR group members.

Contents:

Cover

Half Title

Series

Title

Copyright

Contents

From the Same Author

List of Figures

List of Tables

1 Introduction

2 LTE PMR Networks: Service, Seamless Federation of Tactical Networks, Backup by the Public Operators' Coverage, and Direct Calls

2.1 PMR tactical network elements

2.2 PMR tactical networks' federation

2.2.1 Operational needs' summary

2.2.2 Radio planning and IP addressing of the various federated tactical networks

2.2.3 Radio planning for mobility between tactical bubbles of a federation: Requirements and solution

2.2.4 Initial configuration of a user to associate with its assigned group

2.3 Federation method for N−1 concurrent networks with one taking the central role

2.3.1 Architecture description

2.4 Using the multicast for MCPTT and federating MBFSN areas

2.4.1 Introduction to eMBMS

2.4.1.1 Broadcast mode

2.4.1.2 Multicast mode

2.4.2 Attachment of a tactical network in an existing federation: GCS AS-centric architecture

2.5 MBMS extension of the radio coverage of the new joining tactical network

2.5.1 Crude basic federation (cross-copying) active service to another service area

2.5.2 Federated MCEs or central MCE?

2.5.2.1 MBMS LTE channels

2.5.2.2 Meaning of "MBMS synchronization," role of the central or coordinated MCE

2.5.2.3 Behavior of an MBMS-enabled UE

2.5.2.4 Optimization of the MBMS channel allocation between federated groups

2.5.2.5 Meaning of MBMS synchronization, role of the MCE

2.6 Overview of a PMR or local loop network architecture: Inclusion of direct calls' support

2.6.1 PMR HLR-HSS capabilities and architecture

2.6.2 Proximity services (ProSe)

References

3 Geo-Localization of PMR Group Members and Monitoring of the Quality of Service with the ECID Method.

3.1 Operational need for a geo-localization service in PMR networks

3.2 Localization methods in tactical networks

3.2.1 Enabling the LPP protocol in the UEs

3.2.2 Using SUPL as main geo-localization protocol

3.3 ECID positioning method (LPP control plane) using a graphic interface

3.4 Cell database for the ECID method yielding the UE received signal level

3.5 Why not use GPS positioning method (LPP control plane)?

3.6 ECID method: Calculation of the physical measures from the measurements received from the UE

3.6.1 RSRP measurement → Dbm values for signal level at the UE

3.6.2 UE Rx-Tx → distance estimate between UE and eNodeB

3.6.3 Field results and coverage comparisons between various eNodeBs

3.6.4 Operational use and presentation of the ECID method results in PMR tactical networks

4 Choice of the SIM Card Type for PMR or M2M Networks and Automatic Profile Switching Possibilities

4.1 Classical UICC, eUICC M2M, or eUICC "consumer" SIM cards

4.1.1 Usage difference

4.1.2 Difference of logical structure between UICC and eUICC

4.1.2.1 eUICC

4.1.2.2 UICC

4.1.2.3 Recent file additions for all card types

4.2 Remote provisioning system for eUICC (M2M and consumer)

4.2.1 Explanation of the remote provisioning figure

4.3 eUICC and UICC profile switching methods

4.3.1 Add IMSI with its own security domain in UICC by OTA

4.3.1.1 Logical organization of a multi-security domain UICC SIM card

4.3.1.2 Add a new IMSI with its own security domain

4.3.1.3 Summary of the applet management commands

4.3.2 Updating the OTA security keys KiC and Kid in multi-IMSI UICC cards

4.4 Is it possible to reduce the automatic network switching time VPLMN → HPLMN?

4.4.1 The TS 23.122 3GPP standard

4.4.1.1 Automatic network selection mode procedure.

4.4.1.2 (In VPLMN) automatic and manual network selection modes

4.4.1.3 Reducing the timer T

4.5 OTA provisioning of the SIM: "card initiated OTA SIM with IP" or "network initiated" using SMS

4.5.1 OTA SIM over IP

4.5.1.1 Legacy network initiated

4.5.1.2 Card initiated

4.5.2 Card initiated mode with a data connection to the OTA IP server

4.5.2.1 BIP/CAT-TP

4.5.2.2 OTA over https

4.5.3 Network initiated SMS triggering of a SIM IP connection (BIP/CAT-TP or https) to the OTA server

4.5.4 GSMa SP02 v3.2

4.6 Profile update of the security domain and protection against the cloning of a stolen SIM

4.7 Application provisioning in the device (not in the SIM card)

4.8 Is being a full MVNO justified for an autonomous car manufacturer?

4.8.1 Current high latency connected applications from the car to the manufacturer

4.8.2 The next big thing: Autonomous vehicle with sensors

4.8.3 Data trafic costs comparison between local IMSI and full MVNO

4.8.4 Security discussion: Local IMSI compared to own IMSI as a full MVNO

4.8.5 Supplementary features provided by the full MVNO model

4.8.6 Minimum setup for a car manufacturer to manage their SIMs: OTA-IP server

4.8.6.1 Need to have its own OTA server for its own management of the SIMs and the SW updates

4.8.6.2 Consequence: The card manufacturer must be a full MVNO

4.8.6.3 Summary table of the 2018 solutions for car manufacturers

5 Group Communication Provisioning by OTA, SMS 4G, and SMS IMS

5.1 Operational need for OTA provisioning in PMR networks

5.2 SMS service convergence 2G, 3G, 4G, SIP, and SMPP in other non-PMR cases

5.3 SMS in the EUTRAN 4G domain

5.4 SMS procedure to handle destinations in 4G networks

5.4.1 SMS procedure and call flow

5.4.2 Virtualized type 1 implementation example.

5.4.3 HLR-HSS interrogation with MAP/SS7 (3GPP TS 29.002)

5.4.4 HLR-HSS interrogation with S6c/diameter (3GPP TS 29.338)

5.4.5 SIP registration in the SM-IP-GW to receive SMS with SIP MESSAGES

5.4.5.1 Standard 3GP registration for SIP message reception

5.4.5.2 MAP traces for ANY-TIME-MODIFICATION IP-SM-GW → HLR-HSS

5.4.5.3 Standard 3GP deregistration for SIP message reception

5.4.5.4 Registration of the reachability for SMS in the IP-SM-GW with MAP NOTE SUBSCRIBER DATA MODIFIED

5.4.5.5 Simpler registration for SIP message reception (recommended)

5.5 Detailed procedure for SMS-MT and SMS-MO single segment

5.5.1 SMS-MT

5.5.2 SMS-MO

5.6 Long SMS with segmentation

5.6.1 Long SMS-MT from 3G to a 4G coverage handset

5.6.2 The 4G resends (SMS-MO) the long SMS received from the 3G

5.7 Application to OTA SIM in pure PMR 4G networks

5.8 Mobile and fixed number portability with Dx/diameter to send SMS to IMS networks

5.8.1 LIR/Cx/diameter is the equivalent IMS of a legacy 3G MAP SEND ROUTING INFO req

5.8.2 Principle of the use of the location-information-request/Cx diameter to resolve the portability

5.8.3 Fixed ↔ mobile portability

5.8.4 How to implement the portability of a number in the ported-out network

5.9 3G ↔ SIP MMS interworking

5.9.1 SIP receiving of 3G MMS

5.9.2 Sending an MMS from the SIP client to a 3G UE

6 Multicast: MCPTT PMR, MOOC Teaching, and TV in Local Loop Networks (RTTH)

6.1 Operational need for multicast in PMR networks

6.2 Triple play, the need for multicast TV and massive open online course (MOOC)

6.3 Quantitative elementary modeling of the fiber vs 4G local loop choice

6.3.1 Average distance center - household with fibering

6.3.2 Cost model for the fibering solution to the home (FTTH) vs 4G Radio (RTTH)

6.4 3GPP multicast architecture.

6.5 Detailed call flow of an MBMS session

6.5.1 Overall call flow

6.5.2 M3/diameter messages MCE ↔ MME: Role of the MCE

6.5.3 M2/diameter messages eNodeB ↔ MCE

6.5.4 "Joining" (MBMS multicast activation by the user) GC1 UE → application server

6.6 Centralized or distributed multicast coordination entity (MCE)

6.7 MBMS delivery and eMBMS-capable device stack

6.7.1 Group communication delivery appeared in [6.7 Rel 13]

6.7.2 Transparent delivery appeared in [6.7 Rel 14] and other modes

6.8 Interoperability: Intergroup and interagency communication

6.9 Architecture with virtual machines

7 Integration of IMS and VoLTE in the PMR Networks and the MNOs, Details on the PCC Processing, and Access Using a Non-trusted WLAN (WiFi with an ePDG)

7.1 WiFi and VoLTE4G access to a PMR central core network

7.2 Operational need for VoLTE in PMR networks

7.3 Reminder of the VoTT architecture for a pure VoIP MNO

7.3.1 Public identity for VoTT VoIP vs LTE

7.3.2 VoTT VoIP network architecture

7.4 IMS-based PMR network architecture for the services

7.4.1 Equivalence between 3G/2G notions, VoLTE/IMS, WiFi EAPsiim/VoTT, and SIP VoTT

7.4.2 Equivalence between 3G/4G notions and the equivalent in IMS (mobility management of Cx/diameter)

7.4.3 Incoming call (protocol Cx/diameter)

7.4.4 IMS subscriber's services' management (protocol Sh/diameter)

7.5 Call flow of the IMS services

7.5.1 IMS registration: Voice calls

7.5.1.1 Authentication of the subscriber, VoLTE and OTT VoIP compatible core IMS: MAR and MAA/Cx messages

7.5.1.2 Registration in the HSS to be able to receive calls and SMS

7.5.1.3 De-registration of a subscriber

7.5.2 Handling of incoming calls or SMS from the PSTSN or the SS7 network

7.5.2.1 Emergency call handling in IMS with calling party localization

7.5.2.2 SMS.

7.5.2.3 Charging of the calls and SMS.

Notes:

Description based on print version record.

ISBN:

1-000-79622-1

1-00-333912-3

1-003-33912-3

1-000-79345-1

87-93609-78-7

9781003339120

OCLC:

1056071722