The Public Safety LTE & Mobile Broadband Market is Booming Globally with CAGR of 45% during period 2017-2030

Until recently, LTE has predominantly been considered a supplementary mobile broadband technology in the public safety sector, to provide high-bandwidth data applications that cannot be delivered over existing narrowband LMR (Land Mobile Radio) systems. However, with the standardization of capabilities such as MCPTT (Mission-Critical PTT) by the 3GPP, LTE is increasingly being viewed as an all-inclusive critical communications platform for the delivery of multiple mission-critical services ranging from PTT group communications to real-time video surveillance.

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A number of dedicated public safety LTE networks are already operational across the globe, ranging from nationwide systems in the oil-rich GCC (Gulf Cooperation Council) region to citywide networks in Spain, China, Pakistan, Laos and Kenya. Among other notable engagements, several "early builder" networks are operational in the United States – that will subsequently merge with the wider FirstNet nationwide system; early pilot LTE networks for the Sate-Net program are in the process of being commercialized in South Korea; and Canada is beginning to see its first dedicated LTE network deployments, starting with the Halton Regional Police Service.

However, the use of LTE in the public safety sector is not restricted to dedicated networks alone. For example, the United Kingdom Home Office is in the process of deploying an ESN (Emergency Services Network) that will use British mobile operator EE’s commercial LTE RAN and a dedicated mobile core to eventually replace the country's existing nationwide TETRA system. The secure MVNO (Mobile Virtual Network Operator) model is already being used in multiple European countries, albeit at a smaller scale – to complement existing TETRA networks with broadband capabilities. In addition, this approach also beginning to gain traction in other parts of the world, such as Mexico.

Driven by demand for both dedicated and secure MVNO networks, SNS Research estimates that annual investments in public safety LTE infrastructure will surpass $800 Million by the end of 2017, supporting ongoing deployments in multiple frequency bands across the 400/450 MHz, 700 MHz, 800 MHz, and higher frequency ranges. The market – which includes base stations (eNBs), mobile core and transport network equipment – is further expected to grow at a CAGR of nearly 45% over the next three years. By 2020, these infrastructure investments will be complemented by up to 3.8 Million LTE device shipments, ranging from smartphones and ruggedized handheld terminals to vehicular routers and IoT modules.

The “Public Safety LTE & Mobile Broadband Market: 2017 – 2030 – Opportunities, Challenges, Strategies & Forecasts” report presents an in-depth assessment of the global public safety LTE market, besides touching upon the wider LMR and mobile broadband industries. In addition to covering the business case, market drivers, challenges, enabling technologies, applications, key trends, standardization, spectrum availability/allocation, regulatory landscape, deployment case studies, opportunities, future roadmap, value chain, ecosystem player profiles and strategies for public safety LTE, the report presents comprehensive forecasts for mobile broadband, LMR, and public safety LTE subscriptions from 2017 till 2030. Also covered are unit shipment and revenue forecasts for public safety LTE infrastructure, devices, integration services and management solutions. In addition, the report tracks public safety LTE service revenues, over both private and commercial networks.

The report comes with an associated Excel datasheet suite covering quantitative data from all numeric forecasts presented in the report, as well as a list and associated details of over 190 global public safety LTE engagements – as of Q4’2017.

 
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1 Chapter 1: Introduction
1.1 Executive Summary
1.2 Topics Covered
1.3 Forecast Segmentation
1.4 Key Questions Answered
1.5 Key Findings
1.6 Methodology
1.7 Target Audience
1.8 Companies & Organizations Mentioned

2 Chapter 2: An Overview of the Public Safety Mobile Broadband Market
2.1 Narrowband LMR (Land Mobile Radio) Systems in Public Safety
2.1.1 LMR Market Size
2.1.1.1 Analog LMR
2.1.1.2 DMR
2.1.1.3 dPMR, NXDN & PDT
2.1.1.4 P25
2.1.1.5 TETRA
2.1.1.6 Tetrapol
2.1.1.7 Other LMR Technologies
2.1.2 The Limitations of LMR Networks for Non-Voice Services
2.2 Adoption of Commercial Mobile Broadband Technologies for Public Safety
2.2.1 Why Use Commercial Mobile Broadband Technologies?
2.2.2 The Perceived Role of Mobile Broadband in Public Safety Scenarios
2.2.2.1 Partnerships with Commercial Mobile Operators
2.2.2.2 Private LTE and WiMAX Networks
2.2.3 Can Mobile Broadband Technologies Replace LMR Systems?
2.2.4 How Big is the Commercial Mobile Broadband Market?
2.2.5 Will the Public Safety Witness the Same Level of Growth as the Consumer Sector?
2.2.6 What are the Growth Drivers?
2.3 Why LTE?
2.3.1 Performance Metrics
2.3.2 Coexistence, Interoperability and Spectrum Flexibility
2.3.3 A Thriving Ecosystem
2.3.4 Economic Feasibility
2.4 Public Safety LTE Technology & Architecture
2.4.1 UE (User Equipment)
2.4.1.1 Smartphones & Handportable Terminals
2.4.1.2 Vehicle-Mounted Routers & Terminals
2.4.1.3 Stationary CPEs
2.4.1.4 Tablets & Notebook PCs
2.4.1.5 USB Dongles, Embedded IoT Modules & Others
2.4.2 E-UTRAN – The LTE RAN (Radio Access Network)
2.4.2.1 eNB Base Stations
2.4.2.2 TDD vs. FDD
2.4.3 Transport Network
2.4.4 EPC (Evolved Packet Core) – The LTE Mobile Core
2.4.4.1 SGW (Serving Gateway)
2.4.4.2 PGW (Packet Data Network Gateway)
2.4.4.3 MME (Mobility Management Entity)
2.4.4.4 HSS (Home Subscriber Server)
2.4.4.5 PCRF (Policy Charging and Rules Function)
2.4.5 IMS (IP-Multimedia Subsystem), Application & Service Elements
2.4.5.1 IMS Core & VoLTE
2.4.5.2 eMBMS (Enhanced Multimedia Broadcast Multicast Service)
2.4.5.3 ProSe (Proximity Services)
2.4.5.4 Group Communication & Mission-Critical Services
2.4.6 Gateways for LTE-LMR Interworking
2.5 LTE-Advanced & 5G: Implications for Public Safety
2.5.1 The Move Towards LTE-Advanced Networks
2.5.2 LTE Advanced Pro: Accelerating Public Safety LTE Rollouts
2.5.3 5G Requirements: Looking Towards the Future
2.5.4 5G Applications for Public Safety
2.6 Support for Roaming in Public Safety LTE Networks
2.6.1 Inter-System Roaming
2.6.2 Intra-System Roaming with External LTE Networks
2.7 Public Safety LTE Deployment Models
2.7.1 Private Public Safety LTE
2.7.2 Shared Commercial Public Safety LTE: Private-Public Partnerships
2.7.3 Public Safety LTE Access over Commercial Mobile Networks
2.7.4 Hosted-Core Public Safety LTE Networks
2.8 Funding Models for Private Public Safety LTE Network Deployments
2.8.1 BOO (Built, Owned and Operated) by Integrator/Vendor
2.8.2 Owned and Operated by the Government Authority
2.8.3 Local Agency Hosted Core
2.8.4 Multiple Networks
2.9 Market Growth Drivers
2.9.1 Higher Throughput and Low Latency
2.9.2 Economic Feasibility
2.9.3 Bandwidth Flexibility
2.9.4 Spectral Efficiency
2.9.5 Regional Interoperability
2.9.6 Lack of Competition from Other Standards
2.9.7 Endorsement from the Public Safety Community
2.9.8 Commitments by Infrastructure and Device Vendors
2.9.9 QoS (Quality of Service), Priority & Preemption Provisioning
2.9.10 Group Voice & Multimedia Communications Support
2.10 Market Barriers
2.10.1 Spectrum Allocation
2.10.2 Budgetary Issues
2.10.3 Delayed Standardization
2.10.4 Dependency on New Chipsets & Devices for Dedicated Public Safety Features
2.10.5 Smaller Coverage Footprint than LMR Systems

3 Chapter 3: Key Enabling Technologies for Public Safety LTE
3.1 Mission-Critical Voice & Group Communications
3.1.1 Group Communications
3.1.1.1 GCSE (Group Communication System Enablers)
3.1.1.2 eMBMS (Multimedia Broadcast Multicast Service)
3.1.1.3 Additional Group-Based Enhancements
3.1.2 MCPTT (Mission-Critical PTT)
3.1.2.1 Architecture & Functional Capabilities
3.1.2.2 Performance Comparison with LMR Voice Services
3.1.3 Mission-Critical Data & Video
3.2 D2D (Device-to-Device) Functionality
3.2.1 ProSe (Proximity Services) for D2D Connectivity & Communications
3.2.2 ProSe Service Classification
3.2.2.1 Discovery
3.2.2.2 Direct Communication
3.2.3 Public Safety Applications for ProSe
3.2.3.1 Direct Communication for Coverage Extension
3.2.3.2 Direct Communication within Network Coverage
3.2.3.3 Infrastructure Failure & Emergency Situations
3.2.3.4 Additional Capacity for Incident Response & Special Events
3.2.3.5 Discovery Services for Disaster Relief
3.3 IOPS (Isolated E-UTRAN Operation for Public Safety)
3.3.1 Ensuring Resilience and Service Continuity for Public Safety LTE Users
3.3.2 Localized EPC & Application Capabilities
3.3.3 Support for Regular & Nomadic eNBs
3.3.4 Isolated E-UTRAN Scenarios
3.3.4.1 No Backhaul
3.3.4.2 Limited Backhaul for Signaling Only
3.3.4.3 Limited Backhaul for Signaling & User Data
3.4 Deployable LTE Systems
3.4.1 Key Operational Capabilities
3.4.1.1 eNB-Only Systems for Coverage & Capacity Enhancement
3.4.1.2 Mobile Core Integrated Systems for Autonomous Operation
3.4.1.3 Backhaul Connectivity
3.4.2 NIB (Network-in-a-Box): Self-Contained Portable Systems
3.4.2.1 Backpacks
3.4.2.2 Tactical Cases
3.4.3 Vehicular Platforms
3.4.3.1 COW (Cell-on-Wheels)
3.4.3.2 COLT (Cell-on-Light Truck)
3.4.3.3 SOW (System-on-Wheels)
3.4.3.4 VNS (Vehicular Network System)
3.4.4 Airborne Platforms
3.4.4.1 Drones
3.4.4.2 Balloons
3.4.4.3 Other Aircraft
3.4.5 Maritime Platforms
3.5 UE Enhancements
3.5.1 Ruggedization for Meet Public Safety Usage Requirements
3.5.2 Dedicated PTT-Buttons & Functional Enhancements
3.5.3 Long-Lasting Batteries
3.5.4 HPUE (High-Power User Equipment)
3.6 QPP (QoS, Priority & Preemption)
3.6.1 3GPP Specified QPP Capabilities
3.6.1.1 Access Priority: ACB (Access Class Barring)
3.6.1.2 Admission Priority & Preemption: ARP (Allocation and Retention Priority)
3.6.1.3 Traffic Scheduling Priority: QCI (QoS Class Indicator)
3.6.1.4 Emergency Scenarios: eMPS (Enhanced Multimedia Priority Service)
3.6.2 Additional QPP Enhancements
3.7 End-to-End Security
3.7.1 3GPP Specified LTE Security Architecture
3.7.1.1 Device Security
3.7.1.2 Air Interface & E-UTRAN Security
3.7.1.3 Mobile Core & Transport Network Security
3.7.2 Application Domain Protection & E2EE (End-to-End Encryption)
3.7.3 Enhancements to Support National Security & Additional Requirements
3.8 Complimentary Technologies & Concepts
3.8.1 Satellite Communications
3.8.2 High Capacity Microwave Links
3.8.3 Spectrum Sharing & Aggregation
3.8.4 MOCN (Multi-Operator Core Network)
3.8.5 DECOR (Dedicated Core)
3.8.6 Network Slicing
.......

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