The Public Safety LTE & 5G Market: 2023 – 2030 – Opportunities, Challenges, Strategies & Forecasts

The Public Safety LTE & 5G Market: 2023 – 2030 – Opportunities, Challenges, Strategies & Forecasts

With the commercial availability of 3GPP-standards compliant MCX (Mission-Critical PTT, Video & Data), HPUE (High-Power User Equipment), IOPS (Isolated Operation for Public Safety) and other critical communications features, LTE and 5G NR (New Radio) networks are increasingly gaining recognition as an all-inclusive public safety communications platform for the delivery of real-time video, high-resolution imagery, multimedia messaging, mobile office/field data applications, location services and mapping, situational awareness, unmanned asset control and other broadband capabilities, as well as MCPTT (Mission-Critical PTT) voice and narrowband data services provided by traditional LMR (Land Mobile Radio) systems. Through ongoing refinements of additional standards – specifically 5G MBS/5MBS (5G Multicast-Broadcast Services), 5G NR sidelink for off-network D2D (Device-to-Device) communications, NTN (Non-Terrestrial Network) integration, and support for lower 5G NR bandwidths – 3GPP networks are eventually expected to be in a position to fully replace legacy LMR systems by the late 2020s. National public safety communications authorities in multiple countries have already expressed a willingness to complete their planned narrowband to broadband transitions within the second half of the 2020 decade.

A myriad of fully dedicated, hybrid government-commercial and secure MVNO/MOCN-based public safety LTE and 5G-ready networks are operational or in the process of being rolled out throughout the globe. The high-profile FirstNet (First Responder Network) and South Korea’s Safe-Net (National Disaster Safety Communications Network) nationwide public safety broadband networks have been successfully implemented. Although Britain’s ESN (Emergency Services Network) project has been hampered by a series of delays, many other national-level programs have made considerable headway in moving from field trials to wider scale deployments – most notably, New Zealands NGCC (Next-Generation Critical Communications) public safety network, Frances RRF (Radio Network of the Future), Italys public safety LTE service, Spains SIRDEE mission-critical broadband network, Finlands VIRVE 2.0 broadband service, Swedens Rakel G2 secure broadband system and Hungarys EDR 2.0/3.0 broadband network. Nationwide initiatives in the pre-operational phase include but are not limited to Switzerlands MSK (Secure Mobile Broadband Communications) system, Norways Nytt Nødnett, Germanys planned hybrid broadband network for BOS (German Public Safety Organizations), Netherlands NOOVA (National Public Order & Security Architecture) program, Japans PS-LTE (Public Safety LTE) project, Australias PSMB (Public Safety Mobile Broadband) program and Canadas national PSBN (Public Safety Broadband Network) initiative.

Other operational and planned deployments range from the Halton-Peel region PSBN in Canadas Ontario province, New South Wales state-based PSMB solution, Chinas city and district-wide Band 45 (1.4 GHz) LTE networks for police forces, Hong Kongs 700 MHz mission-critical broadband network, Royal Thai Police’s Band 26 (800 MHz) LTE network, Qatar MOI (Ministry of Interior), ROP (Royal Oman Police), Abu Dhabi Police and Nedaas mission-critical LTE networks in the oil-rich GCC (Gulf Cooperation Council) region, Brazils state-wide LTE networks for both civil and military police agencies, Barbados Band 14 (700 MHz) LTE-based connectivity service platform, Zambias 400 MHz broadband trunking system and Mauritanias public safety LTE network for urban security in Nouakchott to local and regional-level private LTE networks for first responders in markets as diverse as Laos, Indonesia, the Philippines, Pakistan, Lebanon, Egypt, Kenya, Ghana, Cote DIvoire, Cameroon, Mali, Madagascar, Mauritius, Canary Islands, Spain, Turkey, Serbia, Argentina, Colombia, Venezuela, Bolivia, Ecuador and Trinidad & Tobago, as well as multi-domain critical communications broadband networks such as MRCs (Mobile Radio Center) LTE-based advanced MCA digital radio system in Japan, and secure MVNO platforms in Mexico, Belgium, Netherlands, Slovenia, Estonia and several other countries.

Even though critical public safety-related 5G NR capabilities defined in the 3GPPs Release 17 and 18 specifications are yet to be commercialized, public safety agencies have already begun experimenting with 5G for applications that can benefit from the technologys high-bandwidth and low-latency characteristics. For example, the Lishui Municipal Emergency Management Bureau is using private 5G slicing over China Mobiles network, portable cell sites and rapidly deployable communications vehicles as part of a disaster management and visualization system.

In neighboring Taiwan, the Kaohsiung City Police Department relies on end-to-end network slicing over a standalone 5G network to support license plate recognition and other use cases requiring the real-time transmission of high-resolution images. The Hsinchu City Fire Departments emergency response vehicle can be rapidly deployed to disaster zones to establish high-bandwidth, low-latency emergency communications using a satellite-backhauled private 5G network based on Open RAN standards. The Norwegian Air Ambulance is adopting a similar private 5G-based NOW (Network-on-Wheels) system for enhancing situational awareness during search and rescue operations.

In addition, first responder agencies in Germany, Japan and several other markets are beginning to utilize mid-band and mmWave (Millimeter Wave) spectrum available for local area licensing to deploy portable and small-scale 5G NPNs (Non-Public Networks) to support applications such as UHD (Ultra-High Definition) video surveillance, control of unmanned firefighting vehicles, reconnaissance robots and drones. In the near future, we also expect to see rollouts of localized 5G NR systems – including direct mode communications – for incident scene management and related use cases, potentially using up to 50 MHz of Band n79 spectrum in the 4.9 GHz frequency range (4,940-4,990 MHz), which has been designated for public safety use in multiple countries including but not limited to the United States, Canada, Australia, Malaysia and Qatar.

SNS Telecom & IT estimates that annual investments in public safety LTE/5G infrastructure and devices reached $4.3 Billion in 2023, driven by both new projects and the expansion of existing dedicated, hybrid government-commercial and secure MVNO/MOCN networks. Complemented by an expanding ecosystem of public safety-grade LTE/5G devices, the market will further grow at a CAGR of approximately 10% over the next three years, eventually accounting for more than $5.7 Billion by the end of 2026. Despite the positive outlook, some significant challenges continue to plague the market. The most noticeable pain point is the lack of a D2D communications capability.

The ProSe (Proximity Services) chipset ecosystem failed to materialize in the LTE era due to limited support from chipmakers and terminal OEMs. However, the 5G NR sidelink interface offers a clean slate opportunity to introduce direct mode D2D communications for public safety broadband users, as well as coverage expansion in both on-network and off-network scenarios using UE-to-network and UE-to-UE relays respectively. Recent demonstrations of 5G NR sidelink-enabled MCX services by the likes of Qualcomm have generated renewed confidence in 3GPP technology for direct mode communications.

Until recently, another barrier impeding the market was the non-availability of cost-optimized RAN equipment and terminals that support operation in spectrum reserved for PPDR (Public Protection & Disaster Relief) communications – most notably Band 68 (698-703 / 753-758 MHz), which has been allocated for PPDR broadband systems in several national markets across Europe, including France, Germany, Switzerland, Austria, Spain, Italy, Estonia, Bulgaria and Cyprus. Other countries such as Greece, Hungary, Romania, Sweden, Denmark, Netherlands and Belgium are also expected to make this assignment. Since the beginning of 2023, multiple suppliers – including Ericsson, Nokia, Teltronic and CROSSCALL – have introduced support for Band 68.

The “Public Safety LTE & 5G Market: 2023 – 2030 – Opportunities, Challenges, Strategies & Forecasts” report presents an in-depth assessment of the public safety LTE and 5G market, including the value chain, market drivers, barriers to uptake, enabling technologies, operational models, application scenarios, key trends, future roadmap, standardization, spectrum availability/allocation, regulatory landscape, case studies, ecosystem player profiles and strategies. The report also presents global and regional market size forecasts from 2023 to 2030, covering public safety LTE/5G infrastructure, terminal equipment, applications, systems integration and management solutions, as well as subscriptions and service revenue.

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 1,300 global public safety LTE/5G engagements – as of Q1’2024.

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 Summary of Recent Market Developments
1.7 Methodology
1.8 Target Audience
1.9 Companies & Organizations Mentioned

2 Chapter 2: An Overview of the Public Safety LTE & 5G Market
2.1 Narrowband LMR (Land Mobile Radio) Systems in the Public Safety Sector
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
2.2 Adoption of Commercial Mobile Broadband Technologies
2.2.1 Why Use Commercial Technologies?
2.2.2 The Role of Mobile Broadband in Public Safety Communications
2.2.3 Can Mobile Broadband Technologies Replace LMR Systems?
2.3 An Introduction to the 3GPP-Defined LTE & 5G Standards
2.3.1 LTE: The First Global Standard for Cellular Communications
2.3.2 LTE-Advanced: Delivering the Promise of True 4G Performance
2.3.3 LTE-Advanced Pro: Laying the Foundation for the 5G Era
2.3.4 Public Safety Communications Support in LTE-Advanced Pro
2.3.5 5G: Accelerating 3GPP Expansion in Vertical Industries
2.3.5.1 5G Service Profiles
2.3.5.1.1 eMBB (Enhanced Mobile Broadband)
2.3.5.1.2 URLLC (Ultra-Reliable, Low-Latency Communications)
2.3.5.1.3 mMTC/mIoT (Massive Machine-Type Communications/Internet of Things)
2.3.6 5G-Advanced & the Evolution to 6G
2.3.7 5G Application Scenarios for Public Safety
2.4 Why Adopt LTE & 5G for Public Safety Broadband?
2.4.1 Performance, Reliability & Security Characteristics
2.4.2 Coexistence, Interoperability & Spectrum Flexibility
2.4.3 3GPP Support for Mission-Critical Applications
2.4.4 Future-Proof Transition Path Towards 6G Networks
2.4.5 Thriving Ecosystem of Chipsets, Devices & Network Equipment
2.4.6 Economic Viability of Deployment & Operational Costs
2.5 Public Safety LTE/5G Network Operational Models
2.5.1 Fully Dedicated Private Broadband Network
2.5.2 Shared Core Network With Independent RANs
2.5.3 Hybrid Government-Commercial Network
2.5.4 Secure MVNO & MOCN (Dedicated Mobile Core)
2.5.5 Access Over Commercial Broadband Networks
2.5.6 Sliced Private Network for Public Safety Communications
2.5.7 Other Approaches
2.6 Financing & Delivering Dedicated Public Safety LTE/5G Networks
2.6.1 National Government Authority-Owned & Operated
2.6.2 Local Government/Public Safety Agency-Owned & Operated
2.6.3 BOO (Built, Owned & Operated) by Critical Communications Service Provider
2.6.4 Government-Funded & Commercial Carrier-Operated
2.6.5 Other Forms of PPPs (Public-Private Partnerships)
2.7 Public Safety LTE/5G Value Chain
2.7.1 Enabling Technology Providers
2.7.2 RAN, Mobile Core & Transport Infrastructure Suppliers
2.7.3 Terminal Equipment Vendors
2.7.4 System Integrators
2.7.5 Application Developers
2.7.6 Test, Measurement & Performance Specialists
2.7.7 Mobile Operators
2.7.8 MVNOs
2.7.9 Public Safety & Government Agencies
2.8 Market Drivers
2.8.1 Growing Demand for High-Speed & Low-Latency Data Applications
2.8.2 Recognition of LTE & 5G as the De-Facto Platform for Wireless Connectivity
2.8.3 Spectral Efficiency & Bandwidth Flexibility
2.8.4 National & Cross-Border Interoperability
2.8.5 Consumer-Driven Economies of Scale
2.8.6 Endorsement From the Public Safety Community
2.8.7 Limited Competition From Other Wireless Broadband Technologies
2.8.8 Control Over QPP (QoS, Priority & Preemption) Policies
2.8.9 Support for Mission-Critical Functionality
2.8.10 Data Privacy & Network Security
2.9 Market Barriers
2.9.1 Limited Availability of Licensed Spectrum for Public Safety Broadband
2.9.2 Financial Challenges Associated With Large-Scale & Nationwide Networks
2.9.3 Technical Complexities of Network Implementation & Operation
2.9.4 Smaller Coverage Footprint Than Legacy LMR Systems
2.9.5 Delayed Standardization & Commercialization of Mission-Critical Functionality
2.9.6 ProSe/Sidelink Chipset Ecosystem for Direct Mode Communications
2.9.7 COTS (Commercial Off-the-Shelf) Equipment-Related Challenges
2.9.8 Conservatism of End User Organizations

3 Chapter 3: System Architecture & Technologies for Public Safety LTE/5G Networks
3.1 Architectural Components of Public Safety LTE/5G Networks
3.1.1 UE (User Equipment)
3.1.1.1 Smartphones & Handportable Terminals
3.1.1.2 Mobile & Vehicular Routers
3.1.1.3 Fixed CPEs (Customer Premises Equipment)
3.1.1.4 Tablets & Notebook PCs
3.1.1.5 Smart Wearables
3.1.1.6 Cellular IoT Modules
3.1.1.7 Add-On Dongles
3.1.2 RAN (Radio Access Network)
3.1.2.1 E-UTRAN – LTE RAN
3.1.2.1.1 eNBs – LTE Base Stations
3.1.2.2 NG-RAN – 5G NR Access Network
3.1.2.2.1 gNBs – 5G NR Base Stations
3.1.2.2.2 en-gNBs – Secondary Node 5G NR Base Stations
3.1.2.2.3 ng-eNBs – Next-Generation LTE Base Stations
3.1.2.3 Architectural Components of eNB/gNB Base Stations
3.1.2.3.1 RUs (Radio Units)
3.1.2.3.2 Integrated Radio & Baseband Units
3.1.2.3.3 DUs (Distributed Baseband Units)
3.1.2.3.4 CUs (Centralized Baseband Units)
3.1.3 Transport Network
3.1.3.1 Fronthaul
3.1.3.2 Midhaul
3.1.3.3 Backhaul
3.1.3.4 Physical Transmission Mediums
3.1.3.4.1 Fiber & Wireline Transport Technologies
3.1.3.4.2 Microwave & mmWave (Millimeter Wave) Wireless Links
3.1.3.4.3 Satellite Communications
3.1.4 Mobile Core
3.1.4.1 EPC (Evolved Packet Core) – LTE Mobile Core
3.1.4.1.1 SGW (Serving Gateway)
3.1.4.1.2 PGW (Packet Data Network Gateway)
3.1.4.1.3 MME (Mobility Management Entity)
3.1.4.1.4 HSS (Home Subscriber Server)
3.1.4.1.5 PCRF (Policy Charging & Rules Function)
3.1.4.2 5GC (5G Core) – Core Network for Standalone 5G Implementations
3.1.4.2.1 AMF (Access & Mobility Management Function)
3.1.4.2.2 SMF (Session Management Function)
3.1.4.2.3 UPF (User Plane Function)
3.1.4.2.4 PCF (Policy Control Function)
3.1.4.2.5 NEF (Network Exposure Function)
3.1.4.2.6 NRF (Network Repository Function)
3.1.4.2.7 UDM (Unified Data Management)
3.1.4.2.8 UDR (Unified Data Repository)
3.1.4.2.9 AUSF (Authentication Server Function)
3.1.4.2.10 AFs (Application Functions)
3.1.4.2.11 NSSF (Network Slice Selection Function)
3.1.4.2.12 NWDAF (Network Data Analytics Function)
3.1.4.3 Other 5GC Elements
3.1.5 Services & Interconnectivity
3.1.5.1 IMS (IP-Multimedia Subsystem) & Application Service Elements
3.1.5.1.1 IMS Core & VoLTE-VoNR (Voice-Over-LTE & 5G NR)
3.1.5.1.2 MBMS, eMBMS, FeMBMS & 5G MBS/5MBS (5G Multicast-Broadcast Services)
3.1.5.1.3 Group Communications & MCS (Mission-Critical Services)
3.1.5.1.4 ProSe (Proximity-Based Services) for Direct D2D (Device-to-Device) Discovery & Communications
3.1.5.2 Interconnectivity With 3GPP & Non-3GPP Networks
3.1.5.2.1 3GPP Roaming & Service Continuity
3.1.5.2.2 National & International Roaming
3.1.5.2.3 Service Continuity Outside Network Footprint
3.1.5.2.4 Gateways Supporting Non-3GPP Network Integration
3.1.5.2.5 IWF (Interworking Function) for LMR-3GPP Interoperability
3.2 Key Enabling Technologies & Concepts
3.2.1 MCPTT (Mission-Critical PTT) Voice & Group Communications
3.2.1.1 Functional Capabilities of the MCPTT Service
3.2.1.2 Performance Comparison With LMR Voice Services
3.2.1.3 Mission-Critical Video & Data
3.2.1.3.1 MCVideo (Mission-Critical Video)
3.2.1.3.2 MCData (Mission-Critical Data)
3.2.2 ProSe & Sidelink-Enabled Direct Mode Communications
3.2.2.1 Direct Communication for Coverage Extension
3.2.2.2 Direct Communication Within Network Coverage
3.2.2.3 Infrastructure Failure & Emergency Scenarios
3.2.2.4 Additional Capacity for Incident Response & Special Events
3.2.2.5 Discovery Services for Disaster Relief
3.2.3 UE-Related Enhancements
3.2.3.1 Ruggedization to Meet Critical Communications User Requirements
3.2.3.2 Dedicated PTT Buttons & Functional Enhancements
3.2.3.3 Long-Lasting Batteries
3.2.3.4 HPUE (High-Power User Equipment)
3.2.3.5 Wireless Connection Bonding
3.2.4 IOPS (Isolated Operation for Public Safety)
3.2.4.1 Ensuring Resilience & Service Continuity for Critical Communications
3.2.4.2 Localized Mobile Core & Application Capabilities
3.2.4.3 Support for Regular & Nomadic Base Stations
3.2.4.4 Isolated RAN Scenarios
3.2.4.4.1 No Backhaul
3.2.4.4.2 Limited Backhaul for Signaling Only
3.2.4.4.3 Limited Backhaul for Signaling & User Data
3.2.5 Cell Site & Infrastructure Hardening
3.2.5.1 Overlapping Cell Site Coverage
3.2.5.2 Geo-Redundant Data Centers
3.2.5.3 Multiple Backhaul Connections
3.2.5.4 Backup Power Sources
3.2.5.5 Structural Hardening
3.2.5.6 Physical Security Measures
3.2.6 Rapidly Deployable LTE & 5G Network Systems
3.2.6.1 Key Operational Capabilities
3.2.6.1.1 RAN-Only Systems for Coverage & Capacity Enhancement
3.2.6.1.2 Mobile Core-Integrated Systems for Autonomous Operation
3.2.6.1.3 Backhaul Interfaces & Connectivity
3.2.6.2 NIB (Network-in-a-Box): Self-Contained Portable Systems
3.2.6.2.1 Backpacks
3.2.6.2.2 Tactical Cases
3.2.6.2.3 Pre-Integrated Racks
3.2.6.3 Wheeled & Vehicular-Based Deployables
3.2.6.3.1 COW (Cell-on-Wheels)
3.2.6.3.2 COLT (Cell-on-Light Truck)
3.2.6.3.3 SOW (System-on-Wheels)
3.2.6.3.4 VNS (Vehicular Network System)
3.2.6.4 Aerial Cell Sites
3.2.6.4.1 Drones
3.2.6.4.2 Balloons
3.2.6.4.3 Other Aircraft
3.2.6.5 Maritime Cellular Platforms
3.2.7 Network Coverage Extension
3.2.7.1 UE-to-Network & UE-to-UE Relays
3.2.7.2 Indoor & Outdoor Small Cells
3.2.7.3 DAS (Distributed Antenna Systems)
3.2.7.4 IAB (Integrated Access & Backhaul)
3.2.7.5 Mobile IAB: VMRs (Vehicle-Mounted Relays)
3.2.7.6 NCRs (Network-Controlled Repeaters)
3.2.7.7 NTNs (Non-Terrestrial Networks)
3.2.7.8 ATG/A2G (Air-to-Ground) Connectivity
3.2.8 QPP (QoS, Priority & Preemption)
3.2.8.1 3GPP-Specified QPP Capabilities
3.2.8.1.1 Access Priority: ACB (Access Class Barring) & UAC (Unified Access Control)
3.2.8.1.2 Admission Priority & Preemption: ARP (Allocation & Retention Priority)
3.2.8.1.3 Traffic Scheduling Priority: QCI (QoS Class Indicator) & 5QI (5G QoS Identifier)
3.2.8.1.4 Emergency Scenarios: MPS (Multimedia Priority Service)
3.2.8.2 Additional QPP Enhancements
3.2.9 E2E (End-to-End) Security
3.2.9.1 3GPP-Specified Security Architecture
3.2.9.1.1 UE Authentication Framework
3.2.9.1.2 Subscriber Privacy
3.2.9.1.3 Air Interface Confidentiality & Integrity
3.2.9.1.4 Resilience Against Radio Jamming
3.2.9.1.5 RAN, Core & Transport Network Security
3.2.9.1.6 Security Aspects of Network Slicing
3.2.9.2 Application Domain Protection & E2E Encryption
3.2.9.3 National Requirements & Other Considerations
3.2.9.4 Quantum Cryptography Technologies
3.2.10 3GPP Support for NPNs (Non-Public Networks)
3.2.10.1 Types of NPNs
3.2.10.1.1 SNPNs (Standalone NPNs)
3.2.10.1.2 PNI-NPNs (Public Network-Integrated NPNs)
3.2.10.2 SNPN Identification & Selection
3.2.10.3 PNI-NPN Resource Allocation & Isolation
3.2.10.4 CAG (Closed Access Group) for Cell Access Control
3.2.10.5 Mobility, Roaming & Service Continuity
3.2.10.6 Interworking Between SNPNs & Public Networks
3.2.10.7 UE Configuration & Subscription-Related Aspects
3.2.10.8 Other 3GPP-Defined Capabilities for NPNs
3.2.11 Network Slicing
3.2.11.1 Logical Partitioning of Network Resources
3.2.11.2 3GPP Functions, Identifiers & Procedures for Slicing
3.2.11.3 RAN Slicing
3.2.11.4 Mobile Core Slicing
3.2.11.5 Transport Network Slicing
3.2.11.6 UE-Based Network Slicing Features
3.2.11.7 Management & Orchestration Aspects
3.2.12 Infrastructure Sharing
3.2.12.1 Service-Specific PLMN (Public Land Mobile Network) IDs
3.2.12.2 DNN (Data Network Name)/APN (Access Point Name)-Based Isolation
3.2.12.3 GWCN (Gateway Core Network): Core Network Sharing
3.2.12.4 MOCN (Multi-Operator Core Network): RAN & Spectrum Sharing
3.2.12.5 MORAN (Multi-Operator RAN): RAN Sharing Without Spectrum Pooling
3.2.12.6 DECOR (Dedicated Core) & eDECOR (Enhanced DECOR)
3.2.12.7 Roaming in Non-Overlapping Service Areas
3.2.12.8 Passive Sharing of Infrastructure Resources
3.2.13 IoT-Focused Technologies
3.2.13.1 eMTC, NB-IoT & mMTC: Wide Area & High-Density IoT Applications
3.2.13.2 5G NR Light: RedCap (Reduced Capability) UE Type
3.2.13.3 URLLC Techniques: High-Reliability & Low-Latency Enablers
3.2.13.4 5G LAN (Local Area Network)-Type Service
3.2.13.5 Integration With IEEE 802.1 TSN (Time-Sensitive Networking) Systems
3.2.13.6 Native 3GPP Support for TSC (Time-Sensitive Communications)
3.2.14 High-Precision Positioning
3.2.14.1 Assisted-GNSS (Global Navigation Satellite System)
3.2.14.2 RAN-Based Positioning Techniques
3.2.14.3 RAN-Independent Methods
3.2.15 Spectrum Sharing & Management
3.2.15.1 Public Safety Spectrum Sharing & Aggregation
3.2.15.2 SDR (Software-Defined Radio)
3.2.15.3 Cognitive Radio & Spectrum Sensing
3.2.15.4 Shared & Unlicensed Spectrum Usage
3.2.15.4.1 CBRS (Citizens Broadband Radio Service): Three-Tiered Sharing
3.2.15.4.2 LSA (Licensed Shared Access): Two-Tiered Sharing
3.2.15.4.3 Local Area Licensing of Shared Spectrum
3.2.15.4.4 LTE-U, LAA (Licensed Assisted Access), eLAA (Enhanced LAA) & FeLAA (Further Enhanced LAA)
3.2.15.4.5 MulteFire: Standalone LTE Operation in Unlicensed Spectrum
3.2.15.4.6 License-Exempt 1.9 GHz sXGP (Shared Extended Global Platform)
3.2.15.4.7 5G NR-U (NR in Unlicensed Spectrum)
3.2.16 MEC (Multi-Access or Mobile Edge Computing)
3.2.16.1 Optimizing Latency, Service Performance & Backhaul Costs
3.2.16.2 3GPP-Defined Features for Edge Computing Support
3.2.16.3 Public vs. Private Edge Computing
3.2.17 Cloud-Native, Software-Driven & Open Networking
3.2.17.1 Cloud-Native Technologies
3.2.17.2 Microservices & SBA (Service-Based Architecture)
3.2.17.3 Containerization of Network Functions
3.2.17.4 NFV (Network Functions Virtualization)
3.2.17.5 SDN (Software-Defined Networking)
3.2.17.6 Cloud Compute, Storage & Networking Infrastructure
3.2.17.7 APIs (Application Programming Interfaces)
3.2.17.8 Open RAN & Core Architectures
3.2.18 Network Intelligence & Automation
3.2.18.1 AI (Artificial Intelligence)
3.2.18.2 Machine & Deep Learning
3.2.18.3 Big Data & Advanced Analytics
3.2.18.4 SON (Self-Organizing Networks)
3.2.18.5 Intelligent Control, Management & Orchestration
3.2.18.6 Support for Network Intelligence & Automation in 3GPP Standards

4 Chapter 4: Public Safety LTE/5G Application Scenarios & Use Cases
4.1 Mission-Critical HD Voice & Group Communications
4.1.1 Group Calls
4.1.2 Private Calls
4.1.3 Broadcast Calls
4.1.4 System Calls
4.1.5 Emergency Calls & Alerts
4.1.6 Imminent Peril Calls
4.1.7 Ambient & Discrete Listening
4.1.8 Remotely Initiated Calls
4.2 Real-Time Video & High-Resolution Imagery
4.2.1 Mobile Video & Imagery Transmission
4.2.2 Group-Based Video Communications
4.2.3 Video Conferencing for Small Groups
4.2.4 Private One-To-One Video Calls
4.2.5 Video Pull & Push Services
4.2.6 Ambient Viewing
4.2.7 Video Transport From Fixed Cameras
4.2.8 Aerial Video Surveillance
4.3 Messaging, File Transfer & Presence Services
4.3.1 SDS (Short Data Service)
4.3.2 RTT (Real-Time Text)
4.3.3 File Distribution
4.3.4 Multimedia Messaging
4.3.5 Presence Services
4.4 Secure & Seamless Mobile Broadband Access
4.4.1 IP Connectivity & Data Streaming for Mission-Critical Services
4.4.2 Email, Internet & Corporate Intranet
4.4.3 Remote Database Access
4.4.4 Mobile Office & Field Applications
4.4.5 Wireless Telemetry
4.4.6 Bulk Multimedia & Data Transfers
4.4.7 Seamless Data Roaming
4.4.8 Public Safety-Grade Mobile VPN (Virtual Private Network)
4.5 Location Services & Mapping
4.5.1 Network Assisted-GPS/GNSS
4.5.2 Indoor & Urban Positioning
4.5.3 Floor-Level & 3D Geolocation
4.5.4 Advanced Mapping & Spatial Analytics
4.5.5 AVL (Automatic Vehicle Location) & Fleet Management
4.5.6 Field Personnel & Asset Tracking
4.5.7 Navigation for Vehicles, Vessels & Aircraft
4.5.8 Geo-Fencing for Public Safety Operations
4.6 Command & Control
4.6.1 CAD (Computer Aided Dispatch)
4.6.2 Situational Awareness
4.6.3 Common Operating Picture
4.6.4 Integration of Critical IoT Assets
4.6.5 Remote Control of Drones, Robots & Other Unmanned Systems
4.6.6 Digital Signage & Traffic Alerts
4.7 5G & Advanced Public Safety Broadband Applications
4.7.1 UHD (Ultra-High Definition) Video Transmission
4.7.2 Massive-Scale Surveillance & Analytics
4.7.3 AR, VR & MR (Augmented, Virtual & Mixed Reality)
4.7.4 Smart Glasses for Frontline Police Officers
4.7.5 5G-Connected AR Headgear for Firefighters
4.7.6 Telehealth & Remote Surgery for EMS (Emergency Medical Services)
4.7.7 AR Overlays for Police Cruisers, Ambulances, Fire Engines & Helicopters
4.7.8 Holographic Command Centers
4.7.9 Wireless VR/MR-Based Training
4.7.10 Real-Time Physiological Monitoring of First Responders
4.7.11 5G-Equipped Autonomous Police Robots
4.7.12 Unmanned Aerial, Ground & Marine Vehicles
4.7.13 Powering the IoLST (Internet of Life Saving Things)
4.7.14 5G MBS/5MBS Multicast-Broadcast Services in High-Density Environments
4.7.15 5G NR Sidelink-Based Direct Mode Voice, Video & Data Communications
4.7.16 Coverage Expansion Through UE-To-Network & UE-to-UE Relaying
4.7.17 Satellite & NTN (Non-Terrestrial Network)-Assisted 5G NR Access
4.7.18 Centimeter-Level Positioning for First Responder Operations
4.7.19 Practical Examples of 5G Era Public Safety Applications
4.7.19.1 Area X.O (Invest Ottawa): 5G Mobile Command Center
4.7.19.2 Blueforce Development: 5G & Edge Computing for Real-Time Situational Awareness
4.7.19.3 Citymesh: 5G-Connected Safety Drones for Emergency Services
4.7.19.4 Cosumnes Fire Department: AR Firefighting Helmets
4.7.19.5 DRZ (German Rescue Robotics Center): 5G-Equipped Mobile Robotics for Rescue Operations
4.7.19.6 Dubai Police: AI-Enabled Identification of Criminals
4.7.19.7 Dublin Fire Brigade: Coordinating Emergency Incidents With 5G Connectivity
4.7.19.8 Edgybees: Real-Time Augmented Visual Intelligence
4.7.19.9 Government of Catalonia: 5G-Equipped Emergency Medical Vehicles
4.7.19.10 Guardia Civil (Spanish Civil Guard): Tactical 5G Bubbles for Drone-Based Security & Surveillance Missions
4.7.19.11 Hsinchu City Fire Department: Digital Resiliency Through Private 5G & Satellite Communications
4.7.19.12 Kaohsiung City Police Department: Sliced 5G Network for Smart Patrol Cars
4.7.19.13 Leuven Police: Combating Illegal Dumping & Public Nuisances With 5G-Connected Mobile Cameras
4.7.19.14 Lishui Municipal Emergency Management Bureau: 5G-Enabled Natural Disaster Management System
4.7.19.15 Maebashi City Fire Department: 5G for Emergency Response & Rescue Services
4.7.19.16 National Police of the Netherlands: AR-Facilitated Crime Scene Investigations
4.7.19.17 New Zealand Police: Aerial Surveillance Through 5G NR Connectivity
4.7.19.18 NHS (National Health Service, United Kingdom): 5G-Connected Smart Ambulances
4.7.19.19 Norwegian Air Ambulance: Private 5G Network for Search & Rescue Operations
4.7.19.20 PDRM (Royal Malaysia Police): 5G-Enabled Safe City Solution for Langkawi
4.7.19.21 Shenzhen Public Security Bureau: 5G-Connected Unmanned Police Boats
4.7.19.22 SPF (Singapore Police Force): 5G-Equipped Police Robots
4.7.19.23 V-Armed: Preparing Officers for Active Shooter Scenarios Through VR Training


List Of Tables

10T Tech
1NCE
1oT
3GPP (Third Generation Partnership Project)
450 MHz Alliance
4K Solutions
4RF
5GCT (5G Catalyst Technologies)
6Harmonics/6WiLInk
6WIND
7Layers
7P (Seven Principles)
A Beep/Diga-Talk+
A1 Telekom Austria Group
A10 Networks
A5G Networks
AAEON Technology
AALTO HAPS
Aarna Networks
ABEL Mobilfunk
ABiT Corporation
ABS
Abside Networks
Abu Dhabi Police
Accedian
AccelerComm
Accelink Technologies
Accelleran
Accenture
ACCESS CO.
ACCF (Australasian Critical Communications Forum)
Accton Technology Corporation
Accuver
ACE Technologies
AceAxis
AceTel (Ace Solutions)
Achronix Semiconductor Corporation
ACMOSS (Agency for Operational Security & Rescue Mobile Communications, France)
ACOME
Actelis Networks
Actemium (VINCI Energies)
Action Technologies (Shenzhen Action Technologies)
Actiontec Electronics
Active911
Actus Networks
Adax
ADCOM911 (Adams County Communications Center)
Adcor Magnet Systems
ADF (Australian Defence Force)
ADI (Analog Devices, Inc.)
ADLINK Technology
ADRF (Advanced RF Technologies)
ADT
Adtran
Advanced Energy Industries
AdvanceTec Industries
Advantech
Advantech Wireless Technologies
Aegex Technologies
Aerial Applications
Aeris
Aero Wireless Group
AeroMobile Communications
Aerostar International
AeroVironment
AERTEC
Aethertek
Affarii Technologies
Affirmed Networks
AFL Global
AFRY
AGCOM (Communications Regulatory Authority, Italy)
Agile (Agile Interoperable Solutions)
AGIS (Advanced Ground Information Systems)
AGM Mobile
AH NET (MVM NET)
AI-LINK
AINA Wireless
Airbus
Airfide Networks
Airgain
AirHop Communications
Airlinq
Airspan Networks
Airtower Networks
Airwave Solutions
Airwavz Solutions
AIS (Advanced Info Service)
AiVader
Ajman Police
Akamai Technologies
AKOS (Agency for Communication Networks and Services of the Republic of Slovenia)
Akoustis Technologies
Akquinet
Alaxala Networks Corporation
ALBEDO Telecom
albis-elcon
Alcadis
Alcobendas City Council
ALE (Antarctic Logistics & Expeditions)
Alea
Alef (Alef Edge)
Alepo
Alestra
Alibaba Group
Aliniant
Allbesmart
Allen Vanguard Wireless
Allerio
Allied Telesis
Allot
Alpha Networks
Alpha Wireless
Alphabet
Alsatis Réseaux
ALSOK (Sohgo Security Services)
Altaeros
Altair Semiconductor (Sony Semiconductor Israel)
ALTÁN Redes
Altice Group
Altice Labs
ALVIS (Argentina)
AM Telecom
Amantya Technologies
Amarisoft
Amazon
Ambra Solutions-ECOTEL
Ambulance Victoria
Ambulancezorg Groningen
AMD (Advanced Micro Devices)
Amdocs
América Móvil
American Tower Corporation
AMI (American Megatrends International)
AMIT Wireless
AMN (Africa Mobile Networks)
Ampere Computing
Amphenol Corporation
Ampleon
Amtele Communication
An Garda Síochána (Irish National Police Service)
ANACOM (National Communications Authority, Portugal)
Anatel (National Telecommunications Agency, Brazil)
ANCOM (National Authority for Management and Regulation in Communications, Romania)
Andesat
ANDEX (Sendai)
ANDRO Computational Solutions
Angola Telecom
Angolan Ministry of Interior
Anktion (Fujian) Technology
Anokiwave
Anritsu
ANS (Advanced Network Services)
Antenna Company
Anterix
Antevia Networks
Antna Antenna Technology
Antwerp Police
Aorotech
APCO (Association of Public-Safety Communications Officials) International
Apple
APRESIA Systems
APSTAR (APT Satellite Company)
APT (Asia Pacific Telecom)
Aptica
aql
Aquila (Suzhou Aquila Solutions)
Aqura Technologies
Arabsat
Arcadyan Technology Corporation
ARCEP (Regulatory Authority for Electronic Communications and Posts, France)
Archos
ARCIA (Australian Radio and Communications Industry Association)
Arctic Semiconductor (Formerly SiTune Corporation)
Arete M
AREU (Lombardy Regional Emergency Service Agency)
Argela
Argentine Federal Police
ArgoNET
Aria Networks
ARIB (Association of Radio Industries and Businesses, Japan)
Arico Technologies
Arista Networks
Arkessa
Arm
Armasuisse (Federal Office for Defense Procurement, Switzerland)
Armour Communications
Arqit Quantum
Arqueiro Telecom
ArrayComm (Chengdu ArrayComm Wireless Technologies)
Arrcus
Artemis Networks
Artiza Networks
Aruba
Arukona
Asagao TV
Asahikawa Cable Television
Asavie
ASELSAN
AsiaInfo Technologies
AsiaSat (Asia Satellite Telecommunications Company)
Askey Computer Corporation
ASOCS
Aspire Technology
ASR Microelectronics
Assured Wireless Corporation
AST SpaceMobile
ASTELLA (Astella Technologies)
ASTRI (Hong Kong Applied Science and Technology Research Institute)
ASTRID
ASUS (ASUSTeK Computer)
Asylon
AT (Auckland Transport)
AT&T
ATDI
ATEL (Asiatelco Technologies)
Atel Antennas
Atesio
Athonet
ATIS (Alliance for Telecommunications Industry Solutions)
ATL (A Test Lab)
AtlantiCare Regional Medical Center
Atlas Telecom
ATN International
Atos
Atrinet
AttoCore
ATU (African Telecommunications Union)
Auckland Westpac Rescue Helicopter
Auden Techno
audius
Auray Technology
Aurens (Orrence)
Aurora Flight Sciences
Australian Department of Home Affairs
Australian Productivity Commission
Avanti Communications
Avari Wireless
AVI
Aviat Networks
AVIWEST
AVM
AW2S (Advanced Wireless Solutions and Services)
AWS (Amazon Web Services)
AWTG
Axega 112 (Galician Emergency Agency)
AXESS Networks
Axians
Axiata Group
Axione
Axis Communications
Axon
Axpo WZ-Systems
Axtel
Axxcelera Broadband Wireless
Axxcss Wireless Solutions
Azcom Technology
Azetti Networks
B+B SmartWorx
BABS/FOCP (Federal Office for Civil Protection, Switzerland)
BAE Systems
Bahia State Secretariat of Public Security
Baicells
BAKOM/OFCOM (Federal Office of Communications, Switzerland)
Ball Aerospace
Ballast Networks
BandRich
BandwidthX
Bangladesh SSF (Special Security Force)
Bangs Ambulance
Barcelona City Council
Barrett Communications
BARTEC
BATM Advanced Communications
BATS Wireless (Broadband Antenna Tracking Systems)
Bay Minette Police Department
BAYFU (Bayerische Funknetz)
Baylin Technologies
BayRICS (Bay Area Regional Interoperable Communications Systems Authority)
BBB (BB Backbone Corporation)
BBK Electronics
BC Hydro
BCDVideo
BDBOS (Federal Agency for Public Safety Digital Radio, Germany)
Beagle Systems
Beam Semiconductor
Beamlink
BearCom
BEC Technologies
becon
Beeper Communications
Beijer Electronics Group
Beijing Emergency Center
BEL (Bharat Electronics Limited)
Belden
BelFone
Bell Canada
Bellantenna
Benetel
BesoVideo
Betacom
Bharti Airtel
BHE (Bonn Hungary Electronics)
BICS
Billion Electric
BinnenBereik
BIPT (Belgian Institute for Postal Services and Telecommunications)
biqx
Bird Technologies
BISDN (Berlin Institute for Software Defined Networks)
Bittium
BK Technologies
Black & Veatch
Black Box
BlackBerry
Blackned
Blickle & Scherer
BLiNQ Networks
Blu Wireless
Blue Arcus Technologies
Blue Wireless
Bluebird
Blueforce Development Corporation
BLUnet Schweiz
BMI (Federal Ministry of Interior, Germany)
BMVg (Federal Ministry of Defense, Germany)
BMWK (Federal Ministry for Economic Affairs and Climate Action, Germany)
BNetzA (Federal Network Agency, Germany)
BNPB (National Agency for Disaster Management, Indonesia)
Boeing
Boelink (Shanghai Boelink Communication Technology)
Boingo Wireless
Boise Police Department
Boldyn Networks (Formerly BAI Communications)
Bombers de Barcelona (Barcelona Fire Service)
Booz Allen Hamilton
Boston Dynamics
Boston Police Department
Botswana Police Service
Bouygues Telecom
Boxchip
Branch Communications
BravoCom
Brazil Federal District Military Police
Brazilian Army
Bredengen
BRI (Paris Research and Intervention Brigade)
Bristol Port Company
British Army
Broadcom
BroadForward
Broadmobi (Shanghai Broadmobi Communication Technology)
Broadpeak
Broadtech
BSNL (Bharat Sanchar Nigam Limited)
BT Group
Btel (Bakrie Telecom)
BTI Wireless
B-TrunC (Broadband Trunking Communication) Industry Alliance
Buenos Aires City Police
Bulgarian Ministry of Interior
Bullitt Mobile
Bumicom Telecommunicatie
Bundeswehr (German Armed Forces)
Bundeswehr University Munich
Bureau Veritas
Burlington Fire Department
BVSystems (Berkeley Varitronics Systems)
BWT (BlueWaveTel)
B-Yond
C Spire
C Squared Systems
C3Spectra
Cable Television Toyama
Cable TV Tokushima
CableFree (Wireless Excellence)
CableLabs
CACI International
Cadence Design Systems
CalAmp
CalChip Connect
Calgary Police Service
Caliber Public Safety
California National Guard
Calix
Calnex Solutions
Caltta Technologies
Cambium Networks
Cambridge Consultants
CampusGenius
Camtel (Cameroon Telecommunications)
Canadian Army
Canoga Perkins
Canonical
Capgemini Engineering
Capgemini Invent
CapX Nederland
Carabinieri (Italy)
Carbyne
Casa Systems
CASIC (China Aerospace Science and Industry Corporation)
Casio Computer Company
Castor Marine
CATA (Canadian Advanced Technology Alliance)
Catalyst Communications Technologies
CATV (Cable TV)
Cavli Wireless
CBNG (Cambridge Broadband Networks Group)
CCI (Communication Components Inc.)
CCN (Cirrus Core Networks)
CCSA (China Communications Standards Association)
CCww (Communications Consultants Worldwide)
CDE Lightband
CEA-Leti
Cegeka
CeLa Link Corporation
Celab Communications
Celfinet
CellAntenna Corporation
Cellcomm Solutions
Cellient
Celling 5G
CellMax Technologies
Cellnex Telecom
Cellwize
cellXica
cellXion
Celona
CelPlan Technologies
Centerline Communications
CENTRA Technology
CentralSquare Technologies
CEPT (European Conference of Postal and Telecommunications Administrations)
Ceragon Networks
Cerillion
CertusNet
CETC (China Electronics Technology Group Corporation)
CEVA
CGI
Challenge Networks
Changi General Hospital
ChannelPorts
Charge Enterprises
Charter Communications
Cheerzing (Xiamen Cheerzing IoT Technology)
Chelton
Chemring Technology Solutions
Chengdu NTS
Chicago Police Department
Chicony Electronics
China All Access
China Broadnet (CBN – China Broadcasting Network)
China Mobile
China Satcom (China Satellite Communications)
China Telecom
China Unicom
Choice NTUA Wireless
Chongqing Dima
Chulalongkorn University
Chunghwa Telecom
Cibicom
CICPA (Critical Infrastructure and Coastal Protection Authority, UAE)
CICT – China Information and Communication Technology Group (China Xinke Group)
Cielo Networks
Ciena Corporation
CIG (Cambridge Industries Group)
Cincinnati Police Department
CIO (Connected IO)
CircleGx
Cirpack
Cirtek Holdings Philippines Corporation
Cisco Systems
CITEL (Inter-American Telecommunication Commission)
CITIG (Canadian Interoperability Technology Interest Group)
CITRA (Communication and Information Technology Regulatory Authority, Kuwait)
City and County of San Francisco
City of Antwerp
City of Boulder
City of Cape Town
City of Charlotte
City of Chicago
City of Euless
City of Fort Worth
City of Genk
City of Glendale
City of Irving
City of Johannesburg EMS (Emergency Management Services)
City of Las Vegas
City of Leuven
City of London Police
City of Longmont
City of New Orleans
City of Tacoma
City of Tampere
City of Tucson
City of Wavre
Citymesh
CitySwitch
CK Hutchison
CKH IOD
Claro Brasil
Clavister
Clear-Com (HME)
Cleveland Police
Clever Logic
CloudMinds
CMIoT (China Mobile IoT)
CNIT (National Inter-University Consortium for Telecommunications, Italy)
Cobham
Cobham Satcom
COCUS
Codan Communications
Codium Networks
Cogisys
Cognizant
Cohere Technologies
Coherent (Formerly II-VI)
Coherent Logix
Cohort
Coiler Corporation
Collinear Networks
Collins Aerospace
Colorado Parks and Wildlife
Colt Technology Services
Com4
Comarch
Comba Telecom
Combain Mobile
Comcast Corporation
Comcores
Comfone
COMLAB
CommAgility
CommandWear Systems
Commercis
Commnet Wireless
Commonwealth of Massachusetts
Comms365
CommScope
Compal Electronics
Comprod
Comptek Technologies
ComReg (Commission for Communications Regulation, Ireland)
Comrod Communication Group
COMsolve
COMSovereign
Comtech Telecommunications Corporation
Comtrend Corporation
Comviva
CONET Technologies
CONEXIO Corporation
CONGIV
Connect Tech
Connect44 Group
Connectivity Wireless Solutions
Consort Digital
Contela
Contour Networks
Coolpad
CopaSAT
coreNOC
Cornerstone (CTIL)
Cornet Technology
Corning
Cortina Access
Cosemi Technologies
COSMOTE
Cosumnes Fire Department
Council Rock
County of Renfrew Paramedic Service
Coweaver
Cox Communications
CPQD (Center for Research and Development in Telecommunications, Brazil)
CRA (Communications Regulatory Authority, Qatar)
CRC (Communications Research Centre Canada)
Creanord
CrisisGo
CritiComms
CROSSCALL
Crown Castle International Corporation
CS Corporation
CSG Systems International
CST (Communications, Space & Technology Commission, Saudi Arabia)
CTG (Celestia Technologies Group)
CTL
CTS (Communication Technology Services)
CTS Corporation
CTTC (Catalan Telecommunications Technology Center)
CTU (Czech Telecommunication Office)
CTY (Japan)
CU Boulder (University of Colorado Boulder)
Cubic Corporation
Cubic Telecom
Cumucore
Custom MMIC
Cyber Forza
CybertelBridge
Cyderes
Cyient
Cyrus Technology
Czech Ministry of Interior
D2 Technologies
DAEL Group
Dahua Technology
Dali Wireless
DAMM Cellular Systems
Danish Energy Agency
Danish National Police
DART (Dallas Area Rapid Transit)
DATACOM
Datang Telecom Technology & Industry Group
Dataport
DataSoft
Datatec
DBcom
DBK (Dansk Beredskabskommunikation)
dbSpectra
DeepSig
Dejero Labs
DeKalb Police Department
DEKRA
Dell Technologies
Delta Electronics
DENGYO (Nihon Dengyo Kosaku)
Dense Air
DFW (Dallas Fort Worth) International Airport
DGS (Digital Global Systems)
Dialog Axiata
Dialogic
Diamond Communications
DIGI Communications
Digi International
Digi Telecommunications
Digicert
Digita
Digital Ally
Digital Enhancement
DigitalBridge Group
DigitalRoute
Digitata
DigitGate (Nanjing DigitGate Communication Technology)
Dimetor
DISH Network Corporation
DKK (Denki Kogyo)
D-Link Corporation
DNA (Finland)
DND (Department of National Defence, Canada)
Docomo Pacific
DOKICI
Doodle Labs
Doogee
Doosan Corporation
Dortmund Fire Brigade
Dräger
DragonWave-X
Drakontas
DRDC (Defence Research and Development Canada)
DREHTAINER
DriveNets
Drone Aviation
DroneSense
Druid Software
DRZ (German Rescue Robotics Center)
DSA (Dynamic Spectrum Alliance)
DSB (Directorate for Civil Protection, Norway)
DSBJ (Suzhou Dongshan Precision Manufacturing)
DSTL (Defence Science and Technology Laboratory, United Kingdom)
DT (Deutsche Telekom)
DTAC (Total Access Communication)
du (EITC – Emirates Integrated Telecommunications Company)
Dubai Customs
Dubai Police
Dublin City Council
Dublin Fire Brigade
Duons
Durabook (Twinhead International Corporation)
Duubee
DXC Technology
Dynabook
DZS
Eahison Communication
EANTC
Eastcom (Eastern Communications)
Easycom (Shenzhen Easycom Electronics)
E-Band Communications
e-BO Enterprises
EBRCSA (East Bay Regional Communications System Authority)
ECE (European Communications Engineering)
EchoStar Corporation
Ecom Instruments
E-Comm 9-1-1
Econocom
Ecrio
Edgecore Networks
EdgeQ
Edgybees
edotco Group
EDX Wireless
Edzcom
Effnet
EGC International
Egyptian Ministry of Defense
Eigencomm
eino
EION Wireless
Eir (Eircom)
Ekinops
Elbit Systems
Elefante Group
Element Materials Technology
E-Lins Technology
Elisa
Elisa Estonia
Elisa Polystar
Elistair
Elsight
Elta Systems
Eltex
ELUON Corporation
ELVA-1
Emblasoft
Embraer
Embratel
EMERCOM (Ministry for Civil Defense, Emergencies and Disaster Relief, Russia)
EMnify
EMS (Electronic Media Services)
ENACOM (National Communications Agency, Argentina)
Encore Networks
Enea
ENENSYS Technologies
Energizer Mobile (Avenir Telecom)
EnerSys
ENLETS (European Network of Law Enforcement Technology Services)
Entel (Chile)
Entel (United Kingdom)
Entropia
Entropy Solution
Eolane
Eoptolink Technology
EOS (Electro Optic Systems)
Equiendo
Eravant (SAGE Millimeter)
Ericsson
Ericsson-LG
Erillisverkot (State Security Networks Group, Finland)
Errigal
ErvoCom
ESA (European Space Agency)
Eseye
Esharah Etisalat Security Solutions
E-Space
Estalky (K-Mobile Technology)
Estonian Ministry of Defense
ETELM
eTera (Sinotech R&D Group)
Ethernity Networks
Etherstack
Etisalat Group (e&)
ETRI (Electronics & Telecommunications Research Institute, South Korea)
ETSI (European Telecommunications Standards Institute)
EUCAST
EURECOM
Eurescom
Eurofins E&E (Electrical and Electronics)
Eurotech
Eutelsat Group
Eventide Communications
Everbridge
Evolon Technology
EWA (Enterprise Wireless Alliance)
Ewing Police Department
Exacom
Exaware
Excelerate Technology
EXFO
Exium
Expeto
Extenet
Extreme Networks
EY (Ernst & Young)
Eyecom Telecommunications Group
EZcon Network
F2G (Far-Together) Solutions
F5


List Of Figures

Figure 1: Global LMR (Land Mobile Radio) Subscriptions by Technology: 2023 – 2030 (Millions)
Figure 2: Global Analog LMR Subscriptions: 2023 – 2030 (Millions)
Figure 3: Global DMR Subscriptions: 2023 – 2030 (Millions)
Figure 4: Global dPMR, NXDN & PDT Subscriptions: 2023 – 2030 (Millions)
Figure 5: Global P25 Subscriptions: 2023 – 2030 (Millions)
Figure 6: Global TETRA Subscriptions: 2023 – 2030 (Millions)
Figure 7: Global Tetrapol Subscriptions: 2023 – 2030 (Millions)
Figure 8: Global Other LMR Technology Subscriptions: 2023 – 2030 (Millions)
Figure 9: Minimum Performance Requirements for 5G Systems
Figure 10: Independent Private LTE/5G Network Model
Figure 11: Managed Private LTE/5G Network Model
Figure 12: Shared Core Network Model
Figure 13: Hybrid Government-Commercial Network Model
Figure 14: Secure MVNO & MOCN Network Model
Figure 15: Public Safety Access Over Commercial Broadband Networks
Figure 16: Sliced Private 5G Network for Public Safety Communications
Figure 17: Public Safety LTE & 5G Value Chain
Figure 18: Public Safety LTE & 5G Network Architecture
Figure 19: 5G NG-RAN Architecture
Figure 20: Fronthaul, Midhaul & Backhaul Transport Network Segments
Figure 21: 5GC (5G Core) Architecture
Figure 22: Sidelink Air Interface for D2D (Device-to-Device) Communications
Figure 23: Transition From Normal Backhaul Connectivity to IOPS
Figure 24: Public Safety-Related Application Scenarios of Rapidly Deployable LTE/5G Networks
Figure 25: 5G NR Access Over Satellite-Based NTN (Non-Terrestrial Network) System Architecture
Figure 26: E2E (End-to-End) Security in Public Safety LTE & 5G Networks
Figure 27: FirstNet Deployment Timeline
Figure 28: FirstNet CRD (Compact Rapid Deployable)
Figure 29: New Zealand NGCC Public Safety Networks Deployment Timeline
Figure 30: South Korea’s Safe-Net Deployment Timeline
Figure 31: Japans National PS-LTE Service Deployment Timeline
Figure 32: Royal Thai Polices LTE Network Deployment Timeline
Figure 33: Deployable LTE Platform & Terminals for the Tham Luang Cave Rescue
Figure 34: Great Britains ESN Deployment Timeline
Figure 35: ESN Product Functionality
Figure 36: Frances RRF Deployment Timeline
Figure 37: BDBOS Broadband Trial Setup
Figure 38: Germanys BOS Broadband Network Deployment Timeline
Figure 39: ASTRIDs Envisioned Hybrid Network Model for Critical Communications
Figure 40: Foreseen Network Architecture of Switzerlands MSK Network
Figure 41: MSK Program Indicative Roadmap: 2021 – 2026
Figure 42: Spains SIRDEE Mission-Critical Broadband Network Deployment Timeline
Figure 43: SIRDEE Broadband Service Portfolio
Figure 44: Swedens Rakel G2 Deployment Timeline
Figure 45: Finlands VIRVE 2.0 Deployment Timeline
Figure 46: Hungarys EDR 2.0/3.0 Deployment Timeline
Figure 47: Man-Portable 4G/5G Base Station for the California National Guard
Figure 48: Faroe Islands MCX System Architecture
Figure 49: PIAs (PSBN Innovation Alliance) Proposed Network-of-Networks Approach
Figure 50: Lishuis 5G-Enabled Integrated Emergency Visualization & Natural Disaster Management System
Figure 51: PrioComs Critical Communications MVNO Solution
Figure 52: User Segments & Applications of the RESCAN LTE Network
Figure 53: Key Architectural Elements of the Rivas Vaciamadrid Smart eLTE Network
Figure 54: Shanghai Police Convergent Command Center
Figure 55: Swisscoms Public Safety LTE Platform
Figure 56: Telstra LANES for Emergency Services
Figure 57: Thales Eiji Secure MVNO Service
Figure 58: TWFRS (Tyne and Wear Fire and Rescue Service) LTE-Equipped Command & Control Vehicle
Figure 59: Standardization of Public Safety Features in 3GPP Releases 11 – 18
Figure 60: ETSIs Critical Communications System Reference Model
Figure 61: SpiceNet (Standardized PPDR Interoperable Communication Service for Europe) Reference Architecture
Figure 62: Global Public Safety LTE & 5G Network Infrastructure Revenue: 2023 – 2030 ($ Million)
Figure 63: Global Public Safety LTE & 5G Network Infrastructure Revenue by Submarket: 2023 – 2030 ($ Million)
Figure 64: Global Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments: 2023 – 2030
Figure 65: Global Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 66: Global Public Safety LTE & 5G Mobile Core Revenue: 2023 – 2030 ($ Million)
Figure 67: Global Public Safety LTE & 5G Backhaul & Transport Revenue: 2023 – 2030 ($ Million)
Figure 68: Global Public Safety LTE & 5G Network Infrastructure Revenue by Technology Generation: 2023 – 2030 ($ Million)
Figure 69: Global Public Safety LTE Network Infrastructure Revenue: 2023 – 2030 ($ Million)
Figure 70: Global Public Safety 5G Network Infrastructure Revenue: 2023 – 2030 ($ Million)
Figure 71: Global Public Safety LTE & 5G Network Infrastructure Unit Shipments by Mobility: 2023 – 2030
Figure 72: Global Public Safety LTE & 5G Network Infrastructure Unit Shipment Revenue by Mobility: 2023 – 2030 ($ Million)
Figure 73: Global Fixed Public Safety LTE/5G Base Station & Infrastructure Unit Shipments: 2023 – 2030
Figure 74: Global Fixed Public Safety LTE/5G Base Station & Infrastructure Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 75: Global Deployable Public Safety LTE & 5G Network Asset Unit Shipments: 2023 – 2030
Figure 76: Global Deployable Public Safety LTE & 5G Network Asset Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 77: Global Deployable Public Safety LTE & 5G Network Asset Unit Shipments by Form Factor: 2023 – 2030
Figure 78: Global Deployable Public Safety LTE & 5G Network Asset Unit Shipment Revenue by Form Factor: 2023 – 2030 ($ Million)
Figure 79: Global Public Safety LTE & 5G NIB (Network-in-a-Box) Unit Shipments: 2023 – 2030
Figure 80: Global Public Safety LTE & 5G NIB (Network-in-a-Box) Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 81: Global Public Safety LTE & 5G Vehicular COW (Cell-on-Wheels) Unit Shipments: 2023 – 2030
Figure 82: Global Public Safety LTE & 5G Vehicular COW (Cell-on-Wheels) Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 83: Global Public Safety LTE & 5G Aerial Cell Site Unit Shipments: 2023 – 2030
Figure 84: Global Public Safety LTE & 5G Aerial Cell Site Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 85: Global Public Safety LTE & 5G Maritime Cellular Platform Unit Shipments: 2023 – 2030
Figure 86: Global Public Safety LTE & 5G Maritime Cellular Platform Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 87: Global Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments by Air Interface Technology Generation: 2023 – 2030
Figure 88: Global Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue by Air Interface Technology Generation: 2023 – 2030 ($ Million)
Figure 89: Global Public Safety LTE Base Station (eNB) Unit Shipments: 2023 – 2030
Figure 90: Global Public Safety LTE Base Station (eNB) Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 91: Global Public Safety 5G NR Base Station (gNB) Unit Shipments: 2023 – 2030
Figure 92: Global Public Safety 5G NR Base Station (gNB) Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 93: Global Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments by Cell Size: 2023 – 2030
Figure 94: Global Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue by Cell Size: 2023 – 2030 ($ Million)
Figure 95: Global Public Safety LTE & 5G Macrocell Base Station (eNB/gNB) Unit Shipments: 2023 – 2030
Figure 96: Global Public Safety LTE & 5G Macrocell Base Station (eNB/gNB) Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 97: Global Public Safety LTE & 5G Small Cell Base Station (eNB/gNB) Unit Shipments: 2023 – 2030
Figure 98: Global Public Safety LTE & 5G Small Cell Base Station (eNB/gNB) Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 99: Global Public Safety LTE & 5G Mobile Core Revenue by Technology Generation: 2023 – 2030 ($ Million)
Figure 100: Global Public Safety LTE EPC Revenue: 2023 – 2030 ($ Million)
Figure 101: Global Public Safety 5GC Revenue: 2023 – 2030 ($ Million)
Figure 102: Global Public Safety LTE & 5G Backhaul & Transport Revenue by Air Interface Technology Generation: 2023 – 2030
Figure 103: Global Public Safety LTE Backhaul & Transport Revenue: 2023 – 2030 ($ Million)
Figure 104: Global Public Safety 5G NR Backhaul & Transport Revenue: 2023 – 2030 ($ Million)
Figure 105: Global Public Safety LTE & 5G Backhaul & Transport Revenue by Transmission Medium: 2023 – 2030 ($ Million)
Figure 106: Global Public Safety LTE & 5G Fiber/Wireline-Based Backhaul & Transport Revenue: 2023 – 2030 ($ Million)
Figure 107: Global Public Safety LTE & 5G Microwave-Based Backhaul & Transport Revenue: 2023 – 2030 ($ Million)
Figure 108: Global Public Safety LTE & 5G Satellite-Based Backhaul & Transport Revenue: 2023 – 2030 ($ Million)
Figure 109: Global Public Safety LTE & 5G Terminal Equipment Unit Shipments: 2023 – 2030 (Thousands of Units)
Figure 110: Global Public Safety LTE & 5G Terminal Equipment Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 111: Global Public Safety LTE & 5G Terminal Equipment Unit Shipments by Air Interface Technology Generation: 2023 – 2030 (Thousands of Units)
Figure 112: Global Public Safety LTE & 5G Terminal Equipment Unit Shipment Revenue by Air Interface Technology Generation: 2023 – 2030 ($ Million)
Figure 113: Global Public Safety LTE Terminal Equipment Unit Shipments: 2023 – 2030 (Thousands of Units)
Figure 114: Global Public Safety LTE Terminal Equipment Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 115: Global Public Safety 5G NR Terminal Equipment Unit Shipments: 2023 – 2030 (Thousands of Units)
Figure 116: Global Public Safety 5G NR Terminal Equipment Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 117: Global Public Safety LTE & 5G Terminal Equipment Unit Shipments by Form Factor: 2023 – 2030 (Thousands of Units)
Figure 118: Global Public Safety LTE & 5G Terminal Equipment Unit Shipment Revenue by Form Factor: 2023 – 2030 ($ Million)
Figure 119: Global Public Safety LTE & 5G Smartphone/Handportable Terminal Unit Shipments: 2023 – 2030 (Thousands of Units)
Figure 120: Global Public Safety LTE & 5G Smartphone/Handportable Terminal Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 121: Global Public Safety LTE& 5G Mobile/Vehicular Router Unit Shipments: 2023 – 2030 (Thousands of Units)
Figure 122: Global Public Safety LTE & 5G Mobile/Vehicular Router Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 123: Global Public Safety LTE & 5G Fixed CPE Unit Shipments: 2023 – 2030 (Thousands of Units)
Figure 124: Global Public Safety LTE & 5G Fixed CPE Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 125: Global Public Safety LTE & 5G Tablet/Notebook PC Unit Shipments: 2023 – 2030 (Thousands of Units)
Figure 126: Global Public Safety LTE & 5G Tablet/Notebook PC Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 127: Global Public Safety LTE & 5G IoT Module, Dongle & Other Device Unit Shipments: 2023 – 2030 (Thousands of Units)
Figure 128: Global Public Safety LTE & 5G IoT Module, Dongle & Other Device Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 129: Global Public Safety LTE & 5G Subscriptions: 2023 – 2030 (Millions)
Figure 130: Global Public Safety LTE & 5G Service Revenue: 2023 – 2030 ($ Million)
Figure 131: Global Public Safety LTE & 5G Subscriptions by Air Interface Technology Generation: 2023 – 2030 (Millions)
Figure 132: Global Public Safety LTE & 5G Service Revenue by Air Interface Technology Generation: 2023 – 2030 ($ Million)
Figure 133: Global Public Safety LTE Subscriptions: 2023 – 2030 (Millions)
Figure 134: Global Public Safety LTE Service Revenue: 2023 – 2030 ($ Million)
Figure 135: Global Public Safety 5G NR Subscriptions: 2023 – 2030 (Millions)
Figure 136: Global Public Safety 5G NR Service Revenue: 2023 – 2030 ($ Million)
Figure 137: Global Public Safety LTE & 5G Subscriptions by Network Type: 2023 – 2030 (Millions)
Figure 138: Global Public Safety LTE & 5G Service Revenue by Network Type: 2023 – 2030 ($ Million)
Figure 139: Global Public Safety LTE & 5G Subscriptions Over Dedicated & Hybrid Government-Commercial Networks: 2023 – 2030 (Millions)
Figure 140: Global Public Safety LTE & 5G Service Revenue Over Dedicated & Hybrid Government-Commercial Networks: 2023 – 2030 ($ Million)
Figure 141: Global Public Safety LTE & 5G Subscriptions Over Secure MVNO & MOCN Networks: 2023 – 2030 (Millions)
Figure 142: Global Public Safety LTE & 5G Service Revenue Over Secure MVNO & MOCN Networks: 2023 – 2030 ($ Million)
Figure 143: Global Public Safety LTE & 5G Subscriptions Over Sliced & Commercial Mobile Networks: 2023 – 2030 (Millions)
Figure 144: Global Public Safety LTE & 5G Service Revenue Over Sliced & Commercial Mobile Networks: 2023 – 2030 ($ Million)
Figure 145: Global Public Safety LTE & 5G Systems Integration & Management Solutions Revenue: 2023 – 2030 ($ Million)
Figure 146: Global Public Safety LTE & 5G Systems Integration & Management Solutions Revenue by Submarket: 2023 – 2030 ($ Million)
Figure 147: Global Public Safety LTE & 5G Network Integration & Testing Revenue: 2023 – 2030 ($ Million)
Figure 148: Global Public Safety LTE & 5G Device Management & User Services Revenue: 2023 – 2030 ($ Million)
Figure 149: Global Public Safety LTE & 5G Managed Services, Operations & Maintenance Revenue: 2023 – 2030 ($ Million)
Figure 150: Global Public Safety LTE & 5G Cybersecurity Revenue: 2023 – 2030 ($ Million)
Figure 151: Global Public Safety Broadband Applications Revenue: 2023 – 2030 ($ Million)
Figure 152: Global Public Safety Broadband Applications Revenue by Submarket: 2023 – 2030 ($ Million)
Figure 153: Global Mission-Critical Voice & Group Communications Revenue for Public Safety Broadband: 2023 – 2030 ($ Million)
Figure 154: Global Real-Time Video Transmission Revenue for Public Safety Broadband: 2023 – 2030 ($ Million)
Figure 155: Global Messaging, File Transfer & Presence Services Revenue for Public Safety Broadband: 2023 – 2030 ($ Million)
Figure 156: Global Mobile Office & Field Applications Revenue for Public Safety Broadband: 2023 – 2030 ($ Million)
Figure 157: Global Location Services & Mapping Revenue for Public Safety Broadband: 2023 – 2030 ($ Million)
Figure 158: Global Situational Awareness Applications Revenue for Public Safety Broadband: 2023 – 2030 ($ Million)
Figure 159: Global Command & Control Applications Revenue for Public Safety Broadband: 2023 – 2030 ($ Million)
Figure 160: Global AR/VR/MR (Augmented, Virtual & Mixed Reality) Revenue for Public Safety Broadband: 2023 – 2030 ($ Million)
Figure 161: Public Safety LTE & 5G Network Infrastructure Revenue by Region: 2023 – 2030 ($ Million)
Figure 162: Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments by Region: 2023 – 2030
Figure 163: Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue by Region: 2023 – 2030 ($ Million)
Figure 164: Public Safety LTE & 5G Mobile Core Revenue by Region: 2023 – 2030 ($ Million)
Figure 165: Public Safety LTE & 5G Backhaul & Transport Revenue by Region: 2023 – 2030 ($ Million)
Figure 166: Public Safety LTE & 5G Terminal Equipment Unit Shipments by Region: 2023 – 2030 (Thousands of Units)
Figure 167: Public Safety LTE & 5G Terminal Equipment Unit Shipment Revenue by Region: 2023 – 2030 ($ Million)
Figure 168: Public Safety LTE & 5G Subscriptions by Region: 2023 – 2030 (Millions)
Figure 169: Public Safety LTE & 5G Service Revenue by Region: 2023 – 2030 ($ Million)
Figure 170: Public Safety LTE & 5G Systems Integration & Management Solutions Revenue by Region: 2023 – 2030 ($ Million)
Figure 171: Public Safety Broadband Applications Revenue by Region: 2023 – 2030 ($ Million)
Figure 172: North America Public Safety LTE & 5G Network Infrastructure Revenue: 2023 – 2030 ($ Million)
Figure 173: North America Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments: 2023 – 2030
Figure 174: North America Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 175: North America Public Safety LTE & 5G Mobile Core Revenue: 2023 – 2030 ($ Million)
Figure 176: North America Public Safety LTE & 5G Backhaul & Transport Revenue: 2023 – 2030 ($ Million)
Figure 177: North America Public Safety LTE & 5G Terminal Equipment Unit Shipments: 2023 – 2030 (Thousands of Units)
Figure 178: North America Public Safety LTE & 5G Terminal Equipment Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 179: North America Public Safety LTE & 5G Subscriptions: 2023 – 2030 (Millions)
Figure 180: North America Public Safety LTE & 5G Service Revenue: 2023 – 2030 ($ Million)
Figure 181: North America Public Safety LTE & 5G Systems Integration & Management Solutions Revenue: 2023 – 2030 ($ Million)
Figure 182: North America Public Safety Broadband Applications Revenue: 2023 – 2030 ($ Million)
Figure 183: Asia Pacific Public Safety LTE & 5G Network Infrastructure Revenue: 2023 – 2030 ($ Million)
Figure 184: Asia Pacific Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments: 2023 – 2030
Figure 185: Asia Pacific Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 186: Asia Pacific Public Safety LTE & 5G Mobile Core Revenue: 2023 – 2030 ($ Million)
Figure 187: Asia Pacific Public Safety LTE & 5G Backhaul & Transport Revenue: 2023 – 2030 ($ Million)
Figure 188: Asia Pacific Public Safety LTE & 5G Terminal Equipment Unit Shipments: 2023 – 2030 (Thousands of Units)
Figure 189: Asia Pacific Public Safety LTE & 5G Terminal Equipment Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 190: Asia Pacific Public Safety LTE & 5G Subscriptions: 2023 – 2030 (Millions)
Figure 191: Asia Pacific Public Safety LTE & 5G Service Revenue: 2023 – 2030 ($ Million)
Figure 192: Asia Pacific Public Safety LTE & 5G Systems Integration & Management Solutions Revenue: 2023 – 2030 ($ Million)
Figure 193: Asia Pacific Public Safety Broadband Applications Revenue: 2023 – 2030 ($ Million)
Figure 194: Europe Public Safety LTE & 5G Network Infrastructure Revenue: 2023 – 2030 ($ Million)
Figure 195: Europe Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments: 2023 – 2030
Figure 196: Europe Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 197: Europe Public Safety LTE & 5G Mobile Core Revenue: 2023 – 2030 ($ Million)
Figure 198: Europe Public Safety LTE & 5G Backhaul & Transport Revenue: 2023 – 2030 ($ Million)
Figure 199: Europe Public Safety LTE & 5G Terminal Equipment Unit Shipments: 2023 – 2030 (Thousands of Units)
Figure 200: Europe Public Safety LTE & 5G Terminal Equipment Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 201: Europe Public Safety LTE & 5G Subscriptions: 2023 – 2030 (Millions)
Figure 202: Europe Public Safety LTE & 5G Service Revenue: 2023 – 2030 ($ Million)
Figure 203: Europe Public Safety LTE & 5G Systems Integration & Management Solutions Revenue: 2023 – 2030 ($ Million)
Figure 204: Europe Public Safety Broadband Applications Revenue: 2023 – 2030 ($ Million)
Figure 205: Middle East & Africa Public Safety LTE & 5G Network Infrastructure Revenue: 2023 – 2030 ($ Million)
Figure 206: Middle East & Africa Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments: 2023 – 2030
Figure 207: Middle East & Africa Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 208: Middle East & Africa Public Safety LTE & 5G Mobile Core Revenue: 2023 – 2030 ($ Million)
Figure 209: Middle East & Africa Public Safety LTE & 5G Backhaul & Transport Revenue: 2023 – 2030 ($ Million)
Figure 210: Middle East & Africa Public Safety LTE & 5G Terminal Equipment Unit Shipments: 2023 – 2030 (Thousands of Units)
Figure 211: Middle East & Africa Public Safety LTE & 5G Terminal Equipment Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 212: Middle East & Africa Public Safety LTE & 5G Subscriptions: 2023 – 2030 (Millions)
Figure 213: Middle East & Africa Public Safety LTE & 5G Service Revenue: 2023 – 2030 ($ Million)
Figure 214: Middle East & Africa Public Safety LTE & 5G Systems Integration & Management Solutions Revenue: 2023 – 2030 ($ Million)
Figure 215: Middle East & Africa Public Safety Broadband Applications Revenue: 2023 – 2030 ($ Million)
Figure 216: Latin & Central America Public Safety LTE & 5G Network Infrastructure Revenue: 2023 – 2030 ($ Million)
Figure 217: Latin & Central America Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments: 2023 – 2030
Figure 218: Latin & Central America Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 219: Latin & Central America Public Safety LTE & 5G Mobile Core Revenue: 2023 – 2030 ($ Million)
Figure 220: Latin & Central America Public Safety LTE & 5G Backhaul & Transport Revenue: 2023 – 2030 ($ Million)
Figure 221: Latin & Central America Public Safety LTE & 5G Terminal Equipment Unit Shipments: 2023 – 2030 (Thousands of Units)
Figure 222: Latin & Central America Public Safety LTE & 5G Terminal Equipment Unit Shipment Revenue: 2023 – 2030 ($ Million)
Figure 223: Latin & Central America Public Safety LTE & 5G Subscriptions: 2023 – 2030 (Millions)
Figure 224: Latin & Central America Public Safety LTE & 5G Service Revenue: 2023 – 2030 ($ Million)
Figure 225: Latin & Central America Public Safety LTE & 5G Systems Integration & Management Solutions Revenue: 2023 – 2030 ($ Million)
Figure 226: Latin & Central America Public Safety Broadband Applications Revenue: 2023 – 2030 ($ Million)
Figure 225: Future Roadmap for Public Safety LTE & 5G: 2023 – 2030
Figure 226: Global Public Safety LTE & 5G Subscriptions by Network Model: 2023 – 2026 (Millions)
Figure 227: Distribution of Public Safety LTE & 5G Infrastructure Investments by Frequency Band: Q42023 (%)
Figure 230: TCO Comparison Between Fully Independent LTE/5G Networks & PPPs (Public-Private Partnerships)


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