The Public Safety LTE & 5G Market: 2020 – 2030 – Opportunities, Challenges, Strategies & Forecasts
A myriad of dedicated, hybrid commercial-private and MVNO-based public safety LTE and 5G-ready networks are operational or in the process of being rolled out throughout the globe. In addition to the high-profile FirstNet, South Koreas Safe-Net and Britains ESN nationwide public safety broadband projects, many additional national-level engagements have recently come to light most notably, the Royal Thai Polices LTE network which is already operational in the greater Bangkok region, Finlands VIRVE 2.0 mission-critical mobile broadband service, Frances PCSTORM critical communications broadband project, and Russias secure 450 MHz LTE network for police forces, emergency services and the national guard.
Other operational and pilot deployments range from nationwide systems in the oil-rich GCC (Gulf Cooperation Council) region to local and city-level private LTE networks for first responders in markets as diverse as Canada, China, Laos, Indonesia, the Philippines, Pakistan, Lebanon, Egypt, Kenya, Ghana, Cote DIvoire, Cameroon, Mali, Madagascar, Mauritius, Canary Islands, Spain, Italy, Serbia, Argentina, Brazil, Colombia, Venezuela, Bolivia, Ecuador and Trinidad & Tobago, as well as multi-domain critical communications broadband networks such as Nordic Telecom in the Czech Republic and MRCs (Mobile Radio Center) LTE-based advanced MCA digital radio system in Japan, and secure MVNO platforms in countries including but not limited to Mexico, Belgium, Switzerland, the Netherlands, Sweden, Slovenia and Estonia.
In addition, even though critical public safety-related 5G NR capabilities are yet to be standardized as part of the 3GPPs Release 17 specifications, 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, New Zealand Police are utilizing mobile operator Vodafones 5G NR network to share real-time UHD (Ultra High Definition) video feeds from cellular-equipped drones and police cruisers with officers on the ground and command posts. In the near future, we also expect to see rollouts of localized 5G NR systems 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.
It estimates that annual investments in public safety LTE/5G-ready infrastructure will surpass $2 Billion by the end of 2020, predominantly driven by new build-outs and the expansion of existing dedicated and hybrid commercial-private networks in a variety of licensed bands across 420/450 MHz, 700 MHz, 800 MHz, 1.4 GHz and higher frequencies, in addition to secure MVNO networks for critical communications. Complemented by a rapidly expanding ecosystem of public safety-grade LTE/5G devices, the market will further grow at a CAGR of approximately 10% between 2020 and 2023, eventually accounting for more than $3 Billion by the end of 2023.
The Public Safety LTE & 5G Market: 2020 2030 Opportunities, Challenges, Strategies & Forecasts report presents an in-depth assessment of the public safety LTE/5G market including market drivers, challenges, enabling technologies, application scenarios, use cases, operational models, key trends, standardization, spectrum availability/allocation, regulatory landscape, case studies, opportunities, future roadmap, value chain, ecosystem player profiles and strategies. The report also presents global and regional market size forecasts from 2020 till 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 500 global public safety LTE/5G engagements as of Q22020.
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 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 Why LTE & 5G?
2.3.1 Performance Metrics
2.3.2 Coexistence, Interoperability & Spectrum Flexibility
2.3.3 A Thriving Ecosystem of Chipsets, Devices & Network Equipment
2.3.4 Economic Feasibility of Operation
2.3.5 Moving Towards LTE-Advanced & LTE-Advanced Pro
2.3.6 Public Safety Communications Support in LTE-Advanced Pro
2.3.7 5G NR (New Radio) Capabilities & Usage Scenarios
2.3.7.1 eMBB (Enhanced Mobile Broadband)
2.3.7.2 URLCC (Ultra-Reliable Low-Latency Communications)
2.3.7.3 mMTC (Massive Machine-Type Communications)
2.3.8 5G Applications for Public Safety
2.4 Public Safety LTE & 5G Operational Models
2.4.1 Public Safety Communications Over Commercial LTE/5G Networks
2.4.2 Independent Private LTE/5G Network
2.4.3 Managed Private LTE/5G Network
2.4.4 Shared Core Private LTE/5G Network
2.4.5 Hybrid Commercial-Private LTE/5G Network
2.4.6 Secure MVNO: Commercial LTE/5G RAN With a Private Mobile Core
2.4.7 Other Approaches
2.5 Financing & Delivering Dedicated Public Safety LTE & 5G Networks
2.5.1 National Government Authority-Owned & Operated
2.5.2 Local Government/Public Safety Agency-Owned & Operated
2.5.3 BOO (Built, Owned & Operated) by Critical Communications Service Provider
2.5.4 Government-Funded & Commercial Carrier-Operated
2.5.5 Other Forms of PPPs (Public-Private Partnerships)
2.6 Market Drivers
2.6.1 Growing Demand for High-Speed & Low-Latency Data Applications
2.6.2 Recognition of LTE & 5G as the De-Facto Platform for Wireless Connectivity
2.6.3 Spectral Efficiency & Bandwidth Flexibility
2.6.4 National & Cross-Border Interoperability
2.6.5 Consumer-Driven Economies of Scale
2.6.6 Endorsement From the Public Safety Community
2.6.7 Limited Competition From Other Wireless Broadband Technologies
2.6.8 Control Over QoS (Quality-of-Service), Prioritization and Preemption Policies
2.6.9 Support for Mission-Critical Functionality
2.6.10 Privacy & Security
2.7 Market Barriers
2.7.1 Limited Availability of Licensed Spectrum for Public Safety Broadband
2.7.2 Financial Challenges Associated With Large-Scale & Nationwide Networks
2.7.3 Technical Complexities of Implementation & Operation
2.7.4 Smaller Coverage Footprint Than LMR Systems
2.7.5 Delayed Standardization & Commercialization of Mission-Critical Functionality
2.7.6 Dependence on New Chipsets for Direct-Mode Communications
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 E-UTRAN LTE RAN (Radio Access Network)
3.1.2.1 eNBs LTE Base Stations
3.1.3 NG-RAN 5G NR (New Radio) Access Network
3.1.3.1 gNBs 5G NR Base Stations
3.1.3.2 en-gNBs Secondary Node 5G NR Base Stations
3.1.3.3 ng-eNBs Next Generation LTE Base Stations
3.1.4 Transport Network
3.1.4.1 Backhaul
3.1.4.2 Fronthaul & Midhaul
3.1.5 EPC (Evolved Packet Core) LTE Mobile Core
3.1.5.1 SGW (Serving Gateway)
3.1.5.2 PGW (Packet Data Network Gateway)
3.1.5.3 MME (Mobility Management Entity)
3.1.5.4 HSS (Home Subscriber Server)
3.1.5.5 PCRF (Policy Charging and Rules Function)
3.1.6 5GC (5G Core)/NGC (Next-Generation Core)
3.1.6.1 AMF (Access & Mobility Management Function)
3.1.6.2 UPF (User Plane Function)
3.1.6.3 SMF (Session Management Function)
3.1.6.4 PCF (Policy Control Function)
3.1.6.5 NEF (Network Exposure Function)
3.1.6.6 NRF (Network Repository Function)
3.1.6.7 UDM (Unified Data Management)
3.1.6.8 UDR (Unified Data Repository)
3.1.6.9 AUSF (Authentication Server Function)
3.1.6.10 AF (Application Function)
3.1.6.11 NSSF (Network Slice Selection Function)
3.1.6.12 NWDAF (Network Data Analytics Function)
3.1.6.13 Other Elements
3.1.7 IMS (IP-Multimedia Subsystem), Application & Service Elements
3.1.7.1 IMS Core & VoLTE/VoNR
3.1.7.2 eMBMS/FeMBMS Broadcasting/Multicasting Over LTE/5G Networks
3.1.7.3 ProSe (Proximity Services)
3.1.7.4 Group Communication & Mission-Critical Services
3.1.8 Gateways for LTE/5G-External Network Interworking
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
3.2.2 Mission-Critical Video & Data
3.2.2.1 MCVideo (Mission-Critical Video)
3.2.2.2 MCData (Mission-Critical Data)
3.2.3 ProSe (Proximity Services) for D2D Connectivity & Communications
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 Scenarios
3.2.3.4 Additional Capacity for Incident Response & Special Events
3.2.3.5 Discovery Services for Disaster Relief
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 Deployable LTE & 5G Systems
3.2.5.1 Key Operational Capabilities
3.2.5.1.1 RAN-Only Systems for Coverage & Capacity Enhancement
3.2.5.1.2 Mobile Core-Integrated Systems for Autonomous Operation
3.2.5.1.3 Backhaul Interfaces & Connectivity
3.2.5.2 NIB (Network-in-a-Box): Self-Contained Portable Systems
3.2.5.2.1 Backpacks
3.2.5.2.2 Tactical Cases
3.2.5.3 Vehicular-Based Deployables
3.2.5.3.1 COW (Cell-on-Wheels)
3.2.5.3.2 COLT (Cell-on-Light Truck)
3.2.5.3.3 SOW (System-on-Wheels)
3.2.5.3.4 VNS (Vehicular Network System)
3.2.5.4 Aerial Cell Sites
3.2.5.4.1 Drones
3.2.5.4.2 Balloons
3.2.5.4.3 Other Aircraft
3.2.5.5 Maritime Platforms
3.2.6 UE Enhancements
3.2.6.1 Ruggedization to Meet Critical Communications User Requirements
3.2.6.2 Dedicated PTT Buttons & Functional Enhancements
3.2.6.3 Long-Lasting Batteries
3.2.6.4 HPUE (High-Power User Equipment)
3.2.7 IoT-Focused Technologies
3.2.7.1 eMTC, NB-IoT & mMTC: Wide Area & High Density IoT Applications
3.2.7.2 Techniques for URLLC
3.2.7.3 TSN (Time Sensitive Networking)
3.2.8 High-Precision Positioning
3.2.8.1 Support for Assisted-GNSS & RTK (Real Time Kinematic) Technology
3.2.8.2 RAN-Based Positioning Techniques
3.2.8.3 RAN-Independent Methods
3.2.9 QPP (QoS, Priority & Preemption)
3.2.9.1 3GPP-Specified QPP Capabilities
3.2.9.1.1 Access Priority: ACB (Access Class Barring)
3.2.9.1.2 Admission Priority & Preemption: ARP (Allocation and Retention Priority)
3.2.9.1.3 Traffic Scheduling Priority: QCI (QoS Class Indicator)
3.2.9.1.4 Emergency Scenarios: eMPS (Enhanced Multimedia Priority Service)
3.2.9.2 Additional QPP Enhancements
3.2.10 E2E (End-to-End) Security
3.2.10.1 3GPP-Specified Security Architecture
3.2.10.1.1 Device Security
3.2.10.1.2 Air Interface Security
3.2.10.1.3 Mobile Core & Transport Network Security
3.2.10.2 Application Domain Protection & E2E Encryption
3.2.10.3 Enhancements to Support National Security & Additional Requirements
3.2.10.4 Quantum Cryptography Technologies
3.2.11 Licensed Spectrum Sharing & Aggregation
3.2.12 Unlicensed & Shared Spectrum Usage
3.2.12.1 CBRS (Citizens Broadband Radio Service): Three-Tiered Sharing
3.2.12.2 LSA (Licensed Shared Access): Two-Tiered Sharing
3.2.12.3 sXGP (Shared Extended Global Platform): Non-Tiered Unlicensed Access
3.2.12.4 LTE-U/LAA (License Assisted Access) & eLAA (Enhanced LAA): Licensed & Unlicensed Spectrum Aggregation
3.2.12.5 MulteFire
3.2.12.6 5G NR-U
3.2.13 SDR (Software-Defined Radio)
3.2.14 Cognitive Radio & Spectrum Sensing
3.2.15 Wireless Connection Bonding
3.2.16 Network Sharing & Slicing
3.2.16.1 MOCN (Multi-Operator Core Network)
3.2.16.2 MORAN (Multi-Operator RAN)
3.2.16.3 GWCN (Gateway Core Network)
3.2.16.4 Service-Specific PLMN (Public Land Mobile Network) IDs
3.2.16.5 DDN (Data Network Name)/APN (Access Points Name)-Based Isolation
3.2.16.6 DECOR (Dedicated Core)
3.2.16.7 eDECOR (Enhanced DECOR)
3.2.16.8 5G Network Slicing
3.2.17 Software-Centric Networking
3.2.17.1 NFV (Network Functions Virtualization)
3.2.17.2 SDN (Software Defined Networking)
3.2.18 Small Cells
3.2.19 C-RAN (Centralized RAN)
3.2.20 Satellite Communications
3.2.21 High Capacity Microwave/Millimeter Wave Links
3.2.22 Wireline Fiber Infrastructure
3.2.23 SON (Self-Organizing Networks)
3.2.24 MEC (Multi-Access Edge Computing)
3.2.25 Artificial Intelligence & Machine Learning
3.2.26 Big Data & Advanced Analytics
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 Multicast-Broadcast Services in High-Density Environments
4.7.15 Direct Mode Voice, Video & Data Communications
4.7.16 Coverage Expansion Through UE-To-Network 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 Blueforce Development: Leveraging 5G and Edge Computing for Real-Time Situational Awareness
4.7.19.2 Cosumnes Fire Department: AR Firefighting Helmets
4.7.19.3 Dubai Police: AI (Artificial Intelligence)-Enabled Identification of Criminals
4.7.19.4 Dublin Fire Brigade: Coordinating Emergency Incidents With 5G Connectivity
4.7.19.5 Edgybees: Real-Time Augmented Visual Intelligence
4.7.19.6 Government of Catalonia: 5G-Equipped Emergency Medical Vehicles
4.7.19.7 National Police of the Netherlands: AR-Facilitated Crime Scene Investigations
4.7.19.8 New Zealand Police: Aerial Surveillance Through 5G NR Connectivity
4.7.19.9 NHS (National Health Service, United Kingdom): 5G-Connected Smart Ambulances
4.7.19.10 Singapore Police Force: 5G-Equipped Police Robots
4.7.19.11 V-Armed: Preparing Officers for Active Shooter Scenarios Through VR Training
4.7.19.12 Maebashi City Fire Department: 5G for Emergency Response & Rescue Services
5 Chapter 5: Review of Public Safety LTE & 5G Engagements Worldwide
5.1 North America
5.1.1 United States: Leading the Way With FirstNet The Worlds Largest Purpose-Built Public Safety Broadband Network
5.1.2 Canada: Dedicated 700 MHz LTE Network Rollouts by the Halton & Peel Regional Police Services
5.2 Asia Pacific
5.2.1 Australia: Establishing a National PSMB (Public Safety Mobile Broadband) Capability
5.2.2 New Zealand: Nationwide Critical Communications Platform Based on Commercial LTE and 5G NR Networks
5.2.3 China: City & District-Wide 1.4 GHz LTE Networks for Police Forces
5.2.4 Hong Kong: Field Trials of Dedicated 400 MHz & 700 MHz LTE Networks
5.2.5 Japan: Use of Both Commercial & Private LTE/5G Networks
5.2.6 South Korea: Safe-Net Spearheading Nationwide Public Safety LTE Network Deployments
5.2.7 Singapore: LTE-Based Broadband Overlay to Complement TETRA
5.2.8 Malaysia: Evaluating Multiple Delivery Models for Mission-Critical Broadband
5.2.9 Indonesia: Field Trials of 700 MHz Public Safety LTE Networks
5.2.10 Philippines: Rapidly Deployable LTE Systems for Disaster Relief
5.2.11 Thailand: 800 MHz LTE Network for the Royal Thai Police
5.2.12 Laos: LTE-Based Emergency Communications Networks for Local Governments
5.2.13 Myanmar: Possible Rollout of a 700 MHz Public Safety Broadband Network
5.2.14 India: Proposed Deployment of a National Hybrid Broadband PPDR Network
5.2.15 Pakistan: Dedicated 800 MHz LTE Networks for Safe City Projects
5.3 Europe
5.3.1 United Kingdom: ESN Pioneering the Use of Resilient Commercial RAN Infrastructure for Emergency Communications
5.3.2 Ireland: Early Field Trials of Dedicated LTE/5G-Ready Systems for First Responders
5.3.3 France: Transitioning to Mission-Critical Broadband Through the PCSTROM and RRF Projects
5.3.4 Germany: Planned Rollout of the BDBOS Hybrid Government-Commercial Broadband Network
5.3.5 Belgium: Government-Owned Secure MVNO With Priority & National/Cross-Border Roaming
5.3.6 Netherlands: Growing Acceptance of Secure MVNO Services for Mission-Critical Broadband
5.3.7 Switzerland: Dedicated 700 MHz RAN Trials & Secure MVNO Services With QPP (QoS, Priority & Preemption)
5.3.8 Austria: Possibility to Use Both Dedicated & Commercial RAN Infrastructure Options
5.3.9 Italy: Joint Use of TETRA & LTE Systems for Mission-Critical Communications
5.3.10 Spain: Establishing European Leadership in Dedicated Public Safety LTE Networks
5.3.11 Portugal: Preliminary Trials of 5G for Emergency Services
5.3.12 Sweden: Ongoing Efforts for 700 MHz Spectrum Allocation
5.3.13 Norway: NGN (Next Generation Ndnett) Mission-Critical Broadband System Using Commercial LTE/5G Networks
5.3.14 Denmark: Secure MVNO Model With Prioritized Access Over Commercial RAN Infrastructure
5.3.15 Finland: VIRVE 2.0 Mission-Critical Broadband Service
5.3.16 Estonia: State-Owned MVNO for Public Safety Broadband
5.3.17 Czech Republic: Worlds First 420 MHz LTE Network for Critical Communications
5.3.18 Poland: Leveraging LTE to Modernize Existing Police Radio Communications Systems
5.3.19 Greece: TETRA-Broadband Integration & LTE-Equipped Portable Emergency Command Systems
5.3.20 Turkey: Domestically-Produced LTE/5G-Ready Base Stations for Public Safety & Emergency Communications
5.3.21 Bulgaria: Hybrid TETRA-LTE Implementation to Meet Mission-Critical Communications Needs
5.3.22 Romania: Possible Deployment of a 700 MHz Public Safety Broadband Network
5.3.23 Hungary: Planned Rollout of a 420/450 MHz LTE Network to Supplement TETRA-Based EDR System
5.3.24 Slovenia: Setting 5G PPDR Projects in Motion
5.3.25 Serbia: LTE-Connected Safe City & Surveillance Systems
5.3.26 Russia: Secure 450 MHz LTE Network for Police Forces, Emergency Services & the National Guard
5.4 Middle East & Africa
5.4.1 Saudi Arabia: Unified TETRA-LTE Network for Mission-Critical Communications
5.4.2 United Arab Emirates: Emirate-Wide 700 MHz Public Safety LTE Networks
5.4.3 Qatar: Middle Easts First Dedicated Public Safety Broadband Network
5.4.4 Oman: Nationwide 800 MHz LTE Network for the ROP (Royal Oman Police)
5.4.5 Jordan: Pilot LTE Network for the Jordanian Armed Forces
5.4.6 Iraq: Local LTE-Based Wireless Communications Systems for Security Forces
5.4.7 Egypt: Security-Oriented LTE Networks for Safe City Initiatives
5.4.8 Lebanon: LTE Network for Internal Security Forces
5.4.9 Israel: LTE/5G-Ready Network Rollouts for Military & Public Safety Communications
5.4.10 South Africa: Demand for Access to Sub-1 GHz Public Safety Broadband Spectrum
5.4.11 Kenya: Custom-Built LTE Network for the Kenyan Police Service
5.4.12 Ghana: 1.4 GHz LTE-Based National Security Network
5.4.13 Nigeria: Planned Rollouts of Public Safety LTE Networks for Safe City Initiatives
5.4.14 Angola: TETRA-LTE Integration Through Commercial Mobile Operators
5.4.15 Republic of the Congo: LTE-Equipped ECVs (Emergency Communications Vehicles)
5.4.16 Cte dIvoire: Dedicated LTE Network for the Ministry of Interior and Security
5.4.17 Cameroon: LTE Connectivity for Video Surveillance & Broadband Applications
5.4.18 Mali: LTE-Based Safe City Network for Police & Security Forces
5.4.19 Madagascar: LTE-Based Secure Communications Network for the Madagascar National Police
5.4.20 Mauritius: Private LTE Network for the MPF (Mauritius Police Force)
5.5 Latin & Central America
5.5.1 Brazil: 700 MHz LTE Systems for Military Police, Fire Departments & Other Public Safety Agencies
5.5.2 Mexico: Secure MVNO Broadband Services for Public Safety & Defense Authorities
5.5.3 Argentina: Tactical LTE Systems for Incident Response & Major Events
5.5.4 Colombia: LTE Network Field Trials by the National Police of Colombia
5.5.5 Chile: Potential Rollout of a 700 MHz Public Safety LTE Network
5.5.6 Peru: Unified LMR-LTE Implementation for Mission-Critical Voice & Broadband Data Services
5.5.7 Venezuela: LTE-Equipped VEN 911/SIMA Video Surveillance and Emergency Response System
5.5.8 Ecuador: LTE-Based Communications for the ECU-911 Emergency Response Program
5.5.9 Bolivia: Dedicated LTE Networks for the BOL-110 Citizen Security System & Other Safe City Projects
5.5.10 Caribbean Countries: Diverse Operational Models to Deliver Public Safety Broadband Services
6 Chapter 6: Public Safety LTE & 5G Case Studies
6.1 Nationwide Public Safety LTE/5G Projects
6.1.1 United States FirstNet (First Responder Network)
6.1.1.1 Operational Model
6.1.1.2 Vendors
6.1.1.3 Deployment Summary
6.1.1.4 Key Applications
6.1.1.5 FirstNet Service Plans & Pricing
6.1.1.6 Integration of Early Builder Band 14 Networks
6.1.1.7 Retrofitted & Purpose-Built FirstNet Cell Sites
6.1.1.8 Rapidly Deployable Cellular Assets for Temporary Coverage & Capacity
6.1.1.9 Certification of Terminal Equipment, Accessories & Applications
6.1.1.10 HPUE Solutions for Coverage Enhancement
6.1.1.11 Controlled Introduction of 3GPP-Complaint MCPTT Service
6.1.1.12 Interoperability With Legacy LMR Systems
6.1.1.13 Supporting COVID-19 Emergency Response Efforts
6.1.2 United Kingdoms ESN (Emergency Services Network)
6.1.2.1 Operational Model
6.1.2.2 Vendors
6.1.2.3 Deployment Summary
6.1.2.4 Key Applications
6.1.2.5 ESN Products
6.1.2.6 EEs LTE Network Expansion & Additional Low Band Spectrum
6.1.2.7 Government-Funded RAN Assets for Remote Areas & the London Underground
6.1.2.8 A2G (Air-to-Ground) Network to Deliver ESN Coverage Above 500 Feet
6.1.2.9 Deployable Assets & RRVs (Rapid Response Vehicles)
6.1.2.10 Direct Mode Solution for ESN Terminals
6.1.2.11 Replacement of the Airwave TETRA Network
6.1.3 South Koreas Safe-Net (National Disaster Safety Communications Network)
6.1.3.1 Operational Model
6.1.3.2 Vendors
6.1.3.3 Deployment Summary
6.1.3.4 Key Applications
6.1.3.5 Government-Owned RAN & Mobile Core Equipment
6.1.3.6 RAN Sharing With Commercial Mobile Operators
6.1.3.7 Planned Evolution Towards 5G
6.1.3.8 Experimentation With D2D Communications
6.1.3.9 Interworking With LTE-Based Railway & Maritime Networks
6.1.4 Royal Thai Polices LTE Network
6.1.4.1 Operational Model
6.1.4.2 Vendors
6.1.4.3 Deployment Summary
6.1.4.4 Key Applications
6.1.4.5 Broadband Access for Other Government & PPDR Users
6.1.4.6 Use of Deployable LTE Assets During the Tham Luang Cave Rescue
6.1.5 Frances PCSTORM Critical Communications Broadband Project
6.1.5.1 Operational Model
6.1.5.2 Vendors
6.1.5.3 Deployment Summary
6.1.5.4 Key Applications
6.1.5.5 Paving the Way for a Nationwide LTE/5G-Based RRF (Radio Network of the Future)
6.1.5.6 RFIs to Address Direct-Mode, A2G (Air-to-Ground), LSA (Licensed Shared Access) & Other Issues
6.1.5.7 Fully Operational RRF to Support the 2023 Rugby World Cup and 2024 Olympic Games
6.1.5.8 Expansion of the Mission-Critical RRF Network to Overseas Territories
6.1.6 Finlands VIRVE 2.0 Mission-Critical Broadband Network
6.1.6.1 Operational Model
6.1.6.2 Vendors
6.1.6.3 Deployment Summary
6.1.6.4 Key Applications
6.1.6.5 Legislative Support for the Rollout of VIRVE 2.0
6.1.6.6 Migration From Existing TETRA Network to VIRVE 2.0
6.1.7 Russias Secure 450 MHz LTE Network
6.1.7.1 Operational Model
6.1.7.2 Vendors
6.1.7.3 Deployment Summary
6.1.7.4 Key Applications
6.1.7.5 Physical & Cybersecurity Measures to Address National Security Concerns
6.1.7.6 Integration With Russias National Broadband Platform for Socially Critical Infrastructure
6.1.8 Slovenias 5G PPDR (Public Protection & Disaster Relief) Project
6.1.8.1 Operational Model
6.1.8.2 Vendors
6.1.8.3 5G Pilot Deployment Summary
6.1.8.4 Key Applications
6.1.8.5 Cross-Border Collaboration With Hungary
6.1.8.6 Ongoing Rollout of Hybrid Government-Commercial LTE/5G-Ready Network
6.1.9 Belgiums ASTRID BLM (Blue Light Mobile)
6.1.9.1 Operational Model
6.1.9.2 Vendors
6.1.9.3 Deployment Summary
6.1.9.4 Key Applications
6.1.9.5 Priority & Preemption Service Levels
6.1.9.6 VPN Tunneling for Secure Connectivity
6.1.9.7 ASTRID Cloud: Application Hosting & Sharing
6.1.9.8 Future Plans for Service Evolution
6.1.9.9 Possible Rollout of Complementary RAN Infrastructure
6.1.10 Qatar MOIs (Ministry of Interior) LTE Network
6.1.10.1 Operational Model
6.1.10.2 Vendors
6.1.10.3 Deployment Summary
6.1.10.4 Key Applications
6.1.10.5 Integration With the MOIs TETRA Network
6.1.10.6 Technology-Driven Security for the 2022 FIFA World Cup
6.2 Additional Case Studies of Public Safety LTE/5G Network & Service Rollouts
6.2.1 5G RuralDorset Coastal Connectivity for First Responders
6.2.2 Abu Dhabi Police
6.2.3 Airbus MXLINK
6.2.4 BLUnet
6.2.5 Buenos Aires City Police
6.2.6 City of Sendai
6.2.7 Cochabamba Safe City Project
6.2.8 Dublin Fire Brigade
6.2.9 Ecuador ECU-911
6.2.10 Ghanas Integrated National Security Communications Network
6.2.11 Guangzhou Hybrid TETRA-5G Network
List Of Figures
Figure 1: Global LMR Subscriptions by Technology: 2020 2030 (Millions)Figure 2: Global Analog LMR Subscriptions: 2020 2030 (Millions)
Figure 3: Global DMR Subscriptions: 2020 2030 (Millions)
Figure 4: Global dPMR, NXDN & PDT Subscriptions: 2020 2030 (Millions)
Figure 5: Global P25 Subscriptions: 2020 2030 (Millions)
Figure 6: Global TETRA Subscriptions: 2020 2030 (Millions)
Figure 7: Global Tetrapol Subscriptions: 2020 2030 (Millions)
Figure 8: Global Other LMR Technology Subscriptions: 2020 2030 (Millions)
Figure 9: LTE Connection Speed Compared to 3G & Wi-Fi Networks (Mbps)
Figure 10: Global LTE & 5G Subscriptions: 2020 2030 (Millions)
Figure 11: 5G Performance Requirements
Figure 12: Public Safety Communications Over Commercial LTE/5G Networks
Figure 13: Independent Private LTE/5G Network
Figure 14: Managed Private LTE/5G Network
Figure 15: Shared Core Private LTE/5G Network
Figure 16: Hybrid Commercial-Private LTE/5G Network
Figure 17: Secure MVNO Network With a Private Mobile Core
Figure 18: Public Safety LTE & 5G Network Architecture
Figure 19: 5G NR-RAN Architecture
Figure 20: 5GC (5G Core) Service-Based Architecture
Figure 21: Sidelink Air Interface for ProSe (Proximity Services)
Figure 22: Transition From Normal Backhaul Connectivity to IOPS
Figure 23: Telefnicas Portable LTE NIB (Network-in-Box) System
Figure 24: Use Cases of eMTC and NB-IoT Technologies
Figure 25: E2E (End-to-End) Security in Public Safety LTE & 5G Networks
Figure 26: Conceptual Architecture for Network Slicing in 5G Networks
Figure 27: NFV (Network Functions Virtualization) Concept
Figure 28: C-RAN (Centralized RAN) Architecture
Figure 29: FirstNet Deployment Timeline
Figure 30: FirstNet Flying COW (Cell-on-Wheels)
Figure 31: United Kingdoms ESN Deployment Timeline
Figure 32: ESN Product Functionality & Release Dates
Figure 33: South Koreas Safe-Net Deployment Timeline
Figure 34: Royal Thai Polices LTE Network Deployment Timeline
Figure 35: Deployable LTE Platform & Terminals for the Tham Luang Cave Rescue
Figure 36: Frances PCSTORM & RRF Deployment Timeline
Figure 37: Finlands VIRVE 2.0 Deployment Timeline
Figure 38: PrioComs Critical Communications MVNO Solution
Figure 39: User Segments and Applications of the RESCAN LTE Network
Figure 40: Key Architectural Elements of the Rivas Vaciamadrid Smart eLTE Network
Figure 41: Shanghai Police Convergent Command Center
Figure 42: Swisscoms Public Safety LTE Platform
Figure 43: Telstra LANES for Emergency Services
Figure 44: Thales Eiji Secure MVNO Service
Figure 45: TWFRS (Tyne and Wear Fire and Rescue Service) LTE-Equipped Command & Control Vehicle
Figure 46: ETSIs Critical Communications System Reference Model
Figure 47: SpiceNet (Standardized PPDR Interoperable Communication Service for Europe) Reference Architecture
Figure 48: Future Roadmap for Public Safety LTE & 5G: 2020 2030
Figure 49: Public Safety LTE & 5G Value Chain
Figure 50: Global Public Safety LTE & 5G Network Infrastructure Revenue: 2020 2030 ($ Million)
Figure 51: Global Public Safety LTE & 5G Network Infrastructure Revenue by Submarket: 2020 2030 ($ Million)
Figure 52: Global Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments: 2020 2030
Figure 53: Global Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 54: Global Public Safety LTE & 5G Mobile Core Revenue: 2020 2030 ($ Million)
Figure 55: Global Public Safety LTE & 5G Backhaul & Transport Revenue: 2020 2030 ($ Million)
Figure 56: Global Public Safety LTE & 5G Network Infrastructure Revenue by Technology Generation: 2020 2030 ($ Million)
Figure 57: Global Public Safety LTE Network Infrastructure Revenue: 2020 2030 ($ Million)
Figure 58: Global Public Safety 5G Network Infrastructure Revenue: 2021 2030 ($ Million)
Figure 59: Global Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments by Air Interface Technology Generation: 2020 2030
Figure 60: Global Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue by Air Interface Technology Generation: 2020 2030 ($ Million)
Figure 61: Global Public Safety LTE Base Station (eNB) Unit Shipments: 2020 2030
Figure 62: Global Public Safety LTE Base Station (eNB) Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 63: Global Public Safety 5G NR Base Station (gNB) Unit Shipments: 2021 2030
Figure 64: Global Public Safety 5G NR Base Station (gNB) Unit Shipment Revenue: 2021 2030 ($ Million)
Figure 65: Global Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments by Cell Size: 2020 2030
Figure 66: Global Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue by Cell Size: 2020 2030 ($ Million)
Figure 67: Global Public Safety LTE & 5G Macrocell Base Station (eNB/gNB) Unit Shipments: 2020 2030
Figure 68: Global Public Safety LTE & 5G Macrocell Base Station (eNB/gNB) Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 69: Global Public Safety LTE & 5G Small Cell Base Station (eNB/gNB) Unit Shipments: 2020 2030
Figure 70: Global Public Safety LTE & 5G Small Cell Base Station (eNB/gNB) Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 71: Global Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments by Mobility: 2020 2030
Figure 72: Global Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue by Mobility: 2020 2030 ($ Million)
Figure 73: Global Fixed Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments: 2020 2030
Figure 74: Global Fixed Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 75: Global Deployable Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments: 2020 2030
Figure 76: Global Deployable Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 77: Global Deployable Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments by Form Factor: 2020 2030
Figure 78: Global Deployable Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue by Form Factor: 2020 2030 ($ Million)
Figure 79: Global Public Safety LTE & 5G NIB (Network-in-a-Box) Unit Shipments: 2020 2030
Figure 80: Global Public Safety LTE & 5G NIB (Network-in-a-Box) Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 81: Global Public Safety LTE & 5G Vehicular COW (Cell-on-Wheels) Unit Shipments: 2020 2030
Figure 82: Global Public Safety LTE & 5G Vehicular COW (Cell-on-Wheels) Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 83: Global Public Safety LTE & 5G Aerial Cell Site Unit Shipments: 2020 2030
Figure 84: Global Public Safety LTE & 5G Aerial Cell Site Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 85: Global Public Safety LTE & 5G Maritime Cellular Platform Unit Shipments: 2020 2030
Figure 86: Global Public Safety LTE & 5G Maritime Cellular Platform Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 87: Global Public Safety LTE & 5G Mobile Core Revenue by Technology Generation: 2020 2030 ($ Million)
Figure 88: Global Public Safety LTE EPC Revenue: 2020 2030 ($ Million)
Figure 89: Global Public Safety 5GC (5G Core) Revenue: 2021 2030 ($ Million)
Figure 90: Global Public Safety LTE & 5G Backhaul & Transport Revenue by Air Interface Technology Generation: 2020 2030
Figure 91: Global Public Safety LTE Backhaul & Transport Revenue: 2020 2030 ($ Million)
Figure 92: Global Public Safety 5G NR Backhaul & Transport Revenue: 2021 2030 ($ Million)
Figure 93: Global Public Safety LTE & 5G Backhaul & Transport Revenue by Transmission Medium: 2020 2030 ($ Million)
Figure 94: Global Public Safety LTE & 5G Fiber/Wireline-Based Backhaul & Transport Revenue: 2020 2030 ($ Million)
Figure 95: Global Public Safety LTE & 5G Microwave-Based Backhaul & Transport Revenue: 2020 2030 ($ Million)
Figure 96: Global Public Safety LTE & 5G Satellite-Based Backhaul & Transport Revenue: 2020 2030 ($ Million)
Figure 97: Global Public Safety LTE & 5G Terminal Equipment Unit Shipments: 2020 2030 (Thousands of Units)
Figure 98: Global Public Safety LTE & 5G Terminal Equipment Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 99: Global Public Safety LTE & 5G Terminal Equipment Unit Shipments by Air Interface Technology Generation: 2020 2030 (Thousands of Units)
Figure 100: Global Public Safety LTE & 5G Terminal Equipment Unit Shipment Revenue by Air Interface Technology Generation: 2020 2030 ($ Million)
Figure 101: Global Public Safety LTE Terminal Equipment Unit Shipments: 2020 2030 (Thousands of Units)
Figure 102: Global Public Safety LTE Terminal Equipment Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 103: Global Public Safety 5G NR Terminal Equipment Unit Shipments: 2020 2030 (Thousands of Units)
Figure 104: Global Public Safety 5G NR Terminal Equipment Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 105: Global Public Safety LTE & 5G Terminal Equipment Unit Shipments by Form Factor: 2020 2030 (Thousands of Units)
Figure 106: Global Public Safety LTE & 5G Terminal Equipment Unit Shipment Revenue by Form Factor: 2020 2030 ($ Million)
Figure 107: Global Public Safety LTE & 5G Smartphone/Handportable Terminal Unit Shipments: 2020 2030 (Thousands of Units)
Figure 108: Global Public Safety LTE & 5G Smartphone/Handportable Terminal Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 109: Global Public Safety LTE& 5G Mobile/Vehicular Router Unit Shipments: 2020 2030 (Thousands of Units)
Figure 110: Global Public Safety LTE & 5G Mobile/Vehicular Router Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 111: Global Public Safety LTE & 5G Fixed CPE Unit Shipments: 2020 2030 (Thousands of Units)
Figure 112: Global Public Safety LTE & 5G Fixed CPE Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 113: Global Public Safety LTE & 5G Tablet/Notebook PC Unit Shipments: 2020 2030 (Thousands of Units)
Figure 114: Global Public Safety LTE & 5G Tablet/Notebook PC Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 115: Global Public Safety LTE & 5G Smart Wearable Unit Shipments: 2020 2030 (Thousands of Units)
Figure 116: Global Public Safety LTE & 5G Smart Wearable Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 117: Global Public Safety LTE & 5G IoT Module, Dongle & Other Device Unit Shipments: 2020 2030 (Thousands of Units)
Figure 118: Global Public Safety LTE & 5G IoT Module, Dongle & Other Device Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 119: Global Public Safety LTE & 5G Subscriptions: 2020 2030 (Millions)
Figure 120: Global Public Safety LTE & 5G Service Revenue: 2020 2030 ($ Million)
Figure 121: Global Public Safety LTE & 5G Subscriptions by Air Interface Technology Generation: 2020 2030 (Millions)
Figure 122: Global Public Safety LTE & 5G Service Revenue by Air Interface Technology Generation: 2020 2030 ($ Million)
Figure 123: Global Public Safety LTE Subscriptions: 2020 2030 (Millions)
Figure 124: Global Public Safety LTE Service Revenue: 2020 2030 ($ Million)
Figure 125: Global Public Safety 5G NR Subscriptions: 2020 2030 (Millions)
Figure 126: Global Public Safety 5G NR Service Revenue: 2020 2030 ($ Million)
Figure 127: Global Public Safety LTE & 5G Subscriptions by Network Type: 2020 2030 (Millions)
Figure 128: Global Public Safety LTE & 5G Service Revenue by Network Type: 2020 2030 ($ Million)
Figure 129: Global Public Safety LTE & 5G Subscriptions Over Dedicated & Hybrid Commercial-Private Networks: 2020 2030 (Millions)
Figure 130: Global Public Safety LTE & 5G Service Revenue Over Dedicated & Hybrid Commercial-Private Networks: 2020 2030 ($ Million)
Figure 131: Global Public Safety LTE & 5G Subscriptions Over Secure MVNO Networks: 2020 2030 (Millions)
Figure 132: Global Public Safety LTE & 5G Service Revenue Over Secure MVNO Networks: 2020 2030 ($ Million)
Figure 133: Global Public Safety LTE & 5G Subscriptions Over Commercial Mobile Networks: 2020 2030 (Millions)
Figure 134: Global Public Safety LTE & 5G Service Revenue Over Commercial Mobile Networks: 2020 2030 ($ Million)
Figure 135: Global Public Safety LTE & 5G Systems Integration & Management Solutions Revenue: 2020 2030 ($ Million)
Figure 136: Global Public Safety LTE & 5G Systems Integration & Management Solutions Revenue by Submarket: 2020 2030 ($ Million)
Figure 137: Global Public Safety LTE & 5G Network Integration & Testing Revenue: 2020 2030 ($ Million)
Figure 138: Global Public Safety LTE & 5G Device Management & User Services Revenue: 2020 2030 ($ Million)
Figure 139: Global Public Safety LTE & 5G Managed Services, Operations & Maintenance Revenue: 2020 2030 ($ Million)
Figure 140: Global Public Safety LTE & 5G Cybersecurity Revenue: 2020 2030 ($ Million)
Figure 141: Global Public Safety Broadband Applications Revenue: 2020 2030 ($ Million)
Figure 142: Global Public Safety Broadband Applications Revenue by Submarket: 2020 2030 ($ Million)
Figure 143: Global Mission-Critical Voice & Group Communications Revenue for Public Safety Broadband: 2020 2030 ($ Million)
Figure 144: Global Real-Time Video Transmission Revenue for Public Safety Broadband: 2020 2030 ($ Million)
Figure 145: Global Messaging, File Transfer & Presence Services Revenue for Public Safety Broadband: 2020 2030 ($ Million)
Figure 146: Global Mobile Office & Field Applications Revenue for Public Safety Broadband: 2020 2030 ($ Million)
Figure 147: Global Location Services & Mapping Revenue for Public Safety Broadband: 2020 2030 ($ Million)
Figure 148: Global Situational Awareness Applications Revenue for Public Safety Broadband: 2020 2030 ($ Million)
Figure 149: Global Command & Control Applications Revenue for Public Safety Broadband: 2020 2030 ($ Million)
Figure 150: Global AR/VR/MR (Augmented, Virtual & Mixed Reality) Revenue for Public Safety Broadband: 2020 2030 ($ Million)
Figure 151: Public Safety LTE & 5G Network Infrastructure Revenue by Region: 2020 2030 ($ Million)
Figure 152: Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments by Region: 2020 2030
Figure 153: Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue by Region: 2020 2030 ($ Million)
Figure 154: Public Safety LTE & 5G Mobile Core Revenue by Region: 2020 2030 ($ Million)
Figure 155: Public Safety LTE & 5G Backhaul & Transport Revenue by Region: 2020 2030 ($ Million)
Figure 156: Public Safety LTE & 5G Terminal Equipment Unit Shipments by Region: 2020 2030 (Thousands of Units)
Figure 157: Public Safety LTE & 5G Terminal Equipment Unit Shipment Revenue by Region: 2020 2030 ($ Million)
Figure 158: Public Safety LTE & 5G Subscriptions by Region: 2020 2030 (Millions)
Figure 159: Public Safety LTE & 5G Service Revenue by Region: 2020 2030 ($ Million)
Figure 160: Public Safety LTE & 5G Systems Integration & Management Solutions Revenue by Region: 2020 2030 ($ Million)
Figure 161: Public Safety Broadband Applications Revenue by Region: 2020 2030 ($ Million)
Figure 162: North America Public Safety LTE & 5G Network Infrastructure Revenue: 2020 2030 ($ Million)
Figure 163: North America Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments: 2020 2030
Figure 164: North America Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 165: North America Public Safety LTE & 5G Mobile Core Revenue: 2020 2030 ($ Million)
Figure 166: North America Public Safety LTE & 5G Backhaul & Transport Revenue: 2020 2030 ($ Million)
Figure 167: North America Public Safety LTE & 5G Terminal Equipment Unit Shipments: 2020 2030 (Thousands of Units)
Figure 168: North America Public Safety LTE & 5G Terminal Equipment Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 169: North America Public Safety LTE & 5G Subscriptions: 2020 2030 (Millions)
Figure 170: North America Public Safety LTE & 5G Service Revenue: 2020 2030 ($ Million)
Figure 171: North America Public Safety LTE & 5G Systems Integration & Management Solutions Revenue: 2020 2030 ($ Million)
Figure 172: North America Public Safety Broadband Applications Revenue: 2020 2030 ($ Million)
Figure 173: Asia Pacific Public Safety LTE & 5G Network Infrastructure Revenue: 2020 2030 ($ Million)
Figure 174: Asia Pacific Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments: 2020 2030
Figure 175: Asia Pacific Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 176: Asia Pacific Public Safety LTE & 5G Mobile Core Revenue: 2020 2030 ($ Million)
Figure 177: Asia Pacific Public Safety LTE & 5G Backhaul & Transport Revenue: 2020 2030 ($ Million)
Figure 178: Asia Pacific Public Safety LTE & 5G Terminal Equipment Unit Shipments: 2020 2030 (Thousands of Units)
Figure 179: Asia Pacific Public Safety LTE & 5G Terminal Equipment Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 180: Asia Pacific Public Safety LTE & 5G Subscriptions: 2020 2030 (Millions)
Figure 181: Asia Pacific Public Safety LTE & 5G Service Revenue: 2020 2030 ($ Million)
Figure 182: Asia Pacific Public Safety LTE & 5G Systems Integration & Management Solutions Revenue: 2020 2030 ($ Million)
Figure 183: Asia Pacific Public Safety Broadband Applications Revenue: 2020 2030 ($ Million)
Figure 184: Europe Public Safety LTE & 5G Network Infrastructure Revenue: 2020 2030 ($ Million)
Figure 185: Europe Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments: 2020 2030
Figure 186: Europe Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 187: Europe Public Safety LTE & 5G Mobile Core Revenue: 2020 2030 ($ Million)
Figure 188: Europe Public Safety LTE & 5G Backhaul & Transport Revenue: 2020 2030 ($ Million)
Figure 189: Europe Public Safety LTE & 5G Terminal Equipment Unit Shipments: 2020 2030 (Thousands of Units)
Figure 190: Europe Public Safety LTE & 5G Terminal Equipment Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 191: Europe Public Safety LTE & 5G Subscriptions: 2020 2030 (Millions)
Figure 192: Europe Public Safety LTE & 5G Service Revenue: 2020 2030 ($ Million)
Figure 193: Europe Public Safety LTE & 5G Systems Integration & Management Solutions Revenue: 2020 2030 ($ Million)
Figure 194: Europe Public Safety Broadband Applications Revenue: 2020 2030 ($ Million)
Figure 195: Middle East & Africa Public Safety LTE & 5G Network Infrastructure Revenue: 2020 2030 ($ Million)
Figure 196: Middle East & Africa Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments: 2020 2030
Figure 197: Middle East & Africa Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 198: Middle East & Africa Public Safety LTE & 5G Mobile Core Revenue: 2020 2030 ($ Million)
Figure 199: Middle East & Africa Public Safety LTE & 5G Backhaul & Transport Revenue: 2020 2030 ($ Million)
Figure 200: Middle East & Africa Public Safety LTE & 5G Terminal Equipment Unit Shipments: 2020 2030 (Thousands of Units)
Figure 201: Middle East & Africa Public Safety LTE & 5G Terminal Equipment Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 202: Middle East & Africa Public Safety LTE & 5G Subscriptions: 2020 2030 (Millions)
Figure 203: Middle East & Africa Public Safety LTE & 5G Service Revenue: 2020 2030 ($ Million)
Figure 204: Middle East & Africa Public Safety LTE & 5G Systems Integration & Management Solutions Revenue: 2020 2030 ($ Million)
Figure 205: Middle East & Africa Public Safety Broadband Applications Revenue: 2020 2030 ($ Million)
Figure 206: Latin & Central America Public Safety LTE & 5G Network Infrastructure Revenue: 2020 2030 ($ Million)
Figure 207: Latin & Central America Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipments: 2020 2030
Figure 208: Latin & Central America Public Safety LTE & 5G Base Station (eNB/gNB) Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 209: Latin & Central America Public Safety LTE & 5G Mobile Core Revenue: 2020 2030 ($ Million)
Figure 210: Latin & Central America Public Safety LTE & 5G Backhaul & Transport Revenue: 2020 2030 ($ Million)
Figure 211: Latin & Central America Public Safety LTE & 5G Terminal Equipment Unit Shipments: 2020 2030 (Thousands of Units)
Figure 212: Latin & Central America Public Safety LTE & 5G Terminal Equipment Unit Shipment Revenue: 2020 2030 ($ Million)
Figure 213: Latin & Central America Public Safety LTE & 5G Subscriptions: 2020 2030 (Millions)
Figure 214: Latin & Central America Public Safety LTE & 5G Service Revenue: 2020 2030 ($ Million)
Figure 215: Latin & Central America Public Safety LTE & 5G Systems Integration & Management Solutions Revenue: 2020 2030 ($ Million)
Figure 216: Latin & Central America Public Safety Broadband Applications Revenue: 2020 2030 ($ Million)
Figure 217: Distribution of Public Safety LTE/5G Engagements by Frequency Band: Q22020 (%)
Figure 218: TCO Comparison Between Fully-Independent LTE/5G Networks & PPPs (Public-Private Partnerships)
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