Public Safety LTE & 5G Market: 2025 - 2030 - Opportunities, Challenges, Strategies & Forecasts
샘플 요청 목록에 추가
3GPP 표준 규격 준수 MCX(Mission-Critical PTT, Video & Data), QPP(QoS, Priority & Preemption), HPUE(High-Power User Equipment), IOPS(Isolated Operation for Public Safety)를 비롯한 중요 통신 기능의 상용화로 LTE-5G NR(New Radio) 네트워크는 실시간 비디오, 고해상도 영상, 멀티미디어 메시징, 모바일 오피스/현장 데이터 애플리케이션, 위치정보 서비스와 매핑, 상황 인식, 무인 자산 제어, 기타 광대역 기능뿐만 아니라 기존 LMR(Land Mobile Radio) 시스템이 제공하는 MCPTT(Mission-Critical PTT) 음성 및 협대역 데이터 서비스를 제공하는 종합적인 공공안전 통신 플랫폼으로 인식되고 있습니다. 3GPP 네트워크는 미래를 내다보는 전환 경로를 통해 기존 LMR 시스템을 완전히 대체할 수 있는 단계에 가까워지고 있으며, 고밀도 환경에서의 MCX 서비스를 위한 5G MBS/5MBS(5G Multicast-Broadcast Services), 네트워크 외부 통신을 위한 5G NR 사이드 링크, VMR(Vehicle-Mounted Relay), MWAB(무선 액세스 백홀링 기능이 있는 모바일 gNB), NTN(비지상파 네트워크) 통합, PPDR(공공 안전 및 재난 구호) 주파수 대역에서의 저대역폭 5G NR 지원 등 추가적인 5G 기능으로 보완됩니다.
영국, 프랑스, 핀란드, 스웨덴을 포함한 서유럽 및 북유럽 국가에서는 2028-2031년 모든 PPDR 사용자를 TETRA-Tetrapol 시스템에서 전국 규모의 미션 크리티컬 3GPP 네트워크로 전환하는 계획이 이미 진행 중입니다. 한국은 예외로, 이전에는 전국 규모의 디지털 LMR 네트워크가 존재하지 않았기 때문에 전환을 대폭 앞당겨 실시했습니다. 협대역에서 광대역으로의 전환 일정은 일부 국가에서는 더 길어질 것으로 예상됩니다. 예를 들어 루마니아의 경우, TETRA 네트워크는 2035년까지 루마니아의 새로운 3GPP 기반 PPDR 광대역 네트워크와 병행하여 운영될 것으로 예상됩니다. 미국에서는 많은 APCO P25 시스템이 2030년대 후반까지 폐기되지 않을 것으로 예상되지만, 일부 기관(특히 LMR 네트워크가 수명을 다했거나 범위가 불충분한 기관)에서는 광대역 네트워크에서 MCPTT 서비스로의 완전한 전환이 시작되고 있습니다. 뉴질랜드 당국은 새로운 디지털 LMR 네트워크를 구축하기로 결정하고 이를 공공 셀룰러 네트워크에 대한 우선 접속으로 보완하고 있습니다.
전환 상황은 차치하고서라도, 전 세계 곳곳에서 완전 전용, 정부/상업용 하이브리드, 보안 MVNO/MOCN 기반 공공안전 LTE 및 5G 네트워크가 운영 중이거나 구축되고 있습니다. 2025년 기밀 해제된 가장 큰 프로젝트 중 하나는 사우디의 국방, 법 집행 및 정보 기관을 위한 87억 달러 규모의 미션 크리티컬 광대역 네트워크입니다. 기타 국가 수준의 공공 안전 브로드밴드 네트워크 계획으로는 미국의 FirstNet(First Responder Network), 한국의 Safe-Net(국가재난안전통신망), 영국의 ESN(Emergency Services Network), 프랑스의 RRF(Radio Network of the Future), 스웨덴의 SWEN(Swedish Emergency Network), 핀란드의 PPDR 사용자 대상 VIRVE 2 브로드밴드 서비스부터 뉴질랜드의 PSN(Public Safety Network), 태국 왕립경찰의 Band 26/n26(800MHz) LTE 네트워크, 일본의 PSMS(Public Safety Mobile System), 아일랜드의 신임무중요통신시스템, 이탈리아 내무부의 공공안전 LTE/5G 서비스, 스페인의 SIRDEE(State Emergency Digital Radiocommunications System) 미션 크리티컬 브로드밴드 네트워크, 헝가리의 EDR 2.0/3.0 5G 지원 PPDR 브로드밴드 네트워크, 터키 국가경찰의 KETUM(암호화 중요 통신 시스템), 루마니아의 하이브리드 PPDR 브로드밴드 네트워크, 카타르 내무부의 LTE 네트워크, 오만의 Band 20/n20(800MHz) 공공 안전 광대역 네트워크, 요르단의 하이브리드 TETRA-LTE 통신 시스템, 이집트의 NAS(통합 국가 비상 및 공공 안전 네트워크), 브라질 연방 정부의 프라이빗 네트워크 프로젝트 등이 있습니다.
세계의 공공안전 LTE 및 5G 시장을 조사 분석했으며, 가치사슬, 시장 촉진요인, 보급 장벽, 기반 기술, 운영 모델, 응용 시나리오, 주요 동향, 향후 로드맵, 표준화, 주파수 가용성/할당, 규제 환경, 사례 연구, 에코시스템 기업 프로파일 및 전략을 포함한 상세한 평가를 제공합니다.
목차 제1장 소개
제2장 공공안전 LTE 및 5G 시장 개요
공공안전 부문의 협대역 LMR(Land Mobile Radio) 시스템
상업용 모바일 브로드밴드 기술 채용
3GPP 정의 LTE 및 5G 규격 소개
공공안전 브로드밴드에 LTE 및 5G를 채용하는 이유
공공안전 브로드밴드 네트워크 운영 모델
공공안전 전용 브로드밴드 네트워크 자금 조달과 납입
공공안전 LTE/5G 밸류체인
시장 성장 촉진요인
시장 장벽
제3장 공공안전 LTE/5G 네트워크 시스템 아키텍처와 기술
공공안전 LTE/5G 네트워크 아키텍처 컴포넌트
주요 실현 기술과 컨셉
제4장 공공안전 LTE/5G 응용 시나리오와 이용 사례
미션 크리티컬 HD 음성·그룹 통신
실시간 비디오·고해상도 영상
메시징·파일 전송·프레전스 서비스
안전하고 원활한 모바일 브로드밴드 액세스
위치 기반 서비스·매핑
지휘 통제
5G·첨단 공공안전 브로드밴드 응용
제5장 세계의 공공안전 LTE/5G의 대처 리뷰
북미
아시아태평양
유럽
중동 및 아프리카
라틴아메리카 및 중앙아메리카
제6장 공공안전 LTE/5G 사례 연구
전국적인 공공안전 LTE/5G 프로젝트
공공안전 LTE/5G 네트워크와 서비스 전개에 관한 추가 사례 연구
제7장 공공안전 LTE/5G 주파수대 가용성, 할당, 사용
공공안전 LTE 및 5G 네트워크 주파수 대역
북미
아시아태평양
호주
뉴질랜드
중국
홍콩
대만
일본
한국
싱가포르
말레이시아
인도네시아
필리핀
태국
베트남
라오스
미얀마
인도
파키스탄
방글라데시
스리랑카
기타 아시아태평양
유럽
영국
아일랜드
프랑스
독일
벨기에
네덜란드
스위스
오스트리아
이탈리아
스페인
포르투갈
스웨덴
노르웨이
덴마크
핀란드
에스토니아
라트비아
리투아니아
체코
폴란드
헝가리
슬로베니아
크로아티아
튀르키예
키프로스
그리스
불가리아
루마니아
우크라이나
러시아
기타 유럽
중동 및 아프리카
사우디아라비아
아랍에미리트
카타르
오만
바레인
쿠웨이트
이라크
요르단
이스라엘
이집트
튀니지
남아프리카공화국
보츠와나
잠비아
케냐
에티오피아
나이지리아
우간다
가나
기타 중동 및 아프리카
라틴아메리카 및 중앙아메리카
브라질
멕시코
아르헨티나
콜롬비아
칠레
페루
에콰도르
볼리비아
바베이도스
트리니다드토바고
기타 라틴아메리카 및 중앙아메리카
제8장 표준화, 규제 및 협력 이니셔티브
3GPP(Third Generation Partnership Project)
APCO(Association of Public-Safety Communications Officials) International
ASTRID
ATIS(Alliance for Telecommunications Industry Solutions)
Study of Interworking Between P25 LMR & 3GPP Mission-Critical Services
Australian Department of Home Affairs
BDBOS(Federal Agency for Public Safety Digital Radio, Germany)
BMWE(Federal Ministry for Economic Affairs and Energy, Germany)
B-TrunC(Broadband Trunking Communication) Industry Alliance
CITIG(Canadian Interoperability Technology Interest Group)
CMA(Critical Messaging Association)
DRDC(Defence Research and Development Canada)
Participation in Canada's National PSBN Program
R&D Efforts in Public Safety & Military LTE/5G Networks
DSB(Directorate for Civil Protection, Norway)
EENA(European Emergency Number Association)
Erillisverkot(State Security Networks Group, Finland)
ETSI(European Telecommunications Standards Institute)
Standards & Guidelines for Critical Communications Broadband & TETRA-3GPP Interworking
MCX Plugtests
FirstNet(First Responder Network) Authority
French Ministry of Interior
GCF(Global Certification Forum)
GPSOC(Global Public Safety Operators Conference)
United Kingdom Home Office
ICCRA(International Critical Control Rooms Alliance)
IETF(Internet Engineering Task Force)
IGOF(International Governmental Operators' Forum)
ISED(Innovation, Science and Economic Development Canada)
Interoperability Research & Evaluation of Public Safety LTE/5G Networks
ITU(International Telecommunication Union)
MOIS(Ministry of the Interior and Safety, South Korea)
National Police of the Netherlands
NCCOM(Nordic Critical Communication Operators Meeting)
Nkom(Norwegian Communications Authority)
NSC(National Spectrum Consortium)
NSW(New South Wales) Telco Authority
OMA SpecWorks(Open Mobile Alliance)
PIA(PSBN Innovation Alliance)
PSBTA(Public Safety Broadband Technology Association)
PSCE(Public Safety Communication Europe)
BroadMap: Specifications & Roadmap for Procurement
BroadWay: R&D/PCP(Pre-Commercial Procurement)
BroadNet: EUCCS(EU Critical Communication System) Preparation
PSRG(Public Safety Radiocommunications Group)
Public Safety Canada
Safe-Net Forum
Safer Buildings Coalition
TCCA(The Critical Communications Association)
TIA(Telecommunications Industry Association)
TTA(Telecommunications Technology Association, South Korea)
U.S. DHS(Department of Homeland Security)
U.S. FCC(Federal Communications Commission)
U.S. NIST(National Institute of Standards and Technology)
U.S. NPSTC(National Public Safety Telecommunications Council)
U.S. NTIA(National Telecommunications and Information Administration)
기타
제9장 주요 생태계 기업
제10장 시장 규모 추정과 예측
세계의 공공안전 LTE 및 5G 전망
공공안전 LTE 및 5G 네트워크 인프라
RAN
모바일 코어
백홀·트랜스포트
공공안전 LTE 및 5G 단말 장비
공공안전 LTE 및 5G 가입자수/서비스 매출
공공안전 LTE 및 5G 시스템 통합/관리 솔루션
공공안전 브로드밴드 용도
지역 전망
북미
아시아태평양
유럽
중동 및 아프리카
라틴아메리카 및 중앙아메리카
제11장 결론과 전략적 제안
왜 시장이 성장할 것으로 예상되는가?
향후 로드맵(2025-2030년)
벤더 상황, 제휴, 통합
주요 실현 기술의 표준화와 상용화
국가적 공공안전 브로드밴드 프로그램 리뷰
건물내 커버 범위, 프라이빗 5G, 슬라이싱, 네트워크 확장
현재 및 미래 사용 사례를 위한 대역폭 옵션
전국적인 공공안전 브로드밴드 네트워크의 경제적 실현 가능성 확보
LMR 시스템에서 미션 크리티컬 브로드밴드 네트워크로의 전환
오프 네트워크 통신의 잠정적인 솔루션
5G 시대에서의 공공안전 응용 부문 동향
전략적 제안
KSM
With the commercial availability of 3GPP standards-compliant MCX (Mission-Critical PTT, Video & Data), QPP (QoS, Priority & Preemption), HPUE (High-Power User Equipment), IOPS (Isolated Operation for Public Safety), and other critical communications features, LTE and 5G NR (New Radio) networks have gained 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. 3GPP networks are nearing the point where they can fully replace legacy LMR systems with a future-proof transition path, supplemented by additional 5G features, such as 5G MBS/5MBS (5G Multicast-Broadcast Services) for MCX services in high-density environments, 5G NR sidelink for off-network communications, VMRs (Vehicle-Mounted Relays), MWAB (Mobile gNB With Wireless Access Backhauling), NTN (Non-Terrestrial Network) integration, and support for lower 5G NR bandwidths in PPDR (Public Protection & Disaster Relief) frequency bands.
Western and Northern European countries, including the United Kingdom, France, Finland, and Sweden, are already moving ahead with plans to migrate all PPDR users from TETRA and Tetrapol systems to nationwide mission-critical 3GPP networks between 2028 and 2031. South Korea is an outlier, having carried out its transition much earlier due to the previous lack of a national-scale digital LMR network. The narrowband-to-broadband transition timeline is expected to be longer in some national markets. For example, Romania's TETRA network will continue to operate in parallel with the country's new 3GPP-based PPDR broadband network until 2035. In the United States, many APCO P25 systems are not expected to be decommissioned until the late 2030s, although some agencies - particularly those whose LMR networks are reaching end-of-life or have poor coverage - are beginning to fully transition to MCPTT services over broadband networks. Authorities in New Zealand have chosen to deploy a new digital LMR network, which is complemented by priority access over public cellular networks.
Transitions aside, a myriad of fully dedicated, hybrid government-commercial, and secure MVNO/MOCN-based public safety LTE and 5G networks are operational or in the process of being rolled out throughout the globe. One of the largest projects that emerged from secrecy in 2025 is Saudi Arabia's $8.7 billion mission-critical broadband network for the Kingdom's defense, law enforcement, and intelligence agencies. Other national-level public safety broadband network programs extend from high-profile national initiatives such as the United States' FirstNet (First Responder Network), South Korea's Safe-Net (National Disaster Safety Communications Network), Great Britain's ESN (Emergency Services Network), France's RRF (Radio Network of the Future), SWEN (Swedish Emergency Network), and Finland's VIRVE 2 broadband service for PPDR users to New Zealand's PSN (Public Safety Network), Royal Thai Police's Band 26/n26 (800 MHz) LTE network, Japan's PSMS (Public Safety Mobile System), Ireland's new mission-critical communications system, Italian Ministry of Interior's public safety LTE/5G service, Spain's SIRDEE (State Emergency Digital Radiocommunications System) mission-critical broadband network, Hungary's EDR 2.0/3.0 5G-ready PPDR broadband network, Turkish National Police's KETUM (Encrypted Critical Communications System), Romania's hybrid PPDR broadband network, Qatar MOI's (Ministry of Interior) LTE network, Oman's Band 20/n20 (800 MHz) public safety broadband network, Jordan's hybrid TETRA-LTE communications system, Egypt's NAS (Unified National Emergency & Public Safety Network), and Brazilian Federal Government's private network project.
The Hong Kong Police Force's $250 million 5G-based NGCS (Next-Generation Communications System) project, which follows a very different approach from mainland China, is comparable to national programs in smaller countries. Nationwide initiatives in the pre-operational stage include Norway's Nytt Nodnett, Germany's BOS broadband network, Belgium's NextGenCom (Next-Generation Mobile Communication), Dutch Ministry of Justice and Security's VMX (Mission-Critical Communications Renewal), Switzerland's MSK (Secure Mobile Broadband Communications) system, India's BB-PPDR (Broadband PPDR) network, Sri Lanka Police's new crime and emergency services communications system, Nigerian federal government's NPSCS (National Public Security Communication System), Australia's PSMB (Public Safety Mobile Broadband) program, and Canada's national PSBN (Public Safety Broadband Network) initiative.
3GPP-compliant MCX services are a foundational component of nationwide public safety broadband networks, and multiple procurement contracts have recently been awarded for both gateway-enabled interoperability solutions and 3GPP standards-based IWF (Interworking Function) technology, which enables system-level interworking between LMR and MCX systems during concurrent operation. The integration of NG911 (Next-Generation 911) systems, live video feeds from body-worn cameras, drones, and vehicles, 3D geolocation services, AI (Artificial Intelligence) analytics, and situational awareness platforms is increasingly gaining significance in national public safety broadband programs, as is the inclusion of rapidly deployable network assets, direct-to-device connectivity from satellites, and in-building coverage for emergency communications. FirstNet's macro coverage layer is complemented by a growing number of indoor small cells - currently at 14,000 units - supporting operation in Band 14/n14 (700 MHz) spectrum. Britain's ESN, Sweden's SWEN, and Finland's VIRVE 2 programs will also involve large-scale rollouts of in-building coverage solutions.
Beyond state-funded national programs, public mobile operators in some countries are pitching network slicing over their recently launched standalone 5G cores as an alternative to dedicated networks. Independent small-to-medium scale private 5G networks are also being deployed to address specific operational needs. For instance, Mexico City Police is using a standalone private 5G network to enable low-latency streaming of visual content to wireless VR headsets as part of an immersive training system, while Abu Dhabi Police has recently procured a private 5G solution, with an initial focus on high-definition video surveillance. The police force's broader video surveillance systems are supplemented by over 150 AI models for real-time detection of traffic violations, suspect identification, and predictive analytics for crime prevention. In Spain, Madrid City Council and UME (Emergency Military Unit) have adopted tactical bubble solutions - based on transportable private 5G cell sites and network slicing over commercial 5G networks - for enhanced emergency preparedness and forest firefighting operations. Among other examples, the southern French city of Istres has deployed a private 5G network to reduce video surveillance camera installation costs by up to 80% by eliminating infrastructure-related overheads typically associated with fiber-based connections.
In the United States, both Verizon and T-Mobile have launched first responder network slices to rival the AT&T-operated FirstNet national public safety broadband network. In addition to other Band 48/n48 (3.5 GHz) CBRS spectrum-enabled private 5G networks for smart city applications, GDC (Georgia Department of Corrections) is deploying a private 5G network to provide indoor and outdoor coverage for physically isolated and secure communications at a new state prison campus. There has also been an uptick in both procurement efforts and field trials of private 5G network equipment operating in Band n79 (4.4-5 GHz) federal spectrum and Globalstar's Band 53/n53 (2.4 GHz) spectrum. In addition, 50 MHz of public safety spectrum in the 4,940-4,990 MHz frequency range is being standardized as Band n114 (4.9 GHz) in 3GPP Release 20 specifications.
Other operational deployments range from the Halton-Peel region PSBN in Canada's Ontario province, Polkomtel's Band 87/n87 (410 MHz) MCX network in Poland, China's city and district-wide Band 45 (1.4 GHz) LTE networks for police forces, portable 5G systems and sliced virtual private 5G networks in both China and Taiwan, provincial-level Band 26/n26 (800 MHz) safe city networks in Pakistan, Nedaa's mission-critical broadband network in Dubai, Kenyan Police Service's custom-built LTE network, Zambia's 400 MHz broadband trunking system, Mauritania's public safety LTE network for urban security in Nouakchott, Madagascar's private LTE network for safe city applications in Antananarivo, Uruguayan Ministry of Interior's private LTE for border surveillance reinforcement in the Rivera Department, Brazil's state-wide LTE networks for public security secretariats, penitentiary administrations, and military police forces, and the Guyanese government's 3GPP-based critical communications network to local and regional-level public safety broadband networks in markets as diverse as Singapore, Malaysia, Indonesia, the Philippines, Laos, Iraq, Kuwait, Bahrain, Lebanon, Ghana, Cote D'Ivoire, Cameroon, Mali, Mauritius, Canary Islands, Trinidad & Tobago, Colombia, Venezuela, Ecuador, Bolivia, Argentina, Serbia, Ukraine, and Russia, as well as multi-domain critical communications broadband networks such as Southern Linc's mission-critical LTE network for first responders and utilities in the southeastern United States, and secure MVNO platforms in Mexico and several European countries.
SNS Telecom & IT estimates that annual investments in public safety LTE/5G infrastructure and devices reached $5 billion in 2025, 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 8% over the next three years, eventually accounting for more than $6.3 billion by the end of 2028. The positive outlook of the market coincides with meaningful progress in addressing the remaining challenge of direct mode or D2D (Device-to-Device) communications, which is often cited as the last major hurdle in the transition from LMR systems to 3GPP broadband technology. 5G NR sidelink-equipped prototype terminals for D2D communications and multi-hop relay networking are being made available for field trials by defense and public safety agencies between 2026 and 2027, with the commercial availability of chipsets expected before the end of the decade. In parallel, some national program administrators are adopting interim solutions, including LMR-based RSMs (Remote Speaker Microphones) and hybrid LMR-broadband devices.
The "Public Safety LTE & 5G Market: 2025 - 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 2025 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 1,900 global public safety LTE/5G engagements - as of Q1 2026.
Table of Contents 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
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 Data Service Limitations in Digital LMR Systems
2.2 Adoption of Commercial Mobile Broadband Technologies
2.2.1 Why Use Commercial Technologies?
2.2.2 Role of Mobile Broadband in Public Safety Communications
2.2.3 Can Mission-Critical 3GPP Networks Fully 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 Spectrum Diversity & Flexible Channel Bandwidths
2.4.3 Support for Mission-Critical Applications
2.4.4 Interworking With Legacy LMR Systems
2.4.5 Future Transition Path Towards 6G Networks
2.4.6 Thriving Ecosystem of Chipsets, Devices & Network Equipment
2.5 Public Safety Broadband 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 5G Network for Public Safety Communications
2.5.7 Other Approaches
2.6 Financing & Delivering Dedicated Public Safety Broadband 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 Terminal Equipment Manufacturers
2.7.3 RAN, Mobile Core & Transport Infrastructure Suppliers
2.7.4 MCX/PTT & Broadband-Enabled Application Developers
2.7.5 Connectivity Providers
2.7.5.1 Critical Communications Service Providers
2.7.5.2 Commercial Mobile Operators
2.7.5.3 In-Building Neutral Hosts
2.7.5.4 Satellite Operators & Others
2.7.6 Public Safety Communications System Integrators
2.7.7 Dispatch, Control Room & Ancillary System Specialists
2.7.8 Test/Measurement, Cybersecurity & Other Ecosystem Players
2.7.9 End User Organizations
2.8 Market Drivers
2.8.1 Growing Demand for Video Communications & High-Speed Data Access
2.8.2 Public Safety Community's Endorsement of 3GPP Technology
2.8.3 Support for MCX (Mission-Critical PTT, Video & Data) Functionality
2.8.4 Provision of Enhanced QPP (QoS, Priority & Preemption) Capabilities
2.8.5 Interoperability for National & Cross-Border Operations
2.8.6 Data Privacy & Network Security in Dedicated Broadband Networks
2.8.7 Cost Benefits Enabled by Consumer-Driven Economies of Scale
2.8.8 Limited Competition From Non-3GPP Broadband Technologies
2.9 Market Barriers
2.9.1 Licensed PPDR Spectrum Availability & Legal Basis for QPP Capabilities
2.9.2 Financial Challenges Associated With Nationwide & Large-Scale Deployments
2.9.3 Technical Complexities of Dedicated Network Implementation & Operation
2.9.4 Gap Between Standardization & Commercial Availability of Critical Features
2.9.5 ProSe/Sidelink Chipset Ecosystem for Direct Mode Communications
2.9.6 Design & Ergonomics of Broadband Devices for Critical Communications
2.9.7 COTS (Commercial Off-the-Shelf) Network Equipment Challenges
2.9.8 Conservatism of End User Organizations
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 Interoperability Gateways Supporting Non-3GPP Network Integration
3.1.5.2.5 IWF (Interworking Function) for LMR-3GPP 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
3.2.1.3 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 (PC5) Interface for 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 Cyber & 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 MWAB (Mobile gNB With Wireless Access Backhauling)
3.2.7.7 NCRs (Network-Controlled Repeaters)
3.2.7.8 NTNs (Non-Terrestrial Networks) & Direct-to-Device Technology
3.2.7.9 ATG/A2G (Air-to-Ground) Connectivity
3.2.8 QPP Mechanisms for Network Resource Control
3.2.8.1 Access Priority: ACB (Access Class Barring) & UAC (Unified Access Control)
3.2.8.2 Admission Control Priority: ARP (Allocation & Retention Priority)
3.2.8.3 Preemption: PCI/PVI (Preemption Capability & Vulnerability Information)
3.2.8.4 Traffic Scheduling Priority: QCI (QoS Class Indicator) & 5QI (5G QoS Identifier)
3.2.8.5 Emergency Scenarios: MPS (Multimedia Priority Service)
3.2.8.6 Application Priority & Additional Capabilities
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: LTE-Based Wide Area & High-Density IoT Applications
3.2.13.2 5G NR Light: RedCap (Reduced Capability) UE Type
3.2.13.3 eRedCap (Enhanced RedCap) for Low-Tier Use Cases
3.2.13.4 Ambient IoT Technology Supporting Battery-Less Operation
3.2.13.5 URLLC Techniques: High-Reliability & Low-Latency Enablers
3.2.13.6 5G LAN (Local Area Network)-Type Service
3.2.13.7 Integration With IEEE 802.1 TSN (Time-Sensitive Networking) Systems
3.2.13.8 Native 3GPP Framework for TSC (Time-Sensitive Communications)
3.2.13.9 Support for IETF DetNet (Deterministic Networking)
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
3.2.15.4.1 DSS (Dynamic Spectrum Sharing): LTE & 5G NR Coexistence
3.2.15.4.2 CBRS (Citizens Broadband Radio Service): Three-Tiered Sharing
3.2.15.4.3 LSA (Licensed Shared Access) & eLSA (Evolved LSA): Two-Tiered Sharing
3.2.15.4.4 AFC (Automated Frequency Coordination): License-Exempt Sharing
3.2.15.4.5 Local Area Licensing of Shared Spectrum
3.2.15.4.6 LTE-U, LAA (Licensed Assisted Access), eLAA (Enhanced LAA) & FeLAA (Further Enhanced LAA)
3.2.15.4.7 MulteFire: Standalone LTE Operation in Unlicensed Spectrum
3.2.15.4.8 License-Exempt 1.9 GHz sXGP (Shared Extended Global Platform)
3.2.15.4.9 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
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 First-to-Answer Calls
4.1.4 Broadcast Calls
4.1.5 Imminent Peril Calls
4.1.6 Emergency Calls & Alerts
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 Video Transport From Fixed Cameras
4.2.3 Aerial Video Surveillance
4.2.4 Group-Based Video Communications
4.2.5 Video Conferencing for Small Groups
4.2.6 Private One-To-One Video Calls
4.2.7 Video Pull & Push Services
4.2.8 Ambient Viewing
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 Data Streaming
4.3.6 Presence & Status
4.4 Secure & Seamless Mobile Broadband Access
4.4.1 IPCon (IP Connectivity) 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 NG911 (Next-Generation 911) Integration
4.6.3 Situational Awareness
4.6.4 Common Operating Picture
4.6.5 Integration of Critical IoT Assets
4.6.6 Remote Control of Drones, Robots & Other Unmanned Systems
4.6.7 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-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 Abu Dhabi Police: Leveraging Private 5G & AI Models for Real-Time Video Intelligence
4.7.19.2 Area X.O (Invest Ottawa): 5G Mobile Command Center
4.7.19.3 Blueforce Development: 5G & Edge Computing for Situational Awareness
4.7.19.4 City of Istres: Private 5G-Connected Video Surveillance Cameras
4.7.19.5 City of Las Vegas: Improving Traffic Safety With Municipal Private 5G Network
4.7.19.6 Citymesh: 5G Safety Drone Shield for Emergency Services
4.7.19.7 Cosumnes Fire Department: AR Firefighting Helmets
4.7.19.8 DRZ (German Rescue Robotics Center): 5G-Equipped Mobile Robotics for Rescue Operations
4.7.19.9 Dubai Police: AI-Enabled Identification of Criminals
4.7.19.10 Edgybees: Real-Time Augmented Visual Intelligence
4.7.19.11 Edmonton Police Service: 5G Network Slicing for Critical Surveillance During Special Events
4.7.19.12 Gimcheon City Integrated Control Center: Private 5G Network for AI-Powered CCTV System
4.7.19.13 Government of Catalonia: 5G-Equipped Emergency Medical Vehicles
4.7.19.14 Hsinchu City Fire Department: Digital Resiliency Through Satellite-Backhauled Private 5G Network
4.7.19.15 Kaohsiung City Police Department: 5G Smart Patrol Car Solution Based on End-to-End Network Slicing
4.7.19.16 LAFD (Los Angeles Fire Department): Prioritized 5G Connectivity for Wildfire Response
4.7.19.17 Leuven Police: Combating Illegal Dumping & Public Nuisances With 5G-Connected Mobile Cameras
4.7.19.18 Lishui Municipal Emergency Management Bureau: 5G-Enabled Natural Disaster Management System
4.7.19.19 Madrid City Council: Hybrid Sliced & Private 5G Network Solution for Enhanced Emergency Preparedness
4.7.19.20 Maebashi City Fire Department: 5G for Emergency Response & Rescue Services
4.7.19.21 Mexico City Police: Transforming Law Enforcement Training Using Private 5G & Wireless VR
4.7.19.22 National Police of the Netherlands: AR-Facilitated Crime Scene Investigations
4.7.19.23 New Zealand Police: Aerial Surveillance Through 5G NR Connectivity
4.7.19.24 NHS (National Health Service, United Kingdom): 5G-Connected Smart Ambulances
4.7.19.25 Norwegian Air Ambulance: Portable 5G Network for Search & Rescue Operations
4.7.19.26 PDRM (Royal Malaysia Police): 5G-Enabled Safe City Solution for Langkawi
4.7.19.27 Shenzhen Public Security Bureau: 5G-Connected Unmanned Police Boats
4.7.19.28 Skydio: 5G-Enabled Multi-Modal Drone Connectivity Solution for Public Safety Agencies
4.7.19.29 SPF (Singapore Police Force): 5G-Equipped Police Robots
4.7.19.30 UME (Emergency Military Unit, Spain): Private 5G Solution for Forest Firefighting Operations
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 World's Largest Public Safety Broadband Network
5.1.2 Canada: National PSBN (Public Safety Broadband Network) - Hopes for Progress Through New National Security Funding
5.2 Asia Pacific
5.2.1 Australia: National PSMB (Public Safety Mobile Broadband) Program
5.2.2 New Zealand: PSN (Public Safety Network) Program - Multi-Operator Cellular Roaming With Priority & Preemption
5.2.3 China: Private 5G Slicing & Band 45 (1.4 GHz) LTE Networks for Police Forces
5.2.4 Hong Kong: NGCS (Next-Generation Communications System) - Band 28/n28 (700 MHz) Mission-Critical 5G Network
5.2.5 Taiwan: Private 5G Deployables for Local Agencies & Planned Implementation of an MOCN-Enabled National PPDR Broadband System
5.2.6 Japan: PSMS (Public Safety Mobile System) - National Secure MVNO Service With Priority Access for First Responders
5.2.7 South Korea: Safe-Net - Spearheading Nationwide Public Safety Broadband Network Deployments
5.2.8 Singapore: Evolution of Public Safety Communications & Sliced Defense/National Security 5G Solution
5.2.9 Malaysia: Evaluating Multiple Delivery Models for Mission-Critical Broadband Services
5.2.10 Indonesia: Hybrid Narrowband-Broadband Solutions & Field Trials of 450/700 MHz Public Safety LTE Networks
5.2.11 Philippines: Rapidly Deployable LTE Systems for Disaster Relief
5.2.12 Thailand: Band 26/n26 (800 MHz) LTE Network for the Royal Thai Police
5.2.13 Vietnam: Future Plans for a Public Safety Broadband Capability
5.2.14 Laos: LTE-Based Emergency Communications Networks for Local Governments
5.2.15 Myanmar: Possible Rollout of a 700 MHz Public Safety Broadband Network
5.2.16 India: Proposed Deployment of a Pan-India BB-PPDR (Broadband PPDR) Network
5.2.17 Pakistan: Dedicated Band 26/n26 (800 MHz) LTE Networks for Safe City Projects
5.2.18 Sri Lanka: Planned Deployment of an LTE-Based Emergency Services Communications System
5.2.19 Bangladesh: Portable LTE Networks for VIP Protection Operations
5.3 Europe
5.3.1 United Kingdom
5.3.1.1 Great Britain: ESN - Leveraging Resilient Commercial RAN Infrastructure for Emergency Communications
5.3.1.2 Northern Ireland: Shared RAN for FRMCS & Public Safety Broadband Communications
5.3.2 Republic of Ireland: TETRA Replacement With a Hybrid Commercial-Government Network
5.3.3 France: RRF (Radio Network of the Future) - Transitioning From Tetrapol to Mission-Critical Broadband
5.3.4 Germany: Moving Towards Phase 1 of New BDBOS Broadband Program
5.3.5 Belgium: NextGenCom (Next-Generation Mobile Communication) Program
5.3.6 Luxembourg: MCX Over Commercial Networks & RRVs (Rapid Response Vehicles) for Security Missions
5.3.7 Netherlands: Upcoming Tender Process VMX (Mission-Critical Communications Renewal) Program
5.3.8 Switzerland: Delays to the MSK (Secure Mobile Broadband Communications) Program
5.3.9 Austria: Preliminary Planning for a Future Secure Mobile Broadband System
5.3.10 Italy: National Rollout of Mission-Critical Broadband Across 11 Provinces
5.3.11 Spain: Ongoing Buildout of the SIRDEE Mission-Critical Broadband Network
5.3.12 Portugal: Field Trials of TETRA-LTE Integration & 5G for Emergency Services
5.3.13 Sweden: SWEN (Swedish Emergency Network) - Progressing Towards TETRA-to-3GPP MCX Migration
5.3.14 Norway: Nytt Nodnett - Mission-Critical Communications Over Commercial 3GPP Networks
5.3.15 Denmark: FREBI (Future of Emergency Communication - Infrastructure) Project
5.3.16 Finland: VIRVE 2 - MOCN-Based Mission-Critical Broadband Service
5.3.17 Estonia: Preliminary Planning for TETRA-to-Broadband Migration
5.3.18 Latvia: 5G-Connected Drones for Public Safety Monitoring & Rescue Operations
5.3.19 Lithuania: Preparatory Work on National Public Safety Broadband Program
5.3.20 Czech Republic: Virtual Network Operator Model for Governmental Purposes
5.3.21 Poland: MCX Over 410 MHz LTE Network for First Responders & Critical User Groups
5.3.22 Hungary: EDR 2.0 Broadband Service Over Band 3/n3 (1.8 GHz) 5G-Ready PPDR Network
5.3.23 Slovenia: Establishment of an Interface Between TETRA & LTE/5G Networks
5.3.24 Croatia: Early Planning Efforts for PPDR Broadband Program
5.3.25 Turkiye: KETUM Hybrid Narrowband-Broadband Public Safety Communications System
5.3.26 Cyprus: Planned Deployment of 700 MHz Public Safety Broadband Network
5.3.27 Greece: Preparations for National Mobile Broadband Project
5.3.28 Bulgaria: LTE-Equipped Body Cameras & TETRA-Broadband Integration
5.3.29 Romania: Procurement Contracts Issued for Hybrid PPDR Broadband Network
5.3.30 Serbia: Expansion of eLTE Network for Video Surveillance & Broadband Trunking
5.3.31 Ukraine: Use of Both Private & Commercial Mobile Networks for Public Safety Broadband
5.3.32 Russia: Delayed Buildout of 360-380 MHz LTE Network for Public Safety & Transport Authorities
5.4 Middle East & Africa
5.4.1 Saudi Arabia: Mission-Critical Broadband Network for Defense, Law Enforcement & Intelligence Agencies
5.4.2 United Arab Emirates: Emirate-Wide Band 28/n28 (700 MHz) Public Safety Broadband Networks
5.4.3 Qatar: The Middle East's First Dedicated Public Safety Broadband Network
5.4.4 Oman: Nationwide Band 20/n20 (800 MHz) LTE Network for the ROP (Royal Oman Police)
5.4.5 Bahrain: Planned Rollout of PPDR Broadband Network
5.4.6 Kuwait: Mission-Critical Communications Solution for Narrowband-to-Broadband Transition
5.4.7 Iraq: Local LTE-Based Wireless Systems for Tactical Communications
5.4.8 Jordan: Hybrid TETRA-LTE Communications System
5.4.9 Lebanon: LTE Network for Internal Security Forces
5.4.10 Israel: Mission-Critical LTE/5G-Ready Networks for Military & Public Safety Communications
5.4.11 Egypt: NAS (Unified National Emergency & Public Safety Network) Program
5.4.12 Tunisia: Dedicated Band 28/n28 (700 MHz) Spectrum for Public Safety Broadband
5.4.13 South Africa: Demand for Access to Sub-1 GHz PPDR Broadband Spectrum
5.4.14 Botswana: Planned Band 87/n87 (410 MHz) Public Safety Broadband Network
5.4.15 Zambia: 400 MHz Private Broadband System for Safe City Project
5.4.16 Kenya: Custom-Built LTE Network for the Kenyan Police Service
5.4.17 Madagascar: Antananarivo Private LTE Network for Public Safety & Government Agencies
5.4.18 Mauritius: Public Safety LTE Network for the MPF (Mauritius Police Force)
5.4.19 Seychelles: Physically Hardened & Geo-Redundant Emergency Communications Network
5.4.20 Angola: TETRA-LTE Integration Through Commercial Mobile Operators
5.4.21 Republic of the Congo: LTE-Equipped ECVs (Emergency Communications Vehicles)
5.4.22 Cameroon: Dedicated LTE Network for Video Surveillance & Broadband Applications
5.4.23 Nigeria: NPSCS (National Public Security Communication System) Project
5.4.24 Uganda: Private Wireless Network for Fixed & Wireless Surveillance Cameras
5.4.25 Ghana: 1.4 GHz LTE-Based National Security Communications Network
5.4.26 Cote d'Ivoire: Purpose-Built LTE Network for the Ministry of Interior and Security
5.4.27 Mali: LTE-Based Safe City Network for Police & Security Forces
5.4.28 Senegal: LTE-Enabled Smart City & Video Surveillance System
5.4.29 Mauritania: Public Safety LTE Network for Urban Security in Nouakchott
5.5 Latin & Central America
5.5.1 Brazil: Private Broadband Networks for the Federal District & State-Level Authorities
5.5.2 Mexico: Secure MVNO Broadband Services for Public Safety & Defense Authorities
5.5.3 Argentina: City of Buenos Aires' Hybrid TETRA-MCX Service Platform
5.5.4 Uruguay: Private LTE Network for Border Surveillance Operations
5.5.5 Colombia: LTE Network Field Trials by the National Police of Colombia
5.5.6 Chile: Complementary Broadband Access Over Commercial Networks
5.5.7 Peru: Unified LMR-LTE Implementation for Mission-Critical Voice & Broadband Data Services
5.5.8 Venezuela: LTE-Equipped VEN 911/SIMA Video Surveillance & Emergency Response System
5.5.9 Ecuador: LTE-Based Communications for the ECU-911 Emergency Response Program
5.5.10 Bolivia: Private LTE Networks for the BOL-110 Citizen Security System & Other Safe City Projects
5.5.11 Barbados: Band 14/n14 (700 MHz) 3GPP-Based Connectivity Service Platform
5.5.12 Trinidad & Tobago: Rapidly Deployable 400 MHz LTE System for National Security Applications
5.5.13 Dutch Caribbean: Integrated LMR-Broadband Systems for Mission-Critical Voice & Broadband Capabilities
5.5.14 Guyana: 3GPP-Based Critical Communications Network for Safe City Applications
Chapter 6: Public Safety LTE/5G Case Studies
6.1 Nationwide Public Safety LTE/5G Projects
6.1.1 United States' FirstNet Nationwide Public Safety Broadband Network
6.1.1.1 Operational Model
6.1.1.2 Integrators & Suppliers
6.1.1.3 Deployment Summary
6.1.1.3.1 AT&T RAN & Purpose-Built Band 14/n14 (700 MHz) Cell Sites
6.1.1.3.2 Physically Isolated Mobile Core Infrastructure
6.1.1.3.3 In-Building Coverage Enhancement Solutions
6.1.1.3.4 Deployables for Disasters, Critical Incidents & Planned Events
6.1.1.3.5 Plans for Direct-to-Cellular Connectivity via LEO Satellites
6.1.1.3.6 Standalone 5G Core Upgrade & Additional Investments
6.1.1.4 Key Applications
6.1.1.5 3GPP-Compliant MCX Service Platforms
6.1.1.6 Interoperability With Legacy LMR Systems
6.1.1.7 FirstNet Service Plans & Pricing
6.1.1.8 Certification of Terminals, Accessories & Applications
6.1.1.9 HPUE & In-Vehicle Solutions
6.1.2 New Zealand's NGCC (Next-Generation Critical Communications)-Led PSN Program
6.1.2.1 Operational Model
6.1.2.2 Integrators & Suppliers
6.1.2.3 Deployment Summary
6.1.2.3.1 Multi-Network Cellular Roaming Service
6.1.2.3.2 Priority Access for First Responders
6.1.2.3.3 Network Visibility Service
6.1.2.3.4 Compact Rapid Deployables for Temporary Coverage
6.1.2.4 Key Applications
6.1.2.5 Transition Timeline
6.1.3 Hong Kong Police Force's 5G-Based NGCS Project
6.1.3.1 Operational Model
6.1.3.2 Integrators & Suppliers
6.1.3.3 Deployment Summary
6.1.3.3.1 Phase 1: Dedicated Core, MCX Platform & Shared Mobile Operator RAN Services
6.1.3.3.2 Phase 2: Purpose-Built Band 28/n28 (700 MHz) RAN Infrastructure in Strategic Locations
6.1.3.4 Key Applications
6.1.3.5 Direct Supplier Engagement Instead of Public Tendering
6.1.3.6 TETRA Replacement & Anticipated Cost Savings
6.1.4 Japan's PSMS (Public Safety Mobile System) Service - Formerly PS-LTE (Public Safety LTE)
6.1.4.1 Operational Model
6.1.4.2 Integrators & Suppliers
6.1.4.3 Deployment Summary
6.1.4.3.1 Field Demonstration Tests of PS-LTE Technology
6.1.4.3.2 Launch of National PSMS-Compatible Services
6.1.4.4 Key Applications
6.1.4.5 PSMS Service Evolution Plans
6.1.4.6 Substitution of Legacy Systems With PSMS
6.1.5 South Korea's Safe-Net National Disaster Safety Communications Network
6.1.5.1 Operational Model
6.1.5.2 Integrators & Suppliers
6.1.5.3 Deployment Summary
6.1.5.3.1 Nationwide Buildout Following Successful Pilot Projects
6.1.5.3.2 Government-Owned RAN & Mobile Core Infrastructure
6.1.5.3.3 MOCN-Based RAN Sharing With Mobile Operators
6.1.5.3.4 Transportable Base Stations for Coverage Extension
6.1.5.3.5 Interworking With 3GPP-Based Railway & Maritime Networks
6.1.5.4 Key Applications
6.1.5.5 MCX Service & eMBMS Bearer Support
6.1.5.6 Future Plans for 4G-5G Interworking & Migration
6.1.5.7 AI-Enabled Safety Management System for South Korea
6.1.6 Royal Thai Police's Band 26/n26 (800 MHz) LTE Network
6.1.6.1 Operational Model
6.1.6.2 Integrators & Suppliers
6.1.6.3 Deployment Summary
6.1.6.3.1 Initial Buildout in Bangkok
6.1.6.3.2 Expansion to Other Major Cities
6.1.6.3.3 Rapidly Deployable Network-in-a-Box Systems
6.1.6.3.4 Integration With National Command, Control & Dispatch Platform
6.1.6.4 Key Applications
6.1.6.5 Broadband Access for Other Government & PPDR Users
6.1.6.6 Use of Portable LTE Network During the Tham Luang Cave Rescue
6.1.6.7 APEC (Asia-Pacific Economic Cooperation) Meetings in Thailand
6.1.7 Great Britain's ESMCP Program & ESN Critical Communications System
6.1.7.1 Operational Model
6.1.7.2 Integrators & Suppliers
6.1.7.3 Deployment Summary
6.1.7.3.1 Enhanced Coverage Over EE's Commercial RAN Infrastructure
6.1.7.3.2 Government-Funded EAS (Extended Area Service) Cell Sites
6.1.7.3.3 ESN Air: Overlay A2G Network for Emergency Service Aircraft
6.1.7.3.4 London Underground & Specific Road/Rail Tunnels
6.1.7.3.5 In-Building Coverage Enhancement Solutions
6.1.7.3.6 Rapidly Deployable Assets for Temporary Coverage
6.1.7.3.7 Dedicated Three-Site Mobile Core Network
6.1.7.3.8 Comprehensive User Services
6.1.7.4 Key Applications
6.1.7.5 ESN Products & MCX Solution
6.1.7.6 Replacement of the Airwave TETRA Network
6.1.7.7 ESN-Airwave Interworking During Switchover
6.1.8 Ireland's New Mission-Critical Communications System
6.1.8.1 Operational Model
6.1.8.2 Integrators & Suppliers
6.1.8.3 Deployment Summary
6.1.8.3.1 NLLP (National Low-Latency Platform) & Project 2.5
6.1.8.3.2 Westport & Rosslare Europort Field Trials
6.1.8.3.3 Mission-Critical Communications System Rollout
6.1.8.4 Key Applications
6.1.8.5 Enhancing Emergency Response in Rural Communities
6.1.9 France's RRF Future Public Safety Network Program
6.1.9.1 Operational Model
6.1.9.2 Integrators & Suppliers
6.1.9.3 Deployment Summary
6.1.9.3.1 Multi-Operator 4G/5G RAN Coverage
6.1.9.3.2 Geo-Redundant Core Infrastructure
6.1.9.3.3 Deployable Solutions for Ad Hoc Coverage
6.1.9.3.4 700 MHz PPDR Broadband Spectrum
6.1.9.4 Key Applications
6.1.9.5 MCX Application & Interoperability Gateways
6.1.9.6 RSM Devices for Off-Network Communications
6.1.9.7 Transition From Tetrapol to the RRF Network
6.1.9.8 RRF Expansion to Overseas Territories
6.1.10 Germany's BOS Broadband Network Development Program
6.1.10.1 Operational Model
6.1.10.2 Integrators & Suppliers
6.1.10.3 Deployment Summary
6.1.10.3.1 Hybrid Broadband Network Trial
6.1.10.3.2 Project KoMeT: Dedicated 4G/5G Core Network Implementation
6.1.10.3.3 Project MCx System: Procurement of MCX Solution
6.1.10.3.4 Access Over Commercial Networks & Plans for State-Controlled RAN
6.1.10.4 Key Applications
6.1.10.5 Interoperability With TETRA & Bundeswehr's Cellular Assets
6.1.10.6 KoPa_45: R&D Projects to Support the Broadband Strategy of BDBOS
6.1.11 Belgium's ASTRID BLM (Blue Light Mobile) Service & NextGenCom Program
6.1.11.1 Operational Model
6.1.11.2 Integrators & Suppliers
6.1.11.3 BLM Secure MVNO Service
6.1.11.3.1 Priority & Preemption Service Levels
6.1.11.3.2 VPN Tunneling for Secure Connectivity
6.1.11.3.3 ASTRID Cloud: Application Hosting & Sharing
6.1.11.4 NextGenCom Deployment Summary
6.1.11.4.1 Geo-Redundant Core Network
6.1.11.4.2 MCRAN (Mission-Critical RAN) Infrastructure
6.1.11.4.3 MOCN-Based RAN Sharing With Commercial Mobile Operators
6.1.11.4.4 Integration of Private Networks & Coverage Enhancement Solutions
6.1.11.5 Key Applications
6.1.11.6 Planned Implementation of MCX Solution
6.1.11.7 TETRA-to-NextGenCom Migration
6.1.12 Italian Ministry of Interior's LTE/5G Mission-Critical Broadband Service
6.1.12.1 Operational Model
6.1.12.2 Integrators & Suppliers
6.1.12.3 Deployment Summary
6.1.12.3.1 Dedicated Frequencies for Guaranteed Bandwidth
6.1.12.3.2 Hybrid RAN, Core Network & eMBMS Solution
6.1.12.3.3 Mission-Critical Broadband Service Rollout in 11 Provinces
6.1.12.4 Key Applications
6.1.12.5 Standalone 5G Connectivity & Service Evolution
6.1.12.6 Future Plans for TETRA-to-Broadband Migration
6.1.13 Spain's SIRDEE Mission-Critical Broadband Network
6.1.13.1 Operational Model
6.1.13.2 Integrators & Suppliers
6.1.13.3 Deployment Summary
6.1.13.3.1 Purpose-Built Cell Sites for Exclusive Use
6.1.13.3.2 Dedicated Core Network & MCX Servers
6.1.13.3.3 eMBMS Integration for Multicast Bearer Support
6.1.13.3.4 Backup Connectivity via Commercial RAN Coverage
6.1.13.4 Key Applications
6.1.13.5 Specific Requirements for Mission-Critical Broadband Network
6.1.13.6 Preparing for Tetrapol-to-Broadband Transition
6.1.14 Sweden's SWEN Next-Generation Digital Network for Critical Communications
6.1.14.1 Operational Model
6.1.14.2 Integrators & Suppliers
6.1.14.3 Deployment Summary
6.1.14.3.1 Dual-Mode 5G Core Solution
6.1.14.3.2 MOCN-Enabled Commercial RAN Access
6.1.14.3.3 Dedicated Band 28/n28 (700 MHz) Coverage Layer
6.1.14.3.4 Integration With Other Public Sector 5G Networks
6.1.14.3.5 Indoor Coverage, Portable Cell Sites & Other Initiatives
6.1.14.4 Key Applications
6.1.14.5 TETRA-to-3GPP Migration Solution
6.1.14.6 Procurement of 3GPP-Based MCX Platform
6.1.14.7 Future Support for Device-to-Device Communications
6.1.14.8 Cross-Border Cooperation
6.1.14.9 Timeline for Rakel G1 to SWEN Migration
6.1.15 Finland's VIRVE 2 Mission-Critical Broadband Service for PPDR Users
6.1.15.1 Operational Model
6.1.15.2 Integrators & Suppliers
6.1.15.3 Deployment Summary
6.1.15.3.1 State-Owned 4G/5G Core Network & Application Servers
6.1.15.3.2 MOCN-Enabled Commercial RAN Coverage With QPP
6.1.15.3.3 New Base Stations & Battery Backups for Site Hardening
6.1.15.3.4 In-Building Installations for VIRVE 2 Service Availability
6.1.15.3.5 Integration of Band 68/n68 (700 MHz) Private RAN Coverage
6.1.15.3.6 National & International Roaming for Finnish PPDR Agencies
6.1.15.3.7 Evaluation of NTN Coverage Expansion via LEO Satellites
6.1.15.4 Key Applications
6.1.15.5 MCX Services & User Equipment
6.1.15.6 Legislative Support for the Operation of VIRVE 2
6.1.15.7 Migration From TETRA to Mission-Critical Broadband
6.1.16 Hungary's EDR 2.0/3.0 5G-Ready PPDR Broadband Network
6.1.16.1 Operational Model
6.1.16.2 Integrators & Suppliers
6.1.16.3 Deployment Summary
6.1.16.3.1 EDR 2.0 Rollout: Band 3/n3 (1.8 GHz) RAN, Dual-Mode Core & MOCN Coverage
6.1.16.3.2 Further EDR 2.0 Development: Roaming, eSIMs & Number Portability
6.1.16.3.3 EDR 3.0 Service: Aerial Coverage for Drones, Hotspots & MCX Solution
6.1.16.4 Key Applications
6.1.16.5 TETRA-Broadband Interoperability
6.1.16.6 Cross-Border Cooperation With Neighboring Countries
6.1.16.7 5G Smartcom: Standalone 5G Network Along the Ukrainian Border
6.1.17 Turkish National Police's KETUM Program
6.1.17.1 Operational Model
6.1.17.2 Integrators & Suppliers
6.1.17.3 Deployment Summary
6.1.17.3.1 Mission-Critical LTE Network Buildout in Adana
6.1.17.3.2 Nationwide Expansion of Hybrid Narrowband-Broadband System
6.1.17.3.3 Rapidly Deployable Network Assets for Coverage Extension
6.1.17.4 Key Applications
6.1.17.5 Supporting Public Safety Modernization
6.1.18 Romania's LTE/5G NR-Based Hybrid PPDR Broadband Network Project
6.1.18.1 Operational Model
6.1.18.2 Integrators & Suppliers
6.1.18.3 Deployment Summary
6.1.18.3.1 Initial Operational Deployment
6.1.18.3.2 Public Mobile Operator Interconnections & QPP Rights
6.1.18.3.3 Gradual Expansion of State-Owned RAN Infrastructure
6.1.18.4 Key Applications
6.1.18.5 Additional Public Tenders for Network & Service Expansion
6.1.19 Saudi Arabia's Mission-Critical Broadband Network for Defense, Law Enforcement & Intelligence Agencies
6.1.19.1 Operational Model
6.1.19.2 Integrators & Suppliers
6.1.19.3 Deployment Summary
6.1.19.3.1 RAN Infrastructure
6.1.19.3.2 Core Network Buildout
6.1.19.3.3 MCX Services & Terminals
6.1.19.4 Key Applications
6.1.19.5 Unifying Secure Communications
6.1.20 Qatar MOI's (Ministry of Interior) Nationwide Public Safety LTE Network
6.1.20.1 Operational Model
6.1.20.2 Integrators & Suppliers
6.1.20.3 Deployment Summary
6.1.20.3.1 Band 20/n20 (800 MHz) for Nationwide Coverage
6.1.20.3.2 Band 7/n7 (2.6 GHz) for Additional Capacity
6.1.20.3.3 Dedicated Core Network Infrastructure
6.1.20.3.4 eMBMS Integration & MCX Upgrades
6.1.20.4 Key Applications
6.1.20.5 Integration With the MOI's TETRA Network
6.1.20.6 Technology-Driven Security for the FIFA World Cup
6.1.20.7 Delivering Safe City Applications for Qatar National Vision 2030
6.2 Additional Case Studies of Public Safety LTE/5G Network & Service Rollouts
6.2.1 Abu Dhabi Police
6.2.2 Bahia State Secretariat of Public Security
6.2.3 Brazilian Federal Government's Private Network Project
6.2.4 Buenos Aires Ministry of Justice and Security
6.2.5 Bundeswehr (German Armed Forces)
6.2.6 California National Guard
6.2.7 Ceara Secretariat of Penitentiary Administration and Reintegration
6.2.8 City of Brownsville
6.2.9 City of Sendai
6.2.10 Cochabamba Safe City Project
6.2.11 Ecuador ECU-911
6.2.12 Foroya Tele's (Faroese Telecom) KIMA
6.2.13 Georgia State Patrol
6.2.14 Ghana's Integrated National Security Communications Network
6.2.15 Gimcheon City Integrated Control Center
6.2.16 Government of Barbados
6.2.17 Guangzhou Hybrid TETRA-5G Network
6.2.18 Halton-Peel Region PSBN (Public Safety Broadband Network)
6.2.19 Hsinchu City Fire Department
6.2.20 Kaohsiung City Police Department
6.2.21 Kenyan Police Service
6.2.22 Lijiang Police
6.2.23 Lishui Municipal Emergency Management
6.2.24 Madrid City Council
6.2.25 Malaga Local Police
6.2.26 MPF (Mauritius Police Force)
6.2.27 Nanjing Municipal Government
6.2.28 National Police of Colombia
6.2.29 Nedaa
6.2.30 New Zealand Police
6.2.31 Philippine Red Cross
6.2.32 Polkomtel's Plus MCX
6.2.33 PrioCom
6.2.34 PSCA (Punjab Safe Cities Authority)
6.2.35 RESCAN (Canary Islands Network for Emergency and Security)
6.2.36 RIKS (State Infocommunication Foundation, Estonia)
6.2.37 Rivas Vaciamadrid City Council
6.2.38 ROP (Royal Oman Police)
6.2.39 Sao Paulo & Minas Gerais State Military Police Forces
6.2.40 Shanghai Police Department
6.2.41 SPF (Singapore Police Force)
6.2.42 Telstra's LANES Emergency
6.2.43 Teltronic's MCX MVNO Service in Mexico
6.2.44 T-Mobile's T-Priority
6.2.45 TWFRS (Tyne and Wear Fire and Rescue Service)
6.2.46 UN (United Nations)
6.2.47 Verizon's Frontline Solutions
6.2.48 Vientiane Municipal Government
6.2.49 Wujiang Public Security Bureau
6.2.50 Zambian Ministry of Home Affairs and Internal Security
Chapter 7: Public Safety LTE/5G Spectrum Availability, Allocation & Usage
7.1 Frequency Bands for Public Safety LTE & 5G Networks
7.1.1 200 - 400 MHz
7.1.1.1 Japan's 170 - 202.5 MHz Band
7.1.1.2 380 - 400 MHz PPDR Band
7.1.1.3 Other Non-Traditional Frequency Bands
7.1.2 410 & 450 MHz
7.1.2.1 Bands 31/n31 & 72/n72 (450 - 470 MHz)
7.1.2.2 Bands 87/n87 & 88/n88 (410 - 430 MHz)
7.1.3 600 MHz
7.1.3.1 470 - 694 MHz UHF Band
7.1.4 700 MHz
7.1.4.1 Band 14/n14 (758 - 798 MHz)
7.1.4.2 Band 28/n28 (703 - 803 MHz)
7.1.4.3 Band 68/n68 (698 - 783 MHz)
7.1.4.4 Other 700 MHz Bands
7.1.5 800 MHz
7.1.5.1 Band 20/n20 (791 - 862 MHz)
7.1.5.2 Band 26/n26 (814 - 894 MHz)
7.1.5.3 Other 800 MHz Bands
7.1.6 900 MHz
7.1.6.1 Band 8/n8 (880 - 960 MHz)
7.1.6.2 Other 900 MHz Bands
7.1.7 Mid-Band (1 - 6 GHz)
7.1.7.1 1.4 - 1.9 GHz
7.1.7.2 2.3 - 2.4 GHz
7.1.7.3 2.5 - 2.6 GHz
7.1.7.4 3.3 - 3.8 GHz
7.1.7.5 3.8 - 4.2 GHz
7.1.7.6 4.6 - 4.9 GHz
7.1.7.7 5 - 6 GHz
7.1.7.8 Other Bands
7.1.8 Upper Mid-Band (7 - 24 GHz)
7.1.8.1 7 GHz
7.1.8.2 10 - 14 GHz
7.1.8.3 17 - 20 GHz
7.1.8.4 Other Bands
7.1.9 High-Band mmWave (Millimeter Wave) Spectrum
7.1.9.1 26 GHz
7.1.9.2 28 GHz
7.1.9.3 37 GHz
7.1.9.4 60 GHz
7.1.9.5 Other Bands
7.2 North America
7.2.1 United States
7.2.2 Canada
7.3 Asia Pacific
7.3.1 Australia
7.3.2 New Zealand
7.3.3 China
7.3.4 Hong Kong
7.3.5 Taiwan
7.3.6 Japan
7.3.7 South Korea
7.3.8 Singapore
7.3.9 Malaysia
7.3.10 Indonesia
7.3.11 Philippines
7.3.12 Thailand
7.3.13 Vietnam
7.3.14 Laos
7.3.15 Myanmar
7.3.16 India
7.3.17 Pakistan
7.3.18 Bangladesh
7.3.19 Sri Lanka
7.3.20 Rest of Asia Pacific
7.4 Europe
7.4.1 United Kingdom
7.4.1.1 Great Britain
7.4.1.2 Northern Ireland
7.4.2 Republic of Ireland
7.4.3 France
7.4.4 Germany
7.4.5 Belgium
7.4.6 Netherlands
7.4.7 Switzerland
7.4.8 Austria
7.4.9 Italy
7.4.10 Spain
7.4.11 Portugal
7.4.12 Sweden
7.4.13 Norway
7.4.14 Denmark
7.4.15 Finland
7.4.16 Estonia
7.4.17 Latvia
7.4.18 Lithuania
7.4.19 Czech Republic
7.4.20 Poland
7.4.21 Hungary
7.4.22 Slovenia
7.4.23 Croatia
7.4.24 Turkiye
7.4.25 Cyprus
7.4.26 Greece
7.4.27 Bulgaria
7.4.28 Romania
7.4.29 Ukraine
7.4.30 Russia
7.4.31 Rest of Europe
7.5 Middle East & Africa
7.5.1 Saudi Arabia
7.5.2 United Arab Emirates
7.5.3 Qatar
7.5.4 Oman
7.5.5 Bahrain
7.5.6 Kuwait
7.5.7 Iraq
7.5.8 Jordan
7.5.9 Israel
7.5.10 Egypt
7.5.11 Tunisia
7.5.12 South Africa
7.5.13 Botswana
7.5.14 Zambia
7.5.15 Kenya
7.5.16 Ethiopia
7.5.17 Nigeria
7.5.18 Uganda
7.5.19 Ghana
7.5.20 Rest of the Middle East & Africa
7.6 Latin & Central America
7.6.1 Brazil
7.6.2 Mexico
7.6.3 Argentina
7.6.4 Colombia
7.6.5 Chile
7.6.6 Peru
7.6.7 Ecuador
7.6.8 Bolivia
7.6.9 Barbados
7.6.10 Trinidad & Tobago
7.6.11 Rest of Latin & Central America
Chapter 8: Standardization, Regulatory & Collaborative Initiatives
8.1 3GPP (Third Generation Partnership Project)
8.1.1 Release 11: HPUE (Power Class 1) for Band 14
8.1.2 Release 12: Early Mission-Critical Enablers - ProSe & GCSE
8.1.3 Release 13: MCPTT, IOPS & Further Enhancements
8.1.4 Release 14: Support for MCVideo & MCData Services
8.1.5 Release 15: MCX Refinements, 5G eMBB & Additional Operating Bands
8.1.6 Release 16: Further Evolution of MCX, 3GPP-LMR Interworking, Vertical Application Enablers & 5G URLLC
8.1.7 Release 17: MCX Over 5G (Unicast), LTE MCIOPS, 5G NR Sidelink Enhancements, NTN Connectivity & RedCap
8.1.8 Release 18: MCX Using 5G MBS (Multicast)/5G ProSe, UE-to-UE Relays, VMRs, Support for Less Than 5 MHz of Bandwidth & eRedCap
8.1.9 Releases 19, 20 & Beyond: New 5G NR Bands, Enhanced MCX, Multi-Hop Sidelink Relaying, MWAB, IOPS Over 5G & Regenerative NTN
8.2 APCO (Association of Public-Safety Communications Officials) International
8.2.1 Public Safety LTE/5G Advocacy Efforts
8.2.2 ANS 2.106.1-2019: Standard for PSG (Public Safety Grade) Site Hardening Requirements
8.3 ASTRID
8.3.1 Public Safety LTE/5G-Related Standardization Efforts
8.4 ATIS (Alliance for Telecommunications Industry Solutions)
8.4.1 ATIS/TIA JLMRLTE (Joint LMR-LTE) Working Group
8.4.1.1 Study of Interworking Between P25 LMR & 3GPP Mission-Critical Services
8.4.2 Other Efforts Relevant to Public Safety Broadband Communications
8.5 Australian Department of Home Affairs
8.5.1 Leading Australia's National PSMB Program
8.6 BDBOS (Federal Agency for Public Safety Digital Radio, Germany)
8.6.1 Public Safety LTE/5G-Related Standardization Efforts
8.7 BMWE (Federal Ministry for Economic Affairs and Energy, Germany)
8.7.1 Standardization Efforts for Critical Communications Over 3GPP Networks
8.8 B-TrunC (Broadband Trunking Communication) Industry Alliance
8.8.1 B-TrunC Standard for LTE-Based Critical Communications
8.9 CITIG (Canadian Interoperability Technology Interest Group)
8.9.1 Public Safety LTE/5G Advocacy Efforts
8.10 CMA (Critical Messaging Association)
8.10.1 Advancing the Delivery of Mission-Critical Messaging
8.11 DRDC (Defence Research and Development Canada)
8.11.1 DRDC CSS (DRDC Centre for Security Science)
8.11.1.1 Participation in Canada's National PSBN Program
8.11.1.2 R&D Efforts in Public Safety & Military LTE/5G Networks
8.12 DSB (Directorate for Civil Protection, Norway)
8.12.1 Public Safety LTE/5G-Related Standardization Efforts
8.13 EENA (European Emergency Number Association)
8.13.1 Broadband MCX Integration With NG112/911/999
8.14 Erillisverkot (State Security Networks Group, Finland)
8.14.1 Public Safety LTE/5G-Related Standardization Efforts
8.15 ETSI (European Telecommunications Standards Institute)
8.15.1 TCCE (TETRA and Critical Communications Evolution) Technical Committee
8.15.1.1 Standards & Guidelines for Critical Communications Broadband & TETRA-3GPP Interworking
8.15.2 CTI (Center for Testing and Interoperability)
8.15.3 Other Technical Committees & Critical Communications LTE/5G-Related Standards
8.16 FirstNet (First Responder Network) Authority
8.16.1 Overseeing the Buildout, Operation & Evolution of the FirstNet Public Safety Broadband Network
8.16.2 Standardization of Mission-Critical Features for 3GPP Technologies
8.16.3 Innovation & Test Lab
8.16.4 PSAC (Public Safety Advisory Committee)
8.17 French Ministry of Interior
8.17.1 Public Safety LTE/5G-Related Standardization Efforts
8.18 GCF (Global Certification Forum)
8.18.1 Mission-Critical Services Certification Program & Work Stream
8.19 GPSOC (Global Public Safety Operators Conference)
8.19.1 Advancing Public Safety Broadband Initiatives
8.20 United Kingdom Home Office
8.20.1 Public Safety LTE/5G-Related Standardization Efforts
8.21 ICCRA (International Critical Control Rooms Alliance)
8.21.1 LTE/5G Support in Critical Control Room Interface Standards
8.22 IETF (Internet Engineering Task Force)
8.22.1 Protocols for Broadband MCX Services Over 3GPP Networks
8.23 IGOF (International Governmental Operators' Forum)
8.23.1 Addressing Broadband-Related Issues in Critical Communications
8.24 ISED (Innovation, Science and Economic Development Canada)
8.24.1 Participation in Canada's National PSBN Program
8.24.2 Regulation of Public Safety Broadband Spectrum
8.24.3 CRC (Communications Research Centre Canada)
8.24.3.1 Interoperability Research & Evaluation of Public Safety LTE/5G Networks
8.25 ITU (International Telecommunication Union)
8.25.1 Spectrum Harmonization for PPDR Broadband Systems
8.25.2 Defining the Role of IMT-2020 to Support PPDR Applications
8.26 MOIS (Ministry of the Interior and Safety, South Korea)
8.26.1 Public Safety LTE/5G-Related Standardization Efforts
8.27 National Police of the Netherlands
8.27.1 Public Safety LTE/5G-Related Standardization Efforts
8.28 NCCOM (Nordic Critical Communication Operators Meeting)
8.28.1 Requirements for Rugged Devices & Other PPDR Broadband Capabilities
8.29 Nkom (Norwegian Communications Authority)
8.29.1 Standardization Efforts for Critical Communications Over 3GPP Networks
8.30 NSC (National Spectrum Consortium)
8.30.1 Enhancing Spectrum Superiority & 5G Capabilities for Federal Users
8.31 NSW (New South Wales) Telco Authority
8.31.1 Role in Australia's National PSMB Program
8.32 OMA SpecWorks (Open Mobile Alliance)
8.32.1 PoC (PTT-over-Cellular): V1.04, V2.0 & V2.1
8.32.2 PCPS (Push-to-Communicate for Public Safety)
8.33 PIA (PSBN Innovation Alliance)
8.33.1 PSBN Governance in Canada's Ontario Province
8.34 PSBTA (Public Safety Broadband Technology Association)
8.34.1 Public Safety LTE/5G-Related Activities
8.35 PSCE (Public Safety Communication Europe)
8.35.1 Public Safety LTE/5G Standardization
8.35.2 BroadX Projects: Pan-European Public Safety Mobile Broadband System
8.35.2.1 BroadMap: Specifications & Roadmap for Procurement
8.35.2.2 BroadWay: R&D/PCP (Pre-Commercial Procurement)
8.35.2.3 BroadNet: EUCCS (EU Critical Communication System) Preparation
8.35.3 Other Public Safety LTE/5G-Related Work
8.36 PSRG (Public Safety Radiocommunications Group)
8.36.1 Technical Exchanges on Emergency Communications Modernization
8.37 Public Safety Canada
8.37.1 Federal PSBN Task Team
8.37.2 TNCO (Temporary National Coordination Office) for Canada's National PSBN
8.38 Safe-Net Forum
8.38.1 Technical/Policy Guidance & Ecosystem Development for Critical Communications LTE/5G Networks
8.39 Safer Buildings Coalition
8.39.1 Key Initiatives for Enabling In-Building Wireless Communications
8.40 TCCA (The Critical Communications Association)
8.40.1 BIG (Broadband Industry Group)
8.40.2 CCBG (Critical Communications Broadband Group)
8.40.3 IWF Working Group
8.40.4 Future Technologies Group
8.40.5 Other TCCA Groups & Activities
8.41 TIA (Telecommunications Industry Association)
8.41.1 TR-8: Engineering Committee on Mobile & Personal Private Radio Standards
8.41.1.1 J-STD-200: Study of Interworking Between LMR and 3GPP Mission-Critical Services
8.41.1.2 Addendums to ISSI/CSSI & DFSI Standards
8.41.1.3 Work on Mission-Critical Priority & QoS Control
8.42 TTA (Telecommunications Technology Association, South Korea)
8.42.1 Functional Requirements, Testing & Certification for Public Safety LTE/5G Technologies
8.43 U.S. DHS (Department of Homeland Security)
8.43.1 S&T (Science and Technology) Directorate
8.43.1.1 Standards-Based Interworking Solution for MCPTT-LMR Communications
8.43.1.2 Interoperability Between FirstNet, Southern Linc & Other Broadband PTT Systems
8.43.1.3 Mission-Critical Voice Intelligibility, Deployables & Other Public Safety LTE/5G-Related Projects
8.43.2 CISA (Cybersecurity and Infrastructure Security Agency)
8.43.2.1 SAFECOM: Best Practices for LMR-3GPP Integration
8.44 U.S. FCC (Federal Communications Commission)
8.44.1 PSHSB (Public Safety and Homeland Security Bureau)
8.44.2 Endorsement of 3GPP Technology as the Platform for 700 MHz Public Safety Broadband Infrastructure
8.44.3 Regulation of Public Safety Broadband Spectrum
8.44.4 Other Engagements Relevant to Public Safety LTE/5G
8.45 U.S. NIST (National Institute of Standards and Technology)
8.45.1 CTL (Communications Technology Laboratory)
8.45.2 PSCR (Public Safety Communications Research) Division
8.45.2.1 R&D Partnership With the FirstNet Authority
8.45.2.2 Research Portfolio & Broadband-Related Projects
8.46 U.S. NPSTC (National Public Safety Telecommunications Council)
8.46.1 Early Leadership in Public Safety LTE Technology
8.46.2 Spectrum Management, LMR-3GPP Integration, Public Safety-Grade Systems & Other Work
8.47 U.S. NTIA (National Telecommunications and Information Administration)
8.47.1 FirstNet Governance & Funding
8.47.2 Other Work Related to Public Safety LTE/5G Networks
8.48 Others
8.48.1 Government Agencies & National Regulators
8.48.2 Critical Communications Industry Associations
8.48.3 Vendor-Led Alliances & Partner Programs
8.48.4 Spectrum & Technology Innovation Industry Alliances
8.48.5 Academic Institutions, Research Centers & Labs
Chapter 9: Key Ecosystem Players
Chapter 10: Market Sizing & Forecasts
10.1 Global Outlook for Public Safety LTE & 5G
10.2 Public Safety LTE & 5G Network Infrastructure
10.2.1 Segmentation by Submarket
10.2.1.1 RAN
10.2.1.2 Mobile Core
10.2.1.3 Backhaul & Transport
10.2.2 Segmentation by Technology Generation
10.2.3 Segmentation by Mobility
10.2.3.1 Fixed Base Stations & Infrastructure
10.2.3.2 Deployable Network Assets
10.2.4 Segmentation by Deployable Network Asset Form Factor
10.2.4.1 NIB (Network-in-a-Box)
10.2.4.2 Vehicular COWs (Cells-on-Wheels)
10.2.4.3 Aerial Cell Sites
10.2.4.4 Maritime Platforms
10.3 RAN
10.3.1 Segmentation by Air Interface Technology Generation
10.3.1.1 LTE eNBs
10.3.1.2 5G NR gNBs
10.3.2 Segmentation by Cell Size
10.3.2.1 Macrocells
10.3.2.2 Small Cells
10.4 Mobile Core
10.4.1 Segmentation by Technology Generation
10.4.1.1 LTE EPC
10.4.1.2 5GC
10.5 Backhaul & Transport
10.5.1 Segmentation by RAN Air Interface Generation
10.5.1.1 LTE
10.5.1.2 5G NR
10.5.2 Segmentation by Transmission Medium
10.5.2.1 Fiber & Wireline
10.5.2.2 Microwave
10.5.2.3 Satellite
10.6 Public Safety LTE & 5G Terminal Equipment
10.6.1 Segmentation by Air Interface Technology Generation
10.6.1.1 LTE
10.6.1.2 5G NR
10.6.2 Segmentation by Form Factor
10.6.2.1 Smartphones & Handportable Terminals
10.6.2.2 Mobile & Vehicular Routers
10.6.2.3 Fixed CPEs
10.6.2.4 Tablets & Notebook PCs
10.6.2.5 IoT Modules, Dongles & Others
10.7 Public Safety LTE & 5G Subscriptions/Service Revenue
10.7.1 Segmentation by Air Interface Technology Generation
10.7.1.1 LTE
10.7.1.2 5G NR
10.7.2 Segmentation by Network Type
10.7.2.1 Dedicated & Hybrid Government-Commercial Networks
10.7.2.2 Secure MVNO & MOCN Networks
10.7.2.3 Sliced & Commercial Mobile Networks
10.8 Public Safety LTE & 5G Systems Integration/Management Solutions
10.8.1 Segmentation by Submarket
10.8.1.1 Network Integration & Testing
10.8.1.2 Device Management & User Services
10.8.1.3 Managed Services, Operations & Maintenance
10.8.1.4 Cybersecurity
10.9 Public Safety Broadband Applications
10.9.1 Segmentation by Submarket
10.9.1.1 Mission-Critical Voice & Group Communications
10.9.1.2 Real-Time Video Transmission
10.9.1.3 Messaging, File Transfer & Presence Services
10.9.1.4 Mobile Office & Field Applications
10.9.1.5 Location Services & Mapping
10.9.1.6 Situational Awareness
10.9.1.7 Command & Control
10.9.1.8 AR/VR/MR (Augmented, Virtual & Mixed Reality)
10.10 Regional Outlook
10.10.1 Public Safety LTE & 5G Network Infrastructure
10.10.1.1 RAN
10.10.1.2 Mobile Core
10.10.1.3 Backhaul & Transport
10.10.2 Public Safety LTE & 5G Terminal Equipment
10.10.3 Public Safety LTE & 5G Subscriptions/Service Revenue
10.10.4 Public Safety LTE & 5G Systems Integration/Management Solutions
10.10.5 Public Safety Broadband Applications
10.11 North America
10.11.1 Public Safety LTE & 5G Network Infrastructure
10.11.1.1 RAN
10.11.1.2 Mobile Core
10.11.1.3 Backhaul & Transport
10.11.2 Public Safety LTE & 5G Terminal Equipment
10.11.3 Public Safety LTE & 5G Subscriptions/Service Revenue
10.11.4 Public Safety LTE & 5G Systems Integration/Management Solutions
10.11.5 Public Safety Broadband Applications
10.12 Asia Pacific
10.12.1 Public Safety LTE & 5G Network Infrastructure
10.12.1.1 RAN
10.12.1.2 Mobile Core
10.12.1.3 Backhaul & Transport
10.12.2 Public Safety LTE & 5G Terminal Equipment
10.12.3 Public Safety LTE & 5G Subscriptions/Service Revenue
10.12.4 Public Safety LTE & 5G Systems Integration/Management Solutions
10.12.5 Public Safety Broadband Applications
10.13 Europe
10.13.1 Public Safety LTE & 5G Network Infrastructure
10.13.1.1 RAN
10.13.1.2 Mobile Core
10.13.1.3 Backhaul & Transport
10.13.2 Public Safety LTE & 5G Terminal Equipment
10.13.3 Public Safety LTE & 5G Subscriptions/Service Revenue
10.13.4 Public Safety LTE & 5G Systems Integration/Management Solutions
10.13.5 Public Safety Broadband Applications
10.14 Middle East & Africa
10.14.1 Public Safety LTE & 5G Network Infrastructure
10.14.1.1 RAN
10.14.1.2 Mobile Core
10.14.1.3 Backhaul & Transport
10.14.2 Public Safety LTE & 5G Terminal Equipment
10.14.3 Public Safety LTE & 5G Subscriptions/Service Revenue
10.14.4 Public Safety LTE & 5G Systems Integration/Management Solutions
10.14.5 Public Safety Broadband Applications
10.15 Latin & Central America
10.15.1 Public Safety LTE & 5G Network Infrastructure
10.15.1.1 RAN
10.15.1.2 Mobile Core
10.15.1.3 Backhaul & Transport
10.15.2 Public Safety LTE & 5G Terminal Equipment
10.15.3 Public Safety LTE & 5G Subscriptions/Service Revenue
10.15.4 Public Safety LTE & 5G Systems Integration/Management Solutions
10.15.5 Public Safety Broadband Applications
Chapter 11: Conclusion & Strategic Recommendations
11.1 Why is the Market Poised to Grow?
11.2 Future Roadmap: 2025 - 2030
11.2.1 2025 - 2027: Focus on 3GPP-Compliant MCX Service Enablement & Functional Expansion
11.2.2 2028 - 2030: Growing Adoption of Standalone 5G Networks for Public Safety Communications
11.2.3 2031 & Beyond: 5G NR Sidelink Availability & Accelerated Transitions From Digital LMR Systems
11.3 Vendor Landscape, Alliances & Consolidation
11.3.1 LTE/5G Network Infrastructure & Device Suppliers
11.3.2 MCX & Broadband-Enabled Application Developers
11.3.3 Cross-Segment Partnerships for Mission-Critical Solutions
11.3.4 Consolidation in the Wider Critical Communications Industry
11.4 Standardization & Commercial Availability of Key Enabling Technologies
11.4.1 MCX: MCPTT, MCVideo & MCData Services
11.4.2 LMR-3GPP MCX Interworking Solutions
11.4.3 Support for PPDR Spectrum
11.4.4 HPUE
11.4.5 IOPS & MCIOPS
11.4.6 eMBMS & 5G MBS/5MBS
11.4.7 ProSe & 5G NR Sidelink
11.4.8 VMRs & MWAB
11.4.9 Satellite NTN Integration
11.4.10 Other Technologies
11.5 Review of National Public Safety Broadband Programs
11.5.1 New National-Scale Projects
11.5.2 Operational Nationwide Networks
11.5.3 Pre-Operational Initiatives
11.5.4 Diversity of Network Delivery Models
11.6 In-Building Coverage, Private 5G, Slicing & Network Extensions
11.6.1 In-Building Coverage Enhancement
11.6.2 Independent Small-to-Medium Scale Private 5G Networks
11.6.3 Deployables for Incident Command & Disaster Relief Operations
11.6.4 Network Slicing Over Standalone 5G Cores
11.6.5 National Roaming & Multi-Operator Redundancy
11.6.6 International Roaming for Cross-Border Policing & Emergency Response
11.7 Spectrum Options for Current & Future Use Cases
11.7.1 Private RAN Infrastructure Frequency Bands
11.7.2 Dedicated Spectrum for Future 5G Applications
11.7.3 Public Safety Use of 5G NR Bands n79 & n114 (4.9 GHz)
11.7.4 Shared & Local Area Licensed Spectrum
11.8 Ensuring the Economic Viability of Nationwide Public Safety Broadband Networks
11.8.1 TCO Comparison: Independent Networks vs. PPPs (Public-Private Partnerships)
11.8.2 Monetizing Unused Network Capacity Through Secondary Commercial Users
11.8.3 Industry Solutions for Other Critical Communications User Groups
11.8.4 Dynamic Spectrum Sharing With Tiered Priority Access
11.9 Migration From LMR Systems to Mission-Critical Broadband Networks
11.9.1 South Korea: Pioneering MCX Service Adoption on a National Scale
11.9.2 Developing Countries: Leapfrogging Directly to 3GPP-Based Critical Communications Networks
11.9.3 Europe: Varied Transition Timelines From Nationwide TETRA & Tetrapol Systems
11.9.4 United States, Australia & New Zealand: Prolonged P25 & Broadband Coexistence
11.10 Interim Solutions for Off-Network Communications
11.10.1 RSM (Remote Speaker Microphone) Companion Devices
11.10.2 Hybrid LMR-Broadband Terminals With Direct Mode Functionality
11.10.3 Tactical IP Radios & Other Solutions
11.11 Public Safety Application Sector Trends in the 5G Era
11.11.1 Mission-Critical Group Communications
11.11.2 NG911 Coordination for Rich Data Exchange
11.11.3 Fixed, Mobile & Aerial Video Surveillance
11.11.4 Data-Intensive Field Applications for First Responders
11.11.5 IoLST (Internet of Life Saving Things): Gunshot Detection, Fire Alarms & Other Sensors
11.11.6 Situational Awareness & Common Operating Picture
11.11.7 AI-Enabled Video Analytics & Safety Management Platforms
11.11.8 5G-Era Applications: UHD Video, AR/VR/MR, Drones & Robotics
11.11.9 Public Safety Application Stores & Developer Programs
11.11.10 5G Labs & Testbeds for First Responder Communications
11.12 Strategic Recommendations
11.12.1 Public Safety & Government Agencies
11.12.2 LTE/5G Infrastructure, Device & Chipset Suppliers
11.12.3 LMR Vendors & System Integrators
11.12.4 Mobile Operators & Critical Communications Service Providers
