LTE – CRI Report

SON (Self-Organizing Networks) in the 5G & Open RAN Era: 2022 – 2030 – Opportunities, Challenges, Strategies & Forecasts

admin — Thu, 08 Dec 2022 02:46:41 +0000

Self-Organizing Networks in the 5G & Open RAN Era

SON (Self-Organizing Network) technology minimizes the lifecycle cost of running a mobile network by eliminating manual configuration of network elements at the time of deployment right through to dynamic optimization and troubleshooting during operation. Besides improving network performance and customer experience, SON can significantly reduce the cost of mobile operator services, improving the OpEx-to-revenue ratio and deferring avoidable CapEx.

Early adopters of SON have already witnessed a multitude of benefits in the form of accelerated 5G NR and LTE RAN (Radio Access Network) rollout times, simplified network upgrades, fewer dropped calls, improved call setup success rates, higher end user throughput, alleviation of congestion during special events, increased subscriber satisfaction and loyalty, operational efficiencies such as energy and cost savings, and freeing up radio engineers from repetitive manual tasks.

Although SON was originally developed as an operational approach to streamline and automate cellular RAN deployment and optimization, mobile operators and vendors are increasingly focusing on integrating new capabilities such as self-protection against digital security threats and self-learning through AI (Artificial Intelligence) techniques, as well as extending the scope of SON beyond the RAN to include both mobile core and transport network segments – which will be critical to address 5G requirements such as end-to-end network slicing.

In addition, with the cellular industry’s ongoing shift towards open interfaces, virtualization and software-driven networking, the SON ecosystem is progressively transitioning from the traditional D-SON (Distributed SON) and C-SON (Centralized SON) approach to open standards-based components supporting RAN programmability for advanced automation and intelligent control.

The surging popularity of innovative Open RAN and vRAN (Virtualized RAN) architectures has reignited the traditionally niche and proprietary product-driven SON market with a host of open standards-compliant RIC (RAN Intelligent Controller), xApp and rApp offerings, which are capable of supporting both near real-time D-SON and non real-time C-SON capabilities for RAN automation and optimization needs.

This report estimates that global spending on RIC platforms, xApps and rApps will reach $120 Million in 2023 as initial implementations move from field trials to production-grade deployments. With commercial maturity, the submarket is further expected to quintuple to nearly $600 Million by the end of 2025. Annual investments in the wider SON market – which includes licensing of embedded D-SON features, third party C-SON functions and associated OSS platforms, in-house SON capabilities internally developed by mobile operators, and SON-related professional services across the RAN, mobile core and transport domains – are expected to grow at a CAGR of approximately 7% during the same period.

The “SON (Self-Organizing Networks) in the 5G & Open RAN Era: 2022 – 2030 – Opportunities, Challenges, Strategies & Forecasts” report presents a detailed assessment of the SON market, including the value chain, market drivers, barriers to uptake, enabling technologies, functional areas, use cases, key trends, future roadmap, standardization, case studies, ecosystem player profiles and strategies. The report also provides global and regional market size forecasts for both SON and conventional mobile network optimization from 2022 till 2030, including submarket projections for three network segments, six SON architecture categories, four access technologies and five regional submarkets.

The report comes with an associated Excel datasheet suite covering quantitative data from all numeric forecasts presented in the report.

Topics Covered

The report covers the following topics:
– Introduction to SON
– Value chain and ecosystem structure
– Market drivers and challenges
– SON technology, architecture and functional areas
– D-SON (Distributed SON), C-SON (Centralized SON), H-SON (Hybrid SON), RIC (RAN Intelligent Controller), xApps and rApps
– Review of over 40 SON use cases across the RAN, core and transport domains, ranging from ANR (Automatic Neighbor Relations) and rapid equipment configuration to advanced traffic steering, QoE-based optimization and automated anomaly detection
– Key trends in next-generation 5G SON implementations, including Open RAN and vRAN (Virtualized RAN) architectures, dynamic spectrum management, network slicing, edge computing, Big Data, advanced analytics, AI (Artificial Intelligence)/ML (Machine Learning) and zero-touch automation
– Case studies of 20 commercial-scale SON deployments and examination of ongoing projects covering both traditional D-SON/C-SON and RIC-x/rApp approaches
– Future roadmap for the SON market
– Standardization, regulatory and collaborative initiatives
– Profiles and strategies of more than 230 ecosystem players
– Strategic recommendations for SON solution providers and mobile operators
– Market analysis and forecasts from 2022 till 2030

Forecast Segmentation

Market forecasts are provided for each of the following submarkets and their subcategories:

SON & Mobile Network Optimization
– SON
– Conventional Mobile Network Planning & Optimization

SON Network Segment Submarkets
– RAN (Radio Access Network)
– Mobile Core
– Transport (Fronthaul, Midhaul & Backhaul)

RAN Segment SON Architecture Submarkets
– Traditional D-SON & C-SON
○ Embedded D-SON (Distributed SON) Features
○ Third Party C-SON (Centralized SON) & OSS Platforms
– Open RAN RIC, xApps & rApps
○ RIC (RAN Intelligent Controller) Platforms
○ Near Real-Time xApps
○ Non Real-Time rApps
– Mobile Operators’ In-House SON Tools & Systems

SON Access Network Technology Submarkets
– 2G & 3G
– LTE
– 5G NR
– Wi-Fi & Others

Regional Markets
– North America
– Asia Pacific
– Europe
– Middle East & Africa
– Latin & Central America

Key Questions Answered

The report provides answers to the following key questions:
– How big is the SON opportunity?
– What trends, drivers and challenges are influencing its growth?
– What will the market size be in 2025, and at what rate will it grow?
– Which submarkets and regions will see the highest percentage of growth?
– How do SON investments compare with spending on conventional mobile network optimization?
– What are the practical, quantifiable benefits of SON – based on live, commercial deployments?
– How can mobile operators capitalize on SON to ensure optimal network performance, improve customer experience, reduce costs, and drive revenue growth?
– What is the status of D-SON and C-SON adoption worldwide?
– When will open standards-based RIC platforms, xApps and rApps replace the traditional SON approach?
– What are the prospects of AI/ML-driven automation in the SON market?
– What opportunities exist for SON capabilities in the mobile core and transport network domains?
– How can SON ease the deployment of private 4G/5G networks for enterprises and vertical industries?
– In what way will SON facilitate network slicing and other advanced 5G capabilities?
– How does SON impact mobile network optimization engineers?
– Who are the key ecosystem players, and what are their strategies?
– What strategies should SON solution providers and mobile operators adopt to remain competitive?

Key Findings

The report has the following key findings:
– The surging popularity of innovative Open RAN and vRAN (Virtualized RAN) architectures has reignited the traditionally niche and proprietary product-driven SON market with a host of open standards-compliant RIC (RAN Intelligent Controller), xApp and rApp offerings, which are capable of supporting both near real-time D-SON and non real-time C-SON capabilities for RAN automation and optimization needs.
– The report estimates that global spending on RIC platforms, xApps and rApps will reach $120 Million in 2023 as initial implementations move from field trials to production-grade deployments. With commercial maturity, the submarket is further expected to quintuple to nearly $600 Million by the end of 2025.
– Annual investments in the wider SON market – which includes licensing of embedded D-SON features, third party C-SON functions and associated OSS platforms, in-house SON capabilities internally developed by mobile operators, and SON-related professional services across the RAN, mobile core and transport domains – are expected to grow at a CAGR of approximately 7% during the same period.
– The third party SON vendor ecosystem is exhibiting signs of consolidation, with several prominent M&A deals such as Qualcomm’s recent acquisition of C-SON specialist Cellwize – in a bid to strengthen its 5G RAN infrastructure offerings, Elisa Automate’s merger with Polystar to form Elisa Polystar, and HCL’s acquisition of Cisco’s SON technology business.
– However, on the other hand, newer suppliers are also beginning to emerge – extending from VMware, Juniper Networks and other RIC platform providers to x/rApp specialists such as Cohere Technologies, DeepSig, Groundhog Technologies, Subex, B-Yond, Net AI and RIMEDO Labs.
– SON capabilities are playing a pivotal role in the ongoing proliferation of private 4G/5G networks, as evident from a growing number of cross-sector partnerships. For example, private wireless service provider Betacom is collaborating with Qualcomm to accelerate enterprise adoption of private 5G networks by combining the former’s 5GaaS (5G-as-a-Service) offering with the latter’s enablement ecosystem, including the Cellwize RAN automation and management platform. Similarly, Germany-based systems integrator Opticoms has entered into a partnership with SON specialist Innovile to automate and optimize Open RAN standards-compliant private 5G networks.
– Over the last two years, with the steep rise of mobile data consumption in residential areas during the COVID-19 pandemic-imposed lockdowns, mobile operators – despite coping relatively well – have recognized the importance of a more dynamic and automated approach to the optimization of network assets in order to provide a consistent and seamless user experience.
– The 2020-2022 period saw large-scale C-SON deployments by several operators, including but not limited to Verizon, EE (BT Group), Orange, Telefónica, Turkcell, beCloud (Belarusian Cloud Technologies), VEON, Ooredoo, Zain, BTC (Botswana Telecommunications Corporation), LTT (Libya Telecom & Technology), Telstra, Singtel, Telkomsel, Globe Telecom, Smart Communications (PLDT), and Telecom Argentina.

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The Public Safety LTE & 5G Market: 2022 – 2030 – Opportunities, Challenges, Strategies & Forecasts

admin — Tue, 01 Nov 2022 02:09:49 +0000

Synopsis

With the commercial availability of 3GPP-standards compliant MCX (Mission-Critical PTT, Video & Data), HPUE (High-Power User Equipment), IOPS (Isolated Operation for Public Safety) and other critical communications features, LTE and 5G NR (New Radio) networks are increasingly gaining recognition as an all-inclusive public safety communications platform for the delivery of real-time video, high-resolution imagery, multimedia messaging, mobile office/field data applications, location services and mapping, situational awareness, unmanned asset control and other broadband capabilities, as well as MCPTT (Mission-Critical PTT) voice and narrowband data services provided by traditional LMR (Land Mobile Radio) systems.

Through ongoing refinements of additional standards – specifically 5G MBS (5G Multicast-Broadcast Services), 5G NR sidelink for off-network D2D (Device-to-Device) communications, NTN (Non-Terrestrial Network) integration, and support for lower 5G NR bandwidths – 3GPP networks are eventually expected to be in a position to fully replace legacy LMR systems by the mid-to-late 2020s.

National public safety communications authorities in multiple countries have already expressed a willingness to complete their planned narrowband to broadband transitions within the second half of the 2020 decade.

A myriad of fully dedicated, hybrid government-commercial and secure MVNO/MOCN-based public safety LTE and 5G-ready networks are operational or in the process of being rolled out throughout the globe.

In addition to the high-profile FirstNet (First Responder Network), South Korea’s Safe-Net (National Disaster Safety Communications Network) and Britain’s ESN (Emergency Services Network) nationwide public safety broadband projects, many additional national-level programs are making considerable headway in moving from field trials to wider scale deployments – most notably, France’s RRF (Radio Network of the Future), Spain’s SIRDEE mission-critical broadband network, Finland’s VIRVE 2.0 broadband service, Sweden’s Rakel G2 secure broadband system and Hungary’s EDR 2.0/3.0 broadband network.

Nationwide initiatives in the pre-operational phase include but are not limited to Switzerland’s MSK (Secure Mobile Broadband Communications) system, Norway’s NGN (Next-Generation Nødnett), Germany’s planned hybrid broadband network for BOS (German Public Safety Organizations), Japan’s PS-LTE (Public Safety LTE) project, Australia’s PSMB (Public Safety Mobile Broadband) program and Canada’s national PSBN (Public Safety Broadband Network).

Other operational and planned deployments range from the Halton-Peel region PSBN in Canada’s Ontario province, China’s city and district-wide Band 45 (1.4 GHz) LTE networks for police forces, Royal Thai Police’s Band 26 (800 MHz) LTE network, Qatar MOI (Ministry of Interior), ROP (Royal Oman Police) and Nedaa’s mission-critical LTE networks in the oil-rich GCC (Gulf Cooperation Council) region, Brazil’s state-wide Band 28 (700 MHz) networks for both civil and military police agencies, Barbados’ Band 14 (700 MHz) LTE-based connectivity service platform, and Zambia’s 400 MHz broadband trunking system to local and regional-level private LTE networks for first responders in markets as diverse as Laos, Indonesia, the Philippines, Pakistan, Lebanon, Egypt, Kenya, Ghana, Cote D’Ivoire, Cameroon, Mali, Madagascar, Mauritius, Canary Islands, Spain, Italy, Turkey, Serbia, Argentina, Colombia, Venezuela, Bolivia, Ecuador and Trinidad & Tobago, as well as multi-domain critical communications broadband networks such as MRC’s (Mobile Radio Center) LTE-based advanced MCA digital radio system in Japan, and secure MVNO platforms in Mexico, Belgium, the Netherlands, Slovenia, Estonia and several other countries.

Even though critical public safety-related 5G NR capabilities defined in the 3GPP’s Release 17 specifications are yet to be commercialized, public safety agencies have already begun experimenting with 5G for applications that can benefit from the technology’s high-bandwidth and low-latency characteristics.

For example, the Lishui Municipal Emergency Management Bureau is using private 5G slicing over China Mobile’s network, portable cell sites and rapidly deployable communications vehicles as part of a disaster management and visualization system.

In neighboring Taiwan, the Hsinchu City Fire Department is using an emergency response vehicle that can be rapidly deployed to disaster zones to establish high-bandwidth, low-latency emergency communications by means of a satellite-backhauled private 5G network based on Open RAN standards.

In addition, first responder agencies in Germany, Japan and several other markets are beginning to utilize mid-band and mmWave (Millimeter Wave) spectrum available for local area licensing to deploy portable and small-scale 5G NPNs (Non-Public Networks) to support applications such as UHD (Ultra-High Definition) video surveillance and control of unmanned firefighting vehicles, reconnaissance robots and drones.

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.

We estimates that annual investments in public safety LTE and 5G infrastructure will reach nearly $1.6 Billion by the end of 2022, driven by both new build-outs and the expansion of existing dedicated, hybrid government-commercial and secure MVNO/MOCN networks.

Complemented by a rapidly expanding ecosystem of public safety-grade LTE/5G devices, the market will further grow at a CAGR of approximately 13% between 2022 and 2025, eventually accounting for more than $2.3 Billion by the end of 2025. Despite the positive outlook, a number of significant challenges continue to plague the market. The most noticeable pain point is the lack of a D2D communications capability.

The ProSe (Proximity Services) chipset ecosystem has failed to materialize in the LTE era due to limited support from chipmakers and terminal OEMs. However, the 5G NR sidelink interface offers a clean slate opportunity to introduce direct mode, D2D communications for public safety broadband users, as well as coverage expansion in both on-network and off-network scenarios using UE-to-network and UE-to-UE relays respectively.

Another barrier impeding the market is the non-availability of cost-optimized COTS (Commercial Off-the-Shelf) RAN equipment and terminals that support operation in certain frequency bands such as Band 68 (698-703 MHz / 753-758 MHz), which has been allocated for PPDR (Public Protection & Disaster Relief) broadband systems in multiple European countries.

The “Public Safety LTE & 5G Market: 2022 – 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 2022 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 1,150 global public safety LTE/5G engagements – as of Q4’2022.

Key Findings

The report has the following key findings:

SNS Telecom & IT estimates that annual investments in public safety LTE and 5G infrastructure will reach nearly $1.6 Billion by the end of 2022, driven by both new build-outs and the expansion of existing dedicated, hybrid government-commercial and secure MVNO/MOCN networks. Complemented by a rapidly expanding ecosystem of public safety-grade LTE/5G devices, the market will further grow at a CAGR of approximately 13% between 2022 and 2025, eventually accounting for more than $2.3 Billion by the end of 2025.
In addition to the high-profile FirstNet, South Korea’s Safe-Net and Britain’s ESN nationwide public safety broadband projects, many additional national-level programs are making considerable headway in moving from field trials to wider scale deployments – most notably, France’s RRF, Spain’s SIRDEE mission-critical broadband network, Finland’s VIRVE 2.0 broadband service, Sweden’s Rakel G2 secure broadband system and Hungary’s EDR 2.0/3.0 broadband network.
Other operational and planned deployments include but are not limited to the Halton-Peel region PSBN in Canada’s Ontario province, China’s city and district-wide Band 45 (1.4 GHz) LTE networks for police forces, Royal Thai Police’s Band 26 (800 MHz) LTE network, Qatar MOI (Ministry of Interior), ROP (Royal Oman Police) and Nedaa’s mission-critical LTE networks in the oil-rich GCC region, Brazil’s state-wide Band 28 (700 MHz) networks for both civil and military police agencies, Barbados’ Band 14 (700 MHz) LTE-based connectivity service platform, and Zambia’s 400 MHz broadband trunking system.
Production-grade deployments of 3GPP standards-compliant MCX services – beginning with MCPTT – are continuing to accelerate over both commercial and public safety broadband networks. Early adopters range from Safe-Net, FirstNet and ESN to mobile operators such as Verizon, Southern Linc, Telus, SFR, KPN, Swisscom, Telia, Føroya Tele and STC (Saudi Telecom Company).
Even though critical public safety-related 5G NR capabilities defined in the 3GPP’s Release 17 specifications are yet to be commercialized, public safety agencies have already begun experimenting with 5G for applications that can benefit from the technology’s high-bandwidth and low-latency characteristics. For example, the Lishui Municipal Emergency Management Bureau is using a 5G-enabled closed-loop system for integrated emergency visualization and natural disaster management.
As 5G implementations become well-established in the 2020s, MCX services in high-density environments, real-time UHD video transmission through coordinated fleets of drones, 5G-connected autonomous police robots, smart ambulances, AR (Augmented Reality) firefighting helmets and other sophisticated public safety broadband applications will become a common sight.
Over the last two years, COWs (Cells-on-Wheels), COLTs (Cells-on-Light Trucks) and other deployable LTE network assets have played a pivotal role in facilitating mission-critical communications, real-time transmission of video footage, and improved situational awareness for incident command and emergency response needs – for instance, the mobilization of FirstNet deployables during the wildfire seasons of 2021 and 2022 in the United States.
5G NR-equipped portable network systems are also beginning to emerge. For example, Taiwan’s Hsinchu City Fire Department is using an emergency response vehicle – which features a satellite-backhauled private 5G network based on Open RAN standards – to establish high-bandwidth, low-latency emergency communications in disaster zones. Between 2022 and 2025, SNS Telecom & IT expects cumulative spending on deployable assets for public safety broadband to exceed $700 Million.
Although much of the public safety spectrum debate is centered around low-band frequencies in the sub-1 GHz range, a number of PPDR stakeholders have started eyeing up mmWave spectrum reservation to be able to support advanced use cases in the coming years. For example, the Hungarian Ministry of Interior has specifically requested access to a 200 MHz block of Band n258 (26 GHz) spectrum for future 5G applications.
In addition, first responder agencies in Germany, Japan and several other markets are beginning to utilize mid-band and mmWave spectrum available for local area licensing to deploy portable and small-scale 5G NPNs (Non-Public Networks) to support applications such as UHD video surveillance and control of unmanned firefighting vehicles, reconnaissance robots and drones.
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.
The ProSe chipset ecosystem has failed to materialize in the LTE era due to limited support from chipmakers and terminal OEMs. However, the 5G NR sidelink interface offers a clean slate opportunity to introduce direct mode, D2D communications for public safety broadband users, as well as coverage expansion in both on-network and off-network scenarios using UE-to-network and UE-to-UE relays respectively.
Another barrier impeding the market is the non-availability of cost-optimized COTS RAN equipment and terminals that support operation in certain frequency bands such as Band 68 (698-703 MHz / 753-758 MHz), which has been allocated for PPDR broadband systems in multiple European countries.

Summary of Recent Market Developments

Some of the recent, ongoing and planned public safety broadband deployments are summarized below:

North America
- AT&T is continuing to expand the reach of the FirstNet nationwide public safety broadband communications platform using purpose-built Band 14 (700 MHz) cell sites in multiple states across the United States, in-building wireless coverage enhancement solutions, and deployable network assets for on-demand coverage during emergencies and events.
- In addition, the mobile operator is progressively expanding 5G NR access for first responders using upgraded dedicated core network infrastructure and commercial mmWave, mid-band and low-band spectrum.
- Rival operator Verizon Communications has recently introduced THOR’s (Tactical Humanitarian Operations Response) Hammer, a nearly 30-foot trailer that is able to act a locally managed private 5G network – operating in C-Band and mmWave spectrum – for providing coverage in areas where network connections and coverage can be challenging or where natural disasters like earthquakes or hurricanes have damaged existing infrastructure.
- Within the framework of a U.S. DIU (Defense Innovation Unit)-led project, the California National Guard is trialing rapidly deployable private 5G network equipment – using the 3.5 GHz CBRS band – to provide reliable, ad-hoc data and voice services to civil and military emergency response teams operating anywhere in the State of California.
- Canada’s TNCO (Temporary National Coordination Office) has recommended that the country’s planned PSBN (Public Safety Broadband Network) be delivered as a single nationwide platform using a shared network approach.
- In Ontario, the PIA (PSBN Innovation Alliance) has proposed an expansion of the operational public safety LTE network in the Halton and Peel regional municipalities to a province-wide PSBN based on a hybrid network-of-networks approach by combining the strategic use of regional Band 14 (700 MHz) RAN infrastructure hosted on the existing shared geo-redundant core implementation and PS-MVNO (Public Safety Mobile Virtual Network Operator) services through multi-carrier roaming with commercial operator networks.
Asia Pacific
- Following the successful nationwide rollout of the LTE-based Band 28 (700 MHz) Safe-Net national disaster safety communications network for the KNPA (Korean National Police Agency), NFA (National Fire Agency), local governments and other first responder organizations, South Korean authorities are actively exploring possible options for the introduction of public safety-grade 5G connectivity services.
- Japanese authorities are continuing to make progress on their so-called national PS-LTE (Public Safety LTE) project. Another related development is the MRC’s (Mobile Radio Center) expansion of its 900 MHz LTE-based advanced MCA digital radio system to provide nationwide coverage for critical communications.
- Several 2.5 GHz regional BWA (Broadband Wireless Access) networks have also been deployed in cities across Japan to support PPDR-related applications. In addition, a number of pilot projects are trialing local 5G networks – operating in 4.6-4.9 GHz and 28 GHz spectrum – for public safety applications such as UHD video surveillance.
- In China, city and district-wide Band 45 (1.4 GHz) private LTE networks are continuing to be deployed for police forces and other government users. 5G-enabled solutions for PPDR broadband applications are also beginning to emerge.
- For example, the Lishui Municipal Emergency Management Bureau is using private 5G slicing over China Mobile’s network, portable cell sites and rapidly deployable communications vehicles as part of a disaster management and visualization system.
- Taiwan’s Hsinchu City Fire Department is using an emergency response vehicle that can be rapidly deployed to disaster zones to establish high-bandwidth, low-latency emergency communications by means of a satellite-backhauled private 5G network based on Open RAN standards.
- NT (National Telecom) has designed and deployed an Open RAN standards-compliant private 5G network – spanning a total of 160 5G NR-equipped smart poles – using 26 GHz mmWave spectrum in Ban Chang (Rayong), Thailand, for smart city-related applications, including AI (Artificial Intelligence)-based video analytics for public safety purposes using fixed, mobile and drone cameras.
- In Australia, the NSW (New South Wales) Telco Authority-led PoC (Proof-of-Concept) trial of a multi-operator PSMB (Public Safety Mobile Broadband) network has recently been completed. The PoC’s architecture utilized government-owned core network infrastructure while supporting flexibility in terms of RAN coverage options, including cell sites operating in dedicated public safety spectrum.
Europe
- The BroadWay PCP (Pre-Commercial Procurement) project for a pan-European interoperable PPDR broadband system has concluded with the completion of pilots in Ljubljana (Slovenia), Kerkrade (Netherlands) and Málaga (Spain).
- Britain’s planned transition from the Airwave TETRA network to the LTE-based ESN (Emergency Service Network) has been delayed until the end of 2026. EAS (Extended Area Service) sites are progressively being built and activated to expand ESN coverage in the most remote and rural areas of the country.
- The overlay A2G (Air-to-Ground) component of the ESN – which spans more than 80 cell sites operating in Band 40 (2.3 GHz) spectrum – is currently undergoing live trials and optimization.
- The PSNI (Police Service of Northern Ireland), which manages its own TETRA-based radio communications network, is considering plans for the deployment of a public safety broadband network using Band 28 (700 MHz) and 800/900 MHz spectrum.
- France’s Ministry of Interior plans to commence the rollout of its RRF (Radio Network of the Future) in 2023 with an initial focus on the territories hosting the 2024 Olympics, having awarded contracts to Orange, Bouygues Telecom, Airbus, Capgemini and Atos.
- The nationwide public safety broadband network will be built on a dedicated core network, RAN coverage from commercial mobile operators with priority, preemption and national roaming, state-owned 700 MHz RAN infrastructure in strategic locations, and rapidly deployable tactical bubbles pioneered by the PCSTORM project.
- Germany’s BDBOS (Federal Agency for Public Safety Digital Radio) has completed a trial of its proposed hybrid broadband network for BOS (German Public Safety Organizations). The federal agency is also setting up a broadband development environment, which features LTE and 5G campus network infrastructure in both stationary and mobile variants as well as support for MCX services and interworking with TETRA.
- In addition, multiple first responder agencies are independently evaluating the use of portable 5G NPNs (Non-Public Networks) – operating in 3.7-3.8 GHz local area licensed spectrum – to enable emergency personnel to communicate with each other and control unmanned firefighting vehicles, reconnaissance robots and drones.
- As part of the ZNV (Deployable Cellular Networks) program, the Bundeswehr (German Armed Forces) is adopting a rapidly deployable cellular network solution that supports mission-critical voice and narrowband data transmission via the TETRA standard and broadband applications using LTE technology, and is interoperable with the BOS TETRA network.
- Among other efforts to evolve the BLM (Blue Light Mobile) secure MVNO service, Belgian government-owned critical communications service provider ASTRID is considering the deployment of complementary 4G/5G RAN infrastructure to fill in coverage gaps that are not sufficiently served by commercial mobile operator networks, as well as for specialized scenarios such as A2G (Air-to-Ground) communications.
- The City of Genk and Citymesh are setting up a private cellular network covering the city’s borders to enable drone communication during emergencies, specifically to transmit images in real-time to the police, fire brigade and other emergency services.
- The Spanish Ministry of Interior has contracted Telefónica to deploy and operate its SIRDEE nationwide mission-critical broadband network using a combination of Band 31 (450 MHz) and Band 28 (700 MHz) spectrum.
- Commercial and small-scale private 5G networks are also being trialed by national and local government agencies, including Guardia Civil (Spanish Civil Guard), Málaga Local Police, Guàrdia Urbana de Barcelona (Barcelona Urban Guard) and Bombers de Barcelona (Barcelona Fire Service).
- Switzerland’s BABS/FOCP (Federal Office for Civil Protection) is coordinating a pilot project and proof-of-concept field trials for the country’s nationwide MSK (Secure Mobile Broadband Communications) system. The pilot is scheduled to run from 2020 to 2023.
- As the first step in developing Sweden’s LTE and 5G NR-ready Rakel G2 (Next-Generation Rakel) secure broadband communications system, the country’s MSB (Civil Contingencies Agency) has initially procured dedicated core network infrastructure, commercial mobile operator RAN coverage and SIM cards to provide mobile data communications services to public safety users through an MOCN (Multi-Operator Core Network) arrangement.
- Teracom is building a 5G-ready AGA (Air-to-Ground-to-Air) network – using its high-mast infrastructure and Band 40 (2.3 GHz) spectrum assets – to provide aerial coverage for critical communications across 96% of Sweden’s surface area.
- Erillisverkot (State Security Networks Group) has made significant progress on the VIRVE 2.0 mission-critical broadband service by deploying a dedicated core network and integrating it with commercial mobile operator Elisa’s 4G/5G RAN infrastructure – using the MOCN model – to deliver prioritized mobile broadband connectivity to Finnish PPDR (Public Protection & Disaster Relief) users.
- Føroya Tele (Faroese Telecom) has developed KIMA, a mission-critical communications system to meet the unique requirements of the Fareo Islands’ public safety agencies.
- The system is based on the mobile operator’s LTE RAN infrastructure – including dedicated coverage for tunnels, ATG (Air-to-Ground) and maritime connectivity 100 kilometers out to sea, geo-redundant mobile core implementation and 3GPP standards-compliant MCX functionality.
- Pro-M – the Hungarian government communications service provider for PPDR and other critical user groups – has carried out field tests of a multi-site 700 MHz LTE system in Budapest, in preparation for the rollout of its EDR 2.0/3.0 broadband network.
Other Regions
- Within the framework of the Zambia’s nationwide Safe City project, the country’s Ministry of Home Affairs and Internal Security has deployed a Caltta Technologies-supplied broadband trunking communications system – operating in 400 MHz spectrum – to enhance public safety communications, reduce emergency response time and improve cross-departmental collaboration.
- In Brazil, the Bahia State Secretariat of Public Security is rolling out a 92-site public safety LTE network – using Huawei’s equipment operating in a 2 x 5 MHz block of Band 28 (700 MHz) spectrum – in 13 municipalities across the state of Bahia.
- The Paraná State Secretariat of Public Security has invested in a Motorola Solutions-supplied LTE infrastructure solution to provide in-field, deployable broadband capabilities for both voice and data communications. Rio Grande do Sul and several other Brazilian states are also planning to implement private LTE networks for public safety broadband communications.
- Neptune Communications is setting up an LTE-based connectivity service platform – using dedicated Band 14 (700 MHz) spectrum – to deliver resilient, mission-critical voice and data services to key agencies of the Government of Barbados.

Topics Covered

Introduction to public safety LTE and 5G
Value chain and ecosystem structure
Market drivers and challenges
System architecture and key elements of public safety LTE and 5G networks
Operational models for public safety LTE and 5G networks, including fully dedicated, shared core, hybrid government-commercial, secure MVNO/MOCN, commercial and sliced private networks
PPPs (Public-Private Partnerships) and other common approaches to financing and delivering dedicated nationwide public safety broadband networks
Enabling technologies and concepts, including 3GPP-defined MCX, HPUE, IOPS, 5G MBS, ProSe and sidelink for D2D communications, rapidly deployable LTE/5G systems, QPP (QoS, Priority & Preemption), network slicing, end-to-end security, high-precision positioning, ATG/A2G (Air-to-Ground), and satellite-based NTN (Non-Terrestrial Network) integration
Analysis of public safety broadband application scenarios and use cases, ranging from mission-critical group communications and real-time video transmission to 5G era applications centered upon MCX services in high-density environments, massive-scale UHD video surveillance and analytics, AR/VR/MR (Augmented, Virtual & Mixed Reality), drones and robotics
Key trends such as the growing prevalence of nationwide hybrid government-commercial broadband networks, production-grade deployments of 3GPP standards-compliant MCX services, LMR-based interim solutions for off-network communications, deployable LTE network assets for wildfire fighting and other disaster relief operations, and 5G NR-equipped portable networks supporting high-bandwidth, low-latency emergency communications.
Future roadmap for the public safety LTE and 5G market
Review of public safety LTE/5G engagements worldwide, including a detailed assessment of 15 nationwide public safety broadband projects and additional case studies of 50 dedicated, hybrid, secure MVNO/MOCN and commercial operator-supplied systems
Spectrum availability, allocation and usage across the global, regional and national domains
Standardization, regulatory and collaborative initiatives
Profiles and strategies of 1,700 ecosystem players, including LTE/5G equipment suppliers and public safety-domain specialists
Strategic recommendations for public safety and government agencies, LTE/5G infrastructure, device and chipset suppliers, LMR vendors, system integrators, and mobile operators
Market analysis and forecasts from 2022 till 2030

Forecast Segmentation:

Market forecasts are provided for each of the following submarkets and their subcategories:

Public Safety LTE & 5G Network Infrastructure
- Submarkets
  - RAN (Radio Access Network)
  - Mobile Core
  - Backhaul & Transport
- Technology Generations
  - LTE
  - 5G NR
- Mobility Categories
  - Fixed Base Stations & Infrastructure
  - Deployable Network Assets
- Deployable Network Asset Form Factors
  - NIB (Network-in-a-Box)
  - Vehicular COWs (Cells-on-Wheels)
  - Aerial Cell Sites
  - Maritime Platforms
- RAN Base Station (eNB/gNB) Cell Sizes
  - Macrocells
  - Small Cells
- Backhaul & Transport Transmission Mediums
  - Fiber & Wireline
  - Microwave
  - Satellite

Public Safety LTE & 5G Terminal Equipment
- Technology Generations
  - LTE
  - 5G NR
- Form Factors
  - Smartphones & Handportable Terminals
  - Mobile & Vehicular Routers
  - Fixed CPEs (Customer Premises Equipment)
  - Tablets & Notebook PCs
  - Smart Wearables
  - IoT Modules, Dongles & Others

Public Safety LTE & 5G Subscriptions/Service Revenue
- Technology Generations
  - LTE
  - 5G NR
- Network Types
  - Dedicated & Hybrid Government-Commercial Networks
  - Secure MVNO & MOCN Networks
  - Sliced & Commercial Mobile Networks

Public Safety LTE & 5G Systems Integration & Management Solutions
- Submarkets
  - Network Integration & Testing
  - Device Management & User Services
  - Managed Services, Operations & Maintenance
  - Cybersecurity

Public Safety Broadband Applications
- Submarkets
  - Mission-Critical Voice & Group Communications
  - Real-Time Video Transmission
  - Messaging, File Transfer & Presence Services
  - Mobile Office & Field Applications
  - Location Services & Mapping
  - Situational Awareness
  - Command & Control
  - AR/VR/MR (Augmented, Virtual & Mixed Reality)

Regional Markets
- North America
- Asia Pacific
- Europe
- Middle East & Africa
- Latin & Central America

Key Questions Answered

The report provides answers to the following key questions:

How big is the public safety LTE and 5G opportunity?
What trends, drivers and challenges are influencing its growth?
What will the market size be in 2025, and at what rate will it grow?
Which submarkets and regions will see the highest percentage of growth?
What are the operational models and application scenarios of LTE and 5G for first responders?
What are the existing and candidate frequency bands for the operation of PPDR broadband systems?
How can public safety stakeholders leverage excess spectrum capacity to ensure the economic viability of purpose-built LTE and 5G NR infrastructure?
When will MCX, HPUE, IOPS, 5G MBS, 5G NR sidelink, NTN connectivity and other 3GPP-defined critical communications features be widely employed?
What is the status of fully dedicated, hybrid government-commercial and secure MVNO/MOCN-based public safety broadband networks worldwide?
When will FirstNet, Safe-Net, ESN, RRF, SIRDEE, VIRVE 2.0 and other nationwide public safety broadband networks replace existing digital LMR systems?
What opportunities exist for commercial mobile operators and critical communications service providers?
What are the future prospects of NIB (Network-in-a-Box), COW (Cell-on-Wheels), aerial cell sites and other rapidly deployable LTE and 5G NR-equipped network systems for incident command and emergency response needs?
How will 5G enable advanced features such as MCX services in high-density environments, UE-to-network and UE-to-UE relaying for coverage expansion, satellite-assisted NR access, high-precision positioning, and network slicing-based dynamic QoS guarantees and isolation?
Who are the key ecosystem players, and what are their strategies?
What strategies should LTE/5G infrastructure suppliers, LMR vendors, system integrators and mobile operators adopt to remain competitive?

1 Chapter 1: Introduction

1.1 Executive Summary

1.2 Topics Covered

1.3 Forecast Segmentation

1.4 Key Questions Answered

1.5 Key Findings

1.6 Summary of Recent Market Developments

1.7 Methodology

1.8 Target Audience

1.9 Companies & Organizations Mentioned

2 Chapter 2: An Overview of the Public Safety LTE & 5G Market

2.1 Narrowband LMR (Land Mobile Radio) Systems in the Public Safety Sector

2.1.1 LMR Market Size

2.1.1.1 Analog LMR

2.1.1.2 DMR

2.1.1.3 dPMR, NXDN & PDT

2.1.1.4 P25

2.1.1.5 TETRA

2.1.1.6 Tetrapol

2.1.1.7 Other LMR Technologies

2.1.2 The Limitations of LMR Networks

2.2 Adoption of Commercial Mobile Broadband Technologies

2.2.1 Why Use Commercial Technologies?

2.2.2 The Role of Mobile Broadband in Public Safety Communications

2.2.3 Can Mobile Broadband Technologies Replace LMR Systems?

2.3 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 URLLC (Ultra-Reliable Low-Latency Communications)

2.3.7.3 mMTC (Massive Machine-Type Communications)

2.3.8 5G-Advanced & the Evolution to 6G

2.3.9 5G Applications for Public Safety

2.4 Public Safety LTE/5G Network Operational Models

2.4.1 Fully Dedicated Private Broadband Network

2.4.2 Shared Core Network With Independent RANs

2.4.3 Hybrid Government-Commercial Network

2.4.4 Secure MVNO & MOCN (Dedicated Mobile Core)

2.4.5 Access Over Commercial Broadband Networks

2.4.6 Sliced Private Network for Public Safety Communications

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 Public Safety LTE/5G Value Chain

2.6.1 Enabling Technology Providers

2.6.2 RAN, Mobile Core & Transport Infrastructure Suppliers

2.6.3 Terminal Equipment Vendors

2.6.4 System Integrators

2.6.5 Application Developers

2.6.6 Test, Measurement & Performance Specialists

2.6.7 Mobile Operators

2.6.8 MVNOs

2.6.9 Public Safety & Government Agencies

2.7 Market Drivers

2.7.1 Growing Demand for High-Speed & Low-Latency Data Applications

2.7.2 Recognition of LTE & 5G as the De-Facto Platform for Wireless Connectivity

2.7.3 Spectral Efficiency & Bandwidth Flexibility

2.7.4 National & Cross-Border Interoperability

2.7.5 Consumer-Driven Economies of Scale

2.7.6 Endorsement From the Public Safety Community

2.7.7 Limited Competition From Other Wireless Broadband Technologies

2.7.8 Control Over QPP (QoS, Priority & Preemption) Policies

2.7.9 Support for Mission-Critical Functionality

2.7.10 Privacy & Security

2.8 Market Barriers

2.8.1 Limited Availability of Licensed Spectrum for Public Safety Broadband

2.8.2 Financial Challenges Associated With Large-Scale & Nationwide Networks

2.8.3 Technical Complexities of Implementation & Operation

2.8.4 Smaller Coverage Footprint Than Legacy LMR Systems

2.8.5 Delayed Standardization & Commercialization of Mission-Critical Functionality

2.8.6 ProSe/Sidelink Chipset Ecosystem for Direct Mode Communications

2.8.7 COTS (Commercial Off-the-Shelf) Equipment-Related Challenges

2.8.8 Conservatism of End User Organizations

3 Chapter 3: System Architecture & Technologies for Public Safety LTE/5G Networks

3.1 Architectural Components of Public Safety LTE/5G Networks

3.1.1 UE (User Equipment)

3.1.1.1 Smartphones & Handportable Terminals

3.1.1.2 Mobile & Vehicular Routers

3.1.1.3 Fixed CPEs (Customer Premises Equipment)

3.1.1.4 Tablets & Notebook PCs

3.1.1.5 Smart Wearables

3.1.1.6 Cellular IoT Modules

3.1.1.7 Add-On Dongles

3.1.2 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 & Rules Function)

3.1.6 5GC (5G 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 & 5G MBS

3.1.7.3 ProSe (Proximity Services)

3.1.7.4 Group Communication & Mission-Critical Services

3.1.8 Gateways 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

3.2.2 Mission-Critical Video & Data

3.2.2.1 MCVideo (Mission-Critical Video)

3.2.2.2 MCData (Mission-Critical Data)

3.2.3 ProSe & Sidelink for D2D 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

3.2.5.2.3 Pre-Integrated Racks

3.2.5.3 Wheeled & 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 RedCap (Reduced Capability) NR Devices

3.2.7.3 Techniques for URLLC

3.2.7.4 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 & 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 Public Safety Spectrum Sharing & Aggregation

3.2.12 Shared & Unlicensed 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 Local Area Licensing of Shared Spectrum

3.2.12.4 LTE-U, LAA (Licensed Assisted Access), eLAA (Enhanced LAA) & FeLAA (Further Enhanced LAA)

3.2.12.5 MulteFire: Standalone Operation in Unlicensed Spectrum

3.2.12.6 License-Exempt 1.9 GHz sXGP (Shared Extended Global Platform)

3.2.12.7 5G NR-U (NR in Unlicensed Spectrum)

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 DAS (Distributed Antenna Systems)

3.2.20 New RAN Architectures: From D-RAN & C-RAN (Distributed & Centralized RAN) to vRAN (Virtualized RAN) & Open RAN

3.2.21 ATG/A2G (Air-to-Ground) Communications

3.2.22 Satellite Communications, HAPS (High-Altitude Platforms) & NTNs (Non-Terrestrial Networks)

3.2.23 High-Capacity Microwave & mmWave (Millimeter Wave) Links

3.2.24 Wireline Fiber Infrastructure

3.2.25 SON (Self-Organizing Networks)

3.2.26 MEC (Multi-Access Edge Computing)

3.2.27 AI (Artificial Intelligence) & ML (Machine Learning)

3.2.28 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 MBS (5G Multicast-Broadcast Services) in High-Density Environments

4.7.15 5G NR Sidelink-Based Direct Mode Voice, Video & Data Communications

4.7.16 Coverage Expansion Through UE-To-Network & UE-to-UE Relaying

4.7.17 Satellite & NTN (Non-Terrestrial Network)-Assisted 5G NR Access

4.7.18 Centimeter-Level Positioning for First Responder Operations

4.7.19 Practical Examples of 5G Era Public Safety Applications

4.7.19.1 Area X.O (Invest Ottawa): 5G Mobile Command Center

4.7.19.2 Blueforce Development: 5G & Edge Computing for Real-Time Situational Awareness

4.7.19.3 Cosumnes Fire Department: AR Firefighting Helmets

4.7.19.4 DRZ (German Rescue Robotics Center): 5G-Equipped Mobile Robotics for Rescue Operations

4.7.19.5 Dubai Police: AI (Artificial Intelligence)-Enabled Identification of Criminals

4.7.19.6 Dublin Fire Brigade: Coordinating Emergency Incidents With 5G Connectivity

4.7.19.7 Edgybees: Real-Time Augmented Visual Intelligence

4.7.19.8 Government of Catalonia: 5G-Equipped Emergency Medical Vehicles

4.7.19.9 Guardia Civil (Spanish Civil Guard): Tactical 5G Bubbles for Drone-Based Security & Surveillance Missions

4.7.19.10 Hsinchu City Fire Department: Digital Resiliency Through Private 5G & Satellite Communications

4.7.19.11 Leuven Police: Combating Illegal Dumping & Public Nuisances With 5G-Connected Mobile Cameras

4.7.19.12 Lishui Municipal Emergency Management Bureau: 5G-Enabled Natural Disaster Management System

4.7.19.13 Maebashi City Fire Department: 5G for Emergency Response & Rescue Services

4.7.19.14 National Police of the Netherlands: AR-Facilitated Crime Scene Investigations

4.7.19.15 New Zealand Police: Aerial Surveillance Through 5G NR Connectivity

4.7.19.16 NHS (National Health Service, United Kingdom): 5G-Connected Smart Ambulances

4.7.19.17 PDRM (Royal Malaysia Police): 5G-Enabled Safe City Solution for Langkawi

4.7.19.18 Shenzhen Public Security Bureau: 5G-Connected Unmanned Police Boats

4.7.19.19 SPF (Singapore Police Force): 5G-Equipped Police Robots

4.7.19.20 V-Armed: Preparing Officers for Active Shooter Scenarios Through VR Training

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 World’s Largest Purpose-Built Public Safety Broadband Network

5.1.2 Canada: Shared Network Approach for Nationwide PSBN (Public Safety Broadband Network)

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 & 5G NR Networks

5.2.3 China: Private 5G Slicing & Band 45 (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 Taiwan: Private 5G-Equipped Emergency Response Vehicles & Hybrid P25-Broadband Communications

5.2.6 Japan: Multiple Spectrum Options for Public Safety Broadband

5.2.7 South Korea: Safe-Net – Spearheading Nationwide Public Safety LTE Network Deployments

5.2.8 Singapore: LTE-Based Broadband Overlay to Complement TETRA

5.2.9 Malaysia: Evaluating Multiple Delivery Models for Mission-Critical Broadband

5.2.10 Indonesia: Field Trials of 700 MHz Public Safety LTE Networks

5.2.11 Philippines: Rapidly Deployable LTE Systems for Disaster Relief

5.2.12 Thailand: Band 26 (800 MHz) LTE Network for the Royal Thai Police

5.2.13 Laos: LTE-Based Emergency Communications Networks for Local Governments

5.2.14 Myanmar: Possible Rollout of a 700 MHz Public Safety Broadband Network

5.2.15 India: Proposed Deployment of a National Hybrid Broadband PPDR (Public Protection & Disaster Relief) Network

5.2.16 Pakistan: Dedicated Band 26 (800 MHz) LTE Networks for Safe City Projects

5.2.17 Bangladesh: Portable LTE Networks for VIP Protection Operations

5.3 Europe

5.3.1 United Kingdom

5.3.1.1 Great Britain: ESN – Pioneering the Use of Resilient Commercial RAN Infrastructure for Emergency Communications

5.3.1.2 Northern Ireland: Planned Transition From TETRA to Broadband

5.3.2 Republic of Ireland: Early Field Trials of Dedicated LTE/5G-Ready Systems for First Responders

5.3.3 France: RRF (Radio Network of the Future) – Transitioning From Tetrapol to Mission-Critical Broadband

5.3.4 Germany: Planned Rollout of the BOS Hybrid Broadband Network

5.3.5 Belgium: Government-Owned Secure MVNO With Priority & National/Cross-Border Roaming

5.3.6 Luxembourg: RRVs (Rapid Response Vehicles) for Security Missions

5.3.7 Netherlands: Proposed Adoption of Hybrid Government-Commercial Network Model

5.3.8 Switzerland: Field Trials for the Nationwide MSK (Secure Mobile Broadband Communications) System

5.3.9 Austria: Possibility to Use Both Dedicated & Commercial RAN Infrastructure Options

5.3.10 Italy: Joint Use of TETRA & LTE Systems for Mission-Critical Communications

5.3.11 Spain: SIRDEE – Establishing European Leadership With Dedicated 450 MHz & 700 MHz Infrastructure

5.3.12 Portugal: Preliminary Trials of 5G for Emergency Services

5.3.13 Sweden: Rakel G2 Secure Broadband System & Teracom AGA Network for Aerial Coverage

5.3.14 Norway: NGN (Next-Generation Nødnett) – Mission-Critical Communications Over Commercial 3GPP Networks

5.3.15 Denmark: Secured Shared 4G/5G Infrastructure for Mission-Critical Broadband Services

5.3.16 Finland: VIRVE 2.0 – MOCN-Based Mission-Critical Broadband Service

5.3.17 Estonia: State-Owned MVNO for Public Safety Broadband

5.3.18 Czech Republic: National Roaming & Priority for Public Safety Traffic Over 700 MHz Spectrum

5.3.19 Poland: Leveraging LTE to Modernize Existing Police Radio Communications Systems

5.3.20 Greece: TETRA-Broadband Integration & LTE-Equipped Portable Emergency Command Systems

5.3.21 Türkiye: Domestically-Produced 4G/5G Base Stations for Public Safety & Emergency Communications

5.3.22 Bulgaria: Hybrid TETRA-LTE Implementation to Meet Mission-Critical Communications Needs

5.3.23 Romania: Possible Deployment of a 700 MHz Public Safety Broadband Network

5.3.24 Hungary: EDR 2.0/3.0 – Hybrid PPDR Broadband Network

5.3.25 Slovenia: Setting 5G PPDR Projects in Motion

5.3.26 Serbia: LTE-Connected Safe City & Surveillance Systems

5.3.27 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-Broadband Network for Mission-Critical Communications

5.4.2 United Arab Emirates: Emirate-Wide Band 28 (700 MHz) Public Safety LTE Networks

5.4.3 Qatar: The Middle East’s First Dedicated Public Safety Broadband Network

5.4.4 Oman: Nationwide Band 20 (800 MHz) LTE Network for the ROP (Royal Oman Police)

5.4.5 Kuwait: Ongoing Narrowband to Broadband Transition

5.4.6 Bahrain: Planned 700 MHz PPDR Broadband Rollout

5.4.7 Jordan: Pilot LTE Network for the Jordanian Armed Forces

5.4.8 Iraq: Local LTE-Based Wireless Communications Systems for Security Forces

5.4.9 Egypt: Security-Oriented LTE Networks for Safe City Initiatives

5.4.10 Lebanon: LTE Network for Internal Security Forces

5.4.11 Israel: Mission-Critical LTE/5G-Ready Networks for Military & Public Safety Communications

5.4.12 Tunisia: Dedicated Band 28 (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 (410 MHz) Public Safety Broadband Network

5.4.15 Kenya: Custom-Built LTE Network for the Kenyan Police Service

5.4.16 Zambia: 400 MHz Private Broadband System for Safe City Project

5.4.17 Ghana: 1.4 GHz LTE-Based National Security Communications Network

5.4.18 Nigeria: Planned Rollouts of Public Safety LTE Networks for Safe City Initiatives

5.4.19 Angola: TETRA-LTE Integration Through Commercial Mobile Operators

5.4.20 Republic of the Congo: LTE-Equipped ECVs (Emergency Communications Vehicles)

5.4.21 Côte d’Ivoire: Purpose-Built LTE Network for the Ministry of Interior and Security

5.4.22 Cameroon: LTE Connectivity for Video Surveillance & Broadband Applications

5.4.23 Mali: LTE-Based Safe City Network for Police & Security Forces

5.4.24 Senegal: LTE-Enabled Smart City & Video Surveillance System

5.4.25 Madagascar: LTE-Based Secure Communications Network for the Madagascar National Police

5.4.26 Mauritius: Private LTE Network for the MPF (Mauritius Police Force)

5.5 Latin & Central America

5.5.1 Brazil: Regional Band 28 (700 MHz) LTE Networks for Public Security & Military Police Forces

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 Band 28 (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 & Emergency Response System

5.5.8 Ecuador: LTE-Based Communications for the ECU-911 Emergency Response Program

5.5.9 Bolivia: Private LTE Networks for the BOL-110 Citizen Security System & Other Safe City Projects

5.5.10 Trinidad & Tobago: Rapidly Deployable 400 MHz LTE System for National Security Applications

5.5.11 Barbados: Band 14 (700 MHz) LTE-Based Connectivity Service Platform

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 In-Building FirstNet Connectivity

6.1.1.12 5G NR Access for First Responders

6.1.1.13 Multiple 3GPP-Complaint MCPTT Service Offerings

6.1.1.14 Interoperability With Legacy LMR Systems

6.1.2 South Korea’s Safe-Net (National Disaster Safety Communications 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 Government-Owned RAN & Mobile Core Equipment

6.1.2.6 RAN Sharing With Commercial Mobile Operators

6.1.2.7 Interworking With LTE-Based Railway & Maritime Networks

6.1.2.8 3GPP Standards-Compliant MCPTT Service

6.1.2.9 Planned Evolution Towards 5G

6.1.2.10 Experimentation With D2D Communications

6.1.3 Royal Thai Police’s LTE 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 Broadband Access for Other Government & PPDR Users

6.1.3.6 Use of Deployable LTE Assets During the Tham Luang Cave Rescue

6.1.4 Great Britain’s ESN (Emergency Services 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 ESN Products

6.1.4.6 EE’s LTE Network Expansion & Additional Low-Band Spectrum

6.1.4.7 Government-Funded RAN Assets for Remote Areas

6.1.4.8 London Underground Coverage

6.1.4.9 Overlay A2G (Air-to-Ground) Network

6.1.4.10 In-Building ESN Coverage Enhancement

6.1.4.11 Deployable Assets for Temporary Coverage

6.1.4.12 Direct Mode Solution for ESN Terminals

6.1.4.13 Replacement of the Airwave TETRA Network

6.1.5 France’s RRF (Radio Network of the Future)

6.1.5.1 Operational Model

6.1.5.2 Vendors

6.1.5.3 Deployment Summary

6.1.5.3.1 PCSTORM PoC (Proof-of-Concept) Project

6.1.5.3.2 Nationwide Mission-Critical RRF Network

6.1.5.4 Key Applications

6.1.5.5 Interworking With Legacy Networks

6.1.5.6 Expansion of the RRF Network to Overseas Territories

6.1.5.7 RFIs to Address Direct Mode, A2G (Air-to-Ground), LSA (Licensed Shared Access) & Other Issues

6.1.6 Germany’s Planned BOS Hybrid Broadband Network

6.1.6.1 Operational Model

6.1.6.2 Vendors

6.1.6.3 Deployment Summary

6.1.6.3.1 Hybrid Broadband Network Trial

6.1.6.3.2 KoPa_45 Project Mission-Critical Broadband Development Environment

6.1.6.3.3 Planned Nationwide Rollout of Broadband Network

6.1.6.4 Key Applications

6.1.6.5 Interoperability With TETRA & Bundeswehr’s Cellular Assets

6.1.6.6 Spectrum, Direct Communications & Other Areas of Interest

6.1.7 Belgium’s ASTRID BLM (Blue Light Mobile)

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 Priority & Preemption Service Levels

6.1.7.6 VPN Tunneling for Secure Connectivity

6.1.7.7 ASTRID Cloud: Application Hosting & Sharing

6.1.7.8 Future Plans for Service Evolution

6.1.7.9 Possible Rollout of Complementary RAN Infrastructure

6.1.8 Switzerland’s MSK (Secure Mobile Broadband Communications) Program

6.1.8.1 Operational Model

6.1.8.2 Vendors

6.1.8.3 Deployment Summary

6.1.8.3.1 Pilot Project & PoC (Proof-of-Concept) Trials

6.1.8.3.2 Planned Nationwide Mission-Critical Broadband Network Rollout

6.1.8.4 Key Applications

6.1.8.5 MSK System Requirements

6.1.8.6 Interconnectivity With POLYCOM & SDVS

6.1.9 Spain’s SIRDEE Mission-Critical Broadband Network

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 Specific Requirements for Mission-Critical Broadband Network

6.1.9.6 Preparing for Tetrapol to Broadband Transition

6.1.10 Sweden’s Rakel G2 Secure Broadband Communications System

6.1.10.1 Operational Model

6.1.10.2 Vendors

6.1.10.3 Deployment Summary

6.1.10.3.1 Early Pilot Projects for Public Safety Broadband Capabilities

6.1.10.3.2 Stage 1: Initial Procurement of Dedicated Core, RAN Coverage & SIM Cards

6.1.10.3.3 Stage 2: Planned Rollout of State-Owned RAN Infrastructure

6.1.10.4 Key Applications

6.1.10.5 Cross-Border Cooperation

6.1.10.6 Timeline for Rakel to Rakel G2 Migration

6.1.11 Finland’s VIRVE 2.0 Mission-Critical Broadband Service

6.1.11.1 Operational Model

6.1.11.2 Vendors

6.1.11.3 Deployment Summary

6.1.11.4 Key Applications

6.1.11.5 Legislative Support for the Rollout of VIRVE 2.0

6.1.11.6 Migration From Existing TETRA Network to VIRVE 2.0

6.1.12 Hungary’s EDR 2.0/3.0 PPDR Broadband Network

6.1.12.1 Operational Model

6.1.12.2 Vendors

6.1.12.3 Deployment Summary

6.1.12.3.1 Multi-Site 700 MHz LTE Field Trial

6.1.12.3.2 EDR 2.0 Broadband Data Service

6.1.12.3.3 EDR 3.0 Voice & Data Service

6.1.12.4 Key Applications

6.1.12.5 Cross-Border Cooperation With Neighboring Countries

6.1.12.6 Future Plans for 5G PPDR Use Cases

6.1.13 Slovenia’s 5G PPDR Project

6.1.13.1 Operational Model

6.1.13.2 Vendors

6.1.13.3 5G Pilot Deployment Summary

6.1.13.4 Key Applications

6.1.13.5 Cross-Border Collaboration With Hungary

6.1.13.6 Ongoing Rollout of Hybrid Government-Commercial LTE/5G-Ready Network

6.1.14 Russia’s Secure 450 MHz LTE Network

6.1.14.1 Operational Model

6.1.14.2 Vendors

6.1.14.3 Deployment Summary

6.1.14.4 Key Applications

6.1.14.5 Physical & Cybersecurity Measures to Address National Security Concerns

6.1.14.6 Integration With Russia’s National Broadband Platform for Socially Critical Infrastructure

6.1.15 Qatar MOI’s (Ministry of Interior) LTE Network

6.1.15.1 Operational Model

6.1.15.2 Vendors

6.1.15.3 Deployment Summary

6.1.15.4 Key Applications

6.1.15.5 Integration With the MOI’s TETRA Network

6.1.15.6 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 ALADIN (Advanced Low-Altitude Data Information System) Project

6.2.5 Bahia State Secretariat of Public Security

6.2.6 Ban Chang Smart City Private 5G Network

6.2.7 BLUnet Schweiz’s BLU.swiss

6.2.8 Buenos Aires City Police

6.2.9 California National Guard

6.2.10 City of Sendai

6.2.11 Cochabamba Safe City Project

6.2.12 Dublin Fire Brigade

6.2.13 Ecuador ECU-911

6.2.14 Føroya Tele’s (Faroese Telecom) KIMA

6.2.15 Ghana’s Integrated National Security Communications Network

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 Kenyan Police Service

6.2.21 KPN Critical Communications Platform

6.2.22 Lijiang Police

6.2.23 Lishui Municipal Emergency Management

6.2.24 Málaga Local Police

6.2.25 Ministry of Home Affairs and Internal Security (Zambia)

6.2.26 MPF (Mauritius Police Force)

6.2.27 MRC (Mobile Radio Center)

6.2.28 Nanjing Municipal Government

6.2.29 National Police of Colombia

6.2.30 Nedaa

6.2.31 New Zealand Police

6.2.32 Philippine Red Cross

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 São Paulo State Military Police

6.2.40 Shanghai Police Department

6.2.41 SPF (Singapore Police Force)

6.2.42 Swisscom Broadcast’s Public Safety LTE Platform

6.2.43 Telstra LANES Emergency

6.2.44 Thales’ Eiji

6.2.45 TIM’s (Telecom Italia Mobile) Public Safety LTE Service

6.2.46 TWFRS (Tyne and Wear Fire and Rescue Service)

6.2.47 UN (United Nations)

6.2.48 Verzion’s Frontline Solutions

6.2.49 Vientiane Municipal Government

6.2.50 Wujiang Public Security Bureau

7 Chapter 7: Public Safety LTE/5G Spectrum Availability, Allocation & Usage

7.1 Frequency Bands for Public Safety LTE & 5G Networks

7.1.1 200 MHz

7.1.1.1 Japan’s 170 – 202.5 MHz Band

7.1.1.2 Other Non-Traditional Frequency Bands

7.1.2 400 MHz

7.1.2.1 Bands 31, 72 & 73 (450 – 470 MHz)

7.1.2.2 Bands 87 & 88 (410 – 430 MHz)

7.1.2.3 Non-3GPP Bands

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 (758 – 798 MHz)

7.1.4.2 Band 28 (703 – 803 MHz)

7.1.4.3 Band 68 (698 – 783 MHz)

7.1.4.4 Other 700 MHz Bands

7.1.5 800 MHz

7.1.5.1 Band 20 (791 – 862 MHz)

7.1.5.2 Band 26 (814 – 894 MHz)

7.1.5.3 Other 800 MHz Bands

7.1.6 900 MHz

7.1.6.1 Band 8 (880 – 960 MHz)

7.1.7 Mid-Band (1 – 6 GHz) Frequencies

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 High-Band mmWave (Millimeter Wave) Spectrum

7.1.8.1 26 GHz

7.1.8.2 28 GHz

7.1.8.3 37 GHz

7.1.8.4 57 – 71 GHz

7.1.8.5 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 Japan

7.3.6 South Korea

7.3.7 Singapore

7.3.8 Malaysia

7.3.9 Indonesia

7.3.10 Thailand

7.3.11 Myanmar

7.3.12 India

7.3.13 Pakistan

7.3.14 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 Czech Republic

7.4.18 Poland

7.4.19 Türkiye

7.4.20 Bulgaria

7.4.21 Romania

7.4.22 Hungary

7.4.23 Slovenia

7.4.24 Russia

7.4.25 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 Jordan

7.5.7 Israel

7.5.8 Tunisia

7.5.9 South Africa

7.5.10 Kenya

7.5.11 Ghana

7.5.12 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 Chile

7.6.5 Bardados

7.6.6 Rest of Latin & Central America

8 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, 5G MBS, MCIOPS, NTN Connectivity & 5G NR Sidelink Enhancements

8.1.8 Release 18 & Beyond: UE-to-UE Relays, VMRs, High-Density 5G MBS & Support for Less Than 5 MHz of Bandwidth

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 LMR-3GPP Interworking & Public Safety LTE/5G-Related Standardization Efforts

8.5 Australian Department of Home Affairs

8.5.1 Leading Australia’s National PSMB (Public Safety Mobile Broadband) Program

8.6 BDBOS (Federal Agency for Public Safety Digital Radio, Germany)

8.6.1 Public Safety LTE/5G-Related Standardization Efforts

8.7 BMWi (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 CATA (Canadian Advanced Technology Alliance)

8.9.1 Public Safety LTE/5G-Related Advocacy Efforts

8.10 CITIG (Canadian Interoperability Technology Interest Group)

8.10.1 Public Safety LTE/5G Advocacy Efforts

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 (Public Safety Broadband Network) 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 Erillisverkot (State Security Networks Group, Finland)

8.13.1 Public Safety LTE/5G-Related Standardization Efforts

8.14 ETSI (European Telecommunications Standards Institute)

8.14.1 TCCE (TETRA and Critical Communications Evolution) Technical Committee

8.14.1.1 Standards & Guidelines for Critical Communications Broadband & TETRA-3GPP Interworking

8.14.2 CTI (Center for Testing and Interoperability)

8.14.2.1 MCX (Mission-Critical PTT, Video & Data) Plugtests

8.14.3 Other Technical Committees & Critical Communications LTE/5G-Related Standards

8.15 FirstNet (First Responder Network) Authority

8.15.1 Overseeing the Buildout, Operation & Evolution of the FirstNet Public Safety Broadband Network

8.15.2 Standardization of Mission-Critical Features for 3GPP Technologies

8.15.3 Innovation & Test Lab

8.15.4 PSAC (Public Safety Advisory Committee)

8.16 French Ministry of Interior

8.16.1 Public Safety LTE/5G-Related Standardization Efforts

8.17 GCF (Global Certification Forum)

8.17.1 Certification of LTE/5G Devices for Public Safety & Critical Communications Networks

8.18 United Kingdom Home Office

8.18.1 Public Safety LTE/5G-Related Standardization Efforts

8.19 ICCRA (International Critical Control Rooms Alliance)

8.19.1 LTE/5G Support in Critical Control Room Interface Standards

8.20 IETF (Internet Engineering Task Force)

8.20.1 Standards & Protocols for Mission-Critical Services Over LTE & 5G Networks

8.21 IGOF (International Governmental Operators’ Forum)

8.21.1 Addressing Broadband-Related Issues in Critical Communications

8.22 ISED (Innovation, Science and Economic Development Canada)

8.22.1 Participation in Canada’s National PSBN (Public Safety Broadband Network) Program

8.22.2 Regulation of Public Safety Broadband Spectrum

8.22.3 CRC (Communications Research Centre Canada)

8.22.3.1 Interoperability Research and Evaluation of Public Safety LTE/5G Networks

8.23 ITU (International Telecommunication Union)

8.23.1 Spectrum Harmonization for PPDR (Public Protection & Disaster Relief) Broadband Systems

8.23.2 Defining the Role of IMT-2020 to Support PPDR Applications

8.24 MCOP (Mission-Critical Open Platform)

8.24.1 Open Platform for the Development of Standards-Compliant MCPTT Applications

8.25 MCS-TaaSting (Mission-Critical Services – Testing-as-a-Service)

8.25.1 Flexible Testing Tools & Certification Procedures for 3GPP’s MCX Standards

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 Nkom (Norwegian Communications Authority)

8.28.1 Standardization Efforts for Critical Communications Over 3GPP Networks

8.29 NSW (New South Wales) Telco Authority

8.29.1 Role in Australia’s National PSMB (Public Safety Mobile Broadband) Program

8.30 OMA SpecWorks (Open Mobile Alliance)

8.30.1 PoC (PTT-over-Cellular): V1.04, V2.0 & V2.1

8.30.2 PCPS (Push-to-Communicate for Public Safety)

8.31 PIA (PSBN Innovation Alliance)

8.31.1 PSBN Governance in Canada’s Ontario Province

8.32 PSBTA (Public Safety Broadband Technology Association)

8.32.1 Public Safety LTE/5G-Related Activities

8.33 PSCE (Public Safety Communication Europe)

8.33.1 Public Safety LTE/5G Standardization

8.33.2 BroadX Projects: Pan-European Interoperable Mobile Broadband for Public Safety

8.33.2.1 BroadMap (2016 – 2017): Specifications & Roadmap for Procurement

8.33.2.2 BroadWay (2018 – 2022): R&D/PCP (Pre-Commercial Procurement)

8.33.2.3 BroadNet (2023 & Beyond): Live Procurement and Sustainable Governance

8.33.3 Other Public Safety LTE/5G-Related Work

8.34 Public Safety Canada

8.34.1 Federal PSBN (Public Safety Broadband Network) Task Team

8.34.2 TNCO (Temporary National Coordination Office) for Canada’s National PSBN

8.35 Safe-Net Forum

8.35.1 Technical/Policy Guidance & Ecosystem Development for Critical Communications LTE/5G Networks

8.36 TCCA (The Critical Communications Association)

8.36.1 CCBG (Critical Communications Broadband Group)

8.36.2 BIG (Broadband Industry Group)

8.36.3 Future Technologies Group

8.37 TIA (Telecommunications Industry Association)

8.37.1 TR-8.8: Subcommittee on Broadband Data Systems

8.37.1.1 Defining Requirements for LMR-3GPP Interworking & Critical Broadband Capabilities

8.38 TTA (Telecommunications Technology Association, South Korea)

8.38.1 Functional Requirements, Testing & Certification for Public Safety LTE/5G Technologies

8.39 U.S. DHS (Department of Homeland Security)

8.39.1 S&T (Science and Technology) Directorate

8.39.1.1 Public Safety LTE/5G-Related Projects

8.39.2 CISA (Cybersecurity and Infrastructure Security Agency)

8.39.2.1 SAFECOM: Best Practices for LMR-3GPP Integration

8.40 U.S. FCC (Federal Communications Commission)

8.40.1 PSHSB (Public Safety and Homeland Security Bureau)

8.40.2 Endorsement of LTE as the Platform for 700 MHz Public Safety LTE Networks

8.40.3 Regulation of Public Safety Broadband Spectrum

8.40.4 Other Engagements Relevant to Public Safety LTE/5G

8.41 U.S. NIST (National Institute of Standards and Technology)

8.41.1 CTL (Communications Technology Laboratory)

8.41.2 PSCR (Public Safety Communications Research): R&D Leadership for FirstNet

8.41.2.1 R&D, Testing & Evaluation of Technologies for Public Safety LTE/5G

8.42 U.S. NPSTC (National Public Safety Telecommunications Council)

8.42.1 Early Leadership in Public Safety LTE

8.42.2 Spectrum Management, LMR-3GPP Integration, Public Safety-Grade Systems & Other Work

8.43 U.S. NTIA (National Telecommunications and Information Administration)

8.43.1 FirstNet Governance & Funding

8.43.2 Other Work Related to Public Safety LTE/5G Networks

8.44 Vendor-Led Alliances

8.44.1 Huawei’s eLTE Industry Alliance

8.44.2 Nokia’s Mission-Critical Communications Alliance

8.44.3 L3Harris’ Mission Critical Alliance

8.45 Others

8.45.1 Government Agencies & National Regulators

8.45.2 Spectrum & Technology Innovation Industry Alliances

8.45.3 Regional & Country-Specific Associations

8.45.4 Academic Institutes, Research Centers & Labs

9 Chapter 9: Key Ecosystem Players

9.1 10T Tech

9.2 1NCE

9.3 1oT

9.4 4K Solutions

9.5 4RF

9.6 6Harmonics/6WiLInk

9.7 6WIND

9.8 7P (Seven Principles)

9.9 A Beep/Diga-Talk+

9.10 A1 Telekom Austria Group

9.11 A10 Networks

9.12 A5G Networks

9.13 AAEON Technology (ASUS – ASUSTeK Computer)

9.14 Aarna Networks

9.15 ABEL Mobilfunk

9.16 ABiT Corporation

9.17 ABS

9.18 Abside Networks

9.19 Accedian

9.20 AccelerComm

9.21 Accelink Technologies

9.22 Accelleran

9.23 Accenture

9.24 Accton Technology Corporation

9.25 Accuver (InnoWireless)

9.26 ACE Technologies

9.27 AceAxis

9.28 AceTel (Ace Solutions)

9.29 Achronix Semiconductor Corporation

9.30 ACOME

9.31 Actelis Networks

9.32 Action Technologies (Shenzhen Action Technologies)

9.33 Actiontec Electronics

9.34 Active911

9.35 Actus Networks

9.36 Adax

9.37 Adcor Magnet Systems

9.38 ADI (Analog Devices, Inc.)

9.39 ADLINK Technology

9.40 ADRF (Advanced RF Technologies)

9.41 ADT

9.42 ADTRAN

9.43 ADVA

9.44 Advanced Energy Industries

9.45 AdvanceTec Industries

9.46 Advantech

9.47 Advantech Wireless Technologies (Baylin Technologies)

9.48 Aegex Technologies

9.49 Aerial Applications

9.50 Aeris

9.51 Aerostar International

9.52 Aethertek

9.53 Affarii Technologies

9.54 Affirmed Networks (Microsoft Corporation)

9.55 AFL Global

9.56 AFRY

9.57 Agile (Agile Interoperable Solutions)

9.58 AGIS (Advanced Ground Information Systems)

9.59 AGM Mobile

9.60 AH NET (MVM NET)

9.61 AI-LINK

9.62 AINA Wireless

9.63 Airbus/SLC (Secure Land Communications)

9.64 Airfide Networks

9.65 Airgain

9.66 AirHop Communications

9.67 Airlinq

9.68 Airspan Networks

9.69 Airtower Networks

9.70 Airwavz Solutions

9.71 AIS (Advanced Info Service)

9.72 AiVader

9.73 Akamai Technologies

9.74 Akoustis Technologies

9.75 Alaxala Networks Corporation (Fortinet)

9.76 ALBEDO Telecom

9.77 albis-elcon (UET – United Electronic Technology)

9.78 Alcadis

9.79 Alea (Leonardo)

9.80 Alef (Alef Edge)

9.81 Alepo

9.82 Alibaba Group

9.83 Aliniant

9.84 Allbesmart

9.85 Allen Vanguard Wireless

9.86 Allerio

9.87 Allied Telesis

9.88 Allot

9.89 Alpha Networks

9.90 Alpha Wireless

9.91 Alsatis Réseaux

9.92 Altaeros

9.93 Altair Semiconductor (Sony Semiconductor Israel)

9.94 ALTÁN Redes

9.95 Altice Group

9.96 Altiostar (Rakuten Symphony)

9.97 ALVIS (Argentina)

9.98 AM Telecom

9.99 Amantya Technologies

9.100 Amarisoft

9.101 Amazon/AWS (Amazon Web Services)

9.102 Ambra Solutions-ECOTEL

9.103 AMD (Advanced Micro Devices)

9.104 Amdocs

9.105 América Móvil

9.106 American Tower Corporation

9.107 AMI (American Megatrends International)

9.108 AMIT Wireless

9.109 Ampere Computing

9.110 Amphenol Corporation

9.111 Ampleon

9.112 Amtele Communication

9.113 Ananki (Intel Corporation)

9.114 Andesat

9.115 ANDRO Computational Solutions

9.116 Anktion (Fujian) Technology

9.117 Anokiwave

9.118 Anritsu

9.119 ANS – Advanced Network Services (Charge Enterprises)

9.120 Antenna Company

9.121 Antna Antenna Technology

9.122 Aorotech

9.123 Apple

9.124 APRESIA Systems

9.125 APSTAR (APT Satellite Company)

9.126 APT (Asia Pacific Telecom)

9.127 aql

9.128 Aquila (Suzhou Aquila Solutions)

9.129 Aqura Technologies (Telstra Purple)

9.130 Arabsat

9.131 Arcadyan Technology Corporation (Compal Electronics)

9.132 Archos

9.133 Arete M

9.134 Argela

9.135 ArgoNET

9.136 Aria Networks

9.137 Arista Networks

9.138 Arkessa (Wireless Logic Group)

9.139 Arm

9.140 Armour Communications

9.141 Arqit Quantum

9.142 ArrayComm (Chengdu ArrayComm Wireless Technologies)

9.143 Arrcus

9.144 Artemis Networks

9.145 Artiza Networks

9.146 Aruba (HPE – Hewlett Packard Enterprise)

9.147 Arukona

9.148 Asavie

9.149 ASELSAN

9.150 AsiaInfo Technologies

9.151 AsiaSat (Asia Satellite Telecommunications Company)

9.152 Askey Computer Corporation (ASUS – ASUSTeK Computer)

9.153 ASOCS

9.154 Aspire Technology (NEC Corporation)

9.155 ASR Microelectronics

9.156 Assured Wireless Corporation

9.157 ASTELLA (Astella Technologies)

9.158 ASTRI (Hong Kong Applied Science and Technology Research Institute)

9.159 ASUS (ASUSTeK Computer)

9.160 Asylon

9.161 AT&T

9.162 ATDI

9.163 ATEL (Asiatelco Technologies)

9.164 Atel Antennas

9.165 Atesio

9.166 Athonet

9.167 ATL – A Test Lab (Eurofins E&E – Electrical and Electronics)

9.168 Atlas Telecom

9.169 ATN International

9.170 Atos

9.171 Atrinet

9.172 AttoCore

9.173 Auden Techno

9.174 Auray Technology (Auden Techno)

9.175 Aurora Insight

9.176 Avanti Communications

9.177 Avari Wireless

9.178 AVI

9.179 Aviat Networks

9.180 AVIWEST (Haivision)

9.181 AVM

9.182 AW2S – Advanced Wireless Solutions and Services (SERMA Group)

9.183 AWTG

9.184 Axell Wireless

9.185 AXESS Networks (HISPASAT)

9.186 Axians (VINCI Energies)

9.187 Axiata Group

9.188 Axione

9.189 Axis Communications

9.190 Axon

9.191 Axtel

9.192 Axxcelera Broadband Wireless (Axxcss Wireless Solutions)

9.193 Axxcss Wireless Solutions

9.194 Azcom Technology

9.195 Azetti Networks

9.196 B+B SmartWorx (Advantech)

9.197 BAE Systems

9.198 BAI Communications

9.199 Baicells

9.200 Ball Aerospace

9.201 Ballast Networks

9.202 BandRich

9.203 BandwidthX

9.204 Barrett Communications (Motorola Solutions)

9.205 BATS Wireless (Broadband Antenna Tracking Systems)

9.206 BAYFU (Bayerische Funknetz)

9.207 Baylin Technologies

9.208 BBB (BB Backbone Corporation)

9.209 BBK Electronics

9.210 BCDVideo

9.211 Beam Semiconductor

9.212 Beamlink

9.213 BearCom

9.214 BEC Technologies

9.215 becon

9.216 Beeper Communications

9.217 Beijer Electronics Group

9.218 Belden

9.219 BelFone

9.220 Bell Canada

9.221 Bellantenna

9.222 Benetel

9.223 BesoVideo

9.224 Betacom

9.225 Bharti Airtel

9.226 BHE (Bonn Hungary Electronics)

9.227 BICS (Proximus)

9.228 Billion Electric

9.229 BinnenBereik (NOVEC)

9.230 Bird Technologies

9.231 BISDN (Berlin Institute for Software Defined Networks)

9.232 Bittium

9.233 BK Technologies

9.234 Black & Veatch

9.235 Black Box

9.236 BlackBerry

9.237 Blackned

9.238 BLiNQ Networks (CCI – Communication Components Inc.)

9.239 Blu Wireless

9.240 Blue Arcus Technologies

9.241 Blue Danube Systems (NEC Corporation)

9.242 Blue Wireless

9.243 Bluebird

9.244 Blueforce Development Corporation

9.245 BLUnet Schweiz (Axpo WZ-Systems)

9.246 Boeing/Aurora Flight Sciences

9.247 Boelink (Shanghai Boelink Communication Technology)

9.248 Boingo Wireless (DigitalBridge Group)

9.249 Booz Allen Hamilton

9.250 Boston Dynamics

9.251 Bouygues Telecom

9.252 Boxchip

9.253 Branch Communications

9.254 BravoCom

9.255 Bredengen

9.256 Broadcom

9.257 BroadForward

9.258 Broadmobi – Shanghai Broadmobi Communication Technology (Wutong Group)

9.259 Broadpeak

9.260 BSNL (Bharat Sanchar Nigam Limited)

9.261 BT Group

9.262 BTI Wireless

9.263 Bullitt Mobile

9.264 Bumicom Telecommunicatie

9.265 Bureau Veritas/7Layers

9.266 BVSystems (Berkeley Varitronics Systems)

9.267 BWT (BlueWaveTel)

9.268 B-Yond

9.269 C Spire

9.270 C Squared Systems

9.271 CableFree (Wireless Excellence)

9.272 CableLabs

9.273 CACI International/LGS Innovations

9.274 Cadence Design Systems

9.275 CalAmp

9.276 CalChip Connect

9.277 Caliber Public Safety

9.278 Calix

9.279 Calnex Solutions

9.280 Caltta Technologies

9.281 Cambium Networks

9.282 Cambridge Consultants (Capgemini Invent)

9.283 CampusGenius

9.284 Canoga Perkins

9.285 Canonical

9.286 Capgemini Engineering

9.287 Capita

9.288 CapX Nederland

9.289 Carbyne

9.290 Carlson Wireless Technologies

9.291 Casa Systems

9.292 CASIC (China Aerospace Science and Industry Corporation)

9.293 Casio Computer Company

9.294 Catalyst Communications Technologies

9.295 Cavli Wireless

9.296 CBNG (Cambridge Broadband Networks Group)

9.297 CCI (Communication Components Inc.)

9.298 CCN (Cirrus Core Networks)

9.299 CCS (Cambridge Communication Systems)

9.300 CCww (Communications Consultants Worldwide)

9.301 Cegeka

9.302 CeLa Link Corporation

9.303 Celfinet

9.304 CellAntenna Corporation

9.305 Cellcomm Solutions

9.306 Cellient

9.307 Celling 5G

9.308 CellMax Technologies (Rosenberger)

9.309 Cellnex Telecom

9.310 CellOnyx

9.311 Cellwize (Qualcomm)

9.312 cellXica

9.313 cellXion

9.314 Celona

9.315 CelPlan Technologies

9.316 Centerline Communications

9.317 CENTRA Technology

9.318 CentralSquare Technologies

9.319 Ceragon Networks

9.320 CertusNet

9.321 CETC (China Electronics Technology Group Corporation)

9.322 CEVA

9.323 CGI

9.324 Challenge Networks

9.325 Charter Communications

9.326 Cheerzing (Xiamen Cheerzing IoT Technology)

9.327 Chelton

9.328 Chemring Technology Solutions

9.329 Chengdu NTS

9.330 China All Access

9.331 China Mobile

9.332 China Satcom (China Satellite Communications)

9.333 China Telecom

9.334 China Unicom

9.335 Chunghwa Telecom

9.336 Cibicom

9.337 CICT – China Information and Communication Technology Group (China Xinke Group)

9.338 Ciena Corporation

9.339 CIG (Cambridge Industries Group)

9.340 CIO (Connected IO)

9.341 Cirpack

9.342 Cisco Systems

9.343 Citymesh (Cegeka/DIGI Communications)

9.344 CitySwitch

9.345 CKH IOD (CK Hutchison)

9.346 Clavister

9.347 Clever Logic

9.348 CloudMinds

9.349 CMIoT (China Mobile IoT)

9.350 Cobham

9.351 COCUS

9.352 Codan Communications

9.353 Codium Networks

9.354 Cogisys

9.355 Cognizant

9.356 Cohere Technologies

9.357 Coherent Logix

9.358 Coiler Corporation

9.359 Collinear Networks (EOS – Electro Optic Systems)

9.360 Colt Technology Services

9.361 Com4 (Wireless Logic Group)

9.362 Comarch

9.363 Comba Telecom

9.364 Comcast Corporation

9.365 Comcores

9.366 Comfone

9.367 COMLAB

9.368 CommAgility (Wireless Telecom Group)

9.369 CommandWear Systems

9.370 Comms365

9.371 CommScope

9.372 Compal Electronics

9.373 Comprod

9.374 Comptek Technologies (Aero Wireless Group)

9.375 Comrod Communication Group

9.376 COMSovereign

9.377 Comtech Telecommunications Corporation

9.378 Comtrend Corporation

9.379 Comviva (Tech Mahindra)

9.380 CONET Technologies

9.381 CONEXIO Corporation

9.382 CONGIV (ROBUR Industry Service Group)

9.383 Connect Tech

9.384 Connect44 Group

9.385 Connectivity Wireless Solutions (M/C Partners)

9.386 Contela

9.387 Continual

9.388 Coolpad

9.389 CopaSAT

9.390 coreNOC

9.391 Cornerstone (CTIL)

9.392 Cornet Technology

9.393 Corning

9.394 Cortina Access

9.395 Cosemi Technologies

9.396 COSMOTE (OTE Group)

9.397 Council Rock

9.398 Coweaver

9.399 Cox Communications

9.400 Cradlepoint (Ericsson)

9.401 Creanord

9.402 CrisisGo

9.403 CROSSCALL

9.404 Crown Castle International Corporation

9.405 CS Corporation

9.406 CSG Systems International

9.407 CTG (Celestia Technologies Group)

9.408 CTS (Communication Technology Services)

9.409 CTS Corporation

9.410 Cubic Corporation

9.411 Cubic Telecom

9.412 Cumucore

9.413 Custom MMIC

9.414 CybertelBridge

9.415 Cyient

9.416 Cyrus Technology

9.417 D2 Technologies

9.418 DAEL Group

9.419 Dahua Technology

9.420 Dali Wireless

9.421 DAMM Cellular Systems

9.422 DATACOM

9.423 DataSoft

9.424 DBcom

9.425 DeepSig

9.426 Dejero Labs

9.427 DEKRA

9.428 Dell Technologies

9.429 Delta Electronics

9.430 DENGYO (Nihon Dengyo Kosaku)

9.431 Dense Air (SIP – Sidewalk Infrastructure Partners)

9.432 DGS (Digital Global Systems)

9.433 Dialogic

9.434 Diamond Communications

9.435 Digi International

9.436 Digicert

9.437 Digita (DigitalBridge Group)

9.438 Digital Ally

9.439 Digital Enhancement

9.440 DigitalBridge Group

9.441 DigitalRoute

9.442 Digitata

9.443 DigitGate (Nanjing DigitGate Communication Technology)

9.444 Dimetor

9.445 DISH Network Corporation

9.446 DKK (Denki Kogyo)

9.447 D-Link Corporation

9.448 Doogee

9.449 Doosan Corporation

9.450 DragonWave-X (COMSovereign)

9.451 Drakontas

9.452 DriveNets

9.453 Drone Aviation (COMSovereign)

9.454 DroneSense

9.455 Druid Software

9.456 DSBJ (Suzhou Dongshan Precision Manufacturing)

9.457 DT (Deutsche Telekom)

9.458 DTAC (Total Access Communication)

9.459 du (EITC – Emirates Integrated Telecommunications Company)

9.460 Duons

9.461 Durabook (Twinhead International Corporation)

9.462 Duubee

9.463 DZS

9.464 Eahison Communication

9.465 EANTC

9.466 Eastcom (Eastern Communications)

9.467 Easycom (Shenzhen Easycom Electronics)

9.468 E-Band Communications (Axxcss Wireless Solutions)

9.469 e-BO Enterprises

9.470 ECE (European Communications Engineering)

9.471 EchoStar Corporation

9.472 Ecom Instruments (Pepperl+Fuchs)

9.473 Ecrio

9.474 Edgecore Networks (Accton Technology Corporation)

9.475 EdgeQ

9.476 Edgybees

9.477 edotco Group (Axiata Group)

9.478 EDX Wireless

9.479 Edzcom (Cellnex Telecom)

9.480 Effnet

9.481 Eigencomm

9.482 eino

9.483 EION Wireless

9.484 Eir (Eircom)

9.485 Ekinops

9.486 Elbit Systems

9.487 Elefante Group

9.488 E-Lins Technology

9.489 Elisa

9.490 Elisa Polystar

9.491 Elistair

9.492 Elsight

9.493 Elta Systems (IAI – Israel Aerospace Industries)

9.494 Eltex

9.495 ELUON Corporation

9.496 ELVA-1

9.497 Embraer

9.498 Embratel

9.499 EMnify

9.500 EMS (Electronic Media Services)

9.501 Encore Networks

9.502 Enea

9.503 ENENSYS Technologies

9.504 Energizer Mobile (Avenir Telecom)

9.505 EnerSys

9.506 Entropia

9.507 Entropy Solution

9.508 Eoptolink Technology

9.509 Equiendo

9.510 Eravant (SAGE Millimeter)

9.511 Ericsson

9.512 Errigal

9.513 Eseye

9.514 Esharah Etisalat Security Solutions

9.515 Estalky (K-Mobile Technology)

9.516 ETELM

9.517 eTera (Sinotech R&D Group)

9.518 Ethernity Networks

9.519 Etherstack

9.520 Etisalat Group (e&)

9.521 ETRI (Electronics & Telecommunications Research Institute, South Korea)

9.522 EUCAST

9.523 Eurofins E&E (Electrical and Electronics)

9.524 Eurotech

9.525 Eutelsat Communications

9.526 Eventide Communications

9.527 Exacom

9.528 Exaware

9.529 Excelerate Technology

9.530 EXFO

9.531 Exium

9.532 Expeto

9.533 ExteNet Systems (DigitalBridge Group)

9.534 Extreme Networks

9.535 EY (Ernst & Young)

9.536 Eyecom Telecommunications Group

9.537 EZcon Network

9.538 F2G (Far-Together) Solutions

9.539 F5

9.540 Fairspectrum

9.541 Fairwaves

9.542 Faraday Technology Corporation

9.543 Fastback Networks (COMSovereign)

9.544 FCNT (Fujitsu Connected Technologies)-JEMS (Japan EM Solutions)

9.545 Federal Engineering

9.546 Federated Wireless

9.547 Fenix Group

9.548 FET (Far EasTone Telecommunications)

9.549 FIBERSTAMP

9.550 Fibocom

9.551 Fibrolan

9.552 Filtronic

9.553 Fingu (Wuhan Fingu Electronic Technology)

9.554 Fiplex Communications (Honeywell International)

9.555 Firecell

9.556 Haystax Technology (Fishtech Group/Cyderes)

9.557 Fivecomm

9.558 Flash Networks

9.559 Flash Private Mobile Networks

9.560 Fleet Complete

9.561 Flex

9.562 Flex Logix Technologies

9.563 Flightcell International

9.564 FLIR Systems

9.565 floLIVE

9.566 Flymotion

9.567 FMBE (FMB Engineering)

9.568 Forsk

9.569 Fortinet

9.570 Fortress Solutions

9.571 Four-Faith Communication Technology

9.572 Foxconn (Hon Hai Technology Group)

9.573 Franklin Wireless

9.574 Fraunhofer FOKUS (Institute for Open Communication Systems)

9.575 Fraunhofer HHI (Heinrich Hertz Institute)

9.576 Fraunhofer IIS (Institute for Integrated Circuits)

9.577 Fraunhofer IPT (Institute for Production Technology)

9.578 FreedomFi

9.579 Freeeway

9.580 Frequentis

9.581 Freshwave Group (DigitalBridge Group)

9.582 Frog Cellsat

9.583 FRTek

9.584 FSG (Field Solutions Group)

9.585 FTS – Formula Telecom Solutions (Magic Software Group)

9.586 Fujikura

9.587 Fujitsu

9.588 Funk-Electronic Piciorgros

9.589 Furukawa Electric

9.590 Furuno Electric

9.591 Future Technologies Venture

9.592 G REIGNS (HTC Corporation)

9.593 G+D (Giesecke+Devrient)

9.594 G3 Global

9.595 Galtronics (Baylin Technologies)

9.596 Gamma Nu

9.597 Gapwaves

9.598 Garderos

9.599 Gazprom Space Systems

9.600 GCT Semiconductor

9.601 GD (General Devices)

9.602 GE (General Electric)

9.603 Gemtek Technology

9.604 General Dynamics

9.605 Genesis Group

9.606 GENEViSiO (QNAP Systems)

9.607 Genew Technologies

9.608 Genmix Technology

9.609 GenXComm

9.610 Geotab

9.611 GeoTraq

9.612 Commnet Wireless (ATN International)

9.613 Getac Technology Corporation

9.614 Gewei (Wuhan Gewei Electronic Technology)

9.615 GF (GlobalFoundries)

9.616 GIGABYTE Technology

9.617 Gigalane

9.618 GIGALIGHT

9.619 Gigamon

9.620 GigaTera Communications (KMW)

9.621 GigSky

9.622 Gilat Satellite Networks

9.623 GL Communications

9.624 Global Telecom

9.625 Globalgig

9.626 Globalstar

9.627 Globe Telecom

9.628 GNConnect (Greenet)

9.629 Goodman Telecom Services

9.630 Goodmill Systems

9.631 Google (Alphabet)

9.632 Goosetown Communications

9.633 Gore (W. L. Gore & Associates)

9.634 GosuncnWelink Technology (Gosuncn Group)

9.635 Granite Telecommunications

9.636 Grape One (Sumitomo Corporation)

9.637 Green Communications

9.638 Green Packet

9.639 GreenPalm (Hangzhou GreenPalm Technology)

9.640 GrenTech

9.641 GridGears

9.642 Groundhog Technologies

9.643 GroupTalk

9.644 GS Lab (Great Software Laboratory)

9.645 GSI (GS Instech)/GST (GS Teletech)

9.646 Guavus (Thales)

9.647 Guerrilla RF

9.648 HAAS Alert

9.649 Haier

9.650 Haivision

9.651 Halys

9.652 Hancom MDS

9.653 Handheld Group

9.654 Handsfree Group

9.655 Hansen Technologies

9.656 Hanswell

9.657 Hanwha Techwin

9.658 HAPSMobile

9.659 HARMAN DTS (Digital Transformation Solutions)

9.660 Harvilon (Shenzhen Harvilon Technology)

9.661 Hawk Networks (Althea)

9.662 HBFEC (Hebei Far East Communication System Engineering)

9.663 HCL Technologies

9.664 Helios (Fujian Helios Technologies)

9.665 Hengxin (Jiangsu Hengxin Technology)

9.666 Henkel

9.667 Herystorm (Guangzhou Herystorm Technology)

9.668 Hexagon

9.669 Hexagon Communication (Suzhou Hexagon Communication Technologies)

9.670 HFCL

9.671 HFR Networks

9.672 HG Genuine (HGTECH – Huagong Technology)

9.673 Highstreet Technologies

9.674 Hikvision (Hangzhou Hikvision Digital Technology)

9.675 Hilinks Technology

9.676 HipLink Software

9.677 Hisense

9.678 HiSilicon Technologies (Huawei)

9.679 HISPASAT

9.680 Hitachi

9.681 HKT (PCCW)

9.682 HKTech (Howking Tech)

9.683 HMD Global

9.684 HMF (Hytera Mobilfunk)

9.685 HMS Networks

9.686 Hologram

9.687 Honeywell International

9.688 Hongdian Corporation

9.689 HONOR

9.690 Hoverfly Technologies

9.691 HP

9.692 HPE (Hewlett Packard Enterprise)

9.693 HQT (Shenzhen HQT Science and Technology)

9.694 HSC (Hughes Systique Corporation)

9.695 HTC Corporation

9.696 Huahuan (Beijing Huahuan Electronics)

9.697 Huaptec

9.698 Huawei

9.699 HUBER+SUHNER

9.700 HUCOM Wireless

9.701 Hughes Network Systems (EchoStar Corporation)

9.702 HXI (Renaissance Electronics & Communications)

9.703 Hypha (Wireless Innovation)

9.704 Hytec Inter

9.705 Hytera Communications

9.706 i.safe MOBILE

9.707 i2i Systems

9.708 iBASIS (Tofane Global)

9.709 IBM

9.710 IBO Technology Company

9.711 iBwave Solutions

9.712 iCana (Foxconn – Hon Hai Technology Group)

9.713 Ice Norway (Lyse)

9.714 Icom

9.715 Iconec

9.716 iConNext

9.717 iDAQS

9.718 IDEMIA

9.719 IDY Corporation

9.720 IFLY Electronics

9.721 IIJ (Internet Initiative Japan)

9.722 II-VI

9.723 IM Technology

9.724 Imec

9.725 IMPTT

9.726 InCoax Networks

9.727 Indra

9.728 INEX Microtechnology

9.729 Infineon Technologies

9.730 Infinera

9.731 InfiNet Wireless

9.732 Infinite Electronics

9.733 Infomark Corporation

9.734 Infosys

9.735 Infovista

9.736 InHand Networks

9.737 Inmanta

9.738 Inmarsat

9.739 Innertron

9.740 InnoGence Technology (TROY Information)

9.741 InnoLight Technology

9.742 Innonet

9.743 Innovile

9.744 InnoWireless

9.745 Inrico Technologies

9.746 Inseego Corporation

9.747 Inspur

9.748 Insta Group

9.749 Instant Connect

9.750 INSYS icom (INSYS Microelectronics)

9.751 Intec E&C

9.752 Intel Corporation

9.753 Intelliport Solutions

9.754 Intelsat

9.755 Intenna Systems

9.756 InterDigital

9.757 INTERLEV

9.758 Interop Technologies

9.759 InterTalk Critical Information Systems

9.760 Intracom Telecom

9.761 Intrado Corporation

9.762 Intrepid Networks

9.763 Inventec Corporation

9.764 INWIT (Infrastrutture Wireless Italiane)

9.765 IoT4Net

9.766 IoTAS (IoT & Approval Solutions)

9.767 IP Infusion (ACCESS CO.)

9.768 IPAGEON

9.769 IPITEK (Integrated Photonics Technology)

9.770 IPLOOK Technologies

9.771 iPosi

9.772 Iradio Electronics

9.773 Iridium Communications

9.774 ISCO International

9.775 Iskratel (S&T Group)

9.776 IS-Wireless

9.777 Italtel

9.778 ITCEN

9.779 ITRI (Industrial Technology Research Institute, Taiwan)

9.780 Jabil

9.781 JACS Solutions

9.782 JATONTEC (Jaton Technology)

9.783 JCI (Japan Communications Inc.)

9.784 Jezetek (Sichuan Jiuzhou Electric Group)

9.785 Jiaxun Feihong (Beijing Jiaxun Feihong Electrical)

9.786 Jinan USR IoT Technology (Mokuai/Wenheng)

9.787 JIT (JI Technology)

9.788 JMA Wireless

9.789 JOUAV

9.790 JPC Connectivity

9.791 JPS Interoperability Solutions

9.792 JQL Technologies

9.793 JRC (Japan Radio Company)

9.794 JSC Ingenium

9.795 JT IoT

9.796 Juniper Networks

9.797 Junkosha

9.798 Juvare

9.799 JVCKENWOOD Corporation

9.800 Kacific Broadband Satellites

9.801 Kaelus

9.802 Kajeet

9.803 Kaloom

9.804 Kalray

9.805 Katela Networks

9.806 Kathrein Mobile Communication (Ericsson)

9.807 KBR

9.808 KBT (Kenbotong Technology)

9.809 KDDI Corporation

9.810 Key Bridge Wireless

9.811 Keysight Technologies

9.812 Kiana Analytics

9.813 Kigen

9.814 Kindroid – Shanghai Jinzhuo Technology (Kyland Technology)

9.815 Kirisun Communications

9.816 Kisan Telecom

9.817 KLA Laboratories

9.818 Klas Telecom

9.819 Klein Electronics

9.820 Kleos

9.821 KMW

9.822 Knightscope

9.823 Kontron Transportation (S&T Group)

9.824 KORE Wireless

9.825 KPN

9.826 KT Corporation

9.827 Kudelski Group

9.828 Kumu Networks

9.829 Kyland Technology

9.830 Kymeta Corporation

9.831 Kyndryl

9.832 Kyocera Corporation

9.833 Kyrio (CableLabs)

9.834 KZ TECH (KZ Broadband Technologies)

9.835 L3Harris Technologies

9.836 Laird Connectivity

9.837 Landmark Dividend (DigitalBridge Group)

9.838 Lanner Electronics

9.839 Lantronix

9.840 Lattice Semiconductor

9.841 LCR Embedded Systems

9.842 Leenos Corporation

9.843 Leidos

9.844 Lekha Wireless Solutions

9.845 Lemko Corporation

9.846 Lenovo

9.847 Leonardo

9.848 Lextrum (COMSovereign)

9.849 LG Corporation

9.850 LG Uplus

9.851 Lierda Science & Technology Group

9.852 Lifecycle Software

9.853 Ligado Networks

9.854 Lightron

9.855 Lime Microsystems

9.856 Lindsay Broadband

9.857 Linkem

9.858 Linksys

9.859 Linx Technologies

9.860 LIONS Technology

9.861 Lisheng Fujian Communications

9.862 LITE-ON Technology Corporation

9.863 LitePoint (Teradyne)

9.864 LiveU

9.865 Lociva

9.866 Lockheed Martin Corporation

9.867 Logicalis (Datatec)

9.868 LogicTree IT Solutions

9.869 Longsung Technology (Sunsea AIoT Technology)

9.870 Lookout

9.871 LS Mtron

9.872 LS telcom

9.873 LTTS (L&T Technology Services)

9.874 Luceor

9.875 Lumen Technologies

9.876 Lumentum

9.877 Lumineye

9.878 LuxCarta

9.879 Luxoft (DXC Technology)

9.880 Lyfo

9.881 Lynk Global (Ubiquitilink)

9.882 M1

9.883 m3connect

9.884 M4PS (Mobility 4 Public Safety)

9.885 M87 (XCOM Labs)

9.886 MACOM

9.887 Magnaquest Technologies

9.888 Maipu Communication Technology

9.889 Maja Systems

9.890 MantisNet

9.891 MarchNet

9.892 Marlink

9.893 Marquistech

9.894 Martin UAV

9.895 Marubeni Corporation

9.896 Marubun Corporation

9.897 Marvell Technology

9.898 MÁSMÓVIL

9.899 Mathworks

9.900 Matrix Electrónica/Webdyn (Flexitron Group)

9.901 MATRIXX Software

9.902 MatSing

9.903 Maven Wireless

9.904 Mavenir

9.905 MaxComm

9.906 Maxim Integrated (ADI – Analog Devices, Inc.)

9.907 Maxis

9.908 MaxLinear

9.909 MC Technologies

9.910 MCP (Mission Critical Partners)

9.911 MCS Benelux

9.912 MD (MICRODRIVE)

9.913 Mdex (Wireless Logic Group)

9.914 MEASAT Satellite Systems

9.915 MECSware

9.916 Media Broadcast (freenet Group)

9.917 MediaTek

9.918 Meeami Technologies

9.919 MegaChips Corporation

9.920 MegaFon

9.921 MeiG Smart Technology

9.922 Meizu

9.923 Mentura Group

9.924 MER Group

9.925 Meta Connectivity

9.926 Metanoia Communications

9.927 Metaswitch Networks (Microsoft Corporation)

9.928 Metawave Corporation

9.929 Metismake

9.930 MetTel

9.931 MHD (Muhan Digital)

9.932 MIC Nordic

9.933 MICAS-RF (MICAS Shenzhen Telecommunication)

9.934 MiCOM Labs

9.935 Micran

9.936 Microamp Solutions

9.937 Microchip Technology

9.938 Microlab (RF Industries)

9.939 MicroNova

9.940 Microsoft Corporation

9.941 Microwave Networks

9.942 MikroTik

9.943 Mikwave (Guangdong Mikwave Communication Tech)

9.944 Milesight

9.945 Milestone Systems

9.946 Miliwave

9.947 MiMOMax

9.948 MIPS

9.949 MiTAC Computing Technology Corporation

9.950 MitraStar Technology (Unizyx Holding Corporation)

9.951 MITRE Corporation

9.952 Mitsubishi Electric Corporation

9.953 MixComm (Sivers Semiconductors)

9.954 MKI (Mitsui Knowledge Industry)

9.955 MOBI (Mobi Antenna Technologies)

9.956 Mobile Mark

9.957 Mobile Tornado

9.958 Mobile Viewpoint

9.959 MobileDemand

9.960 MobiledgeX (Google)

9.961 MobileIron

9.962 MobileTek (Shanghai Mobiletek Communication)

9.963 Mobileum

9.964 Mobilicom

9.965 Mobilitie (BAI Communications)

9.966 Mobilogix (Telit)

9.967 Mobiveil

9.968 Molex

9.969 Monogoto

9.970 Morningcore Technology (CICT – China Information and Communication Technology Group)

9.971 Morningstar Corporation

9.972 Moseley Associates (Axxcss Wireless Solutions)

9.973 MosoLabs (Sercomm Corporation)

9.974 Motive Infrastructure Solutions

9.975 Motorola Mobility (Lenovo)

9.976 Motorola Solutions

9.977 Mott MacDonald

9.978 Movandi

9.979 Moxa

9.980 MP Antenna

9.981 MRK Media

9.982 MRT Technology (Suzhou)

9.983 MSB (M S Benbow & Associates)

9.984 MTI (Microelectronics Technology Inc.)

9.985 MTI Wireless Edge

9.986 MTN Group

9.987 MTS (Mobile TeleSystems)

9.988 MUGLER

9.989 MultiTech (Multi-Tech Systems)

9.990 Murata Manufacturing

9.991 Mushroom Networks

9.992 Mutualink

9.993 MVI Group

9.994 MYCOM OSI (Amdocs)

9.995 Mynaric

9.996 MYT Electronics

9.997 N.A.T.

9.998 Nable Communications

9.999 NanoSemi (MaxLinear)

9.1000 Napatech

9.1001 Nash Technologies

9.1002 Nearby Computing

9.1003 NEC Corporation

9.1004 Nemergent Solutions

9.1005 Nemko

9.1006 Neolink Communications Technology

9.1007 Neoway Technology

9.1008 Neptune Communications

9.1009 Neragon Networks

9.1010 Net AI

9.1011 Netaş

9.1012 NETBEE (NET-Automation)

9.1013 Netcracker Technology (NEC Corporation)

9.1014 NetFoundry

9.1015 Netgear

9.1016 NetModule (Belden)

9.1017 Netmore Group

9.1018 NETSCOUT Systems

9.1019 Netsia (Argela)

9.1020 Netvision Telecom

9.1021 Neutral Wireless

9.1022 Neutroon Technologies

9.1023 New H3C Technologies (Tsinghua Unigroup)

9.1024 New Postcom Equipment

9.1025 NewEdge Signal Solutions

9.1026 NEXCOM International

9.1027 Nexign

9.1028 Nexpring

9.1029 Nextivity

9.1030 NextNav

9.1031 Nextworks

9.1032 ng4T

9.1033 NGK Group (NGK Insulators)

9.1034 ng-voice

9.1035 NI (National Instruments)

9.1036 NICE

9.1037 NimbeLink

9.1038 Niral Networks

9.1039 Nitto Denko Corporation

9.1040 NKG (New Kinpo Group)

9.1041 Node-H

9.1042 Nokia

9.1043 Nordic Semiconductor

9.1044 Northrop Grumman Corporation

9.1045 NOTION Information Technology

9.1046 Nova Labs (Helium)

9.1047 NOVEC

9.1048 NOVELSAT

9.1049 NRB (Network Research Belgium)

9.1050 NS Solutions Corporation

9.1051 Nsight

9.1052 NT (National Telecom)

9.1053 NTMore (Network Technology More)

9.1054 NTT DoCoMo

9.1055 NTT Group

9.1056 Nubia Technology (ZTE)

9.1057 NuRAN Wireless

9.1058 Nurlink Technology

9.1059 NVIDIA Corporation

9.1060 NXP Semiconductors

9.1061 Oasis Smart SIM

9.1062 Oceus Networks

9.1063 Octasic

9.1064 O-Cubes

9.1065 ODN (Orbital Data Network)

9.1066 OE Solutions

9.1067 OFS Fitel (Furukawa Electric)

9.1068 OKI Electric Industry

9.1069 Omnitele

9.1070 Omnitron Systems

9.1071 Omnitronics

9.1072 One2many (Everbridge)

9.1073 OneLayer

9.1074 OnePlus (BBK Electronics)

9.1075 OneSimCard

9.1076 OneWeb

9.1077 Onomondo

9.1078 Ontix

9.1079 Onwave

9.1080 Ooredoo

9.1081 Opanga Networks

9.1082 Open Valley

9.1083 Opencode Systems

9.1084 Openet (Amdocs)

9.1085 OPPO (BBK Electronics)

9.1086 O’Prueba Technology

9.1087 OPTAGE

9.1088 OptConnect

9.1089 Optical Zonu Corporation

9.1090 Opticoms

9.1091 Option (Crescent)

9.1092 Optiva

9.1093 Oracle Communications

9.1094 Orange

9.1095 ORBCOMM

9.1096 Ori Industries

9.1097 Orion Labs

9.1098 Oscilloquartz (ADVA)

9.1099 OV (Manx Telecom)

9.1100 OVHcloud

9.1101 P.I. Works

9.1102 PacStar (Pacific Star Communications)

9.1103 Padtec

9.1104 Palo Alto Networks

9.1105 Panasonic Corporation

9.1106 Panda Electronics

9.1107 PanOptis

9.1108 Panorama Antennas

9.1109 Parallel Wireless

9.1110 Parsec Technologies

9.1111 Particle

9.1112 PAStech

9.1113 Patrocinium Systems

9.1114 Patton

9.1115 Pavlov Media

9.1116 PCS Technologies

9.1117 PCTEL

9.1118 PCTEST Lab (PCTEST Engineering Laboratory)

9.1119 Peatalk Corporation

9.1120 Pegatron Corporation

9.1121 Pei Tel Communications

9.1122 Pelion

9.1123 Penguin Solutions (SGH – SMART Global Holdings)

9.1124 Pente Networks

9.1125 Peplink (Plover Bay Technologies)

9.1126 Pepro

9.1127 Peraso

9.1128 Peraton Labs (Perspecta Labs)

9.1129 Percepto

9.1130 Perle Systems

9.1131 Pharrowtech

9.1132 Phirst Technologies/xCraft Enterprises

9.1133 Phluido

9.1134 Phytium Technology (Tianjin Phytium Information Technology)

9.1135 PHYTunes

9.1136 Picocom

9.1137 Pierson Wireless

9.1138 Pivot Technology Services

9.1139 Pivotal Commware

9.1140 Pivotel Group

9.1141 Pivotone

9.1142 Pixavi (BARTEC)

9.1143 Platform9

9.1144 Pletronics

9.1145 Plextek

9.1146 Plintron

9.1147 Plus (Polkomtel)

9.1148 POCSTARS

9.1149 Pod Group (G+D – Giesecke+Devrient)

9.1150 Polaris Networks (Motorola Solutions)

9.1151 Polaris Wireless

9.1152 Pollen Mobile

9.1153 Polte

9.1154 Positron Access Solutions

9.1155 Potevio (CETC – China Electronics Technology Group Corporation)

9.1156 PPC Broadband (Belden)

9.1157 Precision OT (Optical Transceivers)

9.1158 PRESCOM

9.1159 PrioCom

9.1160 Proef

9.1161 Proptivity

9.1162 Proscend Communications

9.1163 PROSE Technologies (Rosenberger)

9.1164 PROTEI

9.1165 Proxim Wireless Corporation (SRA Holdings)

9.1166 Proximus

9.1167 Pryme Radio Products

9.1168 pSemi Corporation (Murata Manufacturing)

9.1169 PT INTI (PT Industri Telekomunikasi Indonesia)

9.1170 PT LEN Industri

9.1171 PTI (Persistent Telecom Inc.)

9.1172 Publicis Sapient

9.1173 Pulsara

9.1174 Pulse Electronics (YAGEO Corporation)

9.1175 Pycom

9.1176 QCT (Quanta Cloud Technology)

9.1177 Qinetiq

9.1178 Qorvo

9.1179 QuadGen Wireless Solutions

9.1180 Qualcomm

9.1181 Quanta Computer

9.1182 Quantum Wireless

9.1183 Qucell Networks (InnoWireless)

9.1184 Quectel Wireless Solutions

9.1185 Quintel (Cirtek Holdings Philippines Corporation)

9.1186 Qulsar

9.1187 Quortus (CradlePoint)

9.1188 Qwake Technologies

9.1189 Qwilt

9.1190 R Systems (Computaris International)

9.1191 RACOM (Czech Republic)

9.1192 RACOM Corporation

9.1193 RAD

9.1194 RADCOM

9.1195 Radiall

9.1196 Radio Gigabit

9.1197 Radio IP Software

9.1198 RadioMobile

9.1199 Radisys (Reliance Industries)

9.1200 RADTONICS

9.1201 Radware

9.1202 RADWIN

9.1203 Rafael Advanced Defense Systems

9.1204 Raisecom

9.1205 Rajant Corporation

9.1206 Rakon

9.1207 Rakuten Symphony

9.1208 Range Networks (AMN – Africa Mobile Networks)

9.1209 Ranger Systems

9.1210 Ranplan Wireless

9.1211 Rapid.Space (Nexedi)

9.1212 RapidDeploy

9.1213 RapidSOS

9.1214 Rapidtek Technologies

9.1215 Rave Mobile Safety

9.1216 Raycap

9.1217 Raytheon Technologies Corporation

9.1218 RCS Telecommunications

9.1219 Ready Wireless

9.1220 Realme (BBK Electronics)

9.1221 Red Hat (IBM)

9.1222 Red Lion Controls (Spectris)

9.1223 RED Technologies

9.1224 REDCOM Laboratories

9.1225 Redline Communications (Aviat Networks)

9.1226 RedZinc

9.1227 Reliance Jio Infocomm (Jio Platforms)

9.1228 REMEC Broadband Wireless Networks (Bridgewave Communications/SAGE SatCom)

9.1229 Renesas Electronics Corporation

9.1230 REPLY

9.1231 Rescue 42

9.1232 Responder Corp

9.1233 RF Connect

9.1234 RF DSP

9.1235 RF Industries

9.1236 RF MORECOM

9.1237 RF Window

9.1238 RFHIC Corporation

9.1239 RFI Technology Solutions

9.1240 RFS (Radio Frequency Systems)

9.1241 RFTech

9.1242 Ribbon Communications

9.1243 Ricon Mobile

9.1244 Rivada Networks

9.1245 Rivada Space Networks

9.1246 RKTPL (RK Telesystem Private Limited)

9.1247 Robert Bosch

9.1248 Robin.io (Rakuten Symphony)

9.1249 Robustel

9.1250 Rogers Communications

9.1251 Rogers Corporation

9.1252 Rohde & Schwarz

9.1253 Rohill

9.1254 Rolling Wireless (Fibocom)

9.1255 Rosenberger

9.1256 Royole Corporation

9.1257 RSCC (Russian Satellite Communications Company)

9.1258 RSConnect

9.1259 RTX A/S

9.1260 RTx Technology

9.1261 RugGear

9.1262 RuggON Corporation

9.1263 Ruijie Networks

9.1264 RunEL

9.1265 Rushmere Technology

9.1266 Saab

9.1267 Saankhya Labs (Tejas Networks)

9.1268 SABIC

9.1269 SAC Wireless (Nokia)

9.1270 SAF Tehnika

9.1271 Safe-Com Wireless

9.1272 SafeMobile

9.1273 Sagemcom

9.1274 SageRAN (Guangzhou SageRAN Technology)

9.1275 Saguna Networks (COMSovereign)

9.1276 SAI Technology

9.1277 SAIC (Science Applications International Corporation)

9.1278 Samji Electronics

9.1279 Samsung

9.1280 SAMWON FA

9.1281 Samyoung Celetra

9.1282 Sandvine

9.1283 Sanechips Technology (ZTE)

9.1284 Sanjole

9.1285 San-tron

9.1286 Sasken Technologies

9.1287 SaskTel

9.1288 SatixFy

9.1289 Savox Communications

9.1290 SBA Communications

9.1291 Sceye

9.1292 Seamless Waves

9.1293 Sectra Communications

9.1294 Secured Communications

9.1295 SecureG

9.1296 Select Spectrum

9.1297 SEMPRE

9.1298 Semtech Corporation

9.1299 Senko Advanced Components

9.1300 Sensorview

9.1301 Senstar Corporation

9.1302 Sentinel Camera Systems

9.1303 Seong Ji Industrial

9.1304 SEONTECH

9.1305 Seowon Intech

9.1306 Sepura

9.1307 Sequans Communications

9.1308 Sercomm Corporation

9.1309 SES

9.1310 SETUP Protokolltester

9.1311 SGS

9.1312 Shannon Wireless (Zhejiang Shannon Communication Technology)

9.1313 Shared Access

9.1314 Sharp Corporation (Foxconn – Hon Hai Technology Group)

9.1315 Shenglu (Guangdong Shenglu Telecommunication)

9.1316 Shenzhen CXD Science & Technology

9.1317 Shenzhen Recoda Technologies

9.1318 SIAE Microelettronica

9.1319 Siemens

9.1320 Sierra Wireless (Semtech Corporation)

9.1321 Sigma Wireless

9.1322 Signalchip

9.1323 Signalwing

9.1324 Siklu

9.1325 Silicom Connectivity Solutions

9.1326 Silicom SAS (France)

9.1327 SIMCom Wireless Solutions (Sunsea AIoT Technology)

9.1328 Simnovus

9.1329 Simoco Wireless Solutions

9.1330 Sinclair Technologies (Norsat International/Hytera Communications)

9.1331 Singtel

9.1332 Sinnwell (audius)

9.1333 SIRADEL

9.1334 siticom (Logicalis)

9.1335 SiTime Corporation

9.1336 SITRONICS (Sistema)

9.1337 SiTune Corporation

9.1338 Sivers Semiconductors

9.1339 Siyata Mobile

9.1340 SK Telecom

9.1341 SK Telesys

9.1342 Skoltech (Skolkovo Institute of Science and Technology)

9.1343 SKY Perfect JSAT

9.1344 Skylark Wireless

9.1345 Tele2 Russia (Rostelecom)

9.1346 Skylo Technologies

9.1347 Skyvera (TelcoDR)

9.1348 Skyworks Solutions

9.1349 SLA Corporation

9.1350 SM Optics (SIAE Microelettronica)

9.1351 Smart Communications (PLDT)

9.1352 Smart Mobile Labs

9.1353 Smartfren

9.1354 SmarTone

9.1355 SMAWave (Shanghai SMAWave Technology)

9.1356 Socionext

9.1357 SoftBank Group

9.1358 Softil

9.1359 Soitec

9.1360 Solectek Corporation/Cielo Networks

9.1361 SOLiD

9.1362 Solidtronic

9.1363 Soliton Systems

9.1364 Sonim Technologies

9.1365 Sony Group Corporation

9.1366 Sooktha

9.1367 Soracom

9.1368 Source Photonics

9.1369 Southern Linc

9.1370 Space Data Corporation

9.1371 SpaceBridge

9.1372 Spacecom

9.1373 SpaceX

9.1374 Spark New Zealand

9.1375 Spectra Group

9.1376 SpectraRep

9.1377 Spectre (Rostec)

9.1378 Spectronite

9.1379 Spectronn

9.1380 Spectrum Effect

9.1381 Speedcast

9.1382 Spideradio (Suzhou Spideradio Telecommunication Technology)

9.1383 SPIE Group

9.1384 Spirent Communications

9.1385 SPIRIT DSP

9.1386 SPL (Stratospheric Platforms Limited)

9.1387 Sporton International

9.1388 SQUAN

9.1389 SRS (Software Radio Systems)

9.1390 SRTechnology

9.1391 SSC (Shared Spectrum Company)

9.1392 ST (STMicroelectronics)

9.1393 ST Engineering iDirect

9.1394 Star Microwave

9.1395 Star Solutions

9.1396 StarHub

9.1397 StarPoint (Beijing StarPoint Technology)

9.1398 STC (Saudi Telecom Company)

9.1399 Steep

9.1400 STEP CG

9.1401 STL (Sterlite Technologies Ltd.)

9.1402 Stop Noise

9.1403 Streambox

9.1404 Streamwide

9.1405 Subex

9.1406 Sumitomo Electric Industries

9.1407 Summa Networks

9.1408 Summit Tech

9.1409 Sunrise UPC (Liberty Global)

9.1410 Sunsea AIoT Technology

9.1411 Sunwave Communications

9.1412 Supermicro (Super Micro Computer)

9.1413 SureSite Consulting Group

9.1414 SUSE

9.1415 Swisscom

9.1416 Swissphone

9.1417 Sylincom (Beijing Sylincom Technology)

9.1418 Synctechno

9.1419 Syniverse

9.1420 SYRTEM

9.1421 Systech Corporation

9.1422 System Innovation Group

9.1423 Systemics-PAB

9.1424 T&W (Shenzhen Gongjin Electronics)

9.1425 T2M

9.1426 TacSat Networks

9.1427 Tait Communications

9.1428 Taiwan Mobile

9.1429 TAIYO YUDEN

9.1430 Talia Communications (Commercis)

9.1431 Talk-IP International

9.1432 Talkpod Technology

9.1433 Tambora Systems

9.1434 Tampa Microwave (Thales)

9.1435 Tango Networks

9.1436 Tango Tango

9.1437 Taoglas

9.1438 Tarana Wireless

9.1439 TASSTA

9.1440 Tata Elxsi

9.1441 Tatfook (Shenzhen Tatfook Technology)

9.1442 TCL Communication

9.1443 TCOM

9.1444 TCS (Tata Consultancy Services)

9.1445 TD Tech

9.1446 TDC NET

9.1447 TE Connectivity

9.1448 Teal Communications

9.1449 Tech Mahindra

9.1450 Techbros

9.1451 Technicolor

9.1452 Tecom

9.1453 Tecore Networks

9.1454 Tejas Networks

9.1455 TEKTELIC Communications

9.1456 Telco Systems (BATM Advanced Communications)

9.1457 Telcoware

9.1458 Teldat

9.1459 Tele2

9.1460 Teleena (Tata Communications MOVE)

9.1461 Telefield

9.1462 Telefónica Group

9.1463 Telekom Slovenije

9.1464 Telenet

9.1465 Telenor Group

9.1466 Telent

9.1467 Telesat

9.1468 Telespazio (Leonardo/Thales)

9.1469 Teleste

9.1470 Telet Research

9.1471 Televate

9.1472 Telewave

9.1473 Teleworld Solutions (Samsung)

9.1474 Telia Company

9.1475 Telit

9.1476 Telkomsel

9.1477 Tellabs

9.1478 Tellion

9.1479 Telna

9.1480 TELNET Redes Inteligentes

9.1481 TELOX (Telo Systems)

9.1482 Telrad Networks

9.1483 Telsasoft

9.1484 Telstra

9.1485 Teltonika

9.1486 Teltronic (Hytera Communications)

9.1487 Telus

9.1488 TEOCO

9.1489 Teracom

9.1490 Teradek

9.1491 TeraGo

9.1492 Tera-Pass

9.1493 Tessares

9.1494 TESSCO Technologies/Ventev

9.1495 Thaicom

9.1496 Thales

9.1497 ThinkRF

9.1498 Three Private Networks (Three UK/CK Hutchison)

9.1499 Thundercomm

9.1500 TI (Texas Instruments)

9.1501 Tianyi (Sichuan Tianyi Comheart Telecom)

9.1502 Tibco Telecoms

9.1503 TietoEVRY

9.1504 Tillman Global Holdings

9.1505 Tilson

9.1506 TIM (Telecom Italia Mobile)

9.1507 Titan ICT

9.1508 Titan.ium Platform (Formerly NetNumber)

9.1509 TJ Innovation

9.1510 TLC Solutions

9.1511 TM (Telekom Malaysia)

9.1512 T-Mobile US

9.1513 TMYTEK (TMY Technology)

9.1514 TNS (Transaction Network Services)

9.1515 TO21COMMS

9.1516 Tofane Global

9.1517 TOKIE (Irvees Technology)

9.1518 TOMIA

9.1519 Tongyu Communication

9.1520 Toshiba Corporation

9.1521 Totogi

9.1522 TowerJazz

9.1523 TPG Telecom

9.1524 TPL Systèmes

9.1525 TP-Link Technologies

9.1526 Transatel (NTT Group)

9.1527 Transit Wireless (BAI Communications)

9.1528 TransPacket

9.1529 TriaSys Technologies Corporation

9.1530 TRIOPT

9.1531 Trópico (CPQD – Center for Research and Development in Telecommunications, Brazil)

9.1532 TrueMove H (True Corporation)

9.1533 Truphone

9.1534 TRX Systems

9.1535 TSMC (Taiwan Semiconductor Manufacturing Company)

9.1536 Tsofun

9.1537 TST Systems (Thorcom Systems/Sonic Communications/Tioga Electronic Assembly)

9.1538 T-Systems International

9.1539 TTG International

9.1540 TTM Technologies

9.1541 Tupl

9.1542 Türk Telekom

9.1543 Turkcell

9.1544 TUSUR (Tomsk State University of Control Systems and Radioelectronics)

9.1545 TÜV SÜD

9.1546 Twilio

9.1547 Two Six Labs

9.1548 Tyler Technologies

9.1549 U.S. Cellular

9.1550 UANGEL

9.1551 UBCS

9.1552 Ubicquia

9.1553 Ubiik

9.1554 UBiqube

9.1555 Ubiquoss

9.1556 Ubiwhere

9.1557 U-Blox

9.1558 Ucloudy (Shanghai Ucloudy Information Technology)

9.1559 UCtel

9.1560 UfiSpace

9.1561 UL

9.1562 ULAK Communication

9.1563 Ultraband Technologies

9.1564 UMC (United Microelectronics Corporation)

9.1565 Umlaut (Accenture)

9.1566 UMS (United Monolithic Semiconductors)

9.1567 UNIMO Technology

9.1568 UNISOC (Tsinghua Unigroup)

9.1569 UniStrong

9.1570 UNITAC Technology

9.1571 UROS

9.1572 URSYS

9.1573 US Digital Designs

9.1574 USI (Universal Scientific Industrial)

9.1575 Utility (Utility Associates)

9.1576 UTStarcom

9.1577 V&M (Venus & Mercury) Telecom

9.1578 V5 Systems

9.1579 Valid (Brazil)

9.1580 Valid8

9.1581 Vantage Towers

9.1582 Vanu

9.1583 Vapor IO

9.1584 Vavitel (Shenzhen Vavitel Technology)

9.1585 VDI (Virginia Diodes, Inc.)

9.1586 Vector Data

9.1587 Veea

9.1588 VEON

9.1589 Verana Networks

9.1590 Verizon Communications

9.1591 Verkotan

9.1592 Versa Networks

9.1593 Vertel

9.1594 Vertical Bridge (DigitalBridge Group)

9.1595 Vertiv

9.1596 Verveba Telecom

9.1597 VHT (Viettel High Tech)

9.1598 Viasat

9.1599 VIAVI Solutions

9.1600 VIDA Technologies

9.1601 Vigilate

9.1602 Vilicom (BAI Communications)

9.1603 VinSmart (Vingroup)

9.1604 Viper RF

9.1605 Viprinet

9.1606 ViPRO Corporation

9.1607 Virtual Access (Westermo Network Technologies)

9.1608 Virtusa Corporation

9.1609 Vislink Technologies

9.1610 Visual Labs

9.1611 Vital (New Zealand)

9.1612 VITES

9.1613 Vivo (BBK Electronics)

9.1614 VMware

9.1615 VNC – Virtual NetCom (COMSovereign)

9.1616 VNL – Vihaan Networks Limited (Shyam Group)

9.1617 Vodacom Group

9.1618 Vodafone Group

9.1619 VoiceAge Corporation

9.1620 Voipfuture

9.1621 Voxer

9.1622 VTT Technical Research Centre of Finland

9.1623 Vubiq Networks

9.1624 VVDN Technologies

9.1625 WAV4M

9.1626 WAVE (AGC)

9.1627 Wave1

9.1628 Wave-In Communication

9.1629 Wavelabs

9.1630 Wavesight

9.1631 Wavetel Technology

9.1632 Waycare

9.1633 WCCTV (Wireless CCTV)

9.1634 WDNA (Wireless DNA)

9.1635 Weaccess Group

9.1636 WebRadar

9.1637 Westell Technologies

9.1638 Wevercomm

9.1639 Wewins (Shenzhen Wewins Wireless)

9.1640 wgtwo (Working Group Two)

9.1641 WH Bence Group

9.1642 Whale Cloud Technology (Alibaba Group)

9.1643 Whizz Systems

9.1644 Widelity

9.1645 WIG (Wireless Infrastructure Group)

9.1646 Wildox (Shenzhen Happy Technology)

9.1647 Wilson Electronics

9.1648 Wilus

9.1649 WIN Connectivity (Wireless Information Networks)

9.1650 Wind River

9.1651 Wind Tre

9.1652 Wingtech Technology

9.1653 WINITECH

9.1654 Winmate Communications

9.1655 Winncom Technologies

9.1656 Wipro

9.1657 Wireless Logic Group

9.1658 Wireless Technologies Finland

9.1659 Wireless Telecom Group

9.1660 WiSig Networks

9.1661 Wistron Corporation

9.1662 Wiwynn (Wistron Corporation)

9.1663 WM Systems

9.1664 WNC (Wistron NeWeb Corporation)

9.1665 Wolfspeed

9.1666 WooriNet

9.1667 Workz

9.1668 World View

9.1669 WorldCell Solutions

9.1670 Wouxun (Quanzhou Wouxun Electronics)

9.1671 WTL (World Telecom Labs)

9.1672 WTW Electronic

9.1673 WWT (World Wide Technology)

9.1674 Wytec International

9.1675 Xantaro

9.1676 XAVi Technologies Corporation (Chicony Electronics)

9.1677 XCOM Labs

9.1678 Xelera Technologies

9.1679 Xena Networks

9.1680 Xiamen Puxing Electronics Science & Technology

9.1681 Xiamen Sanan Integrated Circuit

9.1682 Xiaomi

9.1683 Xilinx (AMD – Advanced Micro Devices)

9.1684 Xingtera

9.1685 Xinwei Group

9.1686 XINYI Information Technology

9.1687 XipLink

9.1688 XIUS

9.1689 YADRO (ICS Holding)

9.1690 YAGEO Corporation

9.1691 Yahsat (Al Yah Satellite Communications)/Thuraya

9.1692 YaleBTS

9.1693 Yanton (Quanzhou Yanton Electronics)

9.1694 YOFC (Yangtze Optical Fibre and Cable)

9.1695 Yuge Technology (Shanghai Yuge Information Technology)

9.1696 Zain Group

9.1697 ZaiNar

9.1698 Zaram Technology

9.1699 Z-Com

9.1700 Zealync

9.1701 Zebra Technologies

9.1702 Zeetta Networks

9.1703 Zello

9.1704 ZenFi Networks (BAI Communications)

9.1705 Zengyi Technology

9.1706 Zepcam

9.1707 ZeroEyes

9.1708 Zetron (Codan)

9.1709 Zhengkai Electronics (Jiangsu Zhengkai Electronics Technology)

9.1710 ZILLNK

9.1711 Zinwave (McWane)

9.1712 Zioncom

9.1713 Zmtel (Shanghai Zhongmi Communication Technology)

9.1714 ZT Systems

9.1715 ZTE

9.1716 Zyxel (Unizyx Holding Corporation)

10 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

10.2.2.1 LTE

10.2.2.2 5G

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 (5G Core)

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 Smart Wearables

10.6.2.6 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

11 Chapter 11: Conclusion & Strategic Recommendations

11.1 Why is the Market Poised to Grow?

11.2 Future Roadmap: 2022 – 2030

11.2.1 2022 – 2025: 3GPP Standards-Compliant MCX Service Deployments

11.2.2 2026 – 2029: Growing Adoption of 5G NR Systems & Off-Network Communications

11.2.3 2030 & Beyond: Towards the Cannibalization of Legacy Digital LMR Systems

11.3 Competitive Industry Landscape: Acquisitions, Alliances & Consolidation

11.3.1 LTE/5G Network Infrastructure & Device Suppliers

11.3.2 Public Safety & Critical Communications Industry

11.3.3 LMR-3GPP Vendor Alliances

11.4 Standardization & Commercial Availability of Key Enabling Technologies

11.4.1 MCX: MCPTT, MCVideo & MCData Services

11.4.2 LMR-3GPP MCX Interworking

11.4.3 HPUE

11.4.4 ProSe & Sidelink

11.4.5 IOPS & MCIOPS

11.4.6 Other Technologies

11.5 Continued Investments in Public Safety Broadband Networks

11.6 Diversity of Network Operational Models

11.7 Which Frequency Bands Will Dominate the Market?

11.8 Spectrum for Future 5G Applications

11.9 Developing Countries: Leapfrogging Directly to 3GPP-Based Critical Communications Networks

11.10 Continued Use of Digital Radio Systems in the Developed World

11.11 Interim Solutions for Off-Network Communications

11.12 Potential Integration of Satellite-Based NTN (Non-Terrestrial Network) Connectivity

11.13 Growing Significance of Deployable Assets for Wildfire Fighting & Disaster Relief Operations

11.14 Supporting COVID-19 Emergency Response Efforts

11.15 International Roaming for Cross-Border Policing & Emergency Response

11.16 The Role of Commercial Mobile Operators

11.16.1 Broadband Access Over Commercial Mobile Networks

11.16.2 Carrier-Integrated MCPTT & Dispatch Solutions

11.16.3 Operator Built & Managed Public Safety Broadband Networks

11.16.4 Private MVNO & MOCN Arrangements

11.16.5 Priority & Preemption Service Offerings

11.16.6 Operator Branded Critical Communications Broadband Platforms

11.16.7 Dedicated Access to Licensed Spectrum

11.16.8 BYON (Build-Your-Own-Network) Solutions

11.16.9 Private LTE/5G Data Processing With Edge Computing

11.16.10 Logical Slicing of Mobile Operator Network Assets

11.17 Critical Communications Service Providers: Transitioning to Become Secure MVNOs

11.18 TCO Comparison: Independent Networks vs. PPPs (Public-Private Partnerships)

11.19 Ensuring the Economic Viability of Public Safety Broadband Networks

11.19.1 Monetizing Unused Network Capacity Through Secondary Commercial Users

11.19.2 Industry Solutions for Other Critical Communications User Groups

11.19.3 Dynamic Spectrum Sharing with Tiered-Priority Access

11.20 Leveraging the Benefits of 5G NR Systems for Mission-Critical Communications

11.21 Public Safety Application Sector Trends

11.21.1 Mission-Critical Group Communications

11.21.2 Fixed, Mobile & Aerial Video Surveillance

11.21.3 Situational Awareness & Common Operating Picture

11.21.4 Data-Intensive Field Applications for First Responders

11.21.5 The IoLST (Internet of Life Saving Things)

11.21.6 5G-Era Applications: UHD Video, AR/VR/MR, Drones & Robotics

11.21.7 Public Safety Application Stores & Developer Programs

11.21.8 5G Labs for First Responders

11.22 Strategic Recommendations

11.22.1 Public Safety & Government Agencies

11.22.2 LTE/5G Infrastructure, Device & Chipset Suppliers

11.22.3 LMR Vendors & System Integrators

11.22.4 Commercial & Private Mobile Operators

List of Companies Mentioned

The following companies and organizations have been reviewed, discussed or mentioned in the report:

10T Tech

1NCE

1oT

3GPP (Third Generation Partnership Project)

450 MHz Alliance

4K Solutions

4RF

5GCT (5G Catalyst Technologies)

6Harmonics/6WiLInk

6WIND

7Layers

7P (Seven Principles)

A Beep/Diga-Talk+

A1 Telekom Austria Group

A10 Networks

A5G Networks

AAEON Technology

Aarna Networks

ABEL Mobilfunk

ABiT Corporation

ABS

Abside Networks

Abu Dhabi Police

Accedian

AccelerComm

Accelink Technologies

Accelleran

Accenture

ACCESS CO.

ACCF (Australasian Critical Communications Forum)

Accton Technology Corporation

Accuver

ACE Technologies

AceAxis

AceTel (Ace Solutions)

Achronix Semiconductor Corporation

ACMA (Australian Communications and Media Authority)

ACOME

Actelis Networks

Action Technologies (Shenzhen Action Technologies)

Actiontec Electronics

Active911

Actus Networks

Adax

ADCOM911 (Adams County Communications Center)

Adcor Magnet Systems

ADF (Australian Defence Force)

ADI (Analog Devices, Inc.)

ADLINK Technology

ADRF (Advanced RF Technologies)

ADT

ADTRAN

ADVA

Advanced Energy Industries

AdvanceTec Industries

Advantech

Advantech Wireless Technologies

Aegex Technologies

Aerial Applications

Aeris

Aero Wireless Group

Aerostar International

AeroVironment

AERTEC

Aethertek

Affarii Technologies

Affirmed Networks

AFL Global

AFRY

AGCOM (Communications Regulatory Authority, Italy)

Agile (Agile Interoperable Solutions)

AGIS (Advanced Ground Information Systems)

AGM Mobile

AH NET (MVM NET)

AI-LINK

AINA Wireless

Airbus

Airfide Networks

Airgain

AirHop Communications

Airlinq

Air-Lynx (Atos)

Airspan Networks

Airtower Networks

Airwave Solutions

Airwavz Solutions

AIS (Advanced Info Service)

Aisan Technology

AiVader

Ajman Police

Akamai Technologies

AKOS (Agency for Communication Networks and Services of the Republic of Slovenia)

Akoustis Technologies

Akquinet

Alaxala Networks Corporation

ALBEDO Telecom

albis-elcon

Alcadis

Alcobendas City Council

Alea

Alef (Alef Edge)

Alepo

Alestra

Alestra (Axtel)

Alibaba Group

Aliniant

Allbesmart

Allen Vanguard Wireless

Allerio

Allied Telesis

Allot

Alpha Networks

Alpha Wireless

Alphabet

Alsatis Réseaux

ALSOK (Sohgo Security Services)

Altaeros

Altair Semiconductor (Sony Semiconductor Israel)

ALTÁN Redes

Altice Group

Altice Labs

Altice Portugal

Altiostar

ALVIS (Argentina)

AM Telecom

Amantya Technologies

Amarisoft

Amazon

Ambra Solutions

Ambulance Victoria

Ambulancezorg Groningen

AMD (Advanced Micro Devices)

Amdocs

América Móvil

American Tower Corporation

AMI (American Megatrends International)

AMIT Wireless

AMN (Africa Mobile Networks)

Ampere Computing

Amphenol Corporation

Ampleon

Amtele Communication

An Garda Síochána (Irish National Police Service)

ANACOM (National Communications Authority, Portugal)

Ananki

Anatel (National Telecommunications Agency, Brazil)

ANCOM (National Authority for Management and Regulation in Communications, Romania)

Andesat

ANDEX (Sendai)

ANDRO Computational Solutions

Angola Telecom

Angolan Ministry of Interior

Anktion (Fujian) Technology

Anokiwave

Anritsu

ANS (Advanced Network Services)

Antenna Company

Antna Antenna Technology

Antwerp Police

Aorotech

APCO (Association of Public-Safety Communications Officials) International

Apple

APRESIA Systems

APSTAR (APT Satellite Company)

APT (Asia Pacific Telecom)

APT (Asia-Pacific Telecommunity)

Aptica

aql

Aquila (Suzhou Aquila Solutions)

Aqura Technologies

Arabsat

Arcadyan Technology Corporation

ARCEP (Regulatory Authority for Electronic Communications and Posts, France)

Archos

ARCIA (Australian Radio and Communications Industry Association)

Arete M

AREU (Lombardy Regional Emergency Service Agency)

Argela

Argentine Federal Police

ArgoNET

Aria Networks

ARIB (Association of Radio Industries and Businesses, Japan)

Arico Technologies

Arista Networks

Arkessa

Arm

Armasuisse (Federal Office for Defense Procurement, Switzerland)

Armour Communications

Arqit Quantum

ArrayComm (Chengdu ArrayComm Wireless Technologies)

Arrcus

Artemis Networks

Artiza Networks

Aruba

Arubaito World

Arukona

Asagao TV

Asahikawa Cable Television

Asavie

ASELSAN

AsiaInfo Technologies

AsiaSat (Asia Satellite Telecommunications Company)

Askey Computer Corporation

ASMG (Arab Spectrum Management Group)

ASOCS

Aspire Technology

ASR Microelectronics

Assured Wireless Corporation

AST SpaceMobile

ASTELLA (Astella Technologies)

ASTRI (Hong Kong Applied Science and Technology Research Institute)

ASTRID

ASUS (ASUSTeK Computer)

Asylon

AT (Auckland Transport)

AT&T

AT&T Mexico

ATDI

ATEL (Asiatelco Technologies)

Atel Antennas

Atesio

Athonet

ATIS (Alliance for Telecommunications Industry Solutions)

ATL (A Test Lab)

AtlantiCare Regional Medical Center

Atlas Telecom

ATN International

Atos

Atrinet

AttoCore

ATU (African Telecommunications Union)

Auckland Westpac Rescue Helicopter

Auden Techno

audius

Auray Technology

Aurens (Orrence)

Aurora Flight Sciences

Aurora Insight

Australian Department of Home Affairs

Australian Productivity Commission

Avanti Communications

Avari Wireless

AVI

Aviat Networks

AVIWEST

AVM

AW2S (Advanced Wireless Solutions and Services)

AWS (Amazon Web Services)

AWTG

Axega 112 (Galician Emergency Agency)

Axell Wireless

AXESS Networks

Axians

Axiata Group

Axione

Axis Communications

Axon

Axpo WZ-Systems

Axtel

Axxcelera Broadband Wireless

Axxcss Wireless Solutions

Azcom Technology

Azetti Networks

B+B SmartWorx

BAE Systems

Bahia State Secretariat of Public Security

BAI Communications

Baicells

BAKOM/OFCOM (Federal Office of Communications, Switzerland)

Ball Aerospace

Ballast Networks

BandRich

BandwidthX

Bangladesh SSF (Special Security Force)

Bangs Ambulance

Barcelona City Council

Barrett Communications

BARTEC

BATM Advanced Communications

BATS Wireless (Broadband Antenna Tracking Systems)

Bay Minette Police Department

BAYFU (Bayerische Funknetz)

Baylin Technologies

BayRICS (Bay Area Regional Interoperable Communications Systems Authority)

BBB (BB Backbone Corporation)

BBK Electronics

BC Hydro

BCDVideo

BDBOS (Federal Agency for Public Safety Digital Radio, Germany)

Beagle Systems

Beam Semiconductor

Beamlink

BearCom

BEC Technologies

becon

Beeper Communications

Beijer Electronics Group

BEL (Bharat Electronics Limited)

Belden

BelFone

Bell Canada

Bellantenna

Benetel

BesoVideo

Betacom

Bharti Airtel

BHE (Bonn Hungary Electronics)

BICS

Billion Electric

BinnenBereik

BIPT (Belgian Institute for Postal Services and Telecommunications)

Bird Technologies

BISDN (Berlin Institute for Software Defined Networks)

Bittium

BK Technologies

Black & Veatch

Black Box

BlackBerry

Blackned

BLiNQ Networks

Blu Wireless

Blue Arcus Technologies

Blue Danube Systems

Blue Wireless

Bluebird

Blueforce Development Corporation

BLUnet Schweiz

BMI (Federal Ministry of Interior, Germany)

BMVg (Federal Ministry of Defense, Germany)

BMWi (Federal Ministry for Economic Affairs and Energy, Germany)

BNetzA (Federal Network Agency, Germany)

BNPB (National Agency for Disaster Management, Indonesia)

Boeing

Boelink (Shanghai Boelink Communication Technology)

Boingo Wireless

Boise Police Department

Bombers de Barcelona (Barcelona Fire Service)

Booz Allen Hamilton

Boston Dynamics

Boston Police Department

Botswana Police Service

Bouygues Telecom

Boxchip

Branch Communications

BravoCom

Brazil Federal District Military Police

Brazilian Army

Bredengen

British Army

Broadcom

BroadForward

Broadmobi (Shanghai Broadmobi Communication Technology)

Broadpeak

Broadtech

BSNL (Bharat Sanchar Nigam Limited)

BT Group

BTI Wireless

B-TrunC (Broadband Trunking Communication) Industry Alliance

Buenos Aires City Police

Bulgarian Ministry of Interior

Bullitt Mobile

Bumicom Telecommunicatie

Bundeswehr (German Armed Forces)

Bundeswehr University Munich

Bureau Veritas

Burlington Fire Department

BVSystems (Berkeley Varitronics Systems)

BWT (BlueWaveTel)

B-Yond

C Spire

C Squared Systems

C3 (Critical Communication Caribbean)

Cable Television Toyama

Cable TV Tokushima

CableFree (Wireless Excellence)

CableLabs

CACI International

Cadence Design Systems

CalAmp

CalChip Connect

Calgary Police Service

Caliber Public Safety

California National Guard

Calix

Calnex Solutions

Caltta Technologies

Cambium Networks

Cambridge Consultants

CampusGenius

Camtel (Cameroon Telecommunications)

Canadian Army

Canoga Perkins

Canonical

Capgemini

Capgemini Engineering

Capgemini Invent

Capita

CapX Nederland

Carbyne

Carlson Wireless Technologies

Casa Systems

CASIC (China Aerospace Science and Industry Corporation)

Casio Computer Company

CATA (Canadian Advanced Technology Alliance)

Catalyst Communications Technologies

CATUAV

CATV (Cable TV)

Cavli Wireless

CBNG (Cambridge Broadband Networks Group)

CCA (Control Center Apps)

CCI (Communication Components Inc.)

CCN (Cirrus Core Networks)

CCS (Cambridge Communication Systems)

CCSA (China Communications Standards Association)

CCww (Communications Consultants Worldwide)

CDE Lightband

CEA-Leti

Cegeka

CeLa Link Corporation

Celab Communications

Celcom Axiata

Celfinet

CellAntenna Corporation

Cellcomm Solutions

Cellient

Celling 5G

CellMax Technologies

Cellnex Telecom

CellOnyx

Cellwize

cellXica

cellXion

Celona

CelPlan Technologies

Centerline Communications

CENTRA Technology

CentralSquare Technologies

CEPT (European Conference of Postal and Telecommunications Administrations)

Ceragon Networks

CertusNet

CETC (China Electronics Technology Group Corporation)

CEVA

CGI

Challenge Networks

Changi General Hospital

ChannelPorts

Charge Enterprises

Charter Communications

Cheerzing (Xiamen Cheerzing IoT Technology)

Chelton

Chemring Technology Solutions

Chengdu NTS

Chicago Police Department

Chicony Electronics

China All Access

China Mobile

China Satcom (China Satellite Communications)

China Telecom

China Unicom

Choice NTUA Wireless

Chulalongkorn University

Chunghwa Telecom

Cibicom

CICPA (Critical Infrastructure and Coastal Protection Authority, UAE)

CICT – China Information and Communication Technology Group (China Xinke Group)

Cielo Networks

Ciena Corporation

CIG (Cambridge Industries Group)

Cincinnati Police Department

CIO (Connected IO)

CircleGx

Cirpack

Cirtek Holdings Philippines Corporation

Cisco Systems

CITC (Communications and Information Technology Commission, Saudi Arabia)

CITEL (Inter-American Telecommunication Commission)

CITIG (Canadian Interoperability Technology Interest Group)

City of Cape Town

City of Johannesburg EMS (Emergency Management Services)

City of London Police

CityFibre

Citymesh

CitySwitch

CK Hutchison

CKH IOD

Claro Brasil

Clavister

Cleveland Police

Clever Logic

CloudMinds

CMIoT (China Mobile IoT)

CNIT (National Inter-University Consortium for Telecommunications, Italy)

Cobham

COCUS

Codan Communications

Codium Networks

Cogisys

Cognizant

Cohere Technologies

Coherent Logix

Cohort

Coiler Corporation

Collinear Networks

Colorado Parks and Wildlife

Colt Technology Services

Com4

Comarch

Comba Telecom

Comcast Corporation

Comcores

Comfone

COMLAB

CommAgility

CommandWear Systems

Commercis

Commnet Wireless

Comms365

CommScope

Compal Electronics

Comprod

Comptek Technologies

ComReg (Commission for Communications Regulation, Ireland)

Comrod Communication Group

COMsolve

COMSovereign

Comtech Telecommunications Corporation

Comtrend Corporation

Comviva

CONET Technologies

CONEXIO Corporation

CONGIV

Connect Tech

Connect44 Group

Connectivity Wireless Solutions

Contela

Continual

Coolpad

CopaSAT

coreNOC

Cornerstone (CTIL)

Cornet Technology

Corning

Cortina Access

Cosemi Technologies

COSMOTE

Cosumnes Fire Department

Côte d’Ivoire Ministry of Interior and Security

Council Rock

County of Renfrew Paramedic Service

Coweaver

Cox Communications

CPQD (Center for Research and Development in Telecommunications, Brazil)

Cradlepoint

CRC (Communications Research Centre Canada)

Creanord

CrisisGo

CritiComms

CROSSCALL

Crown Castle International Corporation

CS Corporation

CSG Systems International

CTG (Celestia Technologies Group)

CTS (Communication Technology Services)

CTS Corporation

CTTC (Catalan Telecommunications Technology Center)

CTU (Czech Telecommunication Office)

Cubic Corporation

Cubic Telecom

Cumucore

Custom MMIC

CybertelBridge

Cyderes

Cyient

Cyrus Technology

Czech Ministry of Interior

D2 Technologies

DAEL Group

Dahua Technology

Dali Wireless

DAMM Cellular Systems

Danish National Police

DART (Dallas Area Rapid Transit)

DATACOM

Datang Telecom Technology & Industry Group

Dataport

DataSoft

Datatec

DBcom

DeepSig

Dejero Labs

DeKalb Police Department

DEKRA

Dell Technologies

Delta Electronics

DENGYO (Nihon Dengyo Kosaku)

Dense Air

DGS (Digital Global Systems)

Dialog Axiata

Dialogic

Diamond Communications

DIGI Communications

Digi International

Digi Telecommunications

Digicert

Digita

Digital Ally

Digital Enhancement

DigitalBridge Group

DigitalRoute

Digitata

DigitGate (Nanjing DigitGate Communication Technology)

Dimetor

DISH Network Corporation

DKK (Denki Kogyo)

D-Link Corporation

DNA (Finland)

DND (Department of National Defence, Canada)

Docomo Pacific

DOK’ICI

Doogee

Doosan Corporation

Dortmund Fire Brigade

Dräger

DragonWave-X

Drakontas

DRDC (Defence Research and Development Canada)

DREHTAINER

DriveNets

Drone Aviation

DroneSense

Druid Software

DRZ (German Rescue Robotics Center)

DSA (Dynamic Spectrum Alliance)

DSB (Directorate for Civil Protection, Norway)

DSBJ (Suzhou Dongshan Precision Manufacturing)

DSTL (Defence Science and Technology Laboratory, United Kingdom)

DT (Deutsche Telekom)

DTAC (Total Access Communication)

du (EITC – Emirates Integrated Telecommunications Company)

Dubai Police

Dublin Fire Brigade

Duons

Durabook (Twinhead International Corporation)

Duubee

DXC Technology

DZS

Eahison Communication

EANTC

Eastcom (Eastern Communications)

Easycom (Shenzhen Easycom Electronics)

E-Band Communications

e-BO Enterprises

EBRCSA (East Bay Regional Communications System Authority)

ECE (European Communications Engineering)

EchoStar Corporation

EchoStar Satellite Services

Ecom Instruments

E-Comm 9-1-1

Econocom

ECOTEL

Ecrio

Edgecore Networks

EdgeQ

Edgybees

edotco Group

EDX Wireless

Edzcom

Effnet

EGC International

Egyptian Ministry of Defense

Eigencomm

eino

EION Wireless

Eir (Eircom)

Ekinops

Elbit Systems

Elefante Group

E-Lins Technology

Elisa

Elisa Estonia

Elisa Polystar

Elistair

ELP (European Logistic Partners)

Elsight

Elta Systems

Eltex

ELUON Corporation

ELVA-1

Emblasoft

Embraer

Embratel

EMERCOM (Ministry for Civil Defense, Emergencies and Disaster Relief, Russia)

EMnify

EMS (Electronic Media Services)

ENACOM (National Communications Agency, Argentina)

Encore Networks

Enea

ENENSYS Technologies

Energizer Mobile (Avenir Telecom)

EnerSys

ENLETS (European Network of Law Enforcement Technology Services)

Entel (Chile)

Entropia

Entropy Solution

Eoptolink Technology

EOS (Electro Optic Systems)

Equiendo

Equinix

Eravant (SAGE Millimeter)

Ericsson

Erillisverkot (State Security Networks Group, Finland)

Errigal

ESA (European Space Agency)

Eseye

Esharah Etisalat Security Solutions

Estalky (K-Mobile Technology)

Estonian Ministry of Defense

ETELM

eTera (Sinotech R&D Group)

Ethernity Networks

Etherstack

Etisalat Group (e&)

ETRI (Electronics & Telecommunications Research Institute, South Korea)

ETSI (European Telecommunications Standards Institute)

EUCAST

EURECOM

Eurescom

Eurofins E&E (Electrical and Electronics)

Eurotech

Eutelsat Communications

Eventide Communications

Everbridge

EWA (Enterprise Wireless Alliance)

Ewing Police Department

Exacom

Exaware

Excelerate Technology

EXFO

Exium

Expeto

ExteNet Systems

Extreme Networks

EY (Ernst & Young)

Eyecom Telecommunications Group

EZcon Network

F2G (Far-Together) Solutions

FADA (Andalusian Foundation for Aerospace Development)

Fairspectrum

Fairwaves

Faraday Technology Corporation

Faroe Islands Police

Fastback Networks

Fastweb

FCNT (Fujitsu Connected Technologies)

FCTV (Fukui Cable Television)

Federal Engineering

Federated Wireless

Fenix Group

FET (Far EasTone Telecommunications)

FFI (Defense Research Establishment, Norway)

FiberHome Technologies

FIBERSTAMP

Fibocom

Fibrolan

Filtronic

Fingu (Wuhan Fingu Electronic Technology)

FinnHEMS (Finnish Helicopter Emergency Medical Services)

Finnish Border Guard

Finnish Defense Forces

Fiplex Communications

Firecell

FirstNet (First Responder Network) Authority

Fishtech Group

Fivecomm

Flash Networks

Flash Private Mobile Networks

Fleet Complete

Flex

Flex Logix Technologies

Flexitron Group

Flightcell International

FLIR Systems

floLIVE

Flymotion

flyXdrive

FMBE (FMB Engineering)

FMV (Defense Materiel Administration, Sweden)

Føroya Tele (Faroese Telecom)

Forsk

Forsvaret (Norwegian Armed Forces)

Försvarsmakten (Swedish Armed Forces)

Forsvarsmateriell (Norwegian Defense Materiel Agency)

Forte Comunicaciones

Fortinet

Fortress Solutions

Four-Faith Communication Technology

Foxconn (Hon Hai Technology Group)

Franklin Wireless

Fraunhofer FOKUS (Institute for Open Communication Systems)

Fraunhofer HHI (Heinrich Hertz Institute)

Fraunhofer IIS (Institute for Integrated Circuits)

Fraunhofer IPT (Institute for Production Technology)

FreedomFi

Freeeway

freenet Group

French Air Force

French Army

French Ministry of Armed Forces

French Ministry of Interior

Frequentis

Freshwave Group

Frog Cellsat

FRTek

FSG (Field Solutions Group)

FTS (Formula Telecom Solutions)

Fujikura

Fujitsu

Funk-Electronic Piciorgros

Furukawa Electric

Furuno Electric

Future Technologies Venture

G REIGNS

G+D (Giesecke+Devrient)

G3 Global

Galtronics

Gama Aviation

Gamma Nu

Gandi

Gapwaves

Garderos

Gazprom Space Systems

GCF (Global Certification Forum)

GCT Semiconductor

GD (General Devices)

GDIT (General Dynamics Information Technology)

GDRFA-Dubai (General Directorate of Residency and Foreigners Affairs, Dubai)

GE (General Electric)

Gemtek Technology

Genaker

General Dynamics

General Dynamics Mission Systems

Genesis Group

GENEViSiO

Genew Technologies

Genmix Technology

GenXComm

Geotab

GeoTraq

Getac Technology Corporation

Gewei (Wuhan Gewei Electronic Technology)

GF (GlobalFoundries)

GGD (Municipal Health Service) Brabant-Zuidoost

GIGABYTE Technology

Gigalane

GIGALIGHT

Gigamon

GigaTera Communications

GigSky

Gilat Satellite Networks

GL Communications

Global Telecom

Globalgig

Globalstar

Globe Telecom

GMR (Global Medical Response)

GNConnect

Goodman Telecom Services

Goodmill Systems

Google

Goosetown Communications

Gore (W. L. Gore & Associates)

Gosuncn Group

GosuncnWelink Technology

Gradiant (Spain)

Granite Telecommunications

Grant County Sheriff’s Office (Wisconsin)

Grape One

Greek Ministry of Citizen Protection

Greek Police

Green Communications

Green Packet

Greenet

GreenPalm (Hangzhou GreenPalm Technology)

GrenTech

GridGears

Grob Aircraft

Groundhog Technologies

GroupTalk

GS Lab (Great Software Laboratory)

GSI (GS Instech)/GST (GS Teletech)

Guangzhou Gosuncn Robot

Guardia Civil (Spanish Civil Guard)

Guàrdia Urbana de Barcelona (Barcelona Urban Guard)

Guavus

Guerrilla RF

Guiyang Public Security Bureau

GWT (Global Wireless Technologies)

GWTCA (Government Wireless Technology & Communications Association)

HAAS Alert

Haier

Haivision

Halton Regional Police Service

Halys

Hampshire Fire & Rescue Service

Hampton Valley Forge Volunteer Fire Department

HanbitDrone

Hancock State Prison

Hancom MDS

Handheld Group

Handsfree Group

Hankyu Hanshin Holdings

Hansen Technologies

Hanshin Cable Engineering

Hanswell

Hanwha Techwin

HAPSMobile

HARMAN DTS (Digital Transformation Solutions)

Harvilon (Shenzhen Harvilon Technology)

Hawk Networks (Althea)

Haystax Technology

HBFEC (Hebei Far East Communication System Engineering)

HCL Technologies

Helios (Fujian Helios Technologies)

Hellas Sat

Hengxin (Jiangsu Hengxin Technology)

Henkel

Heropolis

Herystorm (Guangzhou Herystorm Technology)

Hexagon

Hexagon Communication (Suzhou Hexagon Communication Technologies)

HFCL

HFR Networks

HG Genuine

HGTECH (Huagong Technology)

Highstreet Technologies

Hikvision (Hangzhou Hikvision Digital Technology)

Hilinks Technology

HipLink Software

Hisense

HiSilicon Technologies

HISPASAT

Hitachi

HKT

HKTech (Howking Tech)

HMD Global

HMF (Hytera Mobilfunk)

HMS Networks

Hohhot Public Security Bureau

Hologram

Honeywell International

Hong Kong Police Force

Hongdian Corporation

HONOR

HOPE Technik

Hot Mobile

Houston Methodist

Hoverfly Technologies

HPE (Hewlett Packard Enterprise)

HQT (Shenzhen HQT Science and Technology)

HSC (Hughes Systique Corporation)

Hsinchu City Fire Department

HTC Corporation

Huahuan (Beijing Huahuan Electronics)

Hualapai Nation Police Department

Huaptec

Huawei

HUBER+SUHNER

HUCOM Wireless

Hughes Network Systems

Hunan Highway Police

Hungarian Ministry of Interior

HXI (Renaissance Electronics & Communications)

Hypha (Wireless Innovation)

Hytec Inter

Hytera Communications

i.safe MOBILE

i2CAT (Internet Research Center)

i2i Systems

IAI (Israel Aerospace Industries)

iBASIS

IBM

IBO Technology Company

iBwave Solutions

iCana

ICASA (Independent Communications Authority of South Africa)

ICCRA (International Critical Control Rooms Alliance)

Ice Norway

iCERT (Industry Council for Emergency Response Technologies)

ICG (Icelandic Coast Guard)

ICN (Imizu Cable Network)

Icom

Iconec

iConNext

ICS Holding

ICT (Islamabad Capital Territory) Administration

ICU Technologies

iDAQS

IDEMIA

IDF (Israel Defense Forces)

IDY Corporation

IETF (Internet Engineering Task Force)

IFLY Electronics

IFT (Federal Institute of Telecommunications, Mexico)

IGOF (International Governmental Operators’ Forum)

IHiS (Integrated Health Information Systems)

IIJ (Internet Initiative Japan)

II-VI

IM Technology

IMDA (Info-communications Media Development Authority of Singapore)

IMDEA Networks Institute

Imec

IMPTT

Inatel (National Institute of Telecommunications, Brazil)

InCoax Networks

Indian Army

Indianapolis Fire Department

Indra

InDro Robotics

iNET (Infrastructure Networks)

INEX Microtechnology

Infineon Technologies

Infinera

InfiNet Wireless

Infinite Electronics

Infomark Corporation

Infosys

Infovista

InHand Networks

INL (Idaho National Laboratory)

Inmanta

Inmarsat

Inmarsat Government

Innertron

InnoGence Technology

InnoLight Technology

Innonet

Innovile

InnoWireless

In-Q-Tel

Inrico Technologies

Inseego Corporation

Insight Enterprises

Inspur

Insta Group

Instant Connect

InstantCom (Romania)

INSYS icom (INSYS Microelectronics)

Intec E&C

Intel Corporation

Intelliport Solutions

Intelsat

Intenna Systems

InterDigital

INTERLEV

Internet Institute (Slovenia)

Interop Technologies

InterTalk Critical Information Systems

Intracom Telecom

Intrado Corporation

Intrepid Networks

Inventec Corporation

Invest Ottawa

INWIT (Infrastrutture Wireless Italiane)

IoT4Net

IoTAS (IoT & Approval Solutions)

Iowa State University

IP Infusion

ip.access (Mavenir)

IPAGEON

IPITEK (Integrated Photonics Technology)

IPLOOK Technologies

iPosi

Iradio Electronics

Iraqi Ministry of Defense

Iridium Communications

ISCO International

ISCOM (Higher Institute of Communications and Information Technologies, Italy)

iSea

ISED (Innovation, Science and Economic Development Canada)

Iskratel

Israel Fire and Rescue Authority

Israel Police

IS-Wireless

Italian Army

Italian Ministry of Defense

Italian Ministry of Interior

Italtel

ITCEN

I-TEC Solutions

ITRI (Industrial Technology Research Institute, Taiwan)

ITU (International Telecommunication Union)

Jabil

JACS Solutions

JATONTEC (Jaton Technology)

JCI (Japan Communications Inc.)

JEMS (Japan EM Solutions)

Jet Engineering

Jezetek (Sichuan Jiuzhou Electric Group)

Jiaxun Feihong (Beijing Jiaxun Feihong Electrical)

Jinan USR IoT Technology

JIT (JI Technology)

JMA Wireless

JMPD (Johannesburg Metropolitan Police Department)

Jordanian Armed Forces

JOUAV

JPC Connectivity

JPS Interoperability Solutions

JQL Technologies

JRC (Japan Radio Company)

JSC Ingenium

JT IoT

Juganu

Juniper Networks

Junkosha

Juvare

JVCKENWOOD Corporation

Kacific Broadband Satellites

Kaelus

Kaga Cable Television

Kajeet

Kaloom

Kalray

Kantonspolizei St.Gallen (Cantonal Police of St. Gallen)

Kantonspolizei Zürich (Cantonal Police of Zurich)

Katela Networks

Kathrein Mobile Communication

Katla Aero

KBR

KBT (Kenbotong Technology)

KCC (Korea Communications Commission)

KDDI Corporation

KDSG (Kaduna State Government)

Kementerian Kominfo (Ministry of Communication and Information Technology, Indonesia)

Kenyan Police Service

Key Bridge Wireless

Keysight Technologies

Kiana Analytics

Kigen

Kindroid (Shanghai Jinzhuo Technology)

Kirisun Communications

Kisan Telecom

KLA Laboratories

Klas Telecom

Klein Electronics

Kleos

KMW

Knightscope

KNPA (Korean National Police Agency)

Koning & Hartman (Axians/VINCI Energies)

KONTEL

Kontron Transportation

KORE Wireless

KOREN (Korea Advanced Research Network)

KPCN (Dutch Caribbean Police Force)

KPN

KT Corporation

KT SAT

Kudelski Group

Kumu Networks

Kyland Technology

Kymeta Corporation

Kyndryl

Kyocera Corporation

Kyrio

KZ TECH (KZ Broadband Technologies)

L&T (Larsen & Toubro)

L3Harris Technologies

Laird Connectivity

Lancaster University

Landmark Dividend

Langkawi Municipal Council

Lanner Electronics

Lantronix

LA-RICS (Los Angeles Regional Interoperable Communications System)

Las Vegas Metropolitan Police Department

Lattice Semiconductor

LCR Embedded Systems

Lebanese Ministry of Interior and Municipalities

Lebanon’s ISF (Internal Security Forces)

Leenos Corporation

Leidos

Lekha Wireless Solutions

Lemko Corporation

Lenovo

Leonardo

Leuven Police

Levi9 Technology Services

Lextrum

LG CNS

LG Corporation

LG Uplus

LGS Innovations

Liberty Global

Lierda Science & Technology Group

Lifecycle Software

Ligado Networks

Lightron

Lijiang Police

Lime Microsystems

Lindsay Broadband

Linkem

Linksys

Linx Technologies

LIONS Technology

Lisheng Fujian Communications

Lishui Municipal Emergency Management Bureau

LITE-ON Technology Corporation

LitePoint

LiveU

LMCC (Land Mobile Communications Council)

LMT (Latvia Mobile Telecom)

Lociva

Lockheed Martin Corporation

Lockheed Martin Space

Logicalis

LogicTree IT Solutions

Longsung Technology

Lookout

LS Mtron

LS telcom

LTTS (L&T Technology Services)

Luceor

Lumen Technologies

Lumentum

Lumineye

LuxCarta

Luxoft

Lyfo

Lynceo

Lynk Global (Ubiquitilink)

Lyse

M/C Partners

m3connect

M4PS (Mobility 4 Public Safety)

M87

MACC Base (Milford Area Communications Center)

MACOM

Madagascar National Police

MadCo 911 (Huntsville-Madison County 9-1-1 System)

Magic Software Group

Magnaquest Technologies

Maipu Communication Technology

Maja Systems

Makati City DRRMO (Disaster Risk Reduction & Management Office)

Málaga Local Police

Mammoth Lakes Fire Protection District

MantisNet

MarchNet

Marlink

Marquistech

Martin UAV

Marubeni Corporation

Marubun Corporation

Marvell Technology

MÁSMÓVIL

Mathworks

Matrix Electrónica

MATRIXX Software

MatSing

Maven Wireless

Mavenir

MAVOCO

MaxComm

Maxim Integrated

Maxis

MaxLinear

MBIE (Ministry of Business, Innovation and Employment, New Zealand)

MBPJ (Petaling Jaya City Council)

MC Technologies

MCA (Maritime and Coastguard Agency, United Kingdom)

MCMC (Malaysian Communications and Multimedia Commission)

MCP (Mission Critical Partners)

MCS Benelux

McWane

MD (MICRODRIVE)

Mdex

MDS (Mercuries Data Systems)

MEASAT Satellite Systems

MECSware

Media Broadcast

MediaTek

Meeami Technologies

MegaChips Corporation

MegaFon

Megh Computing

MeiG Smart Technology

Meizu

Mengzi Forestry and Grassland Administration

Mentura Group

MER Group

Meta Connectivity

Metanoia Communications

Metaswitch Networks

Metawave Corporation

Metismake

MetTel

Mexican National Guard (Formerly Federal Police)

MFA (MulteFire Alliance)

MHA (Ministry of Home Affairs, Singapore)

MHD (Muhan Digital)

Miami-Dade Police Department

MIC (Ministry of Internal Affairs and Communications, Japan)

MIC Nordic

MICAS-RF (MICAS Shenzhen Telecommunication)

MiCOM Labs

Micran

Microamp Solutions

Microchip Technology

Microlab

MicroNova

Microsoft Corporation

Microwave Networks

MIIT (Ministry of Industry and Information Technology, China)

MikroTik

Mikwave (Guangdong Mikwave Communication Tech)

Milesight

Milestone Systems

Miliwave

MiMOMax

Minas Gerais State Military Police

MindMade (WB Group)

Minnesota Department of Public Safety

MIPS

MiTAC Computing Technology Corporation

MitraStar Technology

MITRE Corporation

Mitsubishi Electric Corporation

MixComm

MKI (Mitsui Knowledge Industry)

MND (Ministry of National Defense, South Korea)

MOBI (Mobi Antenna Technologies)

Mobile Mark

Mobile Tornado

Mobile Viewpoint

MobileDemand

MobiledgeX

MobileIron

MobileTek (Shanghai Mobiletek Communication)

Mobileum

Mobilicom

Mobilitie

Mobilogix

Mobiveil

MOIS (Ministry of the Interior and Safety, South Korea)

Molex

Monmouth County Sheriff’s Office

Monogoto

Morningcore Technology

Morningstar Corporation

Moscow City Police

Moseley Associates

MosoLabs

Motive Infrastructure Solutions

Motorola Mobility

Motorola Solutions

Mott MacDonald

Movandi

Moxa

MP Antenna

MPF (Mauritius Police Force)

MPS (Ministry of Public Security, China)

MRC (Mobile Radio Center)

MRK Media

MRT Technology (Suzhou)

MSB (Civil Contingencies Agency, Sweden)

MSB (M S Benbow & Associates)

MT (Mauritius Telecom)

MTI (Microelectronics Technology Inc.)

MTI Wireless Edge

MTN Group

MTS (Mobile TeleSystems)

MUGLER

MultiTech (Multi-Tech Systems)

Murata Manufacturing

Mushroom Networks

Mutualink

MVI Group

MYCOM OSI

Mynaric

MYT Electronics

N.A.T.

Nable Communications

Nae

NAKIT (National Agency for Communication and Information Technologies, Czech Republic)

Nanjing Municipal Government

Nanning Public Security Bureau

NanoSemi

Napatech

Naragakuen University

Nash Technologies

National Guard of the Russian Federation

National Police of Colombia

National Police of the Netherlands

NATO (North Atlantic Treaty Organization)

NAVER Cloud

NBTC (National Broadcasting and Telecommunications Commission, Thailand)

NC State (North Carolina State University)

NCC (National Communications Commission, Taiwan)

Nearby Computing

NEC Corporation

Nedaa

Nemergent Solutions

Nemko

Neolink Communications Technology

Neoway Technology

Neptune Communications

Neragon Networks

Net AI

Net1 PH (Broadband Everywhere Corporation)

Netaş

NETBEE (NET-Automation)

Netcracker Technology

NetFoundry

Netgear

NetGenuity

Netivei Israel (National Transport Infrastructure Company)

NetModule

Netmore Group

NETSCOUT Systems

Netsia

Netvision Telecom

Neutral Networks (UK)

Neutral Wireless

Neutroon Technologies

Nevada Department of Transportation

New H3C Technologies

New Hampshire Department of Safety

New Postcom Equipment

New Zealand Police

NewCore Wireless

NewEdge Signal Solutions

NEXCOM International

Nexedi

Nexign

Nexpring

Nextivity

NextNav

Nextworks

NFA (National Fire Agency, South Korea)

ng4T

NGK Group (NGK Insulators)

ng-voice

NHS (National Health Service, United Kingdom)

NI (National Instruments)

NICE

NICE TV (Niikawa Information Center)

Nigeria Police Force

NimbeLink

Niral Networks

NITEL (National Inter-University Consortium for Transportation & Logistics)

Nitto Denko Corporation

NKG (New Kinpo Group)

Nkom (Norwegian Communications Authority)

Node-H

Noetsu Cablenet

Nokia

Nopparat Rajathanee Hospital

Nordic Semiconductor

Nordic Telecom

Norsat International

Northeastern University

Northrop Grumman Corporation

Norwegian Police Service

NOTION Information Technology

Nova Labs (Helium)

Novatek (Canada)

NOVEC

NOVELSAT

NRB (Network Research Belgium)

NS Solutions Corporation

NSC (National Spectrum Consortium)

Nsight

NSW (New South Wales) Telco Authority

NT (National Telecom)

NTMore (Network Technology More)

NTT Communications

NTT DoCoMo

NTT Group

NTT West

Nubia Technology

Nuestra Señora del Prado General Hospital

Nuevo León State Government

NuRAN Wireless

Nurlink Technology

Nutaq Innovation

NVIDIA Corporation

NVIS Communications

NXP Semiconductors

O2 Czech Republic

Oakland Fire Department

Oasis Smart SIM

Oaxaca State Government

OceanAlpha

Oceus Networks

OCN (Okinawa Cable Network)

Octasic

O-Cubes

ODN (Orbital Data Network)

OE Solutions

OFCA (Office of the Communications Authority, Hong Kong)

Ofcom (Office of Communications, United Kingdom)

OFS Fitel

OKI Electric Industry

OMA SpecWorks (Open Mobile Alliance)

Omnispace

Omnitele

Omnitron Systems

Omnitronics

One2many

OneLayer

OnePlus

OneSimCard

OneSource (Portugal)

OneWeb

OnGo Alliance

Onomondo

Ontix

Onwave

Ooredoo

Opanga Networks

Open Robotics

Open Valley

Opencode Systems

Openet

OpenSky (Nigeria)

OPPO

O’Prueba Technology

OPTAGE

OptConnect

Optical Zonu Corporation

Opticoms

Option (Crescent)

Optiva

Optus (Singtel)

Oracle Communications

O-RAN Alliance

Orange

Orange Belgium

Orange Romania

Orange Spain

ORBCOMM

Ori Industries

Orion Labs

Oscilloquartz

OSI (Slovenia)

Oslo University Hospital

OTE Group

Ottawa Fire Services

Ottawa Paramedic Service

Ottawa Police Service

OTV (Okinawa Television Broadcasting)

OV (Manx Telecom)

OVHcloud

Ożarowice Government

P.I. Works

PacStar (Pacific Star Communications)

Padtec

Pakistan Army

Pakistan Ministry of Interior

Palo Alto Networks

Panasonic Corporation

Panda Electronics

PanOptis

Panorama Antennas

Parallel Wireless

Paraná State Secretariat of Public Security

Parc Taulí Health Consortium

Parks Canada

Parlem Telecom

Parsec Technologies

Particle

Partner Communications

PAStech

Patrocinium Systems

Patton

Pavlov Media

PCCW

PCS Technologies

PCTEL

PCTEST Lab (PCTEST Engineering Laboratory)

PDRM (Royal Malaysia Police)

Peatalk Corporation

Peel Regional Police

Pegatron Corporation

Pei Tel Communications

Pelion

Penang State Government

Penguin Solutions

PentaTech

Pente Networks

Peplink (Plover Bay Technologies)

Pepperl+Fuchs

Pepro

Peraso

Peraton Labs (Perspecta Labs)

Percepto

Perle Systems

Pharrowtech

Philippine Army

Philippine Red Cross

Philips

Phirst Technologies

Phluido

Phonero

Phytium Technology (Tianjin Phytium Information Technology)

PHYTunes

PIA (PSBN Innovation Alliance)

Picocom

Pierson Wireless

Pivot Technology Services

Pivotal Commware

Pivotel Group

Pivotone

Pixavi

PLA (People’s Liberation Army)

PLA Navy (People’s Liberation Army Navy)

Planet Communications Asia

Platform9

PLDT

Pletronics

Plextek

Plintron

Plus (Polkomtel)

PMC Wireless

PNNL (Pacific Northwest National Laboratory)

PNP (Philippine National Police)

POCSTARS

Pod Group

Polaris Networks

Polaris Wireless

Polish National Police

Pollen Mobile

Polte

Portuguese Red Cross

Positron Access Solutions

Potevio

Powertech Labs

PowerTrunk

PPC Broadband

Precision OT (Optical Transceivers)

PRESCOM

PrioCom

Proef

Pro-M (Hungary)

Proptivity

Proscend Communications

PROSE Technologies

Protection Civile des Vosges

PROTEI

Protezione Civile (Department of Civil Protection, Italy)

Proxim Wireless Corporation

Proximus

Proximus Luxembourg

Pryme Radio Products

PSBTA (Public Safety Broadband Technology Association)

PSCA (Punjab Safe Cities Authority)

PSCE (Public Safety Communication Europe)

PSCP Corporation

pSemi Corporation

PSNI (Police Service of Northern Ireland)

PSU (Prince of Songkla University)

PT INTI (PT Industri Telekomunikasi Indonesia)

PT LEN Industri

PT Net Satu Indonesia (Net1 International)

PTD (Posts and Telecommunications Department, Myanmar)

PTI (Persistent Telecom Inc.)

PTS (Post and Telecom Authority, Sweden)

Public Safety Canada

Publicis Sapient

Puerto Rico Police Department

Pulsara

Pulse Electronics

Purdue University

Pycom

Qatar Armed Forces

Qatar MOI (Ministry of Interior)

Qatar Police

QCT (Quanta Cloud Technology)

Qinetiq

Qingdao Police

Qinhuangdao Public Security Bureau

Qiqihar Municipal Public Security Bureau

Qiqihar Police

QNAP Systems

Qorvo

QTnet (Kyushu Electric Power Company)

QuadGen Wireless Solutions

Qualcomm

Quanta Computer

Quantum Wireless

Qucell Networks

Quectel Wireless Solutions

Queensland Police Service

Querétaro State Government

Quickline Communications

Quintel

Qulsar

Quortus

Qwake Technologies

Qwilt

R Systems (Computaris International)

RACOM (Czech Republic)

RACOM Corporation

RAD

RADCOM

Radiall

Radio Gigabit

Radio IP Software

RadioLabs (Consortium of the University-Industry Radio-Communication Laboratories, Italy)

RadioMobile

Radisys

RADTONICS

Radware

RADWIN

RAF (Royal Air Force)

Rafael Advanced Defense Systems

Rai Way

Raisecom

Rajant Corporation

Rakon

Rakuten Symphony

RAME (Radio Analog Micro Electronics)

Range Networks

Ranger Systems

Ranplan Wireless

Rapid.Space

RapidDeploy

RapidSOS

Rapidtek Technologies

Rave Mobile Safety

Raven Aerostar

Raycap

Raytheon Technologies Corporation

RCC (Regional Commonwealth in the Field of Communications)

RCMP (Royal Canadian Mounted Police)

RCN (Reinan Cable Network)

RCS Telecommunications

Ready Wireless

Realme

RealWear

Red Hat

Red Lion Controls

RED Technologies

REDCOM Laboratories

Redline Communications

RedZinc

Reliance Industries

Reliance Jio Infocomm (Jio Platforms)

REMEC Broadband Wireless Networks (Bridgewave Communications/SAGE SatCom)

Renesas Electronics Corporation

RESCAN (Canary Islands Network for Emergency and Security)

Rescue 101 SAR (Search and Rescue)

Rescue 42

Responder Corp

RF Connect

RF DSP

RF Industries

RF MORECOM

RF Window

RFHIC Corporation

RFI Technology Solutions

RFS (Radio Frequency Systems)

RFTech

Rheinmetall

Ribbon Communications

Ricon Mobile

RIKS (State Infocommunication Foundation, Estonia)

RINA

Rincón de la Victoria Local Police

Rio de Janeiro Fire Department

Rio Grande do Sul State Secretariat of Public Security

RIVA Networks

Rivada Networks

Rivada Space Networks

Rivas Vaciamadrid City Council

RKTPL (RK Telesystem Private Limited)

RNLI (Royal National Lifeboat Institution, United Kingdom)

Robert Bosch

Robin.io

ROBUR Industry Service Group

Robustel

Rogers Communications

Rogers Corporation

Rögg

Rohde & Schwarz

Rohill

ROK (Republic of Korea) Army

ROKAF (Republic of Korea Air Force)

Rolling Wireless

Rombit

ROP (Royal Oman Police)

Rosenberger

Rostec

Rostelecom

Royal Australian Navy

Royal Bahamas Police Force

Royal Flying Doctor Service (Australia)

Royal Netherlands Military Police

Royal Thai Police

Royole Corporation

RSCC (Russian Satellite Communications Company)

RSConnect

RTO Wireless

RTRS (Russian Television and Radio Broadcasting Network)

RTX A/S

RTx Technology

Ruckus (CommScope)

RugGear

RuggON Corporation

Ruijie Networks

RunEL

Rushmere Technology

Russian Army

Russian Ministry of Internal Affairs

RWJ (Regional Wireless Japan)

S&T Group

Saab

Saankhya Labs

SABIC

SAC Wireless

SAF (Singapore Armed Forces)

SAF Tehnika

Safaricom

Safe-Com Wireless

SafeMobile

Safe-Net Forum

Safer Buildings Coalition

Sagemcom

SageRAN (Guangzhou SageRAN Technology)

Saguna Networks

SAI Technology

SAIC (Science Applications International Corporation)

Samji Electronics

Samsung

SAMWON FA

Samyoung Celetra

San Diego Fire-Rescue Department

San Diego Police Department

SANDF (South African National Defense Force)

Sandvine

Sanechips Technology

SANG (Saudi Arabian National Guard)

Sanjole

San-tron

São Paulo State Military Police

SAPS (South African Police Service)

Sapura Secured Technologies (Sapura Group)

SAReye

Sasken Technologies

SaskTel

Sateliot

Satellite Applications Catapult

SatixFy

Saudi MOI (Ministry of Interior)

Savox Communications

SBA Communications

ScaraBot Technologies

Sceye

Schoten Police

SCRF (State Commission for Radio Frequencies, Russia)

SDIS 59 (Nord Departmental Fire & Rescue Service)

SEA (Systems Engineering & Assessment)

Seamless Waves

SECOM

Sectra Communications

Secure Chorus

Secured Communications

SecureG

SecurifAI

Select Spectrum

SELECTRIC Nachrichten-Systeme

SEMPRE

Semtech Corporation

Senko Advanced Components

Sensorview

Senstar Corporation

Sentinel Camera Systems

Seong Ji Industrial

SEONTECH

Seowon Intech

Sepura

Sequans Communications

Serbian Ministry of Interior

Sercomm Corporation

SERMA Group

SES

SETAR (Aruba)

SETUP Protokolltester

SFR (Altice France)

SFU (Simon Fraser University)

SGH (SMART Global Holdings)

SGS

Shanghai Pearl Oriental Group

Shanghai Police Department

Shannon Wireless (Zhejiang Shannon Communication Technology)

Shared Access

Sharp Corporation

ShawnTech Communications

Shenglu (Guangdong Shenglu Telecommunication)

Shenzhen CXD Science & Technology

Shenzhen Public Security Bureau

Shenzhen Recoda Technologies

Shyam Group

SIAE Microelettronica

Siemens

Siemens Mobility

Sierra Wireless

Sigma Wireless

Signalchip

Signalwing

Signify

Siklu

Silicom Connectivity Solutions

Silicom SAS (France)

SIMCom Wireless Solutions

Simnovus

Simoco Wireless Solutions

Sinclair Technologies

Singtel

Sinnwell

SIP (Sidewalk Infrastructure Partners)

SIRADEL

Siriraj Hospital (Mahidol University)

Sistema

SITEP (Spain)

siticom

SiTime Corporation

SITRONICS

SiTune Corporation

Sivers Semiconductors

Siyata Mobile

SK Telecom

SK Telesys

Skoltech (Skolkovo Institute of Science and Technology)

SKY Perfect JSAT

SkyFive

Skylark Wireless

Skylo Technologies

Skyvera (TelcoDR)

Skyworks Solutions

SLA Corporation

SLC (Secure Land Communications)

Slovenian Armed Forces

Slovenian Ministry of Defense

Slovenian Ministry of Interior

Slovenian Ministry of Public Administration

Slovenian Police

SM Optics

Smart Communications

Smart Mobile Labs

Smartfren

SmarTone

SMAWave (Shanghai SMAWave Technology)

Socionext

SoftBank Group

Softil

Soitec

Solectek Corporation

SOLiD

Solidtronic

Soliton Systems

Somewear Labs

Sonic Communications

Sonim Technologies

Sony Group Corporation

Sooktha

Soracom

Sorbonne University

Sougou Shouken

Source Photonics

Southern Adriatic Sea Port Authority

Southern Linc

SPA (Scottish Police Authority)

Space Data Corporation

SpaceBridge

Spacecom

SpaceX

Spanish Army

Spanish Ministry of Interior

Spanish Navy

Spanish Red Cross

Spark New Zealand

Specialist Aviation Services

Spectra Group

SpectraRep

Spectre

Spectris

Spectronite

Spectronn

Spectrum Effect

Speedcast

SPF (Singapore Police Force)

Spideradio (Suzhou Spideradio Telecommunication Technology)

SPIE Group

Spirent Communications

SPIRIT DSP

SPL (Stratospheric Platforms Limited)

Sporton International

Sprint (T-Mobile US)

SQUAN

SRA Holdings

SRS (Software Radio Systems)

SRTechnology

SSC (Shared Spectrum Company)

ST (STMicroelectronics)

ST Engineering iDirect

ST Engineering Land Systems

St John New Zealand

Stadtpolizei Zürich (Zurich City Police)

Star Microwave

Star Solutions

StarHub

StarPoint (Beijing StarPoint Technology)

STC (Saudi Telecom Company)

STCSC (STC Specialized)

Steep

STEP CG

STL (Sterlite Technologies Ltd.)

Stop Noise

Streambox

Streamwide

Strict B.V.

STS (Special Telecommunications Service, Romania)

Subex

Subtel (Undersecretariat of Telecommunications, Chile)

SUE PILARN (State Unitary Enterprise, Saint Petersburg Emergency Service)

Suffolk County Sheriff’s Department

Sultanah Maliha Hospital

Sumitomo Corporation

Sumitomo Electric Industries

Summa Networks

Summit Tech

Sunrise UPC

Sunsea AIoT Technology

Sunwave Communications

Supermicro (Super Micro Computer)

SureSite Consulting Group

Surrey Police

SUSE

Suzhou Police

SWASFT (South Western Ambulance Service NHS Foundation Trust)

Swedish Ministry of Justice

Swedish Police Authority

Swisscom

Swisscom Broadcast

Swissphone

Swoop Aero

Sylincom (Beijing Sylincom Technology)

Synctechno

Syniverse

SYRTEM

SYSCOM (Mexico)

Sysoco (Axians/VINCI Energies)

Systech Corporation

Systel (Systèmes & Télécommunications)

System Innovation Group

Systemics-PAB

T&W (Shenzhen Gongjin Electronics)

T2M

TacSat Networks

Tait Communications

Taiwan Mobile

Taiwan National Police Agency

TAIYO YUDEN

Takaoka Cable Network

Talia Communications

Talk-IP International

Talkpod Technology

Tambora Systems

Tampa Microwave

Tango Networks

Tango Tango

Taoglas

Tarana Wireless

TASSTA

Tata Elxsi

Tatfook (Shenzhen Tatfook Technology)

TBS (Tokyo Broadcasting System) TV

TCCA (The Critical Communications Association)

TCL Communication

TCOM

TCS (Tata Consultancy Services)

TD Tech

TDC NET

TE Connectivity

Teal Communications

Team Telecom Armenia

Tech Mahindra

Techbros

Technicolor

Técnicas Competitivas

Tecom

Tecore Networks

Tejas Networks

TEKTELIC Communications

Telcel (América Móvil)

Telco Systems

Telcoware

Teldat

Tele2

Tele2 Russia

Telecom Namibia

Teleena (Tata Communications MOVE)

Telefield

Telefónica Germany

Telefónica Group

Telefónica Peru

Telefónica Tech

Telefónica UK (Virgin Media O2)

Telekom Slovenije

Telenet

Telenor Group

Telent

Telesat

Telespazio

Teleste

Telesur (Suriname)

Telet Research

Televate

Telewave

Teleworld Solutions

Telia Company

Telia Finland

Telia Norway

Telit

Telkom (PT Telkom Indonesia)

Telkom Kenya

Telkomsel

Tellabs

Tellion

Telna

TELNET Redes Inteligentes

TELOX (Telo Systems)

Telrad Networks

Telsasoft

Telstra

Telstra Purple

Teltonika

Teltronic

Telus

TEOCO

Teracom

Teradek

Teradyne

TeraGo

Tera-Pass

Terranet Communications

TerreStar Corporation

Tessares

TESSCO Technologies/Ventev

Texas A&M University

Texas DPS (Department of Public Safety)

TfL (Transport for London)

TH Lübeck (Technical University of Lübeck)

Thaicom

Thales

Thales Alenia Space

Think Silicon

ThinkRF

Thinnect

THOLEG Civil Protection Systems

Thorcom Systems

Three Private Networks

Three UK

Thundercomm

Thuraya

TI (Texas Instruments)

TIA (Telecommunications Industry Association)

Tianyi (Sichuan Tianyi Comheart Telecom)

Tibco Telecoms

TietoEVRY

Tillman Global Holdings

Tilson

TIM (Telecom Italia Mobile)

TIM Brasil

Tioga Electronic Assembly)

Titan ICT

Titan.ium Platform (Formerly NetNumber)

TJ Innovation

TLC Solutions

TM (Telekom Malaysia)

T-Mobile Czech Republic

T-Mobile Netherlands

T-Mobile Poland

T-Mobile US

TMYTEK (TMY Technology)

TNO (Netherlands Organization for Applied Scientific Research)

TNS (Transaction Network Services)

TO21COMMS

Tofane Global

TOKAI Cable Network Corporation

TOKIE (Irvees Technology)

Tokyo Metropolitan Police Department

TOMIA

Tongyu Communication

ToooAir

Toronto Police Service

Torremolinos Council

Toshiba Corporation

Totogi

TowerJazz

TPG Telecom

TPL Systèmes

TP-Link Technologies

TRA (Telecommunications Regulatory Authority, Bahrain)

Trafikverket (Swedish Transport Administration)

TRAI (Telecom Regulatory Authority of India)

Transatel

Transit Wireless

TransPacket

Tre Sweden

TrellisWare Technologies

TriaSys Technologies Corporation

Trinidad & Tobago Ministry of National Security

TRIOPT

Trópico

TROY Information

TrueMove H (True Corporation)

Truphone

TRX Systems

TSDSI (Telecommunications Standards Development Society, India)

Tsinghua Unigroup

TSMC (Taiwan Semiconductor Manufacturing Company)

Tsofun

TST (Tonami Satellite Communication Television)

TST Systems

T-Systems International

TTA (Telecommunications Technology Association, South Korea)

TTC (Telecommunication Technology Committee, Japan)

TTG International

TTM Technologies

TU Berlin (Technical University of Berlin)

TU Dortmund University

Tupl

Türk Telekom

Turkcell

Turkish Armed Forces

Turkish National Police

TUSUR (Tomsk State University of Control Systems and Radioelectronics)

TÜV SÜD

TWFRS (Tyne and Wear Fire and Rescue Service)

Twilio

Two Six Labs

Tyler Technologies

U Mobile

U.S. Air Force

U.S. Army

U.S. Cellular

U.S. CISA (Cybersecurity and Infrastructure Security Agency)

U.S. Coast Guard

U.S. DHS (Department of Homeland Security)

U.S. DIU (Defense Innovation Unit)

U.S. DOD (Department of Defense)

U.S. DOE (Department of Energy)

U.S. DOJ (Department of Justice)

U.S. FBI (Federal Bureau of Investigation)

U.S. FCC (Federal Communications Commission)

U.S. FEMA (Federal Emergency Management Agency)

U.S. Marine Corps

U.S. National Guard

U.S. Navy

U.S. NIST (National Institute of Standards and Technology)

U.S. NPSTC (National Public Safety Telecommunications Council)

U.S. NSF (National Science Foundation)

U.S. NTIA (National Telecommunications and Information Administration)

UAE Armed Forces

UAE MOI (Ministry of Interior)

UANGEL

UBCS

Ubicquia

Ubiik

UBiqube

Ubiquoss

UBITECH

Ubiwhere

U-Blox

Ucloudy (Shanghai Ucloudy Information Technology)

UCtel

UET (United Electronic Technology)

UfiSpace

UHB (University Hospitals Birmingham NHS Foundation Trust)

ULAK Communication

Ultraband Technologies

UMC (United Microelectronics Corporation)

Umlaut

UMS (United Monolithic Semiconductors)

UN (United Nations)

UNC (University of North Carolina) Health

UNIMO Technology

Union Wireless

UNISOC

UniStrong

UNITAC Technology

United Hatzalah

United Kingdom Home Office

United Kingdom MOD (Ministry of Defence)

University of Adelaide

University of Bologna

University of Glasgow

University of Ljubljana

University of Lübeck

University of Luxembourg

University of Málaga

University of Melbourne

University of Oulu

University of Regina

University of Surrey

University of Tokyo

Unizyx Holding Corporation

UPV/EHU (University of the Basque Country)

UROS

URSYS

US Digital Designs

US Ignite

USI (Universal Scientific Industrial)

USP (University of São Paulo)

UT (University of Tennessee, Knoxville)

Utility (Utility Associates)

UTStarcom

V&M (Venus & Mercury) Telecom

V5 Systems

Valencia City Council

Valid (Brazil)

Valid8

Vancouver Fire Rescue Services

Vantage Towers

Vanu

Vapor IO

Vavitel (Shenzhen Vavitel Technology)

VCS Observation

VDI (Virginia Diodes, Inc.)

Vector Data

Veea

VEON

Verana Networks

Verizon Communications

Verkotan

Versa Networks

Vertel

Vertical Bridge

Vertiv

Verveba Telecom

VHT (Viettel High Tech)

Vi (Vodafone Idea)

Viaero Wireless

ViaPath Technologies (GTL)

Viasat

VIAVI Solutions

Victoria Police

VIDA Technologies

Vientiane Municipal Government

Vigilate

Vilicom

VINCI Energies

Vingroup

VinSmart

Viper RF

Viprinet

ViPRO Corporation

Virginia Tech (Virginia Polytechnic Institute and State University)

Virtual Access

Virtual Access (Ireland)

Virtual Fort Knox

Virtusa Corporation

Visionable

Vislink Technologies

Visual Labs

Vital (New Zealand)

VITES

Vivo

VMware

VNC (Virtual NetCom)

VNL (Vihaan Networks Limited)

Vodacom Group

Vodafone Germany

Vodafone Group

Vodafone Netherlands

Vodafone New Zealand

Vodafone Portugal

Vodafone Spain

Voentelecom

VoiceAge Corporation

Voipfuture

Voxer

VTT Technical Research Centre of Finland

Vubiq Networks

VVDN Technologies

Washington Military Department

Watch Communications

WAV4M

WAVE (AGC)

Wave1

Wave-In Communication

Wavelabs

Wavesight

Wavetel Technology

Waycare

WCCTV (Wireless CCTV)

WDNA (Wireless DNA)

Weaccess Group

Webdyn

WebRadar

Westell Technologies

Westermo Network Technologies

Western Australia Police Force

Wevercomm

Wewins (Shenzhen Wewins Wireless)

wgtwo (Working Group Two)

WH Bence Group

Whale Cloud Technology

Whizz Systems

Widelity

Wien Energie

WIG (Wireless Infrastructure Group)

Wildox (Shenzhen Happy Technology)

Wilson Electronics

Wilus

WIN Connectivity (Wireless Information Networks)

Wind River

Wind Tre

Wingtech Technology

WINITECH

Winmate Communications

Winncom Technologies

WInnForum (Wireless Innovation Forum)

Wipro

Wireless Logic Group

Wireless Technologies Finland

Wireless Telecom Group

WiSig Networks

Wistron Corporation

Wiwynn

WM Systems

WNC (Wistron NeWeb Corporation)

Wolfspeed

WOM Chile

WooriNet

Workz

World View

WorldCell Solutions

Wouxun (Quanzhou Wouxun Electronics)

WTL (World Telecom Labs)

WTW Electronic

Wujiang Public Security Bureau

Wutong Group

WWT (World Wide Technology)

Wytec International

Xantaro

XAVi Technologies Corporation

XCOM Labs

xCraft Enterprises

Xelera Technologies

Xena Networks

Xiamen Puxing Electronics Science & Technology

Xiamen Sanan Integrated Circuit

Xi’an Public Security Bureau

Xiaomi

Xilinx

Xingtera

Xinwei Group

XINYI Information Technology

XipLink

XIUS

YADRO

YAGEO Corporation

Yahsat (Al Yah Satellite Communications)

YaleBTS

Yamareco

Yanton (Quanzhou Yanton Electronics)

YOFC (Yangtze Optical Fibre and Cable)

Yuge Technology (Shanghai Yuge Information Technology)

Zain Group

Zain Saudi Arabia (Zain KSA)

ZaiNar

Zambia Ministry of Home Affairs and Internal Security

Zaram Technology

Zayo Group

Z-Com

Zealync

Zebra Technologies

Zeetta Networks

Zello

ZenFi Networks

Zengyi Technology

Zepcam

Zermatt Bergbahnen

Zero 2 Infinity

ZeroEyes

Zetron

Zhengkai Electronics (Jiangsu Zhengkai Electronics Technology)

Zhengzhou Public Security Bureau

Zhongshan Public Security Bureau

ZILLNK

Zinwave

Zioncom

Zmtel (Shanghai Zhongmi Communication Technology)

ZT Systems

ZTE

ZTV (Japan)

Zyter

Zyxel

The post The Public Safety LTE & 5G Market: 2022 – 2030 – Opportunities, Challenges, Strategies & Forecasts first appeared on CRI Report.

The Shared & Unlicensed Spectrum LTE/5G Network Ecosystem: 2023 – 2030 – Opportunities, Challenges, Strategies & Forecasts

admin — Sat, 16 Jan 2021 07:42:24 +0000

The Shared & Unlicensed Spectrum LTE/5G Network Ecosystem

As the 5G era advances, the cellular communications industry is undergoing a revolutionary paradigm shift, driven by technological innovations, liberal regulatory policies and disruptive business models. One important aspect of this radical transformation is the growing adoption of shared and unlicensed spectrum – frequencies that are not exclusively licensed to a single mobile operator.

Telecommunications regulatory authorities across the globe have either launched or are in the process of releasing innovative frameworks to facilitate the coordinated sharing of licensed spectrum. Examples include but are not limited to the three-tiered CBRS (Citizens Broadband Radio Service) spectrum sharing scheme in the United States, Germany’s 3.7-3.8 GHz and 28 GHz licenses for 5G campus networks, United Kingdom’s shared and local access licensing model, France’s vertical spectrum and sub-letting arrangements, Netherlands’ geographically restricted mid-band spectrum assignments, Switzerland’s 3.4 – 3.5 GHz band for NPNs (Non-Public Networks), Finland’s 2.3 GHz and 26 GHz licenses for local 4G/5G networks, Sweden’s 3.7 GHz and 26 GHz permits, Norway’s regulation of local networks in the 3.8-4.2 GHz band, Poland’s spectrum assignment for local government units and enterprises, Bahrain’s private 5G network licenses, Japan’s 4.6-4.9 GHz and 28 GHz local 5G network licenses, South Korea’s e-Um 5G allocations in the 4.7 GHz and 28 GHz bands, Taiwan’s provision of 4.8-4.9 GHz spectrum for private 5G networks, Hong Kong’s LWBS (Localized Wireless Broadband System) licenses, Australia’s apparatus licensing approach, Canada’s planned NCL (Non-Competitive Local) licensing framework and Brazil’s SLP (Private Limited Service) licenses.

Another important development is the growing accessibility of independent cellular networks that operate solely in unlicensed spectrum by leveraging nationally designated license-exempt frequencies such as the GAA (General Authorized Access) tier of the 3.5 GHz CBRS band in the United States and Japan’s 1.9 GHz sXGP (Shared Extended Global Platform) band. In addition, vast swaths of globally and regionally harmonized license-exempt spectrum – most notably, the 600 MHz TVWS (TV White Space), 5 GHz, 6 GHz and 60 GHz bands – are also available worldwide, which can be used for the operation of unlicensed LTE and 5G NR-U (NR in Unlicensed Spectrum) equipment subject to domestic regulations.

Collectively, ground-breaking spectrum liberalization initiatives are catalyzing the rollout of shared and unlicensed spectrum-enabled 5G NR and LTE networks for a diverse array of use cases – ranging from mobile network densification, FWA (Fixed Wireless Access) in rural communities and MVNO (Mobile Virtual Network Operator) offload to neutral host infrastructure and private cellular networks for enterprises and vertical industries such as agriculture, education, healthcare, manufacturing, military, mining, oil and gas, public sector, retail and hospitality, sports, transportation and utilities.

This report estimates that global investments in 5G NR and LTE-based RAN (Radio Access Network) infrastructure operating in shared and unlicensed spectrum will account for more than $1.4 Billion by the end of 2023. The market is expected to continue its upward trajectory beyond 2023, growing at a CAGR of approximately 27% between 2023 and 2026 to reach nearly $3 Billion in annual spending by 2026.

The “Shared & Unlicensed Spectrum LTE/5G Network Ecosystem: 2023 – 2030 – Opportunities, Challenges, Strategies & Forecasts” report presents a detailed assessment of the shared and unlicensed spectrum LTE/5G network ecosystem, including the value chain, market drivers, barriers to uptake, enabling technologies, key trends, future roadmap, business models, use cases, application scenarios, standardization, spectrum availability and allocation, regulatory landscape, case studies, ecosystem player profiles and strategies. The report also provides global and regional forecasts for shared and unlicensed spectrum LTE/5G RAN infrastructure from 2023 to 2030. The forecasts cover two air interface technologies, two cell type categories, two spectrum licensing models, 15 frequency bands, seven use cases and five regional markets.

The report comes with an associated Excel datasheet suite covering quantitative data from all numeric forecasts presented in the report.

Topics Covered
The report covers the following topics:
– Introduction to shared and unlicensed spectrum LTE/5G networks
– Value chain and ecosystem structure
– Market drivers and challenges
– Enabling technologies and concepts, including CBRS, LSA/eLSA, local area licensing, AFC, 5G NR-U, LTE-U, LAA/eLAA/FeLAA, sXGP and MulteFire
– Key trends such as the growing prevalence of private cellular networks in industrial and enterprise settings, neutral host small cells, fixed wireless broadband rollouts, MVNO offload and mobile network densification
– Business models, use cases and application scenarios
– Future roadmap of shared and unlicensed spectrum LTE/5G networks
– Spectrum availability, allocation and usage across the global, regional and national domains
– Standardization, regulatory and collaborative initiatives
– 100 case studies of 5G NR and LTE deployments in shared and unlicensed spectrum
– Profiles and strategies of more than 400 ecosystem players
– Strategic recommendations for 5G NR and LTE equipment suppliers, system integrators, service providers, enterprises and vertical industries
– Market analysis and forecasts from 2023 to 2030

Forecast Segmentation
Market forecasts for 5G NR and LTE-based RAN equipment operating in shared and unlicensed spectrum are provided for each of the following submarkets and their subcategories:

Air Interface Technologies
– LTE
– 5G NR

Cell Types
– Indoor Small Cells
– Outdoor Small Cells

Spectrum Licensing Models
– Coordinated (Licensed) Shared Spectrum
– Unlicensed (License-Exempt) Spectrum

Frequency Bands
Coordinated (Licensed) Shared Spectrum
– 1.8 GHz
– 2.3-2.6 GHz
– 3.4 GHz
– 3.5 GHz CBRS PAL
– 3.7-3.8 GHz
– 3.8-4.2 GHz
– 4.6-4.9 GHz
– 26/28 GHz
– Other Frequencies

Unlicensed (License-Exempt) Spectrum
– 600 MHz TVWS
– 1.9 GHz sXGP
– 2.4 GHz
– 3.5 GHz CBRS GAA
– 5 GHz
– 6 GHz
– 60 GHz
– Other Frequencies

Use Cases
– Mobile Network Densification
– FWA (Fixed Wireless Access)
– Cable Operators & New Entrants
– Neutral Hosts
– Private Cellular Networks
○ Offices, Buildings & Corporate Campuses
○ Vertical Industries

Regional Markets
– North America
– Asia Pacific
– Europe
– Middle East & Africa
– Latin & Central America

Key Questions Answered
The report provides answers to the following key questions:
– How big is the opportunity for 5G NR and LTE networks operating in shared and unlicensed spectrum?
– What trends, drivers and challenges are influencing its growth?
– What will the market size be in 2026, and at what rate will it grow?
– Which submarkets and regions will see the highest percentage of growth?
– What are the existing and candidate shared/unlicensed spectrum bands for the operation of 5G NR and LTE, and what is the status of their adoption worldwide?
– What are the business models, use cases and application scenarios for shared and unlicensed spectrum?
– How are CBRS and other coordinated shared spectrum frameworks accelerating the uptake of private cellular networks for enterprises and vertical industries?
– How does the integration of shared and unlicensed spectrum relieve capacity constraints faced by traditional mobile operators?
– What opportunities exist for cable operators, neutral hosts, niche service providers and other new entrants?
– How is the commercial availability of 5G NR-based shared and unlicensed spectrum network equipment setting the stage for Industry 4.0 and advanced applications?
– Who are the key ecosystem players, and what are their strategies?
– What strategies should 5G NR and LTE equipment suppliers, system integrators, service providers and other stakeholders adopt to remain competitive?

Key Findings
The report has the following key findings:
– the report estimates that global investments in LTE and 5G NR-based RAN infrastructure operating in shared and unlicensed spectrum will account for more than $1.4 Billion by the end of 2023. The market is expected to continue its upward trajectory beyond 2023, growing at a CAGR of approximately 27% between 2023 and 2026 to reach nearly $3 Billion in annual spending by 2026.
– Breaking away from traditional practices of spectrum assignment for mobile services that predominantly focused on exclusive-use national licenses, telecommunications regulatory authorities across the globe have either launched or are in the process of releasing innovative frameworks to facilitate the coordinated sharing of licensed spectrum. Examples include but are not limited to:
○ The three-tiered CBRS spectrum sharing scheme in the United States
○ Germany’s 3.7-3.8 GHz and 28 GHz licenses for 5G campus networks
○ United Kingdom’s shared and local access licensing model
○ France’s vertical spectrum and sub-letting arrangements
○ Netherlands’ geographically restricted mid-band spectrum assignments
○ Switzerland’s 3.4 – 3.5 GHz band for NPNs (Non-Public Networks)
○ Finland’s 2.3 GHz and 26 GHz licenses for local 4G/5G networks
○ Sweden’s 3.7 GHz and 26 GHz permits, Norway’s regulation of local networks in the 3.8-4.2 GHz band
○ Poland’s spectrum assignment for local government units and enterprises
○ Bahrain’s private 5G network licenses
○ Japan’s 4.6-4.9 GHz and 28 GHz local 5G network licenses
○ South Korea’s e-Um 5G allocations in the 4.7 GHz and 28 GHz bands
○ Taiwan’s provision of 4.8-4.9 GHz spectrum for private 5G networks
○ Hong Kong’s LWBS (Localized Wireless Broadband System) licenses
○ Australia’s apparatus licensing approach
○ Canada’s planned NCL (Non-Competitive Local) licensing framework
○ Brazil’s SLP (Private Limited Service) licenses
– Another important development is the growing accessibility of independent cellular networks that operate solely in unlicensed spectrum by leveraging nationally designated license-exempt frequencies such as the GAA tier of the 3.5 GHz CBRS band in the United States and Japan’s 1.9 GHz sXGP band. In addition, vast swaths of globally and regionally harmonized license-exempt spectrum – most notably, the 600 MHz TVWS, 5 GHz, 6 GHz and 60 GHz bands – are also available worldwide, which can be used for the operation of unlicensed LTE and 5G NR-U (NR in Unlicensed Spectrum) equipment subject to domestic regulations.
– Collectively, ground-breaking spectrum liberalization initiatives are catalyzing the rollout of shared and unlicensed spectrum-enabled LTE and 5G NR networks for a diverse array of use cases – ranging from mobile network densification, FWA in rural communities and MVNO offload to neutral host infrastructure and private cellular networks for enterprises and vertical industries such as agriculture, education, healthcare, manufacturing, military, mining, oil and gas, public sector, retail and hospitality, sports, transportation and utilities.
– In particular, private LTE and 5G networks operating in shared spectrum are becoming an increasingly common theme. Hundreds of local and priority access licenses – predominantly in mid-band spectrum – have been issued in the United States, Germany, United Kingdom, France, Finland, Sweden, Japan, South Korea, Taiwan and other pioneering markets to facilitate the operation of purpose-built wireless networks based on 3GPP standards.
– Airbus, ArcelorMittal, Bayer, BBC (British Broadcasting Corporation), BMW, Bosch, Dow, EDF, Ferrovial, Groupe ADP, Holmen Iggesund, Hoban Construction, Hsinchu City Fire Department, Inventec, John Deere, KEPCO (Korea Electric Power Corporation), Lufthansa, Mercedes-Benz, Mitsubishi, NAVER, NFL (National Football League), Osaka Gas, Ricoh, SDG&E (San Diego Gas & Electric), Siemens, SVT (Sveriges Television), Tesla, Toyota, Volkswagen, X Shore and the U.S. military are just a few of the many end user organizations investing in shared spectrum-enabled private cellular networks.
– In some national markets, neutral host solutions based on shared spectrum small cells are being employed as a cost-effective means of coverage enhancement inside office spaces, public venues and other indoor environments. One prominent example is social media and technology giant Meta’s in-building wireless network that uses small cells operating in the GAA tier of CBRS spectrum and MOCN (Multi-Operator Core Network) technology to provide multi-operator cellular coverage at its properties in the United States.
– Although the uptake of 5G NR equipment operating in high-band mmWave (Millimeter Wave) frequencies has been slower than initially anticipated, practical cases of 5G networks based on locally licensed 26/28 GHz spectrum are steadily piling up in multiple national markets – examples range from private 5G installations at HKIA (Hong Kong International Airport), SMC (Samsung Medical Center) and various manufacturing facilities to Japanese cable TV operator-led deployments of 28 GHz local 5G networks.
– The very first deployments of 5G NR-U technology are also beginning to emerge. For example, the SGCC (State Grid Corporation of China) has deployed a private NR-U network – operating in license-exempt Band n46 (5.8 GHz) spectrum – to support video surveillance, mobile inspection robots and other 5G-connected applications at its Lanzhou East and Mogao substations in China’s Gansu province. In the coming years, with the technology’s commercial maturity, we also anticipate seeing NR-U deployments in Band n96 (6 GHz) and Band n263 (60 GHz) for both licensed assisted and standalone modes of operation.

The post The Shared & Unlicensed Spectrum LTE/5G Network Ecosystem: 2023 – 2030 – Opportunities, Challenges, Strategies & Forecasts first appeared on CRI Report.

LTE & 5G NR in Unlicensed Spectrum: 2020 – 2030 – Opportunities, Challenges, Strategies & Forecasts

admin — Sat, 16 Jan 2021 07:28:36 +0000

Over the past decade, the operation of 3GPP-based cellular networks in unlicensed spectrum has gone from being a perennial talking point to what is now a key element of mobile network densification strategies. Mobile operators across the globe are increasingly rolling out LTE RAN (Radio Access Network) infrastructure operating in unlicensed spectrum – primarily the globally harmonized 5 GHz band – to expand network capacity and deliver higher data rates, particularly in dense urban environments. These implementations are largely based on LAA (Licensed Assisted Access) technology which aggregates unlicensed channels with anchors in licensed spectrum to maintain seamless and reliable connectivity.

However, the practical applicability of unlicensed spectrum is not limited to the capacity enhancement of traditional mobile operator networks. Technical and regulatory initiatives such as MulteFire, CBRS (Citizens Broadband Radio Service) and sXGP (Shared Extended Global Platform) make it possible for enterprises, vertical industries, third-party neutral hosts and other new entrants to build and operate their own independent cellular networks solely in unlicensed spectrum without requiring an anchor carrier in licensed spectrum. Furthermore, in conjunction with the availability of new license-exempt frequencies such as the recently opened 6 GHz band from 5925 MHz to 7125 MHz, the introduction of 5G NR-U in 3GPP’s Release 16 specifications paves the way for 5G NR deployments in unlicensed spectrum for both licensed assisted and standalone modes of operation. Given 5G’s inherent support for reliability and time-sensitive networking, NR-U is particularly well suited to meet industrial IoT requirements for the automation and digitization of environments such as factories, warehouses, ports and mining sites.

Despite the economic slowdown due to the COVID-19 pandemic, competition from non-3GPP wireless technologies and other challenges, SNS Telecom & IT estimates that global investments in LTE and 5G NR-ready RAN infrastructure operating in unlicensed spectrum will reach nearly $500 Million by the end of 2020. The market is further expected to grow at a CAGR of approximately 40% between 2020 and 2023, eventually accounting for $1.3 Billion by 2023.

The “LTE & 5G NR in Unlicensed Spectrum: 2020 – 2030 – Opportunities, Challenges, Strategies & Forecasts” report presents a detailed assessment of the market for LTE and 5G NR in unlicensed spectrum including the value chain, market drivers, barriers to uptake, enabling technologies, key trends, future roadmap, business models, use cases, application scenarios, standardization, spectrum availability/allocation, regulatory landscape, case studies, ecosystem player profiles and strategies. The report also provides global and regional forecasts for unlicensed LTE and 5G NR RAN infrastructure from 2020 till 2030. The forecasts cover two air interface technologies, two modes of operation, two cell type categories, seven frequency band ranges, seven use cases and five regional markets.

The report comes with an associated Excel datasheet suite covering quantitative data from all numeric forecasts presented in the report.

Topics Covered
The report covers the following topics:
– Introduction to LTE and 5G NR in unlicensed spectrum
– Value chain and ecosystem structure
– Market drivers and challenges
– Enabling technologies and concepts including LTE-U, LAA/eLAA/FeLAA, 5G NR-U, MulteFire, CBRS and sXGP
– Key trends such as mobile network densification, neutral host small cells, private cellular networks for enterprises and vertical industries, and the availability of new unlicensed bands
– Future roadmap of LTE and 5G NR in unlicensed spectrum
– Business models, use cases and application scenarios
– Spectrum availability, allocation and usage across the global, regional and national domains
– Standardization, regulatory and collaborative initiatives
– Case studies of LTE and 5G NR-ready deployments in unlicensed spectrum
– Profiles and strategies of more than 280 ecosystem players
– Strategic recommendations for LTE and 5G NR equipment suppliers, system integrators, service providers, enterprises and vertical industries
– Market analysis and forecasts from 2020 till 2030

Forecast Segmentation
Market forecasts for LTE and 5G NR-based RAN equipment operating in unlicensed spectrum are provided for each of the following submarkets and their subcategories:

Air Interface Technologies
– Unlicensed LTE
– 5G NR-U

Modes of Operation
– Standalone Operation
– LAA (Licensed Assisted Access)

Cell Types
– Indoor Small Cells
– Outdoor Small Cells

Frequency Bands
– Sub-1 GHz
– 1.9 GHz sXGP
– 2.4 GHz
– 3.5 GHz CBRS GAA
– 5 GHz
– 6 GHz
– Higher Frequencies

Regional Markets
– North America
– Asia Pacific
– Europe
– Middle East & Africa
– Latin & Central America

Key Questions Answered
The report provides answers to the following key questions:
– How big is the opportunity for LTE and 5G NR in unlicensed spectrum?
– What trends, drivers and challenges are influencing its growth?
– What will the market size be in 2023, and at what rate will it grow?
– Which submarkets and regions will see the highest percentage of growth?
– What are the existing and candidate unlicensed spectrum bands for the operation of LTE and 5G NR, and what is the status of their adoption worldwide?
– What is the outlook for the recently opened 6 GHz greenfield spectrum and license-exempt bands in higher frequencies?
– What are the business models, use cases and application scenarios for LTE and 5G NR networks operating in unlicensed spectrum?
– How does the integration of unlicensed spectrum relieve capacity constraints faced by traditional mobile operators?
– What opportunities exist for cable operators, neutral hosts, niche service providers and other new entrants?
– How will unlicensed spectrum accelerate the uptake of private cellular networks for enterprises and vertical industries?
– How does standardization impact the deployment of LTE and 5G NR in unlicensed spectrum?
– What are the functional capabilities of 5G NR-U based on the 3GPP’s Release 16 specifications, and which NR-U feature enhancements are likely to be supported in Release 17?
– Do Wi-Fi and other non-3GPP technologies operating in unlicensed spectrum pose a threat to LTE and 5G NR?
– Who are the key ecosystem players, and what are their strategies?
– What strategies should LTE and 5G NR equipment suppliers, system integrators, service providers and other stakeholders adopt to remain competitive?

Key Findings
The report has the following key findings:
– Despite the economic slowdown due to the COVID-19 pandemic, competition from non-3GPP wireless technologies and other challenges, SNS Telecom & IT estimates that global investments in LTE and 5G NR-ready RAN infrastructure operating in unlicensed spectrum will reach nearly $500 Million by the end of 2020. The market is further expected to grow at a CAGR of approximately 40% between 2020 and 2023, eventually accounting for $1.3 Billion by 2023.
– As part of their network densification efforts, mobile operators across the globe are increasingly employing the use of LAA technology to aggregate licensed spectrum assets with unlicensed frequencies – primarily the globally harmonized 5 GHz band – in order to deliver higher data rates and alleviate capacity constraints across the most congested parts of their networks.
– With the possibility to leverage the 3.5 GHz CBRS band on a GAA (General Authorized Access) basis in the United States and the availability of Japan’s license-exempt 1.9 GHz sXGP band, independent cellular networks that can operate solely in unlicensed spectrum – without requiring an anchor carrier in licensed spectrum – are beginning to emerge as well. In addition, it is worth noting that a limited number of custom-built, standalone LTE networks operating in the unlicensed 2.4 GHz and 5 GHz bands are operational in certain national markets, predominantly for industrial IoT applications.
– In the coming years, with the commercial maturity of 5G NR-U technology, we also anticipate to see 5G NR deployments in unlicensed spectrum for both licensed assisted and standalone modes of operation – using the 3.5 GHz CBRS, 5 GHz, 6 GHz and higher frequency bands up to 71 GHz.

The post LTE & 5G NR in Unlicensed Spectrum: 2020 – 2030 – Opportunities, Challenges, Strategies & Forecasts first appeared on CRI Report.

LTE & 5G NR-Based CBRS Networks: 2020 – 2030 – Opportunities, Challenges, Strategies & Forecasts

admin — Fri, 04 Dec 2020 02:39:54 +0000

After many years of regulatory, standardization and technical implementation activities, the United States’ dynamic, three-tiered, hierarchical framework to coordinate shared use of 150 MHz of spectrum in the 3.5 GHz CBRS (Citizens Broadband Radio Service) band has finally become a commercial reality. Although the shared spectrum arrangement is access technology neutral, the 3GPP cellular wireless ecosystem is at the forefront of CBRS adoption given the desirability of mid-band spectrum for both LTE and 5G NR network buildouts due its optimal blend of propagation characteristics and capacity.

Following authorization of FCD (Full Commercial Deployment) by the FCC (Federal Communications Commission) and completion of the recent PAL (Priority Access License) auction, LTE-based CBRS network deployments are beginning to gain considerable momentum, with thousands of operational cell sites throughout the United States to support use cases as diverse as mobile network densification, FWA (Fixed Wireless Access), neutral host infrastructure, and private cellular networks for enterprises and vertical industries. In the coming years, we also anticipate the rollout of 5G NR network equipment operating in the CBRS band, which will lay the foundations for advanced application scenarios with more demanding performance requirements in terms of throughput, latency, reliability, availability and connection density – for example, industrial IoT applications such as connected production machinery, mobile robotics, AGVs (Automated Guided Vehicles) and AR (Augmented Reality)-assisted troubleshooting.

The CBRS market remains largely unfazed by the economic disruption associated with the COVID-19 pandemic, with the exception of certain enterprise and vertical submarkets. SNS Telecom & IT estimates that annual investments in LTE and 5G NR-based CBRS RAN (Radio Access Network) infrastructure will account for more than $300 Million by the end of 2020. Complemented by an expanding selection of CBRS-equipped end user devices, the market is further expected to grow at a CAGR of approximately 52% between 2020 and 2023 to surpass $1 Billion in annual spending by 2023.

The “LTE & 5G NR-Based CBRS Networks: 2020 – 2030 – Opportunities, Challenges, Strategies & Forecasts” report presents a detailed assessment of the market for LTE and 5G NR in CBRS spectrum including the value chain, market drivers, barriers to uptake, enabling technologies, key trends, future roadmap, business models, use cases, application scenarios, standardization, regulatory landscape, case studies, ecosystem player profiles and strategies. The report also provides forecasts for LTE and 5G NR-based CBRS RAN infrastructure and terminal equipment from 2020 till 2030. The forecasts cover two air interface technologies, two cell type categories, five device form factors, seven use cases and ten vertical industries.

The report comes with an associated Excel datasheet suite covering quantitative data from all numeric forecasts presented in the report.

Topics Covered
The report covers the following topics:
– Introduction to LTE and 5G NR-based CBRS networks
– Value chain and ecosystem structure
– Market drivers and challenges
– Technical aspects including CBRS spectrum sharing rules, system architecture, functional elements, core network integration and security
– Key trends such as mobile network densification, LTE and 5G NR-based fixed wireless broadband rollouts, neutral host small cell infrastructure for a variety of venues, and the growing prevalence of private cellular networks to support enterprise and industrial IoT applications
– Future roadmap of LTE and 5G NR in CBRS spectrum
– Business models, use cases and application scenarios
– Standardization, regulatory and collaborative initiatives
– Case studies of LTE and 5G NR-based CBRS network deployments
– Profiles and strategies of more than 270 ecosystem players
– Strategic recommendations for LTE and 5G NR equipment suppliers, system integrators, service providers, enterprises and vertical industries
– Market analysis and forecasts from 2020 till 2030

Forecast Segmentation
Market forecasts are provided for each of the following submarkets and their subcategories:

CBRS RAN Infrastructure
Air Interface Technologies
– LTE
– 5G NR

Cell Types
– Indoor Small Cells
– Outdoor Small Cells

Vertical Industries for Private Cellular Networks
– Manufacturing
– Transportation
– Utilities
– Mining
– Oil & Gas
– Healthcare
– Education
– Retail & Hospitality
– Government & Municipalities
– Other Verticals

CBRS Terminal Equipment
Air Interface Technologies
– LTE
– 5G NR

Form Factors
– Smartphones & Handheld Terminals
– Mobile & Vehicular Routers
– Fixed CPEs (Customer Premises Equipment)
– Tablets & Notebook PCs
– IoT Modules, Dongles & Others

Key Questions Answered
The report provides answers to the following key questions:
– How big is the opportunity for LTE and 5G NR-based CBRS networks?
– What trends, drivers and challenges are influencing its growth?
– What will the market size be in 2023, and at what rate will it grow?
– Which submarkets will see the highest percentage of growth?
– What are the business models, use cases and application scenarios for CBRS networks?
– How does the integration of CBRS spectrum relieve capacity constraints faced by traditional mobile operators?
– What opportunities exist for cable operators, neutral hosts, niche service providers and other new entrants?
– How will CBRS accelerate the uptake of private cellular networks for enterprises and vertical industries?
– What is the impact of the COVID-19 pandemic on CBRS network buildouts?
– When will 5G NR-based CBRS network equipment begin to be deployed in large volumes?
– What are the prospects of non-3GPP technologies in CBRS spectrum?
– Who are the key ecosystem players, and what are their strategies?
– What strategies should CBRS equipment suppliers, system integrators, service providers and other stakeholders adopt to remain competitive?

Key Findings
The report has the following key findings:
– The CBRS market remains largely unfazed by the economic disruption associated with the COVID-19 pandemic, with the exception of certain enterprise and vertical submarkets. SNS Telecom & IT estimates that annual investments in LTE and 5G NR-based CBRS RAN infrastructure will account for more than $300 Million by the end of 2020.
– Complemented by an expanding selection of CBRS-equipped end user devices, the market is further expected to grow at a CAGR of approximately 52% between 2020 and 2023 to surpass $1 Billion in annual spending by 2023.
– LTE-based CBRS network deployments are beginning to gain considerable momentum, with thousands of operational cell sites throughout the United States to support use cases as diverse as mobile network densification, FWA, neutral host infrastructure, and private cellular networks for enterprises and vertical industries.
– We expect initial rollouts of 5G NR network equipment in the CBRS band to commence in 2021, paving the way for industrial IoT and other advanced application scenarios with demanding performance requirements in terms of throughput, latency, reliability, availability and connection density.

The post LTE & 5G NR-Based CBRS Networks: 2020 – 2030 – Opportunities, Challenges, Strategies & Forecasts first appeared on CRI Report.

LTE & 5G for Critical Communications: 2020 – 2030 – Opportunities, Challenges, Strategies & Forecasts

admin — Tue, 20 Oct 2020 06:05:20 +0000

For nearly a century, the critical communications industry has relied on narrowband LMR (Land Mobile Radio) networks for mission-critical voice and low-speed data services. Over time, these systems have evolved from relatively basic analog radios to digital communications technologies, such as P25 (Project 25) and TETRA, to provide superior voice quality, end-to-end encryption and other advanced features. However, due to their inherent bandwidth and design limitations, even the most sophisticated digital LMR networks are unable to support mobile broadband and data-driven industrial IoT applications that have become vital for public safety, military, utilities, transportation, oil and gas, mining and other segments of the critical communications industry.

The 3GPP-defined LTE and 5G NR standards have emerged as the leading candidates to fill this void. Over the last decade, a plethora of dedicated, hybrid commercial-private and MVNO-based 3GPP networks have been deployed to deliver critical communications broadband capabilities – in addition to the use of commercial mobile operator networks – for application scenarios as diverse as PTT group communications, real-time mobile video surveillance, AR/VR (Augmented & Virtual Reality), wirelessly connected robotics, and automation in industrial environments. These networks range from nationwide public safety broadband platforms such as the United States’ FirstNet (First Responder Network), South Korea’s Safe-Net (National Disaster Safety Communications Network) and Britain’s ESN (Emergency Services Network) to regional cellular networks covering the service footprint of utility companies and localized wireless systems in settings such as railroads, airports, maritime ports, oil and gas production facilities, remote mining sites, factories and warehouses.

At present, most critical communications user organizations employ LTE and 5G NR as complementary technologies to augment existing voice-centric LMR networks with broadband capabilities. However, with the standardization and commercial availability of MCX (Mission-Critical PTT, Video & Data), IOPS (Isolated Operation for Public Safety), HPUE (High-Power User Equipment) and other 3GPP-defined critical communications features, LTE and 5G NR networks are increasingly gaining recognition as an all-inclusive critical communications platform for the delivery of mobile broadband and industrial IoT capabilities, as well as MCPTT (Mission-Critical PTT) voice functionality comparable to that offered by traditional LMR systems.

Despite the economic slowdown due to the COVID-19 pandemic and other challenges, SNS Telecom & IT estimates that global investments in LTE and 5G network infrastructure for critical communications will surpass $3 Billion by the end of 2020. The market is further expected to grow at a CAGR of approximately 13% between 2020 and 2023, eventually accounting for nearly $5 Billion by 2023.

Spanning over 2,000 pages, the “LTE & 5G for Critical Communications: 2020 – 2030 – Opportunities, Challenges, Strategies & Forecasts” report package encompasses two comprehensive reports covering the use of LTE and 5G NR networks for critical communications.

– The Private LTE & 5G Network Ecosystem: 2020 – 2030 – Opportunities, Challenges, Strategies, Industry Verticals & Forecasts

– The Public Safety LTE & 5G Market: 2020 – 2030 – Opportunities, Challenges, Strategies & Forecasts

This report package provides an in-depth assessment of LTE and 5G for critical communications including the value chain, market drivers, barriers to uptake, enabling technologies, key trends, future roadmap, vertical sectors, application scenarios, standardization, spectrum availability/allocation, regulatory landscape, case studies, ecosystem player profiles and strategies, as well as LTE and 5G network infrastructure investment forecasts from 2020 till 2030.

The report package comes with an associated Excel datasheet suite covering quantitative data from all numeric forecasts presented in both reports.

Topics Covered
The report package covers the following topics:

Report 1: The Private LTE & 5G Network Ecosystem: 2020 – 2030 – Opportunities, Challenges, Strategies, Industry Verticals & Forecasts
– Private LTE and 5G network ecosystem
– Market drivers and barriers
– System architecture and key elements of private LTE and 5G networks
– Analysis of vertical markets and applications – ranging from mobile broadband and mission-critical voice to domain-specific applications such as CBTC (Communications-Based Train Control) and connected robotics for factory automation
– Operational models for private LTE and 5G networks including independent, managed, shared core, hybrid commercial-private and private MVNO networks
– Mission-critical PTT/video/data services, deployable LTE/5G systems, cellular IoT, TSN (Time Sensitive Networking), URLLC (Ultra-Reliable Low-Latency Communications) techniques, quantum cryptography, unlicensed/shared spectrum, neutral-host/multi-operator small cells, network slicing, MEC (Multi-Access Edge Computing) and other enabling technologies
– Key trends including the adoption of local and shared spectrum licensing, commercial readiness of private 5G systems for Industry 4.0, nationwide and city-wide public safety broadband network build-outs, regional mission/business-critical LTE networks for utilities and energy companies, localized private LTE/5G networks for railway infrastructure, ports, airports, mines, factories, warehouses, buildings, campuses and public venues, and pioneering neutral-host business models for enterprise and public wireless connectivity.
– Review of private LTE and 5G network engagements worldwide, including case studies of more than 40 live networks
– Spectrum availability, allocation and usage for private LTE and 5G networks across the global, regional and national regulatory domains
– Standardization, regulatory and collaborative initiatives
– Future roadmap and value chain
– Profiles and strategies of over 600 ecosystem players including LTE/5G network infrastructure suppliers and vertical-domain specialists
– Strategic recommendations for end users, LTE/5G network infrastructure suppliers, system integrators and commercial/private mobile operators
– Market analysis and forecasts from 2020 till 2030

Report 2: The Public Safety LTE & 5G Market: 2020 – 2030 – Opportunities, Challenges, Strategies & Forecasts
– Public safety LTE and 5G ecosystem
– Market drivers and barriers
– System architecture and key elements of public safety LTE and 5G systems
– Analysis of public safety broadband application scenarios and use cases – ranging from mission-critical group communications and real-time video transmission to 5G era applications centered upon UHD (Ultra High Definition Video), AR/VR/MR (Augmented, Virtual & Mixed Reality), drones and robotics
– Operational models for public safety LTE and 5G networks including commercial, independent, managed, shared core, hybrid commercial-private and secure MVNO networks
– PPPs (Public-Private Partnerships) and other common approaches to financing and delivering dedicated public safety LTE and 5G networks
– MCX (Mission-Critical PTT, Video & Data), IOPS (Isolated Operation for Public Safety), deployable LTE/5G systems, ProSe (Proximity Services) for D2D (Device-to-Device) communications, HPUE (High Power User Equipment), QPP (QoS, Priority & Preemption), network slicing, end-to-end security, high-precision positioning, 3GPP access over satellite/NTN (Non-Terrestrial Networking) platforms and other enabling technologies
– Key trends including hybrid RAN (Radio Access Network) implementations for nationwide public safety broadband networks, local and city-level LTE deployments to support police forces in developing countries, adoption of sub-500 MHz spectrum for mission-critical LTE networks, commercial readiness of 3GPP-compliant MCX functionality, LMR-based interim solutions for off-network communications, secure MVNO solutions with cross-border roaming, mobile operator-branded critical communications broadband platforms, 5G NR connectivity for applications requiring higher data rates and lower latencies, and localized 5G NR networks for incident scene management
– Review of public safety LTE/5G engagements worldwide including a detailed assessment of 10 nationwide public safety broadband projects and additional case studies of over 40 dedicated, hybrid, MVNO and commercial operator-supplied systems
– Spectrum availability, allocation and usage for public safety LTE and 5G networks across the global, regional and national regulatory domains
– Standardization, regulatory and collaborative initiatives
– Future roadmap and value chain
– Profiles and strategies of 1,100 ecosystem players including LTE/5G equipment suppliers and public safety-domain specialists
– Strategic recommendations for public safety and government agencies, LTE/5G infrastructure, device and chipset suppliers, LMR vendors, system integrators, and commercial/private mobile operators
– Market analysis and forecasts from 2020 till 2030

Key Questions Answered
The report package provides answers to the following key questions:
– How big is the opportunity for LTE and 5G in the critical communications industry?
– What trends, drivers and barriers are influencing its growth?
– How is the ecosystem evolving by segment and region?
– What will the market size be in 2023, and at what rate will it grow?
– Which vertical markets and regions will see the highest percentage of growth?
– What is the status of dedicated, hybrid commercial-private and secure MVNO-based critical communications broadband networks worldwide?
– What are the existing and candidate licensed, unlicensed and shared spectrum bands for the operation of private LTE and 5G networks?
– What opportunities exist for commercial mobile operators in the critical communications domain?
– What are the key applications of LTE and 5G for public safety, military, utilities, transportation, oil and gas, mining and other verticals?
– Will FirstNet, Safe-Net, ESN and other nationwide public safety broadband networks eventually replace existing digital LMR networks?
– When will LTE and 5G supersede GSM-R as the predominant radio bearer for railway communications?
– How does standardization impact the adoption of LTE and 5G for critical communications and industrial IoT?
– When will MCX, IOPS, HPUE and other 3GPP-defined critical communications features be widely employed in LTE and 5G networks?
– How will the integration of TSN enable 5G networks to deliver reliable, low-latency connectivity across a broad range of time-critical industrial IoT applications?
– Who are the key ecosystem players, and what are their strategies?
– What strategies should LTE/5G equipment suppliers, system integrators, vertical-domain specialists and mobile operators adopt to remain competitive?

The post LTE & 5G for Critical Communications: 2020 – 2030 – Opportunities, Challenges, Strategies & Forecasts first appeared on CRI Report.

The Public Safety LTE & 5G Market: 2020 – 2030 – Opportunities, Challenges, Strategies & Forecasts

admin — Tue, 20 Oct 2020 05:56:59 +0000

New Version Released:

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.

Public Safety LTE & 5G Market

With the standardization of MCX (Mission-Critical PTT, Video & Data), IOPS (Isolated Operation for Public Safety), HPUE (High-Power User Equipment) and other critical communications features by the 3GPP, LTE and 5G NR (New Radio) networks are increasingly gaining recognition as an all-inclusive public safety communications platform for the delivery of real-time video, high-resolution imagery, multimedia messaging, mobile office/field data applications, location services and mapping, situational awareness, unmanned asset control and other broadband capabilities, as well as MCPTT (Mission-Critical PTT) voice and narrowband data services provided by traditional LMR (Land Mobile Radio) systems.

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 Korea’s Safe-Net and Britain’s ESN nationwide public safety broadband projects, many additional national-level engagements have recently come to light – most notably, the Royal Thai Police’s LTE network which is already operational in the greater Bangkok region, Finland’s VIRVE 2.0 mission-critical mobile broadband service, France’s PCSTORM critical communications broadband project, and Russia’s secure 450 MHz LTE network for police forces, emergency services and the national guard.

Global Private LTE and 5G network Market to Surge at 15.85 % CAGR, which is anticipated to reach USD 13.23 billion by 2030

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 D’Ivoire, 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 MRC’s (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 3GPP’s Release 17 specifications, public safety agencies have already begun experimenting with 5G for applications that can benefit from the technology’s high-bandwidth and low-latency characteristics.

For example, New Zealand Police are utilizing mobile operator Vodafone’s 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.

We 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 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 Q2’2020.

Topics Covered

The report covers the following topics:
– Public safety LTE and 5G ecosystem
– Market drivers and barriers
– System architecture and key elements of public safety LTE and 5G systems
– Analysis of public safety broadband application scenarios and use cases – ranging from mission-critical group communications and real-time video transmission to 5G era applications centered upon UHD (Ultra High Definition Video), AR/VR/MR (Augmented, Virtual & Mixed Reality), drones and robotics
– Operational models for public safety LTE and 5G networks including commercial, independent, managed, shared core, hybrid commercial-private and secure MVNO networks
– PPPs (Public-Private Partnerships) and other common approaches to financing and delivering dedicated public safety LTE and 5G networks
– MCX (Mission-Critical PTT, Video & Data), IOPS (Isolated Operation for Public Safety), deployable LTE/5G systems, ProSe (Proximity Services) for D2D (Device-to-Device) communications, HPUE (High Power User Equipment), QPP (QoS, Priority & Preemption), network slicing, end-to-end security, high-precision positioning, 3GPP access over satellite/NTN (Non-Terrestrial Networking) platforms and other enabling technologies
– Key trends including hybrid RAN (Radio Access Network) implementations for nationwide public safety broadband networks, local and city-level LTE deployments to support police forces in developing countries, adoption of sub-500 MHz spectrum for mission-critical LTE networks, commercial readiness of 3GPP-compliant MCX functionality, LMR-based interim solutions for off-network communications, secure MVNO solutions with cross-border roaming, mobile operator-branded critical communications broadband platforms, 5G NR connectivity for applications requiring higher data rates and lower latencies, and localized 5G NR networks for incident scene management
– Review of public safety LTE/5G engagements worldwide including a detailed assessment of 10 nationwide public safety broadband projects and additional case studies of over 40 dedicated, hybrid, MVNO and commercial operator-supplied systems
– Spectrum availability, allocation and usage for public safety LTE and 5G networks across the global, regional and national regulatory domains
– Standardization, regulatory and collaborative initiatives
– Future roadmap and value chain
– Profiles and strategies of 1,100 ecosystem players including LTE/5G equipment suppliers and public safety-domain specialists
– Strategic recommendations for public safety and government agencies, LTE/5G infrastructure, device and chipset suppliers, LMR vendors, system integrators, and commercial/private mobile operators
– Market analysis and forecasts from 2020 till 2030

Forecast Segmentation

Market forecasts are provided for each of the following submarkets and their subcategories:

Public Safety LTE & 5G Network Infrastructure
Submarkets
– RAN (Radio Access Network)
– Mobile Core
– Backhaul & Transport

Technology Generations
– LTE
– 5G NR

RAN Base Station (eNB/gNB) Cell Sizes
– Macrocells
– Small Cells

RAN Base Station (eNB/gNB) Mobility Categories
– Fixed Base Stations
– Deployable Base Stations

Deployable RAN Base Station (eNB/gNB) Form Factors
– NIB (Network-in-a-Box)
– Vehicular COWs (Cells-on-Wheels)
– Aerial Cell Sites
– Maritime Platforms

Backhaul & Transport Network Transmission Mediums
– Fiber & Wireline
– Microwave
– Satellite

Public Safety LTE & 5G Terminal Equipment
Technology Generations
– LTE
– 5G NR

Form Factors
– Smartphones & Handportable Terminals
– Mobile & Vehicular Routers
– Fixed CPEs (Customer Premises Equipment)
– Tablets & Notebook PCs
– Smart Wearables
– IoT Modules, Dongles & Others

Public Safety LTE & 5G Subscriptions/Service Revenue
Technology Generations
– LTE
– 5G NR

Network Types
– Dedicated & Hybrid Commercial-Private Networks
– Secure MVNO Networks
– Commercial Mobile Networks

Public Safety LTE & 5G Systems Integration & Management Solutions
Submarkets
– Network Integration & Testing
– Device Management & User Services
– Managed Services, Operations & Maintenance
– Cybersecurity

Public Safety Broadband Applications
Submarkets
– Mission-Critical Voice & Group Communications
– Real-Time Video Transmission
– Messaging, File Transfer & Presence Services
– Mobile Office & Field Applications
– Location Services & Mapping
– Situational Awareness
– Command & Control
– AR/VR/MR (Augmented, Virtual & Mixed Reality)

Regional Markets
– North America
– Asia Pacific
– Europe
– Middle East & Africa
– Latin & Central America

Key Questions Answered

The report provides answers to the following key questions:
– How big is the public safety LTE and 5G opportunity?
– What trends, drivers and barriers are influencing its growth?
– How is the ecosystem evolving by segment and region?
– What will the market size be in 2023, and at what rate will it grow?
– Which regions and submarkets will see the highest percentage of growth?
– What is the status of dedicated, hybrid commercial-private and secure MVNO-based public safety broadband networks worldwide?
– What are the key application scenarios and use cases of LTE and 5G for first responders?
– When will FirstNet, Safe-Net, ESN and other nationwide public safety broadband networks replace existing digital LMR systems?
– What opportunities exist for commercial mobile operators and critical communications service providers?
– What are the future prospects of NIB (Network-in-a-Box), COWs (Cell-on-Wheels), drone-mounted aerial cells and other rapidly deployable LTE and 5G NR systems?
– How does standardization impact the adoption of LTE and 5G for public safety communications?
– When will MCX, IOPS, ProSe, HPUE and other 3GPP-defined critical communications features be widely employed in public safety broadband networks?
– How will network slicing provide dynamic QoS guarantees and isolation for public safety applications in 5G networks?
– What are the existing and candidate frequency bands for the operation of public safety broadband networks?
– How can public safety stakeholders leverage excess spectrum capacity to ensure the economic viability of dedicated LTE and LTE networks?
– Who are the key ecosystem players, and what are their strategies?
– What strategies should LTE/5G infrastructure suppliers, LMR vendors, system integrators and mobile operators adopt to remain competitive?

Key Findings

The report has the following key findings:
– This report 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 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.

– Public safety LTE networks are playing an integral role in ongoing response efforts to combat the global COVID-19 pandemic. For example, in the United States, the FirstNet communications platform is being leveraged to deliver prioritized voice, data, video and location services for first responders and medical personnel – including mobile telehealth applications to facilitate remote screening and monitoring, as well as temporary coverage and capacity expansion for pop-up testing sites, quarantine centers and healthcare facilities using rapidly deployable cellular assets and in-building wireless systems.

– In addition to the high-profile FirstNet, South Korea’s Safe-Net and Britain’s ESN nationwide public safety broadband projects, many additional national-level engagements have recently come to light – most notably, the Royal Thai Police’s LTE network which is already operational in the greater Bangkok region, Finland’s VIRVE 2.0 mission-critical mobile broadband service, France’s PCSTORM critical communications broadband project, and Russia’s 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 D’Ivoire, 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 MRC’s (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.

– Although the aforementioned references to several developing economies in the list of early adopters may come as a surprise, the lack of well-established digital LMR systems in many of these countries makes it possible to leapfrog directly from ageing analog technologies to LTE-based critical communications networks for both voice and broadband services, without the complex and time-consuming challenges associated with transitioning from large-scale and nationwide digital LMR networks.

– In much of the developed world, digital LMR networks are unlikely to be fully replaced by LTE and 5G until the late 2020s to early 2030s, especially in markets where large-scale systems have been rolled out or upgraded recently – for example, Germany’s BDBOS, Norway’s Nodnett and the Netherlands’ C2000 TETRA networks.

– Leveraging their extensive LTE/5G NR-capable cellular infrastructure assets and technical expertise, mobile operators have managed to establish a foothold in the public safety broadband market – with active involvement in some of the largest public safety LTE/5G engagements using both commercial and dedicated public safety spectrum.

– Dozens of vendors have already developed both client and application server implementations that are compliant with 3GPP’s MCPTT, MCVideo and MCData specifications. Frontrunner customers – for example, South Korea’s National Police Agency – have already begun transitioning to 3GPP-compliant MCX functionality, and we expect to see larger production-grade rollouts of the technology – beginning with MCPTT – in 2020.

– Due to the commercial immaturity of 3GPP-specified ProSe (Proximity Services) functionality, a number of interim solutions are being employed to fulfill direct mode, off-network communications requirements. These range from hybrid TETRA/P25-LTE capable terminals to LMR-based RSMs (Remote Speaker Microphones) and detachable accessories that attach to existing LTE devices to facilitate D2D communications over a sufficient coverage radius.

– Even though critical public safety-related 5G NR capabilities are yet to be standardized as part of the 3GPP’s Release 17 specifications, public safety agencies have already begun experimenting with 5G for applications that can benefit from the technology’s high-bandwidth and low-latency characteristics. For example, New Zealand Police are utilizing mobile operator Vodafone’s 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.

– As public safety-grade 5G implementations become well-established in the 2020s, real-time UHD video transmission through coordinated fleets of drones, 5G-equipped autonomous police robots, smart ambulances, AR (Augmented Reality) firefighting helmets and other sophisticated public safety broadband applications will become a common sight.

The post The Public Safety LTE & 5G Market: 2020 – 2030 – Opportunities, Challenges, Strategies & Forecasts first appeared on CRI Report.

LTE – CRI Report

SON (Self-Organizing Networks) in the 5G & Open RAN Era: 2022 – 2030 – Opportunities, Challenges, Strategies & Forecasts

Self-Organizing Networks in the 5G & Open RAN Era

Topics Covered

Forecast Segmentation

Key Questions Answered

Key Findings

The Public Safety LTE & 5G Market: 2022 – 2030 – Opportunities, Challenges, Strategies & Forecasts

Synopsis

Summary of Recent Market Developments

North America

Asia Pacific

Europe

Other Regions

Topics Covered

Forecast Segmentation:

Public Safety LTE & 5G Network Infrastructure

Public Safety LTE & 5G Subscriptions/Service Revenue

Public Safety LTE & 5G Systems Integration & Management Solutions

Public Safety Broadband Applications

Key Questions Answered

Table of Contents

The Shared & Unlicensed Spectrum LTE/5G Network Ecosystem: 2023 – 2030 – Opportunities, Challenges, Strategies & Forecasts

The Shared & Unlicensed Spectrum LTE/5G Network Ecosystem

LTE & 5G NR in Unlicensed Spectrum: 2020 – 2030 – Opportunities, Challenges, Strategies & Forecasts

LTE & 5G NR-Based CBRS Networks: 2020 – 2030 – Opportunities, Challenges, Strategies & Forecasts

LTE & 5G for Critical Communications: 2020 – 2030 – Opportunities, Challenges, Strategies & Forecasts

The Public Safety LTE & 5G Market: 2020 – 2030 – Opportunities, Challenges, Strategies & Forecasts

Public Safety LTE & 5G Market

Topics Covered

Forecast Segmentation

Key Questions Answered

Key Findings