- R&I-1454
- January 2025
- 276
- PPT, PDF, WORD, EXCEL
- ICT
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Market Overview:
"The global 5G infrastructure in aerospace and defense market was valued at US$ 2.0 Billion in 2024 and is expected to register a CAGR of 24.1% over the forecast period and reach US$ 13.9 Billion in 2033."
|
Report Attributes |
Details |
|
Base Year |
2024 |
|
Forecast Years |
2025-2033 |
|
Historical Years |
2021-2023 |
|
5G Infrastructure in Aerospace and Defense Market Growth Rate (2025-2033) |
24.1% |
5G infrastructure in aerospace and defense refers to the deployment of fifth-generation wireless technology to enhance communication, connectivity, and data transmission within the industry. This advanced network enables faster and more reliable communication between ground control stations, unmanned aerial vehicles (UAVs), and other aerospace systems.
The integration of 5G in defense applications allows for real-time data sharing, quick decision-making, and improved efficiency in military operations. With its low latency and high bandwidth, 5G supports the development and implementation of autonomous systems, marking a significant advancement in connectivity for critical missions and defense operations.
The incorporation of 5G infrastructure into the aerospace and defense market represents a transformative breakthrough in communication and connectivity. Through the deployment of fifth-generation wireless technology, this initiative improves the speed and reliability of data transmission, fostering seamless communication across ground control stations, unmanned aerial vehicles (UAVs), and various aerospace systems.
Within the defense sector, the integration of 5G supports real-time data sharing, expedites decision-making, and enhances operational efficiency, thereby elevating the capabilities of military applications. The low latency and high bandwidth of 5G also contribute to the development and implementation of autonomous systems, signifying a substantial advancement in connectivity for crucial missions and defense operations. The adoption of 5G within the aerospace and defense market underscores its crucial role in shaping the future of communication and technology within these essential sectors.
5G Infrastructure in Aerospace and Defense Market Trends and Drivers:
Low Latency for Real Time Operations: The ultra-low latency offered by 5G infrastructure is instrumental in facilitating real-time communication and swift decision-making, particularly in critical applications such as drone operations. In situations where split-second decisions are crucial for the success of a mission, the rapid and responsive nature of 5G connectivity becomes a decisive factor. This minimal latency ensures that commands from ground control stations reach unmanned aerial vehicles (UAVs) almost instantly, enabling precise control and navigation. In the realm of drone operations, where quick adjustments and real-time data processing are paramount, 5G technology provides a significant advantage. Minimizing communication delays enhances the overall efficiency and effectiveness of drone missions, contributing to heightened situational awareness and the successful execution of complex tasks in the aerospace and defense sectors.
Cost Efficiency and Resource Optimization: The cost-effectiveness and resource optimization facilitated by 5G infrastructure represent a transformative element in defense operations. The effective utilization of bandwidth, along with the capacity to connect numerous devices in a unified network, is instrumental in promoting economical practices. By simplifying communication channels and reducing the dependence on extensive physical infrastructure, 5G contributes to resource optimization, aligning with cost considerations. This becomes particularly crucial in large-scale defense deployments, where the ability to enhance operational efficiency while minimizing expenses is of paramount importance. The inherent resource optimization provided by 5G infrastructure not only supports the financial sustainability of defense applications but also underscores its potential to improve the scalability and adaptability of communication networks in intricate and dynamic military settings.
Technological Interoperability: The encouragement of technological interoperability by 5G infrastructure serves as a crucial enabler in the aerospace and defense sector. This functionality promotes seamless collaboration among diverse technologies and systems deployed within these domains. By facilitating interoperability, 5G supports smooth communication and coordination across various platforms, enhancing the overall efficiency of operations. This interconnectedness allows different elements of the aerospace and defense infrastructure to harmonize, fostering synergy and optimizing the use of advanced technologies. In essence, the focus on technological interoperability through 5G represents a strategic approach to establish a unified and integrated ecosystem, ultimately enhancing the effectiveness and adaptability of operations in the aerospace and defense sectors.
5G Infrastructure in Aerospace and Defense Restraining Factors:
Security Concerns: The integration of 5G technology in the aerospace and defense sectors faces noteworthy security challenges due to the inherently sensitive nature of operations within these domains. The increased susceptibility to cyber threats introduces a significant hurdle, demanding the implementation of robust cybersecurity measures. Concerns about potential breaches and unauthorized access act as deterrents, hindering the broad adoption of 5G in these sectors. Effectively addressing and mitigating these security issues becomes crucial to ensure the successful incorporation of 5G infrastructure, underscoring the paramount importance of safeguarding sensitive information and systems in aerospace and defense operations.
High Initial Costs: The deployment of 5G infrastructure is encumbered by significant upfront costs, encompassing the need to upgrade existing systems and procure compatible devices. This substantial financial investment poses a barrier that may impede the rapid adoption of 5G technology, particularly for defense agencies contending with budgetary constraints. The substantial initial expenses associated with the transition to 5G could potentially delay the widespread integration of this technology in the aerospace and defense sectors, as organizations weigh the financial considerations against the potential benefits of enhanced connectivity and capabilities.
5G Infrastructure in Aerospace and Defense Market Opportunities:
Innovation in Defense Applications: Manufacturers within the aerospace and defense industry can initiate an innovation expedition by concentrating on the creation of 5G solutions specifically designed for defense applications. This involves creating specialized offerings that cater specifically to the unique demands of military operations. Potential areas of advancement encompass refining autonomous systems, implementing real-time data analytics for strategic decision-making, and establishing highly secure communication protocols. Through proactive innovation in these defense-centric applications, manufacturers position themselves to play a pivotal role in elevating the technological capabilities and operational effectiveness of military forces through the integration of cutting-edge 5G solutions.
Advancement in Unmanned Systems: Integration of 5G technology opens avenues for significant progress in unmanned systems, such as drones and autonomous vehicles. Leveraging the low latency and high bandwidth capabilities of 5G, manufacturers have the prospect to enhance the efficiency and sophistication of operations in both defense and civilian domains. The minimal latency ensures nearly instantaneous communication between these unmanned systems and their control centers, facilitating swift response times and precise maneuvering. Concurrently, the expanded bandwidth enables seamless transmission of large data volumes, empowering advanced real-time data processing and analysis. This technological synergy holds promise for improvements in navigation, situational awareness, and overall operational efficacy. Manufacturers, as they explore these opportunities, contribute to the evolution of unmanned systems, demonstrating the transformative influence of 5G technology in this field.
5G Infrastructure in Aerospace and Defense Market Segmentation:
By Communication Infrastructure
- (RAN (Radio Access Network)
- C-Ran/V-Ran
- Small Cell
- MassiveMIMO
- Transport Technology
- Software-Defined Networking
- Network Slicing
- Core Technology
- Network Function Virtualization (NFV)
- Mobile Edge Computing
By Core Network Technology
- Software-Defined Networking (SDN)
- Network Function Virtualization
- By Network Architecture
- 5G NR Non-Standalone (LTE Combined)
- 5G Standalone (NR + Core)
By Operational Frequency
- Sub 6 GHz
- above 6 GHz
By End Use Vertical
- Aerospace
- Defense
- Commercial Flight Line
By Region
- North America
- Latin America
- Europe
- Asia Pacific
- Middle East & Africa
The United States holds the foremost position in the market for 5G infrastructure in aerospace and defense, attributed to its substantial defense budget, technological prowess, and dedicated commitment to modernizing military communication systems. The country's strategic priority on maintaining a state-of-the-art defense infrastructure and fostering innovation positions it as a primary catalyst for the integration of advanced 5G technologies in aerospace and defense applications. Furthermore, the diverse array of defense operations and the imperative for seamless connectivity further solidify the U.S. market's prominence in this sector.
In Europe, the surge in 5G infrastructure sales for aerospace and defense is propelled by trends such as the growing emphasis on autonomous systems, the need for secure communication networks, and collaborative endeavors for cross-border defense initiatives. The region's commitment to technological progress and interoperability converges with the integration of 5G, creating a vibrant market for aerospace and defense applications across European countries.
The significance of investing in China and India for the global expansion of the 5G infrastructure in aerospace and defense sales market lies in their substantial defense budgets, extensive modernization efforts, and strategic relevance in the evolving geopolitical context. These countries prioritize the incorporation of cutting-edge communication technologies, making them pivotal contributors to the growth of the 5G infrastructure market in the aerospace and defense sectors. Given the magnitude of their defense operations and commitment to technological progress, China and India emerge as crucial influencers in driving global sales within this industry.
Leading Companies in 5G Infrastructure in Aerospace and Defense Market & Competitive Landscape:
The 5G infrastructure in aerospace and defense market is highly competitive, with several key players vying for market share and actively engaging in strategic initiatives. These companies focus on product innovation, technological advancements, and expanding their product portfolios to gain a competitive edge. These companies are continuously investing in research and development activities to enhance their product offerings and cater to the evolving needs of customers in terms of efficiency, performance, and sustainability.
Company List
- Airspan Networks
- Affirmed Networks Inc
- American Tower
- AT&T
- China Mobile
- Cisco Systems
- Comba Telecom
- CommScope Inc
- Ciena Corporation
- Ericsson
- Extreme Networks
- Hewlett Packard Enterprise
- Huawei Technologies Co., Ltd
- Juniper
- Korea Telecom
- Mavenir
- NEC Corporation
- Nokia Networks
- Samsung Electronics Co., Ltd
- SK Telecom, T-Mobile US, Inc
- Verizon Communications Inc
- VMware, Inc
- ZTE Corporation
- Vestel Elektronik
Recent Developments:
- September 2023: Delta Air Lines has upgraded the radio altimeters across its operational aircraft fleet to mitigate potential interference from the 5G C-Band.
- February 2023: Ericsson and Mobily have signed a Memorandum of Understanding to broaden the scope of advanced 5G applications in Saudi Arabia.
- January 2023: Intelsat and Thales Alenia Space, a collaboration between Thales and Leonardo, have entered into an agreement to create two software-defined satellites as components of Intelsat's 5G software-defined network.
|
Report Metric |
Report Details |
|
5G Infrastructure in Aerospace and Defense Market size available for the years |
2022-2033 |
|
Base Year |
2024 |
|
Forecast Period |
2025-2033 |
|
Compound Annual Growth Rate (CAGR) |
24.1% |
|
Segment covered |
Communication infrastructure, core network technology, network architecture, operational frequency, end use vertical, and regions. |
|
Regions Covered |
North America: The U.S. & Canada Latin America: Brazil, Mexico, Argentina, & Rest of Latin America Asia Pacific: China, India, Japan, Australia & New Zealand, ASEAN, & Rest of Asia Pacific Europe: Germany, The U.K., France, Spain, Italy, Russia, Poland, BENELUX, NORDIC, & Rest of Europe The Middle East & Africa: Saudi Arabia, United Arab Emirates, South Africa, Egypt, Israel, and Rest of MEA |
|
Fastest Growing Country in Europe |
Germany |
|
Largest Market |
North America |
|
Key Players |
Airspan Networks, Affirmed Networks Inc., American Tower, AT&T, China Mobile, Cisco Systems, Comba Telecom, CommScope Inc., Ciena Corporation, Ericsson, Extreme Networks, Hewlett Packard Enterprise, Huawei Technologies Co., Ltd., Juniper, Korea Telecom, Mavenir, NEC Corporation, Nokia Networks, Samsung Electronics Co., Ltd., SK Telecom, T-Mobile US, Inc., Verizon Communications Inc., VMware, Inc., ZTE Corporation, Vestel Elektronik, and among others. |
1. Global 5G infrastructure Market in Aviation Industry Report Overview
1.1. Introduction
1.2. Report Description
1.3. Methodology
2. Global 5G infrastructure Market in Aviation Industry Overview
2.1. Introduction
2.1.1. Introduction
2.1.2. Market Taxonomy
2.2. Executive Summary
2.3. Global 5G infrastructure Market in Aviation Industry Snapshot
2.4. Global 5G infrastructure Market in Aviation Industry Size And Forecast, 2025–2033
2.4.1. Introduction
2.4.2. Market Value Forecast And Annual Growth Rate (AGR) Comparison (2025–2033)
2.5. Global 5G infrastructure Market in Aviation Industry Dynamics
2.5.1. Drivers
2.5.2. Restraints
2.5.3. Opportunity
2.5.4. Trends
2.6. Porter’s Five Forces Model
2.7. SWOT Analysis
2.8. PESTLE Analysis
3. Global 5G infrastructure Market in Aviation Industry, By Communication Infrastructure
3.1. Introduction
3.1.1. Annual Growth Rate Comparison, By Communication Infrastructure
3.1.2. BPS Analysis, By Communication Infrastructure
3.2. Market Revenue (US$Mn) and Forecast, By Communication Infrastructure
3.2.1. RAN (Radio Access Network)
3.2.1.1. C-Ran/V-Ran
3.2.1.2. Small Cell
3.2.1.3. MassiveMIMO
3.2.2. Transport Technology
3.2.2.1. Software-Defined Networking
3.2.2.2. Network Slicing
3.2.3. Core Technology
3.2.3.1. Network Function Virtulization (NFV)
3.2.3.2. Mobile Edge Computing
3.3. Global 5G infrastructure Market in Aviation Industry Attractiveness Index, By Communication Infrastructure
4. Global 5G infrastructure Market in Aviation Industry, By Core Network Technology
4.1. Introduction
4.1.1. Annual Growth Rate Comparison, By Core Network Technology
4.1.2. BPS Analysis, By Core Network Technology
4.2. Market Revenue (US$Mn) and Forecast, By Core Network Technology
4.2.1. Software-Defined Networking (SDN)
4.2.2. Network Function Virtualization (NFV)
4.3. Global 5G infrastructure Market in Aviation Industry Attractiveness Index, By Core Network Technology
5. Global 5G infrastructure Market in Aviation Industry, Network Architecture
5.1. Introduction
5.1.1. Annual Growth Rate Comparison, Network Architecture
5.1.2. BPS Analysis, Network Architecture
5.2. Market Revenue (US$Mn) and Forecast, Network Architecture
5.2.1. 5G NR Non-Standalone (LTE Combined)
5.2.2. 5G Standalone (NR + Core)
5.3. Global 5G infrastructure Market in Aviation Industry Attractiveness Index, Network Architecture
6. Global 5G infrastructure Market in Aviation Industry, By Operational Frequency
6.1. Introduction
6.1.1. Annual Growth Rate Comparison, By Operational Frequency
6.1.2. BPS Analysis, By Operational Frequency
6.2. Market Revenue (US$Mn) and Forecast, By Operational Frequency
6.2.1. Sub 6 GHz
6.2.2. Above 6 GHz
6.3. Global 5G infrastructure Market in Aviation Industry Attractiveness Index, By Operational Frequency
7. Global 5G infrastructure Market in Aviation Industry, By End Use Vertical
7.1. Introduction
7.1.1. Annual Growth Rate Comparison, By End Use Vertical
7.1.2. BPS Analysis, By End Use Vertical
7.2. Market Revenue (US$Mn) and Forecast, By End Use Vertical
7.2.1. Aerospace
7.2.2. Defense
7.2.3. Commercial Flight Line
7.3. Global 5G infrastructure Market in Aviation Industry Attractiveness Index, By End Use Vertical
8. Global 5G infrastructure Market in Aviation Industry, By Region
8.1. Introduction
8.1.1. Annual Growth Rate Comparison, By Region
8.1.2. BPS Analysis, By Region
8.2. Market Revenue (US$Mn) and Forecast, By Region
8.2.1. North America
8.2.2. Latin America
8.2.3. Europe
8.2.4. Asia Pacific
8.2.5. Middle East
8.2.6. Africa
8.3. Global 5G infrastructure Market in Aviation Industry Attractiveness Index, By Region
9. North America 5G infrastructure Market in Aviation Industry Analysis and Forecast, 2025–2033
9.1. Introduction
9.1.1. Annual Growth Rate Comparison, By Country
9.1.2. BPS Analysis, By Country
9.2. Market Revenue (US$Mn) and Forecast, By Country
9.2.1. U.S. 5G infrastructure Market in Aviation Industry
9.2.2. Canada 5G infrastructure Market in Aviation Industry
9.3. North America 5G infrastructure Market in Aviation Industry, By Communication Infrastructure
9.3.1. RAN (Radio Access Network)
9.3.1.1. C-Ran/V-Ran
9.3.1.2. Small Cell
9.3.1.3. MassiveMIMO
9.3.2. Transport Technology
9.3.2.1. Software-Defined Networking
9.3.2.2. Network Slicing
9.3.3. Core Technology
9.3.3.1. Network Function Virtulization (NFV)
9.3.3.2. Mobile Edge Computing
9.4. North America 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, By Core Network Technology
9.4.1. Software-Defined Networking (SDN)
9.4.2. Network Function Virtualization (NFV)
9.5. North America 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, Network Architecture
9.5.1. 5G NR Non-Standalone (LTE Combined)
9.5.2. 5G Standalone (NR + Core)
9.6. North America 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, By Operational Frequency
9.6.1. Sub 6 GHz
9.6.2. Above 6 GHz
9.7. North America 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, By End Use Vertical
9.7.1. Aerospace
9.7.2. Defense
9.7.3. Commercial Flight Line
9.8. North America 5G infrastructure Market in Aviation Industry Attractiveness Index
9.8.1. By Country
9.8.2. By Communication Infrastructure
9.8.3. By Core Network Technology
9.8.4. Network Architecture
9.8.5. By Operational Frequency
9.8.6. By End Use Vertical
10. Latin America 5G infrastructure Market in Aviation Industry Analysis and Forecast, 2025–2033
10.1. Introduction
10.1.1. Annual Growth Rate Comparison, By Country
10.1.2. BPS Analysis, By Country
10.2. Market (US$Mn) Forecast, By Country
10.2.1. Brazil 5G infrastructure Market in Aviation Industry
10.2.2. Mexico 5G infrastructure Market in Aviation Industry
10.2.3. Rest Of Latin America 5G infrastructure Market in Aviation Industry
10.3. Latin America 5G infrastructure Market in Aviation Industry, By Communication Infrastructure
10.3.1. RAN (Radio Access Network)
10.3.1.1. C-Ran/V-Ran
10.3.1.2. Small Cell
10.3.1.3. MassiveMIMO
10.3.2. Transport Technology
10.3.2.1. Software-Defined Networking
10.3.2.2. Network Slicing
10.3.3. Core Technology
10.3.3.1. Network Function Virtulization (NFV)
10.3.3.2. Mobile Edge Computing
10.4. Latin America 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, By Core Network Technology
10.4.1. Software-Defined Networking (SDN)
10.4.2. Network Function Virtualization (NFV)
10.5. Latin America 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, Network Architecture
10.5.1. 5G NR Non-Standalone (LTE Combined)
10.5.2. 5G Standalone (NR + Core)
10.6. Latin America 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, By Operational Frequency
10.6.1. Sub 6 GHz
10.6.2. Above 6 GHz
10.7. Latin America 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, By End Use Vertical
10.7.1. Aerospace
10.7.2. Defense
10.7.3. Commercial Flight Line
10.8. Latin America 5G infrastructure Market in Aviation Industry Attractiveness Index
10.8.1. By Country
10.8.2. By Communication Infrastructure
10.8.3. By Core Network Technology
10.8.4. Network Architecture
10.8.5. By Operational Frequency
10.8.6. By End Use Vertical
11. Europe 5G infrastructure Market in Aviation Industry Analysis and Forecast, 2025–2033
11.1. Introduction
11.1.1. Annual Growth Rate Comparison, By Country
11.1.2. BPS Analysis, By Country
11.2. Market (US$Mn) Forecast, By Country
11.2.1. U.K. 5G infrastructure Market in Aviation Industry
11.2.2. Germany 5G infrastructure Market in Aviation Industry
11.2.3. Italy 5G infrastructure Market in Aviation Industry
11.2.4. France 5G infrastructure Market in Aviation Industry
11.2.5. Spain 5G infrastructure Market in Aviation Industry
11.2.6. Russia 5G infrastructure Market in Aviation Industry
11.2.7. Poland 5G infrastructure Market in Aviation Industry
11.2.8. BENELUX 5G infrastructure Market in Aviation Industry
11.2.9. NORDIC 5G infrastructure Market in Aviation Industry
11.2.10. Rest Of Europe 5G infrastructure Market in Aviation Industry
11.3. Europe 5G infrastructure Market in Aviation Industry, By Communication Infrastructure
11.3.1. RAN (Radio Access Network)
11.3.1.1. C-Ran/V-Ran
11.3.1.2. Small Cell
11.3.1.3. MassiveMIMO
11.3.2. Transport Technology
11.3.2.1. Software-Defined Networking
11.3.2.2. Network Slicing
11.3.3. Core Technology
11.3.3.1. Network Function Virtulization (NFV)
11.3.3.2. Mobile Edge Computing
11.4. Europe 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, By Core Network Technology
11.4.1. Software-Defined Networking (SDN)
11.4.2. Network Function Virtualization (NFV)
11.5. Europe 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, Network Architecture
11.5.1. 5G NR Non-Standalone (LTE Combined)
11.5.2. 5G Standalone (NR + Core)
11.6. Europe 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, By Operational Frequency
11.6.1. Sub 6 GHz
11.6.2. Above 6 GHz
11.7. Europe 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, By End Use Vertical
11.7.1. Aerospace
11.7.2. Defense
11.7.3. Commercial Flight Line
11.8. Europe 5G infrastructure Market in Aviation Industry Attractiveness Index
11.8.1. By Country
11.8.2. By Communication Infrastructure
11.8.3. By Core Network Technology
11.8.4. Network Architecture
11.8.5. By Operational Frequency
11.8.6. By End Use Vertical
12. Asia Pacific 5G infrastructure Market in Aviation Industry Analysis and Forecast, 2025–2033
12.1. Introduction
12.1.1. Annual Growth Rate Comparison, By Country
12.1.2. BPS Analysis, By Country
12.2. Market (US$Mn) Forecast, By Country
12.2.1. China 5G infrastructure Market in Aviation Industry
12.2.2. India 5G infrastructure Market in Aviation Industry
12.2.3. Japan 5G infrastructure Market in Aviation Industry
12.2.4. Australia and New Zealand 5G infrastructure Market in Aviation Industry
12.2.5. South Korea 5G infrastructure Market in Aviation Industry
12.2.6. Rest of Asia Pacific 5G infrastructure Market in Aviation Industry
12.3. Asia Pacific 5G infrastructure Market in Aviation Industry, By Communication Infrastructure
12.3.1. RAN (Radio Access Network)
12.3.1.1. C-Ran/V-Ran
12.3.1.2. Small Cell
12.3.1.3. MassiveMIMO
12.3.2. Transport Technology
12.3.2.1. Software-Defined Networking
12.3.2.2. Network Slicing
12.3.3. Core Technology
12.3.3.1. Network Function Virtulization (NFV)
12.3.3.2. Mobile Edge Computing
12.4. Asia Pacific 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, By Core Network Technology
12.4.1. Software-Defined Networking (SDN)
12.4.2. Network Function Virtualization (NFV)
12.5. Asia Pacific 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, Network Architecture
12.5.1. 5G NR Non-Standalone (LTE Combined)
12.5.2. 5G Standalone (NR + Core)
12.6. Asia Pacific 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, By Operational Frequency
12.6.1. Sub 6 GHz
12.6.2. Above 6 GHz
12.7. Asia Pacific 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, By End Use Vertical
12.7.1. Aerospace
12.7.2. Defense
12.7.3. Commercial Flight Line
12.8. Asia Pacific 5G infrastructure Market in Aviation Industry Attractiveness Index
12.8.1. By Country
12.8.2. By Communication Infrastructure
12.8.3. By Core Network Technology
12.8.4. Network Architecture
12.8.5. By Operational Frequency
12.8.6. By End Use Vertical
13. Middle East 5G infrastructure Market in Aviation Industry Analysis and Forecast, 2025–2033
13.1. Introduction
13.1.1. Annual Growth Rate Comparison, By Country
13.1.2. BPS Analysis, By Country
13.2. Market (US$Mn) Forecast, By Country
13.2.1. GCC Countries 5G infrastructure Market in Aviation Industry
13.2.2. Israel 5G infrastructure Market in Aviation Industry
13.2.3. Rest Of Middle East 5G infrastructure Market in Aviation Industry
13.3. Middle East 5G infrastructure Market in Aviation Industry, By Communication Infrastructure
13.3.1. RAN (Radio Access Network)
13.3.1.1. C-Ran/V-Ran
13.3.1.2. Small Cell
13.3.1.3. MassiveMIMO
13.3.2. Transport Technology
13.3.2.1. Software-Defined Networking
13.3.2.2. Network Slicing
13.3.3. Core Technology
13.3.3.1. Network Function Virtulization (NFV)
13.3.3.2. Mobile Edge Computing
13.4. Middle East 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, By Core Network Technology
13.4.1. Software-Defined Networking (SDN)
13.4.2. Network Function Virtualization (NFV)
13.5. Middle East 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, Network Architecture
13.5.1. 5G NR Non-Standalone (LTE Combined)
13.5.2. 5G Standalone (NR + Core)
13.6. Middle East 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, By Operational Frequency
13.6.1. Sub 6 GHz
13.6.2. Above 6 GHz
13.7. Middle East 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, By End Use Vertical
13.7.1. Aerospace
13.7.2. Defense
13.7.3. Commercial Flight Line
13.8. Middle East 5G infrastructure Market in Aviation Industry Attractiveness Index
13.8.1. By Country
13.8.2. By Communication Infrastructure
13.8.3. By Core Network Technology
13.8.4. Network Architecture
13.8.5. By Operational Frequency
13.8.6. By End Use Vertical
14. Africa 5G infrastructure Market in Aviation Industry Analysis and Forecast, 2025–2033
14.1. Introduction
14.1.1. Annual Growth Rate Comparison, By Country
14.1.2. BPS Analysis, By Country
14.2. Market (US$Mn) Forecast, By Country
14.2.1. South Africa Countries 5G infrastructure Market in Aviation Industry
14.2.2. Egypt 5G infrastructure Market in Aviation Industry
14.2.3. North Africa 5G infrastructure Market in Aviation Industry
14.2.4. Rest of Africa 5G infrastructure Market in Aviation Industry
14.3. Africa 5G infrastructure Market in Aviation Industry, By Communication Infrastructure
14.3.1. RAN (Radio Access Network)
14.3.1.1. C-Ran/V-Ran
14.3.1.2. Small Cell
14.3.1.3. MassiveMIMO
14.3.2. Transport Technology
14.3.2.1. Software-Defined Networking
14.3.2.2. Network Slicing
14.3.3. Core Technology
14.3.3.1. Network Function Virtulization (NFV)
14.3.3.2. Mobile Edge Computing
14.4. Africa 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, By Core Network Technology
14.4.1. Software-Defined Networking (SDN)
14.4.2. Network Function Virtualization (NFV)
14.5. Africa 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, Network Architecture
14.5.1. 5G NR Non-Standalone (LTE Combined)
14.5.2. 5G Standalone (NR + Core)
14.6. Africa 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, By Operational Frequency
14.6.1. Sub 6 GHz
14.6.2. Above 6 GHz
14.7. Africa 5G infrastructure Market in Aviation Industry Revenue (US$Mn) and Forecast, By End Use Vertical
14.7.1. Aerospace
14.7.2. Defense
14.7.3. Commercial Flight Line
14.8. Africa 5G infrastructure Market in Aviation Industry Attractiveness Index
14.8.1. By Country
14.8.2. By Communication Infrastructure
14.8.3. By Core Network Technology
14.8.4. Network Architecture
14.8.5. By Operational Frequency
14.8.6. By End Use Vertical
15. Competitive Landscape
15.1. Competition Dashboard
15.2. Company Profiles
15.2.1. Airspan Networks
15.2.1.1. Company Overview
15.2.1.2. Financial Overview
15.2.1.3. Key Developments
15.2.1.4. Strategies
15.2.1.5. Product Analysis
15.2.2. Affirmed Networks Inc.
15.2.3. American Tower
15.2.4. AT&T
15.2.5. China Mobile
15.2.6. Cisco Systems
15.2.7. Comba Telecom
15.2.8. CommScope Inc.
15.2.9. Ciena Corporation
15.2.10. Ericsson
15.2.11. Extreme Networks
15.2.12. Hewlett Packard Enterprise
15.2.13. Huawei Technologies Co., Ltd.
15.2.14. Juniper
15.2.15. Korea Telecom
15.2.16. Mavenir
15.2.17. NEC Corporation
15.2.18. Nokia Networks
15.2.19. Samsung Electronics Co., Ltd.
15.2.20. SK Telecom
15.2.21. T-Mobile US, Inc.
15.2.22. Verizon Communications Inc.
15.2.23. VMware, Inc.
15.2.24. ZTE Corporation
15.2.25. Vestel Elektronik
16. Acronyms
Frequently Asked Question
What are some key factors driving revenue growth of the 5G infrastructure in aerospace and defense market?
Some key factors driving market revenue growth include low latency for real time operations, cost efficiency and resource optimization and technological interoperability.
What are some major challenges faced by companies in the 5G infrastructure in aerospace and defense market?
Companies face challenges such as high initial costs and security concerns.
How is the competitive landscape in the global 5G infrastructure in aerospace and defense market?
The market is competitive, with key players focusing on technological advancements, product innovation, and strategic partnerships. Factors such as product quality, reliability, after-sales services, and customization capabilities play a significant role in determining competitiveness.
What are the potential opportunities for companies in the 5G infrastructure in aerospace and defense market?
Companies can leverage opportunities such as innovation in defense applications and advancements in unmanned systems.
How is the 5G infrastructure in aerospace and defense market segmented?
The market is segmented based on factors such as communication infrastructure, core network technology, network architecture, operational frequency, end use vertical and regions.