Military Aircraft Avionics Market By System Type (Flight Control Systems, Communication Systems, Navigation Systems, Surveillance and Reconnaissance Systems, Mission Computers and Integrated Avionics Suites); By Aircraft Type (Fighter Aircraft, Transport and Military Cargo Aircraft, Helicopters and Rotary-Wing Aircraft, Unmanned Aerial Vehicles); By Application (Navigation and Guidance, Communication and Data Link, Electronic Warfare and Threat Detection, Surveillance and Intelligence Gathering); By Geography, Segment Revenue Estimation, Forecast, 2024–2030

Introduction And Strategic Context

The Global Military Aircraft Avionics Market is expected to witness a CAGR of 6.8% , valued at approximately USD 38.5 billion in 2024 , and projected to reach around USD 57.2 billion by 2030 , according to Strategic Market Research.

 

Military aircraft avionics refers to the integrated electronic systems used in defense aircraft to manage navigation, communication, surveillance, mission control, electronic warfare, and flight operations. These systems act as the digital backbone of modern military aircraft. From fighter jets and surveillance platforms to transport aircraft and unmanned combat aerial vehicles, avionics enable pilots and mission systems to operate with precision, awareness, and speed.

 

Between 2024 and 2030 , the strategic importance of avionics is increasing rapidly. Modern warfare has shifted toward network-centric and data-driven operations . Aircraft are no longer isolated combat platforms. They function as nodes in a broader battlefield network that includes satellites, drones, ground stations, and naval systems. As a result, avionics must handle large volumes of real-time data while ensuring secure communication across multiple platforms.

 

One major catalyst is the ongoing modernization of aging military aircraft fleets. Many air forces are upgrading avionics suites in legacy platforms rather than replacing entire aircraft fleets. This includes installing advanced glass cockpits, digital flight control systems, next-generation radar interfaces, and mission computers . These upgrades extend operational life while enabling compatibility with modern combat environments.

 

Another shift is the growing role of electronic warfare and cyber-resilient avionics systems . Modern avionics must operate in contested environments where signals may be jammed or spoofed. As a result, defense agencies are prioritizing resilient navigation systems, secure communication links, and advanced sensor integration.

 

The emergence of fifth-generation and sixth-generation fighter programs is also reshaping the avionics ecosystem. Aircraft such as stealth fighters rely heavily on sensor fusion, AI-assisted decision systems, and integrated mission management software. In these aircraft, avionics are no longer just support systems. They are central to the aircraft’s combat capability.

 

The stakeholder ecosystem is broad and strategically important. Defense ministries, aircraft manufacturers, avionics system integrators, semiconductor suppliers, and cybersecurity firms all play key roles in this market. Governments drive demand through modernization budgets, while aerospace OEMs focus on integrating next-generation avionics architectures.

 

One important insight: avionics upgrades often represent the most cost-effective way to enhance aircraft capability without developing entirely new platforms. Because of this, avionics modernization programs are becoming a priority in many national defense strategies.

 

To be honest, the military aviation industry is entering a phase where software-defined avionics architectures and modular open systems will dominate development. This shift will make aircraft systems easier to upgrade, integrate, and adapt to future technologies.

 

Market Segmentation And Forecast Scope

The Military Aircraft Avionics Market spans multiple technological layers and operational applications. Defense aircraft rely on integrated avionics suites that support navigation, mission execution, threat detection, and aircraft control. Because of this complexity, the market is typically segmented across system type, aircraft type, application, and region . Each layer reflects how modern air forces deploy avionics to enhance combat readiness and operational efficiency.

By System Type

Avionics systems in military aircraft consist of several specialized electronic modules working together to support mission execution.

• Flight Control Systems
  These systems manage aircraft stability, autopilot functions, and flight management operations. Modern fighter jets and surveillance aircraft rely on digital fly-by-wire systems that replace traditional mechanical controls with electronic interfaces. This segment represented roughly 22% of the market share in 2024 , reflecting its critical role in aircraft safety and performance.

• Communication Systems
  Military aircraft require secure and encrypted communication channels for coordination with ground control, naval fleets, and other aircraft. Advanced data links, satellite communications, and secure voice networks are key components here. As multi-domain warfare expands, communication avionics are becoming more sophisticated and cyber-resilient.

• Navigation Systems
  Navigation avionics include GPS-based positioning, inertial navigation systems, terrain-following radar interfaces, and advanced guidance software. These systems ensure accurate route planning and mission execution even in environments where signals may be degraded or jammed.

• Surveillance and Reconnaissance Systems
  These avionics integrate sensors, radar feeds, and real-time intelligence systems to monitor enemy movement and battlefield conditions. Modern platforms combine radar data, infrared imaging, and electronic intelligence into unified displays for pilots and mission operators.

• Mission Computers and Integrated Avionics Suites
  Mission computers serve as the central processing units of military aircraft avionics. They manage sensor fusion, threat analysis, and operational decision support. Many next-generation fighter aircraft rely heavily on these integrated processing systems to interpret vast amounts of data during missions.

 

By Aircraft Type

Military aircraft platforms vary significantly in avionics complexity depending on their operational roles.

• Fighter Aircraft
  Fighter jets represent the most technologically advanced avionics segment. These aircraft rely on advanced sensor fusion, electronic warfare systems, and high-performance mission computers. Fighter aircraft accounted for nearly 35% of the total avionics demand in 2024 , largely due to extensive modernization programs.

• Transport and Military Cargo Aircraft
  Transport aircraft require avionics that support long-range navigation, cargo mission planning, and multi-crew cockpit operations. While less combat-focused than fighter jets, these aircraft depend heavily on reliable navigation and communication avionics.

• Helicopters and Rotary-Wing Aircraft
  Military helicopters use specialized avionics for low-altitude navigation, battlefield communication, and terrain awareness. These platforms often operate in complex environments, making sensor integration and flight stabilization systems essential.

• Unmanned Aerial Vehicles (UAVs)
  UAV avionics focus on autonomous navigation, remote communication links, and real-time surveillance data processing. This segment is currently among the fastest-growing due to expanding military drone deployments.

 

By Application

Military avionics are also categorized based on operational mission requirements.

• Navigation and Guidance
  Ensures precise aircraft positioning and route optimization during missions.

• Communication and Data Link
  Supports secure real-time communication between aircraft, satellites, and command centers .

• Electronic Warfare and Threat Detection
  Includes systems that detect, identify, and counter enemy radar or missile threats.

• Surveillance and Intelligence Gathering
  Used for reconnaissance missions, border monitoring, and battlefield intelligence.

One important shift: avionics platforms are increasingly designed to integrate multiple applications within a single modular system. This reduces hardware weight while improving mission efficiency.

 

By Region

The market outlook varies across major defense regions:

• North America
  Driven by advanced fighter aircraft programs and ongoing avionics modernization initiatives.

• Europe
  Strong investment in next-generation combat aircraft and collaborative defense programs.

• Asia Pacific
  The fastest-growing region due to rising defense budgets and fleet expansion in countries such as China, India, South Korea, and Japan.

• Latin America, Middle East and Africa
  Growing demand linked to defense modernization and regional security priorities.

Interestingly, avionics upgrades are often prioritized even in regions where full aircraft replacement programs are delayed, making this segment resilient across economic cycles.

 

Market Trends And Innovation Landscape

The Military Aircraft Avionics Market is evolving quickly as defense aviation shifts toward highly digital, connected, and software-driven aircraft systems. Modern combat platforms rely on advanced electronics that integrate sensors, mission computers, communication links, and electronic warfare capabilities into a unified operational framework. Between 2024 and 2030 , several technological trends are shaping how avionics systems are designed, deployed, and upgraded.

Shift Toward Modular Open Systems Architecture

One of the most influential developments is the adoption of Modular Open Systems Architecture (MOSA) . Traditionally, avionics systems were tightly integrated and difficult to upgrade without redesigning large portions of the aircraft electronics.

Today, defense agencies prefer modular architectures where individual components such as mission computers, radar interfaces, or navigation systems can be upgraded independently.

This approach offers several advantages:

• Faster technology refresh cycles

• Lower integration costs

• Greater interoperability between allied forces

Many defense analysts believe MOSA will become the standard framework for next-generation combat aircraft because it allows rapid integration of emerging technologies without major platform redesign.

 

Sensor Fusion and Data-Centric Avionics

Modern combat aircraft operate in environments where situational awareness determines mission success. To address this, avionics systems are increasingly built around sensor fusion technologies .

Sensor fusion combines data from radar, electro-optical sensors, infrared systems, and electronic intelligence sources into a unified cockpit display. Instead of interpreting multiple separate systems, pilots receive a simplified tactical picture generated by onboard mission computers.

This capability is especially important in fifth-generation stealth fighters , where avionics continuously analyze incoming sensor data to detect threats, track targets, and recommend actions.

In many cases, the aircraft’s avionics now act as an intelligent assistant to the pilot rather than a passive information system.

 

Artificial Intelligence and Decision Support Systems

Artificial intelligence is gradually entering military avionics ecosystems. AI-driven algorithms are being used for:

• Threat recognition and prioritization

• Autonomous navigation for unmanned aircraft

• Predictive maintenance and system diagnostics

• Mission planning optimization

These capabilities allow avionics to process complex battlefield information far faster than human operators alone.

Looking ahead, AI-enabled avionics may support semi-autonomous combat operations where aircraft systems recommend tactical decisions in real time.

 

Advanced Glass Cockpit Technologies

Cockpit interfaces have also evolved significantly. Traditional analog gauges are being replaced by digital glass cockpit systems featuring large multifunction displays, touch interfaces, and helmet-mounted visualization systems.

These interfaces provide pilots with real-time mission data, navigation information, and threat alerts through integrated display environments.

Helmet-mounted displays, in particular, allow pilots to view targeting information simply by looking at a location outside the aircraft. This technology enhances situational awareness and improves targeting efficiency during combat operations.

 

Electronic Warfare Integration

Electronic warfare capabilities are becoming deeply integrated within avionics platforms. Modern aircraft must detect and counter enemy radar systems, missile guidance signals, and communication jamming attempts.

As a result, avionics suites now include embedded electronic support measures, signal analysis tools, and countermeasure management systems.

These technologies enable aircraft to operate in contested electromagnetic environments , where electronic attacks and signal disruptions are common.

 

Growth of Avionics for Unmanned Systems

Unmanned aerial vehicles are also driving innovation in avionics. Drone platforms rely on advanced flight control software, satellite communication links, and autonomous navigation algorithms.

Unlike traditional aircraft, UAV avionics must support remote operation and autonomous mission execution simultaneously.

This trend is accelerating as defense forces deploy more drones for surveillance, intelligence gathering, and combat missions.

 

Cybersecurity and Secure Avionics Networks

Another emerging priority is cyber-resilient avionics systems . As aircraft become more connected through digital networks and satellite communications, protecting avionics from cyber threats becomes critical.

Defense organizations are investing heavily in secure software architectures, encrypted communication protocols, and intrusion detection systems to safeguard mission-critical avionics.

The future battlefield will be as much about securing data flows as it is about controlling physical airspace.

Overall, avionics innovation is moving toward software-defined, network-enabled, and intelligence-driven systems . These technologies will determine how effectively military aircraft operate within modern multi-domain warfare environments.

 

Competitive Intelligence And Benchmarking

The Military Aircraft Avionics Market is dominated by a relatively small group of aerospace and defense companies that possess the technical expertise, certification capabilities, and government relationships required to develop mission-critical avionics systems. These companies compete through innovation, long-term defense contracts, and integration capabilities , rather than pure price competition.

Another important aspect of this market is that avionics suppliers often collaborate closely with aircraft manufacturers during development programs. Once integrated into a military aircraft platform, avionics systems usually remain part of that aircraft for decades through upgrades and modernization programs.

Honeywell Aerospace

Honeywell Aerospace is one of the most influential avionics providers in military aviation. The company supplies navigation systems, flight management computers, cockpit displays, inertial navigation units, and satellite communication systems for a wide range of defense aircraft.

Honeywell’s strategy focuses on high-reliability avionics architectures and integrated mission management systems . The company is also investing in advanced navigation technologies that operate in environments where GPS signals may be unavailable or compromised.

Honeywell’s strong relationships with U.S. defense programs give it a stable position in both new aircraft development and avionics modernization projects.

 

BAE Systems

BAE Systems plays a critical role in avionics for combat aircraft and electronic warfare platforms. The company specializes in mission computers, electronic warfare systems, and advanced cockpit interfaces .

BAE’s avionics technology is widely deployed in fighter aircraft and military helicopters across North America and Europe. The company has also expanded its capabilities in digital flight control systems and next-generation electronic warfare integration .

Its long-standing participation in major defense programs gives it strong influence in avionics architecture design.

 

Thales Group

Thales Group is a major avionics provider with strong presence in European defense aviation. The company offers navigation systems, flight displays, mission avionics, and advanced communication platforms for fighter jets, transport aircraft, and surveillance platforms.

Thales is particularly recognized for its expertise in integrated avionics suites and cockpit display systems used in modern military aircraft.

The company’s strategy emphasizes interoperability between allied forces and integration with NATO communication standards , making it a key supplier for multinational defense programs.

 

Collins Aerospace (RTX Corporation)

Collins Aerospace , part of RTX Corporation, is one of the largest avionics suppliers globally. The company provides communication systems, cockpit displays, mission computers, and navigation equipment for military aircraft.

Collins Aerospace has built its reputation around networked avionics systems that connect aircraft with ground forces, satellites, and other platforms .

Its ability to integrate communication, navigation, and mission management systems within a unified architecture makes it a major player in modern combat aircraft programs.

 

Leonardo S.p.A.

Leonardo S.p.A. is a key avionics supplier in European defense aviation, providing radar interfaces, mission computers, and electronic warfare systems .

The company supports several military aircraft platforms including fighter jets, helicopters, and maritime patrol aircraft. Leonardo’s avionics expertise is particularly strong in surveillance and intelligence mission systems .

The company also collaborates with international defense partners on next-generation fighter programs.

 

Elbit Systems

Elbit Systems is a prominent avionics developer known for advanced helmet-mounted displays, cockpit electronics, and mission management software .

The company’s helmet-mounted visualization systems allow pilots to access targeting and navigation data directly within their field of view. This technology significantly enhances situational awareness during high-speed combat operations.

Elbit has expanded its global presence through partnerships with several air forces and aircraft manufacturers.

 

Competitive Dynamics at a Glance

Several competitive trends define this market:

• Large aerospace firms dominate due to long certification cycles and high reliability requirements .

• Defense contracts often extend for decades, creating stable revenue streams for established suppliers .

• Partnerships between avionics companies and aircraft manufacturers are critical for system integration.

• Innovation increasingly revolves around software-defined avionics and AI-enabled mission systems .

To be honest, the avionics market rewards companies that can integrate multiple systems into a unified architecture rather than those offering standalone components.

 

Regional Landscape And Adoption Outlook

The Military Aircraft Avionics Market shows strong regional variation, largely shaped by defense budgets, aircraft modernization programs, geopolitical tensions, and domestic aerospace manufacturing capabilities. While mature markets focus on upgrading existing fleets with advanced avionics systems, emerging defense markets are investing in new aircraft platforms equipped with next-generation avionics architectures.

Below is a regional overview highlighting the major adoption trends.

North America

North America represents the largest market for military aircraft avionics , primarily driven by the United States’ defense spending and continuous investment in advanced aviation technologies.

Key factors driving growth include:

• Large-scale modernization of fighter aircraft fleets such as stealth fighters and next-generation combat platforms

• Strong presence of leading avionics manufacturers such as Honeywell Aerospace, Collins Aerospace, and BAE Systems

• Significant investments in AI-enabled avionics, electronic warfare integration, and network-centric combat systems

• Continuous upgrades of legacy aircraft through avionics retrofit programs

The U.S. Department of Defense remains the single largest customer for advanced avionics technologies globally.

Canada also contributes to regional growth through participation in multinational defense aircraft programs and modernization of surveillance and transport aircraft.

 

Europe

Europe is a major market supported by collaborative defense programs and strong aerospace manufacturing capabilities.

Important market dynamics include:

• Development of next-generation fighter aircraft programs such as multinational European combat aircraft initiatives

• Strong presence of avionics manufacturers including Thales Group, Leonardo, and BAE Systems

• Increasing investment in secure communication systems and advanced electronic warfare capabilities

• Modernization of aging fighter and transport aircraft fleets across NATO member countries

Countries such as France, Germany, Italy, and the United Kingdom are particularly active in avionics innovation and aircraft development.

European defense strategy increasingly emphasizes interoperability among allied forces, which is accelerating the demand for standardized avionics architectures.

 

Asia Pacific

Asia Pacific is expected to record the fastest growth rate during the forecast period as regional governments expand military capabilities and strengthen domestic aerospace industries.

Key market drivers include:

• Rising defense budgets in countries such as China, India, South Korea, Japan, and Australia

• Increasing procurement of advanced fighter aircraft and surveillance platforms

• Expansion of indigenous aircraft development programs

• Growing demand for drone avionics and autonomous flight control systems

India and China are heavily investing in domestic fighter aircraft development programs that require advanced avionics integration.

Regional geopolitical tensions and airspace monitoring needs are accelerating investments in advanced military aviation systems.

 

Latin America, Middle East and Africa (LAMEA)

Although smaller in overall market size, this region is gradually expanding its avionics adoption through aircraft modernization and defense procurement programs.

Growth factors include:

• Fighter aircraft modernization programs in Brazil and Mexico

• Increasing defense investments in Saudi Arabia and the United Arab Emirates

• Procurement of advanced surveillance aircraft for border security and maritime monitoring

• Growing adoption of unmanned aerial systems for defense and reconnaissance missions

Several countries in the Middle East are focusing on upgrading avionics systems in existing aircraft fleets to improve operational capability without purchasing entirely new aircraft.

In many cases, avionics upgrades provide a cost-effective approach to improving combat readiness in regions with evolving security challenges.

 

Regional Market Dynamics Summary

• North America leads the market due to advanced defense programs and high military expenditure.

• Europe focuses on collaborative fighter aircraft development and avionics innovation.

• Asia Pacific shows the fastest expansion driven by rising defense investments and indigenous aircraft programs.

• LAMEA is witnessing gradual growth through aircraft upgrades and expanding defense modernization initiatives.

Overall, regional demand for military avionics is closely linked to national security priorities and long-term aircraft modernization strategies.

 

End-User Dynamics And Use Case

The Military Aircraft Avionics Market serves a range of end users within the defense ecosystem. These include air forces, defense aviation agencies, aircraft manufacturers, and military maintenance organizations. Each end-user group interacts with avionics systems differently depending on mission objectives, operational environments, and aircraft platform requirements.

Unlike commercial aviation, military avionics adoption is driven primarily by mission capability, survivability, and interoperability across defense networks . As modern warfare becomes increasingly digital and data-centric, avionics systems are playing a central role in enabling real-time decision-making and battlefield coordination.

Air Forces

Air forces remain the largest end users of military avionics systems . Fighter aircraft, surveillance platforms, transport aircraft, and aerial refueling tankers rely heavily on integrated avionics suites to conduct combat operations and strategic missions.

Key avionics priorities for air forces include:

• Advanced navigation and guidance systems for precision missions

• Secure communication and data link systems connecting aircraft with command centers

• Integrated sensor fusion platforms for situational awareness

• Embedded electronic warfare capabilities to counter radar and missile threats

Many air forces are currently investing in avionics modernization to upgrade legacy aircraft fleets. Rather than replacing entire aircraft platforms, defense agencies often deploy avionics retrofit programs that significantly enhance operational capabilities.

This approach allows aircraft that were originally designed decades ago to operate effectively within modern digital battle networks.

 

Defense Aircraft Manufacturers (OEMs)

Aircraft manufacturers integrate avionics systems into new military aircraft during the design and production stages. Companies developing fighter jets, transport aircraft, and surveillance platforms collaborate closely with avionics suppliers to create integrated mission systems.

Important avionics considerations for OEMs include:

• Compatibility with aircraft architecture and onboard sensors

• Weight reduction and power efficiency

• Integration of open architecture avionics frameworks

• Scalability for future software upgrades

Modern aircraft programs often prioritize modular avionics systems , allowing new technologies to be integrated without redesigning the entire aircraft electronics infrastructure.

 

Military Maintenance and Upgrade Organizations

Maintenance, repair, and overhaul (MRO) organizations play an important role in the avionics ecosystem. These organizations manage aircraft lifecycle support and implement avionics upgrades throughout an aircraft’s operational life.

Their responsibilities include:

• Installing upgraded mission computers and cockpit displays

• Integrating new communication and navigation systems

• Conducting diagnostics and performance testing of avionics modules

• Supporting avionics software updates and cybersecurity enhancements

As military aircraft remain operational for several decades, avionics upgrades represent one of the most common modernization activities throughout an aircraft’s lifecycle.

 

Use Case Highlight

A modern fighter squadron operating in a contested airspace scenario relies heavily on integrated avionics systems for mission success.

During a surveillance and interception mission, the aircraft’s avionics platform performs several tasks simultaneously:

• Radar and infrared sensors detect potential airborne threats

• Sensor fusion software combines incoming data into a unified tactical display

• The mission computer analyzes threat behavior and prioritizes targets

• Secure communication systems share real-time intelligence with other aircraft and ground command units

• Electronic warfare modules monitor enemy radar signals and deploy countermeasures if necessary

Within seconds, the pilot receives a simplified operational picture generated by the aircraft’s avionics system, enabling rapid decision-making during high-speed combat operations.

This example illustrates how avionics systems are no longer passive flight instruments but active mission management platforms.

Overall, end-user adoption of military avionics continues to expand as defense forces prioritize digital battlefield connectivity, advanced situational awareness, and operational resilience across air combat platforms.

 

Recent Developments Opportunities and Restraints

Recent Developments

• 2024: BAE Systems introduced an upgraded mission computer architecture designed to support next-generation fighter aircraft programs and improve real-time data processing capabilities within integrated avionics environments.

• 2024: Collins Aerospace expanded its secure airborne communication technologies aimed at enabling advanced data sharing between military aircraft, ground control stations, and satellite networks in multi-domain combat environments.

• 2023: Thales Group enhanced its avionics solutions portfolio with next-generation cockpit display systems designed for modern combat aircraft and military helicopters, improving pilot situational awareness and mission data visualization.

• 2023: Elbit Systems advanced its helmet-mounted display technology for fighter aircraft, enabling pilots to access targeting data, navigation information, and threat alerts directly within their field of view.

• 2023: Honeywell Aerospace introduced advanced inertial navigation technologies designed to provide accurate positioning for military aircraft operating in environments where GPS signals may be degraded or unavailable.
   

Opportunities

• Expansion of Next-Generation Fighter Aircraft Programs
  Development of fifth-generation and emerging sixth-generation combat aircraft platforms is creating significant demand for advanced avionics systems capable of supporting sensor fusion, artificial intelligence integration, and network-centric warfare.

• Growth of Military Drone and Autonomous Aircraft Programs
  Increasing adoption of unmanned aerial vehicles for surveillance, reconnaissance, and combat missions is driving demand for autonomous navigation systems, secure communication links, and advanced mission management avionics.

• Avionics Modernization for Legacy Aircraft Fleets
  Many defense forces are prioritizing avionics upgrades for existing aircraft rather than purchasing entirely new fleets. These modernization initiatives present major opportunities for avionics suppliers offering modular and scalable upgrade solutions.
   

Restraints

• High Development and Integration Costs
  Designing and integrating advanced avionics systems involves extensive testing, certification, and compliance with strict military standards, which significantly increases development costs and project timelines.

• Complex System Integration Challenges
  Integrating modern avionics technologies into legacy aircraft platforms can be technically challenging due to compatibility issues between older aircraft architectures and new digital avionics systems.

 

7.1. Report Coverage Table

Report Attribute	Details
Forecast Period	2024 – 2030
Market Size Value in 2024	USD 38.5 Billion
Revenue Forecast in 2030	USD 57.2 Billion
Overall Growth Rate	CAGR of 6.8% (2025 – 2030)
Base Year for Estimation	2024
Historical Data	2019 – 2023
Unit	USD Million, CAGR (2025 – 2030)
Segmentation	By System Type, By Aircraft Type, By Application, By Geography
By System Type	Flight Control Systems, Communication Systems, Navigation Systems, Surveillance and Reconnaissance Systems, Mission Computers and Integrated Avionics Suites
By Aircraft Type	Fighter Aircraft, Transport and Military Cargo Aircraft, Helicopters and Rotary-Wing Aircraft, Unmanned Aerial Vehicles
By Application	Navigation and Guidance, Communication and Data Link, Electronic Warfare and Threat Detection, Surveillance and Intelligence Gathering
By Region	North America, Europe, Asia-Pacific, Latin America, Middle East and Africa
Country Scope	U.S., UK, Germany, France, China, India, Japan, South Korea, Brazil, Saudi Arabia, UAE, and others
Market Drivers	- Rising military aircraft modernization programs worldwide - Growing demand for advanced sensor fusion and electronic warfare avionics - Expansion of unmanned aerial systems and autonomous combat platforms
Customization Option	Available upon request