Europe & CIS Air and Missile Defense Radar (AMDR) Market By Platform (Airborne, Land, Naval), By Radar Type (X Band Radar, Y Band Radar), By Application (Conventional, Ballistic Missile Defense), By Country, Competition, Forecast & Opportunities, 2020-2030F

Market Overview:

Europe & CIS Air and Missile Defense Radar (AMDR) Market was valued at USD 539.27 Million in 2024 and is expected to reach USD 753.78 Million by 2030 with a CAGR of 5.74% during the forecast period. Europe & CIS Air and Missile Defense Radar (AMDR) market is experiencing notable growth, fueled by modernization programs aimed at replacing legacy radar systems with next-generation solutions that provide higher accuracy, extended range, and faster target detection. Rising investments in advanced radar technologies, such as phased-array and multi-function radars, are enhancing situational awareness and threat response capabilities. The increasing complexity of aerial and missile threats has driven demand for integrated air defense systems capable of tracking multiple targets simultaneously and coordinating with other defense assets.

Market Drivers

Modernization of Legacy Defense Systems

The drive to replace outdated radar infrastructure with advanced systems is a critical factor shaping market growth. Legacy radars often struggle with limited range, slower processing speeds, and reduced accuracy, making them less effective against modern aerial threats. Modern air and missile defense radars incorporate phased-array technology, multi-function capabilities, and faster signal processing, enabling real-time detection, tracking, and interception of multiple targets simultaneously. The modernization process not only improves operational efficiency but also ensures compatibility with contemporary defense networks, enhancing integrated air defense strategies. Governments and defense agencies are prioritizing modernization to meet evolving threat landscapes and maintain strategic superiority. Investment in advanced radars also allows for scalable and modular designs, enabling upgrades as technology evolves, reducing long-term operational costs. For instance, in 2024, EU states spent $370B on defence, up 19% from 2023 and projected at $412B in 2025. Investments reached $115B, with $95B for equipment, expected to top $108B in 2025. R&D rose to $14B and should hit $18B in 2025. The defence industry generated $172B turnover, $62B exports, and 627K jobs in 2023. EU programmes added $9.5B via the Defence Fund, $1.8B for mobility, $300M for joint procurement, $500M for ammunition, and a planned $1.6B under EDIP by 2027, with 2,500 SMEs central to supply chains.

Advanced Radar Technology Adoption

The adoption of sophisticated radar technologies is transforming air and missile defense operations. Phased-array radars, multi-band frequency systems, and active electronically scanned array (AESA) solutions offer improved detection range, higher resolution, and faster target acquisition. These technologies enable defense forces to detect and respond to highly maneuverable or stealth-enabled threats that traditional radars cannot reliably track. AI and machine learning integration enhances predictive threat analysis, allowing radars to anticipate potential attack vectors, optimize resource allocation, and automate threat prioritization. High-speed processing and improved signal filtering minimize false alarms and enhance operational reliability, which is vital during high-intensity conflict scenarios. Defense agencies are increasingly investing in AI-enabled radar systems for autonomous threat recognition and decision support, reducing human intervention while improving situational awareness. For instance, in 2024, the European Commission allocated $8.6 billion to defense research over seven years, up from $696 million in 2017–2020. Funding through the European Defense Fund supports 34 projects, including drones, radar, hypersonic defense, and AI communications, with $118 million for a long-range ISTAR drone, $29 million for a military 5G network, and $53 million for AI interoperability prototypes.

Rising Aerial and Missile Threats

The growing sophistication of aerial and missile threats is driving demand for advanced radar systems capable of detecting, tracking, and neutralizing multiple high-speed targets. Modern threats, including ballistic missiles, cruise missiles, hypersonic vehicles, and unmanned aerial systems, require radar systems with extended range, rapid refresh rates, and superior tracking precision. These threats often employ stealth technologies and evasive maneuvers, making conventional radar systems inadequate. Air and missile defense radars must therefore provide multi-target engagement capabilities, integration with interceptor systems, and real-time situational awareness. Nations are prioritizing investments in radar solutions that can deliver early warning, threat classification, and rapid response to ensure defense readiness. High mobility and deployable radar units are also gaining attention to support flexible operational requirements across diverse terrains. For instance, in May 2024, Poland signed a nearly $1 billion deal to acquire four U.S.-made aerostat surveillance systems, enhancing early warning and detection of aircraft, drones, missiles, and maritime threats along its eastern and northeastern borders.

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Key Market Challenges

High Development and Procurement Costs

The design, production, and deployment of advanced air and missile defense radar systems require significant financial investment. Cutting-edge technologies such as phased-array radars, AESA systems, and AI-enabled processing demand extensive research and development, precision manufacturing, and rigorous testing, which drive up costs. Procurement programs involve long-term contracts and multi-billion-dollar budgets, often requiring government approval and strategic planning. High costs can limit adoption among smaller defense agencies and slow procurement cycles, affecting overall market growth. Maintenance, upgrades, and integration into existing defense networks further add to operational expenses. These financial challenges necessitate careful allocation of resources and prioritization of radar systems within broader defense budgets.

Integration and Interoperability Complexities

Modern radar systems must seamlessly integrate with a range of existing defense platforms, including missile interceptors, command and control systems, and airborne assets. Achieving interoperability between different generations of equipment, communication protocols, and software architectures presents significant technical challenges. Complex integration processes require extensive testing, calibration, and software optimization to ensure reliable performance during high-pressure operational scenarios. Compatibility issues can lead to delays in deployment, system malfunctions, or reduced operational efficiency. Additionally, cybersecurity concerns arise when integrating networked radar systems, as vulnerabilities could be exploited by adversaries to disrupt defense operations.

Key Market Trends

Modular and Scalable Radar Platforms

Radar manufacturers are increasingly developing modular and scalable systems to provide flexibility in deployment and upgrade paths. Modular designs allow components such as transmitters, receivers, antennas, and signal processors to be easily replaced or enhanced without replacing the entire system. Scalability ensures that radar platforms can be adapted for different mission requirements, from fixed installations to mobile units. This approach extends system lifecycles, reduces costs, and allows for rapid adaptation to evolving threat scenarios. Integration with other defense assets, such as missile defense units and command networks, becomes more efficient, supporting coordinated multi-domain operations. Modular and scalable designs also facilitate international collaborations, technology transfer, and joint procurement programs.

AI and Machine Learning Integration

Incorporating artificial intelligence and machine learning into radar systems is transforming detection, tracking, and threat response processes. AI algorithms analyze vast amounts of radar data in real time, identifying patterns, predicting trajectories, and prioritizing threats with minimal human intervention. Machine learning models improve over time, adapting to new threat behaviors, reducing false positives, and enhancing decision-making speed. AI-enabled radars can also optimize resource allocation, automate target classification, and support autonomous or semi-autonomous defense operations. Integration with command and control systems allows for synchronized responses across multiple platforms, improving operational efficiency. The increasing adoption of AI reflects the broader trend toward smart, autonomous defense technologies that enhance situational awareness, operational reliability, and mission effectiveness.

Electronic Warfare Resistance

Modern radar systems are increasingly designed to withstand electronic warfare tactics, such as jamming, spoofing, and cyber-attacks. Threats that attempt to degrade radar performance or manipulate sensor data require radars to employ robust signal processing, frequency agility, and anti-jamming techniques. Electronic warfare-resistant designs ensure that critical defense operations remain uninterrupted even in hostile electromagnetic environments. Radars capable of operating under contested conditions enhance survivability, reliability, and mission readiness, providing a tactical advantage against adversaries employing advanced countermeasures. This trend is driving innovation in software-defined radar architectures, resilient communication protocols, and adaptive detection techniques, ensuring long-term operational effectiveness and resilience of air and missile defense networks.

Segmental Insights

Platform Insights

In 2024, Europe & CIS Air and Missile Defense Radar (AMDR) market was dominated by land-based radar platforms, which account for the largest share of deployments across the region. Land-based systems provide versatile and scalable solutions capable of monitoring wide areas, detecting multiple aerial and missile threats, and coordinating with other defense assets in real time. These platforms offer high mobility, allowing rapid deployment to critical locations and ensuring coverage in diverse operational environments, from border security to strategic military installations. Advanced technologies such as phased-array antennas, multi-function capabilities, and high-speed signal processing enhance detection accuracy, target tracking, and threat classification, making land-based radars highly effective against evolving aerial threats including cruise missiles, ballistic missiles, and unmanned systems.

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Country Insights

In 2024, Russia dominated Europe & CIS Air and Missile Defense Radar (AMDR) market, maintaining the largest share due to substantial investments in modernizing its air and missile defense capabilities. The focus on deploying advanced radar systems capable of detecting and tracking high-speed aerial and missile threats has strengthened national defense infrastructure. Russian radar networks integrate multi-function phased-array radars with long-range detection capabilities, ensuring comprehensive coverage for critical regions. High mobility and deployable radar units support rapid operational response across vast territories, while integration with command and control networks enhances situational awareness and coordinated defense.

Germany represents the second-largest market in 2024, driven by modernization programs aimed at upgrading legacy radar systems and integrating advanced technologies into existing defense networks. The emphasis on multi-function radar platforms with enhanced detection, tracking, and target classification capabilities has strengthened air and missile defense readiness. Germany’s investment in scalable and modular radar architectures supports operational flexibility and seamless interoperability with allied defense systems. High focus on early warning capabilities and integration with broader European defense initiatives has contributed to steady market growth, reinforcing Germany as a significant contributor to the regional AMDR market. For instance, in March 2025, Germany planned a $16 billion investment in six F127 frigates to replace aging F124 ships by the mid-2030s. The frigates will feature advanced AEGIS combat systems, AN/SPY-6 radar, 64 VLS cells, and modular “flex zones” for drones and mission-specific equipment, enhancing naval capabilities and missile defense.

Recent Developments

• ​In 2025, Greece launched a $27 billion rearmament program under the "Shield of Achilles" initiative, modernizing air, missile, naval, and drone defenses. As part of its "Agenda 2030" strategy, Greece aims to raise defense spending to 3% of GDP and strengthen European defense autonomy through a mix of U.S. and European weaponry.
• In April 2025, Ireland announced plans to deploy its first primary military radar system capable of detecting stealth aircraft. Expected to be operational by 2028, this radar will enhance Ireland's ability to monitor airspace for threats, including hijacked planes and those with disabled transponders.
• In April 2025, NATO awarded Keysight Technologies a contract to provide advanced radar target generators and electronic warfare simulators. These systems will enhance testing of radar and ESM performance across NATO sites, enabling simulation of complex electromagnetic environments and strengthening operational readiness.
• In February 2025, Indra won a contract to supply the German Air Force with an advanced radar system for low Earth orbit monitoring, enhancing protection of military and civilian satellites from debris and unauthorized approaches. The modular system will be operated remotely from Germany's Space Situational Awareness Center.

Key Market Players

• Hensoldt AG
• Israel Aerospace Industries
• Leonardo S.p.A.
• Lockheed Martin Corporation
• Northrop Grumman
• RTX Corporation
• Rheinmetall AG
• Saab AB
• Terma Group
• Thales S.A

Report Scope:

In this report, Europe & CIS Air and Missile Defense Radar (AMDR) Market has been segmented into the following categories, in addition to the industry trends which have also been detailed below:

•           Europe & CIS Air and Missile Defense Radar (AMDR) Market, By Radar Type:

o    X Band Radar

o    Y Band Radar

•           Europe & CIS Air and Missile Defense Radar (AMDR) Market, By Platform:

o    Airborne

o    Land

o    Naval

•           Europe & CIS Air and Missile Defense Radar (AMDR) Market, By Application:

o    Conventional

o    Ballistic Missile Defense

•           Europe & CIS Air and Missile Defense Radar (AMDR) Market, By Country:

o    Germany

o    Russia

o    France

o    Spain

o    Italy

o    United Kingdom

o    Poland

o    Rest of Europe & CIS

Competitive Landscape

Company Profiles: Detailed analysis of the major companies presents in Europe & CIS Air and Missile Defense Radar (AMDR) Market.

Available Customizations:

Europe & CIS Air and Missile Defense Radar (AMDR) Market report with the given market data, TechSci Research offers customizations according to the company’s specific needs. The following customization options are available for the report:

Company Information

• Detailed analysis and profiling of additional market players (up to five).

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