ASRAAM
The Advanced Short Range Air-to-Air Missile (ASRAAM) is a British-developed, infrared-homing air-to-air missile optimized for within-visual-range (WVR) combat, featuring high speed, exceptional maneuverability, and fire-and-forget capability to enable rapid target engagement and pilot evasion.[1][2] Initiated in the 1980s as a multinational effort involving the United Kingdom, Germany, and initially France, the ASRAAM program proceeded independently under British lead after partner nations withdrew, with development handled by Matra BAe Dynamics (now MBDA); the first missiles entered Royal Air Force (RAF) service in 1998, primarily arming Tornado F3, Harrier GR7, and later Eurofighter Typhoon aircraft as a replacement for the AIM-9 Sidewinder.[3][4] Weighing 88 kg with a length of 2.9 m and diameter of 166 mm, ASRAAM achieves speeds exceeding Mach 3 and ranges over 25 km, propelled by a solid-fuel rocket motor and guided by an imaging infrared seeker that supports high off-boresight launches up to 90 degrees, enhancing its effectiveness against agile threats in close-quarters aerial engagements.[5][6] In addition to fixed-wing platforms like the F-35 Lightning II, ASRAAM has been integrated with Royal Australian Air Force aircraft and Indian Jaguar fighters, while recent adaptations include ground- and surface-launched configurations, such as the UK's Raven system supplied to Ukraine for short-range air defense against drones and cruise missiles, demonstrating its versatility beyond original air-to-air roles.[1][7][8]History
Development Origins
The development of the ASRAAM originated from NATO efforts in the early 1980s to modernize short-range air-to-air missiles as replacements for the AIM-9L Sidewinder, amid recognition that existing infrared-guided systems required enhanced agility, range, and off-boresight capability to counter evolving threats in visual-range combat.[9] In August 1980, the United Kingdom, Germany, and United States signed a Memorandum of Understanding (MoU) that allocated the US to lead development of the medium-range AIM-120 AMRAAM, while committing the UK and Germany to jointly pursue an advanced short-range air-to-air missile (ASRAAM) to meet complementary needs for beyond-visual-range and within-visual-range engagements.[3] [9] A tri-national Staff Requirement for ASRAAM was formalized in October 1984, specifying performance goals such as improved seeker sensitivity, high off-boresight firing angles, and rocket motor enhancements for greater speed and maneuverability over legacy Sidewinder variants.[10] The collaboration aimed to leverage shared European industrial resources, with initial design work focusing on imaging infrared seekers and thrust-vectoring controls, but Germany withdrew from the program in 1989 due to budgetary constraints and a decision to prioritize AIM-9L upgrades for its Luftwaffe aircraft.[11] [3] Following Germany's exit, the UK Ministry of Defence proceeded unilaterally, selecting British Aerospace (BAe) Dynamics—later part of MBDA—as the prime contractor in 1990 to advance the project under national control, ensuring alignment with Royal Air Force requirements for integration on platforms like the Tornado F3 and Eurofighter Typhoon.[11] This shift allowed the UK to incorporate proprietary technologies, such as advanced fuze systems and reduced-smoke propulsion, without collaborative compromises, culminating in the missile's qualification by the late 1990s.[3]New ASRAAM Program
In September 2015, the United Kingdom Ministry of Defence awarded MBDA (UK) Ltd a £300 million contract to develop and produce an upgraded variant of the ASRAAM missile.[12] The eight-year program focused on incorporating updated sub-systems into the existing design to improve performance, ensure compatibility with the Royal Air Force's Eurofighter Typhoon and Tornado GR4 aircraft, and prepare for integration with the F-35 Lightning II.[12] This initiative aimed to sustain and enhance the UK's short-range air-to-air defence capabilities amid evolving threats, while leveraging the missile's proven fire-and-forget infrared homing technology.[12] [13] The upgrade emphasized modular enhancements to key components, including the seeker and electronics, without altering the missile's core aerodynamics or propulsion to minimize development risks and costs.[13] MBDA's work under the contract supported approximately 200 direct high-skilled jobs across its facilities in Bristol, Stevenage (Hertfordshire), and Lostock (Lancashire), plus around 200 additional positions in the broader UK supply chain.[12] The program aligned with the MOD's rising £160 billion equipment investment plan, prioritizing sovereign capabilities and industrial base retention.[12] Subsequent phases included a £184 million follow-on contract in August 2016 for ASRAAM production and adaptation specifically for the UK's F-35B fleet, enabling internal carriage and high off-boresight launches via helmet-cued systems.[14] These efforts culminated in the missile's successful live-fire demonstrations from the F-35, confirming enhanced lethality and integration by the early 2020s.[15] The program's outcomes contributed to extended service life for ASRAAM, bridging to potential future short-range missile requirements until at least the mid-2030s.[16]Testing, Qualification, and Production
The ASRAAM underwent initial flight testing in 1994, followed by its first unguided test launch on October 17, 1995, from a Lockheed Martin F-16 at Eglin Air Force Base, Florida.[17] The inaugural guided firing occurred in 1996, also from an F-16 in the United States, validating the missile's infrared seeker and fire-and-forget capabilities against maneuvering targets.[3] Subsequent trials encompassed captive carry, separation, and live-fire demonstrations from platforms including the Tornado F3, confirming compatibility with RAF aircraft under the UK's operational envelope.[18] Qualification for Royal Air Force service was achieved in 1998, enabling initial operational capability and replacement of the AIM-9 Sidewinder on front-line squadrons.[19] Export variants underwent platform-specific certification, such as the Royal Australian Air Force's clearance on August 20, 2004, after integration trials on F/A-18 Hornets that included hazardous electromagnetic radiation operations and telemetry validation. Ongoing qualification efforts for the F-35 Lightning II included handling trials completed in November 2014 and the first live firing on February 24, 2017, from an F-35B over the Point Mugu Sea Range, marking the initial non-U.S. missile integration success.[20][21] Production responsibility lies with MBDA UK, with manufacturing at the Bolton facility following a £40 million facility investment.[3] Initial low-rate production supported RAF entry into service, scaling with export orders including a 2014 £250 million contract for 384 missiles to India for Jaguar integration.[15] A 2016 UK Ministry of Defence contract initiated F-35-specific production, incorporating software enhancements developed collaboratively with Australia.[15] In 2021, MBDA signed a licensing agreement with India's Bharat Dynamics Limited for final assembly, integration, and testing to localize output and transfer technology. Recent exercises, such as the RAF's record 2022 mass firing of over a dozen ASRAAMs from Typhoon and F-35B aircraft in the Hebrides Range, have verified sustained production quality and combat readiness.[22]Design and Characteristics
Guidance and Seeker Technology
The ASRAAM utilizes a passive infrared homing guidance system centered on an advanced imaging infrared (IIR) seeker, which provides fire-and-forget capability with high resistance to electronic countermeasures and flares.[2] The system integrates inertial navigation for mid-course guidance, allowing the missile to receive target updates from the launching aircraft before seeker activation, thereby supporting engagements beyond visual range or against maneuvering targets.[3][23] The seeker's core component is a cooled focal plane array (FPA) detector with 128×128 pixel resolution, originally developed by Hughes (later Raytheon), enabling precise target imaging, discrimination of decoys, and operation in cluttered infrared environments.[2][23][24] This FPA design supports both lock-on before launch (LOBL) and lock-on after launch (LOAL) modes, with a wide field of view (FOV) facilitating off-boresight targeting angles of up to ±90 degrees relative to the missile's axis.[18] The seeker is protected by a robust sapphire dome, enhancing environmental resilience and optical clarity during high-speed flight.[4] These features collectively enable the ASRAAM to engage agile, low-signature targets such as modern fighters employing infrared suppression, prioritizing rapid acquisition and terminal homing over traditional reticle-based seekers found in earlier missiles like the AIM-9L.[18][3]Propulsion, Aerodynamics, and Range
The ASRAAM employs a dual-thrust solid-fuel rocket motor, featuring an initial boost phase followed by a sustain phase to achieve high velocity and extended engagement capability.[25] This propulsion system, with a 166 mm diameter, delivers speeds exceeding Mach 3, enabling rapid target interception.[1][24] The motor's design minimizes infrared signature while providing the impulse necessary for the missile's kinematic performance.[2] Aerodynamically, the ASRAAM features a low-drag airframe optimized for minimal resistance, incorporating tail control surfaces without forward fins to enhance speed and maneuverability across the flight envelope.[1] This configuration, combined with the large rocket motor, supports high agility in within-visual-range engagements, allowing for superior end-game kinematics compared to predecessors.[3] The missile's 2.9 m length and 166 mm diameter contribute to its streamlined profile, facilitating launches from various aircraft platforms with reduced aerodynamic penalties.[2] In air-to-air mode, the ASRAAM achieves an effective range in excess of 25 km, with some reports indicating up to 50 km under optimal conditions, though exact figures remain classified.[3] Surface-launched variants, such as those adapted for ground-based systems, exhibit reduced ranges around 15 km due to launch dynamics and booster constraints.[25] These capabilities stem directly from the integrated propulsion and aerodynamic efficiencies, prioritizing beyond-visual-range shots while retaining dogfight effectiveness.[1]
Warhead and Lethality Features
The ASRAAM employs a high-explosive blast-fragmentation warhead weighing approximately 10 kg (22 lb), designed to inflict damage through both explosive overpressure and high-velocity fragments penetrating airframe structures.[5][6][25] This warhead configuration prioritizes lethality against maneuvering aerial targets, including fighters and smaller threats like drones, by dispersing fragments over a wide radius to maximize structural disruption without requiring precise direct impacts.[5][6] Lethality is enhanced by an advanced fuzing system incorporating both impact and laser proximity modes, which detects and detonates the warhead near the target to optimize fragment dispersion and blast effects against both large aircraft and agile, low-signature platforms.[5][6][26] The laser proximity fuze, developed by Thorn-EMI, employs a conventional pulsed laser to sense target proximity, enabling detonation at an effective standoff distance that compensates for the missile's high-speed intercept dynamics and potential evasive maneuvers.[2][3] This combination of blast-fragmentation payload and dual-mode fuzing provides superior single-shot kill probability in beyond-visual-range engagements, as evidenced by the warhead's ability to defeat hardened targets with minimal collateral fragmentation patterns suited for air-to-air roles.[6][2] In operational adaptations, such as surface-launched variants, the warhead maintains effectiveness against low-flying threats like cruise missiles and UAVs, with reported successes in fragmenting drone airframes while limiting ground risks.[27][28] The design, originally from DASA, emphasizes compact efficiency within the missile's 166 mm diameter envelope to balance payload mass with overall aerodynamics.[3][29]Variants
ASRAAM P3I
The ASRAAM P3I, or Pre-Planned Product Improvement variant, emerged in 1995 as a collaborative effort between Hughes Aircraft Company and British Aerospace to enhance the baseline ASRAAM design for potential integration into United States Air Force short-range air-to-air missile programs.[30] This upgrade aimed to position the missile as a contender in the AIM-9X competition by incorporating advanced features to improve overall performance without fundamentally altering the core airframe.[30] Key proposed modifications included thrust-vectoring control for superior post-launch maneuverability, enabling tighter turns and faster target acquisition in beyond-visual-range engagements, alongside provisions for a heavier warhead to increase lethality against maneuvering threats.[4] These enhancements were intended to address limitations in the original ASRAAM's agility while maintaining its imaging infrared seeker and high-speed propulsion.[4] U.S. Department of Defense officials viewed the P3I development as compatible with ongoing AIM-9X efforts, potentially allowing interoperability testing on platforms like the F-15 Eagle and F/A-18 Hornet, though no production contracts materialized and the variant remained at the proposal stage.[30]ASRAAM Block 6
The ASRAAM Block 6 represents an upgraded configuration of the Advanced Short Range Air-to-Air Missile, incorporating enhancements to sustain and improve its operational effectiveness. Developed under the ASRAAM Sustainment programme by MBDA UK, it achieved initial operating capability on the Eurofighter Typhoon aircraft on 1 April 2022.[3][31] Key upgrades in the Block 6 variant include a new UK-designed infrared seeker featuring higher resolution and increased pixel count, which enhances target detection, discrimination, and resistance to countermeasures compared to prior models.[22][32][31] The missile also integrates an internal cryogenic cooling system, replacing the external cooling required by earlier versions and enabling more reliable seeker performance without additional ground support equipment.[22][32] This variant eliminates all components of U.S. origin, relying exclusively on British-sourced parts, which removes International Traffic in Arms Regulations (ITAR) constraints and broadens export potential for user nations.[33][34] Integration efforts extend to the F-35B Lightning II platform, with service entry anticipated as part of the Block IV software upgrade, though specific timelines remain subject to ongoing testing and qualification.[3][16] These modifications maintain the missile's core fire-and-forget capabilities while addressing sustainment challenges and adapting to evolving within-visual-range combat requirements.[31]Raven Surface-Launched Variant
The Raven is a short-range, mobile air defense system utilizing a surface-launched adaptation of the AIM-132 ASRAAM missile, developed by British defense firms including MBDA to counter aerial threats such as drones, cruise missiles, helicopters, and fixed-wing aircraft.[35] Conceived in response to the Russia-Ukraine conflict, the system repurposes surplus ASRAAM inventory—originally air-to-air missiles nearing expiration—via minimal modifications like aerospace-derived launch pylons, enabling ground-based fire-and-forget engagements through the missile's imaging infrared seeker with lock-on after launch.[35] The missile achieves Mach 3 speeds, carries an 10 kg warhead, and attains effective ranges up to 15 km in surface-to-air mode.[35] Typically integrated on the Supacat HMT 600 6x6 high-mobility tactical vehicle, Raven supports rapid deployment for point defense or layered air/missile protection of forces and infrastructure, with a fully passive design minimizing detectability and logistics via single-truck operations.[35] Deliveries to Ukraine commenced in late 2022, with eight complete systems transferred by early 2025, five more pending, over 400 missiles supplied, and an additional 350 announced on June 24, 2025.[35] In Ukrainian service, Raven has recorded a circa 75% intercept success rate, with individual units downing 24 strike and reconnaissance drones since spring 2023, plus cruise missiles including three Kh-59s and one Kh-101 in a single engagement reported October 23, 2025; one operator noted its unexpected efficacy against guided munitions beyond initial drone-focused expectations.[35][36] Systems have also attempted fixed-wing intercepts, such as a Su-34, and collectively neutralized over 400 targets by late spring 2025.[37][36] MBDA formalized the surface-launched ASRAAM for Raven at DSEI 2025, rendering it platform-agnostic for static, tracked, wheeled, or unmanned integrations—including Estonia's THeMIS robotic vehicles, upgraded Rapier launchers, Wolfhound 6x6 armor, and Ajax vehicles—while enabling shared stockpiles across air and ground commands.[38][37] Upgrades feature doubled missile capacity on HMT 600 chassis, with the overall configuration weighing 13 tonnes and measuring 8 m in length for versatile short-range defense.[38][37]Related Systems
Common Anti-Air Modular Missile (CAMM)
The Common Anti-Air Modular Missile (CAMM) represents a surface-launched evolution of ASRAAM technology, developed by MBDA UK to provide modular short- to medium-range air defense for land and naval platforms. While sharing core components with ASRAAM—including the Roxel rocket motor, warhead, and proximity fuse—CAMM incorporates distinct adaptations such as an active radiofrequency (RF) seeker based on gallium nitride electronics and the PrOTeUS architecture for enhanced processing and all-weather performance.[39][40] This shift from ASRAAM's infrared seeker enables reliable target acquisition in adverse conditions, with mid-course guidance via two-way data link for retargeting before terminal active homing.[41] The design emphasizes commonality to leverage ASRAAM's proven lethality while optimizing for vertical "soft" launch, achieving 360-degree coverage without launch signatures from tilt mechanisms.[39] Development originated from UK Ministry of Defence studies post-2004, with a £10 million concept phase contract in 2004, followed by £15 million for technology maturation in 2008 and a £483 million demonstration/validation phase in 2012. Qualification trials concluded successfully, leading to initial operating capability with the Royal Navy's Sea Ceptor system in May 2018 and the British Army's Sky Sabre in 2020.[39] CAMM replaces legacy systems like Seawolf and Rapier, quad-packing into standard 0.635 m × 0.635 m × 2.44 m containers for high-volume fire rates against saturation threats.[42] Key specifications include a length of 3.2 meters, diameter of 166 mm, and weight of 99 kg, with a maximum range exceeding 25 km and speeds reaching Mach 3 (approximately 1,029 m/s).[39][43] Inertial navigation supports initial flight, transitioning to data-linked updates from offboard sensors until seeker activation. The system's modularity allows integration with diverse radars via networked battle management, without requiring dedicated illuminators. Variants such as CAMM-ER extend range beyond 45 km using an enlarged booster, while CAMM-MR concepts aim for over 100 km.[39] Operational deployment includes naval use on Type 23 and Type 26 frigates, and ground-based roles in Enhanced Modular Air Defence Solutions (EMADS). The first confirmed combat success occurred in March 2024, when HMS Richmond used CAMM to intercept Houthi drones in the Red Sea.[39] This relation to ASRAAM underscores cost efficiencies through component reuse—estimated to reduce development expenses—but CAMM's RF guidance and launch profile make it unsuitable for direct air-to-air roles without further modification.[39]Operational History
Air-Launched Operations in RAF and Allied Forces
The ASRAAM entered service with the Royal Air Force in 1998, initially equipping the Tornado F3, Harrier GR7, and later the Eurofighter Typhoon FGR4, replacing the AIM-9L Sidewinder as the primary short-range air-to-air missile.[2] It is carried on underwing pylons for Typhoon aircraft during Quick Reaction Alert (QRA) duties and operational deployments.[44] The missile's integration supports high off-boresight firing capabilities, enabling pilots to engage targets without pointing the aircraft directly at them.[3] In operational history, ASRAAM achieved its first confirmed combat success on December 14, 2021, when an RAF Typhoon FGR4, operating against Islamic State remnants in southern Syria, downed a hostile unmanned aerial system using the missile near the Al Tanf coalition base.[22] This marked the missile's debut in live combat, demonstrating its effectiveness against small, low-flying threats in a beyond-visual-range scenario.[3] ASRAAM has been routinely deployed on Typhoons for air policing missions over the Baltic and Black Sea regions as part of NATO commitments, often in conjunction with longer-range AMRAAMs for layered defense.[24] Training exercises highlight ASRAAM's reliability in massed firings. In October 2022, RAF Typhoon FGR4 and F-35B Lightning II aircraft conducted the largest-ever ASRAAM live-fire event during the Missile Practice Camp off the Scottish coast, launching 53 missiles with a near-perfect hit rate against towed targets simulating enemy fighters.[45] This exercise validated the missile's performance across platforms, including the F-35B's external carriage configuration, and provided data for tactics refinement.[46] Among allied forces, the Royal Australian Air Force integrated ASRAAM in August 2004 for its F/A-18 Hornet fleet, conducting successful live firings to confirm compatibility and lethality in close-quarters engagements.[2] MBDA reported a test launch from RAAF aircraft, underscoring its operational readiness.[15] India has ordered ASRAAM for overwing integration on its SEPECAT Jaguar fleet, with local assembly planned to enhance short-range air combat capabilities, though full operational deployment remains ongoing as of 2025.[1] Qatar Emiri Air Force and Royal Air Force of Oman employ ASRAAM on Eurofighter Typhoons for similar air superiority roles, participating in joint exercises with RAF assets.[2]Surface-Launched Deployments in Ukraine
In August 2023, the United Kingdom supplied Ukraine with an initial batch of improvised ground-based launchers adapted for the ASRAAM missile, enabling its use as a surface-to-air system against Russian aerial threats.[19] This adaptation, designated as the Raven air defense system, repurposed surplus air-launched ASRAAM missiles by mounting them on vehicle-based platforms with modified pylons from retired fighter aircraft, allowing rapid deployment without extensive redesign.[27] Development of Raven prototypes occurred in approximately four months, from conceptualization to initial fielding, prioritizing quick integration for Ukraine's urgent needs amid shortages of dedicated short-range air defense munitions.[27] Eight Raven systems were delivered by early 2023, with five additional units slated for shipment in 2025 to expand coverage.[47] The Raven system's ASRAAM variant operates with a reduced effective range compared to its air-launched configuration—estimated at under 25 km from ground level due to the absence of initial aircraft velocity—but retains infrared homing guidance for fire-and-forget engagements, proving suitable for intercepting low-flying drones, cruise missiles, and fixed-wing aircraft in contested airspace.[27] Early combat evaluations in Ukraine reported a 90% hit rate for ground-launched ASRAAM engagements as of January 2024, attributed to the missile's agile seeker and high maneuverability against maneuvering targets.[48] By October 2025, Ukrainian forces had used Raven to destroy over 24 Russian drones and four cruise missiles, including three Kh-59s and one Kh-101 in a single engagement reported by Air Command West, alongside confirmed shootdowns of Su-25 ground-attack jets.[36] These successes highlight the system's utility in asymmetric defense scenarios, where its "lock-on after launch" capability allows operators to engage targets obscured by terrain or weather without line-of-sight exposure.[49] To sustain operations, the UK committed 350 additional ASRAAM missiles for ground launch in June 2025, funded partly by proceeds from seized Russian assets, ensuring compatibility with existing Raven platforms and addressing depletion from high-intensity use against drone swarms and standoff munitions.[47] Two prototypes underwent live-fire testing in Ukraine in September 2024, validating integration with mobile launchers and paving the way for scaled production of up to 15 more systems in 2025.[7] British officials have described Raven's performance as "successful," with anecdotal field reports emphasizing its role in bolstering short-range layered defenses, though quantitative data remains limited by operational security.[50]Performance Assessment
Test and Evaluation Results
The ASRAAM achieved initial qualification through developmental firing trials conducted in the 1990s, culminating in its entry into Royal Air Force service by 2002 as a replacement for the AIM-9L Sidewinder.[3] In November 2000, the Royal Australian Air Force conducted the first operational test firings of ASRAAM from F/A-18 Hornet aircraft, validating its integration and performance on non-RAF platforms.[2] Integration testing for the F/A-18 included captive carriage evaluations and live firings to assess the missile's Infra-Red Counter-Counter-Measure (IRCCM) effectiveness against simulated threats.[51] In December 2014, UK test teams completed initial aircraft handling trials for ASRAAM on the F-35B Lightning II, confirming safe carriage and release characteristics.[52] The missile's first live firing from an F-35 occurred in February 2017, marking the debut of a non-U.S. weapon on the platform and demonstrating compatibility with its internal weapons bays.[53] For the ASRAAM Block 6 upgrade, integration on the Eurofighter Typhoon achieved Initial Operating Capability, with trials verifying enhanced software and seeker performance.[3] A major evaluation exercise in September 2022 over the Hebrides range saw RAF Typhoon and F-35B aircraft fire a record 53 ASRAAMs in within-visual-range scenarios, with all launches successful, underscoring the missile's reliability across platforms and operational tempos.[54][45][22] The Royal Australian Air Force has also reported successful live firings of in-service ASRAAMs from its aircraft, affirming sustained performance post-qualification.[15]Combat Effectiveness Data
In ground-launched deployments via the Raven system in Ukraine since spring 2023, ASRAAM has demonstrated a reported hit rate of up to 90% against select Russian aerial targets, including drones and cruise missiles, according to UK Ministry of Defence assessments.[48][55][50] This performance metric reflects successful intercepts in operational conditions, though it pertains specifically to surface-to-air adaptations rather than the missile's primary air-to-air role and applies to "some" target types without detailed breakdown of engagement volumes or failure modes.[56] By October 2025, Raven-equipped units had accounted for the destruction of at least 24 Russian drones and four cruise missiles, including Kh-59 variants, underscoring effectiveness against low-observable, subsonic threats in contested airspace.[36] No verified air-launched combat engagements involving ASRAAM have been publicly documented, limiting broader empirical data to training exercises and simulations where the missile has shown high reliability in within-visual-range scenarios.[45] Overall kill ratios remain classified or unreleased, with available figures derived from allied disclosures rather than independent verification.Comparative Analysis with Rival Missiles
The ASRAAM distinguishes itself from rivals like the AIM-9X Sidewinder, IRIS-T, and Python-5 primarily through its emphasis on extended effective range and sustained velocity, enabled by a larger-diameter rocket motor (166 mm versus 127 mm for the AIM-9X and IRIS-T). This design permits high-speed, fire-and-forget engagements from standoff distances exceeding 25 km under optimal conditions, prioritizing first-shot opportunity over ultra-close-in dogfighting agility. In contrast, the AIM-9X and IRIS-T incorporate thrust-vectoring control for superior endgame maneuverability, achieving off-boresight acquisition angles up to 90 degrees, though their smaller motors limit maximum range to approximately 20-25 km. The Python-5, with its imaging infrared seeker and 160 mm diameter, offers comparable high-agility performance and full-sphere launch capability but carries a heavier warhead (11 kg) at the expense of slightly reduced speed relative to the ASRAAM's Mach 3+ profile.[5][57][58]| Missile | Length (m) | Diameter (mm) | Weight (kg) | Range (km) | Speed | Guidance |
|---|---|---|---|---|---|---|
| ASRAAM | 2.9 | 166 | 88 | >25 | Mach 3+ | Imaging IR homing |
| AIM-9X | 3.02 | 127 | 85 | ~20-25 | Mach 2.5+ | Imaging IR with thrust vectoring |
| IRIS-T | ~2.94 | 127 | ~87 | ~25 | Mach 3 | Imaging IR with thrust vectoring |
| Python-5 | 3.1 | 160 | 105 | ~20+ (BVR capable) | Mach 4 | Imaging IR, full-sphere |