AIM-54 Phoenix

External videos
External videos
	Rare declassified footage of the AIM-54 development program)

AIM-54 Phoenix
AIM-54 Phoenix
	AIM-54A on an F-14 at NAS Patuxent River, 1984
Type	Long range BVR air-to-air missile
Place of origin	United States
Service history
In service	1974–present
Used by	United States Navy (former); Iranian Air Force
Production history
Designer	Hughes Aircraft Company
Designed	1960–1966
Manufacturer	Hughes Aircraft Company; Raytheon Corporation;
Unit cost	US$477,131 (1974 FY)
Produced	1966
Specifications
Mass	AIM-54A/B - 976 lb (443 kg); AIM-54C – 1,015 lb (460 kg);
Length	12 ft 9+1⁄2 in (3.9 m)
Diameter	15 in (380 mm)
Wingspan	2 ft 11+1⁄2 in (0.9 m)
Warhead	AIM-54A/B - HE continuous rod; AIM-54C – HE Mk 82; WDU‐29/B continuous rod;
Warhead weight	133 lb (60.33 kg)
Detonation; mechanism	Proximity fuze
Engine	Solid propellant rocket motor
Operational; range	AIM-54A/B - 72.9 nmi (135.0 km; 83.9 mi); AIM-54C – 99.4 nmi (184.1 km; 114.4 mi);
Flight ceiling	103,500 ft (31.5 km)
Maximum speed	AIM-54A/B - Mach 4.3 (1,460 m/s; 4,800 ft/s); AIM-54C – Mach 5 (1,700 m/s; 5,600 ft/s);
Guidance; system	Semi-active radar homing and terminal phase active radar homing
Launch; platform	Grumman F-14 Tomcat
References	Janes

The AIM-54 Phoenix is an American active radar-guided, beyond-visual-range air-to-air missile (AAM), carried in clusters of up to six missiles on the Grumman F-14 Tomcat, its only operational launch platform.

The AIM-54 Phoenix was the United States' only operational long-range AAM during its service life; its operational capabilities were supplemented by the AIM-7 Sparrow (and later, the AIM-120 AMRAAM), which served as the primary medium-range AAM and the AIM-9 Sidewinder, serving as the primary short-range or "dogfight" AAM. The combination of Phoenix missile and the Tomcat's AN/AWG-9 guidance radar meant that it was the first aerial weapons system that could simultaneously engage multiple targets. Due to its active radar tracking, the brevity code "Fox Three" was used when firing the AIM-54. The act of the missile achieving a radar lock with its own radar is known under brevity as "Going Pitbull".

Both the missile and the aircraft were used by Iran and the United States Navy (USN). In US service both are now retired, the AIM-54 Phoenix in 2004 and the F-14 in 2006. They were replaced by the shorter-range AIM-120 AMRAAM, employed on the F/A-18 Hornet and F/A-18E/F Super Hornet; in its AIM-120D version, the latest version of the AMRAAM just matches the Phoenix's maximum range.^[2] In July 2024, the USN announced the operational fielding of the AIM-174, the "Air-Launched Configuration"^[3] of the RIM-174 Standard ERAM, the first dedicated long-range AAM to be fielded by the U.S. military since the AIM-54's retirement.^[4]

The AIM-54 has been used in 62 air-to-air strikes, all by Iran during the eight-year Iran–Iraq War.^[5]^[6] Following the retirement of the F-14 by the USN, the weapon's only current operator is the Islamic Republic of Iran Air Force.

Development

Background

Since 1951, the Navy faced the initial threat from the Tupolev Tu-4K 'Bull' carrying^[7] anti-ship missiles or nuclear bombs.

Eventually, during the height of the Cold War, the threat would have expanded into regimental-size raids of Tu-16 Badger and Tu-22M Backfire bombers equipped with low-flying, long-range, high-speed, nuclear-armed cruise missiles and considerable electronic countermeasures (ECM) of various types. This combination was considered capable of saturating fleet defenses and threatening carrier groups.

The Navy would require a long-range, long-endurance interceptor aircraft to defend carrier battle groups against this threat. The proposed Douglas F6D Missileer was intended to fulfill this mission and oppose the attack as far as possible from the fleet it was defending. The weapon needed for interceptor aircraft, the Bendix AAM-N-10 Eagle, was to be an air-to-air missile of unprecedented range when compared to contemporary AIM-7 Sparrow missiles. It would work together with Westinghouse AN/APQ-81 radar. The Missileer project was cancelled in December 1960.

AIM-54

In the early 1960s, the U.S. Navy made the next interceptor attempt with the F-111B, and they needed a new missile design. At the same time, the USAF canceled the projects for their land-based high-speed interceptor aircraft, the North American XF-108 Rapier and the Lockheed YF-12, and left the capable AIM-47 Falcon missile at a quite advanced stage of development, but with no effective launch platform.

Originally designated AAM-N-11,^[8] the AIM-54 Phoenix, developed for the F-111B fleet air defense fighter, had an airframe with four cruciform fins that was a scaled-up version of the AIM-47. One characteristic of the Missileer ancestry was that the radar sent it mid-course corrections, which allowed the fire control system to "loft" the missile up over the target into thinner air where it had better range.

The F-111B was canceled in 1968. Its weapons system, the AIM-54 working with the AWG-9 radar, migrated to the new U.S. Navy fighter project, the VFX, which would later become the F-14 Tomcat.^[9]

The AIM-54 Phoenix was also considered by the Royal Air Force to be used on Avro Vulcan bomber planes as part of an air defence aircraft. This missileer conversion would have used 12 missiles onboard and an extensive modification to the Vulcan's radar.^[10]

In 1977, development of a significantly improved Phoenix version, the AIM-54C, was developed to better counter projected threats from tactical anti-naval aircraft and cruise missiles, and its final upgrade included a re-programmable memory capability to keep pace with emerging ECM.^[11]

Usage in comparison to other weapon systems

The AIM-54/AWG-9 combination had multiple track (up to 24 targets) and multiple launch (up to six Phoenixes can be launched nearly simultaneously) capability, regardless of weather conditions or heavy enemy electronic warfare, known as jamming. The large 1,000 lb (500 kg) missile is equipped with a conventional warhead.

The AIM-54 is designed for ejection launch, where a pyrotechnic charge forcefully jettisons it from either a LAU-93 or a LAU-132 launcher before its solid propellant rocket motor ignites.^[12]

On the F-14, four missiles can be carried under the fuselage tunnel attached to special aerodynamic pallets, plus two under glove stations. A full load of six Phoenix missiles and the unique launch rails weighs in at over 8,000 lb (3,600 kg), about twice the weight of Sparrows, putting it above the allowable bringback load (which also would include enough fuel for go-around attempts).^[13] As such, carrying six Phoenix missiles would necessitate the jettison of at least some of the Phoenix missiles if they were not used. The most common air superiority payload was a mix of two Phoenix, three Sparrow, and two Sidewinder missiles.^{[citation needed]}

Most other US aircraft relied on the smaller, semi-active medium-range AIM-7 Sparrow. Semi-active guidance meant the aircraft no longer had a search capability while supporting the launched Sparrow, reducing situational awareness.

The Tomcat's radar could track up to 24 targets in track-while-scan mode, with the AWG-9 selecting up to six potential targets for the missiles. The pilot or radar intercept officer (RIO) could then launch the Phoenix missiles once parameters were met. The large tactical information display (TID) in the RIO's cockpit gave information to the aircrew (the pilot had the ability to monitor the RIO's display) and the radar could continually search and track multiple targets after Phoenix missiles were launched, thereby maintaining situational awareness of the battlespace.

The Link 4 datalink allowed US Navy Tomcats to share information with the E-2C Hawkeye AEW aircraft. During Desert Shield in 1990, the Link 4A was introduced; this allowed the Tomcats to have a fighter-to-fighter datalink capability, further enhancing overall situational awareness. The F-14D entered service with JTIDS that brought the even better Link 16 datalink "picture" to the cockpit.

Active guidance

The Phoenix has several guidance modes and achieves its longest range by using mid-course updates from the F-14A/B AWG-9 radar (APG-71 radar in the F-14D) as it climbs to cruise between 80,000 ft (24,000 m) and 100,000 ft (30,000 m) at close to Mach 5. The Phoenix uses this high altitude to maximize its range by reducing atmospheric drag. At around 11 miles (18 km) from the target, the missile activates its own radar to provide terminal guidance.^[14] Minimum engagement range for the Phoenix is around 2 nmi (3.7 km); at this range active homing would initiate upon launch.^[14] If the AWG-9 radar lost radar lock on a target before the missile had activated its own radar, the missile proceeded on a ballistic trajectory with no further guidance, known as 'going dumb'.

Service history

U.S. combat experience

On January 5, 1999, a pair of US F-14s fired two Phoenixes at Iraqi MiG-25s southeast of Baghdad. Both AIM-54s' rocket motors failed and neither missile hit its target.^[15]^[16]
On September 9, 1999, another US F-14 launched an AIM-54 at an Iraqi MiG-23 that was heading south into the no-fly zone from Al Taqaddum air base west of Baghdad. The missile missed, eventually going into the ground after the Iraqi fighter reversed course and fled north.^[17]

The AIM-54 Phoenix was retired from USN service on September 30, 2004. F-14 Tomcats were retired on September 22, 2006. They were replaced by shorter-range AIM-120 AMRAAMs, employed on the F/A-18E/F Super Hornet.

Despite the much-vaunted capabilities, the Phoenix was rarely used in combat, with only two confirmed launches and no confirmed targets destroyed in US Navy service. The USAF F-15 Eagle had responsibility for overland combat air patrol duties in Operation Desert Storm in 1991, primarily because of the onboard F-15 IFF capabilities. The Tomcat did not have the requisite IFF capability mandated by the Joint Force Air Component Commander (JFACC) to satisfy the rules of engagement to utilize the Phoenix capability at beyond visual range. The AIM-54 was not adopted by any foreign nation besides Iran, or any other US armed service, and was not used on any aircraft other than the F-14.^{[citation needed]}

Iranian combat experience

On January 7, 1974, as part of Project Persian King, the Imperial Iranian Air Force placed an order for 424 AIM-54As, later increasing it by 290 missiles that June.^[6] Of the initial order, 274 missiles and 10 training rounds were delivered for US$150 million,^[18] until the 1979 Revolution ended deliveries and left the remaining 150 missiles embargoed and the additional order of 290 cancelled.

According to Tom Cooper and Farzad Bishop, during the Iran–Iraq War AIM-54s fired by IRIAF Tomcats achieved 78 victories against Iraqi MiG-21s, MiG-23s, MiG-25s, Tu-22s, Su-20/22s, Mirage F 1s, Super Étendards, and even two AM-39 Exocets and a C-601. This includes two occasions where one AIM-54 was responsible for the downing of two Iraqi aircraft, as well as an incident on January 7, 1981, where a Phoenix fired at a four-ship of MiG-23s downed three and damaged the fourth.^[6]

The US refused to supply spare parts and maintenance after the 1979 Revolution, except for a brief period during the Iran–Contra affair. According to Cooper, the Islamic Republic of Iran Air Force kept its F-14 fighters and AIM-54 missiles in regular use during the entire Iran–Iraq War, though periodic lack of spares grounded large parts of the fleet at times. During late 1987, the stock of AIM-54 missiles was at its lowest, with fewer than 50 operational missiles available. The missiles needed fresh thermal batteries that could only be purchased from the US. Iran found a clandestine buyer that supplied it with batteries, which cost up to US$10,000 each. Iran received spares and parts for both the F-14s and AIM-54s from various sources during the Iran–Iraq War, and has received more spares after the conflict. Iran started a program to build spares for the planes and missiles, and although there are claims that it no longer relies on outside sources to keep its F-14s and AIM-54s operational, there is evidence that Iran continues to procure parts clandestinely.^[19]

Both the F-14 Tomcat and the AIM-54 Phoenix missile continue in the service of the Islamic Republic of Iran Air Force. In 2013, Iran unveiled the Fakour-90, an upgraded and reverse-engineered version of the Phoenix.^[20]

Variants

AIM-54A: Original model that became operational with the U.S. Navy in about 1974, and it was also exported to Iran before the Iran hostage crisis beginning in 1979.
AIM-54B: Also known as the 'Dry' missile. A version with simplified construction and no coolant conditioning. Did not enter series production. Developmental work started in January 1972. 7 X-AIM-54B missiles were created for testing, 6 of them by modifying pilot production IVE/PIP rounds. After two successful test firings, the 'Dry' missile effort was cancelled for being "not cost effective".^[21]
AIM-54C: The only improved model that was ever produced. It used digital electronics in the place of the analog electronics of the AIM-54A. This model had better abilities to shoot down low and high-altitude anti-ship missiles. It was designed for greater service life, reliability, and utilized less parts. It also included a built in self-test (BIST/BIT) and missile on-aircraft test capability.^[12] This model took over from the AIM-54A beginning in 1986.
AIM-54 ECCM/Sealed: More capabilities in electronic counter-countermeasures. It did not require coolant during flight. The missile was deployed from 1988 onwards. Because the AIM-54 ECCM/Sealed received no coolant, F-14s carrying this version of the missile could not exceed a specified airspeed. There were also test, evaluation, ground training, and captive air training versions of the missile; designated ATM-54, AEM-54, DATM-54A, and CATM-54, respectively. The flight versions had A and C versions. The DATM-54 was not made in a C version as there was no change in the ground handling characteristics. A small number of AIM-54As were also converted to NAIM-54As, carrying scientific recording equipment; their use is unknown.^[22]

Sea Phoenix: A 1970s proposal for a ship-launched version of the Phoenix as an alternative/replacement for the Sea Sparrow point defense system. It would also have provided a medium-range SAM capability for smaller and/or non-Aegis equipped vessels (such as the CVV, an abortive proposal for a "medium"-size, conventionally-powered aircraft carrier). The Sea Phoenix system would have included a modified shipborne version of the AN/AWG-9 radar. Hughes Aircraft touted the fact that 27 out of 29 major elements of the standard (airborne) AN/AWG-9 could be used in the shipborne version with little modification. Each system would have consisted of one AWG-9 radar, with associated controls and displays, and a fixed 12-cell launcher for the Phoenix missiles. In the case of an aircraft carrier, for example, at least three systems would have been fitted in order to give overlapping coverage throughout the full 360°.^[23]^[24] The AWG‑9’s track‑while‑scan capability could monitor up to 24 targets simultaneously; however, on the Tomcat, engagements were limited to 6 targets per launching aircraft, as this was the maximum number of Phoenixes a single Tomcat could carry. With the potential for greater "magazine depth" abord ships, the Sea Phoenix would be possibly capable of engaging up to 24 targets simultaneously per AN/AWG-9 system.^[25] Trials included a China Lake surface‑launch in which a standard AIM-54A traveled about 13.5 miles in 90 seconds to evaluate launcher separation and safety, and the 14th production AWG‑9 was installed aboard USNS Wheeling in 1974 where it successfully detected and tracked multiple high‑ and low‑altitude targets from the ship’s deck; unconfirmed reports also describe a "containerised" AWG‑9 trial at Point Mugu as a possible land‑based mobile testbed. Land-based testing may have been in-preperation of a United States Marine Corps weapon system utilizing the AIM-54 as a surface-to-air missile. Development of the land- and sea-based versions did not proceed largely because of high cost and the reduced range and performance penalty of surface launch relative to airborne launch. The AN/AWG‑9’s limited ability to track low‑altitude targets when ship‑mounted was also noted in tests. Redundancy was also noted, with contemporary fleet defense being provided predominantly by F-14s, themselves already equipped with the AWG‑9/AIM‑54 suite. Concerns also arose regarding the AIM-54's inability to function as a close-in system, its missiles lacking maneuverability against targets in the short range, particularly when compared to the smaller Sea Sparrow. With the emergence of the Aegis Combat System and upgraded Sea Sparrow variants becoming operational, any further development of the Sea Phoenix was halted.^[26]^[27] In 1977, Wayne E. Meyer, a U.S. Navy rear admiral, testified before Congress regarding these shortcomings and advised that testing found the Sea Phoenix to be "not favorable" and that it offered "no advantages" over Aegis and Sea Sparrow systems.^[28]

Fakour 90: In February 2013 Iran reportedly tested an indigenous long-range air-to-air missile.^{[citation needed]} In September 2013 it displayed the Fakour-90 on a military parade. It looked almost identical to the AIM-54 Phoenix.^[29] In July 2018 as reported by Jane's, Iran started mass production of the Fakour-90.^[30]

Operators

Current operators

Iran – Islamic Republic of Iran Air Force

Former operators

Imperial State of Iran - Imperial Iranian Air Force
United States – United States Navy: Retired in 2004

Characteristics

The following is a list of AIM-54 Phoenix specifications:^[31]

Primary function: long-range, air-launched, air-intercept missile
Contractor: Hughes Aircraft Company and Raytheon Corporation
Unit cost: about $477,000, but this varied greatly
Power plant: solid propellant rocket motor built by Hercules Incorporated
Length: 13 ft (4.0 m)
Weight: 1,000–1,040 pounds (450–470 kg)
Diameter: 15 in (380 mm)
Wing span: 3 ft (910 mm)
Range: over 100 nautical miles (120 mi; 190 km) (actual range is classified)
Speed: 3,000+ mph (4,680+ km/h)
Guidance system: semi-active and active radar homing
Warheads: proximity fuze, high explosive
Warhead weight: 135 pounds (61 kg)
Users: US (U.S. Navy), Iran (IRIAF)
Date deployed: 1974
Date retired (U.S.): September 30, 2004

References

^ Janes (26 February 2021), "AIM-54 Phoenix", Janes Weapons: Air Launched, Coulsdon, Surrey: Jane's Group UK Limited., retrieved 2 October 2022
^ "New long-range missile project emerges in US budget". November 2, 2017.
^ Johnston, Carter (2024-07-05). "U.S. Navy Confirms SM-6 Air Launched Configuration is Operationally Deployed". Naval News. Retrieved 2024-07-07. The SM-6 Air Launched Configuration (ALC) was developed as part of the SM-6 family of missiles and is operationally deployed in the Navy today.
^ Cenciotti, David (2024-07-03). "First Images Emerge Of U.S. Navy Super Hornet Carrying Two Air-Launched SM-6 Missiles". The Aviationist. Retrieved 2024-07-07. In essence, this new missile fills the gap left by the retirement of the AIM-54 Phoenix. The AIM-54 was a long-range air-to-air missile used by the U.S. Navy's F-14 Tomcat and retired in 2004 alongside the F-14. Known for its impressive range of over 100 nautical miles and multiple-target engagement capability, the AIM-54 left a significant void in long-range engagement capabilities.
^ John Stillion. "Trends in Air-to-Air Combat: Implications for Future Air Superiority" (PDF). Center for Strategic and Budgetary Assessments (CSBA). p. 22. Archived (PDF) from the original on 2022-10-09.
^ ^a ^b ^c Cooper, Tom; Bishop, Farzad. Iranian F-14 Tomcat Units in Combat, p. 85. Oxford: Osprey Publishing, 2004. ISBN 1 84176 787 5.
^ Zaloga, S.J.; Laurier, J. (2005). V-1 Flying Bomb, 1942–52: Hitler's Infamous "Doodlebug". Osprey Publishing, Limited. ISBN 9781841767918. Retrieved 3 October 2014.
^ Pfeiffer, Marie (September 1963). "Naval Weapons". Naval Aviation News. Washington, D.C.: Navy Department: 27.
^ Wragg, David W. (1973). A Dictionary of Aviation (first ed.). Osprey. p. 212. ISBN 9780850451634.
^ "The National Interest: Blog". 19 September 2021.
^ "Raytheon AIM-54 Phoenix". designation-systems.net. Retrieved 3 October 2014.
^ ^a ^b "Raytheon AIM-54C Phoenix | Estrella Warbird Museum". www.ewarbirds.org. Retrieved 2023-12-19.
^ Clancy, Tom (1999-02-01). Carrier. Penguin. ISBN 9781101002254.
^ ^a ^b "AIM-54" (2004). Directory of US Military Rockets and Missiles. Retrieved 28 November 2010.
^ "Defense.gov Transcript: DoD News Briefing January 5, 1999". Archived from the original on December 8, 2015. Retrieved November 30, 2015.
^ Parsons, Dave, George Hall and Bob Lawson. (2006). Grumman F-14 Tomcat: Bye-Bye Baby...!: Images & Reminiscences From 35 Years of Active Service. Zenith Press, p. 73. ISBN 0-7603-3981-3.
^ Tony Holmes, "US Navy F-14 Tomcat Units of Operation Iraqi Freedom", Osprey Publishing (2005). Chapter One – OSW, pp. 16–7.
^ "AIM-54 Phoenix Missile". U.S. Navy. Archived from the original on May 27, 2005.
^ Theimer, Sharon. "Iran Gets Army Gear in Pentagon Sale". Forbes. Archived from the original on 19 January 2007. Retrieved 17 January 2007.
^ Cenciotti, David (26 September 2013). "Iranian F-14 Tomcat's 'new' indigenous air-to-air missile is actually an (improved?) AIM-54 Phoenix replica". The Aviationist. Retrieved 8 November 2015.
^ "Budget estimates descriptive summaries", Supporting data for fiscal year 1983, Department of the Navy.
^ "Raytheon AIM-54C Phoenix". Estrella Warbirds Museum. Paso Robles, California, United States of America: Estrella Warbirds Museum, Inc. Archived from the original on 8 September 2025. The three versions of the AIM-54 Phoenix Missile are the[…] AIM-54 ECCM/Sealed […] The AIM-54C (sealed) missile[…] contains improved electronic counter-countermeasure capabilities and does not require coolant conditioning during captive flight. The[…] AIM-54C (sealed) contains built-in self test and additional missile on-aircraft test capability. […] Initial Operating Capability was attained in[…] 1988 for the AIM-54C ECCM/Sealed […] The AIM-54C ECCM/Sealed Missile provides two major improvements over the AIM-54C. ECCM provides enhanced electronic protection and sealing the missile eliminates the requirement for aircraft supplied liquid thermal conditioning fluid during captive flight.
^ Weapon Systems, Jane's, 1977.
^ Newdick, Thomas (2021-08-11). "Surface-launched version of the Tomcat's AIM-54 Phoenix missile nearly armed Cold War carriers". The War Zone. New York City, New York, United States of America: Recurrent Ventures. Archived from the original on 17 September 2025. The plan was to install three launchers on each carrier so equipped, to provide full 360-degree coverage for each ship.
^ Newdick, Thomas (2021-08-11). "Surface-launched version of the Tomcat's AIM-54 Phoenix missile nearly armed Cold War carriers". The War Zone. New York City, New York, United States of America: Recurrent Ventures. Archived from the original on 17 September 2025. […]the AWG-9 was capable of tracking up to 24 targets simultaneously in track-while-scan mode and then engaging six of these with Phoenix missiles. That number was limited by the six AIM-54s that each F-14 could carry (reduced to four missiles for routine carrier-based operations), but potentially more targets could have been engaged using the Sea Phoenix system with its greater 'magazine depth.'
^ Newdick, Thomas (2021-08-11). "Surface-launched version of the Tomcat's AIM-54 Phoenix missile nearly armed Cold War carriers". The War Zone. New York City, New York, United States of America: Recurrent Ventures. Archived from the original on 17 September 2025. Tests of the surface-launched Phoenix missile included a firing from [...] China Lake [...] during which a standard version of the missile traveled a distance of 13.5 miles in 90 seconds. [...] Meanwhile, the 14th production example of the AWG-9 radar was installed aboard the missile-tracking ship USNS Wheeling, in 1974, where it 'successfully detected and tracked multiple targets at both high and low [...] Unconfirmed reports suggest the AWG-9 radar was also tested on land, in a container van setup, at Point Mugu, California. This was likely in relation to a possible land-based mobile version of the Phoenix, reportedly intended for the U.S. Marine Corps. [...] While the Sea Phoenix would also have offered much more in the way of anti-aircraft and anti-missile defense capabilities than the Sea Sparrow, it seems that its development was abandoned due to the high costs involved. [...W]hile the Sea Sparrow provided an intermediate to close-range point-defense capability [...] the Sea Phoenix[...] was by no means a dogfight missile and would have been of limited value against close-in, maneuvering threats. The AWG-9 radars, mounted low on the carrier's sides, would be severely limited at detecting low-flying threats over the horizon. It could also be argued that, with escort warships and F-14s already providing a robust outer defensive layer, there was not a pressing need[...]
^ Tarpgaard, PT (1976), "The Sea Phoenix—A Warship Design Study", ASNE, 88 (2): 31–44, Bibcode:1976NEngJ..88...31T, doi:10.1111/j.1559-3584.1976.tb03809.x.
^ United States Senate Committee on Armed Services (1977). Fiscal Year 1978 Authorization for Military Procurement, Research, and Development, and Active Duty, Selected Reserve, and Civilian Personnel Strengths: Hearings Before the Committee on Armed Services, United States Senate, Ninety-fifth Congress, First Session, on S. 1210 (Part 7). United States Government Printing Office. pp. 4902–4903. Archived from the original on 21 October 2025. Senator HART. Have you compared the cost and capability of Aegis with the cost and capability of a combination of Sea Phoenix, incorporating the improvements in ECM capability proposed by manufacturers, with the British Sea Wolf antimisile system?; Admiral MEYER. Yes. The Sea Phoenix conceptual system has been examined in depth in past years in order to determine whether the excellent airborne AWG 9 radar could profitably be used for shipboard defense, along with the Phoenix missile. The conclusion was not favorable. The primary limitations were in the radar, where in adapting from aircraft to ship usage the design was not suitable. Two of the most serious difficulties were: (a) a restricted field of view, suitable for the ahead-looking radar on a combat aircraft being vectored to its target by external help but not for the essentially hemispheric coverage needed on the ship, and (b) a less flexible environmental acceptance in respect to jamming and low-over-the-water surveillance, again suitable for the aircraft but not the ship. An attempt to adapt the airborne equipment to the ship needs, by multiple radar installations, additional signal processing, and integration of several sensors tended to drive the complexity, power, size up to the levels of a system designed initially for ships, without the advantages of dedicated design for the purpose. The resulting Sea Phoenix concept ended up not only with engineering and performance penalties, but in practice would provide less true "area" defense than shipboard systems designed for the purpose; that is, Sea Phoenix was more suitable for defending its own ship than others in company. The serious proposals were confined to this role, as on aircraft carriers. Aegis has a different purpose. It is noted that the Institute for Defense Analysis, in independent (non-Navy) study of Aegis for DDR&E examined Sea Phoenix as a possible alternate, and concluded that no advantage was offered, taking account of performance, cost, and readines for use. The British Sea Wolf is a very short range "point defense" system which might in principle be a supplementary inner defense in Aegis ships or any other area defense ship. It has not been examined explicitly with Sea Phoenix or Aegis.
^ "Farouk missile", The Avionist, Sep 26, 2013.
^ "Janes | Latest defence and security news".
^ "Fact File: AIM-54 Phoenix Missile". U.S. Navy. Archived from the original on 29 June 2011. Retrieved 14 July 2011.

External links

NASA Dryden Flight Research Center – Phoenix Missile Hypersonic Testbed Archived 2012-01-30 at the Wayback Machine

[1] Janes (26 February 2021), "AIM-54 Phoenix", Janes Weapons: Air Launched, Coulsdon, Surrey: Jane's Group UK Limited., retrieved 2 October 2022

[2] "New long-range missile project emerges in US budget". November 2, 2017.

[3] Johnston, Carter (2024-07-05). "U.S. Navy Confirms SM-6 Air Launched Configuration is Operationally Deployed". Naval News. Retrieved 2024-07-07. The SM-6 Air Launched Configuration (ALC) was developed as part of the SM-6 family of missiles and is operationally deployed in the Navy today.

[4] Cenciotti, David (2024-07-03). "First Images Emerge Of U.S. Navy Super Hornet Carrying Two Air-Launched SM-6 Missiles". The Aviationist. Retrieved 2024-07-07. In essence, this new missile fills the gap left by the retirement of the AIM-54 Phoenix. The AIM-54 was a long-range air-to-air missile used by the U.S. Navy's F-14 Tomcat and retired in 2004 alongside the F-14. Known for its impressive range of over 100 nautical miles and multiple-target engagement capability, the AIM-54 left a significant void in long-range engagement capabilities.

[5] John Stillion. "Trends in Air-to-Air Combat: Implications for Future Air Superiority" (PDF). Center for Strategic and Budgetary Assessments (CSBA). p. 22. Archived (PDF) from the original on 2022-10-09.

[Cooper2004-6] Cooper, Tom; Bishop, Farzad. Iranian F-14 Tomcat Units in Combat, p. 85. Oxford: Osprey Publishing, 2004. ISBN 1 84176 787 5.

[google-7] Zaloga, S.J.; Laurier, J. (2005). V-1 Flying Bomb, 1942–52: Hitler's Infamous "Doodlebug". Osprey Publishing, Limited. ISBN 9781841767918. Retrieved 3 October 2014.

[8] Pfeiffer, Marie (September 1963). "Naval Weapons". Naval Aviation News. Washington, D.C.: Navy Department: 27.

[9] Wragg, David W. (1973). A Dictionary of Aviation (first ed.). Osprey. p. 212. ISBN 9780850451634.

[10] "The National Interest: Blog". 19 September 2021.

[designation-systems-11] "Raytheon AIM-54 Phoenix". designation-systems.net. Retrieved 3 October 2014.

[:0-12] "Raytheon AIM-54C Phoenix | Estrella Warbird Museum". www.ewarbirds.org. Retrieved 2023-12-19.

[13] Clancy, Tom (1999-02-01). Carrier. Penguin. ISBN 9781101002254.

[Directory-14] "AIM-54" (2004). Directory of US Military Rockets and Missiles. Retrieved 28 November 2010.

[15] "Defense.gov Transcript: DoD News Briefing January 5, 1999". Archived from the original on December 8, 2015. Retrieved November 30, 2015.

[16] Parsons, Dave, George Hall and Bob Lawson. (2006). Grumman F-14 Tomcat: Bye-Bye Baby...!: Images & Reminiscences From 35 Years of Active Service. Zenith Press, p. 73. ISBN 0-7603-3981-3.

[17] Tony Holmes, "US Navy F-14 Tomcat Units of Operation Iraqi Freedom", Osprey Publishing (2005). Chapter One – OSW, pp. 16–7.

[18] "AIM-54 Phoenix Missile". U.S. Navy. Archived from the original on May 27, 2005.

[19] Theimer, Sharon. "Iran Gets Army Gear in Pentagon Sale". Forbes. Archived from the original on 19 January 2007. Retrieved 17 January 2007.

[20] Cenciotti, David (26 September 2013). "Iranian F-14 Tomcat's 'new' indigenous air-to-air missile is actually an (improved?) AIM-54 Phoenix replica". The Aviationist. Retrieved 8 November 2015.

[DeptNav_FY83-21] "Budget estimates descriptive summaries", Supporting data for fiscal year 1983, Department of the Navy.

[22] "Raytheon AIM-54C Phoenix". Estrella Warbirds Museum. Paso Robles, California, United States of America: Estrella Warbirds Museum, Inc. Archived from the original on 8 September 2025. The three versions of the AIM-54 Phoenix Missile are the[…] AIM-54 ECCM/Sealed […] The AIM-54C (sealed) missile[…] contains improved electronic counter-countermeasure capabilities and does not require coolant conditioning during captive flight. The[…] AIM-54C (sealed) contains built-in self test and additional missile on-aircraft test capability. […] Initial Operating Capability was attained in[…] 1988 for the AIM-54C ECCM/Sealed […] The AIM-54C ECCM/Sealed Missile provides two major improvements over the AIM-54C. ECCM provides enhanced electronic protection and sealing the missile eliminates the requirement for aircraft supplied liquid thermal conditioning fluid during captive flight.

[JanesWS76-23] Weapon Systems, Jane's, 1977.

[24] Newdick, Thomas (2021-08-11). "Surface-launched version of the Tomcat's AIM-54 Phoenix missile nearly armed Cold War carriers". The War Zone. New York City, New York, United States of America: Recurrent Ventures. Archived from the original on 17 September 2025. The plan was to install three launchers on each carrier so equipped, to provide full 360-degree coverage for each ship.

[25] Newdick, Thomas (2021-08-11). "Surface-launched version of the Tomcat's AIM-54 Phoenix missile nearly armed Cold War carriers". The War Zone. New York City, New York, United States of America: Recurrent Ventures. Archived from the original on 17 September 2025. […]the AWG-9 was capable of tracking up to 24 targets simultaneously in track-while-scan mode and then engaging six of these with Phoenix missiles. That number was limited by the six AIM-54s that each F-14 could carry (reduced to four missiles for routine carrier-based operations), but potentially more targets could have been engaged using the Sea Phoenix system with its greater 'magazine depth.'

[26] Newdick, Thomas (2021-08-11). "Surface-launched version of the Tomcat's AIM-54 Phoenix missile nearly armed Cold War carriers". The War Zone. New York City, New York, United States of America: Recurrent Ventures. Archived from the original on 17 September 2025. Tests of the surface-launched Phoenix missile included a firing from [...] China Lake [...] during which a standard version of the missile traveled a distance of 13.5 miles in 90 seconds. [...] Meanwhile, the 14th production example of the AWG-9 radar was installed aboard the missile-tracking ship USNS Wheeling, in 1974, where it 'successfully detected and tracked multiple targets at both high and low [...] Unconfirmed reports suggest the AWG-9 radar was also tested on land, in a container van setup, at Point Mugu, California. This was likely in relation to a possible land-based mobile version of the Phoenix, reportedly intended for the U.S. Marine Corps. [...] While the Sea Phoenix would also have offered much more in the way of anti-aircraft and anti-missile defense capabilities than the Sea Sparrow, it seems that its development was abandoned due to the high costs involved. [...W]hile the Sea Sparrow provided an intermediate to close-range point-defense capability [...] the Sea Phoenix[...] was by no means a dogfight missile and would have been of limited value against close-in, maneuvering threats. The AWG-9 radars, mounted low on the carrier's sides, would be severely limited at detecting low-flying threats over the horizon. It could also be argued that, with escort warships and F-14s already providing a robust outer defensive layer, there was not a pressing need[...]

[Tarpgaard-27] Tarpgaard, PT (1976), "The Sea Phoenix—A Warship Design Study", ASNE, 88 (2): 31–44, Bibcode:1976NEngJ..88...31T, doi:10.1111/j.1559-3584.1976.tb03809.x.

[28] United States Senate Committee on Armed Services (1977). Fiscal Year 1978 Authorization for Military Procurement, Research, and Development, and Active Duty, Selected Reserve, and Civilian Personnel Strengths: Hearings Before the Committee on Armed Services, United States Senate, Ninety-fifth Congress, First Session, on S. 1210 (Part 7). United States Government Printing Office. pp. 4902–4903. Archived from the original on 21 October 2025. Senator HART. Have you compared the cost and capability of Aegis with the cost and capability of a combination of Sea Phoenix, incorporating the improvements in ECM capability proposed by manufacturers, with the British Sea Wolf antimisile system?; Admiral MEYER. Yes. The Sea Phoenix conceptual system has been examined in depth in past years in order to determine whether the excellent airborne AWG 9 radar could profitably be used for shipboard defense, along with the Phoenix missile. The conclusion was not favorable. The primary limitations were in the radar, where in adapting from aircraft to ship usage the design was not suitable. Two of the most serious difficulties were: (a) a restricted field of view, suitable for the ahead-looking radar on a combat aircraft being vectored to its target by external help but not for the essentially hemispheric coverage needed on the ship, and (b) a less flexible environmental acceptance in respect to jamming and low-over-the-water surveillance, again suitable for the aircraft but not the ship. An attempt to adapt the airborne equipment to the ship needs, by multiple radar installations, additional signal processing, and integration of several sensors tended to drive the complexity, power, size up to the levels of a system designed initially for ships, without the advantages of dedicated design for the purpose. The resulting Sea Phoenix concept ended up not only with engineering and performance penalties, but in practice would provide less true "area" defense than shipboard systems designed for the purpose; that is, Sea Phoenix was more suitable for defending its own ship than others in company. The serious proposals were confined to this role, as on aircraft carriers. Aegis has a different purpose. It is noted that the Institute for Defense Analysis, in independent (non-Navy) study of Aegis for DDR&E examined Sea Phoenix as a possible alternate, and concluded that no advantage was offered, taking account of performance, cost, and readines for use. The British Sea Wolf is a very short range "point defense" system which might in principle be a supplementary inner defense in Aegis ships or any other area defense ship. It has not been examined explicitly with Sea Phoenix or Aegis.

[29] "Farouk missile", The Avionist, Sep 26, 2013.

[30] "Janes | Latest defence and security news".

[31] "Fact File: AIM-54 Phoenix Missile". U.S. Navy. Archived from the original on 29 June 2011. Retrieved 14 July 2011.

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v t e Raytheon
Subsidiaries	A.C. Cossor ELCAN Optical Technologies Raytheon BBN Raytheon Missiles & Defense Raytheon Intelligence, Information and Services HRB Systems Raytheon Polar Services Company Sarcos ThalesRaytheonSystems
Products	AGM-65 Maverick AGM-88 HARM AGM-129 ACM AGM-154 Joint Standoff Weapon AGM-176 Griffin AIM-9 Sidewinder AIM-54 Phoenix AIM-120 AMRAAM AN/ALE-50 towed decoy system AN/ALR-67 radar warning receiver AN/ALE-47 AN/APG-63 radar family AN/APG-65 radar family AN/APG-79 AN/APQ-181 AN/AQS-20A AN/ASQ-213 AN/ASQ-228 ATFLIR AN/AWG-9 AN/MPQ-64 Sentinel AN/MSQ-18 Battalion Missile Operations System AN/PAS-13 AN/SLQ-32 electronic warfare suite AN/SPS-49 AN/SQQ-32 mine-hunting sonar AN/TPQ-36 Firefinder radar AN/TPQ-37 Firefinder radar AN/TPQ-53 Quick Reaction Capability Radar ASARS-2 Beechcraft AQM-37 Jayhawk Tomahawk Controlled Impact Rescue Tool Counter rocket, artillery, and mortar Coyote FGM-148 Javelin FIM-92 Stinger FMRAAM GBU-53/B StormBreaker Ground-Based Midcourse Defense JLENS Lectron Long-Range Engagement Weapon Mark 48 torpedo Mark 54 lightweight torpedo MIM-23 Hawk MIM-104 Patriot Network Centric Airborne Defense Element Next Generation Jammer Paveway Paveway IV Phalanx CIWS Pyros RAYDAC RIM-116 Rolling Airframe Missile RIM-66 Standard RIM-67 Standard RIM-161 Standard Missile 3 Sea-based X-band radar Sentinel SLAMRAAM Space Fence Vigilant Eagle XM501 non-line-of-sight launch system
Related	RTX Corporation Raytheon 9 Vannevar Bush

v t e 1963 United States Tri-Service missile designations, 1963–present
1–50	MGM-1 RIM-2 MIM-3 AIM-4 MGM-5 RGM-6 AIM-7 RIM-7 RIM-8 AIM-9 CIM-10 PGM-11 AGM-12 CGM-13/MGM-13 MIM-14 RGM-15 CGM-16 PGM-17 MGM-18 PGM-19 ADM-20 MGM-21 AGM-22 MIM-23 RIM-24 HGM-25A LGM-25C AIM-26 UGM-27 AGM-28 MGM-29 LGM-30 MGM-31A/B (MGM-31C) MGM-32 MQM-33 AQM-34 AQM-35 (I) LGM-35 (II) MQM-36 AQM-37 AQM-38 MQM-39 MQM-40 AQM-41 MQM-42 FIM-43 UUM-44 AGM-45 MIM-46 AIM-47 AGM-48 XLIM-49 LIM-49 RIM-50
51–100	MGM-51 MGM-52 AGM-53 AIM-54 RIM-55 PQM-56 MQM-57 MQM-58 RGM-59 AQM-60 MQM-61 AGM-62 AGM-63 AGM-64 AGM-65 RIM-66 RIM-67 AIM-68 AGM-69 LEM-70 BGM-71 MIM-72 UGM-73 BQM-74 BGM-75 AGM-76 FGM-77 AGM-78 AGM-79 AGM-80 AQM-81 AIM-82 AGM-83 AGM-84/RGM-84/UGM-84 AGM-84E AGM-84H/K RIM-85 AGM-86 AGM-87 AGM-88 UGM-89 BQM-90 AQM-91 FIM-92 "AIM-92" XQM-93 YQM-94 AIM-95 UGM-96 AIM-97 YQM-98 LIM-99 LIM-100
101–150	RIM-101 PQM-102 AQM-103 MIM-104 MQM-105 BQM-106 MQM-107 BQM-108 AGM-109/BGM-109/RGM-109/UGM-109 BGM-109G BGM-110 BQM-111 AGM-112 RIM-113 AGM-114 MIM-115 RIM-116 FQM-117 LGM-118 AGM-119 AIM-120 CQM-121/CGM-121 AGM-122 AGM-123 AGM-124 RUM-125/UUM-125 BQM-126 AQM-127 AQM-128 AGM-129 AGM-130 AGM-131 AIM-132 UGM-133 MGM-134 ASM-135 AGM-136 AGM-137 CEM-138 RUM-139 MGM-140 ADM-141 AGM-142 MQM-143 ADM-144 BQM-145 MIM-146 BQM-147 FGM-148 PQM-149 PQM-150
151–200	FQM-151 AIM-152 AGM-153 AGM-154 BQM-155 RIM-156 MGM-157 AGM-158A/B AGM-158C AGM-159 ADM-160 RIM-161 RIM-162 GQM-163 MGM-164 RGM-165 MGM-166 BQM-167 MGM-168 AGM-169 MQM-170 MQM-171 FGM-172 (I) MQM-172 (II) GQM-173 RIM-174 AIM-174B MQM-175 AGM-176 BQM-177 MQM-178 AGM-179 AGM-180 AGM-181 LGM-182 AGM-183 RGM-184 MQM-185 MQM-186 AGM-187
201–	AIM-260 MIM-401
Undesignated	Aequare ASALM Brazo Common Missile CKEM GBI GLSDB HACM HALO Have Dash JSM KEI Longbow LREW LRHW M30 GMLRS/M31 GMLRS-U MA-31 MSDM NCADE NLOS OpFires PrSM SACM Senior Prom Sprint SiAW Wagtail
See also: United States tri-service rocket designations post-1963 Drones designated in UAV sequence