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Grumman F-14 Tomcat

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Title: Grumman F-14 Tomcat  
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Subject: General Dynamics–Grumman F-111B, Grumman F-11 Tiger, Boeing F/A-18E/F Super Hornet, Grumman G-118, Northrop Grumman RQ-180
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Grumman F-14 Tomcat

F-14 Tomcat
A U.S. Navy F-14D conducts a mission over the Persian Gulf-region in 2005.
Role Interceptor, air superiority and multirole combat aircraft
National origin United States of America
Manufacturer Grumman Aerospace Corporation
First flight 21 December 1970
Introduction 22 September 1974
Retired 22 September 2006 (United States Navy)
Status In service with the Islamic Republic of Iran Air Force
Primary users United States Navy (historical)
Imperial Iranian Air Force (historical)
Islamic Republic of Iran Air Force
Produced 1969–1991
Number built 712
Unit cost
US$38 million (1998)

The Grumman F-14 Tomcat is a supersonic, twin-engine, two-seat, variable-sweep wing fighter aircraft. The Tomcat was developed for the United States Navy's Naval Fighter Experimental (VFX) program following the collapse of the F-111B project. The F-14 was the first of the American teen-series fighters, which were designed incorporating the experience of air combat against MiG fighters during the Vietnam War.

The F-14 first flew in December 1970 and made its first deployment in 1974 with the U.S. Navy aboard USS Enterprise (CVN-65), replacing the McDonnell Douglas F-4 Phantom II. The F-14 served as the U.S. Navy's primary maritime air superiority fighter, fleet defense interceptor and tactical aerial reconnaissance platform. In the 1990s, it added the Low Altitude Navigation and Targeting Infrared for Night (LANTIRN) pod system and began performing precision ground-attack missions.[1]

In the 1980s F-14s were used as land-based interceptors by the Islamic Republic of Iran Air Force during the Iran–Iraq War, where they saw combat against Iraqi warplanes. Iranian F-14s reportedly shot down at least 160 Iraqi aircraft during the war, including 58 MiG-23s, 23 MiG-21s, nine MiG-25s, 33 Dassault Mirage F1s, 23 Su-17s, one Mil Mi-24, five Tu-22s, two MiG-27s, one Dassault Mirage 5, one B-6D, one Aérospatiale Super Frelon, and two unknown aircraft.[2] While only 12 to 16 Tomcats were shot down, at least half of the losses were due to accidents.[3]

The Tomcat was retired from the U.S. Navy's active fleet on 22 September 2006, having been supplanted by the Boeing F/A-18E and F Super Hornets.[4] The F-14 remains in service with the Islamic Republic of Iran Air Force, having been exported to Iran in 1976, when the U.S. had amicable diplomatic relations with Iran.



Beginning in the late 1950s, the U.S. Navy sought a long-range, high-endurance interceptor to defend its carrier battle groups against long-range anti-ship missiles launched from the jet bombers and submarines of the Soviet Union. The U.S. Navy needed a Fleet Air Defense (FAD) aircraft with a more powerful radar, and longer range missiles than the F-4 Phantom II to intercept both enemy bombers and missiles.[5] The Navy was directed to participate in the Tactical Fighter Experimental (TFX) program with the U.S. Air Force by Secretary of Defense Robert McNamara. McNamara wanted "joint" solutions to service aircraft needs to reduce development costs, and had already directed the Air Force to buy the F-4 Phantom II, which was developed for the Navy and Marine Corps.[6] The Navy strenuously opposed the TFX as it feared compromises necessary for the Air Force's need for a low-level attack aircraft would adversely impact the aircraft's performance as a fighter .

The F-111B was designed to fulfil the carrier-based interceptor role, but was found to have weight and performance problems, and was not suited to the aerial combat then becoming apparent in Vietnam

Weight and performance issues plagued the U.S. Navy F-111B variant for TFX and would not be resolved to the Navy's satisfaction. The F-111 manufacturer General Dynamics partnered with Grumman on the Navy F-111B. With the F-111B program in distress, Grumman began studying improvements and alternatives. In 1966, the Navy awarded Grumman a contract to begin studying advanced fighter designs. Grumman narrowed down these designs to its 303 design.[7] Vice Admiral Thomas F. Connolly, Deputy Chief of Naval Operations for Air Warfare, took the developmental F-111A variant for a flight and discovered that it had difficulty going supersonic and had poor carrier landing characteristics. He later testified to Congress about his concerns against the official Department of the Navy position and, in May 1968, Congress stopped funding for the F-111B, allowing the Navy to pursue an answer tailored to its requirements. The name "Tomcat" was partially chosen to pay tribute to Admiral Connolly, as the nickname "Tom's Cat" had already been widely used by the manufacturer, although the name also followed the Grumman tradition of naming its fighter aircraft after felines.[8]


The F-111B had been designed for the long-range Fleet Air Defense (FAD) interceptor role, but not for new requirements for air combat based on experience of American aircraft against agile MiG fighters over Vietnam. The Navy studied the need for VFAX, an additional fighter that was more agile than the F-4 Phantom for air-combat and ground-attack roles.[9] Grumman continued work on its 303 design and offered it to the Navy in 1967, which led to fighter studies by the Navy. The company continued to refine the design into 1968.[7]

In July 1968, the Naval Air Systems Command (NAVAIR) issued a request for proposals (RFP) for the Naval Fighter Experimental (VFX) program. VFX called for a tandem two-seat, twin-engined air-to-air fighter with a maximum speed of Mach 2.2. It would also have a built-in M61 Vulcan cannon and a secondary close air support role.[10] The VFX's air-to-air missiles would be either six AIM-54 Phoenix or a combination of six AIM-7 Sparrow and four AIM-9 Sidewinder missiles. Bids were received from General Dynamics, Grumman, Ling-Temco-Vought, McDonnell Douglas and North American Rockwell;[11] four bids incorporated variable-geometry wings.[10][N 1]

Grumman's VFX entry was designed around the TF30 engines, AWG-9 radar and AIM-54 missile intended for the F-111B; this eventually became the F-14A

McDonnell Douglas and Grumman were selected as finalists in December 1968. Grumman was selected for the contract award in January 1969.[12] Grumman's design reused the TF30 engines from the F-111B, though the Navy planned on replacing them with the Pratt & Whitney F401-400 engines under development for the Navy, along with the related Pratt & Whitney F100 for the USAF.[13] Though lighter than the F-111B, it was still the largest and heaviest U.S. fighter to fly from an aircraft carrier, a consequence of the requirement to carry the large AWG-9 radar and AIM-54 Phoenix missiles (from the F-111B) and an internal fuel load of 16,000 lb (7,300 kg).[14]

Upon winning the contract for the F-14, Grumman greatly expanded its Calverton, Long Island, New York facility for evaluating the aircraft. Much of the testing, including the first of many compressor stalls and multiple ejections, took place over Long Island Sound. In order to save time and forestall interference from Secretary McNamara, the Navy skipped the prototype phase and jumped directly to full-scale development; the Air Force took a similar approach with its F-15.[15] The F-14 first flew on 21 December 1970, just 22 months after Grumman was awarded the contract, and reached initial operational capability (IOC) in 1973. The United States Marine Corps was initially interested in the F-14 as an F-4 Phantom II replacement; going so far as to send officers to Fighter Squadron One Twenty-Four (VF-124) to train as instructors. The Marine Corps pulled out of any procurement when development of the stores management system for ground attack munitions was not pursued. An air-to-ground capability was not developed until the 1990s.[15]

Firing trials involved launches against simulated targets of various types, from cruise missiles to high-flying bombers. AIM-54 Phoenix missile testing from the F-14 began in April 1972. The longest single Phoenix launch was successful against a target at a range of 110 nmi (200 km) in April 1973. Another unusual test was made on 22 November 1973, when six missiles were fired within 38 seconds at Mach 0.78 and 24,800 ft (7,600 m); four scored direct hits.[16]

Improvements and changes

With time, the early versions of all the missiles were replaced by more advanced versions, especially with the move to full solid-state electronics that allowed better reliability, better ECCM and more space for the rocket engine. So the early arrangement of the AIM-54A Phoenix active-radar air-to-air missile, the AIM-7E-2 Sparrow Semi-active radar homing air-to-air missile, and the AIM-9J Sidewinder heat-seeking air-to-air missile was replaced in the 1980s with the B (1983) and C (1986) version of the Phoenix, the F (1977), M (1982), P (1987 or later) for Sparrows, and with the Sidewinder, L (1979) and M (1982). Within these versions there are several improved batches (for example, Phoenix AIM-54C++).[17]

The Tactical Airborne Reconnaissance Pod System (TARPS) was developed in the late 1970s for the F-14. Approximately 65 F-14As and all F-14Ds were modified to carry the pod.[18] TARPS was primarily controlled by the Radar Intercept Officer (RIO), who had a specialized display to observe reconnaissance data. The TARPS was upgraded with digital camera in 1996 with the "TARPS Digital (TARPS-DI)". The digital camera was further updated beginning in 1998 with the "TARPS Completely Digital (TARPS-CD)" configuration that provided real-time transmission of imagery.[19]

Some of the F-14A aircraft underwent engine upgrades to the GE F110-400 in 1987. These upgraded Tomcats were redesignated F-14A+, which was later changed to F-14B in 1991.[20] The F-14D variant was developed at the same time; it included the GE F110-400 engines with newer digital avionics systems such as a glass cockpit, and compatibility with the Link 16 secure datalink.[21] The Digital Flight Control System (DFCS) notably improved the F-14's handling qualities when flying at a high angle of attack or in air combat maneuvering.[22]

Adding ground attack capability

An F-14D launching an AIM-7 Sparrow; a GBU-24 Paveway III is also being carried.

In the 1990s, with the pending retirement of the A-6 Intruder, the F-14 air-to-ground program was resurrected. Trials with live bombs had been carried out in the 1980s; the F-14 was cleared to use basic iron bombs in 1992. In Operation Desert Storm, most air-to-ground missions were left to A-7, A-6 Intruder and F/A-18 Hornet squadrons, the F-14 focused on air defense operations. Following Desert Storm, F-14As and F-14Bs underwent upgrades to avionics and cockpit displays to enable the use of precision munitions, enhance defensive systems, and apply structural improvements. The new avionics were comparable with the F-14D; upgraded aircraft were designated F-14A (Upgrade) and F-14B (Upgrade) respectively.[18]

By 1994, Grumman and the Navy were proposing ambitious plans for Tomcat upgrades to plug the gap between the retirement of the A-6 and the F/A-18E/F Super Hornet entering service. However, the upgrades would have taken too long to implement to meet the gap, and were priced in the billions; Congress considered this too expensive for an interim solution.[18] A quick, inexpensive upgrade using the Low Altitude Navigation and Targeting Infrared for Night (LANTIRN) targeting pod was devised. The LANTIRN pod provided the F-14 with a forward-looking infrared (FLIR) camera for night operations and a laser target designator to direct laser-guided bombs (LGB).[23] Although LANTIRN is traditionally a two-pod system, an AN/AAQ-13 navigation pod with terrain-following radar and a wide-angle FLIR, along with an AN/AAQ-14 targeting pod with a steerable FLIR and a laser target designator, the decision was made to only use the targeting pod. The Tomcat's LANTIRN pod was altered and improved over the baseline configuration, such as a Global Positioning System / Inertial Navigation System (GPS-INS) capability to allow an F-14 to accurately locate itself. The pod was carried on the right wing glove pylon.[23]

Pale gray jet aircraft flying over water towards right, perpendicular to the camera. Horizon located two-thirds down the photo. Sky made up of two shades, dark blue covers the top, blending with a lighter shade until it is almost white above horizon
An F-14D(R) from VF-213 flying over Iraq on last Tomcat deployment with LANTIRN pod on starboard wing glove station and LGB underneath fuselage.

The LANTIRN pod did not require changes to the F-14's own system software, but the pod was designed to operate on a MIL-STD-1553B bus not present on the F-14A or B. Consequently, Martin Marietta specially developed an interface card for LANTIRN. The Radar Intercept Officer (RIO) would receive pod imagery on a 10-inch Programmable Tactical Information Display (PTID) or another Multi-Function Display in the F-14[24][25] rear cockpit and guided LGBs using a new hand controller installed on the right side console. Initially, the hand controller replaced the RIO's TARPS control panel, meaning a Tomcat configured for LANTIRN could not carry TARPS and the reverse, but eventually a workaround was later developed to allow a Tomcat to carry LANTIRN or TARPS as needed.[23]

An upgraded LANTIRN named "LANTIRN 40K" for operations up to 40,000 ft (12,000 m) was introduced in 2001, followed by Tomcat Tactical Targeting (T3) and Fast Tactical Imagery (FTI), to provide precise target coordinate determination and ability to transmit images in-flight.[26] Tomcats also added the ability to carry the GBU-38 Joint Direct Attack Munition (JDAM) in 2003, giving it the option of a variety of LGB and GPS-guided weapons.[27] Some F-14Ds were upgraded in 2005 with a ROVER III Full Motion Video (FMV) downlink, a system that transmits real-time images from the aircraft's sensors to the laptop of Forward Air Controller (FAC) on the ground.[28]



Flight demonstration video of an F-14
F-14 Tomcat flight demonstration video

The F-14 Tomcat was designed as both an air superiority fighter and a long-range naval interceptor.[29][30][31] The F-14 has a two-seat cockpit with a bubble canopy that affords all-round visibility. It features variable geometry wings that swing automatically during flight. For high-speed intercept, they are swept back and they swing forward for lower speed flight.[17] It was designed to improve on the F-4 Phantom's air combat performance in most respects.[29]

The F-14's fuselage and wings allow it to climb faster than the F-4, while the twin-tail arrangement offers better stability. The F-14 is equipped with an internal 20 mm M61 Vulcan Gatling cannon mounted on the left side, and can carry AIM-54 Phoenix, AIM-7 Sparrow, and AIM-9 Sidewinder anti-aircraft missiles. The twin engines are housed in widely spaced nacelles. The flat area of the fuselage between the nacelles is used to contain fuel and avionics systems, such as the wing-sweep mechanism and flight controls, as well as weaponry.[17] By itself, the fuselage provides approximately 40 to 60 percent of the F-14's aerodynamic lifting surface depending on the wing sweep position.[32]

Variable-geometry wings

The F-14's wing sweep can be varied between 20° and 68° in flight,[33] and can be automatically controlled by the Central Air Data Computer, which maintains wing sweep at the optimum lift-to-drag ratio as the Mach number varies; pilots can manually override the system if desired.[17] When parked, the wings can be "over swept" to 75° to overlap the horizontal stabilizers to save deck space aboard carriers. In an emergency, the F-14 can land with the wings fully swept to 68°,[17] although this presents a significant safety hazard due to greatly increased airspeed. Thus an aircraft would typically be diverted from an aircraft carrier to a land base if an incident did occur. The F-14 has flown and landed safely with an asymmetrical wing-sweep on an aircraft carrier during testing; this capability could be used in emergencies.[34]

Rear view of stationary aircraft
Rearview of the F-14 showing the area between the engine nacelles

The wings have a two-spar structure with integral fuel tanks. Much of the structure, including the wing box, wing pivots and upper and lower wing skins is made of titanium,[17] a light, rigid and strong material, but also difficult and costly to weld. Ailerons are not fitted, with roll control being provided by wing-mounted spoilers at low speed (which are disabled if the sweep angle exceeds 57°), and by differential operation of the all-moving tailerons at high speed.[17] Full-span slats and flaps are used to increase lift both for landing and combat, with slats being set at 17° for landing and 7° for combat, while flaps are set at 35° for landing and 10° for combat.[17] The twin tail layout helps in maneuvers at high AoA (angle of attack) while reducing the height of the aircraft to fit within the limited roof clearance of hangars aboard aircraft carriers. Two under-engine nacelle mount points are provided for external fuel drop tanks carrying an additional 4,000 lb (1,800 kg) of fuel.

Two triangular shaped retractable surfaces, called glove vanes, were originally mounted in the forward part of the wing glove, and could be automatically extended by the flight control system at high Mach numbers. They were used to generate additional lift (force) ahead of the aircraft's center of gravity, thus helping to compensate for the nose-down pitching tendencies at supersonic speeds. Automatically deployed at above Mach 1.4, they allowed the F-14 to pull 7.5 g at Mach 2 and could be manually extended with wings swept full aft. They were later disabled, however, owing to their additional weight and complexity.[17] The air brakes consist of top-and-bottom extendable surfaces at the rearmost portion of the fuselage, between the engine nacelles. The bottom surface is split into left and right halves, the tailhook hangs between the two halves, an arrangement sometimes called the "castor tail".[35]

Engines and landing gear

The F-14 was initially equipped with two Pratt & Whitney TF30 (or JT10A) turbofan engines with each providing a maximum thrust of 20,900 lb (93 kN) and giving the aircraft an official maximum speed of Mach 2.34.[36] The F-14 would normally fly at a cruising speed for reduced fuel consumption, which was important for conducting lengthy patrol missions.[37] Both of the engine's rectangular air intake ramps were equipped with movable ramps and bleed doors to meet the airflow requirements of the engine but prevent dangerous shockwaves from entering. de Laval nozzles were also fitted to the engine's exhaust.

An F-14D prepares to refuel with probe extended

The performance of the TF30 engine became an object of criticism. John Lehman, Secretary of the Navy in the 1980s, told the U.S. Congress that the TF30/F-14 combination was "probably the worst engine/airframe mismatch we have had in years" and that the TF30 was "a terrible engine";[33][35] 28% of all F-14 accidents were attributed to the engine. A high frequency of turbine blade failures led to the reinforcement of the entire engine bay to limit damage from such failures. The engines also had proved to be extremely prone to compressor stalls, which could easily result in loss of control, severe yaw oscillations, and could lead to an unrecoverable flat spin. At specific altitudes, exhaust produced by missile launches could cause an engine compressor stall; leading to the development of a bleed system to temporarily reduce engine power and block the frontal intake ramp during missile launch. With the TF30, the F-14's overall thrust-to-weight ratio at maximum takeoff weight is around 0.56, considerably less than the F-15A's ratio of 0.85; when fitted with the General Electric F110 engine, an improved thrust-to-weight ratio of 0.73 at maximum weight and 0.88 at normal takeoff weight was achieved.[36]

The landing gear is very robust, in order to withstand the harsh takeoffs and landings necessary for carrier operation. It comprises a double nosewheel and widely spaced single main wheels. There are no hardpoints on the sweeping parts of the wings, and so all the armament is fitted on the belly between the air intake ramps and on pylons under the wing gloves. Internal fuel capacity is 2,400 US gal (9,100 l): 290 US gal (1,100 l) in each wing, 690 US gal (2,600 l) in a series of tanks aft of the cockpit, and a further 457 US gal (1,730 l) in two feeder tanks. It can carry two 267 US gal (1,010 l) external drop tanks under the engine intake ramps.[17] There is also an air-to-air refueling probe, which folds into the starboard nose.[38]

Avionics and flight controls

The cockpit has two seats, arranged in tandem, outfitted with Martin-Baker GRU-7A rocket-propelled ejection seats, rated from zero altitude and zero airspeed up to 450 knots.[39] The canopy is spacious, and fitted with four mirrors to provide effectively all-round visibility. Only the pilot has flight controls; the flight instruments themselves are of a hybrid analog-digital nature.[17] The cockpit also features a head-up display (HUD) to show primarily navigational information; several other avionics systems such as communications and direction-finders are integrated into the AWG-9 radar's display. A significant feature of the F-14 was its Central Air Data Computer (CADC), designed by Garrett AiResearch, that formed the onboard integrated flight control system. It used a MOSFET-based Large-Scale Integration chipset, the MP944, making it possibly the first microprocessor in history.[40]

F-14 with landing gear deployed

The aircraft's large nose contains a two-person crew and several bulky avionics systems. The main element is the Hughes AN/AWG-9 X band radar; the antenna is a 36 in (91 cm)-wide planar array, and has integrated Identification friend or foe antennas. The AWG-9 has several search and tracking modes, such as Track while scan (TWS), Range-While-Search (RWS), Pulse-Doppler Single-Target Track (PDSTT), and Jam Angle Track (JAT); a maximum of 24 targets can be tracked simultaneously, and six can be engaged in TWS mode up to around 60 mi (97 km). Cruise missiles are also possible targets with the AWG-9, which can lock onto and track small objects even at low altitude when in Pulse-Doppler mode.[17] For the F-14D, the AWG-9 was replaced by the upgraded APG-71 radar. The Joint Tactical Information Distribution System (JTIDS)/Link 16 for data communications was added later on.[41]

The F-14 also features electronic countermeasures (ECM) and radar warning receiver (RWR) systems, chaff/flare dispensers, fighter-to-fighter data link, and a precise inertial navigation system.[17] The early navigation system was inertial-based, point-of-origin coordinates were programmed into a navigation computer and gyroscopes would track the aircraft's every motion to calculate distance and direction from that starting point. Global Positioning System later was integrated to provide more precise navigation and redundancy in case either system failed. The chaff/flare dispensers were located on the underside of the fuselage and on the tail. The RWR system consisted of several antennas on the aircraft's fuselage, which could roughly calculate both direction and distance of enemy radar users; it could also differentiate between search radar, tracking radar, and missile-homing radar.[42]

Featured in the sensor suite was the AN/ALR-23, an Infra-red search and track sensor using indium antimonide detectors, mounted under the nose; however this was replaced by an optical system, Northrop's AAX-1, also designated TCS (TV Camera Set). The AAX-1 helped pilots visually identify and track aircraft, up to a range of 60 miles (97 km) for large aircraft. The radar and the AAX-1 were linked, allowing the one detector to follow the direction of the other. A dual infrared/optical detection system was adopted on the later F-14D.


The F-14 was designed to combat highly maneuverable aircraft as well as the Soviet anti-ship cruise missile and bomber (Tupolev Tu-16, Tupolev Tu-22, Tupolev Tu-22M) threats.[31] The Tomcat was to be a platform for the AIM-54 Phoenix, but unlike the canceled F-111B, it could also engage medium- and short-range threats with other weapons.[29][31] The F-14 was an air superiority fighter, not just a long-range interceptor aircraft.[31] Over 6,700 kg (14,800 lb) of stores could be carried for combat missions on several hardpoints under the fuselage and under the wings. Commonly, this meant a maximum of two–four Phoenixes or Sparrows on the belly stations, two Phoenixes/Sparrows on the wing hardpoints, and two Sidewinders on the wing hardpoints. The F-14 was also fitted with an internal 20 mm M61 Vulcan Gatling-type cannon.

Operationally, the capability to hold up to six Phoenix missiles was never used, although early testing was conducted; there was never a threat requirement to engage six hostile targets simultaneously and the load was too heavy to safely recover aboard an aircraft carrier in the event that the missiles were not fired. During the height of Cold War operations in the late 1970s and 1980s, the typical weapon loadout on carrier-deployed F-14s was usually only one AIM-54 Phoenix, augmented by two AIM-9 Sidewinders, two AIM-7 Sparrow IIIs, a full loadout of 20 mm ammunition and two drop tanks. The Phoenix missile was used twice in combat by the U.S. Navy, both over Iraq in 1999,[43][44][45] but the missiles did not score any kills.

Iran made use of the Phoenix system, claiming several kills with it during the 1980-1988 Iran–Iraq War. Iran tried to use other missiles on the Tomcat. It attempted to integrate the Russian R-27R "Alamo" BVR missile, but was apparently unsuccessful.

Operational history

United States Navy

An F-14A of VF-84 Jolly Rogers, in a 1970s color scheme

The F-14 began replacing the F-4 Phantom II in U.S. Navy service starting in September 1974 with squadrons VF-1 "Wolfpack" and VF-2 "Bounty Hunters" aboard USS Enterprise (CVN-65) and participated in the American withdrawal from Saigon. The F-14 had its first kills in U.S. Navy service on 19 August 1981 over the Gulf of Sidra in what is known as the Gulf of Sidra incident. In that engagement two F-14s from VF-41 Black Aces were engaged by two Libyan Su-22 "Fitters". The F-14s evaded the short range heat seeking AA-2 "Atoll" missile and returned fire, downing both Libyan aircraft. U.S. Navy F-14s once again were pitted against Libyan aircraft on 4 January 1989, when two F-14s from VF-32 shot down two Libyan MiG-23 "Floggers" over the Gulf of Sidra in a second Gulf of Sidra incident.

Its first sustained combat use was as a photo reconnaissance platform. The Tomcat was selected to inherit the reconnaissance mission upon departure of the dedicated RA-5C Vigilante and RF-8G Crusaders from the fleet. A large pod called the Tactical Airborne Reconnaissance Pod System (TARPS) was developed and fielded on the Tomcat in 1981. With the retirement of the last RF-8G Crusaders in 1982, TARPS F-14s became the U.S. Navy's primary tactical reconnaissance system.[46] One of two Tomcat squadrons per airwing was designated as a TARPS unit and received 3 TARPS capable aircraft and training for 4 TARPS aircrews.

An F-14A from VF-114 intercepting a Soviet Tu-95RT "Bear-D" maritime reconnaissance aircraft.

While the Tomcat was being used by Iran in combat against Iraq in its intended air superiority mission in the early 1980s, the U.S. Navy found itself flying regular daily combat missions over Lebanon to photograph activity in the Bekaa Valley. At the time, the Tomcat had been thought too large and vulnerable to be used over land, but the need for imagery was so great that Tomcat aircrews developed high speed medium altitude tactics to deal with considerable AAA and SA-7 SAM threat in the Bekaa area. The first exposure of a Navy Tomcat to a SA-2 missile was over Somalia in April 1983 when a local battery was unaware of two Tomcats scheduled for a TARPS mission in prelude to an upcoming international exercise in vicinity of Berbera. An SA-2 was fired at the second Tomcat while conducting 10,000-ft mapping profile at max conserve setting. The Tomcat aircrews spotted the missile launch and dove for the deck thereby evading it without damage. The unexpected demand for combat TARPS laid the way for high altitude sensors such as the KA-93 36 in (910 mm) Long Range Optics (LOROP) to be rapidly procured for the Tomcat as well as an Expanded Chaff Adapter (ECA) to be incorporated in an AIM-54 Phoenix Rail. Commercial "Fuzz buster" type radar detectors were also procured and mounted in pairs in the forward cockpit as a stop gap solution to detect SAM radars such as the SA-6. The ultimate solution was an upgrade to the ALR-67 then being developed, but it would not be ready until the advent of the F-14A+ later in 1980s.

Portrait photography of four aircraft overflying orange desert and almost-flat terrain; horizon is blurred. Leading is black aircraft, followed by two single-engine jet aircraft, the one closer to camera being refueled by leading jet via a stiff hose connecting the two. Closest jet to camera is pale gray, has two engines and vertical fins, flying with wings unswept.
An F-14A of VF-32 during Operation Desert Storm with a KC-135 Stratotanker and two EA-6B Prowlers in the background

The participation of the F-14 in the 1991 Operation Desert Storm consisted of Combat Air Patrol (CAP) over the Red Sea and Persian Gulf and overland missions consisting of strike escort and reconnaissance. Until the waning days of Desert Storm, in-country air superiority was tasked to USAF F-15 Eagles due to the way the Air Tasking Orders (ATO) delegated primary overland CAP stations to the F-15 Eagle. The governing Rules of Engagement (ROE) also dictated a strict Identification Friend or Foe (IFF) requirement when employing Beyond Visual Range weapons such as the AIM-7 Sparrow and particularly the AIM-54 Phoenix. This hampered the Tomcat from using its most powerful weapon. Furthermore, the powerful emissions from the AWG-9 radar are detectable at great range with a radar warning receiver. Iraqi fighters routinely retreated as soon as the Tomcats "lit them up" with the AWG-9.[47][48] The U.S. Navy suffered its only F-14 loss from enemy action on 21 January 1991 when BuNo 161430, an F-14A upgraded to an F-14A+, from VF-103 was shot down by an SA-2 surface-to-air missile while on an escort mission near Al Asad airbase in Iraq. Both crew survived ejection with the pilot being rescued by USAF Special Forces and the RIO being captured by Iraqi troops as a POW until the end of the war.[49] The F-14 also achieved its final kill in US service, an Mi-8 "Hip" helicopter, with an AIM-9 Sidewinder.

In 1995, F-14s from VF-14 and VF-41 participated in Operation Deliberate Force as well as Operation Allied Force in 1999, and in 1998, VF-32 and VF-213 participated in Operation Desert Fox. On 15 February 2001 the Joint Direct Attack Munition or JDAM was added to the Tomcat's arsenal. On 7 October 2001, F-14s would lead some of the first strikes into Afghanistan marking the start of Operation Enduring Freedom and the first F-14 drop of a JDAM occurred on 11 March 2002. F-14s from VF-2, VF-31, VF-32, VF-154, and VF-213 would also participate in Operation Iraqi Freedom. The F-14Ds of VF-2, VF-31, and VF-213 obtained JDAM capability in March 2003.[27] On 10 December 2005, the F-14Ds of VF-31 and VF-213 were upgraded with a ROVER III downlink for transmitting images to a ground Forward Air Controller (FAC).[28]

The last F-14 take-off from a carrier, USS Theodore Roosevelt on 28 July 2006

While the F-14 had been developed as a lightweight alternative to the 80,000 lb (36,000 kg) F-111B, the F-14 was still the largest and most expensive fighter of its time. VFAX was revived in the 1970s as a lower cost solution to replacing the Navy and Marine Corps's fleets of F-4s, and A-7s. VFAX was directed to review the fighters in the USAF Light Weight Fighter competition, which led to the development of the F/A-18 Hornet as roughly a midsize fighter and attack aircraft. In 1994, Congress would reject Grumman proposals to the Navy to upgrade the Tomcat beyond the D model (such as the Super Tomcat 21, the cheaper QuickStrike version, and the more advanced Attack Super Tomcat 21).[50] Instead, the Navy elected to retire the F-14 and chose the F/A-18E/F Super Hornet to fill the roles of fleet defense and strike formerly filled by the F-14. The last two F-14 squadrons, the VF-31 Tomcatters and the VF-213 Black Lions conducted their last fly-in at Naval Air Station Oceana on 10 March 2006.[51]

The last American F-14 combat mission was completed on 8 February 2006, when a pair of Tomcats landed aboard the USS Theodore Roosevelt (CVN-71) after one dropped a bomb over Iraq. During their final deployment with the USS Theodore Roosevelt (CVN-71), VF-31 and VF-213 collectively completed 1,163 combat sorties totaling 6,876 flight hours, and dropped 9,500 lb (4,300 kg) of ordnance during reconnaissance, surveillance, and close air support missions in support of Operation Iraqi Freedom.[52] The USS Theodore Roosevelt (CVN-71) launched an F-14D, of VF-31, for the last time on 28 July 2006; piloted by Lt. Blake Coleman and Lt. Cmdr Dave Lauderbaugh as RIO.[53]

The official final flight retirement ceremony was on 22 September 2006 at Naval Air Station Oceana, and was flown by Lt. Cmdr. Chris Richard and Lt. Mike Petronis as RIO in a backup F-14 after the primary aircraft experienced mechanical problems.[54][55] The actual last flight of an F-14 in U.S. service took place 4 October 2006, when an F-14D of VF-31 was ferried from NAS Oceana to Republic Airport on Long Island, New York.[55] The remaining intact F-14 aircraft in the U.S. were flown to and stored at the 309th Aerospace Maintenance and Regeneration Group "Boneyard", at Davis-Monthan Air Force Base, Arizona; in 2007 the U.S. Navy announced plans to shred the remaining F-14s to prevent any components from being acquired by Iran.[56] In August 2009, the 309th AMARG stated that the last aircraft were taking to HVF West, Tucson, Arizona for shredding. At that time only 11 F-14s remained in desert storage.[57]


An F-14A of the Islamic Republic of Iran Air Force, in 2009

The sole foreign customer for the Tomcat was the Imperial Iranian Air Force, during the reign of the last Shah (King) of Iran, Mohammad Reza Pahlavi. In the early 1970s, the Imperial Iranian Air Force (IIAF) was searching for an advanced fighter, specifically one capable of intercepting Soviet MiG-25 reconnaissance flights. After a visit of U.S. President Richard Nixon to Iran in 1972, during which Iran was offered the latest in American military technology, the IIAF narrowed its choice between the F-14 Tomcat or the McDonnell Douglas F-15 Eagle. Grumman Corporation arranged a competitive demonstration of the Eagle against the Tomcat before the Shah, and in January 1974, Iran ordered 30 F-14s and 424 AIM-54 Phoenix missiles, initiating Project Persian King, worth US$300 million. A few months later, this order was increased to a total of 80 Tomcats and 714 Phoenix missiles as well as spare parts and replacement engines for 10 years, complete armament package, and support infrastructure (including construction of the Khatami Air Base near Esfahan).

The first F-14 arrived in January 1976, modified only by the removal of classified avionics components, but fitted with the TF-30-414 engines. The following year 12 more were delivered. Meanwhile, training of the first groups of Iranian crews by the U.S. Navy, was underway in the USA; and one of these conducted a successful shoot-down with a Phoenix missile of a target drone flying at 50,000 ft (15 km).

Following the overthrow of the Shah in 1979, the air force was renamed the Islamic Republic of Iran Air Force (IRIAF) and the post-revolution interim government of Iran canceled most Western arms orders. In 1980, an Iranian F-14 shot down an Iraqi Mil Mi-25 helicopter for its first air-to-air kill during the Iran–Iraq War.[2]

Formation flight of Iranian Tomcats, 2008

According to research by Tom Cooper, within the first six months of the war Iranian F-14s scored over 50 air-to-air victories, mainly against Iraqi MiG-21s and MiG-23s, but some also against Su-20s/22s. In exchange, one F-14A was lost to a MiG-21.[58]

Between 1982 and 1986 Iranian Tomcats were to see use in a series of slowly developing campaigns: mainly tasked with patrolling the skies over objects vital for the survival of Iranian regime and economy, like Tehran or Kharg Island. Most of these patrols were supported by Boeing 707-3J9C tankers, and some lasted as long as 10 hours with up to four in-flight refuelings. Time and again, they were involved in new air battles, and performed well but their main role was intimidating the Iraqi Air Force. Cognizant of previous heavy losses in battles against Iranian F-14s, the Iraqis avoided any engagement with them, so that the sole presence of a Tomcat over the target area was enough to force Iraqi formations to abort their attacks. Because of this, and because of the precision and effectiveness of the Tomcat's AWG-9 weapons system and AIM-54A Phoenix long-range air-to-air missiles, the F-14 maintained air control over a lengthy period of time.

Iranian ace Jalil Zandi is credited by Tom Cooper with shooting down 11 Iraqi aircraft during the Iran–Iraq War, making him the most successful F-14 pilot.[59]

By 1987, the Iraqis had suffered such heavy losses to Iranian Tomcats that they were forced to find a solution with which they could engage them under equal circumstances. In early 1988 France delivered Mirage F.1EQ-6 fighters, armed with Super 530D and Magic Mk.2 air-to-air missiles, to Iraq.

According to Tom Cooper, IRIAF tried to keep 60 F-14s operational at any time during the war. But since 1986, this number reduced to 30 F-14s, of which only half were fully mission capable.[60] Overall, Cooper states that Iranian F-14s shot down at least 160 Iraqi aircraft during the Iran–Iraq War, which include 58 MiG-23s, 23 MiG-21s, nine MiG-25s, 33 Dassault Mirage F1s, 23 Su-17s, one Mil Mi-24, five Tu-22s, two MiG-27s, one Dassault Mirage 5, one B-6D, one Aérospatiale Super Frelon, and two unknown aircraft. Despite the circumstances under which the F-14s and their crews had to operate in Iran during the eight-year-long war against Iraq, it is still the premier fighter in the Iranian Air Force. The aircraft continued to operate without any support from AWACS or AEW aircraft, without even a proper support from the Ground Control Intercept (GCI). It faced an enemy that was repeatedly introducing new and more capable fighters, radars, weapons and ECM systems in combat and was supported by no less than three "superpowers" (France, the USA, and the USSR). Their crews were also permanently under heavy pressure from the regime in Tehran. That it proved as successful in combat is a result of strenuous efforts of IRIAF personnel and immense investment of the Iranian economy.[2]

While Iraq's army claimed it shot down more than 70 F-14s, According to the Foreign Broadcast Information System in Washington DC, Iran has lost 12 to 16 Tomcat during the war. Cooper writes only three F-14 were shot down by Iraqis and four others by Iranian SAM Missiles. Two Tomcats were lost in unknown circumstances during the battle and 7 were crashed due to technical failure or accidents.[61]

On 31 August 1986, an Iranian F-14A armed with at least one AIM-54A missile defected to Iraq. In addition, one or more of Iran's F-14A was delivered to the Soviet Union in exchange for technical assistance; at least one of its crew defected to the Soviet Union.[62]

Iran had an estimated 44 F-14s in 2009;[63] It had 19 F-14s in operation in January 2013 according to estimate by Aviation Week,[64] FlightGlobal estimated that approximately 28 were in service in 2014.[65]

In January 2007, the U.S. Department of Defense announced that sales of spare F-14 parts would be suspended over concerns of the parts ending up in Iran.[66] In July 2007, the remaining American F-14s were shredded to ensure that any parts could not be acquired.[56] In summer of 2010, Iran requested that the United States deliver the 80th F-14 it had purchased in 1974, but delivery was denied after the Islamic Revolution.[67][68] In October 2010, an Iranian Air Force commander claimed that the country overhauls and optimizes different types of military aircraft, mentioning that Air Force has even installed Iran-made radar systems on the F-14.[69]

On 26 January 2012, an Iranian F-14 crashed three minutes after takeoff. Both crew members were killed.[70]


A total of 712 F-14s were built[71] from 1969 to 1991.[72] F-14 assembly and test flights were performed at Grumman's plant in Calverton on Long Island, NY. Grumman facility at nearby Bethpage, NY was directly involved in F-14 manufacturing and was home to its engineers. The airframes were partially assembled in Bethpage and then shipped to Calverton for final assembly. Various tests were also performed at the Bethpage Plant. Over 160 of the U.S. aircraft were destroyed in accidents.[73]

Close-up view of the distinctive afterburner petals of the GE F110 engine


The F-14A was the initial two-seat, twin-engine, all-weather interceptor fighter variant for the U.S. Navy. It first flew on 21 December 1970. The first 12 F-14As were prototype versions[74] (sometimes called YF-14As). Modifications late in its service life added precision strike munitions to its armament. The U.S. Navy received 478 F-14A aircraft and 79 were received by Iran.[71] The final 102 F-14As were delivered with improved TF30-P-414A engines.[75] Additionally, an 80th F-14A was manufactured for Iran, but was delivered to the U.S. Navy.[71]


The F-14 received its first of many major upgrades in March 1987 with the F-14A Plus (or F-14A+). The F-14A's P&W TF30 engine was replaced with the improved GE F110-GE400 engine. The F-14A+ also received the state-of-the-art ALR-67 Radar Homing and Warning (RHAW) system. Much of the avionics as well as the AWG-9 radar were retained. The F-14A+ was later redesignated F-14B on 1 May 1991. A total of 38 new aircraft were manufactured and 48 F-14A were upgraded into B variants.[20]

The TF30 had been plagued from the start with susceptibility to compressor stalls at high AoA and during rapid throttle transients or above 30,000 ft (9,100 m). The F110-GE400 engine provided a significant increase in thrust, producing 27,080 lbf (120.5 kN) with afterburner at sea level. The increased thrust gave the Tomcat a better than 1:1 thrust-to-weight ratio at low fuel quantities. The basic engine thrust without afterburner was powerful enough for carrier launches, further increasing safety. Another benefit was allowing the Tomcat to cruise comfortably above 30,000 ft (9,100 m), which increased its range and survivability. The F-14B arrived in time to participate in Desert Storm.

In the late 1990s, 67 F-14Bs were upgraded to extend airframe life and improve offensive and defensive avionics systems. The modified aircraft became known as F-14B Upgrade or as "Bombcat".[75]


The final variant of the F-14 was the F-14D Super Tomcat. The F-14D variant was first delivered in 1991. The original TF-30 engines were replaced with GE F110-400 engines, similar to the F-14B. The F-14D also included newer digital avionics systems including a glass cockpit and replaced the AWG-9 with the newer AN/APG-71 radar. Other systems included the Airborne Self Protection Jammer (ASPJ), Joint Tactical Information Distribution System (JTIDS), SJU-17(V) Naval Aircrew Common Ejection Seats (NACES) and Infra-red search and track (IRST).[76]

An upgraded F-14D(R) Tomcat with the ROVER transmit antenna circled with USS Theodore Roosevelt (CVN-71) in the background

Although the F-14D was to be the definitive version of the Tomcat, not all fleet units received the D variant. In 1989, Secretary of Defense Dick Cheney refused to approve the purchase of any more F-14D model aircraft for $50 million each and pushed for a $25 million modernization of the F-14 fleet instead. Congress decided not to shut production down and funded 55 aircraft as part of a compromise. A total of 37 new aircraft were completed, and 18 F-14A models were upgraded to D-models, designated F-14D(R) for rebuild.[20] An upgrade to the F-14D's computer software to allow AIM-120 AMRAAM missile capability was planned but was later terminated.[18]

While upgrades had kept the F-14 competitive with modern fighter aircraft technology, Cheney called the F-14 1960s technology. Despite an appeal from the Secretary of the Navy for at least 132 F-14Ds and some aggressive proposals from Grumman for a replacement,[77] Cheney planned to replace the F-14 with a fighter that was not manufactured by Grumman. Cheney called the F-14 a "jobs program", and when the F-14 was canceled, an estimated 80,000 jobs of Grumman employees, subcontractors, or support personnel were affected.[78] Starting in 2005, some F-14Ds received the ROVER III upgrade.

Projected variants

The first F-14B was to be an improved version of the F-14A with more powerful "Advanced Technology Engine" F401 turbofans. The F-14C was a projected variant of this initial F-14B with advanced multi-mission avionics.[79] Grumman also offered an interceptor version of the F-14B in response to the U.S. Air Force's Improved Manned Interceptor Program to replace the Convair F-106 Delta Dart as an Aerospace Defense Command interceptor in the 1970s. The F-14B program was terminated in April 1974.[80]

Grumman's proposed F-14 Interceptor for USAF Aerospace Defense Command in 1972 with the simulated "Buzz Code" and Aerospace Defense Command livery and emblem on the tail

Grumman proposed a few improved Super Tomcat versions. The first was the Quickstrike, which was an F-14D with navigational and targeting pods, additional attach points for weapons, and added ground attack capabilities to its radar. The Quickstrike was to fill the role of the A-6 Intruder after it was retired. This was not considered enough of an improvement by Congress, so the company shifted to the Super Tomcat 21 proposed design. The Super Tomcat 21 was a proposed lower cost alternative to the Navy Advanced Tactical Fighter (NATF). The Grumman design would have the same shape and body as the Tomcat, and an upgraded AN/APG-71 radar. New GE F110-129 engines were to provide a supercruise speed of Mach 1.3 and featured thrust vectoring nozzles. The version would have increased fuel capacity and modified control surfaces for improved takeoffs and lower landing approach speed. The Attack Super Tomcat 21 version was the last Super Tomcat proposed design. It added even more fuel capacity, more improvements to control surfaces, and possibly an active electronically scanned array (AESA) radar from the canceled A-12 attack aircraft.[81]

The last "Tomcat" variant was the ASF-14 (Advanced Strike Fighter-14), Grumman's replacement for the NATF concept. By all accounts, it would not be even remotely related to the previous Tomcats save in appearance, incorporating the new technology and design know-how from the Advanced Tactical Fighter (ATF) and Advanced Tactical Aircraft (ATA) programs. The ASF-14 would have been a new-build aircraft; however, its projected capabilities were not that much better than that of the (A)ST-21 variants.[82] In the end the Attack Super Tomcat was considered to be too costly. The Navy decided to pursue the cheaper F/A-18E/F Super Hornet to fill the fighter-attack role.[81]


F-14 Tomcat operators as of 2014 (former operators in red)
An IRIAF F-14 Tomcat landing at Mehrabad, Iran.
F-14A Tomcat of VF-126 c1993
Front view of an F-14A at Yokota Air Base, Tokyo, Japan, 2003
F-14A BuNo 162689 at the USS Hornet Museum in Alameda, California, 2009
  • Islamic Republic of Iran Air Force
    • 72nd TFS: F-14A, 1976–1985
    • 73rd TFS: F-14A, 1977–1985
    • 81st TFS: F-14A, 1977–present
    • 82nd TFS: F-14A, 1978–present
    • 83rd Tomcat Flight School: F-14A, 1978–1979
    • 83rd TFS: F-14A, renamed former 62nd TFS[83]
 United States
  • United States Navy operated F-14 from 1974 to 2006
    • Navy Fighter Weapons School (TOPGUN) (Merged with Strike University (Strike U) to form Naval Strike and Air Warfare Center (NSAWC) 1996)
      • VF-126 Bandits (Disestablished 1 April 1994)
    • VF-1 Wolfpack (Disestablished 30 September 1993)
    • VF-2 Bounty Hunters (Pacific Fleet through 1996, Atlantic Fleet 1996-2003, Pacific Fleet 2003–present; redesignated VFA-2 with F/A-18F, 1 July 2003)
    • VF-11 Red Rippers (Redesignated to VFA-11 with F/A-18F, May 2005)
    • VF-14 Tophatters (Redesignated VFA-14 with F/A-18E, 1 December 2001, and transferred to Pacific Fleet, 2002)
    • VF-21 Freelancers (Disestablished 31 January 1996)
    • VF-24 Fighting Renegades (Disestablished 20 August 1996)
    • VF-31 Tomcatters (Redesignated VFA-31 with F/A-18E, October 2006)
    • VF-32 Swordsmen (Redesignated VFA-32 with F/A-18F, 1 October 2005)
    • VF-33 Starfighters (Disestablished 1 October 1993)
    • VF-41 Black Aces (Redesignated VFA-41 with F/A-18F, 1 December 2001)
    • VF-51 Screaming Eagles (Disestablished 31 March 1995)
    • VF-74 Bedevilers (Disestablished 30 April 1994)
    • VF-84 Jolly Rogers (Disestablished 1 October 1995; squadron heritage and nickname transferred to VF-103)
    • VF-102 Diamondbacks (Redesignated VFA-102 with F/A-18F, 1 May 2002, and transferred to Pacific Fleet)
    • VF-103 Sluggers/Jolly Rogers (Redesignated VFA-103 with F/A-18F, 1 May 2005)
    • VF-111 Sundowners (Disestablished 31 March 1995; reestablished as VFC-111 in Naval Air Force Reserve with Northrop F-5N and F-5F, 1 November 2006)
    • VF-114 Aardvarks (Disestablished 30 April 1993)
    • VF-142 Ghostriders (Disestablished 30 April 1995)
    • VF-143 Pukin' Dogs (Redesignated VFA-143 with F/A-18E, early 2005)
    • VF-154 Black Knights (Redesignated VFA-154 with F/A-18F, 1 October 2003)
    • VF-191 Satan's Kittens (Disestablished 30 April 1988)
    • VF-194 Red Lightnings (Disestablished 30 April 1988)
    • VF-211 Fighting Checkmates (Pacific Fleet through 1996, then transferred to Atlantic Fleet; redesignated VFA-211 with F/A-18F, 1 October 2004)
    • VF-213 Black Lions (Pacific Fleet through 1996, then transferred to Atlantic Fleet; redesignated VFA-213 with F/A-18F, May 2006)
  • Naval Air Systems Command Test and Evaluation Squadrons
    • VX-4 Evaluators (Disestablished 30 September 1994 and merged into VX-5 to form VX-9)
    • VX-9 Vampires (Currently operates F/A-18C/D/E/F, EA-18G, EA-6B, AV-8B, AH-1 and UH-1)
    • VX-23 Salty Dogs (Currently operates F/A-18A+/B/C/D/E/F, EA-6B, EA-18G and T-45)
    • VX-30 Bloodhounds (Currently operates P-3, C-130, S-3)
  • Fleet Replacement Squadrons
    • VF-101 Grim Reapers; Atlantic Fleet, then sole single-site, F-14 FRS (Disestablished 15 September 2005; reestablished as VFA-101, sole single-site F-35C Fleet Replacement Squadron in May 2012)[84]
    • VF-124 Gunfighters; Pacific Fleet F-14 FRS
      • (Disestablished 30 September 1994)
  • Naval Air Force Reserve Squadrons
    • VF-201 Hunters (Redesignated VFA-201 and reequipped with F/A-18A+ on 1 January 1999; disestablished 30 June 2007)
    • VF-202 Superheats (Disestablished 31 December 1994)
    • VF-301 Devil's Disciples (Disestablished 11 September 1994)
    • VF-302 Stallions (Disestablished 11 September 1994)
  • Naval Air Force Reserve Squadron Augmentation Units (SAUs)
    • VF-1285 Fighting Fubijars (Disestablished September 1994);[85] augmented VF-301 and VF-302
    • VF-1485 Americans (Disestablished September 1994);[86] augmented VF-124
    • VF-1486 Fighting Hobos (Disestablished September 2005);[87] augmented VF-101

Aircraft on display

An F-14A on display at Grumman Memorial Park in New York
F-14A BuNo 160661 on display at the U.S. Space and Rocket Center's Aviation Challenge facility in Huntsville, Alabama in August 2009
F-14A of VF-84 "Jolly Rogers" at the Museum of Flight

Notable F-14s preserved at museums and military installations include:

Bureau Number (BuNo) – Model – Location – Significance

Specifications (F-14D)

F-14A, VF 111 "Sundowners" (USS Carl Vinson)

Data from U.S. Navy file,[161] Spick,[36] M.A.T.S.[162] FlightGlobal [163]

General characteristics




Tomcat logo

The Tomcat logo design came when Grumman's Director of Presentation Services, Dick Milligan, and one of his artists, Grumman employee Jim Rodriguez, were asked for a logo by Grumman's Director of Business Development and former Blue Angels #5 pilot, Norm Gandia.[166] Per Rodriguez, "He asked me to draw a lifelike Tomcat wearing boxing gloves and trunks sporting a six-shooter on his left side; where the guns are located on the F-14, along with two tails." The Cat was drawn up after a tabby cat was sourced and used for photographs, and named "Tom". The logo has gone through many variations, including one for the then–Imperial Iranian Air Force F-14, called "Ali-cat". The accompanying slogan "Anytime Baby!" was developed by Norm Gandia as a challenge to the U.S. Air Force's McDonnell Douglas F-15 Eagle.[166][167]

Notable appearances in media

See also

Related development
Aircraft of comparable role, configuration and era
Related lists



  1. ^ Note: Admiral Thomas F. Connolly wrote the chapter, "The TFX – One Fighter For All".[10]
  2. ^ The hardpoints between nacelles include two on centerline plus four others next to nacelles. Points between nacelles can only carry a maximum of four missiles at one time. Each wing glove can carry one large pylon for larger missiles, with one rail on the outboard side of the pylon for a Sidewinder.


  1. ^ "F-14 Tomcat fighter fact file." United States Navy, 5 July 2003. Retrieved: 20 January 2007.
  2. ^ a b c Cooper, Tom. Persian Cats: How Iranian air crews, cut off from U.S. technical support, used the F-14 against Iraqi attackers." Air & Space Magazine, November 2006. Retrieved: 24 March 2012.
  3. ^ Cooper, Tom and Farzad Bishop. Iranian F-14 Tomcat Units in Combat, p. 84. Oxford: Osprey Publishing, 2004. ISBN 1 84176 787 5.
  4. ^ "Navy's 'Top Gun' Tomcat Fighter Jet Makes Ceremonial Final Flight." Associated Press, 22 September 2006. Retrieved: 17 July 2008.
  5. ^ Thomason 1998, pp. 3–5.
  6. ^ Dwyer, Larry. "The McDonnell F-4 Phantom II.", 31 March 2010. Retrieved: 24 March 2012.
  7. ^ a b Spick 2000, pp. 71–72.
  8. ^ Marrett 2006, p. 18.
  9. ^ Spangenberg, George. "Spangenberg Fighter Study Dilemma." Retrieved: 24 March 2012.
  10. ^ a b c Woolridge, Capt. E.T., ed. Into the Jet Age: Conflict and Change in Naval Aviation 1945-1975, an Oral History. Annapolis, Maryland: Naval Institute Press, 1995. ISBN 1-55750-932-8.
  11. ^ Spick 1985, pp. 9–10.
  12. ^ Spick 2000, p. 74.
  13. ^ Spick 2000, p. 112.
  14. ^ Gunston and Spick 1983, p. 112.
  15. ^ a b Jenkins, Dennis R. F/A-18 Hornet: A Navy Success Story. New York: McGraw-Hill, 2000. ISBN 0-07-134696-1.
  16. ^ Spick 2000, pp. 110–111.
  17. ^ a b c d e f g h i j k l m Baugher, Joe. "Grumman F-14A Tomcat." Joe Baugher's Encyclopedia of American Military Aircraft, 13 February 2000. Retrieved: 6 May 2010.
  18. ^ a b c d Donald, David. "Northrop Grumman F-14 Tomcat, U.S. Navy today". Warplanes of the Fleet. London: AIRtime Publishing Inc, 2004. ISBN 1-880588-81-1.
  19. ^
  20. ^ a b c Anft, Torsent. "F-14 Bureau Numbers." Home of M.A.T.S. Retrieved: 30 September 2006.
  21. ^ Friedman, Norman. "F-14." The Naval Institute Guide to World Naval Weapon Systems, Fifth edition. Annapolis MD: Naval Institute Press, 2006. ISBN 1-55750-262-5.
  22. ^ "F-14 upgrades." Retrieved: 24 March 2012.
  23. ^ a b c Gobel, Greg. "Bombcat / Tomcat In Service 1992:2005"., 1 November 2006. Retrieved: 8 December 2009.
  24. ^ Pike, John. "F-14 Tomcat Systems." Retrieved: 19 December 2010.
  25. ^ "Approved Navy Training System Plan for the F-14A, F-14B, and F-14D Aircraft (N88-NTSP-A-50-8511B/A)".
  26. ^
  27. ^ a b "U.S. Navy's F-14D Tomcats Gain JDAM Capability." Navy Newsstand (United States Navy), 21 March 2003. Retrieved: 20 January 2007.
  28. ^ a b "ROVER System Revolutionizes F-14's Ground Support Capability." Navy Newsstand (United States Navy), 14 December 2005. Retrieved: 20 January 2007.
  29. ^ a b c Spangenberg, George. "Brief History and Background of the F-14, 1955-1970." George Spangenberg Oral History. Retrieved: 23 December 2009.
  30. ^ Spangenberg, George."Exhibit VF-2." George Spangenberg Oral History, 8 February 1965. Retrieved: 23 December 2009.
  31. ^ a b c d Spangenberg, George. "Statement of Mr. G.A. Spangenberg before the Senate Armed Services Subcommittee, June 1973." George Spangenberg Oral History. Retrieved: 23 December 2009.
  32. ^ Pike, John. "F-14 Tomcat Design." Retrieved: 5 April 2012.
  33. ^ a b Dorr 1991, p. 50.
  34. ^ "F-14A, Aircraft No. 3, BuNo. 157982." F-14 Association. Retrieved: 8 December 2009.
  35. ^ a b Sgarlato 1988, pp. 40–46.
  36. ^ a b c d Spick 2000, p. 81.
  37. ^ Laurence K. Loftin, Jr. "Part II: The Jet Age, Chapter 10: Technology of the Jet Airplane, Turbojet and Turbofan Systems." Quest for Performance: The Evolution of Modern Aircraft, 29 February 2009. Retrieved: 29 January 2009.
  38. ^ "NAVEDTRA No: 14313, Aviation Ordanceman." Retrieved: 8 April 2011.
  39. ^ Dorr 1991, p. 51.
  40. ^ Holt, Ray M. "The F-14A 'Tom Cat' Microprocessor.", 23 February 2009. Retrieved: 8 December 2009.
  41. ^ "Interoperability: A Continuing Challenge in Coalition Air Operations." RAND Monograph Report. pp. 108, 111. Retrieved: 16 November 2010.
  42. ^ "AN/ALR-67(V)3 Advanced Special Receiver." Federation of American Scientists. Retrieved: 29 December 2009.
  43. ^ Rausa, Zeno. Vinson/CVW-11 "Vinson/CVW-11 report." Wings of Gold, Summer 1999. Retrieved: 8 December 2009.
  44. ^ Holmes 2005, pp. 16, 17.
  45. ^
  46. ^ Baugher, Joe. "TARPS Pod for F-14." F-14 Tomcat, 13 February 2000. Retrieved: 6 May 2010.
  47. ^ Gillcrest 1994, p. 168.
  48. ^ "Capt. Dale "Snort" Snodgrass, USN (Ret.) Interview by John Sponauer". (30 August 2000). SimHQ. Retrieved: 26 November 2010.
  49. ^ Baugher, Joe. "F-14." U.S. Navy and U.S. Marine Corps BuNos, 30 September 2006. Retrieved: 6 May 2010.
  50. ^ Donald 2004, pp. 13, 15.
  51. ^ "Squadron Homecoming Marks End of Era for Tomcats". U.S. Navy, 10 March 2006. Retrieved: 20 January 2007.
  52. ^ Murphy, Stephen. "TR Traps Last Tomcat from Combat Mission." Navy Newsstand, 15 February 2006. Retrieved: 20 January 2007.
  53. ^ "Final launch of the F-14 Tomcat." Retrieved: 8 December 2009.
  54. ^ Tiernan, Bill. "F-14's Final Flight." Virginian-Pilot, 23 September 2006.
  55. ^ a b Vanden Brook, Tom. "Navy retires F-14, the Coolest of Cold Warriors". USA Today, 22 September 2006. Retrieved: 20 January 2007.
  56. ^ a b "Pentagon shreds F-14s to keep parts from enemies." AP, 2 July 2007. Retrieved: 8 December 2009.
  57. ^
  58. ^
  59. ^ Cooper, Tom and Farzad Bishop. Iranian F-14 Tomcat Units in Combat, pp. 85–88. Oxford: Osprey Publishing, 2004. ISBN 1 84176 787 5.
  60. ^ Cooper, Tom and Farzad Bishop. Iranian F-14 Tomcat Units in Combat, p. 70. Oxford: Osprey Publishing, 2004. ISBN 1 84176 787 5.
  61. ^ Cooper and Bishop, p. 84.
  62. ^ "F-14 Tomcat interceptors in Iran". Ivanov, Grigoriy, 2003
  63. ^ Cooper, Tom and Liam Devlin. "Iranian Air Power Combat Aircraft". Combat Aircraft, Vol. 9 No. 6, January 2009.
  64. ^ "World Military Aircraft Inventory". 2013 Aerospace Source Book, Aviation Week and Space Technology, 2013.
  65. ^
  66. ^ "US halts sale of F-14 jet parts." BBC News. Retrieved: 8 December 2009.
  67. ^ "Iranian Air Force seeks return of F-14 bombers from U.S." Tehran Times
  68. ^ Parsons, Gary. "Iran wants its F-14 back." AirForces Monthly, 5 August 2010.
  69. ^ "Iranian Air Force Equips F-14 Fighter Jets with Hi-Tech Radars." FARS News Agency, Iran, 5 January 2011. Retrieved: 9 September 2012.
  70. ^ "Iranian F-14 fighter jet crashes in country's south, both pilot and co-pilot killed." Washington Post, 26 January 2012. Retrieved: 24 March 2012.
  71. ^ a b c "F-14 Bureau Numbers." Retrieved: 8 December 2009.
  72. ^ Anft, Torsten. "Grumman Memorial Park." Home of M.A.T.S. Retrieved: 28 December 2006.
  73. ^ Anft, Torsent. "F-14 Crashes sorted by Date." Home of M.A.T.S. Retrieved: 1 January 2008.
  74. ^ Spick 2000, pp. 75–79.
  75. ^ a b "F-14 Tomcat variants". Retrieved: 20 September 2006.
  76. ^ "Developing F-15C." Lockheed Martin Press Release, 28 April 2010.
  77. ^ Jenkins 1997, p. 30.
  78. ^ Saul, Stephanie. "Cheney Aims Barrage at F-14D Calls keeping jet a jobs program." Newsday Washington Bureau, 24 August 1989, p. 6.
  79. ^ Spick 2000, p. 75.
  80. ^ Isham, Marty. U.S. Air Force Interceptors: A Military Photo Logbook 1946–1979. North Branch, Minnesota: Specialty Press Publications, 2010. ISBN 1-58007-150-3.
  81. ^ a b Donald 2004, pp. 9–11.
  82. ^ "F-14 History." Retrieved: 16 November 2010.
  83. ^ Taghvaee, Babak. Aviation News Monthly, UK: Key Publishing, March 2012.
  84. ^ Navy's Newest Squadron Prepares for New F-35 Fighters. Retrieved on 2013-08-16.
  85. ^ "VF-1285." Retrieved: 8 December 2009.
  86. ^ "VF-1485." Retrieved: 8 December 2009.
  87. ^ "VF-1486." Retrieved: 8 December 2009.
  88. ^ "F-14 Tomcat/157982." Cradle of Aviation Museum. Retrieved: 27 March 2013.
  89. ^ a b "F-14 Tomcat/157984." National Naval Aviation Museum. Retrieved: 27 March 2013.
  90. ^ "F-14 Tomcat/157988." Warbird Registry. Retrieved: 27 March 2013.
  91. ^ "F-14 Tomcat/157990." March Field Air Museum. Retrieved: 27 March 2013.
  92. ^ "F-14 Tomcat/158623." Warbird Registry. Retrieved: 27 March 2013.
  93. ^ "F-14 Tomcat/158978." USS Midway Museum. Retrieved: 27 March 2013.
  94. ^ "F-14 Tomcat/158985." Yanks Air Museum. Retrieved: 27 March 2013.
  95. ^ "F-14 Tomcat/158998." Air Victory Museum. Retrieved: 27 Match 2013.
  96. ^ "F-14 Tomcat/158999." Warbird Registry. Retrieved: 27 March 2013.
  97. ^ "F-14 Tomcat/159025." Patriot's Point Maritime and Naval Museum. Retrieved: 27 March 2013.
  98. ^ "F-14 Tomcat/159445." Warbird Registry. Retrieved: 27 March 2013.
  99. ^ "F-14 Tomcat/159448." Warbird Registry. Retrieved: 27 March 2013.
  100. ^ "F-14 Tomcat/159455." Retrieved: 28 March 2013.
  101. ^
  102. ^ "F-14 Tomcat/159620." Warbird Registry. Retrieved: 27 March 2013.
  103. ^ "F-14 Tomcat/159626." Warbird Registry. Retrieved: 27 March 2013.
  104. ^ "F-14 Tomcat/159631." Retrieved: 28 March 2013.
  105. ^ "F-14 Tomcat/159829." Wings Over the Rockies Air & Space Museum. Retrieved: 27 March 2013.
  106. ^ "F-14 Tomcat/159830." Western Museum of Flight. Retrieved: 27 March 2013.
  107. ^ "F-14 Tomcat/159848." Tillamook Air Museum. Retrieved: 28 March 2013.
  108. ^ "F-14 Tomcat/159853." Warbird Registry. Retrieved: 27 March 2013.
  109. ^ "F-14 Tomcat/159856." Warbird Registry. Retrieved: 27 March 2013.
  110. ^ "F-14 Tomcat/160382." Museum of Flight. Retrieved: 27 March 2013.
  111. ^ "F-14 Tomcat/160386." Retrieved: 28 March 2013.
  112. ^ "F-14 Tomcat/160391." Texas Air Museum. Retrieved: 27 March 2013,
  113. ^ "F-14 Tomcat/160395." Air Zoo. Retrieved: 28 March 2013.
  114. ^ "F-14 Tomcat/160401." Warbird Registry. Retrieved: 27 March 2013.
  115. ^ "F-14 Tomcat/160403." Air Power Museum. Retrieved: 28 March 2013
  116. ^ "F-14 Tomcat/160441." Empire State Aeroscience Museum. Retrieved: 29 March 2013.
  117. ^ "F-14 Tomcat/160658." Warbird Registry. Retrieved: 27 March 2013.
  118. ^ "F-14 Tomcat/160661." Retrieved: 28 March 2013.
  119. ^ "F-14 Tomcat/160666." Oakland Aviation Museum. Retrieved: 28 March 2013.
  120. ^ "F-14 Tomcat/160684." Pima Air & Space Museum. Retrieved: 28 March 2013.
  121. ^ "F-14 Tomcat/160694." USS Lexington Museum. Retrieved: 28 March 2013.
  122. ^ "F-14 Tomcat/160889." Pacific Coast Air Museum. Retrieved: 28 March 2013.
  123. ^ "F-14 Tomcat/160898." Palm Springs Air Museum. Retrieved: 28 March 2013.
  124. ^ "F-14 Tomcat/160902." Retrieved: 28 March 2013.
  125. ^ "F-14 Tomcat/160903." Retrieved: 28 March 2013.
  126. ^ "F-14 Tomcat/160909." Warbird Registry. Retrieved: 27 March 2013.
  127. ^ "F-14 Tomcat/160914." Retrieved: 28 March 2013.
  128. ^ "F-14 Tomcat/161134." Valiant Air Command Warbird Museum. Retrieved: 28 March 2013.
  129. ^ "F-14 Tomcat/161163." Prairie Aviation Museum. Retrieved: 28 March 2013.
  130. ^ "F-14 Tomcat/162591." Quonset Air Museum. Retrieved: 28 March 2013,
  131. ^ "F-14 Tomcat/162592." Retrieved: 1 July 2015.
  132. ^ "F-14 Tomcat/162608." Retrieved: 28 March 2013.
  133. ^ "F-14 Tomcat/162689." USS Hornet Museum. Retrieved: 28 March 2013.
  134. ^ "F-14 Tomcat/162694." MAPS Air Museum. Retrieved: 28 March 2013.
  135. ^ "F-14 Tomcat/162710." National Naval Aviation Museum. Retrieved: 28 March 2013.
  136. ^ "F-14 Tomcat/157986." USS Intrepid Museum. Retrieved: 27 March 2013.
  137. ^ "F-14 Tomcat/161598." Tulsa Air and Space Museum. Retrieved: 28 March 2013.
  138. ^ "F-14 Tomcat/161605." Wings of Eagles Discovery Center. Retrieved: 28 March 2013.
  139. ^ "F-14 Tomcat/161615." Combat Air Museum. Retrieved: 28 March 2013.
  140. ^ "F-14 Tomcat/161620." Selfridge Military Air Museum. Retrieved: 28 March 2013.
  141. ^ "F-14 Tomcat/161623." Patuxent River Naval Air Museum. Retrieved: 28 March 2013.
  142. ^ "F-14 Tomcat/162912." Grissom Air Museum. Retrieved: 28 March 2013.
  143. ^ "F-14 Tomcat/162916." Retrieved: 28 March 2013.
  144. ^ "F-14 Tomcat/162926." New England Air Museum. Retrieved: 28 March 2013.
  145. ^ "F-14 Tomcat/159600." OV-10 Bronco Museum. Retrieved: 28 March 2013.
  146. ^ "F-14 Tomcat/159610." NASM. Retrieved: 27 March 2013.
  147. ^ "F-14 Tomcat/159619." Retrieved: 28 March 2013.
  148. ^ "F-14 Tomcat/161166." Carolinas Aviation Museum. Retrieved: 29 Marc 2013.
  149. ^ "F-14 Tomcat/162595." Warbird Registry. Retrieved: 28 March 2013.
  150. ^ "F-14 Tomcat/163893." Retrieved: 28 March 2013.
  151. ^ "F-14 Tomcat/163897." Aerospace Museum of California. Retrieved: 28 March 2013.
  152. ^ "F-14 Tomcat/163902." Hickory Aviation Museum. Retrieved: 28 March 2013.
  153. ^ "F-14 Tomcat/163904." Pacific Aviation Museum. Retrieved: 28 March 2013.
  154. ^ "F-14 Tomcat/164342." Wings Over Miami Air Museum. Retrieved: 28 March 2013.
  155. ^ "F-14 Tomcat/164343." Evergreen Aviation Museum. Retrieved: 29 March 2013.
  156. ^ "F-14 Tomcat/164346." Virginia Aviation Museum. Retrieved: 28 March 2013.
  157. ^ "F-14 Tomcat/164350." Retrieved: 28 March 2013.
  158. ^ "F-14 Tomcat/164601." Castle Air Museum. Retrieved: 28 March 2013.
  159. ^ "F-14 Tomcat/164603." Retrieved: 28 March 2013.
  160. ^ "F-14 Tomcat/164604." Retrieved: 28 March 2013.
  161. ^
  162. ^ "F-14 Specifications." M.A.T.S. Retrieved: 23 December 2009.
  163. ^ "FlightGlobal Magazine 1985"
  164. ^ Spick 2000, pp. 112–115.
  165. ^ Baugher, Joe. "Grumman F-14D Tomcat" Grumman F-14 Tomcat. 5 February 2000.
  166. ^ a b
  167. ^ The Tomcat Logo | Grumman Memorial Park. Retrieved on 2013-08-16.


  • Bishop, Farzad and Tom Cooper. Iranian F-14 Tomcat Units (Osprey Combat Aircraft #49). Oxford, UK: Osprey Publishing Limited, 2004. ISBN 978-1-84176-787-1.
  • Crosby, Francis. Fighter Aircraft. London: Lorenz Books, 2002. ISBN 0-7548-0990-0.
  • Donald, David. Warplanes of the Fleet. London: AIRtime Publishing Inc., 2004. ISBN 1-880588-81-1.
  • Dorr, Robert F. "F-14 Tomcat: Fleet Defender". World Air Power Journal, Volume 7, Autumn/Winter 1991, pp. 42–99. London: Aerospace Publishing. ISSN 0959-7050.
  • Drendel, Lou. F-14 Tomcat in Action. Carrollton, Texas: Squadron/Signal Publications, 1977. ISBN 0-89747-031-1.
  • Eden, Paul. The Encyclopedia of Modern Military Aircraft. London: Amber Books, 2004. ISBN 1-904687-84-9.
  • Eshel, D. Grumman F-14 Tomcat (War Data No. 15). Hod Hasharon, Israel: Eshel-Dramit Ltd., 1982.
  • Gillcrest, Paul T. Tomcat!: The Grumman F-14 Story . Atglen, Pennsylvania: Schiffer Publishing, Ltd. 1994. ISBN 0-88740-664-5
  • Gunston, Bill and Mike Spick. Modern Air Combat. New York: Crescent Books, 1983. ISBN 0-517-41265-9.
  • Holmes, Tony. US Navy F-14 Tomcat Units of Operation Iraqi Freedom (Osprey Combat Aircraft #52). Oxford, UK: Osprey Publishing Limited, 2005. ISBN 1-84176-801-4.
  • Holmes, Tony. F-14 Tomcat Units of Operation Enduring Freedom (Osprey Combat Aircraft #70). Oxford, UK: Osprey Publishing Limited, 2008. ISBN 978-1-84603-205-9.
  • Jenkins, Dennis R. Grumman F-14 Tomcat: Leading US Navy Fleet Fighter. London: Aerofax, 1997. ISBN 1-85780-063-X.
  • Marrett, George. "Flight of the Phoenix." Airpower, Volume 36, No. 7, July 2006.
  • Sgarlato, Nico. "F-14 Tomcat" (Italian). Aereonautica & Difesa magazine Edizioni Monografie SRL., December 1988.
  • Spick, Mike. F-14 Tomcat, Modern Fighting Aircraft, Volume 8. New York: Arco Publishing, 1985. ISBN 0-668-06406-4.
  • Spick, Mike. "F-14 Tomcat". The Great Book of Modern Warplanes. St. Paul, Minnesota: MBI Publishing Company, 2000. ISBN 0-7603-0893-4.
  • Stevenson, J.P. Grumman F-14, Vol. 25. New York: Tab Books, 1975. ISBN 0-8306-8592-8.
  • Thomason, Tommy. Grumman Navy F-111B Swing Wing (Navy Fighters No. 41). Simi Valley, California: Steve Ginter, 1998. ISBN 0-942612-41-8.
  • Wilson, Stewart. Combat Aircraft since 1945. Fyshwick, Australia: Aerospace Publications, 2000. ISBN 1-875671-50-1.

External links

  • F-14 U.S. Navy fact file and F-14 U.S. Navy history page
  • F-14 page on NASA Langley site
  • Joe Baugher's Website on Grumman F-14 Tomcat
  • F-14 Tomcat Reference Work, Home of M.A.T.S.
  • A music video by F-14 pilot from VF-31 while tanking for the last time with a KC-135, titled "Boom Operator" on YouTube, recorded 7 February 2006.
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