The origins of the F-14 lay back in the 1950’s when American intelligence agencies identified a growing family of Soviet air-launched cruise missiles as a potential threat to NATO fleet units. Carried to their launch points by heavy bombers, aircraft like the Tu-16 Badger or Tu-95 Bear, they could be launched well outside the range of enemy SAMs and antiaircraft (AAA) guns. Designated by NATO intelligence analysts as AS-1 “Kennel,” AS-2 “Kipper,” AS-3 “Kangaroo,” AS-4 “Kitchen,” AS-5 “Kelt,” and AS-6 “Kingfish,” these long-ranged, radar-guided pilotless jet- or rocket-powered weapons packed enormous ship-killing power. Armed with 1,000-kg/ 2,200-lb warheads (or high-yield nuclear warheads), they were capable of destroying a destroyer or frigate with a single hit. By way of comparison, the single AM-39 Exocet air-to-surface missile (ASM) that sank the British guided-missile destroyer HMS Sheffield (D 80) in 1982 had a warhead just one tenth that size. Since a single large bomber might carry two or three such monster ASMs, finding a way to defend the fleet against them became a high-level priority.
Experience in World War II against Japanese Kamikaze planes (which were essentially manned ASMs) showed that the best way to protect a fleet was to shoot down the missile-carrying enemy bombers before they could launch their missiles. Thus the response to the ASM threat was the accelerated development of extremely long-range air-to-air missiles (AAMs), which could maintain an outer ring in a layered defense system. Any missiles that “leaked” through the outer ring would then face an inner barrier of patrolling fighters, ship-launched SAMs, and point-defense missiles launched from surface ships. This was supposed to be the U.S. strategy until the end of the Cold War—a scheme that envisioned an extremely high-performance, long-ranged AAM that could be carried by a relatively slow but long-endurance carrier aircraft, the Douglas F6D Missileer. The Missileer would have carried eight long-range Bendix Eagle AAMs, along with powerful airborne radar. The F6Ds would have acted as airborne SAM sites, and would have been placed hundreds of miles ahead of a carrier group to intercept incoming bombers. However, fiscal realities now began to effect the Navy’s plans.
The F6D program was canceled in December 1960, mostly due to the fact that it was a single-mission aircraft only for fleet air defense. Even so, the Eagle missile was eventually resurrected as the Hughes AIM-54 Phoenix, which today is carried by the F-14. Already strapped for funds, the Navy decided that its next fighter should do the job of the F6D, as well as provide air superiority and other missions. Then high-level politics stepped in. In the early 1960’s, then-Secretary of Defense Robert MacNamara, frustrated by seemingly endless inter-service rivalries and hoping to save money, tried to force the Air Force and Navy to procure common types of aircraft. Out of this dream came the TFX (Tactical Fighter, Experimental) program—which became the Air Force’s F-111 swing-wing bomber. To meet its fighter missions, the Navy was directed to develop a variant of the F-111 that would be suitable for carrier operations. It was expected that it would accomplish its fleet air defense and air-superiority missions with the planned F-111B, which would replace the classic F-4 Phantom II.
The problem was that the “navalized” F-111B (which was built by Grumman in partnership with General Dynamics, the USAF “prime” contractor) was just too heavy, fragile, and complex for carrier operations, and its landing speed was too high for a safe landing on a carrier deck. Furthermore, the F-111B, with little maneuverability and thrust from its overworked engines, was not much of a fighter. For all of these reasons, the Navy rejected the F-111B, and the program was scrapped, though not without a fight. In those days, one did not go against a man as powerful as Secretary MacNamara without paying a price. The Navy paid in blood. In a scene reminiscent of the 1940’s “Revolt of the Admirals” a generation earlier, a senior naval aviator, Rear Admiral Tom “Tomcat” Connelly, sacrificed his own career by standing up to MacNamara in Congressional testimony. He stated flatly in an open session, “Senator, there is not enough thrust in all of Christendom to make a fighter out of the F-111!” With this legendary remark, the F-111B died, and the F-14 Tomcat was born.
Politics aside, the Navy still had the problem of those Soviet ASM armed bombers to deal with. As if to amplify the problem further, the Russians had deployed a new supersonic swing-wing bomber in the late 1960s that caused a near panic in U.S./NATO defense planners: the Tu-22M Backfire. The eventual answer to the Navy’s problem came after a series of fighter studies funded by the Navy and run by Grumman. The plan was to wrap a completely new, state-of-the-art airframe around the basic avionics, weapons, and propulsion package that had been intended for the F-111B (including the Phoenix missile system), and then run a series of product improvements upon the new bird. One of the aircraft’s most notable features would be a variable geometry “swing-wing” design that would allow it to “redesign” itself in flight. For good slow-speed performance during landing and cruise the wings would be set forward, and be swept back for supersonic dashes.
It was an ambitious design for the late 1960s. The new fighter would not only carry up to six of the massive AIM-54 Phoenix missiles and the AWG-9 radar to guide them, but it would also be a superb dogfighter. In Vietnam the F-4 Phantom II had severe shortcomings during close-in air-to-air engagements. The Phantoms weren’t very maneuverable, were easy to see (both big and smoky), and didn’t have much range. The new fighter would be very different.
The Request for Proposals went out in 1968, and a number of airframe manufacturers submitted responses to build the new bird. However, with their fighter study and F-111B experience, Grumman had a clear edge, and early in 1969 they won the contract to build what would become known as the F-14. Quickly, Grumman got to work and began to cut metal, and the new bird rapidly came together. The first flight of the F-14A prototype occurred almost a month ahead of schedule, on December 21st, 1970, at Grumman’s Calverton plant on Long Island. Though three of the preproduction aircraft were lost in testing (including the prototype on its second flight), the program progressed well. The new fighter moved along on schedule, with the first two fleet squadrons, VF-1 (the “Wolfpack”) and VF-2 (the “Bounty Hunters”), standing up in 1974. In honor of Admiral Connelly’s role in its creation, the Navy named the new bird the “Tomcat.”48
The Tomcat is a two-seat, twin-engined fighter that measures 62 feet, 8 inches/19.1 meters in length. Its height to the tip of the vertical stabilizer is 16 feet/4.88 meters. The maximum wingspan is 64 feet, 1.5 inches/19.54 meters at a minimum sweep angle of 20°. Minimum wingspan in flight is 38 feet, 2.5 inches/11.65 meters at a maximum flight sweep angle of 68°. For storage in the cramped confines of the flight hangar decks, the wings can “oversweep” (only on deck for stowage) to an angle of 75°, overlapping the horizontal tail surfaces and reducing the span to only 33 feet, 3.5 inches/ 10.15 meters. The Tomcat’s empty weight is 40,150 lb/18,212 kg, with a maximum takeoff weight of 74,500 lb/33,793 kg. The F-14 is by far the heaviest aircraft flying on and off a carrier these days. You can actually feel an aircraft carrier shudder whenever one is catapulted off.
The famous Grumman “Iron Works” has a well-earned reputation for producing the most durable and robust aircraft in the world. Much of the plane’s structure, including the critical “wing box” (containing the swing-wing mechanism), is made of titanium, a metal lighter than aluminum, stronger than steel, and notoriously difficult to weld. The Tomcat’s horizontal tail surfaces were built from boron-epoxy composite—a very costly and advanced material that was used for the first time on any aircraft.
The F-14 is the Navy’s only “variable geometry” aircraft, a trait it inherited from its predecessor, the F-111B. While complex, the swing wing was a valid engineering solution to a difficult design problem for the Navy. The F-14 had to be both a long-range interceptor that could “loiter” (fly slow and wait) and a high-performance fighter for air-superiority missions. If one aircraft was to do both jobs and still be capable of operating off aircraft carriers, it had to be able to literally “redesign” itself in f
light. This was the job of the swing wing. The Tomcat’s wings sweep forward for increased lift in low-speed flight, particularly the critical takeoff and landing phases of a carrier-based mission, but when the wings sweep back for reduced drag at high speed, the F-14 can move like a scalded cat.
Unlike other variable-geometry aircraft like the F-111 Aardvark and MiG-23/27 Flogger, the F-14’s wing sweep is controlled automatically by a computer known as the “Mach Sweep Programmer.” This means that the pilot does not have to worry about it—the plane dynamically reconfigures itself from moment to moment for the optimum solution to the complex equations governing lift and drag. The wings then pivot on immensely strong bearings, moved by jackscrews driven by powerful hydraulic motors, giving the flight crew the best possible “design” for any situation they are in. The result is an aircraft that is always being optimized, whether it is making a low-level, high-speed reconnaissance dash, or digging into a cornering turn pulling “lead” on an enemy fighter. Along with the swing wings, the F-14’s engineers managed to provide the flight crew with a full array of control surfaces, including full-span flaps along the trailing edge, leading edge slats, and spoilers on the upper surface of the wings. The speed brake is positioned far aft, between the twin vertical stabilizers. In fact, it was the seemingly random movement of these surfaces that caused Landing Signals Officers (LSOs) to dub the F-14 “the Turkey” during tests.
Visually, the F-14 is an imposing aircraft. The topside of the Tomcat’s forward fuselage and two huge engine pods blend into a flat structure called the “pancake,” which supports the tail surfaces and the tailhook. The pancake itself is a form of “lifting body,” and provides a significant amount of the aircraft’s total lift. The large canopy offers superb all-around visibility—a great improvement over previous Navy fighters like the F-4 Phantom, which had a deadly blind spot to the rear. This was one of the design criteria that helped make the Tomcat a much better dogfighter than the F-4, or the MiGs that it was designed to kill. The two-person flight crew (a pilot and Radar Intercept Officer or “RIO”) enters the cockpit using a retractable boarding ladder and cleverly designed “kick-in” steps. Both positions have Martin-Baker “zero-zero” ejection seats, meaning that they can actually save an air crew if the aircraft is sitting still (zero speed) on the ground (zero altitude). Three rearview mirrors are positioned around the canopy frame to help the pilot with rear visibility.
The design of the pilot’s station was quite advanced for the early 1970’s, with the most important data being displayed on an integrated “Air Combat Maneuvering panel.” The Tomcat was also equipped with the Navy’s first heads-up display (HUD) projected into the pilot’s forward field of view, and the first use of the “Hands-on-Throttle-and-Stick” (HOTAS) in the cockpit. The control stick and throttles are studded with buttons that govern weapon selection, radar modes, and other functions. HOTAS allows pilots to keep their eyes outside the cockpit during a dogfight. The rest of the cockpit is not so advanced. Since the F-14 was designed a decade ahead of “glass cockpit” aircraft (like the F/A-18 Hornet), most of the control panels are traditional dial-type “steam gauge” indicators. Unlike USAF fighters, though, the RIO’s backseat position does not provide flight controls (unless you count the ejection seat). A large circular display screen—the Tactical Information Display—dominates the RIO’s position, with a smaller Detail Data Display panel above it. These provide readouts for the AWG-9 radar/ fire control system, as well as weapons control. Again, circular “steam gauges” dominate the RIO’s cockpit.
When they arrived upon the aviation scene, the sensor and weapons systems of the Tomcat were a revolution.49 The heart of the F-14 weapons system (in the -A and -B models) is the Raytheon-Hughes Airborne Weapons Group Model Nine (AWG-9) fire-control system. Composed of powerful radar, weapons-computer, signal-processor, and other components, the AWG- 9 made the F-14 the most powerful fighter in the world. Unfortunately, it never really got a chance to show its awesome capability in combat. Designed for the extremely long-range, multiple-target engagements that were projected for the Cold War at sea, the F-14 spent a generation waiting for a battle that never came. The AWG-9 requirement was to simultaneously track up to two dozen airborne targets (in an environment that might have hundreds), while actually engaging (that’s Navy for “shooting”) six of them at once. The actual tracking ranges against various-sized targets are highly classified, but the AWG-9 has regularly tracked fighter-sized targets out beyond 100 nm/ 185 km.
Since F-14 operations have always been constrained by strict rules of engagement (ROE) that require visually identifying the target, long-range shots with radar-guided AAMs have been rare. The five enemy air-to-air “kills” that the Tomcat has scored to date were all achieved at fairly short ranges, the killing missile shots all occurring with visual range of the targets. In recognition of these ROE realities, the F-14 carries a pod under the radome holding a television camera system (TCS). The TCS is equipped with a zoom lens that can be used to identify targets visually at fairly long ranges. As an added bonus, it feeds an onboard videotape recorder, which provides the flight crew an excellent visual record of their engagements.
A VF-102 F-14B Tomcat aboard the USS George Washignton (CVN-73) in 1997. Fully loaded, it carried fuel tanks and “iron” bombs, as well as AIM-9 Sidewinder and AIM-54 Phoenix air-to-air missiles.
OFFICIAL U.S. NAVY PHOTO
From the very start of its career, the F-14 was intended as an air-to-air killer, with little effort or money expended to give it an air-to-ground capability. The Tomcat’s claws were designed to give it the ability to kill at every range, from close in to over 100 nm/185 km, which is still something of a record.
The weapon with the longest range is the mighty Raytheon-Hughes AIM-54 Phoenix AAM. An outgrowth of the original Eagle AAM that was to have armed the F6D, the AIM-54 first flew in the 1960’s. With a range in excess of 100 nm/185 km, the AIM-54 was the first deployed AAM equipped with its own active onboard radar-guidance system. This gave it the capability of being launched in a “fire-and-forget” mode, allowing the launching aircraft to turn away to evade or begin another engagement after firing. It also means that up to six AIM-54’s can be launched at up to six different targets at once. Once launched, the missile climbs in a high-altitude parabolic trajectory, reaching speeds approaching Mach 5. When a Phoenix gets near a target, a huge 133.5-lb/60.7-kg high-explosive warhead ensures that it dies quickly. It was this capability that Navy planners wanted to utilize had the Soviet bomber/ASM missile threat ever been encountered in wartime. The Phoenix has had several versions, each one designed to keep pace with Soviet improvements in their own weaponry; the AIM-54C is the latest.
Along with the AIM-54, the Tomcat is equipped with three other weapons for killing aerial targets. The first of these, the Raytheon AIM-7M Sparrow, is an updated version of the semiactive radar-guided AAM that has been in service since the 1950’s. Weighing some 503 lb/228 kg, this medium-range (out to twenty-plus nm/thirty-seven-plus km) AAM requires continuous “illumination” from the AWG-9 radar to hit its target. Once there, the eighty-eight-pound /forty-kilogram blast-fragmentation warhead can kill any aerial target that it hits. However, the AIM-7 has always been a difficult weapon to employ, because of its need for constant radar illumination of the target. There were plans to replace the Sparrow on the F-14 with the new AIM-120 Advanced Medium Range Air-to-Air Missile (AMRAAM). Unfortunately, budget cuts at the end of the Cold War, combined with the fact that the Tomcat already had a long-range fire-and-forget AAM in the Phoenix, caused this to be canceled.
Shorter-range missile engagements are handled by the classic AIM-9M Sidewinder AAM, which utilizes infrared (heat-seeking) guidance to find its targets. The current AIM-9M version is badly dated, and almost obsolete compared with the Russian R-73/AA-11 Archer, Matra R.550 Magic, or Rafael Python-4. These missiles are not only controlled via helmet-mounted sighting systems, but also can be fired up to 90° “off-boresight” (i.e.
, the centerline of the firing aircraft). This shortcoming will be rectified in the early 21st century with the introduction of the new AIM-9X.
The last of the Tomcat’s air-to-air weapons was the one that designers of the F-4 Phantom thought unnecessary in the age of AAMs: a 20mm cannon. During the Vietnam War, Navy pilots complained bitterly about the MiG kills that they missed because of the Phantom’s lack of a close-in weapon (it was armed only with AIM-7/9 AAMs). When the specification for the F-14 was being written, “Tomcat” Connelly made sure that it had a gun to deal with threats inside the minimum range of AAMs. The gun in the F-14 is the same one in most U.S. fighters, the classic six-barreled 20mm M61 Vulcan. Able to fire up to six thousand 20mm shells per minute, it can literally “chop” an enemy aircraft in half.
With the exception of the internal six-barrel 20mm M61 Gatling gun, all the Tomcat’s weapons are carried externally. For mechanical simplicity, there are no weapon pylons on the movable portions of the wings, since these would have to swivel to stay pointed directly into the airflow. Because of this, drop tanks and other external stores must be accommodated under the fuselage and engines, or on the structure of the wing “glove” inside the pivot. Four deep grooves known as “wells,” shaped to the contours of AIM-7 Sparrow AAMs, are sculpted into the flat underbelly of the fuselage in the tunnel between the engine pods. When the huge (984-lb/447.5-kg) AIM-54 Phoenix missiles are carried, they are mounted on removable pallets that cover the Sparrow wells. Up to four of the AIM-54’s can be carried here, along with another pair on the “glove” pylons. However, these pylons are more normally configured with rails for an AIM-9 Sidewinder and AIM-7 Sparrow AAM.
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