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F-22 Raptor
Type	Stealth Air superiority fighter
Manufacturers	Lockheed Martin Aeronautics Boeing Integrated Defense Systems
Maiden flight	YF-22: 29 September 1990 F-22: 7 September 1997
Introduction	15 December 2005
Status	Active: 91[1] Planned: 183[2]
Primary user	United States Air Force
Number built	100 (as of September 2007)[3]
Program cost	US $ 62 billion[4]
Unit cost	US$137.7 million as of 2007[5]
Variants	X-44 MANTA FB-22

 

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The F-22 Raptor

The F-22 Raptor is an American fighter aircraft that uses stealth technology. It is an air superiority fighter, but is equipped for ground attack, electronic warfare, and signals intelligence roles as well. The United States Air Force considers the F-22 a critical component of the US strike force.^[6]

Faced with a protracted development period, the aircraft was variously designated F-22 and F/A-22 during the three years before formally entering US Air Force service in December 2005, as the F-22A. Lockheed Martin Aeronautics is the prime contractor and is responsible for the majority of the airframe, weapon systems and final assembly of the F-22. Along with Lockheed Martin, partner Boeing Integrated Defense Systems provides the wings, aft fuselage, avionics integration, and all of the pilot and maintenance training systems.

The F-22 is claimed by several sources to be the world’s most effective air superiority fighter. The US Air Force claims that the F-22 cannot be matched by any known or projected fighter aircraft.^[6] Air Marshal Angus Houston, chief of the Australian Defence Force, and former head of the Royal Australian Air Force, said in 2004 that the "F-22 will be the most outstanding fighter plane ever built."^[7]

History of the F-22

 

 

Development

 

The Advanced Tactical Fighter (ATF) contract was a demonstration and validation program undertaken by the United States Air Force (USAF) to develop a next-generation air superiority fighter to counter emerging worldwide threats, including development and proliferation of Soviet-era Su-27 "Flanker"-class fighter aircraft.

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The original Lockheed Advanced Tactical Fighter concept (1986)

In 1981, USAF developed a requirement for a new air superiority fighter intended to replace the capability of the F-15 Eagle. It was envisaged that the ATF would incorporate emerging technologies including advanced alloys and composite materials, advanced fly-by-wire flight control systems, higher power propulsion systems, and low-observable/stealth technology.

A request for proposal (RFP) was issued in July 1986, and two contractor teams, Lockheed/Boeing/General Dynamics and Northrop/McDonnell Douglas were selected in October 1986 to undertake a 50-month demonstration/validation phase, culminating in the flight test of two prototypes, the YF-22 and the YF-23.

Following a hard-fought fly-off competition, in August 1991 the YF-22 was declared the winner and Lockheed was awarded the contract to develop and build the Advanced Tactical Fighter.

 

More On The F-22 Development

 

 

Introduction

 

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The original Boeing Advanced Tactical Fighter concept (1986)

The first production F-22 was delivered to Nellis Air Force Base, Nevada, on 14 January 2003 and "Dedicated Initial Operational Test and Evaluation" commenced on 27 October 2004. By 2004, 51 Raptors were in service.

The first crash of a production F-22 occurred during takeoff at Nellis Air Force Base on 20 December 2004, in which the pilot ejected safely moments before impact. The crash investigation revealed that a brief interruption in power during an engine shutdown prior to flight caused a malfunction in the flight-control system;^[8] consequently the technical data for the aircraft has been amended to avoid a recurrence of this problem.

In August 2007, the United States Air Force signed a $5 billion, multi-year contract with Lockheed Martin that will extend production to 2011,^[2] and as of 2007, F-22 Raptors are being procured at the rate of 20 per year.^[5]

In a ceremony on 29 August 2007, Lockheed Martin reached its "100th F-22 Raptor" milestone, delivering aircraft 05-4100.^[3]

 

 

Procurement

 

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Two F-22s, the upper one being the first EMD F-22, "Raptor 01"

The United States Air Force originally planned to order 750 ATFs, with production beginning in 1994; however, the 1990 Major Aircraft Review altered the plan to 648 aircraft beginning in 1996. The goal changed again in 1994, when it became 442 aircraft entering service in 2003 or 2004, but a 1997 Department of Defense report put the purchase at 339. In 2003, the Air Force said that the existing congressional cost cap limited the purchase to 277. By 2006, the Pentagon said it will buy 183 aircraft, which would save $15 billion but raise the cost of each aircraft, and this plan has been de facto approved by Congress in the form of a multi-year procurement plan, which still holds open the possibility for new orders past that point. The total cost of the program by 2006 was $62 billion.^[4]

In April 2006, the cost of the F-22A was assessed by the Government Accountability Office to be $361 million per aircraft. This cost reflects the F-22A total program cost, divided by the number of fighters the Air Force is programmed to buy; and which has so far invested $28 billion in the Raptor's research, development and testing. That money, referred to as a "sunk cost", is already spent and is separate from money used for future decision-making, including procuring a copy of the jet.

By the time all 183 fighters have been purchased, $34 billion will have been spent on actual procurement, resulting in a total program cost of $62 billion or about $339 million per aircraft. The incremental cost for one additional F-22 is around $137 million; decreasing with larger volumes. If the Air Force were to buy 100 more F-22s today, the cost of each one would be less than $117 million and would continue to drop with additional aircraft purchases.^[4]

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F-22A Raptors over Utah in their first official deployment, October 2005

The F-22 is not the most expensive aircraft aloft. That distinction likely belongs to the roughly $2.2 billion-per-unit B-2 Spirit, whose orders went from hundreds to a few dozen when the Cold War ended thus making the unit cost skyrocket, though the incremental cost was under US$1 billion. The F-22 uses fewer radar absorbent materials than the B-2 or F-117 Nighthawk, which is expected to translate into lower maintenance costs.

On 31 July 2007, Lockheed Martin received a multiyear contract for 60 F-22s worth a total of US$7.3 billion.^[2][9] The contract brings the number of F-22s on order to 183 and extends production through 2011.^[2]

During the recent grounding of nearly 700 F-15s, some US Senators demanded that Deputy Secretary of Defense Gordon England release three government reports that support additional F-22 Raptors beyond the planned 183 jets.^[10] Forbes has reported that the USAF plans to extend the production of the F-22 past 2011. This is believed to be a response to the recent grounding of F-15A-D.^[11]

 

Proposed Forein Sales

Unlike many other tactical fighters, the opportunity for export is currently non-existent because the export sale of the F-22 is barred by federal law. There was a time in the 1970s when the then-new F-16 also had many restrictions. However, regardless of restrictions, very few allies would even be considered for export sale because the F-22 is such a sensitive and expensive system. Most current customers for US fighters are either acquiring earlier designs like the F-15, or F-16 or are waiting to acquire the F-35, which contains much of the F-22's technology but is designed to be cheaper and more flexible.

More recently Japan reportedly showed some interest in buying F-22As in its Replacement-Fighter program for its Air Self-Defense Force (JASDF).^[12] In such an event, it would most likely involve a "watered-down" export variant while still retaining most of its advanced avionics and stealth characteristics. However, such a proposal would still need approval from the Pentagon, State Department and Congress.

Some Australian defense commentators have proposed that Australia purchase F-22 aircraft instead of the F-35.^[13] In 2006, the Australian Labor Party, Australia's main opposition party at the time, supported this proposal on the grounds that the F-22 is a proven, highly capable aircraft while the F-35 is still under development.^[14] The then-current Australian Government, however, ruled out the purchase of the F-22 on the grounds that it is unlikely to be released for export, and does not meet Australia's requirements for a strike aircraft.^[15] This assessment was supported by the Australian Strategic Policy Institute, a non-partisan, government-funded think-tank, which claimed that the F-22 "has insufficient multi-role capability at too high a price" for Australia.^[16]

Israeli Air Force (IAF) chief procurement officer Brigadier-General Ze'ev Snir said that, "The IAF would be happy to equip itself with 24 F-22s, but the problem at this time is the US refusal to sell the aircraft, and its $200 million price tag."^[17]

The US Congress upheld the ban on F-22 Raptor foreign sales during a joint conference on 27 September 2006.^[18] After talks in Washington in December 2006, the US DoD reported the F-22 would not be available for foreign sale.^[19]

 

Design

 

More On The F-22 Program

 

Cockpit

 

The F-22 cockpit represents a zenith in the so-called “glass-cockpit” without any traditional flight instruments and represents a marked improvement on the cockpit design of previous advanced aircraft designs.

More On The F-22 Cockpit

 

Airframe

 

Several small design changes were made from the YF-22A prototype to the production F-22A. The swept-back angle on the wing's leading edge was decreased from 48 degrees to 42 degrees, while the vertical stabilizer area was decreased 20%. To improve pilot visibility, the canopy was moved forward 7 inches (178 mm) and the engine intakes were moved rearward 14 inches (356 mm). The shape of the wing and stabilator trailing edges was refined to improve aerodynamics, strength, and stealth characteristics.^[21]

 

Characteristics

 

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F-22 Raptor displaying its F119-PW-100 engines on full afterburner

The F119-PW-100 is an afterburning turbofan engine developed for the Lockheed Martin F-22 Raptor advanced tactical fighter by Pratt & Whitney. The engine delivers thrust in the 35,000 lbf (160 kN) thrust class (156 kN) and is designed for supersonic flight without the use of afterburner (supercruise). Delivering almost 22% more thrust with 40% fewer parts than conventional, fourth-generation military aircraft engine models, the F119 allows sustained supercruise speeds of up to Mach 1.72. The F-119's nozzles incorporate thrust vectoring technology. These nozzles direct the engine thrust ±20° in the pitch axis to give the F-22A enhanced maneuverability. The F-22's maximum speed could possibly be close to Mach 2.5 but this is unlikely because of its airframe materials. The Pratt & Whitney F135, which powers the Lockheed Martin F-35, is a derivative engine of the F119. It has 40,000 lbf (180 kN) of thrust, the most ever in a fighter engine.

The F-22 is a fifth-generation fighter that is considered a fourth-generation stealth aircraft by the USAF.^[22] Its dual afterburning Pratt & Whitney F119-PW-100 turbofans incorporate thrust vectoring, but in the pitch axis only, with a range of ±20 degrees. The maximum thrust is classified, though most sources place it at about 35,000 lbf (156 kN) per engine. Maximum speed, without external weapons, is estimated to be Mach 1.72 in supercruise mode; as demonstrated by General John P. Jumper, former US Air Force Chief of Staff, when his Raptor exceeded Mach 1.7 without afterburners on 13 January 2005.^[23] With afterburners, it is "greater than Mach 2.0" (1,317 mph, 2,120 km/h), according to Lockheed Martin; however, the Raptor can easily exceed its design speed limits, particularly at low altitudes, with max-speed alerts to help prevent the pilot from exceeding them. Former Lockheed Raptor chief test pilot Paul Metz stated that the Raptor has a fixed inlet; but while the absence of variable intake ramps may theoretically make speeds greater than Mach 2.0 unreachable, there is no evidence to prove this. Such ramps would be used to prevent engine surge, but the intake itself may be designed to prevent this. Metz has also stated that the F-22 has a top speed greater than 1,600 mph (Mach 2.42) and its climb rate is faster than the F-15 Eagle due to advances in engine technology, despite the F-15's thrust-to-weight ratio of about 1.2:1, with the F-22 having a ratio closer to 1:1.^[24] The US Air Force claims that the F-22A cannot be matched by any known or projected fighter.^[1]

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Aircraft wing planform shapes: a KC-10 Extender (top) refuels an F-22 Raptor

The true top-speed of the F-22 is largely unknown to the general public, as engine power is only one factor. The ability of the airframe to withstand the stress and heat from friction is a further, key factor, especially in an aircraft using as many polymers as the F-22. However, while some aircraft are faster on paper, the internal carriage of its standard combat load allows the aircraft to reach comparatively higher performance with a heavy load over other modern aircraft due to its lack of drag from external stores. It is one of only a handful of aircraft that can sustain supersonic flight without the use of afterburner augmented thrust (and its associated high fuel usage). This ability is called supercruise.

The F-22 is highly maneuverable, at both supersonic and subsonic speeds. The F-22's thrust vectoring nozzles allow the aircraft to turn tightly, and perform extremely high alpha (angle of attack) maneuvers such as the Herbst maneuver (or J-turn), Pugachev's Cobra,^[24] and the Kulbit, though the J-Turn is more useful in combat.^[24] The F-22 is also capable of maintaining a constant angle of attack of over 60°, yet still having some control of roll.^[24][25] During June 2006 exercises in Alaska, F-22 pilots demonstrated that cruise altitude has a significant effect on combat performance, and routinely attributed their altitude advantage as a major factor in achieving an unblemished kill ratio.^[26]

 

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The Herbst maneuver (also known as a J-Turn) is an air combat maneuver which uses post-stall technology such as thrust vectoring and advanced flight controls to achieve high angles of attack. The Herbst maneuver allows an aircraft to quickly reverse direction using a combination of high angle-of-attack and rolling. Though categorized with Pugachev's Cobra, which is popular at airshows, the Herbst maneuver is considered more useful in combat. The Herbst maneuver was first performed by a Rockwell-MBB X-31 on April 29, 1993, though the F-22 Raptor is also capable of performing the maneuver.] It is believed that Sukhoi Su-27 can do a J-Turn as well The Herbst maneuver was named after Dr. Wolfgang Herbst, an employee of Messerschmitt-Bölkow-Blohm (MBB). Herbst was the initiator of the Rockwell SNAKE, which formed the basis for the X-31 project, and one of the original developers of post-stall technology.

The Pugachev's Cobra (or Pugachev Cobra) is an aircraft cobra maneuver. It is a demonstration of the pitch control authority, high angle of attack (AOA) stability and engine/inlet compatibility at high angles of attack of the aircraft (i.e. supermaneuverability). The maneuver allows for very quick turns which can make an attack fail or put the pilot in a position to execute an attack. It is an example of air combat maneuvering (ACM), specifically poststall maneuvering. The Pugachev's Cobra is considered to be one of the most dramatic and demanding maneuvers performed at air shows worldwide. The maneuver is so named after the Sukhoi OKB (design bureau) test pilot Viktor Pugachev, who first performed the maneuver in 1989 at the Paris Le Bourget air show. Description The maneuver consists of the pilot pulling the aircraft to a 90°–120° angle of attack, then back down to zero. In a properly performed Pugachev's Cobra, the plane maintains a straight and level flight throughout the maneuver. The vertical form of this maneuver is called a Cobra, named after the snake that behaves in a similar manner. Performing the maneuver on the horizontal plane results in the aircraft effectively stopping while the enemy overshoots, leaving the aircraft in a position for a straightforward missile attack on the enemy aircraft.

The "Kulbitinscy" (or simply, "Kulbit") is an aerial maneuver developed by Russian pilots, in which the aircraft performs an incredibly tight diametered loop, often not much wider than the length of the aircraft itself. It is an example of post-stall maneuvering, a type of supermaneuverability The Kulbit drastically decelerates the aircraft and could theoretically be used to cause a pursuing aircraft to overshoot its target. The maneuver is closely related to the famous "Pugachev's Cobra" maneuver, but the Kulbit completes the loop that the Cobra almost immediately cuts off. Combat use Use of the Kulbit maneuver has never been recorded under actual combat conditions, and its practicality in such a situation is still under debate. However, even the most skeptical observers generally acknowledge its effectiveness as an impressive airshow stunt.

 

Avionics

The F-22's avionics include BAE Systems E&IS (formerly Sanders Associates) radar warning receiver (RWR) AN/ALR-94,^[27] and the Northrop Grumman AN/APG-77 Active Electronically Scanned Array (AESA) radar. The AN/APG-77 is possibly the most capable radar in active service, with both long-range target acquisition and low probability of interception of its own signals by enemy aircraft.

The AN/ALR-94 is a passive receiver system capable of detecting the radar signals in the environment. Composed of more than 30 antennae smoothly blended into the wings and fuselage, it is described by the former head of the F-22 program at Lockheed Martin Tom Burbage as "the most technically complex piece of equipment on the aircraft." With greater range (250+ nmi) than the radar, it enables the F-22 to limit its own radar emission which might otherwise compromise its stealth. As the target approaches, AN/ALR-94 can cue the AN/APG-77 radar to keep track of its motion with a narrow beam, which can be as focused as 2° by 2° in azimuth and elevation.^[28]

The AN/APG-77 AESA radar, designed for air-superiority and strike operations, features a low-observable, active-aperture, electronically-scanned array that can track multiple targets in all kinds of weather. The AN/APG-77 changes frequencies more than 1,000 times per second to reduce the chance of being intercepted. The radar can also focus its emissions to overload enemy sensors, giving the aircraft an electronic-attack capability.^[29]

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A pair on patrol.

The radar’s information is processed by two Raytheon Common Integrated Processor (CIP)s. Each CIP operates at 10.5 billion instructions per second and has 300 megabytes of memory. Information can be gathered from the radar and other onboard and offboard systems, filtered by the CIP, and offered in easy-to-digest ways on several cockpit displays, enabling the pilot to remain on top of complicated situations. The Raptor’s software is composed of over 1.7 million lines of code, most of which concerns processing data from the radar.^[30] The radar has an estimated range of 125-150 miles, though planned upgrades will allow a range of 250 miles (400 km) or more in narrow beams.^[26]

The F-22 has several unique functions for an aircraft of its size and role. For instance, it has threat detection and identification capability along the lines of that available on the RC-135 Rivet Joint.^[26] While the F-22's equipment isn't as powerful or sophisticated, because of its stealth, it can be typically hundreds of miles closer to the battlefield, which often compensates for the reduced capability.^[26]

The F-22 is capable of functioning as a "mini-AWACS." Though reduced in capability compared to dedicated airframes such as the E-3 Sentry, as with its threat identification capability, the F-22's forward presence is often of benefit.^[24] The system allows the F-22 to designate targets for cooperating F-15s and F-16s, and even determine if two friendly aircraft are targeting the same enemy aircraft, thus enabling one of them to choose a different target.^[26][24] It is often able to identify targets hundreds of times faster than accompanying dedicated AWACS.^[26]

The F-22's low probability of intercept radar is being given a high-bandwidth data transmission capability, to allow it to be used in a "broadband" role to permit high-speed relaying of data between friendly transmitters and receivers in the area.^[26] The F-22 can already pass data to other F-22s, resulting in considerably reduced radio "chatter."^[26]

The IEEE-1394B data bus, developed for the F-22, was derived from the commercial IEEE-1394 bus system,^[31] often used on personal computers. The bus was subsequently deployed on the derivative F-35 Lightning II fighter.^[31]

More On The F-22 Avionics

 

 

Armament

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An F-22 releases a JDAM from its internal bay while flying at supersonic speed

The Raptor is designed to carry air-to-air missiles in internal bays to avoid disrupting its stealth capability. Launching missiles requires opening the weapons bay doors for less than a second, while the missiles are pushed clear of the airframe by hydraulic arms. The aircraft can also carry bombs such as the Joint Direct Attack Munitions (JDAM) and the new Small-Diameter Bomb (SDB). The Raptor carries an M61A2 Vulcan 20 mm rotary cannon, also with a trap door, in the right wing root. The M61A2 is a last ditch weapon, and carries only 480 rounds; enough ammunition for approximately five seconds of sustained fire. Despite this, the F-22 has been able to use its gun in dogfighting without being detected, which can be necessary when missiles are depleted.^[24]

As other air forces upgrade capabilities in the areas of air-to-air and air-to-ground munitions, one key aspect of the Raptor must be kept in mind. Its very high sustained cruise speeds, and operational altitude (something that is often ignored), add tremendously to the effective range of both air-to-air and air-to-ground munitions. Indeed, these factors could provide a strong rationale as to why the USAF has not pursued long-range, high-energy air-to-air missiles such as the MBDA Meteor. However the USAF plans to procure the AIM-120D AMRAAM, which will have a significant increase in range compared to the AIM-120C. The launch platform, in this case, provides the additional energy to the missile. This speed and altitude characteristic also helps improve the range of air-to-ground ordnance. While specific figures remain classified, it is expected that JDAMs employed by F-22s will have twice or more the effective range of munitions dropped by legacy platforms.^[32] In testing, a Raptor dropped a 1,000 lb (450 kg) JDAM from 50,000 feet (15,000 m), while cruising at Mach 1.5, striking a moving target 24 miles (39 km) away.^[33] The SDB, as employed from the F-22, should see even greater increases in effective range, due to the improved lift to drag ratio of these weapons.

While in its air-superiority configuration, the F-22 carries its weapons internally, though it is not limited to this option. The wings are capable of supporting four detachable hardpoints. Each hardpoint is theoretically capable of handling 5,000 lb (2,300 kg) of ordnance. However, use of external stores greatly compromises the F-22's stealth, and has a detrimental effect on maneuverability, speed, and range. As many as two of these hardpoints are "plumbed", allowing the usage of external fuel tanks. The hardpoints are detachable in flight allowing the fighter to regain its stealth once these external stores are exhausted. Currently, there is research being conducted to develop a stealth ordnance pod and hardpoints for it. Such a pod would comprise a stealth shape and carry its weapons internally, then would split open when launching a missile or dropping a bomb. Both the pod and hardpoints could be detached when no longer needed. This system would allow the F-22 to carry its maximum ordnance load while remaining stealthy, albeit at a loss of maneuverability. However, there is concern over this program as external carriage of fuel tanks has shown more stress placed on the wings than originally anticipated.

More On The Weapons Of The F-22

 

 

Stealth

Although several recent Western fighter aircraft are less detectable on radar than previous designs using techniques such as radar absorbent material-coated S-shaped intake ducts that shield the compressor fan from reflecting radar waves, the F-22A design placed a much higher degree of importance on low observance throughout the entire spectrum of sensors including radar signature, visual, infrared, acoustic, and radio frequency.

The stealth of the F-22 is due to a combination of factors, including the overall shape of the aircraft, the use of radar absorbent material (RAM), and attention to detail such as hinges and pilot helmets that could provide a radar return.^[34] However, reduced radar cross section is only one of five facets that designers addressed to create a stealth design in the F-22. The F-22 has also been designed to disguise its infrared emissions to make it harder to detect by infrared homing ("heat seeking") surface-to-air or air-to-air missiles. Designers also addressed making the aircraft less visible to the naked eye, controlling radio transmissions, and noise abatement.^[34] The Raptor has an under bay carrier made for hiding heat from missile threats, like Surface-to-air missiles. ^[35]

The F-22 apparently relies less on maintenance-intensive radar absorbent material and coatings than previous stealth designs like the F-117. These materials caused deployment problems due to their susceptibility to adverse weather conditions.^[36] Unlike the B-2, which requires climate-controlled hangars, the F-22 can undergo repairs on the flight line or in a normal hangar.^[36] Furthermore, the F-22 has a warning system (called "Signature Assessment System" or "SAS") which presents warning indicators when routine wear-and-tear have degraded the aircraft's radar signature to the point of requiring more substantial repairs.^[36] The exact radar cross section of the F-22 remains classified

More On The Stealth Of The F-22

 

 

Operational History

 

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The 27th Fighter Squadron at Langley Air Force Base was the first squadron to receive the F-22A

Intended to be the leading American advanced tactical fighter in the early part of the 21st century, the Raptor is the world's most expensive fighter to date with an incremental cost of about US $138 million per unit.^[5] The number of aircraft to be built has dropped to 183,^[2] down from the initial requirement of 750. Part of the reason for the decrease in the requirement is that the F-35 Lightning II uses much of the technology used on the F-22, but at a much more affordable price. To a large extent the cost of these technologies is only lower for the F-35 because they have already been developed for the F-22.

 

The Yf-22 "Lighting II"

 

The YF-22 was a developmental aircraft that led to the F-22; however, there are significant differences between the YF-22 and the F-22. Relocation of cockpit, structural changes, and many other smaller changes exist between the two types.^[37] The two are sometimes confused in pictures, often at angles where it is difficult to see certain features. For example, there are some F-22 with pitot booms which some think are only found on the YF-22 (such as pictured at end of article). The YF-22 was originally given the unofficial name "Lightning II" by Lockheed, which persisted until the mid-1990s when the USAF officially named the aircraft "Raptor". For a short while, the aircraft was also dubbed "SuperStar" and "Rapier".^[38] The F-35 later received the Lightning II name on 7 July 2006.^[39]

The prototype YF-22 won a fly-off competition against the Northrop/McDonnell-Douglas YF-23 for the Advanced Tactical Fighter contract. In April 1992 during flight testing after contract award, test pilot Tom Morgenfeld escaped without injury when the first YF-22 prototype that he was flying crashed while landing at Edwards Air Force Base in California. The cause of the crash was found to be a flight control software error that failed to prevent a pilot-induced oscillation.^[40]

 

The F-22 Raptor To The F/A-22 & Back

 

The production model was formally named F-22 "Raptor" when the first production-representative aircraft was unveiled on 9 April 1997 at Lockheed-Georgia Co., Marietta, Georgia. First flight occurred on 7 September 1997.

In September 2002, Air Force leaders changed the Raptor’s designation to F/A-22. The new designation, which mimicked that of the Navy’s F/A-18 Hornet, was intended to highlight plans to give the Raptor a ground-attack capability amid intense debate over the relevance of the expensive air-superiority jet. This was later changed back to simply F-22 on 12 December 2005. On 15 December 2005, the F-22A entered service.^[41]

 

Testing

 

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An F-22 refuels from a KC-135; the attachment on the back top is for a spin recovery chute

Testing of the F-22 began in 1997 and has been curtailed to save program costs, but risks hiding flaws until a point at which fixing flaws becomes unaffordable.^[42] The US General Accounting Office cautioned, "Moreover, engine and stealthiness problems already disclosed by the DoD, and the potential for avionics and software problems, underscore the need to demonstrate the weapon system’s performance through flight testing before significant commitments are made to production."^[42]

Raptor 4001 was retired and sent to Wright-Patterson AFB to be fired at for testing the fighter's survivability. Usable parts of 4001 would be used to make a new F-22. Another EMD F-22 was also retired and likely to be sent to be rebuilt. A testing aircraft was converted to a maintenance trainer at Tyndall AFB.^[43]

On 3 May 2006, a report was released detailing a problem with a forward titanium boom on the aircraft that was not properly heat treated. Officials are still investigating the problem which was caused by the boom portion not being subjected to high temperatures in the factory for long enough, causing the boom to be less ductile than specified and potentially shortening the lives of the first 80 or so F-22s. Work is underway to restore them to full life expectancy.^[43]

The F-22 fleet underwent modifications at Hill AFB,^[44] and at Edwards AFB near Palmdale, California.

 

 

Recent Developments

 

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An F-22 observes as an F-15 Eagle banks left. The F-22 is slated to replace the F-15C/D.

In 2006, the Raptor's development team, composed of Lockheed Martin and over 1,000 other companies, plus the United States Air Force, won the Collier Trophy, American aviation's most prestigious award.^[45] The U.S Air Force will acquire 183 F-22s which will be divided among seven squadrons.^[4]

During Exercise Northern Edge in Alaska in June 2006, the F-22 downed 108 adversaries with no losses in simulated combat exercises.^[46]

While attempting its first overseas deployment to the Kadena Air Base in Okinawa, Japan, on 11 February 2007, a group of six Raptors flying from Hickam AFB experienced multiple computer crashes coincident with their crossing of the 180th meridian of longitude (the International Date Line). The computer failures included at least navigation (completely lost) and communication. The fighters were able to return to Hawaii by following their tankers in good weather. The error was fixed within 48 hours and the F-22s continued their journey to Kadena.^[47][48]

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F-22 with pitot boom

On 30 April 2007, the National Museum of the Air Force announced that EMD Raptor 91-4003 will be put on display in the space being occupied by the YF-22 sometime in 2008. That particular Raptor is being refurbished in the restoration area of the Museum. There are plans to move the YF-22 to another museum and that will be decided in due time by the National Museum of the Air Force.

In 2007, tests carried out by Northrop Grumman, Lockheed Martin, and L-3 Communications enabled the AESA system of a Raptor to act like a WiFi access point, able to transmit data at 548 Megabit/sec and receive at Gigabit speed; far faster than the current Link 16 system used by US and allied aircraft, which transfers data at just over 1 Megabit/sec.^[49]

On 12 December 2007, the USAF officially declared the F-22 fully operational, three years after the first F-22 Raptor arrived at Langley Air Force Base.^[50][51] On 22 November 2007, F-22A Raptors of the 90th fighter squadron performed their first intercept of two Russian Tu-95MS 'Bear-H' bombers in Alaska. This was the first time that F-22s had been called to support a NORAD mission.^[52]

 

 

Varbut was cut in 1996 to save development costs.[53]

 

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Another more recent proposal is the FB-22, which would be used as a deep strike bomber for the USAF, but there has yet to be any word on whether the USAF plans further development of the program. Also, the X-44 MANTA, short for Multi-Axis, No-Tail Aircraft, is an experimental aircraft which itself is an F-22 with enhanced thrust vectoring controls and no aerodynamic backup (i.e. the aircraft is controlled solely by thrust vectoring, without rudders, ailerons, or elevators). It is scheduled to be tested some time in 2007.

 

Operators

• Air Education and Training Command
  • 325th Fighter Wing
    • 43d Fighter Squadron - The only USAF squadron to operate F-22As at Tyndall AFB, Florida. The 43d was re-established at Tyndall in 2002, and, in 2003, with a corps of 15 Raptor Instructor Pilots, began training student Raptor pilots. The 43d continues to produce new Raptor pilots and serves as the focal point for all F-22 training of pilots and maintainers.
• Air Combat Command
  • 1st Fighter Wing Langley Air Force Base, Virginia.
    • 27th Fighter Squadron - The first deployable F-22 unit in December 2005 after receiving sufficient numbers of trained Raptor pilots and flew the first F-22A operational mission (January 2006 in support of Operation Noble Eagle). They deployed to Kadena Air Base with a complement of 250 Airmen and 12 F-22s.^[54]
    • 94th Fighter Squadron - Full complement as of 19 January 2007.^[54]
  • 53d Wing Eglin Air Force Base, Florida.
    • 422d Test and Evaluation Squadron - The "Green Bats" are responsible for operational testing, tactics development and evaluation for the F-22.
• Air Force Material Command
  • 412th Flight Test Squadron - Conducts developmental tests of F-22 enhancements and modernization.
• Pacific Air Forces
  • 3d Wing Elmendorf Air Force Base, Alaska.
    • 90th Fighter Squadron - Conversion from F-15Es to F-22s begun; first F-22A arrived 8 August 2007.^[55][56]
    • 525th Fighter Squadron - Not activated yet.
    • 302d Fighter Squadron - An Air Force Reserve Command squadron that will convert from F-16s at Luke Air Force Base and move to Elmendorf AFB.
• Air National Guard
  • 192nd Fighter Wing - Virginia Air National Guard. Transitioned from F-16s based in Richmond International Airport, Richmond, VA to F-22s based at Langley AFB, Virginia.

Future bases and units will include:

• 199th Fighter Squadron, Hickam AFB, Hawaii.
• 531st Fighter Squadron, Hickam AFB, Hawaii.
• 49th Fighter Wing, Holloman AFB, New Mexico.

 

Specifications  (F-22 Raptor)

 

Contractors

Click on Picture to enlarge

Lockheed Martin Aeronautical Systems: F-22 program management, the integrated forebody (nose section) and forward fuselage (including the cockpit and inlets), leading edges of the wings, the fins and stabilators, flaps, ailerons, landing gear and final assembly of the aircraft. Lockheed Martin Tactical Aircraft Systems: Center fuselage, stores management, integrated navigation and electronic warfare systems (INEWS), the communications, navigation, and identification (CNI) system, and the weapon support system. Boeing: wings, aft fuselage (including the structures necessary for engine and nozzle installation), radar system development and testing, avionics integration, the training system, and flight-test development and management. Pratt & Whitney: F119-PW-100 engines that power the Raptor.

Major Subcontractors

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Approximately 240 firms in 37 states are considered major subcontractors More than 1,150 firms in 46 states and Puerto Rico, along with firms in seven international countries make up the F-22/F119 subcontractor team. (partial list): Northrop Grumman Texas Instruments Kidde-Graviner Ltd. Allied-Signal Aerospace Hughes Radar Systems Harris Fairchild Defense GEC Avionics Lockheed Sanders Kaiser Electronics Digital Equipment Corp. Rosemount Aerospace Curtiss-Wright Flight Systems Dowty Decoto, EDO Corp. Lear Astronics Corp. Parker-Hannifin Corp. Simmonds Precision Sterer Engineering TRW XAR Motorola Hamilton Standard Sanders/GE Joint Venture Menasco Aerospace

 

General characteristics

Click on Picture to enlarge

USAF poster overview of key features and armament

• Crew: 1
• Length: 62 ft 1 in (18.90 m)
• Wingspan: 44 ft 6 in (13.56 m)
• Height: 16 ft 8 in (5.08 m)
• Wing area: 840 ft² (78.04 m²)
• Airfoil: NACA 64A?05.92 root, NACA 64A?04.29 tip
• Empty weight: 31,700 lb (14,379 kg)
• Loaded weight: 55,352 lb (25,107 kg)
• Max takeoff weight: 80,000 lb (36,288 kg)
• Powerplant: 2× Pratt & Whitney F119-PW-100 Pitch "Thrust" vectoring turbofans, 35,000+ lb (156+ kN) each

Performance

• Maximum speed:
   
  • At altitude: Mach 2+^[58][59] (1,325+ mph, 2,132+ km/h)
  • Supercruise: Mach 1.72 (1,140 mph, 1,825 km/h)^[1][57] at altitude
• Combat radius: 410 nmi^[57] (471 mi, 759 km)
• Ferry range: 2,000 mi (1,738 nmi, 3,219 km)
• Service ceiling 65,000 ft (19,812 m)
• Wing loading: 66 lb/ft² (322 kg/m²)
• Thrust/weight: 1.26
• Maximum g-load: -3.5/+9.5 g

Armament

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• Guns: 1× 20 mm (0.787 in) M61A2 Vulcan gatling gun in starboard wing root, 480 rounds
• Air to air loadout:
  • 6× AIM-120 AMRAAM
  • 2× AIM-9 Sidewinder
• Air to ground loadout:
  • 2× AIM-120 AMRAAM and
  • 2× AIM-9 Sidewinder and one of the following:
    • 2× 1,000 lb (450 kg) JDAM or
    • 2× Wind Corrected Munitions Dispensers (WCMDs) or
    • 8× 250 lb (110 kg) GBU-39 Small Diameter Bombs

• Note: It is estimated that internal bays can carry about 2,000 lb (910 kg) worth of bombs, and/or missiles. Four external hardpoints can be fitted to carry weapons or fuel tanks, each with a capacity of about 5,000 lb (2268 kg), while compromising, to a certain extent, the aircraft's stealth. Some armament is still largely classified. Aircraft in this size class since the F-105 have historically met a requirement of carrying maximum external payloads in the range of 14,000-15,000 lb with combat loads typically closer to 4,000-8,000 lb

   

Avionics

• RWR (Radar warning receiver): 250 nmi (463 km) or more^[28]
• Radar: 125-150 miles (200-240 km) against 1 m² targets (estimated range)^[26]

 

Popular Culture

The F-22 has been featured in numerous books, such as Tom Clancy's Debt of Honor (1994) ^[60] and Fighter Wing (1995)^[61] as well as Clive Cussler's Dark Watch (2005).^[62]

The F-22 made its first major Hollywood debut in the 2007 film "Transformers"^[63] as the form taken by the Deception character Starscream.^[64] The film was allowed to film actual Raptors in flight, unlike previous computer generated appearances, because of the military's support of director Michael Bay. The Raptors were filmed at Edwards Air Force Base.^[65]

 

References

Notes

1. "USAF Fact sheets: F-22A Raptor." United States Air Force. August 2007, Access date: 21 September 2007.
2. "Lockheed Martin Awarded Additional $5 Billion in Multiyear Contract to Build 60 F-22 Raptors", Aviation Today, 31 July 2007.
3.  Shamim, Asif. "Lockheed Martin delivers 100th F-22 to the USAF." F-16.net, 29 August 2007. Access date: 26 October 2007.
4. Lopez, C.T. "F-22 excels at establishing air dominance." Air Force Print News, 23 June 2006.
5. "FY 2008/2009 Budget Estimates." United States Air Force. February 2007.
6. "USAF F-22 Raptor fact sheet"
7. Houston, A. "Strategic Insight 9 - Is the JSF good enough?." Canberra:Australian Strategic Policy Institute18 August 2004.
8. Pike, J. "F-22 Raptor Flight Test." GlobalSecurity.org.
9. US Department of Defense contracts, 31 July 2007.
10. "Senators demand more F-22 fighters", Yahoo news, 9 November 2007.
11. "Pentagon Plans for more F-22s", Forbes, 7 December 2007.
12. Bennet, J.T. "Air Force Plans to Sell F-22As to Allies." InsideDefense.com, 18 February 2006.
13. Carmen, G. "Rapped in the Raptor: why Australia must have the best." The Age, 2 October 2006.
14. Beazley, K.. "Media Statement." Australian Labor Party, 26 June 2006.
15. Landers, K. "Australia to buy 100 Lockheed jet fighters." The World Today, 27 June 2006.
16. Brogo, A. "A Big Deal: Australia's future air combat capability." Australian Strategic Policy Institute (Canberra) , 25 February 2004. p. 62.
17. "Israel Plans to Buy Over 100 F-35s"
18. Bruno, M. "Appropriators Approve F-22A Multiyear, But Not Foreign Sales." Aerospace Daily & Defense Report. 27 September 2006.
19. Stewart, C. "US rules out deal on F-22 Raptor fighter jets." News.com.au. Access date: 14 February 2007.
20. Williams 2002, p. 10.
21. Pace, p. 12-13.
22. Carlson, Maj. Gen. Bruce. "Subject: Stealth Fighters." U.S. Department of Defense Office of the Assistant Secretary of Defense (Public Affairs) News Transcript. Access date: 16 July 2007.
23. Powell, 2nd Lt. William "General Jumper qualifies in F/A-22 Raptor" Air Force Link, 13 January 2005.
24. Fulghum, D.A. and Fabey, M.J. "Turn and Burn." Aviation Week & Space Technology. 8 January 2007.[1].
25. Peron, L. R. "F-22 Initial High Angle-of-Attack Flight Results." Air Force Flight Test Center. (Abstract.)[2].
26. Fulghum, D.A and Fabey, M.J. "F-22: Unseen and Lethal." Aviation Week & Space Technology. 8 January 2007. "Raptor Scores in Alaskan Exercise" (online edition).
27. Klass, Philip J. "Sanders Will Give BAE Systems Dominant Role in Airborne EW." Aviation Week & Space TechnologyVolume 153, issue 5, 31 July 2000. p. 74.
28. Sweetman, Bill. "Fighter EW: The next generation." Journal of Electronic Defense, Volume 23, issue 7, July 2000. p. 41-47.
29. JSF-Raptor Radar Can Fry Enemy Sensors
30. Pike, J. "F-22 Avionics." GlobalSecurity.org.[3].
31. Philips, E.H. "The Electric Jet." Aviation Week & Space Technology. 5 February 2007.
32. "USAF Almanac." Air Force Magazine. May 2006.
33. "U.S. orders two dozen raptors for 2010." United Press International. 22 November 2006.
34. "F-22 Stealth." Globalsecurity.org. [4] |accessdate=2007-02-21
35. F-22 team, responsibilities
36. Fulghum, D.A. "Away Game." Aviation Week & Space Technology. 8 January 2007.
37. "YF-22/F-22A comparison diagram". GlobalSecurity.org.
38. Military Aircraft Names
39. "Lockheed Martin Joint Strike Fighter Officially Named 'Lightning II.'" Official Joint Strike Fighter program office press release. 7 July 2006.
40. F-22 Timeline
41. "U.S. To Declare F-22 Fighter Operational." Agence France-Presse. 15 December 2005.[5].
42. "Tactical Aircraft: Concurrency in Development and Production of F-22 Aircraft Should Be Reduced." General Accounting Office. April, 1995.
43. "Tyndall AFB receives F-22 maintenance trainer." 325th Fighter Wing Public Affairs. 29 April 2006.
44. "Hill begins modifications on F-22A Raptor."
45. "F-22 Raptor Wins 2006 Collier Trophy." National Aeronautic Association.
46. "F-22 excels at establishing air dominance", US Air Force, June 23, 2006.
47. "Lockheed's F-22 Raptor Gets Zapped by International Date Line." Daily Tech, 26 February 2007. [6].
48. Raptors arrive at Kadena
49. "F-22 superjets could act as flying Wi-Fi hotspots." The Register. [7]
50.  "US Air Force: Raptor Stealth Fighter Jet Fully Operational"
51. "F-22s at Langley receive FOC status"
52. "Raptors Perform First Intercept of Russian Bombers
53. Pace 1999, p. 28.
54. "Langley receives last Raptor, completes fleet." [8]. Access date: 20 January 2007.
55. "Lockheed Martin F-22 Raptor Air Dominance Fighters Begin Operational Service In Alaska", Lockheed Martin, 8 August 2007
56.  "Elmendorf welcomes F-22 Raptor ", USAF Press, 8 August 2007
57. "Flight Test Data." Access date: 18 April 2006.
58. Pace, 1999
59. USAF F-22 Fact sheet on Archive.org, June 2007.
60. Clancy, Tom. Debt of Honor. Thorndike, Maine: Thorndike Press, 1994. ISBN 0-7862-0335-8. A lengthy mission by F-22s dominates the last part of the book.
61. Clancy, Tom. Fighter Wing: A Guided Tour of an Air Force Combat Wing. New York: Berkley Books, 1995. ISBN 0-425-14957-9. The F-22 features as a major new combat aircraft in the non-fiction book.
62. Cussler, Clive. Dark Watch. New York: Berkley Books, 2005. ISBN 0-425-20559-2. In the book, an F-22 embarks on a secret mission to take out a Syrian foe.
63. Donna Miles for American Forces Press Service (21 June 2007). Movie makers team with military to create realism.
64. Transformers Movie Buzz (18 June 2007). Transformers Bio: Starscream (Decepticon) (blog).
65. Michael Bay's DVD audio commentary for Transformers, 2007, Paramount/DreamWorks

Bibliography

• Crosby, Francis. Fighter Aircraft. London: Lorenz Books, 2002. ISBN 0-7548-0990-0.
• Miller, Jay. Lockheed Martin's Skunk Works: The Official History... (updated edition). Leicester, UK: Midland Publishing Ltd., 1995. ISBN 1-85780-037-0.
• Pace, Steve. F-22 Raptor. New York: McGraw-Hill, 1999. ISBN 0-07-134271-0.
• Pace, Steve. X-Fighters: USAF Experimental and Prototype Fighters, XP-59 to YF-23. Oscela, Wisconsin: Motorbooks International, 1991. ISBN 0-87938-540-5.
• Williams, Mel, ed. Superfighters: The Next Generation of Combat Aircraft. London: AIRtime Publishing Inc., 2002. ISBN 1-880588-53-6.

Wikipedia

 

 

Lockheed Martin F / A-22 Raptor

 

Joe Baugher

Click on Picture to enlarge

The F/A-22 Raptor has its origin as far back as the early 1970s with a Tactical Air Command (TAC) study known as TAC-85. In 1969-70, even before the F-15, F-16 and A-10 had entered service with the USAF, the TAC-85 study begin exploring the question of what their successor might look like. The results of this study led to TAC issuing a Concept of Operations in 1971 for what they called the Advanced Tactical Fighter (ATF).

At that time, the ATF concept was still fairly vague, and there were only some relatively small-scale studies that were carried out during the early 1970s. In early 1975, the USAF Systems Command actually developed a plan to build two sets of ATF prototypes in 1977-81, but there was no money available to fund such a project at that time.

In 1978, the USAF split the ATF concept into two separate projects, one known as the Enhanced Tactical Fighter (ETF) and the other known as the Advanced Tactical Attack System (ATAS). The ETF would be a near-term project, whereas the ATAS would be a longer-term project which would concentrate on the development of new weapons and other advanced technologies. Initially, the emphasis was to be on the ground-attack mission, since it was assumed that the F-15 and F-16 would be able to deal adequately with the Soviet fighters then in service. However, the appearance of new Soviet fighters such as the MiG-29, Su-27, and the MiG-31 caused the USAF to reconsider its philosophy and to contemplate the development of air-to-air and air-to-ground aircraft in parallel. In April of 1980, the ETF project was shelved, and the ATAS project was redesignated the ATF. It was hoped that both air-to-air and air-to-ground roles could be incorporated in the same aircraft. In addition, it was decided that the possibility of incorporating Short Take-Off and Landing (STOL) capability into the design should also be explored.

The first Request For Information (RFI) for the Advanced Tactical Fighter was issued to the industry in June of 1981. In the RFI, nine companies were invited to submit bids: Boeing, Fairchild, General Dynamics, Grumman, Lockheed, McDonnell Douglas, Northrop, Rockwell, and Vought. An RFI for the engine was issued a month later. Since the USAF had really not yet decided on what kind of aircraft they wanted, RFI was basically a request from the Air Force for the industry to tell them what the requirements for the new aircraft should be.

Seven companies actually responded to the RFI. By October 1982, the USAF had digested the RFI responses that came in and decided that super cruise capability should be an important requirement for the future ATF. NATO commanders had expressed pessimism about the survivability of its forward-based fighter and attack forces in the event that a war broke out in Europe. Control of the skies above central Europe would probably have to be maintained by fighters based in the Benelux countries or in the United Kingdom. In such a scenario, the ability of an aircraft to fly at supersonic speed without afterburning and thus to fly supersonically for the entire mission segment that lay over hostile territory would, it was hoped, reduce the fighter's exposure to enemy SAMs. It was also recommended that the aircraft should have a greater range than that of the F-15, which would allow it to operate from more distant, safer airbases. Short Take-Off and Landing (STOL) capabilities would also be important, since STOL would make it easier to continue operations from damaged airfields.

In addition, the Air Force wanted an attempt to be made to reverse the trend of rapidly increasing cost and complexity that seemed to occur with every new generation of fighters. In support of this goal, the Air Force wanted to set a limit on the size and weight of the ATF aircraft, and strongly recommended the use of new technology to reduce the cost of acquiring and supporting the new fighter.

By the early 1980s, the air-to-ground mission for the ATF began to appear less urgent, since the projected F-117A "stealth fighter" that was currently under development should be able to penetrate the air defenses of the Warsaw Pact in the event of a European war. Also, the F-111 would, it was thought, still remain effective even into the 1990s. In addition, General Dynamics and McDonnell Douglas had both demonstrated that both the F-15 and F-16 fighters could be successfully modified into strike aircraft, which meant that it would probably be safe to optimize the ATF for an air-to-air role. By mid-1983, the USAF had adopted this philosophy and had reoriented the ATF concept as a primarily air-to-air fighter, and had defined the ATF concept as an F-15 replacement that would be capable of supersonic flight without afterburning, with a greater range than the F-15 but with a similar armament, and with thrust vectoring and reversing engine nozzles provided for STOL performance.

At that time, it was anticipated that the ATF would be ready in time to start entering service in the late 1990s, with the ATF being the primary fighter in service with the USAF by the time the new century began.

In October of 1982, representatives from most of the American fighter manufacturers met with USAF representatives in Anaheim, California to discuss the ATF project. They came up with a concept for an aircraft capable of supersonic cruise performance, a combat radius of 600-800 nautical miles, and the ability to take off and land in a 2000-foot runway. The normal takeoff weight should be no greater than 60,000 pounds in the air-to-air mission and 80,000 pounds for the strike mission. In late 1982, a Request For Proposals (RFP) was issued for the Concept Definition Investigation (CDI) stage of the ATF program. It was still hoped that the ATF could be introduced into service by the mid-1990s.

In May of 1983, the final RFP for the CDI phase was issued. At that time, the ATF project was still in the "white" unclassified world, and a lot of the project officers working on the ATF were unaware of the "black" stealth technology that was being developed. Once this project officers were made aware of this work, the ATF RTP was amended to include the incorporation of stealth technology.

In September 1983, concept definition contracts were issued to all of the companies which had responded to the RFP-Boeing, General Dynamics, Lockheed, McDonnell Douglas, Northrop, and Rockwell. The final reports were expected by May 1984.

A parallel program was initiated for the engine that would power the ATF, the project being known as the Joint Advanced Fighter Engine (JAFE). In May of 1983, even before it had released the RFP for the aircraft itself, the Air Force released its Request For Proposals (RFP) for the development of the engines for the ATF. The power plant for the ATF had to be self-starting, with autonomous ground check-out equipment based around very high thrust/weight ratios and high reliability values.

In September of 1983, Pratt & Whitney and General Electric were awarded contracts to design and build engines for the ATF. The Pratt & Whitney engine was known as the PW5000 by the manufacturer and as F119 by the Air Force. The General Electric engine was known as the GE37 by the company and as F120 by the Air Force. The engines were to be interchangeable in the ATF airframe, leaving either one of them to be applicable to the definitive fighter. There was to be a contest between these two manufacturers to see which one of them would build the engine for the production ATF.

By the end of 1984, the ATF requirement had reached a more definitive form. The requirement now called for a fighter with a Mach 1.5 cruising speed, a takeoff roll of only 2000 feet, a gross takeoff weight of no greater than 50,000 pounds and a combat radius of more than 700 nautical miles. The aircraft was to be capable of performing 5g turns at Mach 1 and 6g turns at Mach 1.5 at 30,000 feet. At 10,000 feet, the ATF was to be capable of pulling instantaneous turning acceleration loads as high as 9 gs at Mach 0.9 and was to be capable of performing sustained 2g turns at Mach 1.5 at 50,000 feet. At sea level, the ATF was to be capable of accelerating from Mach 0.6 to Mach 1.0 in 20 seconds. At 20,000 feet or 30,000 feet, the aircraft was to be capable of accelerating from Mach 0.8 to Mach 1.8 in 50 seconds. The unit flyaway cost was to be no more than $40 million in 1985 dollars (later reduced to only $35 million), and the life-cycle cost was to be no more than that of the F-15.

At first, the USAF wanted to develop the ATF through a "Demonstration and Validation" (Dem/Val) process rather than by having a flyoff competition between prototypes as was done in the case of the LWF contest that resulted in the F-16. The Dem/Val process would cover everything short of flight testing. Complete avionics systems would be tested in simulators, and the design would be tested in wind tunnels and on radar cross-section ranges. Full-scale mockups would be built, but flyable aircraft would not be. The winner of the Dem/Val phase would then be awarded a full-scale development (FSD) contract for a flyable aircraft.

In September of 1985, the Air Force issued a full Dem/Val Request for Proposals (RFP) for the ATF, specifying a submission deadline of January of 1986. At this time, the Air Force indicated the possibility of a procurement buy of as many as 750 aircraft. As part of the Dem/Val approach, full and reduced scale wind tunnel models would be built, with computational analysis being made of radar cross sections for low visibility. The deadline for the response to the RFP was later extended to April of 1986.

All seven competitors responded to the Dem/Val RFP. Boeing proposed a V-tailed, diamond-shaped wing design with a single shark-mouth chin-type intake to feed both engines. General Dynamics proposed a delta-winged design that reflected some of the work it had done on the F-16XL. There were two intakes, one located on each of the fuselage sides, just ahead of the leading edge of the wing. There was a single large vertical tail. There were two separate radar arrays fitted behind the cockpit, one over each of the air intakes. Lockheed's design closely paralleled that of the F-117 that was currently under development. It had an arrowhead planform and a leading-edge glove which extended in a straight line to the nose. It had conventional trapezoidal wings, vectored thrust, and a horizontal tail. The design had an internal weapons bay, and featured twin outward-canted vertical tails. The McDonnell Douglas design had a single wedge-shaped chin inlet and sharply swept wings. Northrop's design had a diamond-shaped wing and an internal weapons bay, but did not have thrust vectoring. The Rockwell design had a large, highly blended delta wing. The Grumman design has never been described in any detail, but might have featured a forward-swept wing.

In April of 1986, the US Navy decided to get involved in the ATF program, and agreed that they would use the ATF as the basis for a replacement for the F-14D Tomcat. At the same time, it was agreed that the Air Force would develop an F-111 replacement from the Navy's Advanced Tactical Aircraft (ATA) program. The concept of a navalized ATF was especially attractive to a Congress that was keen to extract maximum utilization from an already strained defense budget.

In May of 1986, the USAF changed its mind and announced that instead of proceeding toward a single contractor at the end of the Dem/Val phase, two contractors would be selected to build prototypes for flight test. The two winning contractors would then compete against each other for a Full Scale Development (FSD) contract. The Packard Commission had strongly advocated the flight testing of prototypes in military procurement contests, and the USAF was under strong pressure to accept its recommendations, with the cost overruns and delays involved in the C-5A and F-111 projects being still fresh in the memories of many.

At first sight, Lockheed would seem to be an unlikely entrant into the ATF contest, and even less likely to have won. Lockheed had not built a successful fighter aircraft since the F-104 Starfighter of the mid-1950s. It is true that Lockheed had successfully integrated the first lookdown pulse-Doppler radar and shoot-down missile into the YF-12, but the company had not been a contender in the F-15 competition. However, Lockheed's Advanced Development Projects Division, better known as the "Skunk Works", had made a series of breakthroughs in low-observability technology during the mid-1970s. These culminated in the Senior Trend low-observabile strike aircraft, which eventually emerged as the F-117A Nighthawk.

One of the first responses by Lockheed to the RFI had been a proposal for a high-altitude, highly supersonic aircraft that would be able to cruise well above its adversaries and shoot them down with long-range missiles. This concept was rejected as being too costly. In 1984-85, the Skunk Works went to work to see if it was possible to combine the newly-emergent stealth technology with supersonic speed and excellent maneuverability, something that was considered virtually impossible at the time. However, advances in computer technology had made it possible to do the mathematical modeling and simulations that were needed to design a stealthy aircraft which was also supersonic and capable of good maneuverability. The computers of the mid-1970s could only model the radar-scattering properties of flat surfaces, but the Cray supercomputer of the 1980s made it possible to handle the much more complex problem of curved surfaces. In addition, much more capable radar absorbent materials (RAM) were now available.

Early in 1985, before the final Dem/Val RFP was issued, Lockheed decided that it was unlikely that it could win the competition for full-scale development all by itself. In June of 1986, it was announced that Lockheed would form a team with Boeing and General Dynamics to develop an ATF entry. It was agreed that the company whose design won the Dem/Val contest would lead the team. Boeing would seem to be as unlikely an entrant in the ATF contest as Lockheed--Boeing had never built a manned supersonic aircraft nor had it ever even built a jet fighter, the company having specialized since the early 1930s in bombers, transports, tankers, and large commercial airliners. The last fighter built by Boeing was the unsuccessful F8B carrier-based fighter of World War 2 vintage. However, Boeing had always recognized that there was a large market for tactical fighters and had kept a design team working on these types of aircraft all throughout the 1970s.

At the same time, Northrop had announced that it would be teaming with McDonnell Douglas in the ATF competition.

Seven manufacturers responded to the RFP--Boeing, General Dynamics, Grumman, Lockheed, McDonnell Douglas, Northrop, and Rockwell. Grumman and Rockwell pulled out of the competition at an early phase. On October 31, 1986, Lockheed and Northrop were announced as the winners and were awarded contracts for the demonstration and validation phase of the program. Each group was to build two flyable prototypes. The designation YF-22A was assigned to the aircraft that would be built by the Lockheed-led team, with YF-23A being assigned to the plane to be built by the Northrop-lead team. Each aircraft would be capable of flying with either a pair of Pratt & Whitney F119 or a pair of General Electric F120 engines. At the completion of the competition, one of the teams would be awarded a Full-Scale Development (FSD) contract.

In 1987, the requirement for the use of thrust reversers was eliminated. The thrust reversers were designed to be used in flight, for deceleration in combat, and for speed control during approach and landing. During development, tests with the F-15 STOL/Maneuver Technology Demonstrator had found that these thrust reversers would be heavier and would require more cooling air than had been predicted. Consequently, late in 1987, the thrust reversers were eliminated from the ATF requirements. Without thrust reversers, the aircraft would land in 3000 feet rather than the 2000 feet that had been originally specified, but the additional weight and complexity needed for the extra 1000 feet of stopping space were deemed not to be worth the cost.

Lockheed assumed responsibility for the overall design of the YF-22A, and was to supply the forward part of the fuselage, including the cockpit. It would also handle most of the specialized stealth development work. Lockheed would also handle the final assembly in its facility at Palmdale, California. Boeing would build the wings and the aft fuselage and would install the engines. General Dynamics of Fort Worth, Texas would handle the center fuselage, the weapons bays, the empennage, and the undercarriage. The entire team would build a complete avionics system.

In mid-1987, the YF-22A design had to be significantly changed because of weight problems. A diamond-shaped wing replaced the less-tapered trapezoidal wing that had originally been planned. The long glove extending all the way to the nose was eliminated, since wind tunnel testing had revealed that the pitch-up forces generated by the glove could not be controlled by the tail surfaces. In addition, the horizontal tails were enlarged in area. The originally-proposed rotary weapons bay was replaced by a flat weapons bay. This redesign coincided with the elimination of the thrust reversers, which meant that the fuselage afterbody could now be made slimmer and lighter.

These extensive redesigns meant that the YF-22A would have to be delayed. By early 1989, it became clear that the YF-22A would not be ready to fly by the beginning of 1990. However, the Air Force agreed to extend the demonstration and validation program by six months.

In 1988, declining budgets forced the Air Force to cut the number of tactical fighter wings from 38 to 35. In 1988, USAF modernization plans now included 750 ATFs, to be delivered at a rate of 72 per year. Following the FSD go-ahead scheduled for 1991, deliveries of the first FSD aircraft were to begin during 1993, with the first aircraft entering service with the USAF in 1996. By late 1988, the ATF program had been extended by one year and the USAF declared a pilot production lot of 24 aircraft.

A draft request for proposals on the FSD phase was issued during August of 1989. On October 6, 1989, the Defense Acquisition Board approved a six-month delay in early design work, extending the Dem/Val phase to mid-1991. This delayed the FSD phase by one year. The Air Force agreed to issue the RFP for FSD at the end of October 1990 and to move to FSD in April 1991, at which time a single contractor would be selected.

The aircraft that finally emerged from the Lockheed/Boeing/General Dynamics team had a forward fuselage that was essentially diamond-shaped in cross-section, merging into a pentagonal mid-fuselage and a tapered flat rear fuselage. The body shape was designed with large flat sides which reflected the "faceting" philosophy that was used in the F-117A. However, the facet breaks are not nearly as sharp as they are on the F-117A, the facets are fewer in number, and curved surfaces are used on the aerodynamic surfaces and above and below the fuselage. The use of curved surfaces was made possible by the advent of Cray supercomputers to do the simulation of the radar reflectivity of various geometries. Air intakes flanked a short, tapered nose which accommodated the cockpit and most of the avionics. The inlet ducts curved inwards and upwards, shielding the front faces of the engines from direct illumination by hostile radars. In the critical front quadrant, it is estimated that the radar cross-section of the YF-22A is about 100 times smaller than that of the F-15.

The aircraft is about the same size as an F-15, but is heavier, weighing about 62,000 pounds in clean condition.

Since variable-geometry intake ramps would be incompatible with stealthy design, the wedge-shaped air intakes were designed to be of fixed geometry with no moving parts. The inlets were of the two-shock variety, and the ramp angles were chosen for optimal efficiency at Mach 1.5. There were spill doors mounted immediately behind the top lip which dump excess air from the inlet at low speeds and low power settings. The intakes ensure low airflow distortion with good recovery and provide low observable characteristics as well as comprehensive boundary layer air bleed. The intakes were offset from the fuselage wall by several inches for effective boundary layer control. S-shaped intake tunnels carried air to the engines, the shape of the intake tunnels being deliberately designed so that the engine faces were completely invisible from any external look-angle. There were a pair of auxiliary blow-in inlets above the body just forward of the vertical tails which provided the engines with extra air for starting and takeoff.

The wing was designed with a diamond-shaped planform, which was actually fairly close to that of a delta with a 48 degree sweep on the forward edge, a nearly straight trailing edge, and a very small tip chord. The sharp taper reduces the bending loads across the wing because most of the lift is generated close to the root. The wing root chord at the fuselage centerline is 34 feet 6 inches, and the wing tip chord is 4 feet 2 1/2 inches. The wing has no twist or pronounced camber, and there are no foreplanes or leading-edge root extensions. Large integral fuel tanks are built into the wing structure.

The wing was fitted with full-span leading edge flaps. The trailing edge has large plain flaps inboard and smaller, tapered flaperons outboard. All of the wing surfaces droop at low speed to reduce takeoff and landing runs.

The forebody of the fuselage was provided with a sharp edge, or hard chine running from the tip of the nose to the upper inlet lip, and there was a small aerodynamic lip attached to the top outside corner of each inlet. These were designed to cause the formation of vortices at high angles of attack. As a result of these chines and lips, at high angles of attack a pair of strong vortices form over the fuselage center section and another pair form over the wings. Because of low pressure inside these vortices, additional lift can be generated, improving the controllability at high angles of attack. However, these vortices can have an adverse affect on the vertical tails-- they can cause aerodynamically buffeting, they can blanket the vertical tails so that they become aerodynamically ineffective, or they can form asymmetrically so that there is a destabilizing effect. Careful computational fluid dynamics calculations using supercomputers were needed to avoid these unwanted side effects.

A large speedbrake was installed on the upper fuselage between the two vertical tails. Like most of the other doors on the aircraft, the airbrake panel had serrated, dogtooth edges to suppress unwanted radar reflections.

The horizontal tail was set on two booms which extend beyond the ends of the engine exhausts. The stabilizers were located in the same plane as the wing and were so close to the wing that the wing and tailplane planforms actually merge smoothly together--the stabilizer leading edges fit neatly into cutouts at the roots of the wing flaps. In accordance with stealth principles, the horizontal tail has the same planform as the wing.

The twin vertical tails were canted outward by 27 degrees. When viewed from the sides, the large fins mask thermal images of the aircraft's tail and engine-exhaust areas and help to block infrared search scans from all but the rear and high elevation angles. The twin vertical tail surfaces are located well forward (like those on the F/A-18). They are unusually massive, and are 70 percent larger than those on the F-15. Because of anticipated problems with structural stresses caused by vortexes from the wing, it was decided not to use an all-flying vertical tail format, and there are two fixed vertical stabilizers with moveable rudders. The rudders account for almost a third of the total area.

Throughout the entire fuselage, all internal and external metal areas were coated with radar absorbent materials (RAM) and with radar absorbent paint (RAP). Considerable progress has been made in this area. When the first F-117A was flown, the RAP was expensive to apply and came off easily. The design of the various doors that are cut into the sides and top of the fuselage (e.g. for landing gear, weapons stowage, blow-in intakes, maintenance access, etc) posed a major challenge for designers trying to achieve low observability. Serrated edges were added to the doors to reflect radar returns in harmless directions. Intake and cooling vents which must remain open at all times are covered with a low-observable wire mesh to prevent enemy radar emissions from getting inside.

The F-22 was to be powered by a pair of advanced technology engines, mounted close together on the fuselage centerline, between the two booms that carry the tail surfaces. The AFF engines are of an advanced type, designed to make it possible to cruise for extended periods of time at supersonic speeds. Conventional fighter engines reach their compressor-exit temperature (CET) limits at speeds of about Mach 1, because of the rise in inlet temperature and pressure. At higher speeds, the engine must be throttled back to hold down the CET, and the extra thrust must come from the afterburner. The afterburner consumes fuel very rapidly, and supersonic flight must of necessity be fairly brief. In contrast, the ATF engines are designed to run at full throttle at speeds of up to Mach 1.5.

Both the YF119 and the YF120 engines are counter-rotating dual-spool, low bypass turbofans with single turbine disks in both low and high compression stages. Both engines have improved blade aerodynamics and structures, reducing the number of stages as well as the number of parts, and making it easier to cool. Both engines also make use of advanced materials and techniques such as composites, ceramic seals, hollow fan blades, and new heat-resistant coatings. The General Electric YF120 engine was apparently the more advanced of the two. The YF120 is a double-bypass variable-cycle powerplant that operates as a turbofan at subsonic speeds and as a turbojet at supersonic speeds. The F120 engine has a low pressure rotor consisting of a two-stage fan and a single-stage high-pressure turbine with a triplex digital control unit mounted on the power plant itself. The YF119 is based around a conventional cycle with an advanced fuel control and management system. It is basically a low-bypass ratio (0.2 to 1) turbofan. The F119 incorporates a three-stage fan as the low-pressure rotor with a singe-stage high-pressure turbine stage and a six-stage high pressure compressor, also driven by a single-stage turbine. Exit guide vanes are cast as an integral part of the strutless diffusers, and a fully-modulating cooling diffuser is located ahead of the two-dimensional convergent-divergent nozzle.

The two-dimensional engine nozzles of the YF-22A can be vectored 20 degrees up or down at any power setting. Vectored thrust is most effective at high engine power and is most useful at each end of the speed range. Continuous vectored thrust can also be used for high-speed turns (e. g. 6 g at Mach 1.8 is an ATF objective), where horizontal tail authority might not be sufficient. Vectored thrust also improves roll control. An afterburner is incorporated for use in combat or for Mach 2 plus dash speeds.

Combining low-observable technology with the requirement for high maneuverability required the use of fly-by-wire controls. The FBW system for the F-22 was developed by General Dynamics. Air data sensors, rate gyroscopes, and accelerometers feed information into the computer, where it is integrated with inputs from the pilot's controls. The central computer then coordinates the operation of leading-edge flaps, ailerons, tailplanes, rudders, airbrake, and thrust-vectoring nozzles.

Roll and yaw is effected by a combination of differential movement of the ailerons, flaperons, and the tailplane. The rudders also provide directional control and feed coordination functions during complex integrated maneuvers. Pitch control is provided by coupled commands to the tailplane and to the thrust-vectored nozzles. The leading edge surfaces operate automatically according to angle of attack, airspeed, altitude, and data inputs from the FBW system.

There is a receptacle for a boom-type midair refueling probe in the upper fuselage, located between the blow-in auxiliary intake doors that are just forward of the vertical tails. This receptacle is covered by a door when not in use.

In the interest of achieving low-observability, all of the air-to-air weapons are carried internally. There are three weapons bays. Two of the weapons bays are located on the sides of the fuselage (one on each side) immediately aft of the cheek intakes, the rear wall of each bay forming the forward wall of the main undercarriage bays. Each side bay can accommodate two AIM-9 Sidewinder infrared-homing air-to-air missiles and is covered by two separate doors. When a Sidewinder missile is fired, the weapons bay doors snap open, the Sidewinder missile swings outward on a trapeze, the missile's infrared seeker locks onto its target, the missile is fired, the trapeze swings back in and the doors close. The quicker this is done, the less likely it is than an enemy could pick up a radar return from the open weapons bay. A third weapons bay is located underneath the fuselage and can carry four or six AIM-120C AMRAAM radar-guided air-to-air missiles. The main bay is covered by two hinged doors, each consisting of two lengthwise fold-back panels. When an AMRAAM is fired, the door is opened and the missile is dropped. The door can be closed right away, because the missile's engine does not ignite until it drops free of the aircraft. The leading and trailing edges of the main weapons bay doors carry serrated edges for low operability.

Although designed largely for internal weapons carriage in the interest of stealth, the F-22 can be fitted with four external weapons pylons under the wings. These could be used for ferry purposes or for operations in which stealth is unnecessary.

The main landing gear members retract forward into bays in the fuselage sides immediately aft of the side weapons bays underneath the wings. These doors have serrated edges for low radar operability. The steerable nose wheel retracts forward into a well between the air intakes. All three undercarriage units are operated via independent hydraulic rams and each wheel has an anti-skid disc brake unit.

About 23 percent of the structure of the prototypes is made up of composite materials, and it is planned for about 40 percent of the production F-22 to be made of composite materials. Some of the high-temperature structural components are made from carbon fibres embedded in a bismaleimide matrix, which can supposedly tolerate higher thermal stresses then the epoxy materials that are currently used. Wing skins are made from carbon fibers in a thermoplastic matrix. The advantage of thermoplastics is that they can be reheated and reformed, lowering the cost of manufacturing and repairing complex components.

The pilot's cockpit is what has come to be known as a "glass" cockpit. The control panel has no dials or gauges, and all information is presented to the pilot on screens or as holographic images on the heads-up display (HUD). The cockpit has two 8x8 inch primary multifunction displays, flanked by three 6x6 inch secondary MFDs, all in full color. There is a three-color up-front control underneath the HUD. All of the displays are liquid-crystal-display (LCD) panels, which replace the conventional cathode-ray tubes used by previous "glass"-cockpit aircraft. The F-22 is the first military aircraft to feature this technology. At first, the liquid crystal displays were provided with finger-on-glass (FOG) panels, but a lack of tactile feedback during tests led to a decision to revert to pushbutton switches surrounding the screens.

In the production aircraft which will carry a full avionics suite, the primary screens will provide tactical situation information while the secondary screens will provide offensive and defensive systems data. Voice enunciators will present vital advisory and cautionary information to the pilot. It will be arranged so that these voice enunciators will present only the most urgent information and will avoid overloading the pilot with things he or she does not need to know.

Control of all aircraft functions is handled by a hands-on throttle and stick (HOTAS) that gives the pilot access to all the selection modes he or she needs to complete an attack. The YF-22A has a central control column, but this will be replaced by a sidestick controller in production machines.

The cockpit canopy is frameless and is shaped and coated to eliminate radar reflections. The single-piece acrylic laminate canopy was only for the prototypes. Indium tin oxide will be added to the laminate in production machines to reduce the radar return. Great emphasis was placed on the design of the cockpit for low operability, and careful selection of proper materials for the control panel, ejector seat, and canopy was a vital part of achieving a stealthy interior.

The pilot's seat is upright, studies having shown that the inclination would have to be at least 65 degrees to provide any significant benefit to a pilot's g-tolerance. The two YF-22A prototypes have the ACES II ejector seat, but the production machines will have a modified Weber seat.

Not many details have been published about the avionics suite that will be fitted to production F-22s. It is known that the avionics suite will include a Northrop Grumman/Raytheon APG-77 active-array, electronically-scanned radar and a Sanders/General Electric ALR-94 integrated electronic warfare system. The sensor antennae for the ALR-94 system are smoothly blended into the skin, and the system can positively identify the target, determine its bearing and its range. The avionics systems are tied together by a computer system. The radar is designed to provide the pilot with a first-look, first-launch, first-kill capability. It has long range and high resolution for the early detection of enemy fighters. It has a low passive-detection signature which is designed to allow the F-22 to approach very close to its target before being detected. The Lockheed Martin AAR-65 Missile Launch Detector comprising six IR focal plane arrays located around the nose is used to warn of immediate treats from enemy missile launches.

Two YF-22A prototypes had been ordered, one to be powered by a pair of F120 engines and the other to be powered by F119 engines. The first YF-22A was ready by June 1990. However, at that time the General Electric F120 engines that were to power the aircraft had not yet been qualified for flight by the Air Force. Lockheed briefly considered switching its initial efforts to the second prototype, which was to be powered by the competing Pratt & Whitney F119 engine, but decided to stick with the original schedule.

The two YF-22As were integrated and assembled at Lockheed's facility at Palmdale, California. The first YF-22A was officially unveiled at a ceremony at Palmdale on August 29, 1990. Rather unusually, the aircraft bore a civilian registration number N22YF rather than a USAF serial number. It flew for the first time on September 29, 1990, with Lockheed test pilot Dave Ferguson at the controls. It was powered by a pair of General Electric YF120 engines. The first flight was a short hop from Palmdale to Edwards AFB. The flight was considerably shorter than planned because of a minor fault with telemetry equipment which required repair at the end of Palmdale's runway, reducing the fuel load available and curtailing the opportunity to perform a number of tests.

The YF-22A achieved supersonic speed for the first time on October 25.

The second YF-22 followed on October 30, with Lockheed test pilot Tom Morgenfeld at the controls. It bore the civilian registration of N22YX and was powered by a pair of Pratt & Whitney YF119 engines. Neither of the two test aircraft carried any radar, nor were they equipped with cannon armament. However, they were capable of carrying and launching AMRAAM and Sidewinder air-to-air missiles.

Early in November of 1990, YF-22 N22YF achieved one of the important milestones of the ATF program, when it attained a speed of Mach 1.58 without using afterburners. Optimal super cruise speed was Mach 1.58 for N22YF and Mach 1.43 for N22YX. With afterburning, both aircraft could easily exceed Mach 2 at 50,000 feet.

The first thrust-vectoring by the YF-22A was performed by N22YF on November 15, with test pilot Dave Ferguson exploring the roll response enhancement that this feature could afford. With 2-dimensional thrust vectoring, the aircraft could achieve supersonic roll and pitch rates in excess of those that can be achieved by a conventional fighter at subsonic speeds. At speeds above Mach 1.4, the two-dimensional nozzles improved turning rates by about 35 percent. The YF-22A was able to perform maneuvers when it was far beyond the stall angle of attack and could perform bank-to-bank rolls at speeds as low as 80 knots and angles of attack as high as 60 degrees. Enhanced agility at high angles of attack will give the F-22A an important edge over other fighters, allowing weapons lock-on with a conventional aircraft that is unable to avoid flick-pointing. The nozzles give a four-fold improvement in pitch-down nose recovery, allowing the aircraft to resume normal flight attitudes within a second.

On November 28, 1990, YF-22 number two achieved another first for the ATF program when test pilot Jon Beesley test-fired an AIM-9M Sidewinder during a flight over the Navy's China Lake range. On December 20, test pilot Tom Morgenfeld fired an AIM-120 AMRAAM from YF-22 number two during a flight over the Pacific Missile Test Center range at Point Mugu, California.

On April 23, 1991, the Air Force announced that the Lockheed group had won the Demonstration/Validation phase of the ATF contest. At the same time, the Pratt & Whitney F119 entry was selected as the winning engine. On August 3, 1991, the Air Force formally awarded an Engineering, Manufacture, and Development (EMD) contract to the Lockheed team. The first of 11 EMD aircraft (including two F-22B two-seaters) was due to fly in 1995. Initial operating capability (IOC) was set for 2001.

N22YX with its YF119 engines went back into the air on October 30, 1991 for more flight tests. N22YF was stripped of its General Electric engines and was moved to Lockheed's Marietta, Georgia facility for EMD systems mock-up tests.

Unfortunately, N22YX was involved in a major accident on May 25, 1992 when it belly-flopped onto the runway after 8 seconds of violent pilot-induced oscillations. It slid several thousand feet down the runway and caught fire, destroying some 25 percent of the airframe. Pilot Tom Morgenfeld was uninjured, but the aircraft was deemed too badly damaged for economical repair.

At the time of the crash, Morgenfeld had been carrying out a planned go-around, and he had just switched on his afterburners and had retracted his undercarriage at less than 50 feet off the runway with thrust vectoring active. At a speed of 175 knots, the aircraft began an uncommanded pitch up followed by a severe stick-forward command from the pilot. The aircraft then entered a series of pitch oscillations, with rapid tail and thrust nozzle fluctuations, exacerbated by control surface actuators hitting rate limiters causing commands to get out of synchronization with their execution.

An investigation later showed that Morgenfeld had ignored a test-card that required that the vectoring nozzles to be locked into position in just such a configuration that he had found himself at the time of the crash. However, most engineers had also ignored this instruction since they thought it to be unnecessary. At the time of the accident, the aircraft had made some 760 flights and had logged 100.4 hours in the air.

After this accident, no further flight testing of the prototypes was carried out, and the program moved into the EMD phase. The other YF-22 (N22YF) was later stripped of its engines and was used for ground testing. N22YF is now on display at the USAF Museum in Dayton, Ohio.

By early 1992, the definitive shape of the EMD F-22 had been finalized. There were some important changes. The length was reduced to 62 feet 6 inches, the wing span was increased to 44 feet 6 inches, and the wing sweep angle was decreased to 42 degrees. Other edges that had to be aligned with the wing sweep angle for low RCS were also changed to 42 degrees. The wing shape was modified to incorporate a clipped section between the ailerons and the tip. The thickness of the root was decreased and the camber and twist were modified. The engine inlets were moved aft by 1 foot 5 3/4 inches. The entire cockpit was moved further forward, with subsequent changes to the nose and radome profile, giving the forward fuselage a blunter shape. The tail surfaces were modified, with the fin/rudder being decreased in area and the horizontal tail being increased in area. The tail platform was modified to a diamond shape, and the aircraft height was reduced to 16 feet 5 inches.

The production F-22A will carry a single General Electric M61A2 20-mm cannon above and aft of the starboard engine intake. This is an improved, lighter version of the standard M61A1 cannon that has been carried by US fighters since the 1950s. Production F-22s will also have a ground-attack capability, and will be provided with two sets of hard points underneath each wing, although the carriage of external stores will severely degrade the low-observable characteristics of the aircraft. The aircraft will be able to carry a pair of Joint Direct Attack Munitions (JDAM) in the under-fuselage weapons bay and two Tri-Service Stand-Off Attack Missiles (TSSAMs) underneath the wing for deep strike missions. The JDAM is a 1000-lb smart bomb that dispenses infrared/acoustic-guided sub munitions. The early versions of the JDAM will be directed by a GPS guidance system, but this will perhaps be replaced with an image seeker in a later version. The Air Force may even want to equip the F-22 with HARM missiles for anti-radiation missions.

Initial Operational Capability (IOC) has slipped steadily over the years. The decision to build prototypes meant that the Dem/Val program had to be extended for a longer time than expected. Metal for the first EMD aircraft was first cut in December of 1993. By that time, the number of pre-production aircraft on order had been cut to nine. The first three EMD F-22s were be used primarily for airframe tests, and the fourth will be used for avionics tests. The seventh and ninth aircraft were to be two-seat F-22Bs, whereas the eighth was to carry out low-operability tests. The nine EMD F-22A and B aircraft were to be followed by four Pre-Production Verification (PPV) aircraft.

Exactly how many production F-22s will be built is still uncertain, since the deployment plans for the F-22 are continuously in flux because of funding cuts and budgetary uncertainties. The initial 1985 RFP had indicated a requirement for 760 aircraft, but budget cuts and force realignments have steadily reduced the total numbers expected to be built. In 1993, the Pentagon cut the planned F-22 fleet from 648 to 442, and then cut it again to 339 in mid 1997. In July of 1996, the USAF deferred the development of the F-22B two-seater and cut the two F-22Bs from the test program, leaving only seven EMD prototypes.

The first of seven F-22A EMD prototypes (91-4001, c/n 4001, named Spirit of America) was unveiled to the public at the Lockheed Martin plant at Marietta, Georgia on April 9, 1997. It was announced that the name Raptor has been chosen for the aircraft. Raptor 01 (as the plane was labeled) was equipped with a pair of vectoring exhaust Pratt & Whitney F119-PW-100 engines, rated at 35,000 lb.s.t. each with afterburning. It flew for the first time on September 7, 1997. The plane was delivered to Edwards AFB aboard a C-5 transport on February 5, 1998. It was reflown for the first time at Edwards AFB on May 17, 1998.

The second EMD F-22A prototype (91-4002, c/n 4002) was rolled off the production line at Marietta, Georgia on February 10, 1998. It flew for the first time on June 29, 1998, and flew cross-country to Edwards AFB on August 26, 1998 to join 91-4001 in the test program. By the end of 1998, the first two F-22s had been able to reach a speed of Mach 1.4 without afterburning.

The third F-22A (91-4003, c/n 4003) was rolled of the production line in Georgia on May 22, 1999. Technically, this was actually the fourth F-22A off the production line, since the third F-22A (3999) serves as a static test vehicle. 91-4003 flew for the first time on March 6, 2000. The plane was the first of the Block 2 F-22s, which is the first Raptor to have an internal structure that is fully representative of the production version. It also had full-envelope flight capability. The fourth Raptor (91-4004) was to be the first F-22 with fully-integrated avionics

A Boeing 757-200 (c/n 22212, registration N757A) was converted as an avionics laboratory to test the radar and other electronics systems. The aircraft was fitted with an F-22 forward fuselage as well as a sensor wing on top of the fuselage just aft of the flight deck. The 757 testbed flew for the first time on March 11, 1999.

Anxiety over the rising costs of the F-22--along with the general opinion that the threat that it was designed to counter no longer existed and that no current or conceivable future threat justifies the expense--led to a move in Congress to remove six F-22 aircraft from the Air Force FY 2000 budget. In July of 1999, the House of Representatives voted to cut the six F-22s that had been planned for FY 2000 out of the budget and to re-allocate the money to more F-15Es, F-16CJs and C-130Js. However, the Senate readily approved the six FY2000 fighters, and a compromise was reached in conference in which the six F-22As requested would be procured as Production Representative Test Vehicle II (PRTV II) aircraft and not as Low Rate Initial Production (LRIP) aircraft. The procurement of ten LRIP aircraft in FY2001 were to be conditional on the test program attaining successful flight testing of the avionics software as well as a verification of its stealth capabilities. The contract for the six F-22 Production Representative Test Vehicle II aircraft was awarded to Lockheed Martin on December 30, 1999. The first PRTV II aircraft were be delivered by March 2002.

On August 25, 1999, the Raptor achieved flight in excess of 60 degrees angle of attack. Raptor 01 demonstrated its super cruise capability on July 21, 1999 by sustaining Mach 1.5 without afterburner.

On August 15, 2001, the Pentagon's Defense Acquisition Board approved LRIP for the F-22A, but reduced the total order from 339 to 295. Construction began on the first operational aircraft (01-4018) and it was announced that the first 13 Raptors in Lot 2 would enter service with the 325th Wing at Tyndall AFB beginning in 2003. It was announced that some Raptors would go the the 57th Fighter Wing at Nellis AFB for operational development work. The first operational wing would be the 1st FW, based at Langley AFB, VA.

The final flight test aircraft (91-4009) under the Engineering and Manufacturing Development (EMD) phase contract, was delivered to the USAF on Apr 15, 2002. It was dedicated to the evaluation of the ease of maintenance and repair for the Raptor. After these tests were completed, the plane was delivered to Edwards AFB to join the other six F-22s already there.

On April 25, 2002, the latest Block 3.1 avionics software package was flight tested on 91-4006 at Edwards AFB. This software provides more than 90 percent of that required for full functionality in production Raptors.

Alarmed at the high cost of the F-22A program , some people in Congress insisted on an air-to-ground role for the Raptor, and work was initiated in determining if the two internal weapons bay could accommodate air-to-ground weapons such as the GBU-32 JDAM, as well as 1000-pound bombs. In order to keep Congress happy, on September 17, 2002, General John Jumper, the Air Force Chief of Staff, announced that the Raptor was going to be re-designated F/A-22 to indicate the support of a dual-role mission. At that time, the USAF had the goal of acquiring 339 Raptors, although up to 762 Raptors could ultimately be required.

At the same time, Air Force Secretary James Roche announced that the 1st Fighter Wing at Langley AFB would develop a limited air-to-ground mission in addition to its primary air-to-air role. The basic problem is that if the air-to ground mission requires stealth, the Raptor will not be able to carry air-to-missiles in the weapons bay, nor will it be able to carry anything on under wing pylons, thus entirely losing its air-to-air capability. However, if stealth is not required, the aircraft can be equipped with four under wing stations that can carry bombs, missiles, or 600 gallon fuel tanks. Each station can carry up to 5000 pounds of weapons or fuel.

Raptor number 10 (99-4010), the first Production Representative Test Vehicle, was formally accepted by the USAF on October 23, 2002. It was assigned to Edwards AFB to serve with the Air Force Operational test and Evaluation Center to support the Dedicated Initial Operational Test and Evaluation phase.

On November 5, 2002, Lockheed Martin was awarded a contract for Low Rate Initial Production Lot 3, comprising 16 aircraft.

Raptor number 11 (99-4011), the last Dedicated Initial Operational Test and Evaluation aircraft, made its first flight on September 16, 2002 and was formally accepted by the USAF on November 26, 2002. On November 22, aircraft 4007 succeeded in launching an unarmed AIM-9M missile. Also accomplished in 2002 was the interception of an aerial target by an AIM-120 launched from a super cruising F/A-22.

The first F/A-22A Raptor (00-4012) was delivered to Nellis AFB, Nevada on January 14, 2003. A further seven Raptors will are scheduled to join 00-4012 with the 422nd Test and Evaluation Squadron by the end of 2004, with nine more due to join the 57th Wing at Nellis AFB between 2008 and 2009. The Block 4 F-22A is scheduled for introduction into service in 2005. It may turn out that F-22 serves with the USAF for forty years, perhaps not being replaced by some later type until the year 2045.

There ia a proposal for an enlarged derivative of the Raptor, the FB-22. It is intended as a pure bomber and is proposed as a replacement for the B-52, B-1B, and B-2. It will have the same stealth characteristics as the Raptor, but will be able to carry up to 30 small-diameter bombs at supersonic speeds at ranges as high as 2000 miles without the need for midair refueling. This project is at the preliminary concept stage, and time will tell if it ever evolves into anything practical.

Serials of Lockheed Martin F/A-22 Raptor

91-4001/4009		Lockheed F-22A Raptor
				EMD aircraft
99-006/007		Lockheed Martin F-22A Raptor
				PRTV aircraft.  Serials cancelled and replaced
				with 99-4010/4011.
99-4010/4011		Lockheed Martin F-22A Raptor
				c/n 4010/4011.  PRTV aircraft
99-4012/4017		Lockheed Martin F-22A Raptor
				c/n 4012/4017.  IP aircraft
99-4018/4025		Lockheed Martin F-22A Raptor
				c/n 4018/4025.  Reserved for future use
Ten Raptors are included in the FY2001 budget

 

Specification of Lockheed YF-22A

Engines: Two Pratt & Whitney YF119-PW-100 or two General Electric YF120-GE-100 afterburning turbofans, each rated at 35,000 lb.s.t.. Performance (estimated): Maximum speed at military power Mach 1.6 (1059 mph). Maximum speed Mach 2.2 (1450 mph) at maximum power with afterburning at altitude. Maximum speed Mach 1.2 (915 mph) at sea level. Maximum sustained cruising speed above 36,000 feet Mach 1.4-1.5 (925-990 mph). Service ceiling 65,000 feet. 3500 feet takeoff length. 750-800 nautical mile unrefuelled combat radius. Weights: 33,000 pounds empty, 58,000 pounds normal takeoff. 62,000 pounds combat takeoff weight. Dimensions: Wingspan 43 feet 0 inches, length 64 feet 2 inches, height 17 feet 8 7/8 inches, wing area 830 square feet. Four AIM-9 Sidewinder missiles are carried in internal bays in the sides of the engine intake ducts. Four AIM-120 AMRAAM missiles are carried in internal bays underneath the air intakes.

Sources:

1. Lockheed F-22: Stealth with Agility, Bill Sweetman, World Airpower Journal, Volume 6, Summer 1991.
    
2. From ATF to Lightning II: A Bolt in Anger. Design Options and the YF-23A, David Baker, Air International, December 1994.
    
3. From ATF to Lightning II: A Bolt in Anger. Lockheed's YF-22A, David Baker, Air International, January 1995.
    
4. Lockheed Martin F-22 Raptor, Bill Sweetman, World AirPower Journal, Vol 38, Fall 1999.
    
5. Air Intel, Tom Kaminski, Combat Aircraft, Oct-Nov 1999.
    
6. Airscene Headlines, Air International, April 2003.
    
7. Classics Compared: F-86 Sabre and F/A-22 Raptor, Robert F. Dorr, Air International, February 2003.
    
8. Airscene Headlines, Air International January 2003.
    
9. Airscene Headlines, Air International November 2002
    
10. Airscene Headlines, Air International October 2002.
     
11. Airscene Headlines, Air International June 2002.

 

 

 

 

 

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