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AIM-9 Sidewinder

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Sidewinder Missile

The AIM-9 Sidewinder is a heat-seeking, short-range, air-to-air missile carried by fighter aircraft and recently, certain gunship helicopters. It is named after the Sidewinder snake, which detects its prey via body heat and also because of the peculiar snake-like path of flight the early versions had when launched. The Sidewinder was the first truly effective air-to-air missile, widely imitated and copied. Its latest variants remain in active service with many air forces. When a Sidewinder missile is being launched, NATO pilots use the brevity code Fox Two in radio communication.

History

Early development

The Sidewinder missile was a development of the Naval Ordnance Test Station (NOTS), Inyokern, California, now the Naval Air Weapons Station China Lake, California. It was officially designated in 1952 and was originally conceived by William Burdette McLean.

Developed by the U.S. Navy (USN) starting in the late 1940s, the Sidewinder introduced several new technologies that made it simpler and much more reliable than its United States Air Force (USAF) counterpart, the AIM-4 Falcon. After terrible experiences with the Falcon in the Vietnam War, the Air Force replaced its Falcons with Sidewinders.

The primary advantage to the Sidewinder is its sophisticated, yet simple detection and guidance system. During WWII the Germans had experimented with infrared guidance systems in a large missile known as the Enzian, but were unable to get it to work reliably. The Enzian was guided by an IR detector mounted in a small, steerable telescope. A vane in front of the mirror shaded the detector, so the system could locate the target. By continually turning toward the telescope, the missile was guided toward the target using what is known as a pure pursuit. The Sidewinder improved on this.

Geometric arrangement of mirror, IR detector and target.

The first was to replace the "steering" mirror with a forward facing mirror rotating around a shaft pointed out the front of the missile. The detector was mounted in front of the mirror. When the long axis of the mirror, the missile axis and the line of sight to the target all fell in the same plane, the reflected rays from the target reached the detector (provided the target was not very far off axis). Therefore, the angle of the mirror at detection estimated the direction of the target in the roll axis of the missile.

The yaw/pitch direction of the target depended on how far to the outer edge of the mirror the target was. If the target was further off axis, the rays reflected from the outer edge of the mirror. If the target was closer on axis, the rays reflected from closer to the center of the mirror. The mirrors linear speed was higher at the outer edge, though its thickness was the same. Therefore if a target was further off-axis its reflection occurred for a briefer time. The off-axis angle could then be estimated by the duration of the reflected pulse of infra-red. If the pulse was long, the target was on-axis.

This signal makes the tracking system both simpler and better. Instead of simply pointing the missile at the target (which is inefficient), the Sidewinder "remembered" each flash's direction and time. By attempting to zero out the changes, instead of the difference between the detector and missile angles, the Sidewinder flies a course known as proportional pursuit[1], which is much more efficient and makes the missile "lead" the target.

However this system also requires the missile to have a fixed roll axis orientation. If the missile spins at all, the timing based on the speed of rotation of the mirror is no longer accurate. Correcting for this spin would normally require some sort of sensor to tell which way is "down" and then adding controls to correct it. Instead, small control surfaces were placed at the rear of the missile with spinning disks on their outer surface. Airflow over the disk spins them to a high speed. If the missile starts to roll, the gyroscopic force of the disk drives the control surface into the airflow, cancelling the motion. Thus the Sidewinder team replaced a potentially complex control system with a simple mechanical solution.

Service entry

A prototype Sidewinder, the XAAM-N-7 (later AIM-9A), was first fired successfully in September 1953. The initial production version, designated AAM-N-7 (later AIM-9B), entered operational use in 1956, and has been improved upon steadily since. The first combat use of the Sidewinder was in 1958 with the air force of the Republic of China on Taiwan. During that period of time, the ROC was engaged in air battles with the People's Republic of China over the Taiwan Strait. The United States provided a few dozen Sidewinders to ROC forces, which used them to great effect against PRC MiG-17s, adding a new element to an air war which had formerly been fought only with guns.

The Taiwan Strait battles inadvertently produced a new derivative of Sidewinder: shortly after that conflict the Soviet Union began the manufacture of the K-13/R-3S missile (NATO reporting name AA-2 'Atoll'), a reverse-engineered copy of the Sidewinder. It was made possible after a Taiwanese AIM-9B hit a Chinese MiG-17 without exploding; amazingly, the missile struck the MiG-17 and became lodged within the airframe, and the pilot was able to return to base with the missile. Years later, Soviet engineers would admit that the captured Sidewinder served as a "university course" in missile design and substantially improved Soviet and allied air-to-air capabilities. The K-13 and its derivatives remained in production for nearly 30 years.

Although originally developed for the USN, the Sidewinder was subsequently adopted by the USAF as the GAR-8 (later AIM-9E). During the 1960s the USN and USAF pursued their own separate versions of the Sidewinder, but cost considerations later forced the development of common variants.

The Sidewinder subsequently evolved through a series of upgraded versions with newer, more sensitive seekers with various types of cooling and various propulsion, fuse, and warhead improvements.

Although each of those versions had various seeker, cooling, and fuzing differences, all but one shared infrared homing. The exception was the U.S. Navy AAM-N-7 Sidewinder IB (later AIM-9C), a Sidewinder with a semi-active radar homing seeker head developed for the F-8 Crusader. Only about 1,000 of these weapons were produced, many of which were later rebuilt as the AGM-122 Sidearm anti-radiation missile.

The AIM-9J Sidewinder version was used by the United States Air Force as well as being widely exported. An improved version of the basic AIM-9B, the main features are larger control surfaces as well as a more aerodynamic IR seeker and improved rocket motor. The missile however still has to be fired at the target from behind, a drawback of all early IR missiles.

All-Aspect Sidewinders

AIM-9L / AIM-9M / AIM-9M-7

The next major advance in IR Sidewinder development was the AIM-9L ("Lima") model, introduced in 1978. This was the first "all-aspect" Sidewinder with the ability to attack from all angles, including head-on. In its first combat uses by Israel over Lebanon and by the United Kingdom during the Falklands War, the "Lima" reportedly achieved a kill ratio of around 80%, a dramatic improvement over the 10-15% levels of earlier weapons. In both cases, the users' opponents had not developed any tactics for the evasion of a head-on missile shot of this kind, making them all the more vulnerable.

The subsequent AIM-9M ("Mike") has the all-aspect capability of the L model while providing all-around higher performance. The M model has improved defense against infrared countermeasures, enhanced background discrimination capability, and a reduced-smoke rocket motor. These modifications increase its ability to locate and lock on a target and decrease the missile's chances for detection. Deliveries began in 1983. The AIM-9M-7 was a specific modification to AIM-9M in response to threats expected in the Persian Gulf war zone.

AIM-9X

Now entering service is the AIM-9X, a new variant with an imaging infrared focal plane array seeker with claimed 90° off-boresight capability, compatibility with helmet-mounted sights (the new U.S. Joint Helmet-Mounted Cueing System), and a totally new thrust-vectoring system replacing the traditional control surfaces. It retains the same motor and warhead of the "Mike," but its lower drag gives it improved range and speed. The AIM-9X has demonstrated a Lock on After Launch capability, allowing for possible internal use for the F-35.[2]

SIDEARM / AGM-122A

File:Sidearm loading.jpg
AIM-9M Sidewinder being loaded onto an F-14 Tomcat.

The Sidewinder was also adapted into a new missile, the AGM-122A Sidearm, which is an anti-radiation missile utilizing an AIM-9C guidance section modified to detect and track a radiating ground-based air defense system radar. The target detecting device is modified for air-to-surface use, employing forward hemisphere acquisition capability. Sidearm stocks have apparently been expended, and the weapon is no longer in the active inventory.

Architecture

The AIM-9 is made up of a number of different components manufactured by different companies, including Aerojet and Raytheon. The missile is divided into four main sections: guidance, target detector, warhead, and rocket motor.

The Guidance and Control Unit (GCU) contains most of the electronics and mechanics that enable the missile to function. At the very front is the IR seeker head utilizing the rotating reticle, mirror, and five CdS cells or “pan and scan” CCD (AIM-9X), electric motor, and armature, all protruding into a glass dome. Directly behind this are the electronics that gather data, interpret signals, and generate the control signals that steer the missile. An umbilical on the side of the GCU attaches to the launcher, which is pulled from the missile at launch. A 5,000 psig (35 MPa) argon bottle (TMU-72/B or A/B) or Sterling liquid nitrogen generator (AIM-9X) is used to cool the electronics. Two electric servos power the canards to steer the missile (except AIM-9X). At the back of the GCU is a gas grain generator or thermal battery (AIM-9X) to provide electrical power. The AIM-9X features High-Off-Boresight capability; together with JHeMoCS (Joint Helmet Mounted Cuing System), this missile is capable of locking on to a target that it is behind it. The AIM-9X also features a Built-In-Test to aid in maintenance and reliability.

Next is a target detector with four IR emitters and detectors that detects if the target is moving farther away. When it detects this action taking place, it sends a signal to the Warhead Safe and Arm device to detonate the warhead. Versions older than the AIM-9L featured an influence fuse that relied on the target's magnetic field as input. Current trends in shielded wires and non-magnetic metals in aircraft construction rendered this obsolete.

The AIM-9H model contained a 25 pound rodded-blast fragmentary warhead. All other models up to the AIM-9M contained a 22 pound annular blast fragmentary warhead.

Recent models of the AIM-9 are configured with an annular blast fragmentation warhead, the WDU-17B by Argotech Corporation. The case is made of spirally wound spring steel filled with 8 pounds (4 kg) of PBXN-3 tritonol. The fuse requires five seconds at 20 g (195.6 m/s²) acceleration to arm and features a safe/arm device.

The solid propellant rocket motor provides propulsion for the missile. A reduced smoke propellant makes it difficult for a target to see and avoid the missile. This section also features the launch lugs used to hold the missile to the rail of the missile launcher. The forward of the three lugs has two contact buttons that electrically activate the motor igniter. The fins provide stability from an aerodynamic point of view, but it is the "rollerons" at the end of the wings providing gyroscopic precession that prevents the serpentine motion that gave the Sidewinder its name in the early days. The wings and fins of the AIM-9X are smaller to accommodate its use on the F-22 Raptor but the missile system is too long to fit in the internal bays of the Raptor for the time being. The control section is located in the rear, while the wings up front provide stability. The AIM-9X also features vectored thrust to increase maneuverability and accuracy, with four vanes inside the exhaust that move as the fins move. The last upgrade to the missile motor on the AIM-9X is the addition of a wire harness that allows communication between the guidance section and the control section, as well as a new 1760 bus to connect the guidance section with the launcher’s digital umbilical.

Sidewinder SAM

A version for the US Army with a launcher with four Sidewinder AIM-9D missiles on a tracked vehicle called MIM-72 Chaparral was also developed.

Conclusion

The Sidewinder is the most widely used missile in the West, with more than 110,000 missiles produced for the U.S. and 27 other nations. It has been built under license by some nations (including Sweden, which builds it under the local designation Rb24). The AIM-9 is one of the oldest, least expensive and most successful air-to-air missiles, with an estimated 270 kills worldwide to date.[2]

It has been said that the design goals for the original Sidewinder were to produce a reliable and effective missile with the "electronic complexity of a table model radio and the mechanical complexity of a washing machine" – goals which were well accomplished in the early missiles. The United States Navy hosted a 50th anniversary celebration of its existence in 2002.

General characteristics (AIM-9L)

Operators

  • Argentina Argentina
  • Australia Australia
  • Belgium Belgium
  • Brazil Brazil
  • Canada Canada
  • Chile Chile
  • Czech Republic Czech Republic
  • Denmark Denmark [3]
  • Finland Finland [4]
  • Germany Germany
  • Greece Greece
  • Iran Iran [5]
  • Israel Israel
  • Japan Japan
  • Kuwait Kuwait
  • Netherlands Netherlands
  • Norway Norway
  • Pakistan Pakistan
  • Poland Poland
  • Saudi Arabia Saudi Arabia [6]
  • Singapore Singapore
  • South Korea South Korea
  • Sweden Sweden — called Robot 24.
  • Switzerland Switzerland
  • Taiwan Taiwan
  • Turkey Turkey [7]
  • United Kingdom United Kingdom
  • United States United States

Please note that this list is not exhaustive.

See also

Notes

References

  • Babcock, Elizabeth (1999). Sidewinder – Invention and Early Years. The China Lake Museum Foundation. 26 pp. A concise record of the development of the original Sidewinder version and the central people involved in its design.

See also