FGM-172 SRAW
A computer graphics representation of FGM-172 SRAW.
TypeAnti-Tank Missile Launcher
Place of originUnited States, Israel
Service history
In service2002–2006
Used byUnited States, Israel
Production history
DesignerLockheed Martin
Designed1990–2002
ManufacturerLockheed Martin
Produced2002–2003
No. built960
VariantsFGM-172A anti-tank
FGM-172B assault
Specifications
Mass9.7 kg (21 lb)
Length70.5 cm (2.31 ft)
Width14 cm (5.5 in)
Diameter139 mm (5.5 in)
Crew1

Caliber139 mm (5.5 in)
Muzzle velocity250 m/s (820 ft/s)
Effective firing range17 to 600 m (19 to 660 yd)
WarheadFGM-172A: explosively formed penetrator
FGM-172B: multipurpose blast warhead
Detonation
mechanism
FGM-172A: proximity fuze
FGM-172B: combined contact fuze & time fuze

Guidance
system
PLOS (Predicted Line Of Sight)
Launch
platform
Man-portable launcher

The FGM-172 SRAW (Short-Range Assault Weapon), also known as the Predator SRAW, was a lightweight, close range missile system produced by Lockheed Martin, developed by Lockheed Martin and Israel Military Industries.[1] It is designed to complement the FGM-148 Javelin anti-tank missile. The Predator had a longer range and was more powerful than the AT4 that it was designed to replace, but had a shorter range than the Javelin.

The missile system received the FGM-172 designation from the United States Department of Defense in 2006. Before that it was known as the SRAW MK 40 MOD 0.

Features

The Predator was a fire-and-forget weapon utilizing a system called predicted line of sight (PLOS). In this system, the operator tracks the target for a short time (at least 2 seconds and no more than 12) before launch. This data is then combined with known missile flight performance to predict a flight path that will intercept the target's course, and program the missile's autopilot system. An inertial guidance unit is incorporated into the autopilot to compensate for crosswind and other factors encountered in flight.

The original FGM-172A was an overfly top attack (OTA) type and used a downward-facing dual laser and magnetic sensor to detect a target and trigger detonation of the warhead. The laser sensor would locate the positions of the leading and trailing edges of a vehicle, and the magnetic sensor would confirm the position of the vehicle. Once a target is detected, the FGM-172A would fire an explosively formed penetrator downward, into what was intended to be the thinner armor of a tank turret roof.

The missile does not lock on to a specific target, rather, the FGM-172A would attack the first potential target it encountered during flight. For this reason, TM 10687A OR/C directs operators to avoid firing the weapon over destroyed vehicles.

The FGM-172B altered the flight control systems for a direct intercept rather than an overfly course, and featured a dual-mode impact fuze with an automatic time delay if the missile struck a soft target.

The Kestrel variant featured an added unguided direct-fire mode.[2]

Variants

The missile was produced in two variants, each with a separate weapon payload.

The FGM-172A had a downward-firing top attack warhead activated by a dual sensor fuse, intended for use as an anti-armor weapon.

The FGM-172B had a multi-purpose blast-fragmentation warhead, intended for use as an assault weapon. Also known as the FGM-172B SRAW-MPV.

History

The Short-Range Assault Weapon (SRAW) program was begun by the U.S. Marine Corps in 1987 as a replacement for existing unguided M72 LAW and AT4 anti-armor rockets. A demonstration and validation phase was conducted by several companies between February 1990 and mid-1993, with the first test firings occurring in 1991.

In July 1994, the Predator design of Loral (now Lockheed Martin) was selected for the engineering and manufacturing development (EMD) phase. EMD Phase I was completed in March 1998, followed by Phase II; 230 missiles were produced during EMD.

In February 2002, the Marine Corps signed a contract with Lockheed Martin for the low-rate initial production (LRIP) of 330 Predator systems, with a second LRIP contract for 400 systems signed in January 2003. In October 2003, the Marine Corps announced a decision to cancel further procurement of the system following completion of low-rate production. The system successfully completed first article and lot 1 testing at the Naval Air Warfare Center, China Lake, California in December 2003.

In June 2004, Lockheed Martin received a contract to refit all 700 remaining SRAW rounds to the FGM-172B SRAW-MPV (Multi-Purpose Variant) configuration with a new multi-purpose blast-fragmentation warhead, converting the system from an anti-armor to a direct-fire urban assault weapon effective against buildings and bunkers, which better fulfilled the needs of the Marines in response to requirements identified during Operation Iraqi Freedom; delivery of the first 400 rounds was completed in May 2005.[2][3] As of 2005, all the FGM-172A missiles supplied formerly to the USMC had been retrofitted with the FGM-172B multi-purpose blast warhead to replace the top attack anti-armor warhead.[4]

The Kestrel was a derivative of the Predator for the British Army's Next-generation Light Anti-tank Weapon (NLAW) programme. In 2000, the UK Ministry of Defence carried out trials of 13 Kestrels. In May 2002, Saab Bofors Dynamics' MBT-LAW was chosen for the UK NLAW requirement.[2][3] In 2003, the U.S. Army decided not to adopt a version of the Predator as its Multipurpose Individual Munition – Short Range Assault Weapon (MPIM/SRAW) candidate.[5]

Former operators

References

  1. "Lockheed Martin to Develop Follow-on to Shoulder-Launched Multi-Purpose Assault Weapon for U.S. Marine Corps" (press release). Lockheed Martin. 2003. Archived from the original on 2011-10-20.
  2. 1 2 3 "Army Technology FGM-172 SRAW". Retrieved 2012-05-12.
  3. 1 2 "Lockheed Martin FGM-172 SRAW". 2006-09-27. Retrieved 2008-10-28.
  4. Jennifer Allen (2005-05-26). "Lockheed Martin, Responding to U.S. Marine Corps Needs, Converts Anti-Tank Missile for Urban Assault" (press release). Lockheed Martin.
  5. John Antal "Packing a Punch: America's Man-Portable Antitank Weapons" page 88 Military Technology 3/2010, Monch Publishing
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