Laser designator explained

A laser designator is a laser light source which is used to designate a target. Laser designators provide targeting for laser-guided bombs, missiles, or precision artillery munitions, such as the Paveway series of bombs, AGM-114 Hellfire, or the M712 Copperhead round, respectively.

When a target is marked by a designator, the beam is invisible and does not shine continuously. Instead, a series of coded laser pulses, also called PRF codes (pulse repetition frequency), are fired at the target. These signals bounce off the target into the sky, where they are detected by the seeker on the laser-guided munition, which steers itself towards the centre of the reflected signal.[1] Unless the people being targeted possess laser detection equipment or can hear aircraft overhead, it is extremely difficult for them to determine whether they are being marked. Laser designators work best in clear atmospheric conditions. Cloud cover, rain or smoke can make reliable designation of targets difficult or impossible unless a simulation is accessible through available ground data.

Deployment

Laser designators may be mounted on aircraft, ground vehicles, naval vessels, or handheld. Depending on the wavelength of light used by the designator, the designation laser may or may not be visible to the personnel deploying it. This is the case with 1064 nm laser designators used by JTACs as that wavelength of light is difficult to see under standard Gen III/III+ night vision devices.[2] Other imaging devices with "see-spot" capabilities to "see" the laser spot are often utilized to make sure the target is being correctly designated. These may include FLIR (forward looking infrared) thermal imagers which normally operate in the MWIR or LWIR spectrum[3] but have a 1064 nm window in which they can see-spot the laser.[4]

Airborne

The U.S. Air Force selected the Lockheed Martin's Sniper Advanced Targeting Pod (ATP) in 2004. It equipped multiple USAF platforms such as the F-16, F-15E, B-1, B-52, and A-10C. It also operates on multiple international fighter platforms. The U.S. Navy currently employ LITENING and ATFLIR targeting pods on a variety of strike aircraft.[5] The Litening II is widely used by many other of the world's air forces. The United Kingdom's Royal Air Force use the Litening III system and the French use the TALIOS (Targeting Long-range Identification Optronic System),[6] Damocles and ATLIS II.

Ground-based

Many modern armed forces employ handheld laser designation systems. Examples include the AN/PEQ-1 SOFLAM of the United States, the Russian LPR series of handheld devices.

U.S. Air Force Joint Terminal Air Controllers and Marine Corps Forward Air Controllers typically employ a lightweight device, such as the AN/PED-1 Lightweight Laser Designator Rangefinder (LLDR), permitting them to designate targets for Close Air Support aircraft flying overhead and in close proximity to friendly forces. While many designators are binocular-based and may utilize tripods, smaller handheld laser designators, like the B.E. Meyers & Co. IZLID 1000P exist as well.[7] Northrop Grumman's LLDR, using an eye-safe laser wavelength, recognizes targets, finds the range to a target, and fixes target locations for laser-guided, GPS-guided, and conventional munitions.[8] This lightweight, interoperable system uniquely provides range finding and targeting information to other digital battlefield systems[9] allowing the system to provide targeting information for non-guided munitions, or when laser designation is unreliable due to battlefield conditions.

See also

Further reading

Notes and References

  1. Web site: U.S. Marine Corps . MCTP 3-10F Fire Support Coordination in the Ground Combat Element . Marines.mil . 16 July 2022 . https://web.archive.org/web/20220716202303/https://www.marines.mil/portals/1/Publications/MCTP%203-10F.pdf?ver=2019-03-28-083848-523 . 16 July 2022 . Appendix K . 4 April 2018.
  2. Web site: Differences between Gen3 and 4G image intensification technology . Photonis Night Vision . 16 July 2022 . https://web.archive.org/web/20210505124344/https://www.photonis.com/system/files/2020-10/Difference_Gen3_4G_english_version.pdf . 5 May 2021 . October 2020.
  3. Web site: Thermal Camera Specs You Should Know Before Buying . FLIR.com . 16 July 2022 . https://web.archive.org/web/20220407192121/https://www.flir.com/discover/professional-tools/thermal-camera-specs-you-should-know-before-buying/ . 7 April 2022 . 18 December 2019.
  4. Donval . Ariela . Fisher . Tali . Lipman . Ofir . Oron . Moshe . Laser designator protection filter for see-spot thermal imaging systems . Proceedings of SPIE Defense, Security, and Sensing 2012 . 1 May 2012 . 8353 . Infrared Technology and Applications XXXVIII . 835324–835324–8 . 10.1117/12.916966 . 2012SPIE.8353E..24D . 122190698 . 16 July 2022.
  5. Web site: Fact Sheet - LITENING II . 24 June 2003 . bot: unknown . https://web.archive.org/web/20030624084136/http://www.af.mil/factsheets/factsheet.asp?fsID=114 . 24 June 2003 .
  6. [:fr:Pod Talios]
  7. Web site: IZLID 1000P . B.E. Meyers & Co. . 29 June 2022 . https://web.archive.org/web/20220519225530/https://bemeyers.com/izlid-1000p . 19 May 2022.
  8. Web site: Lightweight Laser Designator Rangefinder (LLDR) . Northrop Grumman . 4 June 2022 . https://web.archive.org/web/20190805023008/https://www.northropgrumman.com/Capabilities/ANPED1LLDR/Documents/lldr.pdf . 5 August 2019.
  9. Web site: Photo Release -- U.S. Army Awards Northrop Grumman Lightweight Laser Designator Rangefinders Delivery Order Valued at $142.7 Million (NYSE:NOC). dead . https://web.archive.org/web/20100325004140/http://www.irconnect.com/noc/press/pages/news_releases.html?d=187249 . 2010-03-25 .