Military robots are autonomous robots or remote-controlled mobile robots designed for military applications, from transport to search & rescue and attack.[1][2][3]
Some such systems are currently in use, and many are under development.
History
editBroadly defined, military robots date back to World War II and the Cold War in the form of the German Goliath tracked mines and the Soviet teletanks. The introduction of the MQ-1 Predator drone was when "CIA officers began to see the first practical returns on their decade-old fantasy of using aerial robots to collect intelligence".[4]
The use of robots in warfare, although traditionally a topic for science fiction, is being researched as a possible future means of fighting wars. Already several military robots have been developed by various armies. Some believe the future of modern warfare will be fought by automated weapons systems.[5] The U.S. military is investing heavily in the RQ-1 Predator, which can be armed with air-to-ground missiles and remotely operated from a command center in reconnaissance roles. DARPA has hosted competitions in 2004 & 2005 to involve private companies and universities to develop unmanned ground vehicles to navigate through rough terrain in the Mojave Desert for a final prize of 2 million.[6]
Artillery has seen promising research with an experimental weapons system named "Dragon Fire II" which automates loading and ballistics calculations required for accurate predicted fire, providing a 12-second response time to fire support requests. However, military weapons are prevented from being fully autonomous; they require human input at certain intervention points to ensure that _targets are not within restricted fire areas as defined by Geneva Conventions for the laws of war.
There have been some developments towards developing autonomous fighter jets and bombers.[7] The use of autonomous fighters and bombers to destroy enemy _targets is especially promising because of the lack of training required for robotic pilots, autonomous planes are capable of performing maneuvers which could not otherwise be done with human pilots (due to high amount of G-force), plane designs do not require a life support system, and a loss of a plane does not mean a loss of a pilot. However, the largest drawback to robotics is their inability to accommodate for non-standard conditions. Advances in artificial intelligence in the near future may help to rectify this.
In 2020 a Kargu 2 drone hunted down and attacked a human _target in Libya, according to a report from the UN Security Council’s Panel of Experts on Libya, published in March 2021. This may have been the first time an autonomous killer robot armed with lethal weaponry attacked human beings.[8][9]
Examples
editIn current use
edit- D9T Panda, Israel
- Elbit Hermes 450, Israel
- Goalkeeper CIWS
- Guardium[11]
- IAIO Fotros, Iran
- PackBot
- MQ-9 Reaper
- MQ-1 Predator
- TALON
- Samsung SGR-A1[12]
- Shahed 129, Iran
- Baykar Bayraktar TB2, Turkey
- Albatross, Taiwan
- Shomer Gvouloth ("Border Keeper"), Israel
- THeMIS, Estonia
- PLA robot soldiers, deployed on the China-India border [13]
In development
edit- MIDARS, a four-wheeled robot outfitted with several cameras, radar, and possibly a firearm, that automatically performs random or preprogrammed patrols around a military base or other government installation. It alerts a human overseer when it detects movement in unauthorized areas, or other programmed conditions. The operator can then instruct the robot to ignore the event, or take over remote control to deal with an intruder, or to get better camera views of an emergency. The robot would also regularly scan radio frequency identification tags (RFID) placed on stored inventory as it passed and report any missing items.
- Tactical Autonomous Combatant (TAC) units, described in Project Alpha study Unmanned Effects: Taking the Human out of the Loop.[14]
- Autonomous Rotorcraft Sniper System is an experimental robotic weapons system being developed by the U.S. Army since 2005.[15][16] It consists of a remotely operated sniper rifle attached to an unmanned autonomous helicopter.[17] It is intended for use in urban combat or for several other missions requiring snipers.[18] Flight tests are scheduled to begin in summer 2009.[15]
- The "Mobile Autonomous Robot Software" research program was started in December 2003 by the Pentagon who purchased 15 Segways in an attempt to develop more advanced military robots.[19] The program was part of a $26 million Pentagon program to develop software for autonomous systems.[19]
- ACER
- Atlas (robot)
- Battlefield Extraction-Assist Robot
- Dassault nEUROn (French UCAV)
- Dragon Runner
- MATILDA
- MULE (US UGV)
- R-Gator
- Ripsaw MS1 [1]
- SUGV
- Syrano
- iRobot Warrior
- PETMAN
- Excalibur unmanned aerial vehicle
- Teng Yun medium size reconnaissance UAV program, Taiwan
Effects and impact
editAdvantages
editAutonomous robotics would save and preserve soldiers' lives by removing serving soldiers, who might otherwise be killed, from the battlefield. Lt. Gen. Richard Lynch of the United States Army Installation Management Command and assistant Army chief of staff for installation stated at a 2011 conference:
As I think about what’s happening on the battlefield today ... I contend there are things we could do to improve the survivability of our service members. And you all know that’s true.[20]
Major Kenneth Rose of the US Army's Training and Doctrine Command outlined some of the advantages of robotic technology in warfare:[21]
Machines don't get tired. They don't close their eyes. They don't hide under trees when it rains and they don't talk to their friends ... A human's attention to detail on guard duty drops dramatically in the first 30 minutes ... Machines know no fear.
Increasing attention is also paid to how to make the robots more autonomous, with a view of eventually allowing them to operate on their own for extended periods of time, possibly behind enemy lines. For such functions, systems like the Energetically Autonomous Tactical Robot are being tried, which is intended to gain its own energy by foraging for plant matter. The majority of military robots are tele-operated and not equipped with weapons; they are used for reconnaissance, surveillance, sniper detection, neutralizing explosive devices, etc. Current robots that are equipped with weapons are tele-operated so they are not capable of taking lives autonomously.[22] Advantages regarding the lack of emotion and passion in robotic combat is also taken into consideration as a beneficial factor in significantly reducing instances of unethical behavior in wartime. Autonomous machines are created not to be "truly 'ethical' robots", yet ones that comply with the laws of war (LOW) and rules of engagement (ROE).[23] Hence the fatigue, stress, emotion, adrenaline, etc. that affect a human soldier's rash decisions are removed; there will be no effect on the battlefield caused by the decisions made by the individual.
Risks
editHuman rights groups and NGOs such as Human Rights Watch and the Campaign to Stop Killer Robots have started urging governments and the United Nations to issue policy to outlaw the development of so-called "lethal autonomous weapons systems" (LAWS).[24] The United Kingdom opposed such campaigns, with the Foreign Office declaring that "international humanitarian law already provides sufficient regulation for this area".[25]
In July 2015, over 1,000 experts in artificial intelligence signed a letter calling for a ban on autonomous weapons. The letter was presented in Buenos Aires at the 24th International Joint Conference on Artificial Intelligence (IJCAI-15) and was co-signed by Stephen Hawking, Elon Musk, Steve Wozniak, Noam Chomsky, Skype co-founder Jaan Tallinn and Google DeepMind co-founder Demis Hassabis, among others.[26][27]
Psychology
editAmerican soldiers have been known to name the robots that serve alongside them. These names are often in honor of human friends, family, celebrities, pets, or are eponymic.[28] The 'gender' assigned to the robot may be related to the marital status of its operator.[28]
Some affixed fictitious medals to battle-hardened robots, and even held funerals for destroyed robots.[28] An interview of 23 explosive ordnance detection members shows that while they feel it is better to lose a robot than a human, they also felt anger and a sense of loss if they were destroyed.[28] A survey of 746 people in the military showed that 80% either 'liked' or 'loved' their military robots, with more affection being shown towards ground rather than aerial robots.[28] Surviving dangerous combat situations together increased the level of bonding between soldier and robot, and current and future advances in artificial intelligence may further intensify the bond with the military robots.[28]
In fictional media
editPictures
edit-
UGV TALON Gen. IV (USA)
-
UGV "PIRANYA" (Ukraine)
-
Type-X (Estonia)
-
THeMIS (Estonia)
-
Uran-9 (Russia)
-
Berserk (Belarus)
-
Sea Hunter (USA)
-
Miloš L (UGV), a military robot for evacuating the wounded from the battlefield
See also
edit- DARPA Grand Challenge
- Lethal autonomous weapon
- Human-in-the-loop
- Missile guidance
- Multi Autonomous Ground-robotic International Challenge
- Network-centric warfare
- Powered exoskeleton
- Roboethics
- Robot combat
- Robot Wars (disambiguation)
- Supersoldier
- Telerobotics
- Three Laws of Robotics
- Unmanned combat air vehicle
References
edit- ^ Voth, D. (2004). "A new generation of military robots". IEEE Intelligent Systems. 19 (4): 2–3. doi:10.1109/MIS.2004.30.
- ^ Franke, Ulrike Esther (2018). "Military Robots And Drones". Routledge Handbook of Defence Studies. London: Routledge. ISBN 9781315650463.
- ^ Agarwala, Nitin (2023). "Robots and Artificial Intelligence in the Military". Obrana a strategie. 23 (2): 083–100. doi:10.3849/1802-7199.23.2023.02.083-100.
- ^ Steve Coll, Ghost Wars (Penguin, 2005 edn), pp.529 and 658 note 6.
- ^ Robots and Robotics at the Space and Naval Warfare Systems Center Pacific Archived 1999-02-20 at the Wayback Machine
- ^ "Welcome to Grandchallenge". www.grandchallenge.org. Archived from the original on 2007-10-11.
- ^ Talbot, David. "The Ascent of the Robotic Attack Jet". MIT Technology Review.
- ^ Hambling, David. "Drones may have attacked humans fully autonomously for the first time". New Scientist. Retrieved 2021-05-30.
- ^ "Killer drone 'hunted down a human _target' without being told to". New York Post. 2021-05-29. Retrieved 2021-05-30.
- ^ ""Платформа-М": Роботизированный комплекс широких возможностей". arms-expo.ru. Archived from the original on 2016-03-04.
- ^ Guardium Military robot Archived 2005-10-26 at the Wayback Machine
- ^ Korean gun bots Archived 2011-01-15 at the Wayback Machine theregister.co.uk
- ^ "Gravitas: China deploys 'Robot Soldiers' along the border with India - Gravitas News".
- ^ Schafer, Ron (July 29, 2003). "Robotics to play major role in future warfighting". United States Joint Forces Command. Archived from the original on August 13, 2003. Retrieved 2013-04-30.
{{cite web}}
: CS1 maint: unfit URL (link) - ^ a b Page, Lewis (21 April 2009). "Flying-rifle robocopter: Hovering sniper backup for US troops". The Register. Archived from the original on 24 April 2009. Retrieved 2009-04-21.
- ^ "U.S. Army Tests Flying Robot Sniper". Fox News. 2009-04-22. Archived from the original on 2009-04-26. Retrieved 2009-04-23.
- ^ Hambling, David (May 2009). "UAV Helicopter Brings Finesse to Airstrikes". Popular Mechanics. Archived from the original on 2009-04-21. Retrieved 2009-04-21.
- ^ Hambling, David (April 21, 2009). "Army Tests Flying Robo-Sniper". Wired, "Danger Room" blog. Archived from the original on April 23, 2009. Retrieved 2009-04-21.
- ^ a b "Military wants to transform Segway scooters into robots". seattlepi.com. 2003-12-02. Retrieved 2009-04-24.
- ^ Cheryl Pellerin (American Forces Press Service) - DoD News:Article published Aug. 17, 2011 Archived 2015-07-14 at the Wayback Machine published by the U.S. Department of Defense, WASHINGTON (DoD) [Retrieved 2015-07-28]
- ^ "Robot soldiers". BBC News. 2002-04-12. Archived from the original on 2011-01-25. Retrieved 2010-05-12.
- ^ Hellström, Thomas (June 2013). "On the moral responsibility of military robots". Ethics and Information Technology. 15 (2): 99–107. CiteSeerX 10.1.1.305.5964. doi:10.1007/s10676-012-9301-2. S2CID 15205810.
- ^ Lin, Bekey, Abney, Patrick, George, Keith (2009). "Robots in War: Issues of Risk and Ethics". Archived from the original on 2015-11-23.
{{cite web}}
: CS1 maint: multiple names: authors list (link) - ^ Bowcott, Owen Bowcott (9 April 2015). "UN urged to ban 'killer robots' before they can be developed". the Guardian. Archived from the original on 2015-07-28. Retrieved 2015-07-28.
- ^ Bowcott, Owen (13 April 2015). "UK opposes international ban on developing 'killer robots'". the Guardian. Archived from the original on 2015-07-29. Retrieved 2015-07-28.
- ^ Gibbs, Samuel (27 July 2015). "Musk, Wozniak and Hawking urge ban on warfare AI and autonomous weapons". the Guardian. Archived from the original on 2015-07-27. Retrieved 2015-07-28.
- ^ "Musk, Hawking Warn of Artificial Intelligence Weapons". WSJ Blogs - Digits. 2015-07-27. Archived from the original on 2015-07-28. Retrieved 2015-07-28.
- ^ a b c d e f Nidhi Subbaraman. "Soldiers <3 robots: Military bots get awards, nicknames ... funerals". NBC News. Archived from the original on 2013-10-06.
External links
edit- "Biomass military robot in development"
- EATR: Energetically Autonomous Tactical Robot - Phase II Project
Ethical and legal concerns
edit- Gerhard Dabringer (Hg.), Ethica Themen: Ethical and Legal Aspects of Unmanned Systems. Interviews, Wien 2010
- Public Say It's Illegal to _target Americans Abroad as Some Question CIA Drone Attacks, according to Fairleigh Dickinson University PublicMind poll - February 7, 2013
- The future of warfare: Why we should all be very afraid (2014-07-21), Rory Tolan, Salon
- Archive on air wars, Geographical Imaginations
- Logical Limitations to Machine Ethics, with Consequences to Lethal Autonomous Weapons. Also discussed in: Does the Halting Problem Mean No Moral Robots?
- Robots in War: Issues of Risk and Ethics - 2009
Organizations
edit- United States Joint Forces Command website: "Leading the transformation of the U.S. military"
- irobot.com, builder of the PackBot and the R-Gator systems
- Boston Dynamics, builder of BigDog
News articles/press releases
edit- USJFC: 'Robotics to play major role in future warfighting'
- "From bomb disposal to waste disposal" Archived 2015-07-09 at the Wayback Machine Robots help deal with hazards, emergencies and disasters (International Electrotechnical Commission, July 2011)
- "War robots still in Iraq", DailyTech, April 17, 2008
- New Model Army Soldier Rolls Closer to Battle (SWORDS)
- TALON Small Mobile Robot
- TWG Military Robots
- Carnegie Mellon University's snooping robot going to Iraq
- PackBot Battlefield robotic Platform Archived 2015-04-05 at the Wayback Machine
- Miniature Unmanned Aerial Systems - UAV
- Guardium Autonomous Security Vehicle
- Unmanned Ground Systems from Israel Archived 2015-05-01 at the Wayback Machine
- High-Tech Military in Due Course Archived 2007-03-11 at the Wayback Machine
- Launching a new kind of warfare
- Gerry J. Gilmore (January 24, 2006). "Army's Veteran Bomb-Disposal Robot Now 'Packs Heat'". American Forces Press Service. Retrieved 2008-02-02.
- As Wars End, Robot Field Faces Reboot April 11, 2012