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Abstract

Army senior military leaders are invested in acquiring modernized aerial platforms and equipment to augment the US Army’s ability to overcome Anti-Access Area Denial (A2AD) threats imposed by modern Integrated Air Defense Systems (IADS). A prominent element of this modernization effort is the employment of autonomous drones to defeat IADS threats while minimizing risk to Army Soldiers. This research utilizes a framework for classifying the levels of autonomous capability along three dimensions: the ability to act alone, the ability to cooperate, and the ability to adapt. A virtual combat model, created using the Advanced Framework for Simulation, Integration, and Modeling (AFSIM), simulates the engagement between an enemy IADS and a friendly formation comprised of autonomous drones, attack helicopters, and a Long Range Precision Fires (LRPF) capability. A designed experiment evaluates drone performance with varying levels of autonomy. The experimental results reveal that low levels of autonomy yield a 20.74% increase in survivability and a 5.52% increase in lethality.

Keywords

Autonomous systems agent-based modeling contested environment A2AD

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References

Summary of the 2018 National Defense Strategy of the United States of America, 2018, https://www.jcs.mil/Portals/36/Documents/Publications/UNCLASS_2018_National_Military_Strategy_Description.pdf

The U.S. Army in multi-domain operations 2028, 2018, https://adminpubs.tradoc.army.mil/pamphlets/TP525-3-1.pdf

The U.S. ARMY robotic and autonomous systems strategy, 2017, https://mronline.org/wp-content/uploads/2018/02/RAS_Strategy.pdf

Huang

Pavek

Albus

, et al. Autonomy levels for unmanned systems (ALFUS) framework: an update. In: Proceedings of SPIE 5804, Unmanned Ground Vehicle Technology VII (eds Gerhart

Shoemaker

Gage

), Orlando, FL, p. 439, http://proceedings.spiedigitallibrary.org/proceeding.aspx?doi=10.1117/12.603725

Clough

. Metrics, schmetrics! How the heck do you determine a UAV’s autonomy anyway. In: Performance metrics for intelligent systems workshop 2002. Air Force Research Laboratory, p. 5, https://apps.dtic.mil/sti/pdfs/ADA515926.pdf

David

Final report of the Defense Science Board summer study on autonomy (Publicly-Releasable Version). Technical report, Department of Defense, Defense Science Board, 2016, https://apps.dtic.mil/sti/pdfs/AD1017790.pdf

Spiegel

Shideler

Franke

. A framework for autonomy: a short paper on the first principles of autonomous design. Technical Report, Lockheed-Martin, Missiles and Fire Control. Ft Walton Beach, FL, 2019.

Spiegel

Simulation and analysis of cruise missile autonomous behaviors. Master’s Thesis, Air Force Institute of Technology, Wright-Patterson Air Force Base, OH, 2020.

Pollack

Simulation and analysis of high value airborne asset defense with autonomous systems. Master’s Thesis, Air Force Institute of Technology, Wright-Patterson Air Force Base, OH, 2021.

10.

Goggins

KW.

Simulating autonomous cruise missile swarm behaviors in an Anti-Access Area Denial (A2AD) environment. Master’s Thesis, Air Force Institute of Technology, OH, 2022.

11.

Countering air and missile threats, 2017, https://defenseinnovationmarketplace.dtic.mil/wp-content/uploads/2018/02/JointDoctrine-CounteringAirandMissileThreats.pdf

12.

Pelosi

Honeycutt

Cruise missile integrated air defense system penetration: modeling the S-400 system. Int J Aviat Aeronaut Aerosp 2017; 4(3): Article 2. http://doi.org/10.15394/ijaaa.2017.1104

13.

Johnson

Washington’s perceptions and misperceptions of Beijing’s anti-access area-denial (A2-AD)‘strategy’: implications for military escalation control and strategic stability. Pac Rev 2017; 30: 271–288.

14.

Sanders

. Drone swarms. Master’s Thesis, U.S. Army School for Advanced Military Studies, Fort Leavenworth, KS, 2017, https://apps.dtic.mil/sti/pdfs/AD1039921.pdf

15.

Hill

Miller

. A history of United States military simulation. In: Proceedings of the 2017 winter simulation conference, Las Vegas, NV, 3–6 December, pp. 346–364. New York: IEEE. doi: 10.1109/WSC.2017.8247799

16.

Banks

Carson

Nelson

, et al. Discrete-event system simulation. 5th ed. Hoboken, NJ: Prentice Hall, 2010.

17.

Connors

Miller

Lunday

Using agent-based modeling and a designed experiment to simulate and analyze a new air-to-air missile. J Def Model Simul 2016; 13: 321–330.

18.

Macal

Everything you need to know about agent-based modelling and simulation. J Simul 2016; 10: 144–156.

19.

Montgomery

Design and analysis of experiments. 10th ed. Hoboken, NJ: Wiley, 2020.

20.

Sanchez

Wan

. Work smarter, not harder: a tutorial on designing and conducting simulation experiments. In: Proceedings of the 2020 winter simulation conference, Huntington Beach, CA, 6–9 December, pp. 1128–1142. New York: IEEE.

21.

Foster

Petty

Estimating the tactical impact of robot swarms using a semi-automated forces system and design of experiments methods. J Def Model Simul 2021; 18: 247–269.

22.

Army Techniques Publication (ATP) 3-09.60 techniques for Multiple Launch Rocket System (MLRS) and High Mobility Rocket System (HIMARS) operations, 2020. https://armypubs.army.mil/epubs/DR_pubs/DR_d/ARN30083-ATP_3-09.60-000-WEB-1.pdf

Simulating autonomous drone behaviors in an anti-access area denial (A2AD) environment

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