[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.9708/jksci.2019.24.06.099

Application of STANAG-4586 Ed. 4 based Standardization for Up-to-Dated Interoperability of Military UAV System

Kim, Hack-Joon (Hanwha Systems Co.)
Yoon, Chang-Bae (Hanwha Systems Co.)
Hong, Su-Woon (Hanwha Systems Co.)
Lee, Woo-Sin (Hanwha Systems Co.)
Yoo, In-Deok (Hanwha Systems Co.)
Jo, Se-Hyeon (Hanwha Systems Co.)

Publication Information

Journal of the Korea Society of Computer and Information / v.24, no.6, 2019 , pp. 99-107 More about this Journal

Abstract

With the development of various types of military Unmanned Aircraft(UA)s, the need for interworking and integration between different platforms gradually increased. In order to ensure interoperability at each military UA System(UAS) level, North Atlantic Treaty Organization(NATO) has established STANAG-4586 "Standard Interfaces of Unmanned Aircraft(UA) Control Systems(UCS) for NATO UA Interoperability-Interface Control Document". This paper looks at the basic design structure of STANAG-4586 and the changes on Edition 4 to enhance joint operational capability through reflecting and updating the interoperability design of the military UAS. In particular, we analyze the enhanced Datalink Transition/Handover Procedure and Autonomous functions, one of the biggest features added to the edition. Through this, we propose a modification of UA data link exclusive control using UA Bypass structure, which was impossible in the one-to-one communication structure between existing UA and Core UCS(CUCS). We also suggest ways to improve UA operational reliability by applying Autonomous Functions that directly decides how to deal with emergency situations, rather than by a remote operator over CUCS.

Keywords

UAV; UA; UAS; CUCS; VSM; STANAG-4586; Interoperability; Datalink; GCS; Handover; Autonomous/Autonomy; NATO/STANAG;

Citations & Related Records

Reference

1	P., Vasile, "UNMANNED AERIAL SYSTEM IN THE CONTEXT OF MODERN WARFARE", SCIENTIFIC RESEARCH & EDUCATION IN THE AIR FORCE, pp. 177-184, 2016.
2	Bank of America Merrill Lynch, "Robot Revolution - Global Robot & AI Primer.", pp. 7, DEC 2015.
3	Gertler, J. "US unmanned aerial systems", LIBRARY OF CONGRESS WASHINGTON DC CONGRESSIONAL RESEARCH SERVICE, pp. 12, JAN 2012.
4	Department of Defense, "Unamnned Systems Integrated Roadmap FY2013-2038", pp. 5, 2014.
5	Chanda, M., DiPlacido, J., Dougherty, J., Egan, R., Kelly, J.,Kingery, T., Liston, D.Mousseau, D., Nadeau, J.,Rothman, T.,Smith, L., Supko, M. "Proposed functional architecture and associated benefits analysis of a common ground control station for Unmanned Aircraft Systems". Naval Postgraduate School, pp. 3, 2010.
6	NATO, "Standard Interfaces of Unmanned Aircraft(UA) Control Systems(UCS) for NATO UA Interoperability-Interface Control Document Edition 4". NATO Standardization Agency, APR. 2017.
7	Sang wan No, Soon young Lee, Min Soo Kim, Young hoon Lee. "The study of the IFF Mode-5 to apply to Helicopter System" The Society for Aerospace System Engineering 2018 Spring Conference, pp. 114-115, 2018.
8	D. S. Lopez, G. Moreno, J. Cordero, J. Sanchez, S. Govindaraj, M. M. Marques, V. Lobo, S. Fioravanti, A. Grati, K. Rudin, M. Tosa, A. Matos, A. Dias, A. Martins, J. Bedkowski, H. Balta, and G. D. Cubber, "Search and Rescue Robotics - From Theory to Practice". InTech, pp. 97, 2017.
9	D. Cofer et al., "A Formal Approach to Constructing Secure Air Vehicle Software," in Computer, vol. 51, no. 11, pp. 14-23, NOV 2018. DOI
10	U.S. Army, "Unmanned Aircraft Systems Roadmap 2010-2035" UAS Center of Excellence(Fort Rucker), pp. 12, 2010.
11	T. Hutchings, "Architecting UAV sense & avoid systems," in 2007 Institution of Engineering and Technology Conference on Autonomous Systems, pp. 1-8, 2007.
12	Peter Burt, "Off the Leash - The development of autonomous military drones in the UK", Drone Wars UK, pp. 36, NOV 2018.