无人机网络中基于状态迁移的访问控制模型

doi:10.3969/j.issn.1001-2400.2018.06.008

Abstract

Abstract: Due to many types of resources and high mobility in an Unmanned Aerial Vehicle (UAV) network, the traditional access control mechanism cannot achieve the flexible permission management when the authorization changes and the task transfers among UAVs. Therefore, an access control model based on state transition is proposed. The state transition rules are determined by the access properties of object resources, thereby achieving the flexible permission management and subject priority when the authorization changes and resource permissions transfer. Moreover, the experiments in the UAV network environment demonstrate that the execution time for the proposed scheme almost linearly increases with the growing scale of subjects and objects, and that the scheme is feasible in an actual UAV network with complex access control.

Key words: unmanned aerial vehicle network, state transition, fine-grained access control, flexible permission management

CLC Number:

TP309.2

MA Zhuoran, MA Jianfeng, MIAO Yinbin, SUN Cong. State transition-based access control model in the UAV network[J].Journal of Xidian University, 2018, 45(6): 44-50.

References ［15］

［1］	HARTMANN K, STEUP C. The Vulnerability of Uavs to Cyber Attacks—an Approach to the Risk Assessment［C］//Proceedings of the 2013 International Conference on Cyber Conflict. Washington: IEEE Computer Society, 2013: 6568373.<br />
［2］	GUPTA S G, GHONGE M M, JAWANDHIYA D P M. Review of Unmanned Aircraft System(UAS)［J］. International Journal of Advanced Research in Computer Engineering & Technology, 2013, 2(4): 1646-1658.<br />
［3］	ORTIZ-PENA H J, SUDIT M, HIRSCH M, et al. A Multi-perspective Optimization Approach to UAV Resource Management for Littoral Surveillance［C］//Proceedings of the 2013 16th International Conference on Information Fusion. Washington: IEEE Computer Society, 2013: 492-498.<br />
［4］	JAMOOM M B, JOERGER M, PERVAN B. Unmanned Aircraft System Sense and Avoid Integrity and Continuity Risk for Non-cooperatve Intruders［C］//Proceedings of the 2015 AIAA Infotech at Aerospace. Reston: AIAA, 2015: 112879.<br />
［5］	SPINKA O, KROUPA S, HANZALEK Z. Control System for Unmanned Aerial Vehicles［C］//Proceedings of the 2007 IEEE International Conference on Industrial Informatics. Piscataway: IEEE, 2007: 455-460.<br />
［6］	何兆龙. 无人机自组网技术研究［J］. 无线电工程, 2008, 38(8): 47-48.<br />
	HE Zhaolong. Research on Ad-hoc Network Technology of UAV［J］. Radio Engineering of China, 2018, 38(8): 47-48.<br />
［7］	YU Y G, WANG X, ZHONG Z, et al. ROS-based UAV Control Using Hand Gesture Recognition［C］//Proceedings of the 2017 29th Chinese Control and Decision Conference. Piscataway: IEEE, 2017: 6795-6799.<br />
［8］	JEONG H J, HA Y G. RBAC-based UAV Control System for Multiple Operator Environments［C］//Communications in Computer and Information Science: 340. Heidelberg: Springer Verlag, 2012: 210-217. <br />
［9］	LEE B H Y, MORRISON J R, SHARMA R. Multi-UAV Control Testbed for Persistent UAV Presence: ROS GPS Waypoint Tracking Package and Centralized Task Allocation Capability［C］//Proceedings of the 2017 International Conference on Unmanned Aircraft Systems. Piscataway: IEEE, 2017: 1742-1750.<br />
［10］	GANSEL S, SCHNITZER S, GILBEAU-HAMMOUD A, et al. An Access Control Concept for Novel Automotive HMI Systems［C］//Proceedings of the 2014 ACM Symposium on Access Control Models and Technologies. New York: ACM, 2014: 17-28.<br />
［11］	GANSEL S, SCHNITZER S, GILBEAU-HAMMOUD A, et al. Context-aware Access Control in Novel Automotive HMI Systems［C］//Lecture Notes in Computer Science: 9478. Heidelberg: Springer Verlag, 2015: 118-138.<br />
［12］	MO J P T, CHEN A Z J. UAV Delivery System Design and Analysis［C］//Proceedings of the 2017 17th Australian International Aerospace Congress. Melbourne: Australia Royal Aeronautical Society, 2017: 146-151.<br />
［13］	FILATOV D M, DEVYATKIN A V, FRIEDRICH A I. Quadrotor Parameters Identification and Control System Design［C］//Proceedings of the 2017 IEEE Russia Section Young Researchers in Electrical and Electronic Engineering Conference. Piscataway: IEEE, 2017: 826-830.<br />
［14］	PANDYA K G, NESAMANI K. UAV Advancement: from Increasing Endurance, Route Re-plan and Collision Avoidance, to Safe Landing in Critical Conditions［C］//Proceedings of the 2018 International Conference on Modern Research in Aerospace Engineering. Heidelberg: Springer, 2018: 109-120.<br />
［15］	MEIER L, CAMACHO J, GODBOLT B, et al. Mavlink: Micro Air Vehicle Communication Protocol［EB/OL］. ［2018-04-06］. http://qgroundcontrol. org/mavlink/start.<br />
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State transition-based access control model in the UAV network

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