Detection and resolution strategy of UAV low-altitude conflict based on geometric relations

doi:10.16265/j.cnki.issn1003-3033.2023.05.2049

Abstract

Abstract:

In order to ensure the flight safety of multi-rotor UAVs in low-altitude airspace, a conflict detection model and conflict resolution strategy for UAV low-altitude flights were proposed. According to the current Automatic Dependent Surveillance-Broadcast (ADS-B) data of the UAV, the interactive multi-model volumetric Kalman filtering algorithm (IMM-CKF) was used to predict the trajectory of the next stage, and the potential conflict objects were screened. According to the characteristics of the flight protection area, the AABB bounding boxes of the two aircrafts are constructed, and the three-dimensional collision detection algorithm was used to judge whether the two aircraft conflict, and SOSA flight conflict resolution strategy was proposed. Finally, four common conflict scenarios were constructed. The proposed algorithm was used to detect flight conflict. The SOSA combined resolution strategy and the traditional resolution strategy, such as the height adjustment method, the direction adjustment method and the speed adjustment method were used to resolve the flight conflict according to the situation. The results show that the flight conflict detection method based on the AABB bounding box can quickly detect conflicts within 0.02 s, and the use of SOSA combined resolution strategy can reduce the increase of the flying distance to less than 5% of the direct flight distance compared with the traditional resolution strategy. The conflict detection method is robust in real time, the complexity of the resolution strategy operation is low, and the payment distance is small during the conflict resolution process.

Key words: geometric relations, unmanned aerial vehicle(UAV), low altitude flight, conflict detection, resolution strategy, same orientation same angle(SOSA)

YUE Rentian, MA Zhaofei. Detection and resolution strategy of UAV low-altitude conflict based on geometric relations[J]. China Safety Science Journal, 2023, 33(5): 112-120.

Figures/Tables 16

Fig.1

Fig.2

Fig.3

Fig.4

Fig.5

Fig.6

Fig.7

Fig.8

Fig.9

Tab.1

Fig.10

Fig.11

Fig.12

Fig.13

Tab.2

Tab.3

References 15

[1]	刘洋, 向锦武, 罗漳平, 等. 低空自由飞行短期冲突探测算法[J]. 北京航空航天大学学报, 2017, 43(9):1873-1881.
	LIU Yang, XIANG Jinwu, LUO Zhangping, et al. Short-term conflict detection algorithm for free flight in low-altitude airspace[J]. Journal of Beijing University of Aeronautics and Astronautics, 2017, 43(9):1873-1881.
[2]	陈晓波, 宋万忠, 杨红雨. 一种基于概率方法的中期冲突探测算法[J]. 四川大学学报:自然科学版, 2010, 47(3):483-487.
	CHEN Xiaobo, SONG Wanzhong, YANG Hongyu, An algorithm based on conflict probability for mid-term conflict detection[J]. Journal of Sichuan University:Natural Science Edition, 2010, 47(3):483-487.
[3]	张思远, 李仙颖, 沈笑云. 基于ADS-B IN的冲突预测与多机无冲突航迹规划[J]. 系统仿真学报, 2019, 31(8):1627-1635. doi: 10.16182/j.issn1004731x.joss.17-0266
	ZHANG Siyuan, LI Xianying, SHEN Xiaoyun, ADS-B IN based conflict prediction and conflict-free trajectory planning for multi-aircraft[J]. Journal of System Simulation, 2019, 31(8):1627-1635. doi: 10.16182/j.issn1004731x.joss.17-0266
[4]	郝敬堂, 苏志刚. 基于高斯积分的航空器冲突概率计算方法[J]. 中国安全科学学报, 2018, 28(8):123-128. doi: 10.16265/j.cnki.issn1003-3033.2018.08.021
	HAO Jingtang, SU Zhigang, Method for calculating probability of conflict between aircrafts based on Gaussian quadrature[J]. China Safety Science Journal, 2018, 28(8):123-128. doi: 10.16265/j.cnki.issn1003-3033.2018.08.021
[5]	OPROMOLLA R, FASANO G. Visual-based obstacle detection and tracking, and conflict detection for small UAS sense and avoid[J]. Aerospace Science and Technology, 2021, 119: DOI:10.1016/j.ast.2021.107167. doi: 10.1016/j.ast.2021.107167
[6]	HERNÁNDEZ R E, VALENZUELA A, RIVAS D. Probabilistic multi-aircraft conflict detection and resolution considering wind forecast uncertainty[J]. Aerospace Science and Technology, 2020, 105: DOI:10.1016/j.ast.2020.105973. doi: 10.1016/j.ast.2020.105973
[7]	TANG Xinmin, JI Xiaoqi, LI Teng. Key technology in multi-UAV conflict detection and resolution strategy[J]. Transactions of Nanjing University of Aeronautics and Astronautics, 2020, 37(2):175-186.
[8]	袁梦婷, 时宏伟. 基于ADS-B的无人机感知与规避蚁群算法模型[J]. 西北工业大学学报, 2021, 39(4):761-769.
	YUAN Mengting, SHI Hongwei. An ant colony algorithm model for UAV sense and avoid based on ADS-B[J]. Journal of Northwestern Polytechnical University, 2021, 39(4):761-769. doi: 10.1051/jnwpu/20213940761
[9]	张凯, 隋东, 邹国良. 可扩展的无人机多机飞行冲突解脱算法研究[J]. 航空计算技术, 2022, 52(2):62-66.
	ZHANG Kai, SUI Dong, ZOU Guoliang. Study on the scalable intelligent algorithm for UAV multi-actor conflict resolution[J]. Aeronautical Computing Technique, 2022, 52(2):62-66.
[10]	焦卫东, 姚军强, 王瑞东. 基于凸包围盒的飞行冲突检测算法[J]. 中国安全科学学报, 2021, 31(12):32-38. doi: 10.16265/j.cnki.issn 1003-3033.2021.12.005
	JIAO Weidong, YAO Junqiang, WANG Ruidong. Flight conflict detection algorithm based on convex bounding box[J]. China Safety Science Journal, 2021, 31(12):32-38. doi: 10.16265/j.cnki.issn 1003-3033.2021.12.005
[11]	王泽坤, 吴明功, 温祥西, 等. 基于速度障碍法的飞行冲突解脱与恢复策略[J]. 北京航空航天大学学报, 2019, 45(7):1294-1302.
	WANG Zekun, WU Minggong, WEN Xiangxi, et al. Flight collision resolution and recovery strategy based on velocity obstacle method[J]. Journal of Beijing University of Aeronautics and Astronautics, 2019, 45(7):1294-1302.
[12]	宫淑丽, 王帮峰, 吴红兰, 等. 基于IMM算法的机场场面运动目标跟踪[J]. 系统工程与电子技术, 2011, 33(10):2322-2326.
	GONG Shuli, WANG Bangfeng, WU Honglan et al. Tracking of moving targets on airport surface based on IMM algorithm[J]. Systems Engineering and Electronics, 2011, 33(10):2322-2326.
[13]	揭东, 汤新民, 李博, 等. 无人机冲突探测及解脱策略关键技术研究[J]. 武汉理工大学学报:交通科学与工程版, 2018, 42(5):776-782.
	JIE Dong, TANG Xinmin, LI Bo, et al. Research on key technologies of UAV conflict detection and resolution strategy[J]. Journal of Wuhan University of Technology:Transportation Science & Engineering, 2018, 42(5):776-782.
[14]	王莉莉, 阳杰. 基于位置误差概率模型的物流无人机安全间隔评估方法研究[J]. 中国安全生产科学技术, 2022, 18(3):184-192.
	WANG Lili, YANG Jie. Research on assessment method of safety separation for logistics UAVs based on position error probability model[J]. Journal of Safety Science and Technology, 2022, 18(3):184-192.
[15]	吴明功, 王泽坤, 温祥西, 等. 飞行冲突解脱的几何优化模型[J]. 系统工程与电子技术, 2019, 41(4):864-870.
	WU Minggong, WANG Zekun, WEN Xiangxi, et al. Aircraft conflict resolution model based on geometric optimization[J]. Systems Engineering and Electronics, 2019, 41(4):864-870.

场景		起点	航向/ (°)	速度/ (km·h^-1)	解脱方式
对头	UAV1	(0,1,1)	90	40	SOSA
对头	UAV2	(2,1,1)	270	40	SOSA
交叉	UAV1	(0,1,1)	76	40	SOSA
交叉	UAV2	(1,0,1)	14	40	SOSA
交叉	UAV1	(0,0.5,1)	63	40	调速
交叉	UAV2	(2,0.5,1)	297	40	调速
同向	UAV1	(0,2,0.1)	90	40	调高
同向	UAV2	(0.5,2,0.1)	90	20	不变

场景	求解时间/ s	原飞行距离/ km	绕飞增加距离/ km	绕飞增加距离占比/%	机动次数	冲突解脱用时/s
1	0.02	2.00	0.05	2.85	2	5.13
2	0.02	2.06	0.09	4.65	2	8.37
3	0.07	2.24	0	0	2	8.54
4	0.05	2.00	0.05	2.50	2	14.24

场景	冲突解脱点/km	航迹恢复点/km	切入原航迹点/km	切入原航迹时间/s
1	(0.97,1,1)	(1,1.04,1)	(1.03,1,1)	92.43
2	(1.24,1.21,1)	(1.31,1.24,1)	(1.42,1.30,1)	136.98
3	(0.98,0.92,1)	—	(1.02,1.08,1)	103.62
4	(0.92,2,0.1)	(1,2,0.13)	(1.08,2,0.1)	111.44