运动参数辅助的无人机单站机会信号定位方法

doi:10.19665/j.issn1001-2400.2022.03.012

Abstract

Abstract:

The current estimation of the position of drones relies heavily on the Global Navigation Satellite System (GNSS).To solve this problem,a Single Station Positioning of Opportunity Signals Aided by Kinetic Parameters (SPoKP) is proposed.This paper gives the detailed steps of establishing the motion state transfer equation and position estimation output equation,deduces the observability condition for drones position estimation,and gives the method for motion parameter estimation and error suppression by setting the variable adaptive smoothing window,with the decision threshold for window setting given.Finally by relying on the recursion of the motion state and a single ranging radio frequency signal station,the estimation of positions of the drones in different motion states is realized.Theoretical simulation shows that in the environment where the navigation satellite system refuses,the single-station positioning algorithm for the radio frequency opportunistic signal assisted by dynamic parameters can achieve robust positioning of drones in different motion states,which can meet routine tasks such as delivery,drones cruise and reconnaissance and that the actual test using the ultra-wideband (UWB) signal beacon further verifies the accuracy and effectiveness of the proposed method.Compared with the navigation satellite system,the positioning root mean square error of the proposed algorithm is only 2.7 m,which verifies the feasibility of drones using opportunistic signals to achieve higher-precision positioning in a denial environment,and reduces the drones’ dependence on sensors of traditional navigation and positioning systems.

Key words: unmanned aerial vehicle, Kinetic parameters, signal of opportunity, observability, single-station positioning

CLC Number:

TN961

BIAN Zhi’ang,LU Hu,SHI Haodong. Research on the drones single station opportunistic signal positioning method aided by motion parameters[J].Journal of Xidian University, 2022, 49(3): 101-110.

Figures/Tables 5

References 21

[1]	KHALIFE J, KASSAS Z. Assessment of Differential Carrier Phase Measurements from Orbcomm LEO Satellite Signals for Opportunistic Navigation[C]// Proceedings of the 32nd International Technical Meeting of the Satellite Division of The Institute of Navigation.Manassas:ION, 2019:4053-4063.
[2]	SHAMAEI K, KHALIFE J, KASSAS Z M. Exploiting LTE Signals for Navigation:Theory to Implementation[J]. IEEE Transactions on Wireless Communications, 2018, 17(4):2173-2189. doi: 10.1109/TWC.2018.2789882
[3]	FENG D, WANG C, HE C, et al. Kalman-Filter-Based Integration of IMU and UWB for High-Accuracy Indoor Positioning and Navigation[J]. IEEE Internet of Things Journal, 2020, 7(4):3133-3146. doi: 10.1109/JIOT.2020.2965115
[4]	KHALIFE J, KASSAS Z M. Navigation with Cellular CDMA Signals-Part II:Performance Analysis and Experimental Results[J]. IEEE Transactions on Signal Processing, 2018, 66(8):2204-2218. doi: 10.1109/TSP.2018.2799166
[5]	MORALES J J, KASSAS Z M. Tightly Coupled Inertial Navigation System with Signals of Opportunity Aiding[J]. IEEE Transactions on Aerospace and Electronic Systems, 2021, 57(3):1930-1948. doi: 10.1109/TAES.2021.3054067
[6]	黄高明, 景桐, 田威. 机会信号导航综述[J]. 控制与决策, 2019, 34(6):1121-1131.
	HUANG Gaoming, JING Tong, TIAN Wei. Survey on Navigation via Signal of Opportunity[J]. Control and Decision, 2019, 34(6):1121-1131.
[7]	ZHANG F, SUN Y, WAN Q. Calibrating the Error from Sensor Position Uncertainty in TDOA-AOA Localization[J]. Signal Processing, 2020, 166:107213. doi: 10.1016/j.sigpro.2019.07.006
[8]	ZHANG F, LI M, SUN Y, et al. A TDOA-FDOA Localization Method in Closed-form Based on Deviation Refining[C]// 2019 11th International Conference on Wireless Communications and Signal Processing.Piscataway:IEEE, 2019:1-5.
[9]	闫千里, 万鹏武, 卢光跃, 等. 非视距环境下RSS和TDOA联合的信源被动定位[J]. 西安电子科技大学学报, 2019, 46(3):180-188.
	YAN Qianli, WAN Pengwu, LU Guangyue, et al. Passive Localization of the Signal Source Based on RSS and TDOA Combinationin the Non-Line-of-Sight Environment[J]. Journal of Xidian University, 2019, 46(3):180-188.
[10]	KIM O J, KEE C. Single Station-Based Precise Positioning System:Multiple-Antenna Arrangement for Instantaneous Ambiguity Resolution[J]. Navigation-Journal of the Institute of Navigation, 2019, 66(4):747-768. doi: 10.1002/navi.329
[11]	MAKI T, MATSUDA T, SAKAMAKI T, et al. Navigation Method for Underwater Vehicles Based on Mutual Acoustical Positioning with a Single Seafloor Station[J]. IEEE Journal of Oceanic Engineering, 2013, 38(1):167-177. doi: 10.1109/JOE.2012.2210799
[12]	王春琦, 孔祥琦, 丁晓欢, 等. 基于无迹卡尔曼滤波的IMU和UWB融合定位算法研究[J]. 南昌航空大学学报:自然科学版, 2020, 34(3):8-17.
	WANG Chunqi, KONG Xiangqi, DING Xiaohuan, et al. Unscented Kalman Filter Based IMU and UWB Fusion Position Algorithm[J]. Journal of Nanchang Hangkong University:Natural Sciences, 2020, 34(3):8-17.
[13]	邢怀玺, 张宇晖, 陈游, 等. 基于MCIS技术的相位差变化率单站无源定位[J]. 航空学报, 2021, 42(3):359-371.
	XING Huaixi, ZHANG Yuhui, CHEN You, et al. Single Station Passive Location with Phase Difference Change Rate Based on MCIS Technology[J]. Acta Aeronautica et Astronautica Sinica, 2021, 42(3):359-371.
[14]	JINSEUK K, HWANG S, JIN X. A Study on Fuzzy Interacting Multiple Model Algorithm for Maneuvering Target Tracking[J]. Journal of the Korea Institute of Military Science and Technology, 2004, 7(4):5-12.
[15]	SHI Q, CUI X, ZHAO S, et al. Range-Only Collaborative Localization for Ground Vehicles[C]// Proceedings of the 32nd International Technical Meeting of the Satellite Division of The Institute of Navigation.Manassas:ION, 2019:2063-2077.
[16]	ZHANG J. The Calculating Formulae,and Experimental Methods in Error Propagation Analysis[J]. IEEE Transactions on Reliability, 2006, 55(2):169-181. doi: 10.1109/TR.2006.874920
[17]	饶鑫平. 基于迁移学习的室内设备无关被动指纹定位研究[D]. 西安: 西安电子科技大学, 2020.
[18]	刘莹. 基于深度学习的轨迹预测[D]. 成都: 电子科技大学, 2019.
[19]	HOU Z, BU F. A Small UAV Tracking Algorithm Based on AIMM-UKF[J]. Aircraft Engineering and Aerospace Technology, 2021, 93(4):579-591. doi: 10.1108/AEAT-01-2019-0013
[20]	张召友, 郝燕玲, 吴旭. 3种确定性采样非线性滤波算法的复杂度分析[J]. 哈尔滨工业大学学报, 2013, 45(12):111-115.
	ZHANG Shaoyou, HAO Yanling, WU Xu. Complexity Analysis of Three Deterministic Sampling Nonlinear Filtering Algorithms[J]. Journal of Harbin Institute of Technology, 2013, 45(12):111-115.
[21]	KHAN S, AHMMED K. Where Am I? Autonomous Navigation System of a Mobile Robot in an Unknown Environment[C]// 2016 5th International Conference on Informatics,Electronics and Vision.Piscataway:IEEE, 2016:56-61.

仿真参数	参数值
定位维度	二维
量测噪声δ(标准差)	0.005 m/0.005 rad
线性运动判断阈值/m	0.1
静止状态判断阈值/m	0.001
基站位置	(0,0)
无人机初始位置/m	(10,0)
无人机各段目标线速度/(m·s^-1)	0,1.6,4.4,4.2,3.6,7.1
采样时间/s	0.005
速度估计自适应平滑窗口初始大小	5

Research on the drones single station opportunistic signal positioning method aided by motion parameters

RichHTML

PDF (PC)

Like

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 5

References 21

Related Articles 7

Metrics

Comments

Recommended 10

[1]	YANG Xin,MAO Yaqi,WANG Ling. MAC protocol for the dense wireless network of UAV assisted communication [J]. Journal of Xidian University, 2022, 49(3): 10-20.
[2]	TIAN Lin,SU Zhijie,FENG Wanmei,CHEN Zhen,TANG Jie,ZHOU Encheng. Trajectory and resource allocation for multi-UAV enabled swipt systems [J]. Journal of Xidian University, 2021, 48(6): 115-122.
[3]	WANG Haijun,ZHANG Shengyan,DU Yujie. UAV object tracking via the correlation filter with the response divergence constraint [J]. Journal of Xidian University, 2021, 48(5): 149-155.
[4]	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.
[5]	MA Xiao;ZHANG Hailin;HAO Benjian;WAN Pengwu. Method for the estimation of the scanning cycle for countering the reconnaissance radar [J]. Journal of Xidian University, 2018, 45(4): 161-165+180.
[6]	LI Dongxia;LI Chunming;ZHAO Wenqiang;LIU Haitao. Trajectory optimization method for the UAV relaying broadcast communication system [J]. Journal of Xidian University, 2018, 45(3): 143-148+180.
[7]	XI Qing-biao1;YUAN Dong-li2;YAN Jian-guo2. A problem on the UAV navigation system based on multi-model variable structure intelligent control [J]. J4, 2004, 31(4): 644-647.