Vehicle SINS Positioning Algorithm Assisted by Velocity Constraint Based on Neural Network Modification

被引：0

作者：

Li Z. ^{[1
]}

Miao L. ^{[1
]}

Zhou Z. ^{[1
]}

Wu Z. ^{[1
]}

机构：

[1] College of Automation, Beijing Institute of Technology, Beijing

来源：

Yuhang Xuebao/Journal of Astronautics | 2022年 / 43卷 / 09期

关键词：

Adaptive filter; Neural network; Strapdown inertial navigation system (SINS); Velocity constraint;

D O I：

10.3873/j.issn.1000-1328.2022.09.011

中图分类号：

V355 [空中管制与飞行调度];

学科分类号：

摘要：

For the vehicle-mounted global navigation satellite system (GNSS)/strapdown inertial navigation system (SINS) integrated navigation system, aiming at the problem of gradual divergence of longitudinal position error of SINS assisted by velocity constraint when GNSS fails and SINS works alone, a vehicle SINS positioning algorithm assisted by velocity constraint based on neural network madification is proposed. The radial basis function (RBF) neural network is used to predict the correction coefficient of SINS longitudinal position error, so as to improve the positioning accuracy of SINS when working alone. In addition, an adaptive filtering algorithm for real-time measurement noise estimation with limited memory index weighting is proposed. The vehicle tests are carried out under artificially setting GNSS failures and real tunnel scenarios. The results show that the proposed algorithm can correct the longitudinal position error of SINS online without stopping. Compared with the conventional algorithm combining velocity constraint and Kalman filter, the positioning accuracy of vehicle SINS under GNSS failure is effectively improved. © 2022 China Spaceflight Society. All rights reserved.

引用

页码：1236 / 1245

页数：9

共 14 条

[1] CHEN C, CHANG G., Low-cost GNSS/INS integration for enhanced land vehicle performance, Measurement Science and Technology, 31, 3, (2019)
[2] YANG Z, LI Z, LIU Z, Et al., Improved robust and adaptive filter based on non-holonomic constraints for RTK/INS integrated navigation, Measurement Science and Technology, 32, 10, (2021)
[3] FU Qiangwen, QIN Yongyuan, LI Sihai, ZUPT method for vehicular SINS aided by velocity constraint [J], Journal of Systems Engineering and Electronics, 35, 8, pp. 1723-1728, (2013)
[4] HU Jie, YAN Yongjie, WANG Zihui, Vehicle integrated navigation based on velocity constraint and fuzzy adaptive filtering, Acta Armamentarii, 41, 2, pp. 231-238, (2020)
[5] HAN Yongqiang, WANG Xinjian, SUN Shoucai, Et al., A zero velocity update algorithm for vehicle SINS based on radial velocity residual curve-fitting, Journal of Chinese Inertial Technology, 28, 3, pp. 281-286, (2020)
[6] CHEN Yingqiu, KUANG Jian, NIU Xiaoji, Et al., Vehicle integrated navigation based on wheel mounted MEMS-IMU [J], Journal of Chinese Inertial Technology, 26, 6, pp. 799-804, (2018)
[7] LI Bowen, YAO Danya, Low-cost MEMS IMU navigation positioning method for land vehicle, Journal of Chinese Inertial Technology, 22, 6, pp. 719-723, (2014)
[8] WANG G, XU X, YAO Y, Et al., A novel BPNN-based method to overcome the GPS outages for INS/GPS system, IEEE Access, 7, pp. 82134-82143, (2019)
[9] HUANG Guanwen, CUI Bobin, ZHANG Qin, Et al., Real-time clock offset prediction model with periodicand neural network corrections, Journal of Astronautics, 29, 1, pp. 83-88, (2018)
[10] YANG Xixiang, YANG Xiaowei, DENG Xiaolong, Robust trajectory control method for stratospheric airships with combination of backstepping and neural network, Journal of Astronautics, 42, 3, pp. 351-358, (2021)

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