A distributed GNSS/SINS/odometer resilient fusion navigation method for land vehicle

doi:10.11947/j.AGCS.2024.20220349

Abstract

Abstract: To improve the fault-tolerance of a low-cost land vehicle navigation system in the complex environment, this paper proposes a distributed GNSS/SINS/odometer resilient fusion method based on the suboptimal gain fusion algorithm. First, a velocity compensation model for each odometer on four wheels is established according to the Ackermann steering geometry, which improves the accuracy of forward and lateral velocity measurement at the inertial measurement unit center. Then, a fault detection and classification criteria based on Chi-square test statistics is designed to make full use of the available observation information. Last, a resilient adjustment model for the stochastic model and information sharing factors (ISF) are proposed to mitigate the influence of abnormal observation from the sensor layer and the decision layer respectively and realize the resilient fusion of multi-source information. A real car test is carried out to verify the effectiveness of the distributed GNSS/SINS/odometer resilient fusion method. The experiment results demonstrate that the proposed method can effectively reduce the impact of subsystem faults on the global state estimation and improve the fault tolerance performance of the system in complex environments. Moreover, compared with the traditional federated Kalman filtering (FKF), the SGF algorithm can achieve the equivalent accuracy with significant computational efficiency improvement, which is conducive to the practical engineering application of multi-source information resilient fusion.

Key words: multi-information resilient fusion, GNSS/SINS/odometer fusion, odometer velocity compensation model, suboptimal gain fusion, distributed filter

CLC Number:

P228

MU Mengxue, ZHAO Long. A distributed GNSS/SINS/odometer resilient fusion navigation method for land vehicle[J]. Acta Geodaetica et Cartographica Sinica, 2024, 53(3): 425-434.

References

[1] SKOG I, HÄNDEL P. In-car positioning and navigation technologies:a survey[J]. IEEE Transactions on Intelligent Transportation Systems, 2009, 10(1):4-21.
[2] 杨元喜. 弹性PNT基本框架[J]. 测绘学报, 2018, 47(7):893-898.DOI:10.11947/j.AGCS.2018.20180149. YANG Yuanxi. Resilient PNT concept frame[J]. Acta Geodaetica et Cartographica Sinica, 2018, 47(7):893-898.DOI:10.11947/j.AGCS.2018.20180149.
[3] GROVES P D, WANG Lei, WALTER D, et al. The four key challenges of advanced multisensor navigation and positioning[C]//Proceedings of 2014 IEEE/ION Position, Location and Navigation Symposium. Monterey:IEEE, 2014.
[4] CHIANG Kaiwei, CHANG H W, LI Yuhua, et al. Assessment for INS/GNSS/odometer/barometer integration in loosely-coupled and tightly-coupled scheme in a GNSS-degraded environment[J]. IEEE Sensors Journal, 2020, 20(6):3057-3069.
[5] LI Zengke, WANG Jian, LI Binghao, et al. GPS/INS/odometer integrated system using fuzzy neural network for land vehicle navigation applications[J]. Journal of Navigation, 2014, 67(6):967-983.
[6] WANG Maosong, WU Wenqi, HE Xiaofeng, et al. Consistent ST-EKF for long distance land vehicle navigation based on SINS/OD integration[J]. IEEE Transactions on Vehicular Technology, 2019, 68(11):10525-10534.
[7] FU Qiangwen, LIU Yang, LIU Zhenbo, et al. High-accuracy SINS/LDV integration for long-distance land navigation[J]. IEEE/ASME Transactions on Mechatronics, 2018, 23(6):2952-2962.
[8] LI Leilei, SUN Hongxing, YANG Sheng, et al. Online calibration and compensation of total odometer error in an integrated system[J]. Measurement, 2018, 123:69-79.
[9] ALOFI A, ALGHAMDI A, ALAHMADI R, et al. A review of data fusion techniques[J]. International Journal of Computer Applications, 2017, 167(7):37-41.
[10] KHALEGHI B, KHAMIS A, KARRAY F O, et al. Multisensor data fusion:a review of the state-of-the-art[J]. Information Fusion, 2013, 14(1):28-44.
[11] DENG Zili, ZHANG Peng, QI Wenjuan, et al. Sequential covariance intersection fusion Kalman filter[J]. Information Sciences, 2012, 189:293-309.
[12] 从金亮, 李银伢, 戚国庆, 等. 快速协方差交叉融合算法及应用[J]. 自动化学报, 2020, 46(7):1433-1444. CONG Jinliang, LI Yinya, QI Guoqing, et al. A fast covariance intersection fusion algorithm and its application[J]. Acta Automatica Sinica, 2020, 46(7):1433-1444.
[13] SHEN Kai, WANG Meiling, FU Mengyin, et al. Observability analysis and adaptive information fusion for integrated navigation of unmanned ground vehicles[J]. IEEE Transactions on Industrial Electronics, 2020, 67(9):7659-7668.
[14] LI Xu, ZHANG Weigong. An adaptive fault-tolerant multisensor navigation strategy for automated vehicles[J]. IEEE Transactions on Vehicular Technology, 2010, 59(6):2815-2829.
[15] XING Zirui, XIA Yuanqing. Distributed federated Kalman filter fusion over multi-sensor unreliable networked systems[J]. IEEE Transactions on Circuits and Systems I:Regular Papers, 2016, 63(10):1714-1725.
[16] CARLSON N A. Federated square root filter for decentralized parallel processors[J]. IEEE Transactions on Aerospace and Electronic Systems, 1990, 26(3):517-525.
[17] ZHANG Xinchun, CUI Ximin, HUANG Bo. The design and implementation of an inertial GNSS odometer integrated navigation system based on a federated Kalman filter for high-speed railway track inspection[J]. Applied Sciences, 2021, 11(11):5244.
[18] KIM J, JEE G I, LEE J G. A federated Kalman filter design using a gain fusion algorithm[C]//Proceedings of 1998 IFAC Symposium on Automatic Control in Aerospace. Seoul:Elsevier, 1998:385-391.
[19] RAI N, ARORA N. Performance evaluation of Kalman filter sensor fusion based algorithm and gain fusion based algorithm[J]. International Journal for Scientific Research & Development, 2014, 2(3):2321-0613.
[20] HU Gaoge, GAO Shesheng, ZHONG Yongmin, et al. Modified federated Kalman filter for INS/GNSS/CNS integration[J]. Journal of Aerospace Engineering, 2016, 230(1):30-44.
[21] PAIK B S, OH J H. Gain fusion algorithm for decentralised parallel Kalman filters[J]. IEE Proceedings-Control Theory and Applications, 2000, 147(1):97-103.
[22] WANG Rong, XIONG Zhi, LIU Jianye, et al. Chi-square and SPRT combined fault detection for multisensor navigation[J]. IEEE Transactions on Aerospace Electronic Systems, 2016, 52(3):1352-1365.
[23] XU Bo, LI Shengxin, RAZZAQI A A, et al. A novel measurement information anomaly detection method for cooperative localization[J]. IEEE Transactions on Instrumentation and Measurement, 2021, 70:1-18.
[24] JIANG Wei, LIU Dan, CAI Baigen, et al. A fault-tolerant tightly coupled GNSS/INS/OVS integration vehicle navigation system based on an FDP algorithm[J]. IEEE Transactions on Vehicular Technology, 2019, 68(7):6365-6378.
[25] WANG Qiuying, CUI Xufei, LI Yibing, et al. Performance enhancement of a USV INS/CNS/DVL integration navigation system based on an adaptive information sharing factor federated filter[J]. Sensors, 2017, 17(2):239.
[26] XU Jianxin, XIONG Zhi, LIU Jianye, et al. A dynamic vector-formed information sharing algorithm based on two-state Chi Square detection in an adaptive federated filter[J]. Journal of Navigation, 2019, 72(1):101-120.
[27] LYU Xu, HU Baiqing, WANG Zheng, et al. A SINS/GNSS/VDM integrated navigation fault-tolerant mechanism based on adaptive information sharing factor[J]. IEEE Transactions on Instrumentation and Measurement, 2022, 71:3147335.
[28] NOURMOHAMMADI H, KEIGHOBADI J. Design and experimental evaluation of indirect centralized and direct decentralized integration scheme for low-cost INS/GNSS system[J]. GPS Solutions, 2018, 22(3):65.