Design of GNSS/INS Coupled Navigation Algorithm Using Adaptive Neuro-Fuzzy Inference Systems

作者

  • Chen Zerui Guizhou Power Grid Co. Ltd. Electric Power Science Research Institute, Guizhou, Guiyang 550002, China
  • Xiao Yanhong Guizhou Power Grid Co. Ltd. Electric Power Science Research Institute, Guizhou, Guiyang 550002, China
  • Wu Xin Guizhou Power Grid Co. Ltd. Electric Power Science Research Institute, Guizhou, Guiyang 550002, China
  • Hu Houpeng Guizhou Power Grid Co. Ltd. Electric Power Science Research Institute, Guizhou, Guiyang 550002, China
  • Xiao Jian Guizhou Power Grid Co. Ltd. Electric Power Science Research Institute, Guizhou, Guiyang 550002, China
  • Yang Shang Guizhou Power Grid Co. Ltd. Electric Power Science Research Institute, Guizhou, Guiyang 550002, China
  • Gao Zhenghao Guizhou Power Grid Co. Ltd. Electric Power Science Research Institute, Guizhou, Guiyang 550002, China

##plugins.pubIds.doi.readerDisplayName##:

https://doi.org/10.13052/2024.ACES.J.400808

关键词:

Adaptive neuro-fuzzy inference system, data fusion, GNSS/INS coupled navigation, signal loss, system robustness

摘要

Traditional GNSS/INS (Global Navigation Satellite Systems/Inertial Navigation Systems) coupled navigation algorithms often struggle with accuracy in GNSS-denied or challenging environments. This paper introduces a novel adaptive fusion algorithm leveraging an Adaptive Neuro-Fuzzy Inference System (ANFIS) that dynamically adjusts sensor weightings based on real-time signal quality and system performance. The core innovation lies in the real-time integration of fuzzy logic and neural network learning, enabling the system to continuously adapt and optimize its decision-making rules for navigation accuracy. A comprehensive, dynamic error source model is constructed incorporating GNSS atmospheric delays, orbit errors, and INS drift to enhance the learning-driven weight adjustment mechanism. The resulting ANFIS-based fusion strategy shows significant superiority over traditional Kalman-based methods, achieving over 90% robustness across harsh scenarios with an average execution time of 0.69 seconds, demonstrating improved adaptability, learning capability, and fault resilience in dynamic environments.

##plugins.generic.usageStats.downloads##

##plugins.generic.usageStats.noStats##

##submission.authorBiographies##

##submission.authorWithAffiliation##

Chen Zerui received his M.E. degree in Computer Science and Technology from Guizhou University, China, in 2018. He currently works at the Power Science Research Institute of Guizhou Power Grid Co. Ltd. His research interests include algorithmic game theory, blockchain, information security, and AI security.

##submission.authorWithAffiliation##

Xiao Yanhong , born April 1976, is a senior engineer at the Electric Power Science Research Institute of Guizhou Power Grid Co. Ltd. She is of Han nationality and originally from Fuquan, Guizhou, China. Her research interests include network security testing and online monitoring technology for power grids.

##submission.authorWithAffiliation##

Wu Xin, born October 1976, is an engineer at the Electric Power Science and Technology Research Institute of Guizhou Power Grid Co. Ltd. He holds a bachelor’s degree and is of Han nationality, originally from Jinhua, Zhejiang. His research interests include information technology and big data applications.

##submission.authorWithAffiliation##

Hu Houpeng was born in 1992 and is a postgraduate student. His main research direction is electric vehicle charging and replacement technology.

##submission.authorWithAffiliation##

Xiao Jian , born in 1993, is currently an Engineer at the Electric Power Research Institute, Guizhou Power Grid Company Ltd., Guiyang, China. He received his Ph.D. in Information and Communication Engineering from Harbin Engineering University. His research interests include power artificial intelligence and power big data analytics.

##submission.authorWithAffiliation##

Yang Shang was born in 1997 in Tianzhu, Guizhou, China. He received his master’s degree from North China Electric Power University and is currently working at China Southern Power Grid Company Limited. His research interests include communication technology, artificial intelligence, and big data analysis.

##submission.authorWithAffiliation##

Gao Zhenghao , male, born August 1979, is a senior engineer. He graduated in 2002 from the Department of Computer Science at Guizhou University, China, majoring in Computer Applications. Since July 2002, he has been working at the IoT Application Technology Research Center of the Electric Power Research Institute, focusing on information technology, power monitoring system development, network security, and communication technology research.

参考

E. S. Abdolkarimi and M. R. Mosavi, “A modified neuro-fuzzy system for accuracy improvement of low-cost MEMS-based INS/GPS navigation system,” Wirel. Pers. Commun., vol. 129, no. 2, pp. 1369-1392, 2023.

L. Cong, S. Yue, H. Qin, B. Li, and J. Yao, “Implementation of a MEMS-based GNSS/INS integrated scheme using supported vector machine for land vehicle navigation,” IEEE Sensors J., vol. 20, no. 23, pp. 14423-14435, 2020.

Y. Xiao, H. Luo, F. Zhao, F. Wu, X. Gao, Q. Wang, and L. Cui, “Residual attention network-based confidence estimation algorithm for non-holonomic constraint in GNSS/INS integrated navigation system,” IEEE Trans. Veh. Technol., vol. 70, no. 11, pp. 11404-11418, 2021.

R. Sun, G. Wang, Z. Fan, T. Xu, and W. Y. Ochieng, “An integrated urban positioning algorithm using matching, particle swarm optimized adaptive neuro fuzzy inference system and a spatial city model,” IEEE Trans. Veh. Technol., vol. 69, no. 5, pp. 4842-4854, 2020.

E. S. Abdolkarimi and M. R. Mosavi, “Impact assessment of efficient denoising techniques in AI-based low-cost INS/GPS integration during blockage of GPS satellites,” Arab J. Sci. Eng., vol. 47, no. 11, pp. 14583-14600, 2022.

W. Jiang, Y. Yu, K. Zong, B. Cai, C. Rizos, J. Wang, S. Shangguan, and W. Shangguan, “A seamless train positioning system using a LiDAR-aided hybrid integration methodology,” IEEE Trans. Veh. Technol., vol. 70, no. 7, pp. 6371-6384,2021.

Y. Yuan, Y. Wang, W. Gao, and F. Shen, “Vehicular relative positioning with measurement outliers and GNSS outages,” IEEE Sensors J., vol. 23, no. 8, pp. 8556-8567, 2023.

Y. Li, R. Chen, X. Niu, Y. Zhuang, Z. Gao, X. Hu, and N. El-Sheimy, “Inertial sensing meets machine learning: Opportunity or challenge?” IEEE Trans. Intell. Transp. Syst., vol. 23, no. 8, pp. 9995-10011, 2021.

B. Zhu, X. Tao, J. Zhao, M. Ke, H. Wang, and W. Deng, “An integrated GNSS/UWB/DR/VMM positioning strategy for intelligent vehicles,” IEEE Trans. Veh. Technol., vol. 69, no. 10, pp. 10842-10853, 2020.

M. N. Cahyadi, T. Asfihani, H. F. Suhandri, and R. Erfianti, “Unscented Kalman filter for a low-cost GNSS/IMU-based mobile mapping application under demanding conditions,” Geodesy Geodyn., vol. 15, no. 2, pp. 166-176, 2024.

C. Zhang, X. Zhao, C. Pang, Y. Wang, L. Zhang, and B. Feng, “Improved fault detection method based on robust estimation and sliding window test for INS/GNSS integration,” J. Navig., vol. 73, no. 4, pp. 776-796, 2020.

A. Siemuri, K. Selvan, H. Kuusniemi, P. Valisuo, and M. S. Elmusrati, “A systematic review of machine learning techniques for GNSS use cases,” IEEE Trans. Aerosp. Electron. Syst., vol. 58, no. 6, pp. 5043-5077, 2022.

J. Wu, “An innovative neural-fuzzy adaptive Kalman filter for ultra-tightly-coupled GPS/INS integrated system,” in AOPC 2017: Space Optics and Earth Imaging and Space Navigation, vol. 10463, pp. 75-80, Oct. 2017.

X. Lai, S. Tong, and G. Zhu, “Adaptive fuzzy neural network-aided progressive Gaussian approximate filter for GPS/INS integration navigation,” Measurement, vol. 200, p. 111641, 2022.

S. Yue, L. Cong, H. Qin, B. Li, and J. Yao, “A robust fusion methodology for MEMS-based land vehicle navigation in GNSS-challenged environments,” IEEE Access, vol. 8, pp. 44087-44099, 2020.

G. Wang, Y. Han, J. Chen, S. Wang, Z. Zhang, N. Du, and Y. Zheng, “A GNSS/INS integrated navigation algorithm based on Kalman filter,” IFAC-PapersOnLine, vol. 51, no. 17, pp. 232-237, 2018.

A. E. Mahdi, A. Azouz, A. Noureldin, and A. Abosekeen, “A novel machine learning-based ANFIS calibrated RISS/GNSS integration for improved navigation in urban environments,” Sensors, vol. 24, no. 6, p. 1985, 2024.

D. Wang, Y. Dong, Z. Li, Q. Li, and J. Wu, “Constrained MEMS-based GNSS/INS tightly-coupled system with robust Kalman filter for accurate land vehicular navigation,” IEEE Trans. Instrum. Meas., vol. 69, no. 7, pp. 5138-5148, 2019.

B. R. Gudivaka and M. Thanjaivadivel, “IoT-driven signal processing for enhanced robotic navigation systems,” Int. J. Eng. Technol. Res. Manag., vol. 4, no. 5, 2020.

R. Sun, D. Xue, and Y. Zhang, “Rear-end collision detection based on GNSS/compass fusion and adaptive neuro fuzzy inference system,” in 2017 Forum on Cooperative Positioning and Service (CPGPS), pp. 273-277, May 2017.

H. Zhao and Z. Yang, “A novel fault detection and exclusion method for applying low-cost INS/GNSS integrated navigation system in urban environments,” IEEE Trans. Intell. Transp. Syst., vol. 26, pp. 143-156, 2024.

D. J. Jwo, A. Biswal, and I. A. Mir, “Artificial neural networks for navigation systems: A review of recent research,” Appl. Sci., vol. 13, no. 7, p. 4475, 2023.

F. Wu, H. Luo, F. Zhao, L. Wei, and B. Zhou, “Optimizing GNSS/INS integrated navigation: A deep learning approach for error compensation,” IEEE Signal Process. Lett., vol. 31, pp. 3104-3108,2024.

Y. Zhang and L. Wang, “A hybrid intelligent algorithm DGP-MLP for GNSS/INS integration during GNSS outages,” J. Navig., vol. 72, no. 2, pp. 375-388, 2019.

C. Guo and W. Tu, “A novel self-learning GNSS/INS integrated navigation method,” in Proc. 34th Int. Tech. Meeting Satellite Div. Inst. Navig. (ION GNSS+), pp. 168-179, Sep. 2021.

##submission.downloads##

已出版

2025-08-30

##submission.howToCite##

[1]
C. . Zerui, 《Design of GNSS/INS Coupled Navigation Algorithm Using Adaptive Neuro-Fuzzy Inference Systems》, ACES Journal, 卷 40, 期 08, 页 755–766, 8月 2025.

2025: Vol 40 Iss 8

栏目

Advanced Computation with High Performance Computing for Mechanics of Materials

##category.category##