UWB-INS Fusion Positioning Based on a Two-Stage Optimization Algorithm

被引:1
作者
Liu, Yiran [1 ]
Zhang, Yushan [1 ]
Jiang, Yan [2 ]
Liu, Weiping [1 ]
Yang, Fenghao [3 ]
机构
[1] China Acad Railway Sci Corp Ltd, 2 Daliushu Rd, Beijing, Peoples R China
[2] China Railway Beijing Grp Corp Ltd, 6 Fuxing Rd, Beijing, Peoples R China
[3] Beijing Univ Posts & Telecommun, 10 Xitucheng Rd, Beijing, Peoples R China
来源
TEHNICKI VJESNIK-TECHNICAL GAZETTE | 2023年 / 30卷 / 01期
关键词
inertial navigation system; Kalman filter; machine learning; optimal estimation; UWB; IDENTIFICATION; MITIGATION;
D O I
10.17559/TV-20221019035741
中图分类号
T [工业技术];
学科分类号
08 ;
摘要
Ultra-wideband (UWB) is a carrier-less communication technology that transmits data using narrow pulses of non-sine waves on the nanosecond scale. The UWB positioning system uses the multi-lateral positioning algorithm to accurately locate the target, and the positioning accuracy is seriously affected by the non-line-of-sight (NLOS) error. The existing non-line-of-sight error compensation methods lack multidimensional consideration. To combine the advantages of various methods, a two-stage UWB-INS fusion localization algorithm is proposed. In the first stage, an NLOS signal filter is designed based on support vector machines (SVM). In the second stage, the results of UWB and Inertial Navigation System (INS) are fused based on Kalman filter algorithm. The two-stage fusion localization algorithm achieves a great improvement on positioning system, it can improve the localization accuracy by 79.8% in the NLOS environment and by 36% in the (line-of-sight) LOS environment.
引用
收藏
页码:185 / 190
页数:6
相关论文
共 50 条
[31]   A Genetic-Algorithm-based Two-Stage Learning Scheme for Neural Networks [J].
Wang, Shuo ;
Zhang, Xiaomeng ;
Zheng, Xuanyan ;
Yuan, Bingzhi .
2010 INTERNATIONAL CONFERENCE ON E-EDUCATION, E-BUSINESS, E-MANAGEMENT AND E-LEARNING: IC4E 2010, PROCEEDINGS, 2010, :391-394
[32]   UWB/INS-based robust anchor-free relative positioning scheme for UGVs [J].
Zhang, Haifeng ;
Li, Zhitian ;
Zheng, Shuaikang ;
Liu, Yunfei ;
Zheng, Pengcheng ;
Zou, Xudong .
MEASUREMENT SCIENCE AND TECHNOLOGY, 2022, 33 (12)
[33]   Improvement and Verification for Combined Positioning Algorithm Based on UWB and Inertial Navigation [J].
Zhao, Hongliang ;
Gao, Shaofu ;
Hou, Weiyan .
PROCEEDINGS OF THE 2016 6TH INTERNATIONAL CONFERENCE ON MANAGEMENT, EDUCATION, INFORMATION AND CONTROL (MEICI 2016), 2016, 135 :811-815
[34]   TDOA-TWR based positioning algorithm for UWB localization system [J].
Kolakowski, Marcin ;
Djaja-Josko, Vitomir .
2016 21ST INTERNATIONAL CONFERENCE ON MICROWAVE, RADAR AND WIRELESS COMMUNICATIONS (MIKON), 2016,
[35]   Optimization of UWB indoor positioning based on hardware accelerated Fuzzy ISODATA [J].
Guo, Hua ;
Song, Shanshan ;
Yin, Haozhou ;
Ren, Daokuan ;
Zhu, Xiuwei .
SCIENTIFIC REPORTS, 2024, 14 (01)
[36]   UWB Positioning Algorithm Based on Fuzzy Inference and Adaptive Anti-NLOS Kalman Filtering [J].
Wu, Junkang ;
Zhang, Zuqiong ;
Zhang, Shenglan ;
Kuang, Zhenwu ;
Zhang, Lieping .
APPLIED SCIENCES-BASEL, 2022, 12 (12)
[37]   WiFi FTM, UWB and Cellular-Based Radio Fusion for Indoor Positioning [J].
Alvarez-Merino, Carlos S. ;
Luo-Chen, Hao Qiang ;
Khatib, Emil Jatib ;
Barco, Raquel .
SENSORS, 2021, 21 (21)
[38]   Research on the UWB/IMU fusion positioning of mobile vehicle based on motion constraints [J].
Li, Xin ;
Wang, Yang .
ACTA GEODAETICA ET GEOPHYSICA, 2020, 55 (02) :237-255
[39]   Human-Centric Autonomous Driving Based on a Two-Stage Machine Learning Algorithm [J].
Sarker, Md Abdul Latif ;
Han, Dong Seog .
2022 27TH ASIA PACIFIC CONFERENCE ON COMMUNICATIONS (APCC 2022): CREATING INNOVATIVE COMMUNICATION TECHNOLOGIES FOR POST-PANDEMIC ERA, 2022, :334-335
[40]   An INS and UWB Fusion-Based Gyroscope Drift Correction Approach for Indoor Pedestrian Tracking [J].
Tian, Qinglin ;
Wang, Kevin I-Kai ;
Salcic, Zoran .
SENSORS, 2020, 20 (16) :1-16
12345