A Novel Ambiguity Parameter Estimation and Elimination Strategy for GNSS/INS Tightly Coupled Integration

In complex urban environments, a single Global Navigation Satellite System (GNSS) is often not ideal for navigation due to a lack of sufficient visible satellites. Additionally, the heading angle error of a GNSS/micro-electro-mechanical system–grade inertial measurement unit (MIMU) tightly coupled integration based on the single antenna is large, and the attitude angle, velocity, and position calculated therein all have large errors. Considering the above problems, this paper designs a tightly coupled integration of GNSS/MIMU based on two GNSS antennas and proposes a singular value decomposition (SVD)-based robust adaptive cubature Kalman filter (SVD-RACKF) according to the model characteristics of the integration. In this integration, the high-accuracy heading angle of the carrier is obtained through two antennas, and the existing attitude angle information is used as the observation to constrain the filtering estimation. The proposed SVD-RACKF uses SVD to stabilize the numerical accuracy of the recursive filtering. Furthermore, the three-stage equivalent weight function and the adaptive adjustment factor are constructed to suppress the influence of the gross error and the abnormal state on the parameter estimation, respectively. A set of real measured data was employed for testing and analysis. The results show that dual antennas and dual systems can improve the positioning performance of the integrated system to a certain extent, and the proposed SVD-RACKF can accurately detect the gross errors of the observations and effectively suppress them. Compared with the cubature Kalman filter, the proposed filtering algorithm is more robust, with higher accuracy and reliability of parameter estimation.

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“…The velocity error is caused by the difference between the calculated velocity and the real velocity. Its vector expression is [27,28] δ…”

Section: System Error Dynamic Modelmentioning

confidence: 99%

“…where f b indicates the specific force measured by the accelerometer; δf b represents the accelerometer deviation error vector; δg n indicates the local gravity error. Due to error transitivity, the position vector also has a certain deviation, which is modeled as [28] Remote Sens. 2021, 13,1943 4 of 18…”

Section: System Error Dynamic Modelmentioning

confidence: 99%

A Robust Adaptive Cubature Kalman Filter Based on SVD for Dual-Antenna GNSS/MIMU Tightly Coupled Integration

Pan

Qian

et al. 2021

Remote Sensing

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Variational Bayesian-based robust adaptive filtering for GNSS/INS tightly coupled positioning in urban environments

Ma,

Pan,

Gao

et al. 2023

Measurement

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Research on GNSS INS & GNSS/INS Integrated Navigation Method for Autonomous Vehicles: A Survey

Liu

2023

IEEE Access

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A Novel Ambiguity Parameter Estimation and Elimination Strategy for GNSS/INS Tightly Coupled Integration

Cited by 5 publications

References 30 publications

A Robust Adaptive Cubature Kalman Filter Based on SVD for Dual-Antenna GNSS/MIMU Tightly Coupled Integration

A Robust Adaptive Cubature Kalman Filter Based on SVD for Dual-Antenna GNSS/MIMU Tightly Coupled Integration

Variational Bayesian-based robust adaptive filtering for GNSS/INS tightly coupled positioning in urban environments

Research on GNSS INS & GNSS/INS Integrated Navigation Method for Autonomous Vehicles: A Survey

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