Integrated autonomous optical navigation using Q-Learning extended Kalman filter
Aircraft Engineering and Aerospace Technology
ISSN: 0002-2667
Article publication date: 14 February 2022
Issue publication date: 26 April 2022
Abstract
Purpose
This paper aims to improve the performance of the autonomous optical navigation using relativistic perturbation of starlight, which is a promising technique for future space missions. Through measuring the change in inter-star angle due to the stellar aberration and the gravitational deflection of light with space-based optical instruments, the position and velocity vectors of the spacecraft can be estimated iteratively.
Design/methodology/approach
To enhance the navigation performance, an integrated optical navigation (ION) method based on the fusion of both the inter-star angle and the inter-satellite line-of-sight measurements is presented. A Q-learning extended Kalman filter (QLEKF) is designed to optimize the state estimate.
Findings
Simulations illustrate that the integrated optical navigation outperforms the existing method using only inter-star angle measurement. Moreover, the QLEKF is superior to the traditional extended Kalman filter in navigation accuracy.
Originality/value
A novel ION method is presented, and an effective QLEKF algorithm is designed for information fusion.
Keywords
Acknowledgements
This study was supported in part by Civil Aerospace Advance Research Project (D020403) and National Natural Science Foundation of China (U21B6001).
Citation
Xiong, K., Wei, C. and Zhou, P. (2022), "Integrated autonomous optical navigation using Q-Learning extended Kalman filter", Aircraft Engineering and Aerospace Technology, Vol. 94 No. 6, pp. 848-861. https://doi.org/10.1108/AEAT-05-2021-0139
Publisher
:Emerald Publishing Limited
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