Recursive adaptive filter using current innovation for celestial navigation during the Mars approach phase

Celestial navigation is a commonly used autonomous navigation technique for deep space navigation. A nonlinear filter such as the unscented Kalman filter (UKF) is typically applied in a celestial navigation system (CNS). However, on account of being subject to a number of factors, such as ephemeris...

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Bibliographic Details
Published inScience China. Information sciences Vol. 60; no. 3; pp. 164 - 178
Main Authors Ning, Xiaolin, Li, Zhuo, Wu, Weiren, Yang, Yuqing, Fang, Jiancheng, Liu, Gang
Format Journal Article
LanguageEnglish
Published Beijing Science China Press 01.03.2017
Springer Nature B.V
Subjects
Adaptive filters
Autonomous navigation
Celestial navigation
Centroids
Computer Science
Covariance matrix
Error analysis
Information Systems and Communication Service
Innovations
Kalman filters
Mars
Navigation systems
Nonlinear filters
Research Paper
Space navigation
深空探测
navigation
Mars approach
variant noise
导航
deep space
时变噪声
adaptive UKF
自适应UKF
接近段
Online AccessGet full text
ISSN1674-733X
1869-1919
DOI10.1007/s11432-016-0405-2

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Summary:Celestial navigation is a commonly used autonomous navigation technique for deep space navigation. A nonlinear filter such as the unscented Kalman filter (UKF) is typically applied in a celestial navigation system (CNS). However, on account of being subject to a number of factors, such as ephemeris errors and centroid determination, the measurement model error of a CNS cannot be accurately determined. The analysis conducted in this study also shows that the measurement model error is time-variant during the Mars approach phase. This implies that covariance matrix of the measurement error R is usually inaccurate, which may induce large estimation errors that even result in filter divergence. Some adaptive methods are able to address this issue. However, traditional adaptive filters, for scaling R, usually require a sequence of innovation and are affected by the statistic window size. A new recursive adaptive UKF (RAUKF) is proposed in this paper, which only uses current innovation to scale R. The navigation performance of the proposed RAUKF method is compared with some traditional adaptive filters through simulations. The results show that this method is better than traditional adaptive filters in a CNS during the Mars approach phase.
Bibliography:11-5847/TP
Celestial navigation is a commonly used autonomous navigation technique for deep space navigation. A nonlinear filter such as the unscented Kalman filter (UKF) is typically applied in a celestial navigation system (CNS). However, on account of being subject to a number of factors, such as ephemeris errors and centroid determination, the measurement model error of a CNS cannot be accurately determined. The analysis conducted in this study also shows that the measurement model error is time-variant during the Mars approach phase. This implies that covariance matrix of the measurement error R is usually inaccurate, which may induce large estimation errors that even result in filter divergence. Some adaptive methods are able to address this issue. However, traditional adaptive filters, for scaling R, usually require a sequence of innovation and are affected by the statistic window size. A new recursive adaptive UKF (RAUKF) is proposed in this paper, which only uses current innovation to scale R. The navigation performance of the proposed RAUKF method is compared with some traditional adaptive filters through simulations. The results show that this method is better than traditional adaptive filters in a CNS during the Mars approach phase.
deep space, adaptive UKF, navigation, Mars approach, variant noise
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ISSN:1674-733X
1869-1919
DOI:10.1007/s11432-016-0405-2