A cost‐efficient joint target location and clock bias estimation technique using multiple time step measurements in mobile bistatic sonar

Active localization of a stationary target is one key issue in applications of bistatic sonar based on bistatic range (BR) measurement. However, the complex underwater environment makes achieving the synchronization between the transmitted station and the received station difficult. For solving the...

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Bibliographic Details
Published in:IET radar, sonar & navigation sonar & navigation, 2022-01, Vol.16 (1), p.91-102
Main Authors: Zhang, Chenglin, Zhang, Qunfei, Shi, Wentao, Wang, Weidong, Xu, Jiajie, Pang, Feifei
Format: Article
Language:English
Subjects:
Gaussian noise
linearisation techniques
maximum likelihood estimation
mean square error methods
optimisation
recursive estimation
synchronisation
target tracking
time‐ofarrival estimation
time‐of‐arrival estimation
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Summary:Active localization of a stationary target is one key issue in applications of bistatic sonar based on bistatic range (BR) measurement. However, the complex underwater environment makes achieving the synchronization between the transmitted station and the received station difficult. For solving the synchronization problem, this study relies on mobile bistatic sonar to acquire measurement information at multiple time steps. After that, the target location and clock bias are jointly estimated by solving a non‐linear least square problem. To this end, a recursive scheme is proposed to optimise the measurement cost and reduce the impact of the initial value to achieve accurate estimation by taking full advantage of the redundant measurement information. Orthogonal transformation is used to ensure computational efficiency and numerical reliability. The Cramer–Rao Lower Bound (CRLB) is also derived as a lower bound on the error in estimating the target position and clock bias. Simulation results show that the proposed method achieves the CRLB performance and optimises the measurement cost over the small error region under Gaussian noise.
ISSN:1751-8784
1751-8792
DOI:10.1049/rsn2.12166