Efficient Underwater Acoustical Localization Method Based On Time Difference and Bearing Measurements

This article addresses the underwater acoustical localization problem by using the time-difference-of-arrival (TDOA) and bearing-angle-of-arrival (BAOA) measurements. For the underwater acoustic equipment, such as the ultrashort baseline system (USW, whose hearing measurements are different from the traditional angle-of-arrival (AOA) model, a closed-form solution for the hybrid TDOA/BAOA-based source localization problem is developed. However, the solution suffers from the measurement noise and cannot achieve the Cramer-Rao lower bound (CRLB) performance in the case of large measurement noise. Thus, an iterative constrained weighted least-squares method is presented to further minimize the error in the case of large noise. The CRLB for hybrid TDOA/BAOA source localization is analyzed, and the solution is proved to achieve the CRLB performance. Numerical simulations and field tests demonstrate that the proposed method outperforms the traditional methods in terms of estimation bias and accuracy. It can achieve the CRIB performance better.

Automated summary

This article addresses the underwater acoustical localization problem using TDOA and BAOA measurements, developing a closed-form solution for the hybrid TDOA/BAOA-based source localization problem. An iterative constrained weighted least-squares method is presented to minimize error in the case of large noise. The solution is proven to achieve the CRLB performance, outperforming traditional methods in estimation bias and accuracy, achieving better CRIB performance.