Range passive localization of the moving source with a single vector hydrophone

2016 IEEE/OES China Ocean Acoustics (COA) Pub Date : 2016-08-08 DOI:10.1109/COA.2016.7535682

Chen Yu, Meng Zhou, Ma Shuqing, Bao Changchun

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引用次数: 1

Abstract

The pressure and horizontal velocity signals of a vector hydrophone are combined in passive range localization processing. The target in the ocean is moving at a constant speed and the track does not cross the receiver point. Range localization is achieved through four main steps. Firstly, the received pressure and particle velocity are processed together to restrain the isotropic noise. Second, the signals received at different time are cross-correlated and processed to obtain the interference pattern of the intensity field. Third, the radial velocity of the moving source can be extracted from the interference and the following obtained: the best match of the constant speed of the target and the range; and the time of the Closest Point of Approach (CPA). Finally, the range localization is achieved according to the motion equation. In comparison with the pressure sensor, the vector hydrophone has a higher signal to noise ratio (SNR) for its 4-6dB spatial gain in the isotropic noise field. Hence, the performance of range passive localization for the moving source is improved by using a vector hydrophone.

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单矢量水听器运动源的距离无源定位

将矢量水听器的压力和水平速度信号结合起来进行无源距离定位处理。海洋中的目标以恒定速度移动，航迹不会越过接收点。距离定位通过四个主要步骤实现。首先，对接收到的压力和粒子速度进行综合处理，抑制各向同性噪声;其次，对不同时间接收到的信号进行交叉相关处理，得到强度场的干涉图;第三，从干扰中提取出运动源的径向速度，得到目标匀速与距离的最佳匹配;以及最近接近点(CPA)的时间。最后，根据运动方程实现距离定位。与压力传感器相比，矢量水听器在各向同性噪声场中具有4-6dB的空间增益，信噪比更高。因此，采用矢量水听器可以提高运动源的距离无源定位性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2016 IEEE/OES China Ocean Acoustics (COA)

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