Propagation medium impact on sonar coherent processing for high frequency synthetic aperture imaging

Proceedings of IEEE Symposium on Autonomous Underwater Vehicle Technology (AUV'94) Pub Date : 1994-07-19 DOI:10.1109/AUV.1994.518638

C. Ciany, G. Walsh, A. Clark

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引用次数: 3

Abstract

The major benefit of using synthetic aperture sonar (SAS) in underwater imaging applications is the provision of near-optical quality imaging at practical area coverage rates without the need for large physical aperture sizes that carry with them impractical size, weight and power requirements for the host platform. Characterization of the underwater propagation medium's spatio-temporal coherence limitations is a pre-requisite to an effective synthetic aperture sonar (SAS) system design. Raytheon Company, in conjunction with Harbor Branch Oceanographic Institute, has designed and successfully conducted an acoustic medium stability experiment to provide such measurements. The experiment accurately characterizes the medium's coherence simultaneously in both space and time by employing a stationary acoustic projector and a large, stationary acoustic array that is long enough to encompass candidate SAS design lengths without requiring platform motion. The experiment is described, and the temporal coherence measurements are presented.

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传播介质对高频合成孔径成像声纳相干处理的影响

在水下成像应用中使用合成孔径声呐(SAS)的主要优点是在实际的区域覆盖率下提供近光学质量的成像，而不需要大的物理孔径尺寸，这些尺寸、重量和功率对主机平台都有不切实际的要求。水下传播介质时空相干性限制的表征是有效设计合成孔径声呐系统的先决条件。雷神公司与海港分支海洋学研究所合作，设计并成功地进行了声学介质稳定性实验，以提供此类测量。该实验采用了一个固定的声学投影仪和一个大的、固定的声学阵列，该阵列足够长，可以包含候选的SAS设计长度，而不需要平台运动，从而准确地同时表征了介质在空间和时间上的相干性。对实验进行了描述，并给出了时间相干的测量结果。

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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Proceedings of IEEE Symposium on Autonomous Underwater Vehicle Technology (AUV'94)

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