Mojgan Mirzaei Hotkani, S. Seyedin, Jean-François Bousquet
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引用次数: 0
摘要
匹配场处理(matching Field Processing, MFP)是目前最著名的声源检测和水下定位算法之一。传统的MFP依赖于水听器阵列接收到的信号与使用格林函数构造的复制信号之间的匹配,然后通过扫描距离和深度的空间来估计浅水和深水中的源位置。基于格林函数构建复制信号存在不同的环境模型;这包括在浅水波导的正常模式,劳埃德-镜子模式,和图像模型。利用所提出的估计算法,针对目标位于源信号传播路径的情况,建立了基于目标表面反射的解析Lloyd-Mirror模型。为此,本文提出了一种基于广义Lloyd-Mirror方向图的水声目标定位算法。利用2019年在加拿大新斯科舍省Grand Passage进行的水下通信试验的声学数据验证了这一想法。
Underwater Target Localization using the Generalized Lloyd-Mirror Pattern
Matched Field Processing (MFP) is one of the most famous algorithms for source detection and underwater localization. Traditional MFP relies on a match between the received signal at the hydrophone array and a replica signal, which is constructed using Green’s Function, then by scanning the space in range and depth to provide an estimation of source position in shallow water and deep water. Different environment models relying on Green’s function exist for constructing the replica signal; this includes normal modes in a shallow water waveguide, the Lloyd-Mirror Pattern, and the Image model. Using the proposed estimation algorithm, here, an analytical Lloyd-Mirror model is developed based on the reflection from the target surface for a case where a target is located in the source signal propagation path. So, in this paper, a new underwater acoustic target localization algorithm using the generalized Lloyd-Mirror Pattern is presented. This idea is verified using an acoustic data from a 2019 underwater communication trial in Grand Passage, Nova Scotia, Canada.
期刊介绍:
The scope of Majlesi Journal of Electrcial Engineering (MJEE) is ranging from mathematical foundation to practical engineering design in all areas of electrical engineering. The editorial board is international and original unpublished papers are welcome from throughout the world. The journal is devoted primarily to research papers, but very high quality survey and tutorial papers are also published. There is no publication charge for the authors.
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