Broadband sensor location selection using convex optimization in very large scale arrays

2013 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics Pub Date : 2013-10-01 DOI:10.1109/WASPAA.2013.6701889

Y. Lai, R. Balan, Heiko Claussen, J. Rosca

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引用次数: 3

Abstract

Consider a sensing system using a large number of N microphones placed in multiple dimensions to monitor a broadband acoustic field. Using all the microphones at once is impractical because of the amount of data generated. Instead, we choose a subset of D microphones to be active. Specifically, we wish to find the set of D microphones that minimizes the largest interference gain at multiple frequencies while monitoring a target of interest. A direct, combinatorial approach - testing all N choose D subsets of microphones - is impractical because of the problem size. Instead, we use a convex optimization technique that induces sparsity through a l1-penalty to determine which subset of microphones to use. We test the robustness of the our solution through simulated annealing and compare its performance against a classical beamformer which maximizes SNR. Since switching from a subset of D microphones to another subset of D microphones at every sample is possible, we construct a space-time-frequency sampling scheme that achieves near optimal performance.

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基于凸优化的超大规模阵列宽带传感器位置选择

考虑一个传感系统，在多个维度上放置大量N个麦克风来监测宽带声场。同时使用所有的麦克风是不切实际的，因为会产生大量的数据。相反，我们选择D麦克风的一个子集来激活。具体来说，我们希望找到一组D麦克风，在监测感兴趣的目标时，在多个频率下使最大干扰增益最小化。直接的组合方法——测试所有N个选择D个麦克风子集——由于问题的大小是不切实际的。相反，我们使用凸优化技术，该技术通过11惩罚来诱导稀疏性，以确定使用哪个麦克风子集。我们通过模拟退火测试了我们的解决方案的鲁棒性，并将其性能与最大化信噪比的经典波束形成器进行了比较。由于在每个采样点从D个麦克风子集切换到另一个D个麦克风子集是可能的，因此我们构建了一个实现接近最佳性能的空时频采样方案。

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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2013 IEEE Workshop on Applications of Signal Processing to Audio and Acoustics

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