最佳多维能量压实过滤器的设计

Conference Record of the Thirty-Sixth Asilomar Conference on Signals, Systems and Computers, 2002. Pub Date : 2002-11-03 DOI:10.1109/ACSSC.2002.1197205

Niranjan Damera-Venkata, J. Tuqan, B. Evans

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引用次数: 0

摘要

讨论了最优信号适应的多维能量压缩滤波器的设计。与一维(1-D)情况一样，能量压缩问题在压缩滤波器的自相关系数中是线性的，这也必须满足Nyquist-(M)条件的多维(M -d)等效。如果存在最小相位谱因子，则使用m-D离散希尔伯特变换(DHT)恢复最佳压缩滤波器。在不存在最小相位谱因子的情况下，提出一种基于多目标目标实现的迭代算法。在执行Nyquist-M条件的同时，强制压实滤波器的自相关系数尽可能接近产品滤波器的系数，并强制最优压实滤波器的压实增益接近使用最优产品滤波器产生的压实增益。

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Design of optimum multi-dimensional energy compaction filters

We discuss the design of optimum signal-adapted multi-dimensional energy compaction filters. As in the one-dimensional (1-D) case, the energy compaction problem is linear in the auto-correlation coefficients of the compaction filter, which must also satisfy the multi-dimensional (m-D) equivalent of the Nyquist-(M) condition. If a minimum-phase spectral factor exists the optimum compaction filter is recovered using the m-D Discrete Hilbert Transform (DHT). If a minimum phase spectral factor does not exist, an iterative algorithm based on multi-objective goal attainment is proposed. The Nyquist-M condition is enforced while simultaneously forcing the autocorrelation coefficients of the compaction filter to be as close as possible to the coefficients of the product filter and the compaction gain of the optimum compaction filter to be close to the compaction gain produced by using the optimum product filter.

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Conference Record of the Thirty-Sixth Asilomar Conference on Signals, Systems and Computers, 2002.

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