关于协方差估计中的归一化信噪比

arXiv - EE - Signal Processing Pub Date : 2024-09-17 DOI:arxiv-2409.10896

Tzvi Diskin, Ami Wiesel

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摘要

我们讨论了 Reed、Mallett 和 Brennan 关于自适应检测的论文中定义的归一化信噪比（NSNR）指标。其背景是在加性相关噪声中检测目标矢量。NSNR 是使用估计噪声协方差的线性检测器的信噪比与基于精确未知协方差的千里眼检测器的信噪比之间的比率。由于 NSNR 是目标矢量的函数，因此如何评估 NSNR 并不明显。为了弥补这一缺陷，我们考虑了与最差目标相关的信噪比。利用康托洛维奇不等式，我们为最差情况下的 NSNR 提供了一个闭式解。然后，我们证明经典的高斯库尔贝克-莱伯勒（KL）发散对其进行了约束。使用不同的真方差和各种估计值进行的数值实验也表明，与基于规范的竞争指标相比，KL 指标与 NSNR 指标的相关性更高。

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On the normalized signal to noise ratio in covariance estimation

We address the Normalized Signal to Noise Ratio (NSNR) metric defined in the seminal paper by Reed, Mallett and Brennan on adaptive detection. The setting is detection of a target vector in additive correlated noise. NSNR is the ratio between the SNR of a linear detector which uses an estimated noise covariance and the SNR of clairvoyant detector based on the exact unknown covariance. It is not obvious how to evaluate NSNR since it is a function of the target vector. To close this gap, we consider the NSNR associated with the worst target. Using the Kantorovich Inequality, we provide a closed form solution for the worst case NSNR. Then, we prove that the classical Gaussian Kullback Leibler (KL) divergence bounds it. Numerical experiments with different true covariances and various estimates also suggest that the KL metric is more correlated with the NSNR metric than competing norm based metrics.

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arXiv - EE - Signal Processing

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