非线性和非高斯信号处理

Max A. Little
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摘要

线性,时不变(LTI)高斯DSP具有大量的数学便利性,使其在实际DSP应用和机器学习中具有价值。当信号真的是由这样一个lti -高斯模型产生时,从统计的角度来看,这种处理是最优的。然而,当我们不能保证线性、时不变和高斯性的假设成立时,这些技术的使用有很大的局限性。特别是,表现出跳跃或显著的非高斯异常值的信号会导致严重的不利影响,例如LTI滤波器输出中的Gibb现象,并且非平稳信号不能在傅里叶域中紧凑地表示。在实践中,许多真实信号或多或少地显示出这种现象,因此拥有在许多情况下有效的DSP方法“工具包”非常重要。本章致力于探索统计机器学习概念在DSP中的应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Nonlinear and non-Gaussian signal processing
Linear, time-invariant (LTI) Gaussian DSP, has substantial mathematical conveniences that make it valuable in practical DSP applications and machine learning. When the signal really is generated by such an LTI-Gaussian model then this kind of processing is optimal from a statistical point of view. However, there are substantial limitations to the use of these techniques when we cannot guarantee that the assumptions of linearity, time-invariance and Gaussianity hold. In particular, signals that exhibit jumps or significant non-Gaussian outliers cause substantial adverse effects such as Gibb's phenomena in LTI filter outputs, and nonstationary signals cannot be compactly represented in the Fourier domain. In practice, many real signals show such phenomena to a greater or lesser degree, so it is important to have a `toolkit' of DSP methods that are effective in many situations. This chapter is dedicated to exploring the use of the statistical machine learning concepts in DSP.
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