Linear-Gaussian systems and signal processing

Max A. Little
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Abstract

Linear systems theory, based on the mathematics of vector spaces, is the backbone of all “classical” DSP and a large part of statistical machine learning. The basic idea -- that linear algebra applied to a signal can of substantial practical value -- has counterparts in many areas of science and technology. In other areas of science and engineering, linear algebra is often justified by the fact that it is often an excellent model for real-world systems. For example, in acoustics the theory of (linear) wave propagation emerges from the concept of linearization of small pressure disturbances about the equilibrium pressure in classical fluid dynamics. Similarly, the theory of electromagnetic waves is also linear. Except when a signal emerges from a justifiably linear system, in DSP and machine learning we do not have any particular correspondence to reality to back up the choice of linearity. However, the mathematics of vector spaces, particularly when applied to systems which are time-invariant and jointly Gaussian, is highly tractable, elegant and immensely useful.
线性-高斯系统与信号处理
基于向量空间数学的线性系统理论是所有“经典”DSP的支柱,也是统计机器学习的很大一部分。将线性代数应用于信号具有重要的实用价值,这一基本思想在许多科学技术领域都有相应的应用。在科学和工程的其他领域,线性代数通常被证明是现实世界系统的优秀模型。例如,在声学中,(线性)波传播理论是由经典流体动力学中关于平衡压力的小压力扰动的线性化概念产生的。同样,电磁波的理论也是线性的。除非信号来自合理的线性系统,在DSP和机器学习中,我们没有任何与现实的特定对应关系来支持线性的选择。然而,向量空间的数学,特别是当应用于时不变和联合高斯的系统时,是非常容易处理的,优雅的和非常有用的。
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