Wiener Filters in Gaussian Mixture Signal Estimation with Infinity-Norm Error

Abstract

Consider the estimation of a signal x∈RN from noisy observations r=x+z, where the input~ x is generated by an independent and identically distributed (i.i.d.) Gaussian mixture source, and z is additive white Gaussian noise (AWGN) in parallel Gaussian channels. Typically, the 2-norm error (squared error) is used to quantify the performance of the estimation process. In contrast, we consider the ∞-norm error (worst case error). For this error metric, we prove that, in an asymptotic setting where the signal dimension N∞, the ∞-norm error always comes from the Gaussian component that has the largest variance, and the Wiener filter asymptotically achieves the optimal expected ∞-norm error. The i.i.d. Gaussian mixture case is easily applicable to i.i.d. Bernoulli-Gaussian distributions, which are often used to model sparse signals. Finally, our results can be extended to linear mixing systems with i.i.d. Gaussian mixture inputs, in settings where a linear mixing system can be decoupled to parallel Gaussian channels.