Abstract
Impulsive noise plays an important role in power line communication among other applications. To improve the communication performance, this paper proposes a novel design of nonlinear processing which improves the fundamental performance of signal detection in impulsive noise. Power-law tails are firstly introduced in nonlinearity design to provide adjustable decay factors for different distributions. Four modes of nonlinearity functions are developed and analyzed. By taking the exponent and the threshold as two arguments, we formulate the nonlinearity design as an optimization problem of maximizing the efficacy function, which is the fundamental measurement for detecting a deterministic signal in impulsive noise. Given that the efficacy function is differentiable, unimodal but without closed-form derivatives, we propose to solve the optimization problem by derivative-free methods, e.g. the Nelder-Mead simplex method. As concept demonstration, our method is used for three commonly-used distribution examples. Results show that our nonlinearity design can achieve almost the same efficacy and detection performance as the locally optimal detector, with the advantage of easy-to-apply closed form expressions.
Highlights
While Gaussian noise is generally encountered in most systems, impulsive noise raises additional consideration for some scenarios, e.g. long-wave communications and ultrawideband systems [1], [2]
For power line communication (PLC) technology, which is very attractive as a smart grid application given such advantages as no additional installation costs [3], [4], the impulsive noise over the PLC channel may severely deteriorate the communication performance [5]
Our previous work has analyzed the zero-memory nonlinearity (ZMNL) designs based on algebraic tail [33] and Gaussianization [34], both of which are only sub-optimal compared to the locally optimal detector (LOD)
Summary
While Gaussian noise is generally encountered in most systems, impulsive noise raises additional consideration for some scenarios, e.g. long-wave communications and ultrawideband systems [1], [2]. A. Jonckheere: Nonlinearity Design With Power-Law Tails for Correlation Detection in Impulsive Noise. Our previous work has analyzed the ZMNL designs based on algebraic tail [33] and Gaussianization [34], both of which are only sub-optimal compared to the LOD. The decay factor of tails is varied by employing the power-law function xa for a ≤ 0, so as to suit different distributions of impulsive noise. Unlike traditional clipping, blanking, or other fixed tails, the power-law function xa can adapt a to vary its decay speed so that it can be suitable for various distributions of impulsive noise.
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