Inspection of the Output of a Convolution and Deconvolution Process from the Leading Digit Point of View—Benford’s Law

Q3 Computer Science

Journal of Information Hiding and Multimedia Signal Processing Pub Date : 2016-10-11 DOI:10.4236/JSIP.2016.74020

M. Pinchas

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引用次数: 1

Abstract

In the communication field, during transmission, a source signal undergoes a convolutive distortion between its symbols and the channel impulse response. This distortion is referred to as Intersymbol Interference (ISI) and can be reduced significantly by applying a blind adaptive deconvolution process (blind adaptive equalizer) on the distorted received symbols. But, since the entire blind deconvolution process is carried out with no training symbols and the channel’s coefficients are obviously unknown to the receiver, no actual indication can be given (via the mean square error (MSE) or ISI expression) during the deconvolution process whether the blind adaptive equalizer succeeded to remove the heavy ISI from the transmitted symbols or not. Up to now, the output of a convolution and deconvolution process was mainly investigated from the ISI point of view. In this paper, the output of a convolution and deconvolution process is inspected from the leading digit point of view. Simulation results indicate that for the 4PAM (Pulse Amplitude Modulation) and 16QAM (Quadrature Amplitude Modulation) input case, the number “1” is the leading digit at the output of a convolution and deconvolution process respectively as long as heavy ISI exists. However, this leading digit does not follow exactly Benford’s Law but follows approximately the leading digit (digit 1) of a Gaussian process for independent identically distributed input symbols and a channel with many coefficients.

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从前导数的角度检验卷积和反卷积过程的输出——本福德定律

在通信领域，在传输过程中，源信号在其符号和信道脉冲响应之间会发生卷积失真。这种失真被称为码间干扰(ISI)，可以通过对失真的接收符号应用盲自适应反褶积过程(盲自适应均衡器)来显着降低。但是，由于整个盲反褶积过程是在没有训练符号的情况下进行的，信道系数对接收机来说显然是未知的，因此在反褶积过程中，盲自适应均衡器是否成功地从传输符号中去除了严重的ISI，并不能给出实际的指示(通过均方误差(MSE)或ISI表达式)。到目前为止，主要是从ISI的角度研究卷积和反卷积过程的输出。本文从前导数字的角度考察了卷积和反卷积过程的输出。仿真结果表明，对于4PAM(脉冲调幅)和16QAM(正交调幅)输入情况，只要存在重ISI，在卷积和反卷积过程的输出处数字“1”分别为前导数字。然而，这个前导数字并不完全遵循本福德定律，而是近似遵循高斯过程的前导数字(数字1)，用于独立的同分布输入符号和具有许多系数的通道。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Information Hiding and Multimedia Signal Processing Computer Science-Software

CiteScore

3.20

自引率

0.00%

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