DocumentCode
923619
Title
Some cross correlation properties for distorted signals
Author
Brown, John L., Jr.
Volume
21
Issue
4
fYear
1975
fDate
7/1/1975 12:00:00 AM
Firstpage
453
Lastpage
458
Abstract
For a nondecreasing distortion characteristic
and a given signal
, the "cross correlation" function defined by
is shown to satisfy the inequality
, for all
, generalizing an earlier result of Richardson that required
to be continuous and strictly increasing. The methods of the paper also show that, under weak conditions, begin{equation} R_{phi,psi}(tau) triangleq int_{-infty}^{infty} phi[x(t)]psi[x(t - tau)] dt leq R_{phi,psi}(0) end{equation} when
is strictly increasing and
is nondecreasing. In the case of hounded signals (e.g., periodic functions), the appropriate cross correlation function is begin{equation} mathcal{R}_{phi,psi}(tau} triangleq lim_{T rightarrow infty} (2T)^{-l} int_{-T}^T phi[x(t)]psi[x(t - tau)] dt. end{equation} For this case it is shown that
for any nondecreasing (or nonincreasing) distortion functions
and
. The result is then applied to generalize an inequality on correlation functions for periodic signals due to Prosser. Noise signals are treated and inequalities of a similar nature are obtained for ensemble-average cross correlation functions under suitable hypotheses on the statistical properties of the noise. Inequalities of this type are the basis of a well-known method of estimating the unknown time delay of an observed signal. The extension to nondecreasing discontinuous distortion functions allows the use of hard limiting or quantization to facilitate the cross correlation calculation.
and a given signal
, the "cross correlation" function defined by
is shown to satisfy the inequality
, for all
, generalizing an earlier result of Richardson that required
to be continuous and strictly increasing. The methods of the paper also show that, under weak conditions, begin{equation} R_{phi,psi}(tau) triangleq int_{-infty}^{infty} phi[x(t)]psi[x(t - tau)] dt leq R_{phi,psi}(0) end{equation} when
is strictly increasing and
is nondecreasing. In the case of hounded signals (e.g., periodic functions), the appropriate cross correlation function is begin{equation} mathcal{R}_{phi,psi}(tau} triangleq lim_{T rightarrow infty} (2T)^{-l} int_{-T}^T phi[x(t)]psi[x(t - tau)] dt. end{equation} For this case it is shown that
for any nondecreasing (or nonincreasing) distortion functions
and
. The result is then applied to generalize an inequality on correlation functions for periodic signals due to Prosser. Noise signals are treated and inequalities of a similar nature are obtained for ensemble-average cross correlation functions under suitable hypotheses on the statistical properties of the noise. Inequalities of this type are the basis of a well-known method of estimating the unknown time delay of an observed signal. The extension to nondecreasing discontinuous distortion functions allows the use of hard limiting or quantization to facilitate the cross correlation calculation.Keywords
Correlation functions; Distortion; Signal analysis; Delay effects; Delay estimation; Diodes; Distortion; Integral equations; Quantization; Random processes; Signal analysis; Varactors;
fLanguage
English
Journal_Title
Information Theory, IEEE Transactions on
Publisher
ieee
ISSN
0018-9448
Type
jour
DOI
10.1109/TIT.1975.1055411
Filename
1055411
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