Relative-Entropy Minimization with Uncertain Constraints--Theory and Application to Spectrum Analysis
Author | : R. W. Johnson |
Publisher | : |
Total Pages | : 16 |
Release | : 1984 |
ISBN-10 | : OCLC:227633028 |
ISBN-13 | : |
Rating | : 4/5 (28 Downloads) |
Download or read book Relative-Entropy Minimization with Uncertain Constraints--Theory and Application to Spectrum Analysis written by R. W. Johnson and published by . This book was released on 1984 with total page 16 pages. Available in PDF, EPUB and Kindle. Book excerpt: The relative-entropy principle ('principle of minimum cross entropy') is a provably optimal information theoretic method for inferring a probability density from an initial ('prior') estimate together with constraint information that confines the density to a specified convex set. Typically the constraint information takes the form of linear equations that specify the expectation values of given functions. This paper discusses the effect of replacing such linear-equality constraints with quadratic constraints that require linear constraints to hold approximately, to within a specified error bound. The results are applied to the derivation of a new multisignal spectrum-analysis method that simultaneously estimates a number of power spectra given: (1) an initial estimate of each; (2) imprecise values of the autocorrelation function of their sum; (3) estimates of the error in measurement of the autocorrelation values. One application is to separate estimation of the spectra of a signal and independent additive noise, based on imprecise measurements of the autocorrelations of the signal plus noise. The new method is an extension of multisignal relative-entropy spectrum analysis (with exact auto-correlations). The two methods are compared, and connections with previous related work are indicated. Mathematical properties of the new method are discussed, and an illustrative numerical example is presented. Originator-supplied keywords include: Maximum entropy, cross entropy, Relative entropy, Information theory, Prior estimates, and Initial estimates.