Approximation of Nonnegative Systems by Finite Impulse Response Convolutions

Author

Finesso, Lorenzo ; Spreij, Peter

Author_Institution

Inst. of Electron., Comput. & Telecommun. Eng., Padua, Italy

Volume

61

Issue

8

fYear

2015

fDate

Aug. 2015

Firstpage

4399

Lastpage

4409

Abstract

We pose the deterministic, nonparametric, approximation problem for scalar nonnegative input/output systems via finite impulse response convolutions, based on repeated observations of input/output signal pairs. The problem is converted into a nonnegative matrix factorization with special structure for which we useCsiszár´s I-divergenceas the criterion of optimality. Conditions are given, on the input/output data, that guarantee the existence and uniqueness of the minimum. We propose an algorithm of the alternating minimization type for I-divergence minimization, and study its asymptotic behavior. For the case of noisy observations, we give the large sample properties of the statistical version of the minimization problem. Numerical experiments confirm the asymptotic results and exhibit the fast convergence of the proposed algorithm.

Keywords

approximation theory; convergence of numerical methods; convolution; matrix decomposition; minimisation; Csiszár I-divergence minimization; approximation problem; deterministic problem; finite impulse response convolutions; input-output signal pairs; noisy observations; nonnegative matrix factorization; nonnegative systems; nonparametric problem; optimality criterion; scalar nonnegative input-output systems; Algorithm design and analysis; Approximation algorithms; Approximation methods; Mathematical model; Minimization; Radio frequency; Yttrium; FIR approximation; I-divergence; Positive systems; alternating minimization;

fLanguage

English

Journal_Title

Information Theory, IEEE Transactions on

Publisher

ieee

ISSN

0018-9448

Type

jour

DOI

10.1109/TIT.2015.2443786

Filename

7120984