Super-efficiency in blind signal separation of symmetric heavy-tailed sources

Yoav Shereshevski; Arie Yeredor; Hagit Messer

Super-efficiency in blind signal separation of symmetric heavy-tailed sources

Yoav Shereshevski
, Arie Yeredor
, Hagit Messer

Research output: Contribution to conference › Paper › peer-review

Abstract

This paper addresses the Blind Source Separation (BSS) problem in the context of "heavy-tailed", or "impulsive" source signals, characterized by the nonexistence of finite second (or higher) order moments. We consider Pham's Quasi-Maximum Likelihood (QML) approach, a modification of the Maximum Likelihood (ML) approach, applied using some presumed distributions of the sources. We introduce a related family of suboptimal estimators, termed Restricted QML (RQML). A theoretical analysis of the asymptotic performance of RQML is presented. The analysis is used for showing that the variance of the optimal (non-RQML) estimator's error must decrease at a rate faster than 1/T (where T is the number of independent observations). This surprising property, sometimes called super-efficiency, has been observed before (in the BSS context) only for finite-support source distributions. Simulation results illustrate the good agreement with theory.

Original language	English
Pages	78-81
Number of pages	4
State	Published - 2001
Externally published	Yes
Event	2001 IEEE Workshop on Statitical Signal Processing Proceedings - Singapore, Singapore Duration: 6 Aug 2001 → 8 Aug 2001

Conference

Conference	2001 IEEE Workshop on Statitical Signal Processing Proceedings
Country/Territory	Singapore
City	Singapore
Period	6/08/01 → 8/08/01

Cite this

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title = "Super-efficiency in blind signal separation of symmetric heavy-tailed sources",

abstract = "This paper addresses the Blind Source Separation (BSS) problem in the context of {"}heavy-tailed{"}, or {"}impulsive{"} source signals, characterized by the nonexistence of finite second (or higher) order moments. We consider Pham's Quasi-Maximum Likelihood (QML) approach, a modification of the Maximum Likelihood (ML) approach, applied using some presumed distributions of the sources. We introduce a related family of suboptimal estimators, termed Restricted QML (RQML). A theoretical analysis of the asymptotic performance of RQML is presented. The analysis is used for showing that the variance of the optimal (non-RQML) estimator's error must decrease at a rate faster than 1/T (where T is the number of independent observations). This surprising property, sometimes called super-efficiency, has been observed before (in the BSS context) only for finite-support source distributions. Simulation results illustrate the good agreement with theory.",

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AU - Shereshevski, Yoav

AU - Yeredor, Arie

AU - Messer, Hagit

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AB - This paper addresses the Blind Source Separation (BSS) problem in the context of "heavy-tailed", or "impulsive" source signals, characterized by the nonexistence of finite second (or higher) order moments. We consider Pham's Quasi-Maximum Likelihood (QML) approach, a modification of the Maximum Likelihood (ML) approach, applied using some presumed distributions of the sources. We introduce a related family of suboptimal estimators, termed Restricted QML (RQML). A theoretical analysis of the asymptotic performance of RQML is presented. The analysis is used for showing that the variance of the optimal (non-RQML) estimator's error must decrease at a rate faster than 1/T (where T is the number of independent observations). This surprising property, sometimes called super-efficiency, has been observed before (in the BSS context) only for finite-support source distributions. Simulation results illustrate the good agreement with theory.

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T2 - 2001 IEEE Workshop on Statitical Signal Processing Proceedings

Y2 - 6 August 2001 through 8 August 2001

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Super-efficiency in blind signal separation of symmetric heavy-tailed sources

Abstract

Conference

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