Fast recursive equalizers for 1D and 2D linear equalization

Robert J. Drost; Andrew C. Singer

doi:10.1109/TSP.2012.2191967

Fast recursive equalizers for 1D and 2D linear equalization

Research output: Contribution to journal › Article › peer-review

Abstract

We develop fast recursive equalizers to be used in the one-dimensional (1D) or two-dimensional (2D) linear minimum mean-squared error equalization of a known linear finite-length channel. In particular, these equalization algorithms address the communications scenario in which the channel or the prior information on the transmitted symbols may be time varying. The latter case of time-varying priors is especially pertinent for turbo equalization, on which we focus here. We first consider a 1D sliding-window equalizer based on a Cholesky-factorization update and then generalize this approach to the 2D case. Finally, we develop a 2D equalizer that is based on a recursive matrix-inverse update. We summarize each of these algorithms and describe their computational complexities.

Original language	English (US)
Article number	6178017
Pages (from-to)	3886-3891
Number of pages	6
Journal	IEEE Transactions on Signal Processing
Volume	60
Issue number	7
DOIs	https://doi.org/10.1109/TSP.2012.2191967
State	Published - Jul 2012

Keywords

Channel equalization
intersymbol interference
recursive estimation
turbo equalization

ASJC Scopus subject areas

Signal Processing
Electrical and Electronic Engineering

Online availability

10.1109/TSP.2012.2191967

Library availability

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title = "Fast recursive equalizers for 1D and 2D linear equalization",

abstract = "We develop fast recursive equalizers to be used in the one-dimensional (1D) or two-dimensional (2D) linear minimum mean-squared error equalization of a known linear finite-length channel. In particular, these equalization algorithms address the communications scenario in which the channel or the prior information on the transmitted symbols may be time varying. The latter case of time-varying priors is especially pertinent for turbo equalization, on which we focus here. We first consider a 1D sliding-window equalizer based on a Cholesky-factorization update and then generalize this approach to the 2D case. Finally, we develop a 2D equalizer that is based on a recursive matrix-inverse update. We summarize each of these algorithms and describe their computational complexities.",

keywords = "Channel equalization, intersymbol interference, recursive estimation, turbo equalization",

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note = "Funding Information: Manuscript received January 09, 2012; accepted March 09, 2012. Date of publication April 05, 2012; date of current version June 12, 2012. The associate editor coordinating the review of this manuscript and approving it for publication was Dr. Ta-Sung Lee. This work was supported in part by the Department of the Navy, Office of Naval Research, under Grant N00014-01-1-0117, by the National Science Foundation under Grant CCR-0092598 (CAREER), and by an appointment to the U.S. Army Research Laboratory Postdoctoral Fellowship Program administered by the Oak Ridge Associated Universities through a contract with the U.S. Army Research Laboratory.",

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N2 - We develop fast recursive equalizers to be used in the one-dimensional (1D) or two-dimensional (2D) linear minimum mean-squared error equalization of a known linear finite-length channel. In particular, these equalization algorithms address the communications scenario in which the channel or the prior information on the transmitted symbols may be time varying. The latter case of time-varying priors is especially pertinent for turbo equalization, on which we focus here. We first consider a 1D sliding-window equalizer based on a Cholesky-factorization update and then generalize this approach to the 2D case. Finally, we develop a 2D equalizer that is based on a recursive matrix-inverse update. We summarize each of these algorithms and describe their computational complexities.

AB - We develop fast recursive equalizers to be used in the one-dimensional (1D) or two-dimensional (2D) linear minimum mean-squared error equalization of a known linear finite-length channel. In particular, these equalization algorithms address the communications scenario in which the channel or the prior information on the transmitted symbols may be time varying. The latter case of time-varying priors is especially pertinent for turbo equalization, on which we focus here. We first consider a 1D sliding-window equalizer based on a Cholesky-factorization update and then generalize this approach to the 2D case. Finally, we develop a 2D equalizer that is based on a recursive matrix-inverse update. We summarize each of these algorithms and describe their computational complexities.

KW - Channel equalization

KW - intersymbol interference

KW - recursive estimation

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Fast recursive equalizers for 1D and 2D linear equalization

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