Title :
Nonminimum-phase FIR channel estimation using cumulant matrix pencils
Author :
Liang, Jing ; Ding, Zhi
Author_Institution :
Silicon Labs. Inc., Broomfield, CO, USA
Abstract :
This paper studies the blind estimation of single-input-single-output channels with finite impulse response (FIR) and nonminimum phase. Based on higher order statistics, we introduce a new algorithm that exploits a matrix pencil constructed from a set of cumulant matrices. By solving a generalized eigenvalue problem, channel estimates (up to a scalar ambiguity) can be obtained from nontrivial generalized eigenvectors of this cumulant matrix pencil. With multiple estimation results available, different schemes are given to extract channel information effectively. The proposed algorithm does not require exact knowledge of the channel length and can function properly under channel length overestimation. Numerical simulations demonstrate the robustness of this new algorithm to various adverse conditions.
Keywords :
blind source separation; channel estimation; eigenvalues and eigenfunctions; higher order statistics; matrix algebra; blind estimation; channel estimation algorithm; channel information extraction; channel length overestimation; cumulant matrix pencils; finite impulse response; generalized eigenvalue problem; higher order statistics; nonminimum phase channels; nonminimum-phase FIR channel estimation; nontrivial generalized eigenvectors; numerical simulations; robust algorithm; single-input-single-output channels; source separation; weighted overlapping matrix pencil; Bandwidth; Channel estimation; Data mining; Equalizers; Finite impulse response filter; Higher order statistics; Intersymbol interference; Maximum likelihood detection; Maximum likelihood estimation; Signal processing;
Journal_Title :
Signal Processing, IEEE Transactions on
DOI :
10.1109/TSP.2003.815378
