Title :
Learning Echo Paths During Continuous Double-Talk Using Semi-Blind Source Separation
Author_Institution :
Dept. of Electr. & Comput. Eng., Utah State Univ., Logan, UT, USA
Abstract :
Echo cancelers typically employ control mechanisms to prevent adaptive filter updates during double-talk events. By contrast, this paper exploits the information contained in time-varying second order statistics of nonstationary signals to update adaptive filters and learn echo path responses during double-talk. First, a framework is presented for describing mixing and blind separation of independent groups of signals. Then several echo cancellation problems are cast in this framework, including the problem of simultaneous acoustic and line echo cancellation as encountered in speaker phones. A maximum-likelihood approach is taken to estimate both the unknown signal statistics as well as echo canceling filters. When applied to speech signals, the techniques developed in this paper typically achieved between 30 and 40 dB of echo return loss enhancement (ERLE) during continuous double-talking.
Keywords :
acoustic signal processing; adaptive filters; blind source separation; echo suppression; learning (artificial intelligence); maximum likelihood estimation; adaptive filter; continuous double-talk; double-talk event; echo canceling filter; echo path learning; echo return loss enhancement; line echo cancellation; maximum-likelihood approach; nonstationary signal; semiblind source separation; signal statistics; speaker phone; speech signal; time-varying second order statistics; Blind source separation; Correlation; Echo cancellers; Joints; Time frequency analysis; Blind source separation (BSS); echo cancellation; independent component analysis (ICA);
Journal_Title :
Audio, Speech, and Language Processing, IEEE Transactions on
DOI :
10.1109/TASL.2011.2164525
