Title :
Nonlinear acoustic echo cancellation with fast converging memoryless preprocessor
Author :
Stenger, A. ; Kellermann, W.
Author_Institution :
Telecommun. Lab., Erlangen-Nurnberg Univ., Germany
Abstract :
Low-cost audio components in hands-free telephone applications call for nonlinear adaptive echo cancellation (AEC). It has been demonstrated that a cascade of a polynomial and an FIR filter can cancel such nonlinear echoes (Stenger and Rabenstein 1998). Another technique employs a hard-clipping curve with LMS adapted saturation parameter (Nollet and Jones 1997). For both cascaded systems we derive an LMS-type adaptation using a common framework, and propose stepsize normalizations for both approaches. To achieve sufficiently fast convergence for practical use, an RLS-type adaptation for the polynomial is derived and experimentally verified. Both techniques are compared using real hardware and speech signals, and show robust convergence behaviour and an echo reduction gain of up to 10 dB compared to a linear AEC
Keywords :
FIR filters; acoustic signal processing; adaptive filters; convergence of numerical methods; echo suppression; least mean squares methods; nonlinear filters; polynomials; FIR filter; LMS adapted saturation parameter; LMS-type adaptation; RLS-type adaptation; convergence; echo reduction gain; fast converging memoryless preprocessor; hands-free telephone; hard-clipping curve; low-cost audio components; nonlinear acoustic echo cancellation; nonlinear adaptive echo cancellation; polynomial; speech; stepsize normalizations; Convergence; Echo cancellers; Finite impulse response filter; Hardware; Least squares approximation; Nonlinear acoustics; Polynomials; Robustness; Speech; Telephony;
Conference_Titel :
Acoustics, Speech, and Signal Processing, 2000. ICASSP '00. Proceedings. 2000 IEEE International Conference on
Conference_Location :
Istanbul
Print_ISBN :
0-7803-6293-4
DOI :
10.1109/ICASSP.2000.859082
