The perhaps most challenging problem in acoustic feedback cancellation using adaptive filters is the bias problem. It is well-known that a probe noise approach can effectively prevent this problem. However, when the probe noise must be inaudible and the steady-state error of the adaptive filter must be unchanged, this approach causes a significantly decreased convergence rate of the adaptive filter, and might thereby be less useful in practical applications. In this work, we propose a new probe noise approach which significantly increases the convergence rate while maintaining the steady-state error of the adaptive algorithm in a multiple-microphone and single-loud-speaker audio system. This is obtained through a specifically designed probe noise signal and a corresponding probe noise enhancement strategy. We show the effects of the proposed probe noise approach by deriving analytical expressions for its system behavior, and through a simulation experiment in an acoustic feedback cancellation system.
[1]
H. Nyquist,et al.
The Regeneration Theory
,
1954,
Journal of Fluids Engineering.
[2]
Marc Moonen,et al.
Adaptive feedback cancellation in hearing aids
,
2006,
J. Frankl. Inst..
[3]
Jesper Jensen,et al.
On Acoustic Feedback Cancellation Using Probe Noise in Multiple-Microphone and Single-Loudspeaker Systems
,
2012,
IEEE Signal Processing Letters.
[4]
Marc Moonen,et al.
Fifty Years of Acoustic Feedback Control: State of the Art and Future Challenges
,
2011,
Proceedings of the IEEE.
[5]
Jesper Jensen,et al.
Analysis of adaptive feedback and echo cancelation algorithms in a general multiple-microphone and single-loudspeaker system
,
2011,
2011 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP).