Title :
Fast converging and low complexity adaptive filtering using an averaged Kalman filter
Author :
Wigren, Torbjörn
Author_Institution :
R&D Div., Ericsson Radar Electron. AB, Stockholm, Sweden
fDate :
2/1/1998 12:00:00 AM
Abstract :
Kalman filtering is applied to obtain a fast converging, low complexity adaptive filter that is of the matrix stepsize normalized least mean square (NLMS) type. By replacing certain variables with averages, the solution of an averaged diagonal Riccati equation allows optimal time varying adaptation gains to be precomputed or computed online with a small number of scalar Riccati equations. The adaptation gains are computed from prior assumptions on impulse response power and shape. This fact results in a systematic procedure for adaptation gain tuning in the time-varying matrix stepsize case. Simulations using music as input, show significant performance improvements as compared with the NLMS algorithm
Keywords :
Riccati equations; adaptive Kalman filters; adaptive signal processing; echo suppression; filtering theory; least mean squares methods; matrix algebra; music; time-varying filters; transient response; NLMS; adaptation gain tuning; averaged Kalman filter; averaged diagonal Riccati equation; echo suppression; fast convergence; impulse response power; impulse response shape; low complexity adaptive filtering; music; normalized least mean square; optimal time varying adaptation gains; scalar Riccati equations; simulations; time-varying matrix stepsize; Adaptive filters; Convergence; Filtering algorithms; Gaussian noise; Kalman filters; Noise measurement; Riccati equations; Shape; Signal processing algorithms; Steady-state;
Journal_Title :
Signal Processing, IEEE Transactions on
