Title :
Numerically-robust O(N2) RLS algorithms using least-squares prewhitening
Author_Institution :
Dept. of Electr. Eng., Southern Methodist Univ., Dallas, TX, USA
Abstract :
We derive two new O(N2) algorithms for arbitrary recursive least-squares (RLS) estimation tasks. The algorithms employ a novel update for an inverse square-root factor of the exponentially-windowed input signal autocorrelation matrix that is the least-squares equivalent of a natural gradient prewhitening algorithm. Both of the new RLS algorithms require 4N2+O(N) multiply/adds, two divides, and one square root per iteration to implement. We can prove that our new algorithms are numerically-robust, and simulations are used to indicate this fact in fixed-point arithmetic. An algorithm that computes the square-root factorization of the input signal autocorrelation matrix is also described
Keywords :
adaptive signal processing; computational complexity; correlation methods; fixed point arithmetic; least squares approximations; matrix decomposition; numerical stability; recursive estimation; adaptive filters; exponentially-windowed input signal; fixed-point arithmetic; gradient prewhitening algorithm; input signal autocorrelation matrix; inverse square-root factor update; least-squares prewhitening; numerically-robust RLS algorithms; recursive least-squares estimation; simulations; square-root factorization; Adaptive algorithm; Digital signal processing; Eigenvalues and eigenfunctions; Fixed-point arithmetic; Hardware; Matrices; Matrix decomposition; Numerical simulation; Resonance light scattering; Robustness;
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.2000.861994
