Title :
A numerically-stable sliding-window estimator and its application to adaptive filters
Author :
Douglas, S.C. ; Soh, J.K.
Author_Institution :
Dept. of Electr. Eng., Utah Univ., Salt Lake City, UT, USA
Abstract :
While it is possible to implement the sliding discrete Fourier transform (DFT) recursively, numerical errors accumulate in the resulting outputs. This paper presents a recursive system whose output at every Lth sample time is equivalent to that of the sliding DFT and whose numerical errors do not grow with time. We provide a statistical analysis of the numerical performance of the proposed technique, showing that it outperforms a similar approximate method employing an exponentially-decaying window. When applied to sliding-window-covariance RLS adaptive filters, the technique mitigates this system´s error accumulation without any significant increase in complexity. An extension of the method to the sliding discrete cosine transform (DCT) is also provided.
Keywords :
adaptive filters; computational complexity; discrete Fourier transforms; discrete cosine transforms; error analysis; numerical stability; recursive estimation; recursive filters; statistical analysis; adaptive filters; complexity; error accumulation; numerical errors; numerically-stable sliding-window estimator; recursive system; sliding DFT; sliding discrete Fourier transform; sliding discrete cosine transform; sliding-window-covariance RLS adaptive filters; statistical analysis; Adaptive filters; Adaptive signal processing; Cities and towns; Discrete Fourier transforms; Discrete cosine transforms; Estimation error; Finite impulse response filter; Least squares approximation; Resonance light scattering; Statistical analysis;
Conference_Titel :
Signals, Systems & Computers, 1997. Conference Record of the Thirty-First Asilomar Conference on
Conference_Location :
Pacific Grove, CA, USA
Print_ISBN :
0-8186-8316-3
DOI :
10.1109/ACSSC.1997.680039
