Block realization of multirate adaptive digital filters

In this paper, we study multirate transversal adaptive digital filters (ADF's) based on the block least-mean-square (BLMS) algorithms. These include an ADF with decimation (ADFD) and an ADF with interpolation (ADFI). We first formulate these filters based on the block mean-squared error (BMSE) criterion and derive BLMS multi-rate weight-adjustment algorithms, and then study efficient realization of those filters. It is shown that the BLMS ADFD can be realized efficiently in the direct form or in the filter-bank structure both using the fast Fourier transform (FFT) and an appropriate sectioning procedure. According to our analysis of computational complexity, the FFT realization of the BLMS ADFD in the filter-bank structure is more efficient than in the direct form, and the two structures using the FFT become more efficient in comparison to the LMS ADFD as the number of weights increases. Unlike the direct form realization, the filter-bank realization of the BLMS ADFD using the FFT becomes more efficient as the decimation ratio increases. Similar results have been obtained for the BLMS ADFI. Finally, we investigate by computer simulation the effects of different weight-adjustment algorithms and several system parameters on the performances of ADFD's. The results of simulation indicate that, as expected, the convergence speed of the BLMS ADFD can be significantly improved by self-orthogonalization of weight adjustment in the frequency domain. Furthermore, the convergence factor of the self-orthogonalizing BLMS ADFD can be chosen such that the steady-state performance of the new ADFD is the same as that of the existing LMS ADFD.

[1]  Jae Lee On the interrelationships among a class of convolutions , 1984 .

[2]  S. Weinstein A Passband Data-Driven Echo Canceller for Full-Duplex Transmission on Two-Wire Circuits , 1977, IEEE Trans. Commun..

[3]  David Falconer,et al.  Adaptive Reference Echo Cancellation , 1982, IEEE Trans. Commun..

[4]  E. Ferrara Fast implementations of LMS adaptive filters , 1980 .

[5]  A. Gray,et al.  Unconstrained frequency-domain adaptive filter , 1982 .

[6]  Richard D. Gitlin,et al.  Self-Orthogonalizing Adaptive Equalization Algorithms , 1977, IEEE Trans. Commun..

[7]  S. Mitra,et al.  A unified approach to time- and frequency-domain realization of FIR adaptive digital filters , 1983 .

[8]  Georges Bonnerot,et al.  Digital filtering by polyphase network:Application to sample-rate alteration and filter banks , 1976 .

[9]  Richard D. Gitlin,et al.  The Effects of Large Interference on the Tracking Capability of Digitally Implemented Echo Cancellers , 1978, IEEE Trans. Commun..

[10]  Jae Chon Lee,et al.  Performance of transform-domain LMS adaptive digital filters , 1986, IEEE Trans. Acoust. Speech Signal Process..

[11]  L.R. Rabiner,et al.  Interpolation and decimation of digital signals—A tutorial review , 1981, Proceedings of the IEEE.

[12]  Jae Lee,et al.  Realization of adaptive digital filters using the Fermat number transform , 1985, IEEE Trans. Acoust. Speech Signal Process..

[13]  R. D. Gitlin,et al.  Fractionally-spaced equalization: An improved digital transversal equalizer , 1981, The Bell System Technical Journal.

[14]  B. Widrow,et al.  The complex LMS algorithm , 1975, Proceedings of the IEEE.

[15]  G. Ungerboeck,et al.  Fractional Tap-Spacing Equalizer and Consequences for Clock Recovery in Data Modems , 1976, IEEE Trans. Commun..

[16]  Giancarlo Prati,et al.  Self-Orthogonalizing Adaptive Equalization in the Discrete Frequency Domain , 1984, IEEE Trans. Commun..

[17]  J.C. Lee,et al.  A frequency-weighted block LMS algorithm and its application to speech processing , 1985, Proceedings of the IEEE.

[18]  Chong Kwan Un,et al.  A reduced structure of the frequency-domain block LMS adaptive digital filter , 1984 .

[19]  S. Weinstein Echo cancellation in the telephone network , 1977, IEEE Communications Society Magazine.

[20]  Sanjit K. Mitra,et al.  Block implementation of adaptive digital filters , 1981 .