Receiver optimization for dispersive channels employing coded modulation, with application in high rate digital subscriber line transmission

The authors consider decision-feedback sequence estimation of coded modulated signals transmitted over dispersive channels, and examine its application in high-bit-rate (>144-kb/s) transmission over metallic subscriber lines. To mitigate the adverse effect of colored noise, they consider a scheme called noise prediction. Formulas for optimal receiver filters under a minimum mean-squared-error criterion are derived. A key step in the optimization process is the solution of a max-min problem. Because of the complexity in solving this problem, a suboptimal solution is considered which leads to a convenient lower bound on the potential transmission performance. The derived theory is applied to a few example subscriber lines. Numerical results show the potential of substantial signal-to-signal-ratio gain over pure decision-feedback equalization.<<ETX>>

[1]  N. G. Cole,et al.  The potential for high-rate digital subscriber loops , 1989, IEEE International Conference on Communications, World Prosperity Through Communications,.

[2]  Pierre Chevillat,et al.  Decoding of trellis-encoded signals in the presence of intersymbol interference and noise , 1988, IEEE International Conference on Communications, - Spanning the Universe..

[3]  M. Vedat Eyuboglu,et al.  Detection of coded modulation signals on linear, severely distorted channels using decision-feedback noise prediction with interleaving , 1988, IEEE Trans. Commun..

[4]  David Falconer,et al.  Reduced state sequence estimation techniques for digital subscriber loop application , 1988, IEEE Global Telecommunications Conference and Exhibition. Communications for the Information Age.

[5]  D. D. Falconer,et al.  Adaptive channel memory truncation for maximum likelihood sequence estimation , 1973 .

[6]  Ezio Biglieri Ungerboeck codes do not shape the signal power spectrum , 1986, IEEE Trans. Inf. Theory.

[7]  UngerboeckG. Trellis-coded modulation with redundant signal sets Part II , 1987 .

[8]  S. Haykin,et al.  Adaptive Filter Theory , 1986 .

[9]  C.A. Belfiore,et al.  Decision feedback equalization , 1979, Proceedings of the IEEE.

[10]  Alexandra Duel-Hallen,et al.  Delayed decision-feedback sequence estimation , 1989, IEEE Trans. Commun..

[11]  G. David Forney,et al.  Maximum-likelihood sequence estimation of digital sequences in the presence of intersymbol interference , 1972, IEEE Trans. Inf. Theory.

[12]  David W. Lin Wide-band digital subscriber access with multidimensional block modulation and decision-feedback equalization , 1989, IEEE J. Sel. Areas Commun..

[13]  Kenneth Steiglitz,et al.  Multi-channel signal processing for data communications in the presence of crosstalk , 1988, ICASSP-88., International Conference on Acoustics, Speech, and Signal Processing.

[14]  Shahid U. H. Qureshi,et al.  Reduced-state sequence estimation with set partitioning and decision feedback , 1988, IEEE Trans. Commun..

[15]  J. W. Lechleider The feasibility of using adaptive transmitters to suppress crosstalk , 1989, IEEE International Conference on Communications, World Prosperity Through Communications,.

[16]  John M. Cioffi,et al.  Spectrally constrained codes for high rate ISDN subscriber loop , 1988, IEEE International Conference on Communications, - Spanning the Universe..

[17]  M. V. Eyuboglu,et al.  Reduced-state sequence estimation for trellis-coded modulation on intersymbol interference channels , 1988, IEEE Global Telecommunications Conference and Exhibition. Communications for the Information Age.

[18]  Ezio Biglieri,et al.  High-Level Modulation and Coding for Nonlinear Satellite Channels , 1984, IEEE Trans. Commun..

[19]  E. E. Newhall,et al.  Adaptive receiver for data transmission over time-dispersive channels , 1973, IEEE Trans. Inf. Theory.

[20]  G. David Forney,et al.  Coset codes-I: Introduction and geometrical classification , 1988, IEEE Trans. Inf. Theory.

[21]  G. Ungerboeck,et al.  Trellis-coded modulation with redundant signal sets Part I: Introduction , 1987, IEEE Communications Magazine.