论文信息 - Computational complexity of sequential sequence estimation for intersymbol interference channels

Computational complexity of sequential sequence estimation for intersymbol interference channels

The computational complexity of a sequential algorithm (SA) developed for intersymbol interference (ISI) channels is analyzed. To determine the computational complexity, the finite-state machine that models the channel and white matched filter system, of which the SA is a part, is interpreted as a special convolutional encoder followed by a binary symbol to Q-ary symbol mapping. It follows that the computational distribution is Pareto, and that there exists a computational cutoff rate R/sub comp/. For the uncoded data considered, the rate is fixed and the R/sub comp/ criterion translates into a signal-to-noise ratio (SNR) criterion. An upper bound on SNR/sub comp/ is found analytically by assuming a uniform input distribution. Iteration equations developed by S. Arimoto (1976) are adapted to find the true SNR/sub comp/ numerically. >

Fuqin Xiong | Edward Shwedyk | Qingyuan Dai

[1] John E. Savage,et al. Sequential decoding — the computation problem , 1966 .

[2] Fuqin Xiong,et al. Sequential sequence estimation for channels with intersymbol interference of finite or infinite length , 1990, IEEE Trans. Commun..

[3] G. David Forney,et al. Convolutional Codes III. Sequential Decoding , 1974, Inf. Control..

[4] Suguru Arimoto. Computation of random coding exponent functions , 1976, IEEE Trans. Inf. Theory.

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

[6] Daniel J. Costello,et al. A multiple stack algorithm for erasurefree decoding of convolutional codes , 1977, IEEE Transactions on Communications.

[7] R. Gallager. Information Theory and Reliable Communication , 1968 .

[8] Shu Lin,et al. Error control coding : fundamentals and applications , 1983 .