Title :
Soft syndrome decoding of binary convolutional codes
Author :
Ariel, M. ; Snyders, J.
Author_Institution :
Dept. of Electr. Eng. Syst., Tel Aviv Univ., Israel
Abstract :
We present an efficient recursive algorithm for accomplishing maximum likelihood (ML) soft syndrome decoding of binary convolutional codes. The algorithm consists of signal-by-signal hard decoding followed by a search for the most likely error sequence. The number of error sequences to be considered is substantially larger than in hard decoding, since the metric applied to the error bits is the magnitude of the log likelihood ratio rather than the Hamming weight. An error-trellis (alternatively, a decoding table) is employed for describing the recursion equations of the decoding procedure. The number of its states is determined by the states indicator, which is a modified version of the constraint length of the check matrix. Methods devised for eliminating error patterns and degenerating error-trellis sections enable accelerated ML decoding. In comparison with the Viterbi algorithm, the syndrome decoding algorithm achieves substantial reduction in the average computational complexity, particularly for moderately noisy channels.<>
Keywords :
binary sequences; coding errors; computational complexity; convolutional codes; error statistics; maximum likelihood decoding; polynomial matrices; recursive estimation; telecommunication channels; ML decoding; binary convolutional codes; computational complexity; constraint length; decoding table; error patterns; error sequences; error-trellis; hard decoding; log likelihood ratio; maximum likelihood decoding; noisy channels; polynomial check matrix; recursion equations; recursive algorithm; soft syndrome decoding; states indicator; syndrome decoding algorithm; Acceleration; Computational complexity; Convolutional codes; Equations; Hamming weight; Maximum likelihood decoding; Noise reduction; Viterbi algorithm;
Journal_Title :
Communications, IEEE Transactions on
