Title :
Limited search trellis decoding of convolutional codes
Author :
Anderson, John B.
Author_Institution :
Dept. of Electr. Comput. & Syst. Eng., Rensselaer Polytech. Inst., Troy, NY, USA
fDate :
9/1/1989 12:00:00 AM
Abstract :
The least storage and node computation required by a breadth-first tree or trellis decoder that corrects t errors over the binary symmetric channels is calculated. Breadth-first decoders work with code paths of the same length, without backtracking. The Viterbi algorithm is an exhaustive trellis decoder of this type; other schemes look at a subset of the tree or trellis paths. For random tree codes, theorems about the asymptotic number of paths required and their depth are proved. For concrete convolutional codes, the worst case storage for t error sequences is measured. In both cases the optimal decoder storage has the same simple dependence on t. The M algorithm and algorithms proposed by G.J. Foschini (ibid., vol.IT-23, p.605-9, Sept. 1977) and by S.J. Simmons (PhD. diss., Queens Univ., Kingston, Ont., Canada) are optimal, or nearly so; they are all far more efficient than the Viterbi algorithm
Keywords :
codes; decoding; error correction; Viterbi algorithm; binary symmetric channels; breadth first tree decoder; convolutional codes; error correction; limited search trellis decoding; random tree codes; trellis decoder; worst case storage; Binary codes; Concrete; Convolutional codes; Error correction codes; Helium; Information theory; Iterative decoding; Tree data structures; Tree graphs; Viterbi algorithm;
Journal_Title :
Information Theory, IEEE Transactions on
