Title :
Joint source-channel decoding of variable-length encoded sources
Author :
Murad, Ahsun H. ; Fuja, Thomas E.
Author_Institution :
Dept. of Electr. Eng. & Syst. Res. Center, Maryland Univ., College Park, MD, USA
Abstract :
In systems that employ source coding, imperfect compression may leave some redundancy in the data at the input to the channel encoder. This paper presents a new method for exploiting that redundancy via joint source-channel maximum a posteriori (MAP) decoding. The technique may be applied to systems that employ a variable-length source code in conjunction with a channel code; the decoder uses the residual redundancy that remains after compression to enhance robustness. The proposed technique (applicable to both memoryless and Markov sources) combines the source model, the source decoder and the channel decoder to construct a joint decoder with a conventional Viterbi structure. Simulation results comparing the performance of this approach with the conventional tandem decoding approach are presented
Keywords :
Huffman codes; Markov processes; combined source-channel coding; convolutional codes; decoding; memoryless systems; trellis codes; variable length codes; Huffman codes; MAP decoding; Markov sources; Viterbi structure; channel code; channel decoder; channel encoder; convolutional codes; data redundancy; imperfect compression; joint source-channel decoding; maximum a posteriori decoding; memoryless sources; residual redundancy; robustness; simulation results; source coding; source decoder; source model; tandem decoding; trellis codes; variable-length encoded sources; variable-length source code; Binary phase shift keying; Code standards; Convolutional codes; Decoding; Entropy; Modulation coding; Mutual information; Redundancy; Technological innovation; Tree graphs;
Conference_Titel :
Information Theory Workshop, 1998
Conference_Location :
Killarney
Print_ISBN :
0-7803-4408-1
DOI :
10.1109/ITW.1998.706451
