Title :
Joint source-channel decoding for variable-length encoded data by exact and approximate MAP sequence estimation
Author :
Park, Moonseo ; Miller, David J.
Author_Institution :
Dept. of Electr. Eng., Pennsylvania State Univ., University Park, PA, USA
fDate :
1/1/2000 12:00:00 AM
Abstract :
Joint source-channel decoding based on residual source redundancy is an effective paradigm for error-resilient data compression. While previous work only considered fixed-rate systems, the extension of these techniques for variable-length encoded data was independently proposed by the authors and by Demir and Sayood (see Proc. Data Comp. Conf., Snowbird, UT, p.139-48, 1998). We describe and compare the performance of a computationally complex exact maximum a posteriori (MAP) decoder, its efficient approximation, an alternative approximate decoder, and an improved version of this decoder are suggested. Moreover, we evaluate several source and channel coding configurations. The results show that our approximate MAP technique outperforms other approximate methods and provides substantial error protection to variable-length encoded data
Keywords :
Huffman codes; approximation theory; binary codes; combined source-channel coding; convolutional codes; maximum likelihood decoding; maximum likelihood sequence estimation; quantisation (signal); variable length codes; DPCM; Huffman coding; MAP decoder; approximate MAP sequence estimation; approximate MAP technique; approximate decoder; binary convolutional encoding; channel coding; error protection; error-resilient data compression; image coding; joint source-channel decoding; maximum a posteriori decoder; nonbinary convolutional encoding; residual source redundancy; source coding; source encoding/quantization; variable-length encoded data; Channel coding; Communications Society; Data compression; Decoding; Delay; Error correction; Error correction codes; Forward error correction; Protection; Redundancy;
Journal_Title :
Communications, IEEE Transactions on
