Title :
Low-power approach for decoding convolutional codes with adaptive Viterbi algorithm approximations
Author :
Henning, R. ; Chakrabarti, C.
Author_Institution :
Dept. of Electr. Eng., Arizona State Univ., Tempe, AZ, USA
Abstract :
Significant power reduction can be achieved by exploiting real-time variation in system characteristics while decoding convolutional codes. The approach proposed herein adaptively approximates Viterbi decoding by varying truncation length and pruning threshold of the T-algorithm while employing trace-back memory management. Adaptation is performed according to variations in signal-to-noise ratio, code rate, and maximum acceptable bit error rate. Potential energy reduction of 70 to 97.5% compared to Viterbi decoding is demonstrated. The superiority of adaptive T-algorithm decoding compared to fixed T-algorithm decoding is studied. General conclusions about when applications can particularly benefit from this approach are given.
Keywords :
Viterbi decoding; adaptive decoding; convolutional codes; error statistics; low-power electronics; storage management; T-algorithm; Viterbi decoder; Viterbi decoding; adaptive T-algorithm decoding; adaptive Viterbi algorithm approximations; code rate; convolutional codes; energy reduction; fixed T-algorithm. decoding; low-power communications devices; low-power decoding approach; maximum acceptable bit error rate; power reduction; pruning threshold; real-time system characteristics variation; signal-to-noise ratio; trace-back memory management; truncation length; Bandwidth; Bit error rate; Convolution; Convolutional codes; Decoding; Energy consumption; Memory management; Potential energy; Signal to noise ratio; Viterbi algorithm;
Conference_Titel :
Low Power Electronics and Design, 2002. ISLPED '02. Proceedings of the 2002 International Symposium on
Print_ISBN :
1-5811-3475-4
DOI :
10.1109/LPE.2002.146712
