Title
Interleaver Design for Serially Concatenated Convolutional Codes: Theory and Application
Publication Date
6-1-2004
Document Type
Article
Abstract
This paper addresses the problem of interleaver design for serially concatenated convolutional codes (SCCCs) tailored to the constituent codes of the SCCC configuration. We present a theoretical framework for interleaver optimization based on a cost function closely tied to the asymptotic bit-error rate (BER) of the block code Cs resulting from proper termination of the constituent codes in the SCCC code. We define a canonical form of the interleaving engine denoted as the finite state permuter (FSP) and using its structural property, develop a systematic iterative technique for construction of interleavers. The core theoretical results focus on the asymptotic behavior of a class of cost functions and their martingale property, which is then used to develop an order recursive interleaver optimization algorithm. We address the issue of the complexity of the interleaver growth algorithm presented in the paper and demonstrate that it has polynomial complexity. Subsequently, we provide details about the application of the proposed technique and present a modification of the algorithm that employs error pattern feedback for improved performance at a reduced complexity. Sample experimental results are provided for an SCCC code of rate 1/3 and information block length 320 that achieves a minimum distance of dmin=44.
Publication Title
IEEE Transactions on Information Theory
Volume
50
Issue
6
First Page
1177
Last Page
1188
DOI
10.1109/TIT.2004.828065
Publisher Policy
pre-print, post-print
Recommended Citation
Laddomada, Massimiliano; Daneshgaran, F.; and Mondin, M., "Interleaver Design for Serially Concatenated Convolutional Codes: Theory and Application" (2004). School of Engineering and Technology Publications. 174.
https://digitalcommons.tacoma.uw.edu/tech_pub/174
