Title :
Code Decomposition: Theory and Applications
Author_Institution :
Queen´s Univ., Kingston
Abstract :
In this paper, we give an overview of Seymour´s matroid decomposition theory in the context of binary linear codes, and discuss some of its implications for linear programming (LP) decoding of a binary linear code. As shown by Feldman et al. maximum-likelihood (ML) decoding over a discrete memoryless channel can be formulated as an LP problem. Using this formulation, we translate matroid-theoretic results of Grotschel and Truemper from the combinatorial optimization literature as examples of non-trivial families of codes for which ML decoding can be implemented in time polynomial in the length of the code. However, we also show that such families of codes are not good in a coding-theoretic sense - either their dimension or their minimum distance must grow sub-linearly with codelength.
Keywords :
binary codes; linear codes; linear programming; matrix decomposition; maximum likelihood decoding; LP problem; Seymour matroid decomposition theory; binary linear code; code decomposition theory; combinatorial optimization; discrete memoryless channel; linear programming decoding; maximum-likelihood decoding; Cost function; Councils; Linear code; Linear programming; Mathematics; Maximum likelihood decoding; Memoryless systems; Statistics; Vectors;
Conference_Titel :
Information Theory, 2007. ISIT 2007. IEEE International Symposium on
Conference_Location :
Nice
Print_ISBN :
978-1-4244-1397-3
DOI :
10.1109/ISIT.2007.4557271
