Title :
Minimum-distance bounds by graph analysis
Author :
Tanner, Robert Michael
Author_Institution :
Dept. of Comput. & Inf. Sci., California Univ., Santa Cruz, CA, USA
fDate :
2/1/2001 12:00:00 AM
Abstract :
The parity-check matrix of a linear code is used to define a bipartite code constraint (Tanner) graph in which bit nodes are connected to parity-check nodes. The connectivity properties of this graph are analyzed using both local connectivity and the eigenvalues of the associated adjacency matrix. A simple lower bound on the minimum distance of the code is expressed in terms of the two largest eigenvalues. For a more powerful bound, local properties of the subgraph corresponding to a minimum-weight word in the code are used to create an optimization problem whose solution is a lower bound on the code´s minimum distance. Linear programming gives one bound. The technique is illustrated by applying it to sparse block codes with parameters [7,3,4] and [42,23,6]
Keywords :
binary codes; block codes; eigenvalues and eigenfunctions; error correction codes; graph theory; linear codes; linear programming; matrix algebra; Tanner graph; associated adjacency matrix; bipartite code constraint graph; bit nodes are; connectivity properties; eigenvalues; graph analysis; linear code; linear programming; local connectivity; lower bound; minimum-distance bounds; minimum-weight word; optimization problem; parity-check matrix; parity-check nodes; sparse block codes; subgraph; Block codes; Eigenvalues and eigenfunctions; Error correction codes; Iterative decoding; Linear code; Linear programming; Paper technology; Parity check codes; Signal to noise ratio; Sparse matrices;
Journal_Title :
Information Theory, IEEE Transactions on
