TY - JOUR
T1 - Characterizations of pseudo-codewords of (low-density) parity-check codes
AU - Koetter, Ralf
AU - Li, Wen Ching W.
AU - Vontobel, Pascal O.
AU - Walker, Judy L.
N1 - Funding Information:
* Corresponding author. E-mail addresses: [email protected] (R. Koetter), [email protected] (W.-C.W. Li), [email protected] (P.O. Vontobel), [email protected] (J.L. Walker). 1 The author was supported in part by NSF Grant #CCR-9984515. This work was completed while the author was with Coordinated Science Laboratory and Department of Electrical Engineering, University of Illinois, Urbana, IL 61801, USA. 2 The author was supported in part by NSA Grant #MDA904-03-1-0069 and NSF Grant #DMS-0457574. 3 The author was supported in part by NSF Grants #CCR 99-84515, #CCR 01-05719, and #ATM-0296033 and by DOE SciDAC and ONR Grant #N00014-00-1-0966. The work for this paper was done while the author was with the Department of Electrical and Computer Engineering at the University of Wisconsin, Madison. 4 The author was supported in part by NSF Grants #DMS-0302024 and #DMS-0602332.
PY - 2007/8/1
Y1 - 2007/8/1
N2 - An important property of low-density parity-check codes is the existence of highly efficient algorithms for their decoding. Many of the most efficient, recent graph-based algorithms, e.g. message-passing iterative decoding and linear programming decoding, crucially depend on the efficient representation of a code in a graphical model. In order to understand the performance of these algorithms, we argue for the characterization of codes in terms of a so-called fundamental cone in Euclidean space. This cone depends upon a given parity-check matrix of a code, rather than on the code itself. We give a number of properties of this fundamental cone derived from its connection to unramified covers of the graphical models on which the decoding algorithms operate. For the class of cycle codes, these developments naturally lead to a characterization of the fundamental cone as the Newton polyhedron of the Hashimoto edge zeta function of the underlying graph.
AB - An important property of low-density parity-check codes is the existence of highly efficient algorithms for their decoding. Many of the most efficient, recent graph-based algorithms, e.g. message-passing iterative decoding and linear programming decoding, crucially depend on the efficient representation of a code in a graphical model. In order to understand the performance of these algorithms, we argue for the characterization of codes in terms of a so-called fundamental cone in Euclidean space. This cone depends upon a given parity-check matrix of a code, rather than on the code itself. We give a number of properties of this fundamental cone derived from its connection to unramified covers of the graphical models on which the decoding algorithms operate. For the class of cycle codes, these developments naturally lead to a characterization of the fundamental cone as the Newton polyhedron of the Hashimoto edge zeta function of the underlying graph.
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U2 - 10.1016/j.aim.2006.12.010
DO - 10.1016/j.aim.2006.12.010
M3 - Article
AN - SCOPUS:34247259422
SN - 0001-8708
VL - 213
SP - 205
EP - 229
JO - Advances in Mathematics
JF - Advances in Mathematics
IS - 1
ER -