Title :
Capacity Achieving LDPC Codes Through Puncturing
Author :
Hsu, Chun-Hao ; Anastasopoulos, Achilleas
Author_Institution :
Qualcomm, Inc., Santa Clara, CA
Abstract :
The performance of punctured low-definition parity-check (LDPC) codes under maximum-likelihood (ML) decoding is studied in this correspondence via deriving and analyzing their average weight distributions (AWDs) and the corresponding asymptotic growth rate of the AWDs. In particular, it is proved that capacity-achieving codes of any rate and for any memoryless binary-input output-symmetric (MBIOS) channel under ML decoding can be constructed by puncturing some original LDPC code with small enough rate. Moreover, it is shown that the gap to capacity of all the punctured codes can be the same as the original code with a small enough rate. Conditions under which puncturing results in no rate loss with asymptotically high probability are also given in the process. These results show high potential for puncturing to be used in designing capacity-achieving codes, and in rate-compatible coding under any MBIOS channel.
Keywords :
binary codes; channel capacity; channel coding; maximum likelihood decoding; parity check codes; probability; AWD; MBIOS; ML decoding; average weight distributions; capacity achieving LDPC codes; low-definition parity-check codes; maximum-likelihood decoding; memoryless binary-input output-symmetric channel; probability; puncturing; AWGN; Concatenated codes; Graph theory; H infinity control; Iterative decoding; Maximum likelihood decoding; Mobile communication; Parity check codes; Performance analysis; Wireless networks; Asymptotic growth rate; average weight distribution; capacity-achieving codes; low-density parity-check (LDPC) codes; maximum-likelihood (ML) decoding; punctured codes; rate-adaptable codes;
Journal_Title :
Information Theory, IEEE Transactions on
DOI :
10.1109/TIT.2008.928274
