Title :
New Stopping Criterion for Fast Low-Density Parity-Check Decoders
Author :
Tian Xia ; Hsiao-Chun Wu ; Hong Jiang
Author_Institution :
Sch. of Electr. Eng. & Comput. Sci., Louisiana State Univ., Baton Rouge, LA, USA
Abstract :
Low-density parity-check (LDPC) codes are favorable in low bit-error-rate and high code-rate applications. However, the decoding complexity for LDPC codes is quite large, especially for nonbinary LDPC codes. In this paper, we propose a new T-tolerance stopping criterion for LDPC decoders by exploiting the fact that the total aposteriori probability (APP) should increase across iterations when message passing (MP) algorithms are employed. Simulation results demonstrate that our proposed new T-tolerance criterion can greatly reduce the average iteration number (complexity) while the decoding performance degradation is controlled within 0.1 dB in the low bit-energy-to-noise-spectral-density ratio (Eb/N0) scenarios.
Keywords :
computational complexity; error statistics; iterative decoding; message passing; number theory; parity check codes; LDPC decoders; T-tolerance stopping criterion; average iteration number reduction; decoding complexity; decoding performance degradation; fast low-density parity-check decoders; high code-rate application; low bit-energy-to-noise-spectral-density ratio scenario; low bit-error-rate; message passing algorithm; nonbinary LDPC codes; total a posteriori probability; Algorithm design and analysis; Complexity theory; Decoding; Iterative decoding; Monte Carlo methods; Robustness; Iterative decoding; low-density parity-check codes; stopping criterion;
Journal_Title :
Communications Letters, IEEE
DOI :
10.1109/LCOMM.2014.2349988
