Hardware-Efficient and High-Throughput LLRC Segregation Based Binary QC-LDPC Decoding Algorithm and Architecture

Abstract

This brief proposes hardware-friendly QC-LDPC decoding algorithm with layered scheduling based on new logarithmic-likelihood-ratio compound (LLRC) segregation technique. Subsequently, we present hardware-efficient QC-LDPC decoder-architecture based on the proposed algorithm and additional architectural optimizations. This decoder has been designed based on the 5G-NR specifications, supporting code-lengths and code-rates in the ranges of 26112-10368 bits and 1/3-8/9, respectively. Performance analysis has shown that suggested LLRC-segregation based decoding algorithm delivers adequate FER of 10 <sup xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">-5</sup> between 1 to 6.5 dB of SNR range. Furthermore, proposed QC-LDPC decoder is post-route simulated and implemented on the FPGA platform. It operates at a maximum clock frequency of 135 MHz and delivers a peak throughput of 11.02 Gbps. Eventually, comparison with relevant works shows that our decoder delivers 2.2× higher throughput and 8.3× better hardware-efficiency than the state-of-the-art implementations.