可扩展的低功耗LDPC解码器设计，采用高级算法合成

2009 IEEE International SOC Conference (SOCC) Pub Date : 2009-09-01 DOI:10.1109/SOCCON.2009.5398044

Yang Sun, Joseph R. Cavallaro, Tai Ly

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引用次数: 22

摘要

提出了一种适用于下一代无线手机SoC的可扩展低功耗低密度LDPC解码器设计方案。该方法基于高级综合:PICO(程序-芯片-取出)工具用于直接从顺序非定时C算法生成有效的RTL。我们提出了两种并行LDPC解码器架构:(1)具有可扩展并行性的逐层解码架构;(2)具有更高吞吐量的多层流水线解码架构。基于PICO技术，我们在台积电65nm 0.9V 8金属层CMOS技术上实现了两层流水线解码器，核心面积为1.2 mm2。当工作在400mhz时钟频率时，最大可实现吞吐量为415 Mbps，估计峰值功耗为180mw。

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Scalable and low power LDPC decoder design using high level algorithmic synthesis

This paper presents a scalable and low power low-density parity-check (LDPC) decoder design for the next generation wireless handset SoC. The methodology is based on high level synthesis: PICO (program-in chip-out) tool was used to produce efficient RTL directly from a sequential un-timed C algorithm. We propose two parallel LDPC decoder architectures: (1) per-layer decoding architecture with scalable parallelism, and (2) multi-layer pipelined decoding architecture to achieve higher throughput. Based on the PICO technology, we have implemented a two-layer pipelined decoder on a TSMC 65nm 0.9V 8-metal layer CMOS technology with a core area of 1.2 mm2. The maximum achievable throughput is 415 Mbps when operating at 400 MHz clock frequency and the estimated peak power consumption is 180 mW.

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2009 IEEE International SOC Conference (SOCC)

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