Efficient FPGA implementation of H.264 CAVLC entropy decoder

2013 8th IEEE Design and Test Symposium Pub Date : 2013-12-01 DOI:10.1109/IDT.2013.6727116

A. Siblini, Elias Baaklini, Hassan Sbeity, A. Fadlallah, S. Niar

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引用次数: 3

Abstract

Multiprocessor-system-on-a-chip (MPSoC) is the dominating architecture in embedded systems. Applications need to be multi-threaded to benefit from the concurrency provided by the MPSoC. Many parallel versions of the new emerging H.264/AVC [1] already exist. However, providing a full parallel H.264 version is blocked by the fact that all parts of the decoder depend on the first sequential stage of the decoding process which is the entropy decoder (mainly CAVLC). The entropy decoder consumes about 30% [8] of the total time of the decoder. In this work, we propose an optimized FPGA design achieving the demands of multi-threaded H.264 decoder versions which can be integrated in an MPSoC. We focus in our work on time optimization and on cycle number decrease when decoding an encoded 4×4 block of pixels. We also aim to achieve a design that operates at high frequencies. The work leads to the ability to decode at least 62 frames per second for HD resolution 1280×720. Decoding takes 22 clock cycles for one block of 4×4 pixels at most. The design has an upper frequency limit of 247MHz. High resolutions frames such as 1920×1088 FHD (full high definition) video maintain a minimum frequency of 30 fps.

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H.264 CAVLC熵解码器的高效FPGA实现

多处理器单片系统(MPSoC)是嵌入式系统的主流架构。应用程序需要多线程才能从MPSoC提供的并发性中受益。许多新出现的H.264/AVC[1]的并行版本已经存在。然而，由于解码器的所有部分都依赖于解码过程的第一个顺序阶段，即熵解码器(主要是CAVLC)，因此无法提供完全并行的H.264版本。熵解码器大约消耗解码器总时间的30%[8]。在这项工作中，我们提出了一种优化的FPGA设计，以实现可集成在MPSoC中的多线程H.264解码器版本的需求。在解码编码的4×4像素块时，我们的工作重点是时间优化和周期数减少。我们还致力于实现在高频率下工作的设计。这项工作导致解码至少每秒62帧高清分辨率1280×720的能力。解码一个4×4像素块最多需要22个时钟周期。本设计的频率上限为247MHz。高分辨率帧，如1920×1088 FHD(全高清)视频保持最低频率为30fps。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2013 8th IEEE Design and Test Symposium

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