离散小波包变换体系结构研究及VLSI实现

Conference on High Density Microsystem Design and Packaging and Component Failure Analysis, 2006. HDP'06. Pub Date : 2006-06-27 DOI:10.1109/HDP.2006.1707554

XuMei-hua, Chen Zhang-jin, Ran Feng, Cheng Yu-lan

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引用次数: 7

摘要

提出了一种基于分帧结构的离散小波包变换硬件设计。在处理器的设计中，提出了一种内存的优化技术——同地址运算，可以减小内存的大小，提高硬件的使用效率。为满足外部系统的实时性要求，发展了双缓冲结构的存储系统，采用了四级流水线，提高了系统的实时数据处理能力。利用EDA工具对其进行了成功的合成和仿真，并在alters的EP20K200E FPGA上实现。实验表明，这种小波包变换结构能够实现实时性、通用性、参数化和单片可行性的设计目标

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Architecture research and VLSI implementation for discrete wavelet packet transform

A discrete wavelet packet transform hardware design based on frame-partitioned architecture is presented in this paper. In the design of the processor, a kind of optimization technique of memory-the same address operation is proposed, which can decrease the size of the memory and raise the hardware utility efficiency. A two-buffer structure memory system is evolved to meet the real time request of the outside system, and the adoption of four-stage pipeline increases the real time data processing ability of the system. It is successfully synthesized and simulated with EDA tools and implemented in FPGA of Alter's EP20K200E. It is demonstrated that this kind of wavelet packet transform architecture can carry out the design objectives of real time, universal, parameterized and one-chip feasible

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Conference on High Density Microsystem Design and Packaging and Component Failure Analysis, 2006. HDP'06.

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