A low-power asynchronous data-path for a FIR filter bank

Proceedings Second International Symposium on Advanced Research in Asynchronous Circuits and Systems Pub Date : 1996-03-18 DOI:10.1109/ASYNC.1996.494451

L. S. Nielsen, J. Sparsø

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引用次数: 33

Abstract

This paper describes a number of design issues relating to the implementation of low-power asynchronous signal processing circuits. Specifically, the paper addresses the design of a dedicated processor structure that implements an audio FIR filter bank which is part of an industrial application. The algorithm requires a fixed number of steps and the moderate speed requirement allows a sequential implementation. The latter, in combination with a huge predominance of numerically small data values in the input data stream, is the key to a low-power asynchronous implementation. Power is minimized in two ways: by reducing the switching activity in the circuit, and by applying adaptive scaling of the supply voltage, in order to exploit the fact that the average case latency as 2-3 times better than the worst case. The paper reports on a study of properties of real life data, and discusses the implications it has on the choice of architecture, handshake-protocol, data-encoding, and circuit design. This includes a tagging scheme that divides the data-path into slices, and an asynchronous ripple carry adder that avoids a completion tree.

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FIR滤波器组的低功耗异步数据路径

本文介绍了一些与实现低功耗异步信号处理电路有关的设计问题。具体而言，本文讨论了实现音频FIR滤波器组的专用处理器结构的设计，这是工业应用的一部分。该算法需要固定数量的步骤，中等速度要求允许顺序实现。后者与输入数据流中数字小数据值的巨大优势相结合，是低功耗异步实现的关键。功率以两种方式最小化:通过减少电路中的开关活动，以及通过应用电源电压的自适应缩放，以便利用平均情况下延迟比最坏情况好2-3倍的事实。本文对现实生活数据的特性进行了研究，并讨论了它对架构选择、握手协议、数据编码和电路设计的影响。这包括将数据路径划分为片的标记方案，以及避免补全树的异步纹波进位加法器。

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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Proceedings Second International Symposium on Advanced Research in Asynchronous Circuits and Systems

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