随机计算中带噪声新兴器件的精确随机数发生器设计

2017 IEEE/ACM International Conference on Computer-Aided Design (ICCAD) Pub Date : 2017-11-13 DOI:10.1109/ICCAD.2017.8203837

Meng Yang, J. Hayes, Deliang Fan, Weikang Qian

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引用次数: 6

摘要

随机计算(SC)是一种基于随机比特流的非常规计算范式。由于其计算核心的面积和功率需求非常低，最近引起了人们的关注。SC依靠随机数字生成器(sng)将输入二进制数映射到随机比特流。传统的SNG包括一个随机数源(RNS)，通常是一个LFSR和一个比较器。它需要比SC核心更多的面积和功率，抵消了后者的主要优势。为了缓解这一问题，人们提出了采用新兴纳米级器件(如忆阻器和自旋电子器件)的sng。然而，由于制造过程中不可预测的变化和控制信号中的噪声，这些器件的输出概率往往存在较大误差。我们提出了一种利用这种装置来设计高精度煤制煤的新方法。它是围绕RNS构建的，该RNS在理想(名义)条件下生成均匀分布的随机数。它还具有一种新颖的误差消除概率转换电路(ECPCC)，可以保证在RNS存在误差的实际情况下，输出概率具有很高的精度。ECPCC还可用于生成最大相关随机流，这在某些应用中是一个有用的特性。

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Design of accurate stochastic number generators with noisy emerging devices for stochastic computing

Stochastic computing (SC) is an unconventional computing paradigm that operates on stochastic bit streams. It has gained attention recently because of the very low area and power needs of its computing core. SC relies on stochastic number generators (SNGs) to map input binary numbers to stochastic bit streams. A conventional SNG comprises a random number source (RNS), typically an LFSR, and a comparator. It needs far more area and power than the SC core, offsetting the latter's main advantages. To mitigate this problem, SNGs employing emerging nanoscale devices such as memristors and spintronic devices have been proposed. However, these devices tend to have large errors in their output probabilities due to unpredictable variations in their fabrication processes and noise in their control signals. We present a novel method of exploiting such devices to design a highly accurate SNG. It is built around an RNS that generates uniformly distributed random numbers under ideal (nominal) conditions. It also has a novel error-cancelling probability conversion circuit (ECPCC) that guarantees very high accuracy in the output probability under realistic conditions when the RNS is subject to errors. An ECPCC can also be used to generate maximally correlated stochastic streams, a useful property for some applications.

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来源期刊

2017 IEEE/ACM International Conference on Computer-Aided Design (ICCAD)

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