Area-Aware Decomposition for Single-Electron Transistor Arrays

ACM Trans. Design Autom. Electr. Syst. Pub Date : 2016-09-22 DOI:10.1145/2898998

C. Ho, Yung-Chih Chen, Chun-Yao Wang, Ching-Yi Huang, S. Datta, N. Vijaykrishnan

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引用次数: 3

Abstract

Single-electron transistor (SET) at room temperature has been demonstrated as a promising device for extending Moore’s law due to its ultra-low power consumption. Existing SET synthesis methods synthesize a Boolean network into a large reconfigurable SET array where the height of SET array equals the number of primary inputs. However, recent experiments on device level have shown that this height is restricted to a small number, say, 10, rather than arbitrary value due to the ultra-low driving strength of SET devices. On the other hand, the width of an SET array is also suggested to be a small value. Consequently, it is necessary to decompose a large SET array into a set of small SET arrays where each of them realizes a sub-function of the original circuit with no more than 10 inputs. Thus, this article presents two techniques for achieving area-efficient SET array decomposition: One is a width minimization algorithm for reducing the area of a single SET array; the other is a depth-bounded mapping algorithm, which decomposes a Boolean network into many sub-functions such that the widths of the corresponding SET arrays are balanced. The width minimization algorithm leads to a 25%--41% improvement compared to the state of the art, and the mapping algorithm achieves a 60% reduction in total area compared to a naïve approach.

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单电子晶体管阵列的区域感知分解

室温下的单电子晶体管(SET)由于其超低的功耗而被证明是一种很有前途的扩展摩尔定律的器件。现有的SET综合方法将布尔网络合成为一个可重构的大型SET数组，SET数组的高度等于主要输入的个数。然而，最近在器件水平上的实验表明，由于SET器件的超低驱动强度，该高度被限制在一个小数字上，例如10，而不是任意值。另一方面，SET数组的宽度也建议是一个较小的值。因此，有必要将一个大的SET数组分解成一组小的SET数组，每个小的SET数组实现原电路的一个子功能，输入不超过10个。因此，本文提出了实现面积高效SET数组分解的两种技术:一种是用于减少单个SET数组面积的宽度最小化算法;另一种是深度有界映射算法，该算法将布尔网络分解为许多子函数，从而使相应SET数组的宽度平衡。与目前的技术相比，宽度最小化算法可以提高25%- 41%，与naïve方法相比，映射算法可以减少60%的总面积。

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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ACM Trans. Design Autom. Electr. Syst.

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