Superconductor Processor Architecture

Koji Inoue, Masamitsu Tanaka, Koki Ishida
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Abstract

Synopsis : Moore’s Law, doubling the number of transistors in a chip every two years, has contributed to the evolution of computer system architectures to date. The growth of such hardware implementation makes many optimization opportunities available to software developers. Unfortunately, we cannot expect sustainable transistor shrinking anymore; that is, the end of Moore’s Law will come. Although device and manufacturing technologies continue to progress, some researchers predict that transistor shrinking may stop around 2030 to 2035 due to physical or economic reasons. The goal of this research is to open the door for post-CMOS ultrahigh-performance, low-power computing. Our approach is based on device/circuit/architecture-level co-designs by targeting an emerging device called the single-flux quantum (SFQ). We have successfully demonstrated several outstanding physical designs supporting over 30 GHz. This paper summarizes our research outcomes and discusses the future direction of next-generation computer system architecture.
超导体处理器架构
简介:摩尔定律,芯片中晶体管的数量每两年翻一番,对计算机系统架构的发展做出了贡献。这种硬件实现的增长为软件开发人员提供了许多优化机会。不幸的是,我们不能再期待晶体管持续缩小;也就是说,摩尔定律的终结即将到来。尽管器件和制造技术不断进步,但一些研究人员预测,由于物理或经济原因,晶体管的缩小可能会在2030年至2035年左右停止。这项研究的目标是打开后cmos超高性能、低功耗计算的大门。我们的方法是基于器件/电路/架构级协同设计,目标是一种称为单通量量子(SFQ)的新兴器件。我们已经成功地展示了几种支持超过30 GHz的杰出物理设计。本文总结了我们的研究成果,并讨论了下一代计算机系统体系结构的未来发展方向。
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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