Algebraic and Boolean Optimization Methods for AQFP Superconducting Circuits

2021 26th Asia and South Pacific Design Automation Conference (ASP-DAC) Pub Date : 2021-01-18 DOI:10.1145/3394885.3431606

Eleonora Testa, Siang-Yun Lee, Heinz Riener, G. Micheli

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引用次数: 17

Abstract

Adiabatic quantum-flux-parametron (AQFP) circuits are a family of superconducting electronic (SCE) circuits that have recently gained growing interest due to their low-energy consumption, and may serve as alternative technology to overcome the down-scaling limitations of CMOS. AQFP logic design differs from classic digital design because logic cells are natively abstracted by the majority function, require data and clocking in specific timing windows, and have fan-out limitations. We describe here a novel majority-based logic synthesis flow addressing AQFP technology. In particular, we present both algebraic and Boolean methods over majority-inverter graphs (MIGs) aiming at optimizing size and depth of logic circuits. The technology limitations and constraints of the AQFP technology (e.g., path balancing and maximum fanout) are considered during optimization. The experimental results show that our flow reduces both size and depth of MIGs, while meeting the constraint of the AQFP technology. Further, we show an improvement for both area and delay when the MIGs are mapped into the AQFP technology.

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AQFP超导电路的代数和布尔优化方法

绝热量子通量参数电路(AQFP)是一类超导电子(SCE)电路，近年来由于其低能耗而受到越来越多的关注，并且可以作为克服CMOS缩小尺寸限制的替代技术。AQFP逻辑设计不同于经典的数字设计，因为逻辑单元是由大多数功能抽象出来的，需要特定时间窗口的数据和时钟，并且有扇出限制。我们在这里描述了一种新的基于多数的逻辑合成流程，解决了AQFP技术。特别是，我们在多数逆变器图(MIGs)上提出了代数和布尔方法，旨在优化逻辑电路的大小和深度。在优化过程中考虑了AQFP技术的技术限制和约束(如路径平衡和最大扇出)。实验结果表明，该流在满足AQFP技术约束的前提下，减小了mig的尺寸和深度。此外，我们还展示了将migg映射到AQFP技术时对面积和延迟的改进。

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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2021 26th Asia and South Pacific Design Automation Conference (ASP-DAC)

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