Towards Area Efficient Logic Circuit: Exploring Potential of Reconfigurable Gate by Generic Exact Synthesis

IEEE Open Journal of the Computer Society Pub Date : 2023-03-06 DOI:10.1109/OJCS.2023.3247752

Liuting Shang;Azad Naeemi;Chenyun Pan

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Abstract

In this article, we propose a generic design methodology to achieve area-efficient reconfigurable logic circuits by using exact synthesis based on Boolean satisfiability (SAT) solver. The proposed methodology better leverages the high representation ability of emerging reconfigurable logic gates (RLGs) to achieve reconfigurable circuits with fewer gates. In addition, we propose a fence-based acceleration method to provide >10× speed up for the synthesis without an observable loss of optimality. Furthermore, four sets of RLGs are developed based on a recently proposed valley-spin device as a case study to demonstrate the advantage of the proposed circuit. Simulations have been performed to analyze the impact of the fence searching algorithm and combination of operators. Based on disjoint-support decomposable (DSD) benchmarks, up to 38% and 73% reductions are observed in the area and energy-delay-area product (EDAP), respectively, compared to CMOS counterparts. Compared to the two existing synthesis methods, the proposed scheme provides 40% and 26.3% reduction in EDAP based on MCNC benchmark.

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面向区域有效逻辑电路：用广义精确综合法探索可重构门的潜力

在本文中，我们提出了一种通用的设计方法，通过使用基于布尔可满足性（SAT）求解器的精确合成来实现面积有效的可重构逻辑电路。所提出的方法更好地利用了新兴的可重构逻辑门（RLG）的高表示能力，以实现具有较少门的可重构电路。此外，我们提出了一种基于栅栏的加速方法，在没有可观察到的最优性损失的情况下，为合成提供>10倍的加速。此外，以最近提出的谷自旋器件为例，开发了四组RLG，以证明所提出电路的优势。仿真分析了栅栏搜索算法和算子组合的影响。基于不相交支持可分解（DSD）基准，与CMOS对应产品相比，面积和能量延迟面积积（EDAP）分别减少了38%和73%。与现有的两种合成方法相比，基于MCNC基准，该方案的EDAP降低了40%和26.3%。

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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来源期刊

IEEE Open Journal of the Computer Society

CiteScore

12.60

自引率

0.00%

发文量