SMART: Investigating the Impact of Threshold Voltage Suppression in an In-SRAM Multiplication/Accumulation Accelerator for Accuracy Improvement in 65 nm CMOS Technology

2022 25th Euromicro Conference on Digital System Design (DSD) Pub Date : 2022-08-01 DOI:10.1109/DSD57027.2022.00115

Saeed Seyedfaraji, B. Mesgari, Semeen Rehman

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Abstract

State-of-the-art In-memory processing has recently emerged as the most promising solution to overcome design challenges related to data movement inside current computing systems. One of the approaches to performing In-memory processing is based on the analog behavior of the data stored inside the memory cell. Analog-based approaches proposed various system architectures for that. In this paper, we have investigated the effect of threshold voltage suppression on the access transistors of the In-SRAM multiplication and accumulation (MAC) accelerator to improve and enhance the performance of bit line (bit line bar) discharge rate that will increase the accuracy of MAC operation. We provide a comprehensive analytical analysis followed by circuit implementation, including a Monte-Carlo simulation by a 65nm CMOS technology. We confirmed the efficiency of our method (SMART) for a four-by-four-bit MAC operation. The proposed technique improves the accuracy while consuming 0.683 pJ per computation from a power supply of IV. Our novel technique presents less than 0.009 standard deviations for the worst-case incorrect output scenario.

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SMART:研究阈值电压抑制在sram内倍增/累积加速器中对65nm CMOS技术精度提高的影响

最近，最先进的内存处理成为克服当前计算系统中与数据移动相关的设计挑战的最有希望的解决方案。执行内存处理的方法之一是基于存储在内存单元中的数据的模拟行为。基于模拟的方法为此提出了各种系统架构。在本文中，我们研究了阈值电压抑制对In- sram乘法与积累(MAC)加速器的访问晶体管的影响，以改善和提高位线(位线条)放电率的性能，从而提高MAC操作的准确性。我们提供了一个全面的分析分析，然后是电路实现，包括65nm CMOS技术的蒙特卡罗模拟。我们证实了我们的方法(SMART)对于4 × 4位MAC操作的效率。所提出的技术提高了精度，同时每次计算消耗来自IV电源的0.683 pJ。我们的新技术在最坏情况下的不正确输出场景的标准差小于0.009。

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2022 25th Euromicro Conference on Digital System Design (DSD)

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