A Monolithic-3D SRAM Design with Enhanced Robustness and In-Memory Computation Support

Proceedings of the 2007 international symposium on Low power electronics and design (ISLPED '07) Pub Date : 2018-07-23 DOI:10.1145/3218603.3218645

S. Srinivasa, A. Ramanathan, Xueqing Li, Wei-Hao Chen, F. Hsueh, Chih-Chao Yang, C. Shen, J. Shieh, S. Gupta, Meng-Fan Chang, Swaroop Ghosh, J. Sampson, N. Vijaykrishnan

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引用次数: 19

Abstract

We present a novel 3D-SRAM cell using a Monolithic 3D integration (M3D-IC) technology for realizing both robustness and In-memory Boolean logic compute support. The proposed two-layer design makes use of additional transistors over the SRAM layer to enable assist techniques as well as provide logic functions (such as AND/NAND, OR/NOR, XNOR/XOR) without degrading cell density. Through analysis, we provide insights into the benefits provided by three memory assist and two logic modes and evaluate the energy efficiency of our proposed design. Assist techniques improve SRAM read stability by 2.2x and increase the write margin by 17.6%, while staying within the SRAM footprint. By virtue of increased robustness, the cell enables seamless operation at lower supply voltages and thereby ensures energy efficiency. Energy Delay Product (EDP) reduces by 1.6x over standard 6T SRAM with a faster data access. Transistor placement and their biasing technique in layer-2 enables In-memory bitwise Boolean computation. When computing bulk In-memory operations, 6.5x energy savings is achieved as compared to computing outside the memory system.

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具有增强鲁棒性和内存计算支持的单片三维SRAM设计

我们提出了一种新的3D- sram单元，使用单片3D集成(M3D-IC)技术实现鲁棒性和内存布尔逻辑计算支持。提出的两层设计利用SRAM层上的额外晶体管来实现辅助技术以及提供逻辑功能(如AND/NAND, OR/NOR, XNOR/XOR)，而不会降低单元密度。通过分析，我们深入了解了三种内存辅助和两种逻辑模式所提供的好处，并评估了我们提出的设计的能源效率。辅助技术将SRAM的读取稳定性提高了2.2倍，并将写入裕量提高了17.6%，同时保持在SRAM的占用范围内。凭借增强的稳健性，电池可以在较低的电源电压下无缝运行，从而确保能源效率。能量延迟产品(EDP)比标准6T SRAM减少1.6倍，具有更快的数据访问。晶体管的放置及其在第二层的偏置技术使内存中的位布尔计算成为可能。当计算内存中的批量操作时，与在内存系统外计算相比，可以节省6.5倍的能源。

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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Proceedings of the 2007 international symposium on Low power electronics and design (ISLPED '07)

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