超低电压应用的过程变化容忍SRAM阵列

2008 45th ACM/IEEE Design Automation Conference Pub Date : 2008-06-08 DOI:10.1145/1391469.1391498

J. Kulkarni, Keejong Kim, S. P. Park, K. Roy

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引用次数: 74

摘要

在这项工作中，我们提出了一种基于施密特触发器(ST)的差分传感SRAM位单元，可以在超低电源电压下工作。提出的施密特触发器SRAM单元解决了传统6T单元的读与写操作的基本冲突设计要求。与标准6T电池相比，施密特触发操作提供了更好的读取稳定性和更好的写入能力。所提出的ST bitcell集成了内置的反馈机制，实现了对工艺变化的容忍度——这是未来纳米级技术节点所必须的。对10个采用130纳米技术制造的测试芯片的测量表明，与传统的6T电池相比，所提出的Schmitt Trigger位电池的读取静态噪声边界(SNM)提高了58%，写入触发点提高了2倍，读取Vmin降低了120 mV。ST SRAM阵列在150mV电源电压下工作。

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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Process variation tolerant SRAM array for ultra low voltage applications

In this work, we propose a Schmitt Trigger (ST) based differential sensing SRAM bitcell that can operate at ultra-low supply voltage. The proposed Schmitt Trigger SRAM cell addresses the fundamental conflicting design requirement of read versus write operation of a conventional 6T cell. Schmitt Trigger operation gives better read-stability and as well as better write- ability compared to the standard 6T cell. The proposed ST bitcell incorporates a built-in feedback mechanism, achieving process variation tolerance -- a must for future nano-scaled technology nodes. Measurements on 10 test-chips fabricated in 130 nm technology show that the proposed Schmitt Trigger bitcell gives 58% higher read Static Noise Margin (SNM), 2X higher write- trip-point and 120 mV lower read Vmin compared to the conventional 6T cell. The ST SRAM array is operational at 150mV of supply voltage.

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2008 45th ACM/IEEE Design Automation Conference

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