Design of a Single-Ended-Write Schmitt-Trigger Based 10T SRAM Cell

Abstract

Technology scaling is done in order to accommodate more and more transistors in today’s high performance VLSI circuits. These high-performance digital circuits demand large capacity of memory to accomplish faithful operations. However, at scaled technology, SRAM-cell stability is a major issue of concern. Also, increased integration density of these VLSI circuits causes increased power consumption. Leakage power in today’s VLSI circuits has become comparable to dynamic power consumption which also needs to be addressed. In this work, a Schmitt-trigger (ST) based 10T SRAM cell with single-ended-writing and differentially-read feature is proposed. The proposed cell offers enhanced stability and dissipates lower leakage power. Due to separate ports for writing and reading in the proposed cell, the conflict design requirement (which is a condition in conventional 6T cell) is eliminated. Schmitt-trigger based inverters in the proposed cell causes increased threshold voltage of the inverters resulting in enhanced cell stability during read operation. Simulation is carried out on TSPICE using a 65nm Predictive Technology Model (PTM). Results show that the proposed 10T cell provides a 1.7x larger Read static noise margin (RSNM) than the conventional 6T cell. Proposed 10T cell provides Write static noise margin (WSNM) of 155mV during write ‘0’ while 150mV during write ‘1’ operation, respectively, at 0.4V. At a supply voltage of 0.4V, the proposed 10T cell consumes 0.71x lesser static power as compared to that of a conventional 6T cell. However, proposed cell uses more transistors (10 transistors) as compared to that of the conventional 6T cell, therefore, our cell occupies large chip-area as compared to the conventional 6T cell.