Process variation tolerant SRAM array for ultra low voltage applications

Author

Kulkarni, Jaydeep P. ; Kim, Keejong ; Park, Sang Phill ; Roy, Kaushik

Author_Institution

Sch. of Electr. & Comput. Eng., Purdue Univ., West Lafayette, IN

fYear

2008

fDate

8-13 June 2008

Firstpage

108

Lastpage

113

Abstract

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 V_min compared to the conventional 6T cell. The ST SRAM array is operational at 150mV of supply voltage.

Keywords

SRAM chips; circuit feedback; integrated circuit noise; low-power electronics; trigger circuits; Schmitt trigger operation; built-in feedback; differential sensing SRAM bitcell; read static noise margin; ultra-low supply voltage; write-trip-point; Application software; Dynamic voltage scaling; Feedback; Low voltage; Power dissipation; Random access memory; Robustness; Testing; Threshold voltage; Trigger circuits; Low voltage/sub-threshold SRAM; Process Tolerance; Schmitt Trigger SRAM;

fLanguage

English

Publisher

ieee

Conference_Titel

Design Automation Conference, 2008. DAC 2008. 45th ACM/IEEE

Conference_Location

Anaheim, CA

ISSN

0738-100X

Print_ISBN

978-1-60558-115-6

Type

conf

Filename

4555791