Title :
Ultralow-Voltage Process-Variation-Tolerant Schmitt-Trigger-Based SRAM Design
Author :
Kulkarni, Jaydeep P. ; Roy, Kaushik
Author_Institution :
Circuit Res. Lab., Intel Corp., Hillsboro, OR, USA
Abstract :
We analyze Schmitt-Trigger (ST)-based differential-sensing static random access memory (SRAM) bitcells for ultralow-voltage operation. The ST-based SRAM bitcells address the fundamental conflicting design requirement of the read versus write operation of a conventional 6T bitcell. The ST operation gives better read-stability as well as better write-ability compared to the standard 6T bitcell. The proposed ST bitcells incorporate a built-in feedback mechanism, achieving process variation tolerance - a must for future nano-scaled technology nodes. A detailed comparison of different bitcells under iso-area condition shows that the ST-2 bitcell can operate at lower supply voltages. Measurement results on ten test-chips fabricated in 130-nm CMOS technology show that the proposed ST-2 bitcell gives 1.6× higher read static noise margin, 2× higher write-trip-point and 120-mV lower read-Vmin compared to the iso-area 6T bitcell.
Keywords :
CMOS memory circuits; SRAM chips; trigger circuits; CMOS technology; ST-2 bitcell; Schmitt-trigger-based differential-sensing static random access memory bitcell; built-in feedback mechanism; isoarea 6T bitcell; nanoscaled technology node; process variation tolerance; read-stability; size 130 nm; supply voltage; test-chips fabrication; ultralow-voltage operation; ultralow-voltage process-variation-tolerant Schmitt-trigger-based SRAM Design; write-ability; Arrays; Inverters; Logic gates; Noise; Random access memory; Sensors; Transistors; ${rm V}_{min}$ ; Low-voltage SRAM; Schmitt-Trigger (ST); process tolerance;
Journal_Title :
Very Large Scale Integration (VLSI) Systems, IEEE Transactions on
DOI :
10.1109/TVLSI.2010.2100834
