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 writeability 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 130nm technology show that the proposed Schmitt Trigger bitcell gives 58% higher read Static Noise Margin (SNM), 2X higher writetrip-point and 120mV lower read V_min compared to the conventional 6T cell. The ST SRAM array is operational at 150mV of supply voltage.

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	1	Hendrawan Soeleman , Kaushik Roy, Ultra-low power digital subthreshold logic circuits, Proceedings of the 1999 international symposium on Low power electronics and design, p.94-96, August 16-17, 1999, San Diego, California, United States  [doi>10.1145/313817.313874]
	2	Y. Nakagome , M. Horiguchi , T. Kawahara , K. Itoh, Review and future prospects of low-voltage RAM circuits, IBM Journal of Research and Development, v.47 n.5-6, p.525-552, September 2003
	3	A. Bhavnagarwala, X. Tang, and J. Meindl; "The impact of intrinsic device fluctuations on CMOS SRAM cell stability," IEEE Journal of Solid State Circuits; vol. 36, pp. 658--665, April 2001
	4	S. Mukhopadhyay, H. Mahmoodi and K. Roy; "Modeling of Failure Probability and Statistical Design of SRAM Array for Yield Enhancement in Nanoscaled CMOS," IEEE Transactions on Computer Aided Design, pp 1859--1880, December 2005
	5	Arijit Raychowdhury , Saibal Mukhopadhyay , Kaushik Roy, A Feasibility Study of Subthreshold SRAM Across Technology Generations, Proceedings of the 2005 International Conference on Computer Design, p.417-424, October 02-05, 2005  [doi>10.1109/ICCD.2005.7]
	6	L. Chang, D. Fried, J. Hergenrother, J. Sleight, R. Dennard, R. R. Montoye, L. Sekaric, S. McNab, W. Topol, C. Adams, K. Guarini and W. Haensch; "Stable SRAM Cell Design for the 32 nm Node and Beyond," Symposium on VLSI Technology, pp.128--129, 2005
	7	B. H. Calhoun and A. P. Chandrakasan; "A 256kb Subthreshold SRAM in 65nm CMOS," Proc. of International Solid State Circuits Conference, pp. 628--629, February 2006
	8	N. Verma and A. P. Chandrakasan; "65nm 8T Sub-Vt SRAM Employing Sense-Amplifier Redundancy" Proc. of International Solid State Circuits Conference, pp. 328--329, February 2007
	9	T-H. Kim, J. Liu, J. Keane and C-H. Kim; "A High-Density Subthreshold SRAM with Data-Independent Bitline Leakage and Virtual Ground Replica Scheme" Proc. of International Solid State Circuits Conference, pp. 330--331, February 2007
	10	B. Zhai, D. Blaauw, D. Sylvester, S. Hanson; "A Sub-200mV 6T SRAM in 0.13μm CMOS" Proc. of International Solid State Circuits Conference, pp. 332--333, February 2007
	11	I. Chang, J-J. Kim, S. Park and K. Roy; "A 32kb 10T Subthreshold SRAM Array with Bit-Interleaving and Differential Read Scheme in 90nm CMOS" Proc. of International Solid State Circuits Conference, pp. 628--629, February 2008
	12	B. H Calhoun and A. P. Chandrakasan; "Static noise margin variation for sub-threshold SRAM in 65-nm CMOS," IEEE Journal of Solid-State Circuits, vol. 41, pp. 1673--1679, July 2006
	13	J. P. Kulkarni, K. Kim and K. Roy, "A 160mV Robust Schmitt Trigger based Subthreshold SRAM" IEEE Journal of Solid State Circuits, vol. 42, no. 10, pp. 2303--2313, October 2007
	14	Anne Meixner , Jash Banik, Weak Write Test Mode: An SRAM Cell Stability Design for Test Technique, Proceedings of the IEEE International Test Conference, p.1043-1052, November 03-05, 1997