TY - CHAP
T1 - Multi-level wordline driver for low power SRAMs in nano-scale CMOS technology
AU - Moradi, Farshad
AU - Wisland, D.
AU - Panagopoulos, G.
AU - Roy, Kaushik
AU - Karakonstantis, G.
AU - Mahmoodi, H.
AU - Madsen, Jens Kargaard
PY - 2011/1/1
Y1 - 2011/1/1
N2 - In this paper, a multi-level wordline driver scheme is presented to improve SRAM read and write stability while lowering power consumption during hold operation. The proposed circuit applies a shaped wordline voltage pulse during read mode and a boosted wordline pulse during write mode. During read, the applied shaped pulse is tuned at nominal voltage for short period of time, whereas for the remaining access time, the wordline voltage is reduced to a lower level. This pulse results in improved read noise margin without any degradation in access time which is explained by examining the dynamic and nonlinear behavior of the SRAM cell. Furthermore, during hold mode, the wordline voltage starts from a negative value and reaches zero voltage, resulting in a lower leakage current compared to conventional SRAM. Our simulations using TSMC 65nm process show that the proposed wordline driver results in 2X improvement in static read noise margin while the write margin is improved by 3X. In addition, the total leakage of the proposed SRAM is reduced by 10% while the total power is improved by 12% in the worst case scenario of a single SRAM cell. The total area penalty is 10% for a 128Kb standard SRAM array.
AB - In this paper, a multi-level wordline driver scheme is presented to improve SRAM read and write stability while lowering power consumption during hold operation. The proposed circuit applies a shaped wordline voltage pulse during read mode and a boosted wordline pulse during write mode. During read, the applied shaped pulse is tuned at nominal voltage for short period of time, whereas for the remaining access time, the wordline voltage is reduced to a lower level. This pulse results in improved read noise margin without any degradation in access time which is explained by examining the dynamic and nonlinear behavior of the SRAM cell. Furthermore, during hold mode, the wordline voltage starts from a negative value and reaches zero voltage, resulting in a lower leakage current compared to conventional SRAM. Our simulations using TSMC 65nm process show that the proposed wordline driver results in 2X improvement in static read noise margin while the write margin is improved by 3X. In addition, the total leakage of the proposed SRAM is reduced by 10% while the total power is improved by 12% in the worst case scenario of a single SRAM cell. The total area penalty is 10% for a 128Kb standard SRAM array.
UR - http://www.scopus.com/inward/record.url?scp=83455210200&partnerID=8YFLogxK
U2 - 10.1109/ICCD.2011.6081419
DO - 10.1109/ICCD.2011.6081419
M3 - Book chapter
AN - SCOPUS:83455210200
SP - 326
EP - 331
BT - Proceedings - IEEE International Conference on Computer Design: VLSI in Computers and Processors
ER -