[[abstract]]© 2006 Institute of Electrical and Electronics Engineers-This paper highlights the cell current characterization of a low leakage 6T SRAM by adjusting the threshold voltages of the transistors in the memory array to reduce the standby power. Experiments using a 0.25 /spl mu/m 2.5V standard CMOS process with and without the additional threshold voltage adjustment implant on a 1Mb test chip demonstrate the effectiveness. A substantial standby power reduction by an order of magnitude is achievable. However, it incurs a wider cell current variation, which is pronounced only at a lower supply voltage. As the supply voltage decreases, the percent deviation from the average value increases. This can be modeled by a simple power-law rel...
Leakage power dissipation of on-chip static random access memories (SRAMs) constitutes a significant...
Abstract—Semiconductor manufacturing process scaling increases leakage and transistor variations, bo...
The requirement for smaller, lighter yet increasingly powerful electronic devices has never been gre...
Aggressive CMOS scaling results in lower threshold voltage and thin oxide thickness for transistors\...
Abstract—Various aspects of ultra-low leakage static random-access memories (SRAM) cell design are c...
Suppressing the leakage current in memories is critical in low-power design. By reducing the standby...
The performance of the cell deteriorates, when static random access memory (SRAM) cell is operated b...
Modern CMOS processes in the Deep Submicron regime are restricted to supply voltages below 2 volts a...
In this paper, two static random access memory (SRAM) cells that reduce the static power dissipation...
CMOS devices have been scaled down aggressively in last few decades resulting in higher integration ...
Aggressive CMOS scaling results in low threshold voltage and thin oxide thickness for transistors ma...
Scaling of CMOS technology has enabled a phenomenal growth in computing capability throughout the la...
Abstract — Aggressive CMOS scaling results in low threshold voltage and thin oxide thickness for tra...
The paper presents a variability-aware modified 9T SRAM cell. In comparison to 6T SRAM cell the prop...
Due to device and voltage scaling scenarios for present and future deep-submicron CMOS technologies,...
Leakage power dissipation of on-chip static random access memories (SRAMs) constitutes a significant...
Abstract—Semiconductor manufacturing process scaling increases leakage and transistor variations, bo...
The requirement for smaller, lighter yet increasingly powerful electronic devices has never been gre...
Aggressive CMOS scaling results in lower threshold voltage and thin oxide thickness for transistors\...
Abstract—Various aspects of ultra-low leakage static random-access memories (SRAM) cell design are c...
Suppressing the leakage current in memories is critical in low-power design. By reducing the standby...
The performance of the cell deteriorates, when static random access memory (SRAM) cell is operated b...
Modern CMOS processes in the Deep Submicron regime are restricted to supply voltages below 2 volts a...
In this paper, two static random access memory (SRAM) cells that reduce the static power dissipation...
CMOS devices have been scaled down aggressively in last few decades resulting in higher integration ...
Aggressive CMOS scaling results in low threshold voltage and thin oxide thickness for transistors ma...
Scaling of CMOS technology has enabled a phenomenal growth in computing capability throughout the la...
Abstract — Aggressive CMOS scaling results in low threshold voltage and thin oxide thickness for tra...
The paper presents a variability-aware modified 9T SRAM cell. In comparison to 6T SRAM cell the prop...
Due to device and voltage scaling scenarios for present and future deep-submicron CMOS technologies,...
Leakage power dissipation of on-chip static random access memories (SRAMs) constitutes a significant...
Abstract—Semiconductor manufacturing process scaling increases leakage and transistor variations, bo...
The requirement for smaller, lighter yet increasingly powerful electronic devices has never been gre...