Title :
A floating-body dynamic supply boosting technique for low-voltage sram in nanoscale PD/SOI CMOS technologies
Author :
Joshi, Rajan ; Kanj, Rouwaida ; Keunwoo Kim ; Williams, Ross ; Ching-Te Chuang
Author_Institution :
IBM T. J. Watson Res. Center, Yorktown Heights, NY, USA
Abstract :
This paper presents a novel dynamic supply boosting technique for low voltage SRAMs at/beyond 65 nm PD/SOI technologies. For the first time the technique exploits the capacitive coupling effect in a floating-body PD/SOI device to dynamically boost the virtual array supply voltage during Read operation, thus improving the Read performance, Read/half-select stability, and Vmin. This enables significant reduction of the standby cell power and circuit active power in a single supply methodology. The performance and parametric yield improvements in the presence of variability are analyzed/validated using precise and fast Monte Carlo statistical circuit simulations with mixture importance sampling. Fabricated column-based 65nm PD/SOI SRAM circuits are confirmed with simulations and physical analysis and are shown to operate at 0.4 V. to 0.5V.
Keywords :
CMOS digital integrated circuits; SRAM chips; silicon-on-insulator; Monte Carlo statistical circuit simulations; Vmin; capacitive coupling effect; floating-body dynamic supply boosting technique; low-voltage PD-SOI CMOS SRAM; read operation; read-half-select stability; size 65 nm; virtual array supply voltage; voltage 0.4 V to 0.5 V; Analytical models; Boosting; CMOS technology; Circuit simulation; Circuit stability; Coupling circuits; Low voltage; Monte Carlo methods; Performance analysis; Random access memory; SRAM; booster circuit; low power; yield;
Conference_Titel :
Low Power Electronics and Design (ISLPED), 2007 ACM/IEEE International Symposium on
Electronic_ISBN :
978-1-59593-709-4
DOI :
10.1145/1283780.1283784
