Title :
Gated-Vdd: a circuit technique to reduce leakage in deep-submicron cache memories
Author :
Powell, Michael ; Yang, Se-Hyun ; Falsafi, Babak ; Roy, Kaushik ; Vijaykumar, T.N.
Author_Institution :
Sch. of Electr. & Comput. Eng., Purdue Univ., West Lafayette, IN, USA
Abstract :
Deep-submicron CMOS designs have resulted in large leakage energy dissipation in microprocessors. While SRAM cells in on-chip cache memories always contribute to this leakage, there is a large variability in active cell usage both within and across applications. This paper explores an integrated architectural and circuit-level approach to reducing leakage energy dissipation in instruction caches. We propose, gated-Vdd, a circuit-level technique to gate the supply voltage and reduce leakage in unused SRAM cells. Our results indicate that gated-Vdd together with a novel resizable cache architecture reduces energy-delay by 62% with minimal impact on performance.
Keywords :
CMOS memory circuits; VLSI; cache storage; leakage currents; low-power electronics; microprocessor chips; random-access storage; SRAM cells; deep-submicron CMOS designs; deep-submicron cache memories; gated-Vdd circuit-level technique; instruction caches; integrated architectural/circuit-level approach; leakage energy dissipation; leakage reduction; microprocessors; onchip cache memories; resizable cache architecture; supply voltage gating; Cache memory; Circuits; Cooling; Costs; Energy dissipation; Microprocessors; Permission; Power system reliability; Random access memory; Threshold voltage;
Conference_Titel :
Low Power Electronics and Design, 2000. ISLPED '00. Proceedings of the 2000 International Symposium on
Print_ISBN :
1-58113-190-9
DOI :
10.1109/LPE.2000.155259
