Title :
Data-Width-Driven Power Gating of Integer Arithmetic Circuits
Author :
Hoang, Tung Thanh ; Larsson-Edefors, Per
Author_Institution :
Dept. of Comput. Sci. & Eng., Chalmers Univ. of Technol., Gothenburg, Sweden
Abstract :
When performing narrow-width computations, power gating of unused arithmetic circuit portions can significantly reduce leakage power. We deploy coarse-grain power gating in 32-bit integer arithmetic circuits that frequently will operate on narrow-width data. Our contributions include a design framework that automatically implements coarse-grain power-gated arithmetic circuits considering a narrow-width input data mode, and an analysis of the impact of circuit architecture on the efficiency of this data-width-driven power gating scheme. As an example, with a performance penalty of 6.7%, coarse-grain power gating of a 45-nm 32-bit multiplier is demonstrated to yield an 11.6× static leakage energy reduction per 8×8-bit operation.
Keywords :
digital arithmetic; integrated circuit design; circuit architecture; coarse-grain power gating; coarse-grain power-gated arithmetic circuit; data-width-driven power gating; design framework; integer arithmetic circuit; leakage power reduction; narrow-width computation; narrow-width input data mode; size 45 nm; static leakage energy reduction; word length 32 bit; Adders; Computer architecture; Logic gates; Power dissipation; Switches; Switching circuits; Timing; adders; leakage power; multipliers; narrow datawidth; power gating; power switch;
Conference_Titel :
VLSI (ISVLSI), 2012 IEEE Computer Society Annual Symposium on
Conference_Location :
Amherst, MA
Print_ISBN :
978-1-4673-2234-8
DOI :
10.1109/ISVLSI.2012.59
