Title :
Cache leakage power analysis in embedded applications
Author :
Kudithipudi, D. ; Petko, S. ; John, E.
Author_Institution :
Dept. of Electr. Eng., Texas Univ., San Antonio, TX, USA
Abstract :
Power consumption in state-of-the-art embedded systems is determined to a large extent by on-chip caches. In these systems, technology scaling has resulted in an increase of subthreshold and gate leakage currents, which contribute significantly to the total cache power consumption. This underlines a need to analyze leakage power consumption and control techniques at every level of system design in embedded applications. In this paper, we have studied three individual leakage control techniques using Hotleakage as stated in ITRS (2001), applied at architectural level over a range of smaller technology sizes including 70nm. Specifically, evaluation of the effects of varying LI cache sizes (with the size of the other cache constant) demonstrated that the leakage power is directly proportional to the size of the LI cache. With increasing L2 cache sizes the leakage power increased almost to -50° of the total L2-cache power consumption for 70nm technology.
Keywords :
cache storage; circuit analysis computing; embedded systems; leakage currents; microprocessor chips; power control; 70 nm; 70nm technology; architectural level; cache constant; cache leakage power; cache power consumption; cache sizes; control techniques; embedded applications; gate leakage currents; hot leakage; leakage control; on-chip caches; smaller technology sizes; state-of-the-art embedded systems; subthreshold leakage currents; system design; technology scaling; Circuits; Control systems; Embedded system; Energy consumption; Equations; Gate leakage; Leakage current; Size control; System-on-a-chip; Threshold voltage;
Conference_Titel :
Circuits and Systems, 2004. MWSCAS '04. The 2004 47th Midwest Symposium on
Print_ISBN :
0-7803-8346-X
DOI :
10.1109/MWSCAS.2004.1354209
