Title :
Effectiveness of reverse body bias for leakage control in scaled dual Vt CMOS ICs
Author :
Keshavarzi, A. ; Ma, S. ; Narendra, Siva G. ; Bloechel, B. ; Mistry, K. ; Ghani, T. ; Borkar, S. ; De, V.
Author_Institution :
Microprocessor Res. Labs., Intel Corp., Hillsboro, OR, USA
Abstract :
Examines the effectiveness of opportunistic use of reverse body bias (RBB) to reduce leakage power during active operation, burn-in, and standby in 0.18 μm single-Vt and 0.13 μm dual-Vt logic process technologies. Investigates its dependencies on channel length, target Vt, temperature and technology generation. Shows that RBB becomes less effective for leakage reduction at shorter channel lengths and lower Vt at both high and room temperatures, especially when target intrinsic leakage currents are high. RBB effectiveness also diminishes with technology scaling primarily because of worsening short-channel effects (SCE), particularly when target Vt values are low. A model is given that relates different transistor leakage components to full-chip leakage current, and is validated through test-chip measurements across a range of RBB values
Keywords :
CMOS logic circuits; integrated circuit measurement; integrated circuit modelling; integrated circuit reliability; leakage currents; 0.13 micron; 0.18 micron; RBB effectiveness; active operation; burn-in; channel length; full-chip leakage current; intrinsic leakage currents; leakage control; leakage power; leakage reduction; logic process technologies; model; reverse body bias; scaled dual Vt CMOS; short-channel effects; standby; technology scaling; temperature; test-chip measurements; CMOS process; Circuit testing; Current measurement; Leakage current; Logic devices; Microprocessors; Permission; Semiconductor device measurement; Subthreshold current; Temperature dependence;
Conference_Titel :
Low Power Electronics and Design, International Symposium on, 2001.
Conference_Location :
Huntington Beach, CA
Print_ISBN :
1-58113-371-5
DOI :
10.1109/LPE.2001.945402
