Title :
Leakage and leakage sensitivity computation for combinational circuits
Author :
Acar, Emrah ; Devgan, Anirudh ; Rao, Rahul ; Liu, Ying ; Su, Haihua ; Nassif, Sani ; Burns, Jeffrey
Author_Institution :
IBM Res., Austin, TX, USA
Abstract :
Leakage power is emerging as a new critical challenge in the design of high performance integrated circuits. Leakage is increasing dramatically with each technology generation and is expected to dominate system power. This paper describes a static (i.e input independent) technique for efficient and accurate leakage estimation. A probabilistic technique is presented to compute the average leakage of combinational circuits. The proposed technique gives accurate results with an average error of only 2% for the ISCAS benchmarks and accurately predict both subthreshold and gate leakage as well as the leakage sensitivities to process and environmental parameters.
Keywords :
CMOS logic circuits; SPICE; circuit simulation; combinational circuits; integrated circuit design; leakage currents; logic CAD; low-power electronics; probability; sensitivity analysis; ISCAS benchmarks; Iddq analysis; SPICE-like simulator; average leakage; average leakage power estimates; basic logic gate; combinational circuits; environmental parameters; full-chip total leakage power estimation; high performance integrated circuits; leakage sensitivity computation; node occurrence probability; optimization; power estimation; relative error; runtime complexity; state occurrence probability; static analysis technique; subthreshold leakage; total transistor width; transistor stacks; universal expression; Circuit topology; Combinational circuits; Computational modeling; Gate leakage; Integrated circuit technology; Leakage current; Permission; Power generation; State estimation; Threshold voltage;
Conference_Titel :
Low Power Electronics and Design, 2003. ISLPED '03. Proceedings of the 2003 International Symposium on
Print_ISBN :
1-58113-682-X
DOI :
10.1109/LPE.2003.1231842
