Title :
Internal power modelling and minimization in CMOS inverters
Author :
Turgis, S. ; Daga, J.-M. ; Portal, J.M. ; Auvergne, D.
Author_Institution :
Univ. des Sci. et Tech. du Languedoc, Montpellier, France
Abstract :
We present in this paper an alternative for the internal (short-circuit and overshoot) power dissipation estimation of CMOS structures. Using a first order macro-modelling, we consider submicronic additional effects such as: input slow dependency of short-circuit currents and input-to-output coupling. Considering an equivalent capacitance concept we directly compare the different power components. Validations are presented by comparing simulated values (HSPICE level 6, foundry model 0.7 μm) to calculated ones. Application to buffer design enlightens the importance of the internal power component and clearly shows that common sizing alternatives for power and delay minimization can be considered
Keywords :
CMOS logic circuits; SPICE; integrated circuit modelling; logic gates; minimisation of switching nets; short-circuit currents; CMOS inverter; HSPICE simulation; buffer design; equivalent capacitance; foundry model; input-to-output coupling; internal power modelling; macromodel; minimization; overshoot; short-circuit current; Capacitance; Circuit simulation; Design optimization; Inverters; MOSFETs; Minimization; Power dissipation; Semiconductor device modeling; Signal design; Voltage;
Conference_Titel :
European Design and Test Conference, 1997. ED&TC 97. Proceedings
Conference_Location :
Paris
Print_ISBN :
0-8186-7786-4
DOI :
10.1109/EDTC.1997.582423
