An assertion based technique for transistor level dynamic power estimation

Author

Venkatesan, R. ; Bhaskar, S.

fYear

2000

fDate

2000

Firstpage

34

Lastpage

37

Abstract

With increasing complexity of submicron designs, transistor level power estimations and analyses have become a necessity. Power conscious synthesis and optimizations are critical aspect of design flow These require a fast approach to estimate average power and predict the upper bound. A novel assertion based approach for predicting worst dynamic power dissipation is presented here. This technique models all signal correlations within the design. It maximizes loading conditions using assertions to predict maximum power. An Elmore model is used for calculating delay-based power estimates. The technique allows for quick prediction of the power dissipated in the design without loss of much accuracy. It does not need any elaborate circuit simulation iterations. The input pattern dependence is eliminated using the Monte-Carlo approach

Keywords

Monte Carlo methods; VLSI; circuit CAD; circuit analysis computing; delay estimation; integrated circuit design; low-power electronics; Elmore model; Monte-Carlo approach; assertion based technique; delay-based power estimates; loading conditions; signal correlations; submicron designs; transistor level dynamic power estimation; worst dynamic power dissipation; Circuit simulation; Delay estimation; Design optimization; Packaging; Power dissipation; Signal design; Signal synthesis; Transistors; Upper bound; Voltage;

fLanguage

English

Publisher

ieee

Conference_Titel

VLSI Design, 2000. Thirteenth International Conference on

Conference_Location

Calcutta

ISSN

1063-9667

Print_ISBN

0-7695-0487-6

Type

conf

DOI

10.1109/ICVD.2000.812581

Filename

812581