Logic transformation for low-power synthesis

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Logic transformation for low-power synthesis

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ACM Transactions on Design Automation of Electronic Systems (TODAES) archive
Volume 7 , Issue 2 (April 2002) table of contents

Pages: 265 - 283

Year of Publication: 2002

ISSN:1084-4309

Authors

Ki-Wook Kim	Pluris, Inc., Cupertino, CA
Taewhan Kim	Korea Advanced Institute of Science and Technology, Taejeon, Korea
Ting-Ting Hwang	National Tsing Hua University, Hsin-Chu, Taiwan
Sung-Mo Kang	University of California at Santa Cruz
C. L. Liu	National Tsing Hua University, Hsin-Chu, Taiwan

Publisher

ACM New York, NY, USA

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ABSTRACT

In this article we present a new approach to the problem of local logic transformation for reducing power dissipation in logic circuits. The proposed approach overcomes one of the critical limitations common to the previous approaches of local logic transformations for low power, namely, a sequential greedy transformation that identifies signals with high switching activities and then resynthesizes the signals one by one. Instead, we identify a set of signal lines as a group for logic transformation, and determine an order of transformation of the signals with the maximum reduction of power dissipation in the circuit. As a practically feasible solution to this problem, we develop a power model called a finite state input transition (FIT) model, which allows the efficient measurement of the change of power dissipation of the circuit for every possible sequence of logic transformations among the signal lines. Experimental results show that the proposed approach performs an extensive local logic transformation, reducing power consumption by 33% on average without any increase of circuit delay.

REFERENCES

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