Tradeoffs between gate oxide leakage and delay for dual T ox circuits

Anup Kumar Sultania; Dennis Sylvester; Sachin S. Sapatnekar

Tradeoffs between gate oxide leakage and delay for dual T _ox circuits

Anup Kumar Sultania, Dennis Sylvester, Sachin S. Sapatnekar

Electrical and Computer Engineering

Research output: Contribution to journal › Conference article › peer-review

37 Scopus citations

Abstract

Gate oxide tunneling current (I _gate) will become the dominant component of leakage in CMOS circuits as the physical oxide thickness (T _ox) goes below 15Å. Increasing the value of T _ox reduces the leakage at the expense of an increase in delay, and a practical tradeoff between delay and leakage can be achieved by assigning one of the two permissible T _ox values to each transistor. In this paper, we propose an algorithm for dual T _ox assignment to optimize the total leakage power under delay constraints, and generate a leakage/delay tradeoff curve. As compared to the case where all transistors are set to low T _ox, our approach achieves an average leakage reduction of 83% under 100nm models.

Original language	English (US)
Pages (from-to)	761-766
Number of pages	6
Journal	Proceedings - Design Automation Conference
State	Published - Sep 20 2004
Event	Proceedings of the 41st Design Automation Conference - San Diego, CA, United States Duration: Jun 7 2004 → Jun 11 2004

Keywords

Dual T Circuits
Leakage power

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abstract = "Gate oxide tunneling current (I gate) will become the dominant component of leakage in CMOS circuits as the physical oxide thickness (T ox) goes below 15{\AA}. Increasing the value of T ox reduces the leakage at the expense of an increase in delay, and a practical tradeoff between delay and leakage can be achieved by assigning one of the two permissible T ox values to each transistor. In this paper, we propose an algorithm for dual T ox assignment to optimize the total leakage power under delay constraints, and generate a leakage/delay tradeoff curve. As compared to the case where all transistors are set to low T ox, our approach achieves an average leakage reduction of 83% under 100nm models.",

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AU - Sultania, Anup Kumar

AU - Sylvester, Dennis

AU - Sapatnekar, Sachin S.

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N2 - Gate oxide tunneling current (I gate) will become the dominant component of leakage in CMOS circuits as the physical oxide thickness (T ox) goes below 15Å. Increasing the value of T ox reduces the leakage at the expense of an increase in delay, and a practical tradeoff between delay and leakage can be achieved by assigning one of the two permissible T ox values to each transistor. In this paper, we propose an algorithm for dual T ox assignment to optimize the total leakage power under delay constraints, and generate a leakage/delay tradeoff curve. As compared to the case where all transistors are set to low T ox, our approach achieves an average leakage reduction of 83% under 100nm models.

AB - Gate oxide tunneling current (I gate) will become the dominant component of leakage in CMOS circuits as the physical oxide thickness (T ox) goes below 15Å. Increasing the value of T ox reduces the leakage at the expense of an increase in delay, and a practical tradeoff between delay and leakage can be achieved by assigning one of the two permissible T ox values to each transistor. In this paper, we propose an algorithm for dual T ox assignment to optimize the total leakage power under delay constraints, and generate a leakage/delay tradeoff curve. As compared to the case where all transistors are set to low T ox, our approach achieves an average leakage reduction of 83% under 100nm models.

KW - Dual T Circuits

KW - Leakage power

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