Petrol approach to high-level power estimation

R. Peset Llopis; K.G.W. Goossens

Petrol approach to high-level power estimation

R. Peset Llopis
, K.G.W. Goossens

Pre TU & All other research faculty E

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

Abstract

High-level power estimation is essential for designing complex low-power ICs. However, the lack of flexibility, or restriction to synthesizable code of previously presented high-level power estimation approaches limits their use. In this paper we present a novel, more general and flexible high-level power estimation approach, that avoids these limitations. Petrol, as we call it, is not limited to specialized application domains, synthesizable VHDL, or data path parts of a design. We show that glitches can be usefully modeled at higher levels of abstraction. The Petrol approach shows good correlation with gate-level power estimates. It is currently used for commercial designs.

Original language	English
Title of host publication	Proceedings of the 1998 International Symposium on Low Power Electronics and Design, 10 August 1998 through 12 August 1998, Monterey, CA, USA
Pages	130-132
Publication status	Published - 1998

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@inproceedings{d9d8c56317444ee198ef1584df7116db,

title = "Petrol approach to high-level power estimation",

abstract = "High-level power estimation is essential for designing complex low-power ICs. However, the lack of flexibility, or restriction to synthesizable code of previously presented high-level power estimation approaches limits their use. In this paper we present a novel, more general and flexible high-level power estimation approach, that avoids these limitations. Petrol, as we call it, is not limited to specialized application domains, synthesizable VHDL, or data path parts of a design. We show that glitches can be usefully modeled at higher levels of abstraction. The Petrol approach shows good correlation with gate-level power estimates. It is currently used for commercial designs.",

author = "\{Peset Llopis\}, R. and K.G.W. Goossens",

year = "1998",

language = "English",

pages = "130--132",

booktitle = "Proceedings of the 1998 International Symposium on Low Power Electronics and Design, 10 August 1998 through 12 August 1998, Monterey, CA, USA",

}

TY - GEN

T1 - Petrol approach to high-level power estimation

AU - Peset Llopis, R.

AU - Goossens, K.G.W.

PY - 1998

Y1 - 1998

N2 - High-level power estimation is essential for designing complex low-power ICs. However, the lack of flexibility, or restriction to synthesizable code of previously presented high-level power estimation approaches limits their use. In this paper we present a novel, more general and flexible high-level power estimation approach, that avoids these limitations. Petrol, as we call it, is not limited to specialized application domains, synthesizable VHDL, or data path parts of a design. We show that glitches can be usefully modeled at higher levels of abstraction. The Petrol approach shows good correlation with gate-level power estimates. It is currently used for commercial designs.

AB - High-level power estimation is essential for designing complex low-power ICs. However, the lack of flexibility, or restriction to synthesizable code of previously presented high-level power estimation approaches limits their use. In this paper we present a novel, more general and flexible high-level power estimation approach, that avoids these limitations. Petrol, as we call it, is not limited to specialized application domains, synthesizable VHDL, or data path parts of a design. We show that glitches can be usefully modeled at higher levels of abstraction. The Petrol approach shows good correlation with gate-level power estimates. It is currently used for commercial designs.

M3 - Conference contribution

SP - 130

EP - 132

BT - Proceedings of the 1998 International Symposium on Low Power Electronics and Design, 10 August 1998 through 12 August 1998, Monterey, CA, USA

ER -

Petrol approach to high-level power estimation

Abstract

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