Thermal-aware methodology for repeater insertion in low-power VLSI circuits

Author

Ja Chun Ku ; Ismail, Yousr

Author_Institution

EECS Dept., Northwestern Univ., Evanston, IL, USA

fYear

2007

fDate

27-29 Aug. 2007

Firstpage

86

Lastpage

91

Abstract

In this paper, the impact of thermal effects on low-power repeater insertion methodology is studied. An analytical methodology for thermal-aware repeater insertion that includes the electrothermal coupling between power, delay, and temperature is presented, and simulation results with global interconnect repeaters are discussed for 90nm and 65nm technology. Simulation results show that the proposed thermal-aware methodology can save 17.5% more power consumed by the repeaters compared to a thermal-unaware methodology for a given allowed delay penalty. In addition, the proposed methodology also results in a lower chip temperature, and thus, extra leakage power savings from other logic blocks.

Keywords

VLSI; delays; integrated circuit design; integrated circuit interconnections; low-power electronics; delay penalty; electrothermal coupling; global interconnect repeaters; leakage power savings; low-power VLSI circuits; size 65 nm; size 90 nm; thermal effects; thermal-aware repeater insertion; Analytical models; Circuit simulation; Coupling circuits; Delay; Electrothermal effects; Integrated circuit interconnections; Logic; Repeaters; Temperature; Very large scale integration; low-power design; repeater insertion; temperature-aware design;

fLanguage

English

Publisher

ieee

Conference_Titel

Low Power Electronics and Design (ISLPED), 2007 ACM/IEEE International Symposium on

Conference_Location

Portland, OR

Electronic_ISBN

978-1-59593-709-4

Type

conf

DOI

10.1145/1283780.1283799

Filename

5514252