Using mobilize power management IP for dynamic and static power reduction in SoC at 130 nm

Author

Hillman, Dan

fYear

2005

fDate

7-11 March 2005

Firstpage

240

Abstract

At 130 nm and 90 nm, power consumption (both dynamic and static) has become a barrier in the roadmap for SoC designs targeting battery powered, mobile applications. This paper presents the results of dynamic and static power reduction achieved implementing Tensilica´s 32-bit Xtensa microprocessor core, using Virtual Silicon´s Power Management IP. Independent voltage islands are created using Virtual Silicon´s VIP PowerSaver standard cells by using voltage level shifting cells and voltage isolation cells to implement power islands. The VIP PowerSaver standard cells are characterized at 1.2V, 1.0V and 0.8V, to accommodate voltage scaling. Power islands can also be turned off completely. Designers can significantly lower both the dynamic power and the quiescent or leakage power of their SoC designs, with very little impact on speed or area using Virtual Silicon´s VIP Gate Bias standard cells.

Keywords

industrial property; microprocessor chips; mobile computing; power consumption; system-on-chip; 0.8 V; 1 V; 1.2 V; 130 nm; 32 bit; 90 nm; SoC; Tensilica 32-bit Xtensa microprocessor core; VIP Gate Bias standard cells; VIP PowerSaver standard cells; Virtual Silicon Power Management IP; battery power; dynamic power reduction; leakage power; mobile applications; mobilize power management IP; power consumption; power islands; quiescent power; static power reduction; voltage isolation cells; voltage level shifting cells; voltage scaling; Battery management systems; Clocks; Dynamic voltage scaling; Energy consumption; Energy management; Libraries; Microprocessors; Silicon; Technology management; Universal Serial Bus;

fLanguage

English

Publisher

ieee

Conference_Titel

Design, Automation and Test in Europe, 2005. Proceedings

ISSN

1530-1591

Print_ISBN

0-7695-2288-2

Type

conf

DOI

10.1109/DATE.2005.324

Filename

1395828