TOWARDS TEMPERATURE-INSENSITIVE NANOSCALE CMOS CIRCUITS WITH ADAPTIVELY REGULATED VOLTAGE POWER SUPPLIES
Ming Zhu1, Yingtao Jiang1, Mei Yang1, Xiaohang Wang2
1Department of Electrical and Computer Engineering
University of Nevada Las Vegas, Las Vegas, NVUSA 89154
2School of Software, South China University of Technology, Guangzhou, China
In this paper, we show that the temperature-induced performance drop seen in nanoscale CMOS circuits can be tackled by powering the circuits with adaptively regulated voltage power supplies. Essentially, when temperature rises, the supply voltage will be bumped up to offset otherwise performance degradation. To avoid thermal over-drift as chip temperature exceeds its operation range, a voltage limiter is integrated into the proposed power supply to cap the supply voltage. Using this proposed adaptive voltage source to power individual CMOS logic gates and/or subsystems will free the chips from using expensive high-precision temperature sensors for thermal management and performance tuning. Experiments on various benchmark circuits, which are implemented with a 45nm CMOS technology, have confirmed that the circuit delay variation can be reduced to 15%~30% over a wide temperature range (0℃ to 90℃), a sharp contrast to the large delay variations (50%~75%)observed in most IC designs where a constant power supply is employed.
KEYWORDS
High performance VLSI circuits; temperature-insensitive; voltage control; power supply.
Original Source URL :
http://aircconline.com/vlsics/V8N3/8317vlsi01.pdf
For More Details :
http://airccse.org/journal/vlsi/vlsics.html
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