Thermal aware design and comparative analysis of a high performance 64-bit adder in FD-SOI and bulk CMOS technologies

Yusuf Leblebici
2017
Journal paper

Abstract

Thermal behaviours of high-performance digital circuits in bulk CMOS and FDSOI technologies are compared on a 64-bit Kogge-Stone adder designed in 40nm CMOS node. Temperature profiles of the adder in bulk and FDSOI are extracted with thermal simulations and hotspot locations are studied. The influence of local power density on peak temperature is examined. It is shown that high power density devices have significant influence on peak temperature in FDSOI. It is found that some group of devices that perform the same function are the most prominent heat generators. A modification on the design of these devices is proposed which decreases the hotspot temperatures significantly.

Official source

https://infoscience.epfl.ch/record/229291?ln=en

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Ontological neighbourhood

Computer engineering

Hardware engineering: Microprocessors

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