Title :
Trading off reliability and power-consumption in ultra-low power systems
Author :
Maheshwari, Atul ; Burleson, Wayne ; Tessier, Russell
Author_Institution :
Dept. of Electr. & Comput. Eng., Massachusetts Univ., Amherst, MA, USA
Abstract :
Critical systems like pace-makers, defibrillators, wearable computers and other electronic gadgets have to be designed not only for reliability but also for ultra-low power consumption due to limited battery life. This paper explores architecture, logic and circuit level approaches to this tradeoff. Fault tolerance techniques at the architecture level can be broadly classified into spatial or temporal redundancy. Using an example of counters (binary and Gray) we show that temporal redundancy is best suited for these ultra-low power and low performance systems as it consumes 30% less power than an area redundant technique. Circuit techniques allow power-reliability tradeoffs of about 50% in each measure. A methodology is developed based on low-level fault simulation using SPICE, which allows detailed circuit models for both power consumption and reliability in current and future CMOS technology.
Keywords :
CMOS integrated circuits; SPICE; counting circuits; fault simulation; fault tolerance; integrated circuit reliability; low-power electronics; redundancy; sensitivity analysis; CMOS technology; Gray counter; SPICE; binary counter; circuit models; critical systems; fault model; fault tolerance techniques; low performance systems; low-level fault simulation; power consumption; power-reliability tradeoffs; reliability; temporal redundancy; ultra-low power systems; Batteries; CMOS technology; Computer architecture; Energy consumption; Fault tolerance; Logic circuits; Power system faults; Power system reliability; Redundancy; Wearable computers;
Conference_Titel :
Quality Electronic Design, 2002. Proceedings. International Symposium on
Print_ISBN :
0-7695-1561-4
DOI :
10.1109/ISQED.2002.996773
