The move toward smarter, lighter and more powerful electronics, computers and smartphones depends on whether transistor circuits, the building blocks of such devices, can process large amounts of information. As these circuits get faster and smaller, the number of errors they generate — arising from heat dissipation, noise and structural disorder —in the physical information they process increases, which can impede development.
Experts have debated which of two error-suppressing processes is more efficient and efficacious as these circuits are reduced to the nanoscale: (1) physical fault-tolerance, in which the device is scaled down in size (and number of electrons) only to the point at which it can still prevent the generation of logical errors, or (2) architectural fault-tolerance, in which the device is continuously scaled down and robust algorithms are used to correct the errors it generates.
In a new study, Vwani Roychowdhury, professor of electrical engineering at the UCLA Henry Samueli School of Engineering and Applied Science and a member of the California NanoSystems Institute at UCLA, and Thomas Szkopek, professor of electrical and computer engineering at McGill University, and colleagues quantified for the first time these error-suppressing processes for model nanoelectronic systems and estimated the minimum number of electrons necessary for reliable circuit logic. They found that physical fault-tolerance in transistor circuits suppresses the error rate per electron exponentially, while even the most efficient architectural fault-tolerance system only suppresses the error rate subexponentially. They conclude that physical fault-tolerance error prevention is better than architectural fault tolerance error correction.
The study contributes a fundamental insight into the reliability of nanoscale transistor device technologies and scaling and may impose a minimum limit on the size of devices. The findings are of immediate relevance to researchers working in transistor-scaling, through to scientists developing new device concepts.
Authors of the research include Thomas Szkopek, Vwani P. Roychowdhury, Dimitri A. Antoniadis and John N. Damoulakis.
This work was funded in part by grants from the National Science Foundation, and by the Defense Advanced Research Projects Agency.
The research was recently published in the peer-reviewed Physical Review Letters and is available online at: .