Noise abatement is the key problem of small-scaled circuit design. New computational paradigms are needed -- as these circuits shrink, they become very vulnerable to noise and soft errors. In this lecture, we present a probabilistic computation framework for improving the resiliency of logic gates and circuits under random conditions induced by voltage or current fluctuation. Among many probabilistic techniques for modeling such devices, only a few models satisfy the requirements of efficient hardware implementation -- specifically, Boltzman machines and Markov Random Field (MRF) models. These…mehr
Noise abatement is the key problem of small-scaled circuit design. New computational paradigms are needed -- as these circuits shrink, they become very vulnerable to noise and soft errors. In this lecture, we present a probabilistic computation framework for improving the resiliency of logic gates and circuits under random conditions induced by voltage or current fluctuation. Among many probabilistic techniques for modeling such devices, only a few models satisfy the requirements of efficient hardware implementation -- specifically, Boltzman machines and Markov Random Field (MRF) models. These models have similar built-in noise-immunity characteristics based on feedback mechanisms. In probabilistic models, the values 0 and 1 of logic functions are replaced by degrees of beliefs that these values occur. An appropriate metric for degree of belief is probability. We discuss various approaches for noise-resilient logic gate design, and propose a novel design taxonomy based on implementation of the MRF model by a new type of binary decision diagram (BDD), called a cyclic BDD. In this approach, logic gates and circuits are designed using 2-to-1 bi-directional switches. Such circuits are often modeled using Shannon expansions with the corresponding graph-based implementation, BDDs. Simulation experiments are reported to show the noise immunity of the proposed structures. Audiences who may benefit from this lecture include graduate students taking classes on advanced computing device design, and academic and industrial researchers. Table of Contents: Introduction to probabilistic computation models / Nanoscale circuits and fluctuation problems / Estimators and Metrics / MRF Models of Logic Gates / Neuromorphic models / Noise-tolerance via error correcting / Conclusion and future work
S. N. Yanushkevich received M.Sc. (1989) and Ph.D. (1992) degrees in electrical and computer engineering from the State University of Informatics and Radioelectronics, Minsk, Belarus, and she received her Habilitation degree (1999) from the University of Technology,Warsaw, Poland. In 2001, she joined the Department of Electrical and Computer Engineering, University of Calgary, Canada, where she is currently Associate Professor. Dr. Yanushkevich is a Senior Member of the IEEE and a Member of the Institute of Electronics, Information and Communication Engineers (IEICE), Japan. In 2011, she was awarded the Invitation Fellowship by the Japan Society for Promotion of Science ( JSPS) and worked at the Research Center for Integrated Quantum Electronics, Hokkaido University. Dr. Yanushkevich took part in several projects on the development of high-performance parallel computing tools for image processing applications. Her current research interests include nanocomputing in 3D and artificial intelligence in decision making. Dr. Yanushkevich serves as a Guest Editor of several international journals, and she was a general chair and co-chair of about 20 international conferences, symposia, and workshops. Dr. Yanushkevich has published over 200 technical papers and patents, and authored, co-authored, and edited books S. Kasai received B.E., M.E., and Ph.D. degrees in electrical engineering from Hokkaido University, Hokkaido, Japan, in 1992, 1994, and 1997, respectively. He joined Optoelectronics and High Frequency Device Research Laboratories, NEC, Japan, in 1997. In 1999, he moved to the Graduate School of Electronics and Information Engineering, Hokkaido University, as a Research Associate and he has been an Associate Professor since 2001. From 2004, he has been an Associate Professor in Graduate School of Information Science and Technology and Research Center for Integrated Quantum Electronics (RCIQE). From 2007 to 2011, he has also been a researcher of PRESTO, Japan Science and Technology Agency ( JST).His current research interests include III-V compound semiconductor nanodevices and their integrations, and stochastic resonance device. He is a member of IEEE, the Institute of Electronics, Information and Communication Engineers (IEICE), and the Japan Society of Applied Physics ( JSAP G.Tangim is pursuing an M.Sc. in Electrical and Computer Engineering (ECE) in the Department of Electrical and Computer Engineering, University of Calgary. His research interest includes FaultTolerant Nanoarchitectures, VLSI, and Computer Aided Design of Digital logic circuits. Tangim received his B.Sc. in Electrical and Electronics Engineering from Islamic University of Technology (IUT), Bangladesh. He served as a junior lecturer in the School of Engineering and Computer Science (SECS) in Independent University, Bangladesh (IUB) for two years.He is a student member of IEEE A.H.Tran received M.Eng. (2007) and M.Sc. (2011) degrees in electrical and computer engineering from the Schulich School of Engineering, University of Calgary, Calgary, Alberta. His research interests include Stochastic and Probabilistic Logic Computing, Simulation of Logic Computing under extreme noise, and applying Artificial Intelligence in Fault-Tolerant computing.He is planning to pursue his Ph.D. in the near future
Inhaltsangabe
Introduction to probabilistic computation models.- Nanoscale circuits and fluctuation problems.- Estimators and Metrics.- MRF Models of Logic Gates.- Neuromorphic models.- Noise-tolerance via error correcting.- Conclusion and future work.
Introduction to probabilistic computation models.- Nanoscale circuits and fluctuation problems.- Estimators and Metrics.- MRF Models of Logic Gates.- Neuromorphic models.- Noise-tolerance via error correcting.- Conclusion and future work.
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