Parameter variations and impact on circuits and microarchitecture
Proceedings of the 40th annual Design Automation Conference
Energy Aware Computing through Probabilistic Switching: A Study of Limits
IEEE Transactions on Computers
Probabilistic arithmetic and energy efficient embedded signal processing
CASES '06 Proceedings of the 2006 international conference on Compilers, architecture and synthesis for embedded systems
CASES '08 Proceedings of the 2008 international conference on Compilers, architectures and synthesis for embedded systems
A More Precise Model of Noise Based PCMOS Errors
DELTA '10 Proceedings of the 2010 Fifth IEEE International Symposium on Electronic Design, Test & Applications
Modeling of Probabilistic Ripple-Carry Adders
DELTA '10 Proceedings of the 2010 Fifth IEEE International Symposium on Electronic Design, Test & Applications
A general mathematical model of probabilistic ripple-carry adders
Proceedings of the Conference on Design, Automation and Test in Europe
Hi-index | 0.00 |
Quick and accurate error-rate prediction of Probabilistic CMOS (PCMOS) circuits is crucial for their systematic design and performance evaluation. While still in the early stage of research, PCMOS has shown potential to drastically reduce energy consumption at a cost of increased errors. Recently, a methodology has been proposed which could predict the error rates of cascade structures of blocks in PCMOS. This methodology requires error rates of unique blocks to predict the error rates of multiblock cascade structures composed of these unique blocks. In this article we present a new model for characterization of probabilistic circuits/blocks and present a procedure to find and characterize unique circuits/blocks. Unlike prior approaches, our new model distinguishes distinct filtering effects per output, thereby improving prediction accuracy by an average of 95% over the prior art by Palem and coauthors. Furthermore, we show two models where our new model with three stages is 18% more accurate, on average, than our simpler two-stage model. We apply our proposed models to Ripple Carry Adders and Wallace Tree Multipliers and show that using our models, the methodology of cascade structures can predict error rates of PCMOS circuits with reasonable accuracy (within 9%) in PCMOS for uniform voltages as well as multiple voltages. Finally, our approach takes seconds of simulation time whereas using HSPICE would take days of simulation time.