Litcius/Paper detail

Deep-PowerX

Ghasem Pasandi, Mackenzie Peterson, Moisés Torres Herrera, Shahin Nazarian, Massoud Pedram

202017 citationsDOIOpen Access PDF

Abstract

This paper aims at integrating three powerful techniques namely Deep Learning, Approximate Computing, and Low Power Design into a strategy to optimize logic at the synthesis level. We utilize advances in deep learning to guide an approximate logic synthesis engine to minimize the dynamic power consumption of a given digital CMOS circuit, subject to a predetermined error rate at the primary outputs. Our framework, Deep-PowerX1, focuses on replacing or removing gates on a technology-mapped network and uses a Deep Neural Network (DNN) to predict error rates at primary outputs of the circuit when a specific part of the netlist is approximated. The primary goal of Deep-PowerX is to reduce the dynamic power whereas area reduction serves as a secondary objective. Using the said DNN, Deep-PowerX is able to reduce the exponential time complexity of standard approximate logic synthesis to linear time. Experiments are done on numerous open source benchmark circuits. Results show significant reduction in power and area by up to 1.47× and 1.43× compared to exact solutions and by up to 22% and 27% compared to state-of-the-art approximate logic synthesis tools while having orders of magnitudes lower run-time.

Topics & Concepts

NetlistDeep learningComputer scienceBenchmark (surveying)Reduction (mathematics)Artificial neural networkLogic gateLogic synthesisComputer engineeringArtificial intelligenceAlgorithmEmbedded systemMathematicsGeographyGeodesyGeometryLow-power high-performance VLSI designAdvanced Memory and Neural ComputingFerroelectric and Negative Capacitance Devices