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Designing accurate emulators for scientific processes using calibration-driven deep models

Jayaraman J. Thiagarajan, Bindya Venkatesh, Rushil Anirudh, Peer-Timo Bremer, Jim Gaffney, Gemma Anderson, Brian Spears

2020Nature Communications30 citationsDOIOpen Access PDF

Abstract

Predictive models that accurately emulate complex scientific processes can achieve speed-ups over numerical simulators or experiments and at the same time provide surrogates for improving the subsequent analysis. Consequently, there is a recent surge in utilizing modern machine learning methods to build data-driven emulators. In this work, we study an often overlooked, yet important, problem of choosing loss functions while designing such emulators. Popular choices such as the mean squared error or the mean absolute error are based on a symmetric noise assumption and can be unsuitable for heterogeneous data or asymmetric noise distributions. We propose Learn-by-Calibrating, a novel deep learning approach based on interval calibration for designing emulators that can effectively recover the inherent noise structure without any explicit priors. Using a large suite of use-cases, we demonstrate the efficacy of our approach in providing high-quality emulators, when compared to widely-adopted loss function choices, even in small-data regimes.

Topics & Concepts

Computer scienceNoise (video)SuiteMean squared errorMachine learningArtificial intelligenceDeep learningNoisy dataFunction (biology)CalibrationAlgorithmInterval (graph theory)Mean absolute errorProcess (computing)Noise measurementData miningMean squared prediction errorStochastic processComplex systemApproximation errorModel Reduction and Neural NetworksAdvanced Multi-Objective Optimization AlgorithmsMachine Learning in Materials Science