Physics-derived covariance functions for machine learning in structural dynamics
Elizabeth J. Cross, Timothy J. Rogers
Abstract
This paper attempts to bridge the gap between standard engineering practice and machine learning when modelling stochastic processes. For a number of physical processes of interest, derivation of the (auto)covariance is achievable. This paper suggests their use as priors in a standard Gaussian process regression as a means of enhancing predictive capability in situations where they are reflective of the process of interest. A covariance function of a linear oscillator under random load is derived and used in a regression context to predict the displacements of a vibratory system. A simulation case study is used to demonstrate the enhancement over a standard Gaussian process regression model.
Topics & Concepts
CovarianceCovariance functionGaussian processContext (archaeology)KrigingGaussianApplied mathematicsStochastic processRegressionLinear regressionComputer scienceArtificial intelligenceStatistical physicsMachine learningMathematicsPhysicsStatisticsPaleontologyQuantum mechanicsBiologyStructural Health Monitoring TechniquesProbabilistic and Robust Engineering DesignControl Systems and Identification