Abstract
AbstractA framework is proposed for generative models as a basis fordigital twinsormirrorsof structures. The proposal is based on the premise that deterministic models cannot account for the uncertainty present in most structural modeling applications. Two different types of generative models are considered here. The first is a physics-based model based on the stochastic finite element (SFE) method, which is widely used when modeling structures that have material and loading uncertainties imposed. Such models can be calibrated according to data from the structure and would be expected to outperform any other model if the modeling accurately captures the true underlying physics of the structure. The potential use of SFE models as digital mirrors is illustrated via application to a linear structure with stochastic material properties. For situations where the physical formulation of such models does not suffice, a data-driven framework is proposed, using machine learning and conditional generative adversarial networks (cGANs). The latter algorithm is used to learn the distribution of the quantity of interest in a structure with material nonlinearities and uncertainties. For the examples considered in this work, the data-driven cGANs model outperforms the physics-based approach. Finally, an example is shown where the two methods are coupled such that a hybrid model approach is demonstrated.
Highlights
A recent innovation in the field of system simulation is the creation of digital twins for specific systems
What is usually expected from hybrid approaches is: (a) to use the conditional generative adversarial networks (cGANs) algorithm to correct the discrepancy of the stochastic finite element (SFE) model in cases where the physical formulation of the finite elements do not suffice and (b) to allow the hybrid model to have some predictive capability based on the SFE model away from the operational conditions where data are available; that is, extrapolation capability
The results reveal that the SFE model is unable to capture the effect of the nonlinearity on the distributions of the tip displacements; such a result is expected, since nonlinearity is not included in the formulation of the SFE model used
Summary
A recent innovation in the field of system simulation is the creation of digital twins for specific systems (called physical twins). What is usually expected from hybrid approaches (gray-box models) is: (a) to use the cGAN algorithm to correct the discrepancy of the SFE model in cases where the physical formulation of the finite elements do not suffice and (b) to allow the hybrid model to have some predictive capability based on the SFE model away from the operational conditions where data are available; that is, extrapolation capability. In terms of generative black-box models, GANs are by no means the only option; one alternative—the variational auto-encoder (Kingma and Welling, 2014)—has already proved to be generally useful in engineering problems; in condition monitoring problems (e.g., Mylonas et al, 2020) Another versatile generative framework is provided by Gaussian processes (GPs) (Rasmussen and Williams, 2005). Further details about the SFE method can be found in the Supplementary Appendix
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