A Reduced Order Model conditioned on monitoring features for estimation and uncertainty quantification in engineered systems

TL;DR

This paper presents a physics-informed reduced order model that is conditioned on online monitoring features, enabling accurate nonlinear system estimation and uncertainty quantification, improving interpretability and scalability over traditional methods.

Contribution

It introduces a novel conditional variational autoencoder-based ROM that adapts to real-time measurements and quantifies uncertainty, addressing limitations of existing physics-based and data-driven approaches.

Findings

Effective in nonlinear, parametric systems with limited data

Provides probabilistic estimates of quantities of interest

Demonstrated on simulated nonlinear case studies

Abstract

Reduced Order Models (ROMs) form essential tools across engineering domains by virtue of their function as surrogates for computationally intensive digital twinning simulators. Although purely data-driven methods are available for ROM construction, schemes that allow to retain a portion of the physics tend to enhance the interpretability and generalization of ROMs. However, physics-based techniques can adversely scale when dealing with nonlinear systems that feature parametric dependencies. This study introduces a generative physics-based ROM that is suited for nonlinear systems with parametric dependencies and is additionally able to quantify the confidence associated with the respective estimates. A main contribution of this work is the conditioning of these parametric ROMs to features that can be derived from monitoring measurements, feasibly in an online fashion. This is contrary to most existing ROM schemes, which remain restricted to the prescription of the physics-based, and usually a priori unknown, system parameters. Our work utilizes conditional Variational Autoencoders to continuously map the required reduction bases to a feature vector extracted from limited output measurements, while additionally allowing for a probabilistic assessment of the ROM-estimated Quantities of Interest. An auxiliary task using a neural network-based parametrization of suitable probability distributions is introduced to re-establish the link with physical model parameters. We verify the proposed scheme on a series of simulated case studies incorporating effects of geometric and material nonlinearity under parametric dependencies related to system properties and input load characteristics.