Related papers: Machine learning based digital twin for dynamical systems with multiple time-scales

Machine learning based digital twin for dynamical systems with multiple time-scales

URL: http://arxiv.org/abs/2005.05862v2
Date: Sun, 14 Jun 2020 05:12:55 GMT
Title: Machine learning based digital twin for dynamical systems with multiple time-scales
Authors: Souvik Chakraborty and Sondipon Adhikari
Abstract summary: Digital twin technology has a huge potential for widespread applications in different industrial sectors such as infrastructure, aerospace, and automotive. Here we focus on a digital twin framework for linear single-degree-of-freedom structural dynamic systems evolving in two different operational time scales.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Digital twin technology has a huge potential for widespread applications in different industrial sectors such as infrastructure, aerospace, and automotive. However, practical adoptions of this technology have been slower, mainly due to a lack of application-specific details. Here we focus on a digital twin framework for linear single-degree-of-freedom structural dynamic systems evolving in two different operational time scales in addition to its intrinsic dynamic time-scale. Our approach strategically separates into two components -- (a) a physics-based nominal model for data processing and response predictions, and (b) a data-driven machine learning model for the time-evolution of the system parameters. The physics-based nominal model is system-specific and selected based on the problem under consideration. On the other hand, the data-driven machine learning model is generic. For tracking the multi-scale evolution of the system parameters, we propose to exploit a mixture of experts as the data-driven model. Within the mixture of experts model, Gaussian Process (GP) is used as the expert model. The primary idea is to let each expert track the evolution of the system parameters at a single time-scale. For learning the hyperparameters of the `mixture of experts using GP', an efficient framework the exploits expectation-maximization and sequential Monte Carlo sampler is used. Performance of the digital twin is illustrated on a multi-timescale dynamical system with stiffness and/or mass variations. The digital twin is found to be robust and yields reasonably accurate results. One exciting feature of the proposed digital twin is its capability to provide reasonable predictions at future time-steps. Aspects related to the data quality and data quantity are also investigated.

Related papers

Learning System Dynamics without Forgetting [60.08612207170659]
Predicting trajectories of systems with unknown dynamics is crucial in various research fields, including physics and biology. We present a novel framework of Mode-switching Graph ODE (MS-GODE), which can continually learn varying dynamics. We construct a novel benchmark of biological dynamic systems, featuring diverse systems with disparate dynamics.
arXiv Detail & Related papers (2024-06-30T14:55:18Z)
Enhanced multi-fidelity modelling for digital twin and uncertainty quantification [0.0]
Data-driven models play a crucial role in digital twins, enabling real-time updates and predictions. The fidelity of available data and the scarcity of accurate sensor data often hinder the efficient learning of surrogate models. We propose a novel framework that begins by developing a robust multi-fidelity surrogate model.
arXiv Detail & Related papers (2023-06-26T05:58:17Z)
Probabilistic machine learning based predictive and interpretable digital twin for dynamical systems [0.0]
Two approaches for updating the digital twin are proposed. In both cases, the resulting expressions of updated digital twins are identical. The proposed approaches provide an exact and explainable description of the perturbations in digital twin models.
arXiv Detail & Related papers (2022-12-19T04:25:59Z)
Decentralized digital twins of complex dynamical systems [0.0]
We introduce a decentralized twin (DDT) framework for dynamical systems. We discuss the prospects of the DDT paradigm in computational science and engineering applications.
arXiv Detail & Related papers (2022-07-07T19:44:42Z)
Physics-Inspired Temporal Learning of Quadrotor Dynamics for Accurate Model Predictive Trajectory Tracking [76.27433308688592]
Accurately modeling quadrotor's system dynamics is critical for guaranteeing agile, safe, and stable navigation. We present a novel Physics-Inspired Temporal Convolutional Network (PI-TCN) approach to learning quadrotor's system dynamics purely from robot experience. Our approach combines the expressive power of sparse temporal convolutions and dense feed-forward connections to make accurate system predictions.
arXiv Detail & Related papers (2022-06-07T13:51:35Z)
Capturing Actionable Dynamics with Structured Latent Ordinary Differential Equations [68.62843292346813]
We propose a structured latent ODE model that captures system input variations within its latent representation. Building on a static variable specification, our model learns factors of variation for each input to the system, thus separating the effects of the system inputs in the latent space.
arXiv Detail & Related papers (2022-02-25T20:00:56Z)
Leveraging the structure of dynamical systems for data-driven modeling [111.45324708884813]
We consider the impact of the training set and its structure on the quality of the long-term prediction. We show how an informed design of the training set, based on invariants of the system and the structure of the underlying attractor, significantly improves the resulting models.
arXiv Detail & Related papers (2021-12-15T20:09:20Z)
Machine learning based digital twin for stochastic nonlinear multi-degree of freedom dynamical system [0.0]
We propose a novel digital twin framework for nonlinear multi-degree of freedom (DOFM) dynamical systems. The proposed framework can be used with any choice of Bayesian filtering and machine learning algorithm. Results obtained indicate the applicability and excellent performance of the proposed digital twin framework.
arXiv Detail & Related papers (2021-03-29T14:14:06Z)
Using Data Assimilation to Train a Hybrid Forecast System that Combines Machine-Learning and Knowledge-Based Components [52.77024349608834]
We consider the problem of data-assisted forecasting of chaotic dynamical systems when the available data is noisy partial measurements. We show that by using partial measurements of the state of the dynamical system, we can train a machine learning model to improve predictions made by an imperfect knowledge-based model.
arXiv Detail & Related papers (2021-02-15T19:56:48Z)
Combining Machine Learning with Knowledge-Based Modeling for Scalable Forecasting and Subgrid-Scale Closure of Large, Complex, Spatiotemporal Systems [48.7576911714538]
We attempt to utilize machine learning as the essential tool for integrating pasttemporal data into predictions. We propose combining two approaches: (i) a parallel machine learning prediction scheme; and (ii) a hybrid technique, for a composite prediction system composed of a knowledge-based component and a machine-learning-based component. We demonstrate that not only can this method combining (i) and (ii) be scaled to give excellent performance for very large systems, but also that the length of time series data needed to train our multiple, parallel machine learning components is dramatically less than that necessary without parallelization.
arXiv Detail & Related papers (2020-02-10T23:21:50Z)
The role of surrogate models in the development of digital twins of dynamic systems [0.0]
Digital twin technology has significant promise, relevance and potential of widespread applicability. Digital twins are expected to exploit data and computational methods. We have explored the possibility of using surrogate models within the digital twin technology.
arXiv Detail & Related papers (2020-01-25T10:48:35Z)

This list is automatically generated from the titles and abstracts of the papers in this site.