A major challenge in the study of science and engineering systems is that of model discovery: turning data into dynamical models that are not just predictive, but provide insight into the nature of the underlying physics and dynamics that generated the data.
In this talk, we introduce a number of data-driven strategies for discovering nonlinear multiscale dynamical systems and their embeddings from data. We consider two canonical cases: (i) systems for which we have full measurements of the governing variables, and (ii) systems for which we have incomplete measurements. For systems with full state measurements, we show that the recent sparse identification of nonlinear dynamical systems (SINDy) method can discover governing equations with relatively little data and introduce a sampling method that allows SINDy to scale efficiently to problems with multiple time scales, noise and parametric dependencies. For systems with incomplete observations, we show that time-lagging of measurements gives a pathway to infer the underlying dynamics of the system.
In both cases, neural networks are used in targeted ways to aid in the model reduction process. Together, these approaches provide a suite of mathematical strategies for reducing the data required to discover and model unknown phenomena, giving a robust paradigm for modern AI-aided learning of physics and engineering principles.
A major challenge in the study of science and engineering systems is that of model discovery: turning data into dynamical models that are not just predictive, but provide insight into the nature of the underlying physics and dynamics that generated the data.
In this talk, we introduce a number of data-driven strategies for discovering nonlinear multiscale dynamical systems and their embeddings from data. We consider two canonical cases: (i) systems for which we have full measurements of the governing variables, and (ii) systems for which we have incomplete measurements. For systems with full state measurements, we show that the recent sparse identification of nonlinear dynamical systems (SINDy) method can discover governing equations with relatively little data and introduce a sampling method that allows SINDy to scale efficiently to problems with multiple time scales, noise and parametric dependencies. For systems with incomplete observations, we show that time-lagging of measurements gives a pathway to infer the underlying dynamics of the system.
In both cases, neural networks are used in targeted ways to aid in the model reduction process. Together, these approaches provide a suite of mathematical strategies for reducing the data required to discover and model unknown phenomena, giving a robust paradigm for modern AI-aided learning of physics and engineering principles.
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