On the Role of Fixed Points of Dynamical Systems in Training Physics-Informed Neural Networks

Franz Martin Rohrhofer; Stefan Posch; Clemens Gößnitzer; Bernhard Geiger

On the Role of Fixed Points of Dynamical Systems in Training Physics-Informed Neural Networks

Franz Martin Rohrhofer^*, Stefan Posch, Clemens Gößnitzer, Bernhard Geiger

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

This paper empirically studies commonly observed training difficulties of Physics-Informed Neural Networks (PINNs) on dynamical systems. Our results indicate that fixed points which are inherent to these systems play a key role in the optimization of the in PINNs embedded physics loss function. We observe that the loss landscape exhibits local optima that are shaped by the presence of fixed points. We find that these local optima contribute to the complexity of the physics loss optimization which can explain common training difficulties and resulting nonphysical predictions. Under certain settings, e.g., initial conditions close to fixed points or long simulations times, we show that those optima can even become better than that of the desired solution.

Original language	English
Article number	490
Number of pages	22
Journal	Transactions on Machine Learning Research
Volume	2023
Issue number	1
Publication status	Published - 23 Jan 2023

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Cite this

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title = "On the Role of Fixed Points of Dynamical Systems in Training Physics-Informed Neural Networks",

abstract = "This paper empirically studies commonly observed training difficulties of Physics-Informed Neural Networks (PINNs) on dynamical systems. Our results indicate that fixed points which are inherent to these systems play a key role in the optimization of the in PINNs embedded physics loss function. We observe that the loss landscape exhibits local optima that are shaped by the presence of fixed points. We find that these local optima contribute to the complexity of the physics loss optimization which can explain common training difficulties and resulting nonphysical predictions. Under certain settings, e.g., initial conditions close to fixed points or long simulations times, we show that those optima can even become better than that of the desired solution.",

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AU - Gößnitzer, Clemens

AU - Geiger, Bernhard

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N2 - This paper empirically studies commonly observed training difficulties of Physics-Informed Neural Networks (PINNs) on dynamical systems. Our results indicate that fixed points which are inherent to these systems play a key role in the optimization of the in PINNs embedded physics loss function. We observe that the loss landscape exhibits local optima that are shaped by the presence of fixed points. We find that these local optima contribute to the complexity of the physics loss optimization which can explain common training difficulties and resulting nonphysical predictions. Under certain settings, e.g., initial conditions close to fixed points or long simulations times, we show that those optima can even become better than that of the desired solution.

AB - This paper empirically studies commonly observed training difficulties of Physics-Informed Neural Networks (PINNs) on dynamical systems. Our results indicate that fixed points which are inherent to these systems play a key role in the optimization of the in PINNs embedded physics loss function. We observe that the loss landscape exhibits local optima that are shaped by the presence of fixed points. We find that these local optima contribute to the complexity of the physics loss optimization which can explain common training difficulties and resulting nonphysical predictions. Under certain settings, e.g., initial conditions close to fixed points or long simulations times, we show that those optima can even become better than that of the desired solution.

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ER -

On the Role of Fixed Points of Dynamical Systems in Training Physics-Informed Neural Networks

Abstract

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