Abstract
Physics-Informed Neural Networks (PINNs) offer an efficient approach to solving
partial differential equations (PDEs). In theory, they can provide the solution to
a PDE at an arbitrary point for the computational cost of a single forward pass
of a neural network. However, PINNs often pose challenges during training, ne-
cessitating complex hyperparameter tuning, particularly for PDEs with oscillating
solutions. In this paper, we propose a PINN training scheme for PDEs with oscil-
lating solutions. We analyze the impact of sinusoidal activation functions as model
prior and incorporate self-adaptive weights into the training process. Our experi-
ments utilize the double mass-spring-damper system to examine shortcomings in
training PINNs. Our results show that strong model priors, such as sinusoidal
activation functions, are immensely beneficial and, combined with self-adaptive
training, significantly improve performance and convergence of PINNs.
partial differential equations (PDEs). In theory, they can provide the solution to
a PDE at an arbitrary point for the computational cost of a single forward pass
of a neural network. However, PINNs often pose challenges during training, ne-
cessitating complex hyperparameter tuning, particularly for PDEs with oscillating
solutions. In this paper, we propose a PINN training scheme for PDEs with oscil-
lating solutions. We analyze the impact of sinusoidal activation functions as model
prior and incorporate self-adaptive weights into the training process. Our experi-
ments utilize the double mass-spring-damper system to examine shortcomings in
training PINNs. Our results show that strong model priors, such as sinusoidal
activation functions, are immensely beneficial and, combined with self-adaptive
training, significantly improve performance and convergence of PINNs.
| Original language | English |
|---|---|
| Title of host publication | ICLR Workshop |
| Number of pages | 9 |
| Publication status | Published - 2024 |
| Event | ICLR 2024 Workshop on AI4DifferentialEquations In Science - Vienna, Hybrid, Austria Duration: 11 May 2024 → 11 May 2024 |
Conference
| Conference | ICLR 2024 Workshop on AI4DifferentialEquations In Science |
|---|---|
| Country/Territory | Austria |
| City | Vienna, Hybrid |
| Period | 11/05/24 → 11/05/24 |
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CD-Laboratory for Dependable Intelligent Systems in Harsh Environments
Pernkopf, F. (Project manager on research unit) & Pernkopf, F. (Consortium manager resp. coordinator with external organisations)
1/01/23 → 31/12/29
Project: Research project
-
DNN4Rail - Physics-informed Neural Networks for Multibody Dynamics Simulation and its Application to Railway Vehicles
Pernkopf, F. (Project manager on research unit)
1/01/23 → 31/12/23
Project: Research project
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