Physics-Informed Neural Networks
ORAL
Abstract
Methods of machine learning are starting to be widely used in
applications in hadronic physics. Neural networks provide a very
flexible parametrization of functions to be extracted from the
experimental data. They are used in hadronic physics to extract parton
distribution functions and other functions that describe the internal
structure of the nucleon. At the same time, the inverse problem
solutions must obey physical laws encoded in differential equations,
boundary conditions, etc. One of the goals of the inverse problem is
reliable estimation of the errors of the extractions and the posterior
probability density of the underlying parameters. The flexibility
provided by the neural networks is the origin of the pitfall of the
traditional neural networks, which is the extrapolation of the
results. The extrapolation needed for predictions for unmeasured
regions may become nonphysical if the appropriate constraints or
functional forms are not imposed. In our study, we will construct a
neural network that describes synthetic data and demonstrate potential
problems of its utilization. We will further study and apply methods
of the Physics-Informed Neural Networks (PINN) to tame the behavior of
the network and to guide the neural network to obey physical
laws. Using comprehensive examples, we will work towards the goal of
constructing a flexible PINN to handle the inverse problems that arise
in hadronic physics.
applications in hadronic physics. Neural networks provide a very
flexible parametrization of functions to be extracted from the
experimental data. They are used in hadronic physics to extract parton
distribution functions and other functions that describe the internal
structure of the nucleon. At the same time, the inverse problem
solutions must obey physical laws encoded in differential equations,
boundary conditions, etc. One of the goals of the inverse problem is
reliable estimation of the errors of the extractions and the posterior
probability density of the underlying parameters. The flexibility
provided by the neural networks is the origin of the pitfall of the
traditional neural networks, which is the extrapolation of the
results. The extrapolation needed for predictions for unmeasured
regions may become nonphysical if the appropriate constraints or
functional forms are not imposed. In our study, we will construct a
neural network that describes synthetic data and demonstrate potential
problems of its utilization. We will further study and apply methods
of the Physics-Informed Neural Networks (PINN) to tame the behavior of
the network and to guide the neural network to obey physical
laws. Using comprehensive examples, we will work towards the goal of
constructing a flexible PINN to handle the inverse problems that arise
in hadronic physics.
*National Science Foundation (NSF) grants PHY-2310031and PHY-2335114
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Presenters
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Ava Oberrender
- Pennsylvania State University-Berks