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Training Physics-Informed Neural Networks via Multi-Task Optimization for Traffic Density Prediction

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arxiv 2307.03920 v1 pith:HYOTNSTL submitted 2023-07-08 cs.NE cs.LG

Training Physics-Informed Neural Networks via Multi-Task Optimization for Traffic Density Prediction

classification cs.NE cs.LG
keywords trainingframeworktaskdataneuralperformancepinnpinns
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Physics-informed neural networks (PINNs) are a newly emerging research frontier in machine learning, which incorporate certain physical laws that govern a given data set, e.g., those described by partial differential equations (PDEs), into the training of the neural network (NN) based on such a data set. In PINNs, the NN acts as the solution approximator for the PDE while the PDE acts as the prior knowledge to guide the NN training, leading to the desired generalization performance of the NN when facing the limited availability of training data. However, training PINNs is a non-trivial task largely due to the complexity of the loss composed of both NN and physical law parts. In this work, we propose a new PINN training framework based on the multi-task optimization (MTO) paradigm. Under this framework, multiple auxiliary tasks are created and solved together with the given (main) task, where the useful knowledge from solving one task is transferred in an adaptive mode to assist in solving some other tasks, aiming to uplift the performance of solving the main task. We implement the proposed framework and apply it to train the PINN for addressing the traffic density prediction problem. Experimental results demonstrate that our proposed training framework leads to significant performance improvement in comparison to the traditional way of training the PINN.

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Cited by 1 Pith paper

Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

  1. Learning on the Temporal Tangent Bundle for Physics-Informed Neural Networks

    math.NA 2026-04 unverdicted novelty 7.0

    Parameterizing the temporal derivative in PINNs and reconstructing via Volterra integral yields 100-200x lower errors on advection, Burgers, and Klein-Gordon equations while proving equivalence to the original PDE.