The paper introduces GrINd (Grid Interpolation Network for Scattered Observations), a novel approach for forecasting the evolution of spatiotemporal physical systems from sparse, scattered observational data.
The key highlights are:
GrINd combines a Fourier Interpolation Layer and a NeuralPDE model to efficiently predict the state of a physical system in a high-resolution grid space, and then maps the predictions back to the original observation space.
The Fourier Interpolation Layer takes the scattered observations as input and maps them onto a high-resolution grid using a differentiable Fourier series approximation. This allows GrINd to leverage the high performance of grid-based models.
The NeuralPDE model, which has shown state-of-the-art performance on the DynaBench benchmark, is used to forecast the evolution of the physical system in the high-resolution grid space.
Experiments on the DynaBench dataset, which contains six different physical systems observed at scattered locations, demonstrate that GrINd outperforms existing non-grid based models, especially for longer prediction horizons. This highlights the benefits of using a grid representation for improved numerical stability.
The authors also provide analysis on the interpolation accuracy of the Fourier Interpolation Layer, showing that an optimal number of Fourier frequencies can be selected for each physical system to minimize the interpolation error.
Overall, GrINd represents a promising approach for forecasting physical systems from sparse, scattered observational data, extending the applicability of deep learning methods to real-world scenarios with limited data availability.
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arxiv.org
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