%0 Conference Paper %1 10.1007/978-3-031-43412-9_26 %A Dulny, Andrzej %A Hotho, Andreas %A Krause, Anna %B Machine Learning and Knowledge Discovery in Databases: Research Track %C Cham %D 2023 %E Koutra, Danai %E Plant, Claudia %E Gomez Rodriguez, Manuel %E Baralis, Elena %E Bonchi, Francesco %I Springer Nature Switzerland %K app_eco app_physics author:dulny author:hotho author:krause benchmark dataset deep-learning dynamical-systems from:adulny from:martinr myown neural-ode research_knowledge selected %P 438--455 %T DynaBench: A Benchmark Dataset for Learning Dynamical Systems from Low-Resolution Data %U http://arxiv.org/abs/2306.05805 %X Previous work on learning physical systems from data has focused on high-resolution grid-structured measurements. However, real-world knowledge of such systems (e.g. weather data) relies on sparsely scattered measuring stations. In this paper, we introduce a novel simulated benchmark dataset, DynaBench, for learning dynamical systems directly from sparsely scattered data without prior knowledge of the equations. The dataset focuses on predicting the evolution of a dynamical system from low-resolution, unstructured measurements. We simulate six different partial differential equations covering a variety of physical systems commonly used in the literature and evaluate several machine learning models, including traditional graph neural networks and point cloud processing models, with the task of predicting the evolution of the system. The proposed benchmark dataset is expected to advance the state of art as an out-of-the-box easy-to-use tool for evaluating models in a setting where only unstructured low-resolution observations are available. The benchmark is available at https://professor-x.de/dynabench. %@ 978-3-031-43412-9

@inproceedings{10.1007/978-3-031-43412-9_26, abstract = {Previous work on learning physical systems from data has focused on high-resolution grid-structured measurements. However, real-world knowledge of such systems (e.g. weather data) relies on sparsely scattered measuring stations. In this paper, we introduce a novel simulated benchmark dataset, DynaBench, for learning dynamical systems directly from sparsely scattered data without prior knowledge of the equations. The dataset focuses on predicting the evolution of a dynamical system from low-resolution, unstructured measurements. We simulate six different partial differential equations covering a variety of physical systems commonly used in the literature and evaluate several machine learning models, including traditional graph neural networks and point cloud processing models, with the task of predicting the evolution of the system. The proposed benchmark dataset is expected to advance the state of art as an out-of-the-box easy-to-use tool for evaluating models in a setting where only unstructured low-resolution observations are available. The benchmark is available at https://professor-x.de/dynabench.}, added-at = {2023-09-20T08:38:39.000+0200}, address = {Cham}, author = {Dulny, Andrzej and Hotho, Andreas and Krause, Anna}, biburl = {https://www.bibsonomy.org/bibtex/2899228389528bdba00a81d0d93482f36/dmir}, booktitle = {Machine Learning and Knowledge Discovery in Databases: Research Track}, editor = {Koutra, Danai and Plant, Claudia and Gomez Rodriguez, Manuel and Baralis, Elena and Bonchi, Francesco}, interhash = {c005ae8a888da958aaede0341d45a099}, intrahash = {899228389528bdba00a81d0d93482f36}, isbn = {978-3-031-43412-9}, keywords = {app_eco app_physics author:dulny author:hotho author:krause benchmark dataset deep-learning dynamical-systems from:adulny from:martinr myown neural-ode research_knowledge selected}, pages = {438--455}, publisher = {Springer Nature Switzerland}, timestamp = {2024-04-11T09:13:58.000+0200}, title = {DynaBench: A Benchmark Dataset for Learning Dynamical Systems from Low-Resolution Data}, url = {http://arxiv.org/abs/2306.05805}, year = 2023 }