Publications by authors named "Tom Beucler"
Severe convective storms are among the most dangerous weather phenomena and accurate forecasts mitigate their impacts. The recently released suite of AI-based weather models produces medium-range forecasts within seconds, with a skill similar to state-of-the-art operational forecasts for variables on single levels. However, predicting severe thunderstorm environments requires accurate combinations of dynamic and thermodynamic variables and the vertical structure of the atmosphere.
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- Climate change projections rely on physical models that struggle with small-scale processes, leading to uncertainties in predictions.
- Recent machine learning algorithms show potential for improving these models but often fail when applied to new climate conditions they weren't originally trained on.
- The proposed "climate-invariant" ML framework integrates physical knowledge into machine learning, enhancing accuracy and adaptability across various climate scenarios and improving Earth system modeling.
Article Synopsis
- Global storm-resolving models (GSRMs) have gained popularity for their detailed representation of global climate, but assessing their differences in simulating atmospheric formations poses challenges.
- To overcome this, the study introduces methods that analyze distributional distances through nonlinear dimensionality reduction and vector quantization, allowing for a more objective comparison of model outputs.
- The findings indicate that only six out of nine models exhibit similar representations of atmospheric dynamics, while also revealing signs of the convective response to global warming, paving the way for better evaluation of high-resolution simulation data.
A promising approach to improve cloud parameterizations within climate models and thus climate projections is to use deep learning in combination with training data from storm-resolving model (SRM) simulations. The ICOsahedral Non-hydrostatic (ICON) modeling framework permits simulations ranging from numerical weather prediction to climate projections, making it an ideal target to develop neural network (NN) based parameterizations for sub-grid scale processes. Within the ICON framework, we train NN based cloud cover parameterizations with coarse-grained data based on realistic regional and global ICON SRM simulations.
View Article and Find Full Text PDFDeep learning can accurately represent sub-grid-scale convective processes in climate models, learning from high resolution simulations. However, deep learning methods usually lack interpretability due to large internal dimensionality, resulting in reduced trustworthiness in these methods. Here, we use Variational Encoder Decoder structures (VED), a non-linear dimensionality reduction technique, to learn and understand convective processes in an aquaplanet superparameterized climate model simulation, where deep convective processes are simulated explicitly.
View Article and Find Full Text PDFNeural networks can emulate nonlinear physical systems with high accuracy, yet they may produce physically inconsistent results when violating fundamental constraints. Here, we introduce a systematic way of enforcing nonlinear analytic constraints in neural networks via constraints in the architecture or the loss function. Applied to convective processes for climate modeling, architectural constraints enforce conservation laws to within machine precision without degrading performance.
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