Earth Virtualization Engines: A Technical Perspective

Computing in Science & Engineering Institute of Electrical and Electronics Engineers (IEEE) 25:3 (2023) 50-59

Authors:

Torsten Hoefler, Bjorn Stevens, Andreas F Prein, Johanna Baehr, Thomas Schulthess, Thomas F Stocker, John Taylor, Daniel Klocke, Pekka Manninen, Piers M Forster, Tobias Kölling, Nicolas Gruber, Hartwig Anzt, Claudia Frauen, Florian Ziemen, Milan Klöwer, Karthik Kashinath, Christoph Schär, Oliver Fuhrer, Bryan N Lawrence

Biomass Estimation and Uncertainty Quantification From Tree Height

IEEE Journal of Selected Topics in Applied Earth Observations and Remote Sensing Institute of Electrical and Electronics Engineers (IEEE) 16 (2023) 4833-4845

Authors:

Qian Song, Conrad M Albrecht, Zhitong Xiong, Xiao Xiang Zhu

Deep Semantic Model Fusion for Ancient Agricultural Terrace Detection

2022 IEEE International Conference on Big Data (Big Data) IEEE (2022) 4888-4892

Authors:

Yi Wang, Chenying Liu, Arti Tiwari, Micha Silver, Arnon Karnieli, Xiao Xiang Zhu, Conrad M Albrecht

Self-Supervised Learning in Remote Sensing: A review

IEEE Geoscience and Remote Sensing Magazine Institute of Electrical and Electronics Engineers (IEEE) 10:4 (2022) 213-247

Authors:

Yi Wang, Conrad M Albrecht, Nassim Ait Ali Braham, Lichao Mou, Xiao Xiang Zhu

Physics-informed learning of aerosol microphysics

Environmental Data Science Cambridge University Press 1 (2022) e20

Authors:

Paula Harder, Duncan Watson-Parris, Philip Stier, Dominik Strassel, Nicolas R Gauger, Janis Keuper

Abstract:

Aerosol particles play an important role in the climate system by absorbing and scattering radiation and influencing cloud properties. They are also one of the biggest sources of uncertainty for climate modeling. Many climate models do not include aerosols in sufficient detail due to computational constraints. To represent key processes, aerosol microphysical properties and processes have to be accounted for. This is done in the ECHAM-HAM (European Center for Medium-Range Weather Forecast-Hamburg-Hamburg) global climate aerosol model using the M7 microphysics, but high computational costs make it very expensive to run with finer resolution or for a longer time. We aim to use machine learning to emulate the microphysics model at sufficient accuracy and reduce the computational cost by being fast at inference time. The original M7 model is used to generate data of input–output pairs to train a neural network (NN) on it. We are able to learn the variables’ tendencies achieving an average R2 score of 77.1%. We further explore methods to inform and constrain the NN with physical knowledge to reduce mass violation and enforce mass positivity. On a Graphics processing unit (GPU), we achieve a speed-up of up to over 64 times faster when compared to the original model.