AI Article Synopsis
- The increasing availability of Earth science data from climate simulations and satellite sensing provides new opportunities for research but poses computational challenges.
- Machine learning, particularly deep learning, shows promise for improving the efficiency of processing complex datasets like atmospheric corrections by acting as fast statistical models.
- This study introduces DeepEmSat, a deep learning emulator for atmospheric correction, and compares it to traditional physics-based models to demonstrate the potential benefits of using deep learning in satellite image processing.
Article Abstract
The growing volume of Earth science data available from climate simulations and satellite remote sensing offers unprecedented opportunity for scientific insight, while also presenting computational challenges. One potential area of impact is atmospheric correction, where physics-based numerical models retrieve surface reflectance information from top of atmosphere observations, and are too computationally intensive to be run in real time. Machine learning methods have demonstrated potential as fast statistical models for expensive simulations and for extracting credible insights from complex datasets. Here, we develop DeepEmSat: a deep learning emulator approach for atmospheric correction, and offer comparison against physics-based models to support the hypothesis that deep learning can make a contribution to the efficient processing of satellite images.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC7931958 | PMC |
| http://dx.doi.org/10.3389/fdata.2019.00042 | DOI Listing |
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DeepEmSat: Deep Emulation for Satellite Data Mining.
Front Big Data
December 2019
Sustainability and Data Sciences Laboratory, Department of Civil and Environmental Engineering, Northeastern University, Boston, MA, United States.
Article Synopsis
- The increasing availability of Earth science data from climate simulations and satellite sensing provides new opportunities for research but poses computational challenges.
- Machine learning, particularly deep learning, shows promise for improving the efficiency of processing complex datasets like atmospheric corrections by acting as fast statistical models.
- This study introduces DeepEmSat, a deep learning emulator for atmospheric correction, and compares it to traditional physics-based models to demonstrate the potential benefits of using deep learning in satellite image processing.
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