Abstract
Ecosystem model prediction is important for understanding ecosystem responses to climate change and for management support. Model prediction and quantification of predictive uncertainty of ecosystems have long been investigated. The traditional workflow, which calibrates models to match observations and then uses the calibrated models for predictions, relies heavily on inverse modeling to constrain uncertain parameters in complex forward models. This inversion-based prediction approach is infeasible for complex models with heterogeneous parameter uncertainties and incapable of rapid integration of streaming and multiple sources of data because of the difficulty and computational cost in the model inversion, which is typically ill-posed and can require hundreds of thousands of expensive forward simulations to be performed iteratively. We propose to circumvent inverse modeling by precomputing an ensemble of unconstrained forward simulations and then using machine learning (ML) methods to learn the statistical relationship between simulated observation and prediction quantities. Once the ML model has learned the relationship, it can be used to make predictions of future system behavior with uncertainty quantification based on observations. The proposed learningbased inversion-free model prediction (LIMP) framework is computationally efficient which only requires a few thousands of fully parallelizable forward simulations. Additionally, LIMP can continually update predictions based on streaming observations from multiple locations and sources without necessarily requiring extra model simulations. In this study, we apply LIMP to a regional terrestrial ecosystem model with 47 parameters for testing, refining, and evaluating the approach. We demonstrate that LIMP can be used for efficient model prediction, rapid data assimilation, and cost-effective experimental design for improving robust predictive understanding of ecosystems.
| Original language | English |
|---|---|
| Title of host publication | Proceedings - 19th IEEE International Conference on Data Mining Workshops, ICDMW 2019 |
| Editors | Panagiotis Papapetrou, Xueqi Cheng, Qing He |
| Publisher | IEEE Computer Society |
| Pages | 279-287 |
| Number of pages | 9 |
| ISBN (Electronic) | 9781728146034 |
| DOIs | |
| State | Published - Nov 2019 |
| Event | 19th IEEE International Conference on Data Mining Workshops, ICDMW 2019 - Beijing, China Duration: Nov 8 2019 → Nov 11 2019 |
Publication series
| Name | IEEE International Conference on Data Mining Workshops, ICDMW |
|---|---|
| Volume | 2019-November |
| ISSN (Print) | 2375-9232 |
| ISSN (Electronic) | 2375-9259 |
Conference
| Conference | 19th IEEE International Conference on Data Mining Workshops, ICDMW 2019 |
|---|---|
| Country/Territory | China |
| City | Beijing |
| Period | 11/8/19 → 11/11/19 |
Funding
Primary support for this work was provided by the Scientific Discovery through Advanced Computing (SciDAC) program, funded by the U.S. Department of Energy (DOE), Office of Advanced Scientific Computing Research (ASCR) and Office of Biological and Environmental Research (BER). Additional support was provided by BER's Terrestrial Ecosystem Science Scientific Focus Area (TES-SFA) project and Oak Ridge National Laboratory (ORNL) AI initiative project. The authors are supported by ORNL, which is supported by the DOE under contract DE-AC05-00OR22725. Primary support for this work was provided by the Scientific Discovery through Advanced Computing (SciDAC) program, funded by the U.S. Department of Energy (DOE), Office of Advanced Scientific Computing Research (ASCR) and Office of Biological and EnvironmentalResearch (BER). Additional support was provided by BER’s TerrestrialEcosystem Science Scientific Focus Area (TES-SFA) project and Oak Ridge National Laboratory (ORNL) AI initiative project. The authors are supported by ORNL, which is supported by the DOE under contract DE-AC05-00OR22725.
Keywords
- Efficient model prediction
- Machine learning
- Rapid data assimilation
- Terrestrial ecosystem modeling
- Uncertainty quantification