Temel Kavramlar
Large-scale flood modeling and forecasting are enhanced by the FloodCast framework, integrating multi-satellite observations and a geometry-adaptive physics-informed neural solver.
Özet
The FloodCast framework combines multi-satellite observation and hydrodynamic modeling modules to predict flood inundation depths accurately. It introduces GeoPINS, a geometry-adaptive physics-informed neural solver, for large-scale flood modeling. The content discusses the challenges in traditional hydrodynamics, the role of remote sensing observations, SAR-based technologies, and the proposed sequence-to-sequence GeoPINS model for handling long-term temporal series in flood modeling. The methodology section details the reformulation of PINNs in a geometry-adaptive space and the numerical experiments conducted to evaluate the efficacy of GeoPINS.
Introduction:
- Flooding as a global hazard necessitating effective warning systems.
- Importance of flood forecasting for risk reduction.
Remote Sensing Observations:
- Role of satellite observations in improving model parameters.
- Advantages of SAR-based technologies for flood mapping.
Hydrodynamic Modeling:
- Challenges with traditional hydrodynamic methods.
- Introduction of GeoPINS for resolution-invariant flood simulations.
Geometry-adaptive Physics-Informed Neural Solver:
- Reformulating PINNs in a geometry-adaptive space.
- Utilizing Fourier neural operators for spatial-temporal modeling.
Numerical Experiments:
- Implementation details and benchmarks for evaluating GeoPINS effectiveness.
İstatistikler
"The experimental results for the 2022 Pakistan flood demonstrate that the proposed method enables high-precision, large-scale flood modeling with an average MAPE of 14.93% and an average MAE of 0.0610m for 14-day water depth predictions."