13 research outputs found
EfficientTempNet: Temporal Super-Resolution of Radar Rainfall
Rainfall data collected by various remote sensing instruments such as radars
or satellites has different space-time resolutions. This study aims to improve
the temporal resolution of radar rainfall products to help with more accurate
climate change modeling and studies. In this direction, we introduce a solution
based on EfficientNetV2, namely EfficientTempNet, to increase the temporal
resolution of radar-based rainfall products from 10 minutes to 5 minutes. We
tested EfficientRainNet over a dataset for the state of Iowa, US, and compared
its performance to three different baselines to show that EfficientTempNet
presents a viable option for better climate change monitoring.Comment: Published as a workshop paper at Tackling Climate Change with Machine
Learning, ICLR 202
TempNet -- Temporal Super Resolution of Radar Rainfall Products with Residual CNNs
The temporal and spatial resolution of rainfall data is crucial for
environmental modeling studies in which its variability in space and time is
considered as a primary factor. Rainfall products from different remote sensing
instruments (e.g., radar, satellite) have different space-time resolutions
because of the differences in their sensing capabilities and post-processing
methods. In this study, we developed a deep learning approach that augments
rainfall data with increased time resolutions to complement relatively lower
resolution products. We propose a neural network architecture based on
Convolutional Neural Networks (CNNs) to improve the temporal resolution of
radar-based rainfall products and compare the proposed model with an optical
flow-based interpolation method and CNN-baseline model. The methodology
presented in this study could be used for enhancing rainfall maps with better
temporal resolution and imputation of missing frames in sequences of 2D
rainfall maps to support hydrological and flood forecasting studies
TempNet – Temporal Super-resolution Of Radar Rainfall Products With Residual CNNs
The temporal and spatial resolution of rainfall data is crucial for environmental modeling studies in which its variability in space and time is considered as a primary factor. Rainfall products from different remote sensing instruments (e.g., radar, satellite) have different space-time resolutions because of the differences in their sensing capabilities and post-processing methods. In this study, we developed a deep-learning approach that augments rainfall data with increased time resolutions to complement relatively lower-resolution products. We propose a neural network architecture based on Convolutional Neural Networks (CNNs), namely TempNet, to improve the temporal resolution of radar-based rainfall products and compare the proposed model with an optical flow-based interpolation method and CNN-baseline model. While TempNet achieves a mean absolute error of 0.332 mm/h, comparison methods achieve 0.35 and 0.341, respectively. The methodology presented in this study could be used for enhancing rainfall maps with better temporal resolution and imputation of missing frames in sequences of 2D rainfall maps to support hydrological and flood forecasting studies