Related papers: Deep-learning based down-scaling of summer monsoon rainfall data over Indian region

Deep-learning based down-scaling of summer monsoon rainfall data over Indian region

URL: http://arxiv.org/abs/2011.11313v3
Date: Tue, 8 Dec 2020 09:24:20 GMT
Title: Deep-learning based down-scaling of summer monsoon rainfall data over Indian region
Authors: Bipin Kumar, Rajib Chattopadhyay, Manmeet Singh, Niraj Chaudhari, Karthik Kodari and Amit Barve
Abstract summary: Dynamical and statistical downscaling models are often used to get information at high-resolution gridded data over larger domains. Deep Learning (DL) based methods provide an efficient solution in downscaling rainfall data for regional climate forecasting and real-time rainfall observation data at high spatial resolutions. In this work, we employed three deep learning-based algorithms derived from the super-resolution convolutional neural network (SRCNN) methods, to produce 4x-times high-resolution downscaled rainfall data during the summer monsoon season.
Score: 0.0
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Downscaling is necessary to generate high-resolution observation data to validate the climate model forecast or monitor rainfall at the micro-regional level operationally. Dynamical and statistical downscaling models are often used to get information at high-resolution gridded data over larger domains. As rainfall variability is dependent on the complex Spatio-temporal process leading to non-linear or chaotic Spatio-temporal variations, no single downscaling method can be considered efficient enough. In data with complex topographies, quasi-periodicities, and non-linearities, deep Learning (DL) based methods provide an efficient solution in downscaling rainfall data for regional climate forecasting and real-time rainfall observation data at high spatial resolutions. In this work, we employed three deep learning-based algorithms derived from the super-resolution convolutional neural network (SRCNN) methods, to precipitation data, in particular, IMD and TRMM data to produce 4x-times high-resolution downscaled rainfall data during the summer monsoon season. Among the three algorithms, namely SRCNN, stacked SRCNN, and DeepSD, employed here, the best spatial distribution of rainfall amplitude and minimum root-mean-square error is produced by DeepSD based downscaling. Hence, the use of the DeepSD algorithm is advocated for future use. We found that spatial discontinuity in amplitude and intensity rainfall patterns is the main obstacle in the downscaling of precipitation. Furthermore, we applied these methods for model data postprocessing, in particular, ERA5 data. Downscaled ERA5 rainfall data show a much better distribution of spatial covariance and temporal variance when compared with observation.

Related papers

Generative Precipitation Downscaling using Score-based Diffusion with Wasserstein Regularization [19.32044524311079]
A dearth of long-record and high-resolution products can be used to understand local risk and precipitation science. We present a novel generative diffusion model that downscales globally available gauge-based precipitation products. We show that WassDiff has better reconstruction accuracy and bias scores than conventional score-based diffusion models.
arXiv Detail & Related papers (2024-10-01T04:12:40Z)
Observation-Guided Meteorological Field Downscaling at Station Scale: A Benchmark and a New Method [66.80344502790231]
We extend meteorological downscaling to arbitrary scattered station scales and establish a new benchmark and dataset. Inspired by data assimilation techniques, we integrate observational data into the downscaling process, providing multi-scale observational priors. Our proposed method outperforms other specially designed baseline models on multiple surface variables.
arXiv Detail & Related papers (2024-01-22T14:02:56Z)
Precipitation Downscaling with Spatiotemporal Video Diffusion [19.004369237435437]
This work extends recent video diffusion models to precipitation super-resolution. We use a deterministic downscaler followed by a temporally-conditioned diffusion model to capture noise characteristics and high-frequency patterns. Our analysis, capturing CRPS, MSE, precipitation distributions, and qualitative aspects using California and the Himalayas, establishes our method as a new standard for data-driven precipitation downscaling.
arXiv Detail & Related papers (2023-12-11T02:38:07Z)
SSIN: Self-Supervised Learning for Rainfall Spatial Interpolation [37.212272184144]
We propose a data-driven self-supervised learning framework for rainfall spatial analysis. By mining latent spatial patterns from historical data, SpaFormer can learn informative embeddings for raw data and then adaptively model spatial correlations. Our method outperforms the state-of-the-art solutions in experiments on two real-world raingauge datasets.
arXiv Detail & Related papers (2023-11-27T04:23:47Z)
Long-term drought prediction using deep neural networks based on geospatial weather data [75.38539438000072]
High-quality drought forecasting up to a year in advance is critical for agriculture planning and insurance. We tackle drought data by introducing an end-to-end approach that adopts a systematic end-to-end approach. Key findings are the exceptional performance of a Transformer model, EarthFormer, in making accurate short-term (up to six months) forecasts.
arXiv Detail & Related papers (2023-09-12T13:28:06Z)
An evaluation of deep learning models for predicting water depth evolution in urban floods [59.31940764426359]
We compare different deep learning models for prediction of water depth at high spatial resolution. Deep learning models are trained to reproduce the data simulated by the CADDIES cellular-automata flood model. Our results show that the deep learning models present in general lower errors compared to the other methods.
arXiv Detail & Related papers (2023-02-20T16:08:54Z)
On the modern deep learning approaches for precipitation downscaling [0.0]
We carry out the DL-based downscaling to estimate the local precipitation data from the India Meteorological Department (IMD) To test the efficacy of different DL approaches, we apply four different methods of downscaling and evaluate their performance. The results indicate that SR-GAN is the best method for precipitation data downscaling.
arXiv Detail & Related papers (2022-07-02T11:57:39Z)
Super-resolution GANs of randomly-seeded fields [68.8204255655161]
We propose a novel super-resolution generative adversarial network (GAN) framework to estimate field quantities from random sparse sensors. The algorithm exploits random sampling to provide incomplete views of the high-resolution underlying distributions. The proposed technique is tested on synthetic databases of fluid flow simulations, ocean surface temperature distributions measurements, and particle image velocimetry data.
arXiv Detail & Related papers (2022-02-23T18:57:53Z)
Semi-Supervised Video Deraining with Dynamic Rain Generator [59.71640025072209]
This paper proposes a new semi-supervised video deraining method, in which a dynamic rain generator is employed to fit the rain layer. Specifically, such dynamic generator consists of one emission model and one transition model to simultaneously encode the spatially physical structure and temporally continuous changes of rain streaks. Various prior formats are designed for the labeled synthetic and unlabeled real data, so as to fully exploit the common knowledge underlying them.
arXiv Detail & Related papers (2021-03-14T14:28:57Z)
TRU-NET: A Deep Learning Approach to High Resolution Prediction of Rainfall [21.399707529966474]
We present TRU-NET, an encoder-decoder model featuring a novel 2D cross attention mechanism between contiguous convolutional-recurrent layers. We use a conditional-continuous loss function to capture the zero-skewed %extreme event patterns of rainfall. Experiments show that our model consistently attains lower RMSE and MAE scores than a DL model prevalent in short term precipitation prediction.
arXiv Detail & Related papers (2020-08-20T17:27:59Z)
From Rain Generation to Rain Removal [67.71728610434698]
We build a full Bayesian generative model for rainy image where the rain layer is parameterized as a generator. We employ the variational inference framework to approximate the expected statistical distribution of rainy image. Comprehensive experiments substantiate that the proposed model can faithfully extract the complex rain distribution.
arXiv Detail & Related papers (2020-08-08T18:56:51Z)

This list is automatically generated from the titles and abstracts of the papers in this site.