Spatially Regularized Graph Attention Autoencoder Framework for Detecting Rainfall Extremes
- URL: http://arxiv.org/abs/2411.07753v1
- Date: Tue, 12 Nov 2024 12:24:48 GMT
- Title: Spatially Regularized Graph Attention Autoencoder Framework for Detecting Rainfall Extremes
- Authors: Mihir Agarwal, Progyan Das, Udit Bhatia,
- Abstract summary: We introduce a novel Graph Attention Autoencoder (GAE) with spatial regularization to address the challenge of scalable anomaly detection in rainfall data across India from 1990 to 2015.
Our work paves the way for sophisticatedtemporal anomaly detection methodologies in climate science, contributing to better climate preparedness and response strategies.
- Score: 2.273531916003657
- License:
- Abstract: We introduce a novel Graph Attention Autoencoder (GAE) with spatial regularization to address the challenge of scalable anomaly detection in spatiotemporal rainfall data across India from 1990 to 2015. Our model leverages a Graph Attention Network (GAT) to capture spatial dependencies and temporal dynamics in the data, further enhanced by a spatial regularization term ensuring geographic coherence. We construct two graph datasets employing rainfall, pressure, and temperature attributes from the Indian Meteorological Department and ERA5 Reanalysis on Single Levels, respectively. Our network operates on graph representations of the data, where nodes represent geographic locations, and edges, inferred through event synchronization, denote significant co-occurrences of rainfall events. Through extensive experiments, we demonstrate that our GAE effectively identifies anomalous rainfall patterns across the Indian landscape. Our work paves the way for sophisticated spatiotemporal anomaly detection methodologies in climate science, contributing to better climate change preparedness and response strategies.
Related papers
- MambaDS: Near-Surface Meteorological Field Downscaling with Topography Constrained Selective State Space Modeling [68.69647625472464]
Downscaling, a crucial task in meteorological forecasting, enables the reconstruction of high-resolution meteorological states for target regions.
Previous downscaling methods lacked tailored designs for meteorology and encountered structural limitations.
We propose a novel model called MambaDS, which enhances the utilization of multivariable correlations and topography information.
arXiv Detail & Related papers (2024-08-20T13:45:49Z) - Generating Fine-Grained Causality in Climate Time Series Data for Forecasting and Anomaly Detection [67.40407388422514]
We design a conceptual fine-grained causal model named TBN Granger Causality.
Second, we propose an end-to-end deep generative model called TacSas, which discovers TBN Granger Causality in a generative manner.
We test TacSas on climate benchmark ERA5 for climate forecasting and the extreme weather benchmark of NOAA for extreme weather alerts.
arXiv Detail & Related papers (2024-08-08T06:47:21Z) - Explainable Global Wildfire Prediction Models using Graph Neural
Networks [2.2389592950633705]
We introduce an innovative Graph Neural Network (GNN)-based model for global wildfire prediction.
Our approach transforms global climate and wildfire data into a graph representation, addressing challenges such as null oceanic data locations.
arXiv Detail & Related papers (2024-02-11T10:44:41Z) - 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) - GA-SmaAt-GNet: Generative Adversarial Small Attention GNet for Extreme Precipitation Nowcasting [1.642094639107215]
We present the GA-SmaAt-GNet model, a novel generative adversarial framework for extreme precipitation nowcasting.
We evaluate the performance of SmaAt-GNet and GA-SmaAt-GNet using real-life precipitation data from the Netherlands.
arXiv Detail & Related papers (2024-01-18T10:53:45Z) - GD-CAF: Graph Dual-stream Convolutional Attention Fusion for
Precipitation Nowcasting [1.642094639107215]
We introduce Graph Dual-streamtemporal Conal Attention Fusion (GD-CAF) to learn from historical graph of precipitation maps and nowcast future time step ahead.
GD-CAF consists of gated-temporal convolutional attention as well as fusion modules equipped with depthwise-separable convolutional operations.
We evaluate our model seven years of precipitation maps across Europe and its neighboring areas collected from the ERA5 dataset.
arXiv Detail & Related papers (2024-01-15T20:54:20Z) - WeatherGNN: Exploiting Meteo- and Spatial-Dependencies for Local Numerical Weather Prediction Bias-Correction [11.10401300641113]
We propose WeatherGNN, a local NWP bias-correction method that exploits meteorological dependencies and spatial dependencies under the guidance of domain knowledge.
Our experimental results on two real-world datasets demonstrate that WeatherGNN achieves the state-of-the-art performance, outperforming the best baseline with an average of 4.75 % on RMSE.
arXiv Detail & Related papers (2023-10-09T08:33:19Z) - Activation Regression for Continuous Domain Generalization with
Applications to Crop Classification [48.795866501365694]
Geographic variance in satellite imagery impacts the ability of machine learning models to generalise to new regions.
We model geographic generalisation in medium resolution Landsat-8 satellite imagery as a continuous domain adaptation problem.
We develop a dataset spatially distributed across the entire continental United States.
arXiv Detail & Related papers (2022-04-14T15:41:39Z) - HiSTGNN: Hierarchical Spatio-temporal Graph Neural Networks for Weather
Forecasting [13.317147032467306]
We propose a novel Graph Hierarchical Spatio-Temporal Neural Network (HiSTGNN) to model cross-regional-temporal correlations among meteorological variables in multiple stations.
Experimental results on three real-world meteorological datasets demonstrate the superior performance of HiSTGNN beyond 7 baselines.
It reduces the errors by 4.2% to 11.6% especially compared to state-of-the-art weather forecasting method.
arXiv Detail & Related papers (2022-01-22T17:30:46Z) - Deep Graph-level Anomaly Detection by Glocal Knowledge Distillation [61.39364567221311]
Graph-level anomaly detection (GAD) describes the problem of detecting graphs that are abnormal in their structure and/or the features of their nodes.
One of the challenges in GAD is to devise graph representations that enable the detection of both locally- and globally-anomalous graphs.
We introduce a novel deep anomaly detection approach for GAD that learns rich global and local normal pattern information by joint random distillation of graph and node representations.
arXiv Detail & Related papers (2021-12-19T05:04:53Z) - Structural Temporal Graph Neural Networks for Anomaly Detection in
Dynamic Graphs [54.13919050090926]
We propose an end-to-end structural temporal Graph Neural Network model for detecting anomalous edges in dynamic graphs.
In particular, we first extract the $h$-hop enclosing subgraph centered on the target edge and propose the node labeling function to identify the role of each node in the subgraph.
Based on the extracted features, we utilize Gated recurrent units (GRUs) to capture the temporal information for anomaly detection.
arXiv Detail & Related papers (2020-05-15T09:17:08Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.