arxiv_ml 85% Match Research Paper Meteorologists,Climate Scientists,ML Researchers in Spatio-temporal modeling,Data Scientists in Environmental sectors 1 week ago

Hierarchical Graph Networks for Accurate Weather Forecasting via Lightweight Training

graph-neural-networks › graph-learning

📄 Abstract

Abstract: Climate events arise from intricate, multivariate dynamics governed by global-scale drivers, profoundly impacting food, energy, and infrastructure. Yet, accurate weather prediction remains elusive due to physical processes unfolding across diverse spatio-temporal scales, which fixed-resolution methods cannot capture. Hierarchical Graph Neural Networks (HGNNs) offer a multiscale representation, but nonlinear downward mappings often erase global trends, weakening the integration of physics into forecasts. We introduce HiFlowCast and its ensemble variant HiAntFlow, HGNNs that embed physics within a multiscale prediction framework. Two innovations underpin their design: a Latent-Memory-Retention mechanism that preserves global trends during downward traversal, and a Latent-to-Physics branch that integrates PDE solution fields across diverse scales. Our Flow models cut errors by over 5% at 13-day lead times and by 5-8% under 1st and 99th quantile extremes, improving reliability for rare events. Leveraging pretrained model weights, they converge within a single epoch, reducing training cost and their carbon footprint. Such efficiency is vital as the growing scale of machine learning challenges sustainability and limits research accessibility. Code and model weights are in the supplementary materials.

Authors (4)

Thomas Bailie

S. Karthik Mukkavilli

Varvara Vetrova

Yun Sing Koh

Submitted

October 25, 2025

arXiv Category

cs.LG

arXiv PDF

Key Contributions

This paper introduces HiFlowCast and HiAntFlow, Hierarchical Graph Neural Networks designed for accurate weather forecasting. They embed physics within a multiscale prediction framework using a novel Latent-Memory-Retention mechanism to preserve global trends during hierarchical traversal and a Latent-to-Physics branch to integrate PDE solutions across scales, significantly improving forecast accuracy and reliability.

Business Value

Enhances the accuracy and reliability of weather forecasts, which is critical for sectors like agriculture, energy, transportation, and disaster management, leading to better planning and reduced economic losses.

Paper Metadata

Innovation Type

Architectural

Deployment Feasibility

Moderate. Requires significant computational resources for training and inference, and integration with meteorological data streams.

Limitations Addressed

Inability of fixed-resolution methods to capture physical processes across diverse spatio-temporal scales in weather forecasting. Also addresses the issue of nonlinear downward mappings in HGNNs erasing global trends, weakening physics integration.

Performance Gains

Over 5% error reduction at 13-day lead times.,5-8% error reduction under extreme quantiles.,Improved reliability.

Technical Tags

Hierarchical Graph Neural Networks (HGNNs)Weather forecastingSpatio-temporal dynamicsMultiscale representationLatent-Memory-RetentionPDE integrationHiFlowCastHiAntFlowEnsemble forecasting

Research Topics

Spatio-temporal ModelingGraph Neural NetworksClimate ScienceForecastingPhysics-Informed Machine Learning

Methods & Architectures

Hierarchical Graph Neural NetworksLatent-Memory-Retention mechanismLatent-to-Physics branchEnsemble methods HiFlowCastHiAntFlow (Ensemble variant)

Applications & Tasks

Meteorology Climate Science Environmental Monitoring Disaster Prediction Spatio-temporal ForecastingMultiscale ModelingIntegrating Physics into ML Accurate weather predictionForecasting climate eventsCapturing global trends in weather patterns

Datasets & Benchmarks

Benchmarks

13-day lead times (errors cut by over 5%) • 1st and 99th quantile extremes (errors cut by 5-8%)

Forecast errorReliability

Related Fields

MeteorologyClimate ScienceGraph Neural NetworksSpatio-temporal ModelingPhysics-Informed Machine Learning

Keywords

weather forecastinggraph neural networkshierarchical modelsspatio-temporalmultiscalephysics-informedHGNNHiFlowCastclimatemeteorologyensemblePDE

Academic Context

#Spatio-temporal Modeling#Graph Neural Networks#Climate Science#Forecasting#Physics-Informed Machine Learning

Commercial Potential

Potential Products

Next-generation weather forecasting systemsClimate impact prediction toolsEarly warning systems for extreme weather events

Target Industries

EnergyAgricultureInsuranceTransportationGovernment (Disaster Management)

Use Case Examples

Predicting hurricane paths and intensityForecasting solar energy generation potentialAssessing drought risk

Competitive Edge

Offers a novel hierarchical graph-based approach that explicitly preserves global trends and integrates physics across scales, potentially outperforming traditional numerical weather prediction models and other ML-based forecasting methods in accuracy and reliability, especially for longer lead times.

Market Opportunity

Significant market for weather data and forecasting services

Resource Requirements

Compute Needs

High, especially for training and ensemble methods.

Data Requirements

Requires large-scale historical weather data and potentially simulation data from physical models.

Deployment Constraints

Requires significant computational infrastructure for real-time forecasting; integration with existing meteorological systems.

Scalability

Scalability is a key focus, aiming to handle global-scale dynamics efficiently.

Production Readiness

Maturity Level

Research

Time to Market

Long

Patent Potential

Medium

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