arxiv_cv 85% Match Research Paper Urban Planners,Environmental Scientists,Climate Researchers,Geospatial Analysts,AI Researchers 2 weeks ago

Detection and Simulation of Urban Heat Islands Using a Fine-Tuned Geospatial Foundation Model for Microclimate Impact Prediction

computer-vision › scene-understanding

📄 Abstract

Abstract: As urbanization and climate change progress, urban heat island effects are becoming more frequent and severe. To formulate effective mitigation plans, cities require detailed air temperature data, yet conventional machine learning models with limited data often produce inaccurate predictions, particularly in underserved areas. Geospatial foundation models trained on global unstructured data offer a promising alternative by demonstrating strong generalization and requiring only minimal fine-tuning. In this study, an empirical ground truth of urban heat patterns is established by quantifying cooling effects from green spaces and benchmarking them against model predictions to evaluate the model's accuracy. The foundation model is subsequently fine-tuned to predict land surface temperatures under future climate scenarios, and its practical value is demonstrated through a simulated inpainting that highlights its role for mitigation support. The results indicate that foundation models offer a powerful way for evaluating urban heat island mitigation strategies in data-scarce regions to support more climate-resilient cities.

Authors (6)

Jannis Fleckenstein

David Kreismann

Tamara Rosemary Govindasamy

Thomas Brunschwiler

Etienne Vos

Mattia Rigotti

Submitted

October 21, 2025

arXiv Category

cs.CV

arXiv PDF

Key Contributions

This paper introduces a fine-tuned geospatial foundation model for predicting land surface temperatures and simulating urban heat island effects. It addresses the limitations of conventional ML models in predicting detailed air temperature data, especially in underserved areas, by leveraging the generalization capabilities of foundation models. The work demonstrates practical value through simulated inpainting for mitigation support, offering a novel approach to urban climate analysis.

Business Value

Enables cities to develop more effective urban planning and climate adaptation strategies by providing accurate microclimate predictions. This can lead to reduced energy consumption, improved public health, and enhanced urban resilience.

Paper Metadata

Innovation Type

Methodological

Deployment Feasibility

Feasible, as it relies on fine-tuning existing foundation models, which can be adapted to specific urban environments with relevant geospatial data.

Limitations Addressed

Inaccurate predictions from conventional ML models with limited data,Lack of detailed air temperature data for mitigation planning,Poor generalization in underserved areas

Technical Tags

geospatial foundation modelsmicroclimate predictionurban heat islandsland surface temperaturefine-tuninginpaintingclimate change modelingremote sensingspatial data analysismachine learning

Research Topics

Climate Change AdaptationUrban PlanningEnvironmental MonitoringGeospatial AIPredictive ModelingFoundation Models

Methods & Architectures

fine-tuninginpaintingbenchmarkingempirical ground truth quantification Geospatial Foundation Model

Applications & Tasks

Urban Planning Environmental Science Climate Change Research Smart Cities PredictionSimulationData Imputation Microclimate Impact PredictionLand Surface Temperature PredictionUrban Heat Island DetectionCooling Effect Quantification

Related Fields

Remote SensingClimate ScienceUrban StudiesGeoinformaticsMachine Learning

Keywords

urban heat islandgeospatial foundation modelmicroclimateland surface temperatureclimate changefine-tuninginpaintingsimulationurban planningremote sensingspatial predictionmachine learningAI for climate

Academic Context

#Climate Change Adaptation#Urban Planning#Environmental Monitoring#Geospatial AI#Predictive Modeling#Foundation Models

Commercial Potential

Potential Products

Urban climate simulation softwareClimate risk assessment toolsSmart city planning platforms

Target Industries

Urban PlanningGovernmentEnvironmental ConsultingReal Estate Development

Use Case Examples

Predicting temperature rise in specific city districts under future climate scenarios.Simulating the cooling effect of new green spaces.Identifying areas most vulnerable to heat stress.

Competitive Edge

Offers a more generalized and accurate approach compared to traditional ML models, particularly in data-scarce regions, by leveraging foundation models.

Market Opportunity

Growing market for climate adaptation and smart city solutions.

Revenue Models

Software licensingconsulting servicesdata-as-a-service.

Resource Requirements

Compute Needs

Moderate to high, depending on the size of the foundation model and the scale of the geospatial data.

Data Requirements

Requires geospatial data, including land cover, elevation, and historical climate data, for fine-tuning and validation.

Deployment Constraints

Requires access to relevant geospatial data and computational resources for fine-tuning and inference.

Scalability

Scalable to different urban areas and geographical regions, leveraging the generalization capabilities of foundation models.

Regulatory Considerations

None explicitly mentionedbut findings could inform environmental regulations.

Production Readiness

Maturity Level

Research/Development

Time to Market

1-3 years for specialized tools based on this research.

Patent Potential

Low to moderate, primarily related to novel fine-tuning strategies or specific model adaptations.

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