Towards High Resolution Probabilistic Coastal Inundation Forecasting from Sparse Observations

Authors

  • Kazi Ashik Islam Biocomplexity Institute, University of Virginia
  • Zakaria Mehrab Biocomplexity Institute, University of Virginia
  • Mahantesh M Halappanavar Pacific Northwest National Laboratory
  • Henning Mortveit Biocomplexity Institute, University of Virginia
  • Katragadda Sridhar Department of Communications and Information Technology, City of Virginia Beach
  • Jon Derek Loftis Virginia Institute of Marine Science, College of William and Mary
  • Stefan Hoops Biocomplexity Institute, University of Virginia
  • Madhav Marathe Biocomplexity Institute, University of Virginia

DOI:

https://doi.org/10.1609/aaai.v40i45.41203

Abstract

Coastal flooding poses increasing threats to communities worldwide, necessitating accurate and hyper-local inundation forecasting for effective emergency response. However, real-world deployment of forecasting systems is often constrained by sparse sensor networks, where only a limited subset of locations may have sensors due to budget constraints. To approach this challenge, we present Diff-Sparse, a masked conditional diffusion model designed for probabilistic coastal inundation forecasting from sparse sensor observations. Diff-Sparse primarily utilizes the inundation history of a location and its neighboring locations from a context time window as spatiotemporal context. The fundamental challenge of spatiotemporal prediction based on sparse observations in the context window is addressed by introducing a novel masking strategy during training. Digital elevation data and temporal co-variates are utilized as additional spatial and temporal contexts, respectively. A convolutional neural network and a conditional UNet architecture with cross-attention mechanism are employed to capture the spatiotemporal dynamics in the data. We trained and tested Diff-Sparse on coastal inundation data from the Eastern Shore of Virginia and systematically assessed the performance of Diff-Sparse across different sparsity levels (0%, 50%, 95% missing observations). Our experiment results show that Diff-Sparse achieves upto 62% improvement in terms of two forecasting performance metrics compared to existing methods, at 95% sparsity level. Moreover, our ablation studies reveal that digital elevation data becomes more useful at high sparsity levels compared to temporal co-variates.
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Published

2026-03-14

How to Cite

Islam, K. A., Mehrab, Z., Halappanavar, M. M., Mortveit, H., Sridhar, K., Loftis, J. D., … Marathe, M. (2026). Towards High Resolution Probabilistic Coastal Inundation Forecasting from Sparse Observations. Proceedings of the AAAI Conference on Artificial Intelligence, 40(45), 38607–38615. https://doi.org/10.1609/aaai.v40i45.41203

Issue

Vol. 40 No. 45: AAAI-26 Special Track AI for Social Impact I

Section

AAAI Special Track on AI for Social Impact I