RiverScope: High-Resolution River Masking Dataset

Authors

  • Rangel Daroya University of Massachusetts Amherst
  • Taylor Rowley University of Massachusetts Amherst
  • Jonathan Acero Flores University of Massachusetts Amherst
  • Elisa Friedmann University of Massachusetts Amherst
  • Fiona B Bennitt University of Massachusetts Amherst
  • Heejin An University of Massachusetts Amherst
  • Travis Thomas Simmons University of Massachusetts Amherst
  • Marissa Hughes University of North Carolina at Chapel Hill
  • Camryn L Kluetmeier University of North Carolina at Chapel Hill
  • Solomon Kica University of North Carolina at Chapel Hill
  • J. Daniel Vélez University of North Carolina at Chapel Hill
  • Sarah E. Esenther Brown University
  • Thomas E. Howard Brown University
  • Yanqi Ye Brown University
  • Audrey J. Turcotte University of Colorado Boulder
  • Colin Gleason University of Massachusetts Amherst
  • Subhransu Maji University of Massachusetts Amherst

DOI:

https://doi.org/10.1609/aaai.v40i45.41175

Abstract

Surface water dynamics play a critical role in Earth’s climate system, influencing ecosystems, agriculture, disaster resilience, and sustainable development. Yet monitoring rivers and surface water at fine spatial and temporal scales remains challenging---especially for narrow or sediment-rich rivers that are poorly captured by low-resolution satellite data. To address this, we introduce RiverScope, a high-resolution dataset developed through collaboration between computer science and hydrology experts. RiverScope comprises 1,145 high-resolution images (covering 2,577 square kilometers) with expert-labeled river and surface water masks, requiring over 100 hours of manual annotation. Each image is co-registered with Sentinel-2, SWOT, and the SWOT River Database (SWORD), enabling the evaluation of cost-accuracy trade-offs across sensors---a key consideration for operational water monitoring. We also establish the first global, high-resolution benchmark for river width estimation, achieving a median error of 7.2 meters---significantly outperforming existing satellite-derived methods. We extensively evaluate deep networks across multiple architectures (e.g., CNNs and transformers), pretraining strategies (e.g., supervised and self-supervised), and training datasets (e.g., ImageNet and satellite imagery). Our best-performing models combine the benefits of transfer learning with the use of all the multispectral PlanetScope channels via learned adaptors. RiverScope provides a valuable resource for fine-scale and multi-sensor hydrological modeling, supporting climate adaptation and sustainable water management.
AAAI-26 / IAAI-26 / EAAI-26 Proceedings Cover

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Published

2026-03-14

How to Cite

Daroya, R., Rowley, T., Flores, J. A., Friedmann, E., Bennitt, F. B., An, H., Simmons, T. T., Hughes, M., Kluetmeier, C. L., Kica, S., Vélez, J. D., Esenther, S. E., Howard, T. E., Ye, Y., Turcotte, A. J., Gleason, C., & Maji, S. (2026). RiverScope: High-Resolution River Masking Dataset. Proceedings of the AAAI Conference on Artificial Intelligence, 40(45), 38349-38357. https://doi.org/10.1609/aaai.v40i45.41175

Issue

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

Section

AAAI Special Track on AI for Social Impact I