English

RiverScope: High-Resolution River Masking Dataset

Computer Vision and Pattern Recognition 2025-11-17 v2

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.

Keywords

Cite

@article{arxiv.2509.02451,
  title  = {RiverScope: High-Resolution River Masking Dataset},
  author = {Rangel Daroya and Taylor Rowley and Jonathan Flores and Elisa Friedmann and Fiona Bennitt and Heejin An and Travis Simmons and Marissa Jean Hughes and Camryn L Kluetmeier and Solomon Kica and J. Daniel Vélez and Sarah E. Esenther and Thomas E. Howard and Yanqi Ye and Audrey Turcotte and Colin Gleason and Subhransu Maji},
  journal= {arXiv preprint arXiv:2509.02451},
  year   = {2025}
}
R2 v1 2026-07-01T05:17:35.932Z