Technical note: A low-cost approach to monitoring relative streamflow dynamics in small headwater streams using time lapse imagery and a deep learning model

Phillip J. Goodling; Jennifer H. Fair; Amrita Gupta; Jeffrey D. Walker; Todd Dubreuil; Michael J. Hayden; Benjamin H. Letcher

doi:10.5194/hess-29-6445-2025

Technical note: A low-cost approach to monitoring relative streamflow dynamics in small headwater streams using time lapse imagery and a deep learning model

Hydrology and Earth System Sciences

By: Phillip J. Goodling, Jennifer H. Fair, Amrita Gupta, Jeffrey D. Walker, Todd Dubreuil, Michael J. Hayden, and Benjamin H. Letcher

https://doi.org/10.5194/hess-29-6445-2025

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A low-cost approach to monitoring streamflow dynamics in small, headwater streams using timelapse imagery and a deep learning model(2025)

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Abstract

Despite their ubiquity and importance as freshwater habitat, small headwater streams are under-monitored by existing stream gage networks. To address this gap, we describe a low-cost, non-contact, and low-effort method that enables organizations to monitor relative streamflow dynamics in small headwater streams. The method uses a camera to capture repeat images of the stream from a fixed position. A person then annotates pairs of images, in each case indicating which image has more apparent streamflow or indicating equal flow if no difference is discernible. A deep learning modeling framework called streamflow rank estimation (SRE) is then trained on the annotated image pairs and applied to rank all images from highest to lowest apparent streamflow. From this result a relative hydrograph can be derived. We found that our modeled relative hydrograph dynamics matched the observed hydrograph dynamics well for 11 cameras at 8 streamflow sites in western Massachusetts. Higher performance was observed during the annotation period (median Kendall's Tau rank correlation of 0.75, with a range of 0.6–0.83) than after it (median Kendall's Tau of 0.59, with range 0.34–0.74). We found that annotation performance was generally consistent across the 11 camera sites and 2 individual annotators and was positively correlated with streamflow variability at a site. A scaling simulation determined that model performance improvements were limited after 1000 annotation pairs. Our model's estimates of relative flow, while not equivalent to absolute flow, may still be useful for many applications, such as ecological modeling and calculating event-based hydrological statistics (e.g., the number of out-of-bank floods). We anticipate that this method will be a valuable tool to extend existing stream monitoring networks and provide new insights on dynamic headwater systems.

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Additional publication details
Publication type	Article
Publication Subtype	Journal Article
Title	Technical note: A low-cost approach to monitoring relative streamflow dynamics in small headwater streams using time lapse imagery and a deep learning model
Series title	Hydrology and Earth System Sciences
DOI	10.5194/hess-29-6445-2025
Volume	29
Issue	22
Publication Date	November 19, 2025
Year Published	2025
Language	English
Publisher	European Geosciences Union
Contributing office(s)	WMA - Earth System Processes Division
Description	16 p.
First page	6445
Last page	6460
Country	United States
State	Massachusetts
Other Geospatial	western Massachusetts