14 th International Symposium on Particle Image Velocimetry – ISPIV 2021 August 1–5, 2021 An Infrared Quantitative Imaging Technique (IR-QIV) for Remote Sensing of River Flows Edwin A. Cowen 1∗ , Seth A. Schweitzer 1 1 DeFrees Hydraulics Laboratory, School of Civil & Environmental Engineering, Cornell University, Ithaca, NY ∗ eac20@cornell.edu Stage and discharge are some of the oldest measurements in environmental fluid mechanics and are vital in forecasting water supply and flood safety. These measurements are traditionally manpower intensive, hence expensive, and dangerous under high flow conditions. Considering climate change and the planet’s increasing population there is a critical need for better, more accurate, and frequent, in space and time, data for model and forecast guidance. This need spans monitoring small-scale turbulent processes to calibrating and nudging continental scale river dynamics models. Driven by applications from river gaging networks to fish behavior modeling to flood and erosion forecasting, and more generally, the near-shore environment of lakes, estuaries and the coasts, remote sensing with quantitative imaging tools is a rapidly expanding field. Such tools can be deployed from fixed platforms, drones, planes and satellites with valuable information contained within the visible to infrared spectral bands. Figure 1: Infrared image of the water surface of a river (Sutter Slough, California, USA). The in- frared image is georeferenced and overlaid on an aerial image. Detailed thermal patterns can be seen at the water surface. Yellow and blue hues in- dicate thermal patterns at the water surface, pur- ple and silver hues are from foliage on the river banks. The width of the river is approximately 50 m. Distances are in meters on the UTM grid. In this presentation we focus on us- ing a remotely mounted infrared (IR) cam- era to monitor the mean and instantaneous surface velocity field of rivers and on how bathymetry, flow rate, and metrics of tur- bulence, can be inferred from the collected IR images. We provide details of our devel- oped infrared quantitative image velocime- try (IR-QIV) method, which capable of measuring instantaneous velocity at high spatial and temporal resolution, over spa- tial domains with side length scales of or- der 10 m to 100 m (i.e., areas of 10 2 m 2 to 10 4 m 2 ) without the use of artificial flow seeding or illumination (Schweitzer and Cowen, under review). We present results from field measure- ments, made in collaboration with the United States Geological Survey (USGS) and the Department of Water Resources (DWR), in the Sacramento–San Joaquin River Delta, CA, USA, and the Finger Lakes Region of New York, USA. We com- pare state-of-the-art acoustic approaches used by the USGS to measurements made by our IR-QIV technique. We describe key similarities and differences relative to current visible light based techniques (e.g., Large Scale Particle Image Velocimetry, or LSPIV), methods to minimize uncertainty in the measurements, and how to use the physics of open channel flows to calculate the bathymetry from remotely measured turbulent integral length scales of the flow (Johnson and Cowen, 2016) and leverage the measured surface mean velocity field to calculate the flow rate at a river cross-section.