High spatial resolution mapping of surface velocities and depths for shallow overland flow

Point measurements of flow rate, depth or velocity are not sufficient to validate overland flow models, particularly when the interaction of the water with the soil surface creates a complex flow geometry. In this study, we present the coupling of two techniques obtaining spatial data of flow depths and surface velocity measurements for water depths as low as 1?mm. Overland flow experiments were performed in the laboratory at various flow rates and slopes on two surfaces. The first surface was 120?cm by 120?cm showing three undulations of sinusoidal shape with an amplitude of 1?cm and a wavelength of 20?cm, while the second was a 60?cm by 60?cm moulded reproduction of a seedbed with aggregates up to 2?cm in size. Large scale particle image velocimetry (LSPIV) was used for velocity measurements with a sub-centimetre spatial resolution. An instantaneous-profile laser scanner was used to map flow depths with a sub-millimetre spatial resolution. A sensitivity analysis of the image processing of the LSPIV showed good robustness of the method. Comparison with measurements performed with hot film anemometer and salt velocity gauge showed that LSPIV surface velocities were representative of the flow. Water depths measured with the laser scanner were also in good agreement with single-point measurements performed with a dial indicator. Spatially-distributed flow rates could be computed by combining both presented techniques with a mean relative error less than 20%. Copyright (C) 2012 John Wiley & Sons, Ltd.