Introducing PebbleCounts: A grain-sizing tool for photo surveys of dynamic gravel-bed rivers

Abstract

Grain-size distributions are a key geomorphic metric of gravel-bed rivers. Traditional measurement methods include manual counting or photo sieving, but these are achievable only at the 110m2 scale. With the advent of drones and increasingly high-resolution cameras, we can now generate orthoimagery over hectares at millimeter to centimeter resolution. These scales, along with the complexity of high-mountain rivers, necessitate different approaches for photo sieving. As opposed to other image segmentation methods that use a watershed approach, our open-source algorithm, PebbleCounts, relies on k-means clustering in the spatial and spectral domain and rapid manual selection of well-delineated grains. This improves grain-size estimates for complex riverbed imagery, without post-processing. We also develop a fully automated method, PebbleCountsAuto, that relies on edge detection and filtering suspect grains, without the k-means clustering or manual selection steps. The algorithms are tested in controlled indoor conditions on three arrays of pebbles and then applied to 12-1m2 orthomosaic clips of high-energy mountain rivers collected with a camera-on-mast setup (akin to a low-flying drone). A 20-pixel b-Axis length lower truncation is necessary for attaining accurate grain-size distributions. For the k-means PebbleCounts approach, average percentile bias and precision are 0.03 and 0.09 , respectively, for-1:16mmpixel1 images, and 0.07 and 0.05 for one 0.32mmpixel1 image. The automatic approach has higher bias and precision of 0.13 and 0.15 , respectively, for-1:16mmpixel1 images, but similar values of 0:06 and 0.05 for one 0.32mmpixel1 image. For the automatic approach, only at best 70% of the grains are correct identifications, and typically around 50 %. PebbleCounts operates most effectively at the 1m2 patch scale, where it can be applied in-510 min on many patches to acquire accurate grain-size data over 10100m2 areas. These data can be used to validate PebbleCountsAuto, which may be applied at the scale of entire survey sites (102104 m2). We synthesize results and recommend best practices for image collection, orthomosaic generation, and grain-size measurement using both algorithms.