Abstract
Photogrammetric processing algorithms can suffer problems due to either the initial image quality (noise, low radiometric quality, shadows and so on) or to certain surface materials (shiny or textureless objects). This can result in noisy point clouds and/or difficulties in feature extraction. Specifically, dense point clouds which are generated with photogrammetric method using a lightweight thermal camera, are more noisy and sparse than the point clouds of high-resolution digital camera images. In this paper, new method which produces more reliable and dense thermal point cloud using the sparse thermal point cloud and high resolution digital point cloud was considered. Both thermal and digital images were obtained with UAS (Unmanned Aerial System) based lightweight Optris PI 450 and Canon EOS 605D camera images. Thermal and digital point clouds, and orthophotos were produced using photogrammetric methods. Problematic thermal point cloud was transformed to a high density thermal point cloud using image processing methods such as rasterizing, registering, interpolation and filling. The results showed that the obtained thermal point cloud - up to chosen processing parameters - was 87% more densify than the original point cloud. The second improvement was gained at the height accuracy of the thermal point cloud. New densified point cloud has more consistent elevation model while the original thermal point cloud shows serious deviations from the expected surface model.
Highlights
Recent photogrammetric applications which use Unmanned Aerial Systems (UAS) equipped with special sensors such as lightweight thermal and multi-spectral cameras provide three dimensional models in non-visible electromagnetic spectrum besides traditional examples of high-resolution SLR digital cameras
Dense point clouds which are generated with photogrammetric method using a lightweight thermal camera, are more noisy and sparse than the point clouds of high-resolution digital camera images
Process steps include point-to-raster conversion, Laplacian of Gaussian (LoG) filter, spatial image registration based on non-reflective similarity, and point cloud densification
Summary
Recent photogrammetric applications which use Unmanned Aerial Systems (UAS) equipped with special sensors such as lightweight thermal and multi-spectral cameras provide three dimensional models in non-visible electromagnetic spectrum besides traditional examples of high-resolution SLR digital cameras. In order to retrieve complete surfaces with high precision, dense image matching methods solutions which are based on multi-view stereo algorithms are applied (Rothermel et al, 2012; Wenzel et al, 2013). Photogrammetric processing algorithms can suffer problems due to either the initial image quality (noise, low radiometric quality, shadows and so on) or to certain surface materials (shiny or textureless objects). This can result in noisy point clouds and/or difficulties in feature extraction (Remondino et al 2014). Dense point clouds which are generated with photogrammetric method using a lightweight thermal camera, are more noisy and sparse than the point clouds of high-resolution digital camera images. A data fusion was implemented to improve thermal point cloud
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