The influence of the incident angles variation on the accuracy of TLS point cloud based on surface reflectivity and roughness

B. Mala, Dleen Al-shrafany
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Abstract

The accuracy of measuring TLS point clouds depends on the measuring travel time, range detector, and surface properties. TLS conducted interesting experimental tests to examine the effect of different scanned materials in terms of reflectivity and surface roughness on the quality of the measured TLS data at different incident angles. Different types of materials specifically (wood, glass, steel, Ekoplast, and adhesive total station target) were selected for this purpose. During the experiments, 24 scans were measured as the selected four materials scanned at six incident angles (0˚, 15˚, 30˚, 45˚, 60˚, and 75˚) while the range was fixed to about 5m. The experiment’s results reveal that smooth surfaces are more highly affected by the accuracy of the measured 3D point clouds than rough surfaces at different incident angles. At 0˚ incident angle, the total station target reflects about 20cm closer to the scanner than the other materials; this difference decreases with increasing incident angle. At 75˚ incidence angle, the difference decreases to become approximately 2mm in comparison to the other materials. The maximum RMSE of rough materials is less than 1cm except for wood material at 30˚, while the Maximum RMSE for smooth materials reaches 4cm in 45˚ glass material. Furthermore, different materials have different intensities, both smooth materials, glass and steel, have different levels of accuracy due to different properties. The minimum RMSE in glass is 1.47cm, and the maximum RMSE for steel reaches 1.17cm.
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入射角变化对基于表面反射率和粗糙度的 TLS 点云精度的影响
测量 TLS 点云的精度取决于测量行程时间、测距探测器和表面特性。TLS 进行了有趣的实验测试,以研究不同扫描材料的反射率和表面粗糙度对不同入射角度下 TLS 测量数据质量的影响。为此专门选择了不同类型的材料(木材、玻璃、钢材、Ekoplast 和粘合剂全站仪目标)。在实验过程中,选定的四种材料在六个入射角度(0˚、15˚、30˚、45˚、60˚和 75˚)下进行了 24 次扫描,扫描范围固定在 5 米左右。实验结果表明,在不同的入射角度下,光滑表面比粗糙表面更容易受到三维点云测量精度的影响。在入射角为 0˚ 时,全站仪的目标比其他材料的目标更靠近扫描仪约 20 厘米;随着入射角的增大,这一差异会减小。在入射角为 75˚ 时,与其他材料相比,差异减小到约 2 毫米。除 30˚ 入射角的木质材料外,粗糙材料的最大均方根误差小于 1 厘米,而光滑材料的最大均方根误差在 45˚ 玻璃材料中达到 4 厘米。此外,不同的材料具有不同的强度,光滑材料、玻璃和钢材都因其不同的性质而具有不同的精度。玻璃的最小均方根误差为 1.47 厘米,钢的最大均方根误差为 1.17 厘米。
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