Abstract
The intensity value recorded by terrestrial laser scanning (TLS) systems is significantly influenced by the incidence angle. The incidence angle effect is an object property, which is mainly related to target scattering properties, surface structures, and even some instrumental effects. Most existing models focus on diffuse reflections of rough surfaces and ignore specular reflections, despite that both reflections simultaneously exist in all natural surfaces. Due to the coincidence of the emitter and receiver in TLS, specular reflections can be ignored at large incidence angles. On the contrary, at small incidence angles, TLS detectors can receive a portion of specular reflections. The received specular reflections can trigger highlight phenomenon (hot-spot effects) in the intensity data of the scanned targets, particularly those with a relatively smooth or highly-reflective surface. In this study, a new method that takes diffuse and specular reflections, as well as the instrumental effects into consideration, is proposed to eliminate the specular reflection effects in TLS intensity data. Diffuse reflections and instrumental effects are modeled by a polynomial based on Lambertian reference targets, whereas specular reflections are modeled by the Phong model. The proposed method is tested and validated on different targets scanned by the Faro Focus3D 120 terrestrial scanner. Results imply that the coefficient of variation of the intensity data from a homogeneous surface is reduced by approximately 38% when specular reflections are considered. Compared with existing methods, the proposed method exhibits good feasibility and high accuracy in eliminating the specular reflection effects for intensity image interpretation and 3D point cloud representation by intensity.
Highlights
Terrestrial laser scanning (TLS) is a powerful technique for the spatial data acquisition and Remote Sens. 2017, 9, 853; doi:10.3390/rs9080853 www.mdpi.com/journal/remotesensingRemote Sens. 2017, 9, 853 and shadowing [5], is initially used to improve point cloud separability
Diffuse reflections and instrumental effects are modeled by a polynomial based on Lambertian reference targets, whereas specular reflections are modeled by the Phong model
This study presents a new method to eliminate the specular reflection effects in the intensity data of smooth surfaces
Summary
Terrestrial laser scanning (TLS) is a powerful technique for the spatial data acquisition and Remote Sens. 2017, 9, 853; doi:10.3390/rs9080853 www.mdpi.com/journal/remotesensingRemote Sens. 2017, 9, 853 and shadowing [5], is initially used to improve point cloud separability. Terrestrial laser scanning (TLS) is a powerful technique for the spatial data acquisition and Remote Sens. Many confounding variables distort the capability of the original intensity to directly retrieve the target characteristics, of which the instrumental mechanism, atmospheric conditions, target surface properties, and data acquisition geometry plays a significant and dominant role [17,18]. The intensity data recorded by the same TLS system are predominantly influenced by the target reflectance, distance, and incidence angle [19]. A number of studies have been successfully conducted to derive a corrected intensity that is merely related to the scattering properties of the scanned target by correcting the effects of incidence angle and distance. The irregular TLS distance effect is strongly dominated by instrumental factors (e.g., aperture size, automatic gain control, amplifier for low-reflective surfaces, and a brightness reducer for near distances [1]) and differs significantly among different systems
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