Abstract: Described herein is a method for identifying an interference pigment in a coating. Also described herein is a corresponding device and a computer-readable medium.

Abstract: Disclosed herein are retroreflective pigments and paints including the retroreflective pigments.

Abstract: Disclosed herein are coatings having enhanced reflectivity for electromagnetic radiation, as well as a process for producing the coatings.

Abstract: Disclosed herein is a computer-implemented method for generating a coating formulation that yields a coating which is, to the eye of a human observer, identical or substantially similar in appearance to a target coating, as well as a device for performing the method.

Abstract: Described herein is a computer-implemented method for simulating texture features of a n-layer target coating, the method including at least the steps of: a) providing known real geometrical properties and known individual ingredients with known real material properties; b) modelling the n-layer target coating in a virtual environment; c) virtually tracing rays of light from one or more light sources towards an aim region defined on a surface of the n-layer target coating; d) virtually collecting rays of light that interacted with the n-layer target coating; e) virtually determining, at least one of an angular, a spectral and a spatial distribution of intensity of the rays of light re-emitted from or reflected by the n-layer target coating; and f) evaluating the determined distribution(s) of intensity and outputting, by an output device, at least one image based on the evaluation.

Abstract: Described herein is a method for generating a bi-directional texture function (BTF) of an object, the method including at least the following steps: measuring an initial BTF for the object using a camera-based measurement device, capturing spectral reflectance data for the object for a pre-given number of different measurement geometries using a spectrophotometer, and adapting the initial BTF to the captured spectral reflectance data), thus, gaining an optimized BTF. Also described herein are respective systems for generating a bi-directional texture function of an object.

Abstract: Described herein is a method for identifying an interference pigment in a coating. Also described herein is a corresponding device and a computer-readable medium.

Abstract: Described herein is a method for simulating a visibility of a coating applied on a surface for a LiDAR sensor, which includes at least the following steps: applying the coating on the surface (301); measuring a respective reflection of light having an operating wavelength of the LiDAR sensor from the surface coated with the coating at a multiplicity of illumination and/or measurement angles (302); adapting a bidirectional reflectance distribution function for the coating as a function of the respective illumination and/or measurement angle to the respective measured reflections (303); simulating a propagation of the light emitted by the LiDAR sensor and reflected by the surface coated with the coating on the basis of the adapted bidirectional reflectance distribution function by means of a ray tracing application (304); outputting a brightness image.

Abstract: In a process for recognizing organic substances in solids by measuring the spectram of the radiation which is reflected or transmitted, radiation with a wavelength between 2-4 &mgr;m is used and, for radiation of solids, unmodulated radiation is used. The radiation source should have an output of at least 50 W and the distance between the illumination optics from the solid being investigated should be at least 10 cm. Recognition is based on absorption bands of the extended oscillations of C—H bonds and sometimes the presence of absorption bands of N—H bonds. Broad band radiation is preferable for radiation of the solids, and the reflected or transmitted radiation is directed through a narrow band filter with adjustable transmission frequency. This can be advantageously formed with an acousto-optical filter.

Abstract: There are proposed a method and a device for ascertaining the surface condition, particularly of traffic routes, as regards dryness, wetness or icing, in which the surface is irradiated by a radiation source with an infrared component, and the reflected radiation is measured simultaneously in different wavelength ranges characterizing water and ice. In this case at least four wavelength ranges are selected, permitting sufficient depth or penetration of the radiation into the surface. A first and a second wavelength range are so selected that they are influenced to a very small degree by absorption of the water molecules, and a third and fourth wavelength ranges are so selected that they are characteristic for water and ice. The influence of the background on signals measured in the third and fourth wavelength ranges is compensated for by means of the information in the signals measured in the first and second wavelength ranges.