An illumination device for an optical device, a microscope or a macroscope includes a first illumination source configured to emit light which is directed via an illumination beam path onto an object to be illuminated that is arranged in an object plane. At least one second illumination source is positionable in the illumination beam path, and is transparent or semitransparent as well as self-luminous. The at least one second illumination source is configured to allow light emitted from the first illumination source to pass through at least in part. The object plane having the object to be illuminated is configured to be illuminated both by the first and by the at least one second illumination source.

An optical particle sensor includes-at least one light source configured to emit light rays; at least one channel intended to receive a fluid transporting at least one particle, and to at least partially receive the light rays emitted by the at least one source such that said light rays are partially scattered by the at least one particle; and at least one photodetector capable of receiving said scattered light rays. The at least one source has an emission face facing one side of the sensor and the at least one photodetector has a receiving face facing the same side of the sensor, wherein the light rays received by the at least one photodetector are light rays backscattered by the at least one particle, for at least 90% of the light rays.

The invention relates to a sensor module (1) for multiparametric analysis of a medium (105) and to the uses thereof. The sensor module (1) according to the invention is characterised by a combination of photonic and non-photonic measurement principles with parameter-sensitive coatings (103) on a substrate (100). A plurality of properties of a medium (105) can be detected over wide parameter ranges, wherein the most suitable method can be used for the corresponding parameter, at least for example with regard to the accuracy, the long-term stability, the resolution, the reproducibility, the energy consumption, the manufacturing costs, the necessary space requirements.

A method for real-time surface imperfection detection for additive manufacturing and 3-D printing parts is provided. The method includes directing a first light radiation using one or more illumination sources, wherein the first light radiation illuminates a target area of a part being manufactured in a uniform chromatic light such that the target area appears to have a substantially uniform monochromatic color; capturing a current image of a second light radiation that is scattered or reflected by the target area using one or more feedback cameras; and analyzing the current image of the second light radiation using at least one of the one or more feedback camera with a previously acquired image to determine whether a surface imperfection exists or does not exist.

The invention relates to a sensor module (1) for multiparametric analysis of a medium (105) and to the uses thereof. The sensor module (1) according to the invention is characterised by a combination of photonic and non-photonic measurement principles with parameter-sensitive coatings (103) on a substrate (100). A plurality of properties of a medium (105) can be detected over wide parameter ranges, wherein the most suitable method can be used for the corresponding parameter, at least for example with regard to the accuracy, the long-term stability, the resolution, the reproducibility, the energy consumption, the manufacturing costs, the necessary space requirements.

A method for real-time surface imperfection detection for additive manufacturing and 3-D printing parts is provided. The method includes directing a first light radiation using one or more illumination sources, wherein the first light radiation illuminates a target area of a part being manufactured in a uniform chromatic light such that the target area appears to have a substantially uniform monochromatic color; capturing a current image of a second light radiation that is scattered or reflected by the target area using one or more feedback cameras; and analyzing the current image of the second light radiation using at least one of the one or more feedback camera with a previously acquired image to determine whether a surface imperfection exists or does not exist.

A sensor device configured to be attached to a drug delivery device and configured to illuminate the drug delivery device when attached, the sensor device having an OLED having a transparent first electrode, a transparent second electrode and a central layer disposed between the first and second electrodes, the central layer comprising at least one organic layer, the at least one organic layer configured to emit light through the transparent first electrode, and an optical sensor arranged to receive light reflected from a surface of the drug delivery device, wherein the central layer of the OLED has a region without the at least one organic layer and wherein the optical sensor is arranged, when the sensor device is attached to the drug delivery device, to view a predetermined area of the surface of the drug delivery device through the region without the at least one organic layer.

A method involves determining a first initial state parameter with information about prior damage to the hair and a second initial state parameter with information about a hair color. The method further involves determining the initial colour state of the hair to be dyed for the hair region and computer-assisted determination, for a particular hair dye, of a forecast hair colouring result for the hair in the hair region, taking into consideration the determined initial colour state of the hair.

A device for optically exciting fluorescence is disclosed. The device comprises transparent substrate having first and second opposite faces and a multilayer stack disposed on the second face of the substrate. The multilayer stack comprises a first layer having first and second opposite faces and a first refractive index and a second layer having first and second opposite faces and a second refractive index. The first face of the first layer is disposed on the second face of the substrate. The first face of the second layer is disposed on the second face of the first layer such that the first layer is interposed between the second layer and the substrate. The substrate has a third refractive index. The first refractive index is less than the second refractive index and the third refractive index. The device comprises a light source carried by the first face of the substrate and arranged to emit light towards the first face of the first layer.

A device for exciting objects with an excitation radiation and for detecting a photoluminescence radiation emitted by the objects after the absorption of the excitation radiation. The device includes a wall in contact with the objects, an organic light-emitting diode for emitting the excitation radiation and transparent to the photoluminescence radiation, an optical resonator tuned to the wavelength of the photoluminescence radiation and located on the side of the organic light-emitting diode opposite to the wall, and at least one sensor of the photoluminescence radiation arranged on the side of the optical resonator opposite to the organic light-emitting diode.