Abstract: Described herein is a spectral sensing device that includes at least one photosensitive detector, where the at least one photosensitive detector has at least one photosensitive region designated for receiving optical radiation, where at least one detector signal as generated by the at least one photosensitive detector is dependent on an illumination of the at least one photosensitive region; at least one radiation emitting element; at least one optical element; and at least one evaluation unit, where the at least one evaluation unit is configured to perform a calibration of the spectral sensing device by using at least one first detector signal as generated by the at least one photosensitive detector upon the illumination of the at least one photosensitive region by a first portion of the optical radiation. Also described herein is a method for measuring optical radiation with a spectral sensing device.

Abstract: The invention relates to a recognizable carrier for determining physical, chemical or biochemical interactions by means of optical measurement methods. The carrier comprises a surface that defines a substrate surface and that has a base layer coated with reactive elements, which are bonded to receptor molecules, wherein the base layer and/or the reactive elements are provided with a pattern of holes which forms a code and/or the reactive elements are provided with linker molecules or markers which form a code. The substrate surface may additionally have a macroscopically planar pattern which is applied using laser light or chemical etching and forms a code. The invention likewise relates to a method for producing a recognizable carrier for spectroscopic processes and/or intensiometric tests to determine said interactions. The code to recognize the carrier can be controlled via a read-out unit coupled to the photometric analysis unit.

Abstract: In a method for determining optical properties by measuring intensities at a thin layer, light is directed into the thin layer and passes through a beam splitter, which directs a first part of the light onto the thin layer and a second part of the light onto a reference detector. Interference of the first part of the light in the thin layer is detected via a high-resolution detector and forwarded to an evaluating unit, which determines the reflection and/or transmission coefficients, which are correlated with the optical layer thickness through a comparison using at least one database stored in the evaluating unit. The optical layer thickness is obtained as a gray value modification by way of a gray scale value analysis and a conversion factor stored in the at least one data base. A corresponding device and intended uses of the method and device are also described.

Abstract: The invention relates to a method for determining optical properties by measuring intensities on a thin layer, wherein light is irradiated onto a carrier (105) that has said thin layer and that is at least partially transparent. Interferences on the at least one thin layer are measured as the relative intensity of at least one superpositioned wave, optionally using filter arrangements (113, 115, 117) provided for this purpose, whereupon the reflection coefficient(s) and/or the transmission coefficient(s) from the reflection and/or the transmission on the thin layer are determined. Preferably, the intensity of at least two superpositioned waves is measured. The light may be irradiated directly onto the carrier. The invention also relates to a device for determining optical properties by measuring intensities on a thin layer, said device comprising an analysis unit which stores at least one lookup table. The method and the device are preferably used in the area of homeland security.

Abstract: In a method for determining optical properties by measuring intensities at a thin layer, light is directed into the thin layer and passes through a beam splitter, which directs a first part of the light onto the thin layer and a second part of the light onto a reference detector. Interference of the first part of the light in the thin layer is detected via a high-resolution detector and forwarded to an evaluating unit, which determines the reflection and/or transmission coefficients, which are correlated with the optical layer thickness through a comparison using at least one database stored in the evaluating unit. The optical layer thickness is obtained as a gray value modification by way of a gray scale value analysis and a conversion factor stored in the at least one data base. A corresponding device and intended uses of the method and device are also described.

Abstract: A head set includes a cable winding device arranged in the housing for winding cables on both sides in a spring-supported manner, the cable winding device having at least one locking device, and including a microphone and at least one earphone or headphone, with the cable winding device including two take-up reels connected to each other in a rotationally fixed manner, and the take-up reels having different diameters. The microphone is arranged on the housing and it is connected to one of the take-up reels in a rotationally fixed manner and is rotatably supported relative to the housing.

Abstract: The invention relates to a carrier for a thin layer and a method for the analysis of molecular interactions on and/or in such a thin layer. A thin layer disposed on a carrier is illuminated with electromagnetic radiation from at least one radiation source and a reflected radiation part on boundary surfaces of the thin layer is detected by means of an optoelectronic converter that converts the detected radiation into a frequency- and intensity-dependant photocurrent. A reading voltage is applied to the optoelectronic converter. By changing the reading voltage, the spectral sensitivity of the optoelectronic converter is varied such that a substantially constant photocurrent is obtained. Alternatively or in addition to varying the spectral sensitivity by changing the reading voltage, the reflected radiation part is detected with an optoelectronic converter that is designed as a sensor layer in the carrier.

Abstract: The invention relates to a method for determining optical properties by measuring intensities on a thin layer, wherein light is irradiated onto a carrier (105) that has said thin layer and that is at least partially transparent. Interferences on the at least one thin layer are measured as the relative intensity of at least one superpositioned wave, optionally using filter arrangements (113, 115, 117) provided for this purpose, whereupon the reflection coefficient(s) and/or the transmission coefficient(s) from the reflection and/or the transmission on the thin layer are determined. Preferably, the intensity of at least two superpositioned waves is measured. The light may be irradiated directly onto the carrier. The invention also relates to a device for determining optical properties by measuring intensities on a thin layer, said device comprising an analysis unit which stores at least one lookup table. The method and the device are preferably used in the area of homeland security.

Abstract: The invention relates to a recognizable carrier for determining physical, chemical or biochemical interactions by means of optical measurement methods. The carrier comprises a surface that defines a substrate surface and that has a base layer coated with reactive elements, which are bonded to receptor molecules, wherein the base layer and/or the reactive elements are provided with a pattern of holes which forms a code and/or the reactive elements are provided with linker molecules or markers which form a code. The substrate surface may additionally have a macroscopically planar pattern which is applied using laser light or chemical etching and forms a code. The invention likewise relates to a method for producing a recognizable carrier for spectroscopic processes and/or intensiometric tests to determine said interactions. The code to recognize the carrier can be controlled via a read-out unit coupled to the photometric analysis unit.

Abstract: The invention relates to a carrier for a thin layer and a method for the analysis of molecular interactions on and/or in such a thin layer. A thin layer disposed on a carrier is illuminated with electromagnetic radiation from at least one radiation source and a reflected radiation part on boundary surfaces of the thin layer is detected by means of an optoelectronic converter that converts the detected radiation into a frequency- and intensity-dependant photocurrent. A reading voltage is applied to the optoelectronic converter. By changing the reading voltage, the spectral sensitivity of the optoelectronic converter is varied such that a substantially constant photocurrent is obtained. Alternatively or in addition to varying the spectral sensitivity by changing the reading voltage, the reflected radiation part is detected with an optoelectronic converter that is designed as a sensor layer in the carrier.