Abstract: A mobile microprojector is provided to include at least one deflectable micromirror for scanning a projection surface with the aid of a light beam, as well as a control unit for controlling the movements of the micromirror, the control unit being configured to effectuate at least one deflection of the micromirror via a first amplitude in a first operating state for scanning the projection surface. The control unit is configured to effectuate the deflection of the micromirror via a second amplitude in a second operating state, the second amplitude being smaller than the first amplitude.

Abstract: An infrared sensor device includes a semiconductor substrate, at least one sensor element that is micromechanically formed in the semiconductor substrate, and at least one calibration element, which is micromechanically formed in the semiconductor substrate, for the sensor element. An absorber material is arranged on the semiconductor substrate in the area of the sensor element and the calibration element. One cavern each is formed in the semiconductor substrate substantially below the sensor element and substantially below the calibration element. The sensor element and the calibration element are thermally and electrically isolated from the rest of the semiconductor substrate by the caverns. The infrared sensor device has high sensitivity, calibration functionality for the sensor element, and a high signal-to-noise ratio.

Abstract: An infrared sensor device includes at least one sensor element formed in a semiconductor substrate, an SOI wafer that defines a gap below and around the sensor element, and a suspension device that is configured to suspend the sensor element in the SOI wafer. The sensor element is substantially arranged below the suspension device, thereby achieving a high sensitivity, low thermal capacity, low thermal coupling to the substrate and a high image refresh rate.

Abstract: A sensor arrangement includes an infrared sensor and at least one acceleration sensor. The infrared sensor is configured to detect infrared radiation, and to output infrared image data. The at least one acceleration sensor is configured to detect an instantaneous acceleration of the sensor arrangement, and to output acceleration data. The output of the infrared image data from the infrared sensor is blocked when the instantaneous acceleration of the sensor arrangement exceeds a preprogrammed threshold value.

Abstract: A measurement bridge circuit includes a first branch and a second branch. The first branch contains a first resistor which is sensitive to measured variables and an invariable resistor connected in series. A first tap point is located between the first resistor and the invariable resistor. The second branch contains a second resistor which is sensitive to measured variables and a variable resistor arrangement connected in series. The variable resistor arrangement includes a first component having an invariable electrical resistance value and a second component having a variable electrical resistance value. The second component is connected in parallel with the first component in order to vary a total electrical resistance value for the variable resistor arrangement. A second tap point is located between the second resistor and the variable resistor arrangement.

Abstract: An image pixel apparatus for detecting electromagnetic radiation includes an absorption structure device configured to absorb the electromagnetic radiation and to take it up as a quantity of heat. At least one plasmonic resonance structure device of the apparatus is configured to forward the electromagnetic radiation to the absorption structure device. A detection device that has at least one detection element is configured to detect the electromagnetic radiation by way of changes in an electrical property of the at least one detection element that are caused by the quantity of heat taken up.

Abstract: A sensor system has a first sensor-element block and a second sensor-element block, at least one first sensor element and one second sensor element are assigned to the first sensor-element block, and at least one third sensor element is assigned to the second sensor-element block. The third sensor element is situated between the first and second sensor elements.

Abstract: A micro-structured reference element for use in a sensor having a substrate and a dielectric membrane. The reference element has an electrical property which changes its value on the basis of temperature. The reference element is arranged with respect to the substrate so that the reference element is (i) electrically insulated from the substrate, and (ii) thermally coupled to the substrate. The reference element is arranged on the underside of the dielectric membrane. The reference element and side walls of the substrate define a circumferential cavern therebetween, which is also bounded by the dielectric membrane, arranged between them. The dielectric membrane is connected to the substrate. A surface area of the reference element which is covered by the dielectric membrane is greater than or equal to 10% and less than or equal to 100% of the possible coverable surface area.

Abstract: A micro-structured reference element for use in a sensor having a substrate and a dielectric membrane. The reference element has an electrical property which changes its value on the basis of temperature. The reference element is arranged with respect to the substrate so that the reference element is (i) electrically insulated from the substrate, and (ii) thermally coupled to the substrate. The reference element is arranged on the underside of the dielectric membrane. The reference element and side walls of the substrate define a circumferential cavern therebetween, which is also bounded by the dielectric membrane, arranged between them. The dielectric membrane is connected to the substrate. A surface area of the reference element which is covered by the dielectric membrane is greater than or equal to 10% and less than or equal to 100% of the possible coverable surface area.

Abstract: The present invention relates to a method for providing a one- or multipart torsion element of a torque sensor with at least one magnetic encoding by applying at least one current pulse to the torsion element. It is provided that the variation of the current pulse over time is formed. Moreover, the present invention relates to a device for providing a one- or multipart torsion element of a torque sensor with at least one magnetic encoding.

Abstract: A machine tool safety device has a recognition unit which is provided for recognizing an application situation for a machine tool. The recognition unit includes an imaging unit for monitoring a first safety range, and a sensor unit, which is different from the imaging unit, for monitoring a second safety range.

Abstract: A machine tool, e.g., a sawing machine, has a work surface for placing a workpiece to be machined, and a tool support unit for supporting a tool, the unit being supported movably relative to the work surface. The machine tool includes a tool operation monitoring device for monitoring a tool range at least during a tool operation, which monitoring device includes an imaging unit.

Abstract: A micromechanical component and a corresponding production method. The micromechanical component includes a first component and a second component, with which the first component is connected by an alloy region; the first and second components enclosing a vacuum region or residual gas region, which is sealed by the alloy region.

Abstract: A sensor system has a first sensor-element block and a second sensor-element block, at least one first sensor element and one second sensor element are assigned to the first sensor-element block, and at least one third sensor element is assigned to the second sensor-element block. The third sensor element is situated between the first and second sensor elements.

Abstract: A magnetic sensor system (1) is provided that contains sensor elements (5, 6) that are sensitive to magnetic fields, the electrical properties of said sensor elements being modifiable according to a magnetic field that can be influenced by a mobile, passive transmitter element (8). The magnetic sensor system (1) includes two sensor elements (5, 6) in a gradiometer system, each of which is assigned to one of two permanent magnets (2, 3) having a predetermined separation. In terms of their dimensions, separation and position relative to the sensor elements (5, 6), the permanent magnets (2, 3) are located such that the offset of the output signal of the sensor elements (5, 6) is minimized in the gradiometer system.

Abstract: A GMR sensor element is proposed, having a rotationally symmetrical positioning of especially eight GMR resistor elements which are connected to each other to form two Wheatstone's full bridges. This GMR sensor element is especially suitable for use in an angle sensor for the detection of the absolute position of the camshaft or the crankshaft in a motor vehicle, particularly in the case of a camshaft-free engine having electrical or electrohydraulic valve timing, of a motor position of an electrically commutated motor, or of detection of a windshield wiper position, or in the steering angle sensor system in motor vehicles.

Abstract: A magnetic sensor system (1) is provided that contains sensor elements (5, 6) that are sensitive to magnetic fields, the electrical properties of said sensor elements being modifiable according to a magnetic field that can be influenced by a mobile, passive transmitter element (8). The magnetic sensor system (1) includes two sensor elements (5, 6) in a gradiometer system, each of which is assigned to one of two permanent magnets (2, 3) having a predetermined separation. In terms of their dimensions, separation and position relative to the sensor elements (5, 6), the permanent magnets (2, 3) are located such that the offset of the output signal of the sensor elements (5, 6) is minimized in the gradiometer system.

Abstract: A magnetoresistive sensor element is provided, having a magnetoresistive layer system which, in top view, is at least regionally striated. The sensor element operates on the basis of the GMR effect and is constructed according to the spin valve principle, the striated layer system featuring a reference layer having a direction of magnetization substantially uninfluenced by a direction of an outer magnetic field acting on it. During operation, the sensor element provides a measuring signal which changes as a function of a measurement angle between the component of the field strength of the outer magnetic field lying in the plane of the layer system, and the direction of magnetization, and from which this measurement angle is able to be ascertained.

Abstract: A magnetoresistive sensor element is provided, having a magnetoresistive layer system which, in top view, is at least regionally striated. The sensor element operates on the basis of the GMR effect and is constructed according to the spin valve principle, the striated layer system featuring a reference layer having a direction of magnetization substantially uninfluenced by a direction of an outer magnetic field acting on it. During operation, the sensor element provides a measuring signal which changes as a function of a measurement angle between the component of the field strength of the outer magnetic field lying in the plane of the layer system, and the direction of magnetization, and from which this measurement angle is able to be ascertained.

Abstract: A GMR sensor element is proposed, having a rotationally symmetrical positioning of especially eight GMR resistor elements which are connected to each other to form two Wheatstone's full bridges. This GMR sensor element is especially suitable for use in an angle sensor for the detection of the absolute position of the camshaft or the crankshaft in a motor vehicle, particularly in the case of a camshaft-free engine having electrical or electrohydraulic valve timing, of a motor position of an electrically commutated motor, or of detection of a windshield wiper position, or in the steering angle sensor system in motor vehicles.