Abstract: A simple optical projection device with a high luminous efficacy has a point light source, a projection screen, a mask that is arranged in the light path upstream of the projection screen and is light-transmissive in some areas, and a light focusing optical lens arranged between the point light source and the mask. The optical lens is selected such that the prolongations of the emerging beams of the optical lens on the side thereof facing the point light source intersect in a virtual perspective center which is more remote from the lens than the point light source.

Abstract: In a method of determining a position of a touch on a capacitive sensor field having a grid of a plurality of discrete electrodes (12), contacted electrodes are determined by measuring a capacitance value for each of the electrodes and by checking for each of the electrodes for the measured capacitance value whether this value is above a predefined threshold value. A rough touch position (Bg) is calculated by weighting the electrode position with the measured capacitance value. A touch diameter (14) is calculated from the measured capacitance values, and a final touch position (Be) is calculated from the rough touch position (Bg) and the calculated touch diameter (14) using a value table in which correction values that were determined empirically or by means of simulation are stored for possible rough touch positions (Bg) and given touch diameters (14).

Abstract: A proximity sensor (12) is provided which comprises a magnet (16) and a sensor (18). The sensor (18) is aligned relative to the magnet (16) in such a manner that the direction (E) of maximum sensitivity of the sensor (18) is formed so as to be substantially parallel to the magnet axis (M) extending through the poles (20, 22) of the magnet (16). Further, an assembly unit (10) is provided.

Abstract: A capacitive rotary encoder has a stator and a rotor as well as stator electrodes firmly arranged at the stator on an encoding path coaxial to the rotor axis, and coupling electrodes arranged at the rotor. The coupling electrodes are guided over the stator electrodes at a small axial distance from the encoding path by rotation of the rotor, wherein they each cover stator electrodes adjacent in the peripheral direction and connect the latter capacitively to each other. Interrogation electronics detects for each of the stator electrodes a capacitive coupling with an adjacent stator electrode caused by a coupling electrode of the rotor. This permits the reliable detection of the angular position of the rotor both statically and dynamically.

Abstract: A symbol display element for a vehicle interior is proposed, which comprises a front cover formed by a diffusing lens. A shadow mask is arranged in the optical path between the diffusing lens and a plurality of point light sources which can be activated separately, and includes for each point light source an associated symbol which is projected in an enlarged manner onto the rear side of the diffusing lens upon activation of the corresponding point light source. With this easily realizable configuration of the display element, the different symbols share a common display surface on the diffusing lens which acts as a rear projection screen.

Abstract: A position sensor for the inductive detection of a position of a first component comprising a reference coil with respect to a second component comprising a reference body. A control and processing unit of the position sensor is coupled to the reference coil and is designed for issuing an output signal generating a current impulse in the reference coil. In addition, the control and processing unit is designed for evaluation of an oscillation generated by the current impulse in the reference coil as an input signal indicating the position of the reference body.

Abstract: There is provided a radiation detection means (10) which includes a carrier (12) with at least one pivotable portion (16), a receiving unit (18), a drive (24) and an evaluation and control unit. The receiving unit (18) is arranged on the pivotable portion (18) which together with the receiving unit (18) is pivotable about at least one axis relative to the carrier (12). The evaluation and control unit is connected with the drive (24) and the receiving unit (18) and the drive (24) is associated to the pivotable portion (16).

Abstract: In a method of controlling an interior lighting (25) in a vehicle (18), having a plurality of separately drivable lamps (26a-26g), provision is made that a motion light pattern, in particular a wave light pattern, is generated as a function of vehicle operating data by separately driving the individual lamps (26a-26g), the vehicle operating data including ambient data picked up by means of a light sensor.

Abstract: In a method of controlling an interior lighting (25) in a vehicle (18), having a plurality of separately drivable lamps (26a-26g), provision is made that a motion light pattern, in particular a wave light pattern, is generated as a function of vehicle operating data by separately driving the individual lamps (26a-26g), all of the lamps (26a-28g) being driven with an identical or similar light pattern, and the lamps (26a-26g) being driven with the light pattern offset in time. The time offset with which the lamps (26a-26g) are driven is dependent on the driving speed of the vehicle.

Abstract: A capacitive sensor (20) includes a capacitive sensor field (2), the capacitive sensor field (2) having a plurality of discrete electrodes (4) which are coupled to discrete leads (8). The leads (8) of a first electrode (41) are guided such that they are capacitively coupled with at least one second electrode (42). A first signal (Cm1) is detected at a first lead (8) which is coupled with the first electrode (41), and a second signal (Cm2) is detected at a second lead (8) which is coupled with a second electrode (42). The capacity (Cf1, Cf2) of the first electrode (41) or of the second electrode (42) is determined using a predetermined calculation formula which takes the first signal (Cm1), the second signal (Cm2) and the capacitive coupling between the second electrode (4) and the first lead (8) coupled with the first electrode (41) into account.

Abstract: In a method of determining a position of a touch on a capacitive sensor field having a grid of a plurality of discrete electrodes (12), contacted electrodes are determined by measuring a capacitance value for each of the electrodes and by checking for each of the electrodes for the measured capacitance value whether this value is above a predefined threshold value. A rough touch position (Bg) is calculated by weighting the electrode position with the measured capacitance value. A touch diameter (14) is calculated from the measured capacitance values, and a final touch position (Be) is calculated from the rough touch position (Bg) and the calculated touch diameter (14) using a value table in which correction values that were determined empirically or by means of simulation are stored for possible rough touch positions (Bg) and given touch diameters (14).

Abstract: A simple optical projection device with a high luminous efficacy has a point light source, a projection screen, a mask that is arranged in the light path upstream of the projection screen and is light-transmissive in some areas, and a light focusing optical lens arranged between the point light source and the mask. The optical lens is selected such that the prolongations of the emerging beams of the optical lens on the side thereof facing the point light source intersect in a virtual perspective center which is more remote from the lens than the point light source.

Abstract: A capacitive rotary encoder has a stator and a rotor as well as stator electrodes firmly arranged at the stator on an encoding path coaxial to the rotor axis, and coupling electrodes arranged at the rotor. The coupling electrodes are guided over the stator electrodes at a small axial distance from the encoding path by rotation of the rotor, wherein they each cover stator electrodes adjacent in the peripheral direction and connect the latter capacitively to each other. Interrogation electronics detects for each of the stator electrodes a capacitive coupling with an adjacent stator electrode caused by a coupling electrode of the rotor. This permits the reliable detection of the angular position of the rotor both statically and dynamically.

Abstract: An electrodynamic actuator (10), has a flat coil (24) formed by tracks (22, 23) on a face of a circuit board (16) and a permanent magnet (14) the magnetic field of which passes through turns of the flat coil (24).

Abstract: A position sensor for the inductive detection of a position of a first component comprising a reference coil with respect to a second component comprising a reference body. A control and processing unit of the position sensor is coupled to the reference coil and is designed for issuing an output signal generating a current impulse in the reference coil. In addition, the control and processing unit is designed for evaluation of an oscillation generated by the current impulse in the reference coil as an input signal indicating the position of the reference body.

Abstract: An optical sensor has an optical plate which is adapted to make surface contact on a pane, in particular a windshield of a motor vehicle. It further has one or preferably a plurality of photoreceivers arranged on the side of the optical plate facing away from the pane. An optical mask is arranged in the optical path upstream of each photoreceiver, the optical mask having light-blocking and light-transmissive surface areas. The light-transmissive surface areas each allow an optical path to traverse the optical plate, impinging on the photoreceiver and is delimited by the light-blocking surface areas.

Abstract: An optical display and control element comprises an at least partially transparent display screen, at least one light source for illuminating a rear side of the display screen, and at least one light sensor for detecting a temporal signal of the light scattered on the display screen. The light source is able to produce a time-variable light pattern while illuminating the rear side of the display screen. A control and processing unit is able to evaluate the temporal signal, detected by the light sensor, in combination with the time-variable light pattern and to determine a position of at least one object located on the display screen from this evaluation. The invention further relates to a method of optically determining the position of an object which is located on an at least partially transparent display screen of an optical display and control element.

Abstract: An optical sensor device for the detection of ambient light is adapted to be coupled to a pane (10), in particular to a windshield of a vehicle. The optical sensor device has a sensor unit which includes at least one light receiver (22) for ambient light and a lens plate (12) for directionally coupling an ambient light beam (26) out of the pane (10) onto the light receiver (22). The lens plate (12) has a surface (18) facing the light receiver (22) and oriented substantially parallel to the pane (10) in the coupled condition of the optical sensor device. The surface (18) includes a prism structure (20) having a plurality of single prisms (24) which are designed to direct the rays of a specific ambient light beam (26) defined by a principal direction (A) and an aperture angle onto the light receiver (22).

Abstract: An input device (10) has a contact plate (12) having a contact surface (14) and being least partially coated with an electrical resistive layer (16) on a surface opposite the contact surface (14). The electrical resistive layer (16) has at least two electrically conducting contacts (18). A measuring circuit (20) is provided for measuring a sensing capacitor (24) formed by the electrical resistive layer (16) and an electrostatically chargeable object (22) arranged at a contact position on the contact surface (14). Further, a processing unit is provided for determining coordinates (X, Y) of the contact position of the electrostatically chargeable object (22) on the contact surface (14) by means of a determination of the ohmic resistances (Rn) between the contact position of the electrostatically chargeable object (22) and the electrically conducting contacts.

Abstract: An optical sensor device has a sensor unit which includes a light emitter (24), a light receiver (26), and a lens plate (12) that is used for coupling a pencil of rays, radiated by the light emitter (24), into and out of the pane and directing it onto the light receiver (26). The lens plate (12) includes a combined Fresnel structure (16a, 16b) having a Fresnel lens structure (18a, 18b) and a Fresnel reflector structure (20a, 20b) on a first surface (12a) facing the light emitter (24) and the light receiver (26), and a Fresnel reflector structure (22a, 22b) on an opposite, second surface (12b) facing the pane. This configuration is especially suitable for use as a rain sensor. Without the light emitter the sensor device is suitable to be used as a light sensor.