Abstract: A method for verifying the functionality of a laser scanner includes a housing with a light-permeable window, a transmission unit inside the housing, a deflection unit, and a detector unit inside the housing. At least one test signal is transmitted by the transmission unit during a test phase. The deflection unit is oriented so that the at least one test signal is not directed to the window. Components of the at least one test signal are detected by the detector unit, and based on this detection, at least two detector signals are generated. A pulse width is ascertained for each of the detector signals by a computing unit, and a ratio of the pulse width of a first detector signal to the pulse width of a second detector signal is ascertained. The operability of the transmitter unit and/or the detector unit is verified on the basis of said ratio.

Abstract: A received-signal processing apparatus of a detection device for monitoring at least one monitoring region for objects by means of electromagnetic scanning signals is disclosed. The received-signal processing apparatus has at least one frequency analysis means for the frequency analysis of electromagnetic received signals, which are determined from echo signals of electromagnetic scanning signals reflected in at least one monitoring region. The received-signal processing apparatus has a plurality of functionally parallel frequency filters having at least partially different frequency passbands. At least one frequency filter has at least one frequency labeling means, by which the passed received signal can be labeled with a frequency characteristic which characterizes the frequency passband of the at least one passage-allowing frequency filter.

Abstract: According to a method for verifying the functionality of a laser scanner (2b) comprising a housing (4) with a light-permeable window (5), a transmission unit (6) inside the housing (4), a deflection unit (10), and a detector unit (7) inside the housing (4), at least one test signal (15) is transmitted by the transmission unit (6) during a test phase. The deflection unit (10) is oriented in such a way that the at least one test signal (15) is not directed to the window (5). Components of the at least one test signal are detected by the detector unit, and based on said detection, at least two detector signals are generated. A computing unit ascertains a pulse width for each of the detector signals and calculates a sum of the pulse widths. The operability of the transmission unit and/or the detector unit is verified on the basis of said sum.

Abstract: A method for supporting a driver of a motor vehicle in a manual parking procedure of the motor vehicle in a surroundings of the motor vehicle, is disclosed. At least one indicator characterizing the parking procedure is acquired and, depending on an evaluation of the indicator, a performance of a parking procedure is recognized and, depending thereon, at least one parking-procedure-specific function of the motor vehicle is activated to support the driver during the parking procedure, wherein a performance of the parking procedure is recognized when at least a first indicator that characterizes the parking procedure in a surroundings-specific manner is acquired and if, after the acquisition of the first indicator, at least one second indicator that characterizes the parking procedure in a motor-vehicle-specific manner is acquired.

Abstract: The subject matter of the invention is a method for detecting faults related to wheels of a motor vehicle in a driving situation, comprising: —a step (S1) of automatically determining a first series of corrective steering wheel angles applied successively to force the vehicle to follow a path parallel to a first rectilinear portion of a traffic lane; —a step (S2) of automatically detecting, from the corrective steering wheel angles of the first series, the presence of a fault affecting a pair of steering wheels of the vehicle; and, optionally: —a step (S3) of estimating a type of fault associated with the detected fault, a step (S4) of identifying the steering wheel of the pair of wheels affected by the fault; and —a step (S5) of generating a warning message for the attention of the driver of the motor vehicle, the message including the estimated type of fault and the wheel identified as having the fault.

Abstract: The invention relates to a control circuit (50) for pulsed control of a light-emitting means (52), in particular an LED or a laser diode (52), having a switched-mode power supply unit (54) with a first switch (64) arranged in a primary circuit of the switched-mode power supply unit (54), wherein the switched-mode power supply unit (54) has a primary-side connector (62) for connection to a supply voltage, a secondary-side connector (67) for supplying the light-emitting means (52) and a switching input (65) for operating the first switch (64), having a storage capacitor (68) arranged between the secondary-side connector (67) and a ground (66), having a second switch (70) arranged in a current path (71) in parallel with the storage capacitor (68), wherein the light-emitting means (52) is positionable in the current path (71), and having a control unit (72) to control the first and the second switch (64, 70), wherein the control unit (72) is designed to operate the first switch (64) in order to induce at least on

Abstract: A method, apparatus, and computer-readable medium for confirming a perceived position of a traffic light, by obtaining identifiers and results of a first perception of traffic lights associated with the identifiers, the results of the first perception including a first estimation of an ellipse encompassing each of the traffic lights, receiving results of a second perception of traffic lights associated with the identifiers, the results of the second perception including a second estimation of an ellipse encompassing each of the traffic lights, calculating, based on the first perception and the second perception, association parameters for each possible pair of estimated ellipses, selecting, based on the calculated association parameters for each possible pair of estimated ellipses, matching pairs of estimated ellipses, and fusing each matching pair of estimated ellipses.

Abstract: A method for measuring lateral surroundings of a vehicle provided with a lateral ultrasonic transceiver is disclosed. The method involves actuating the ultrasonic transceiver at at least two transmission and reception positions along a lateral direction for the purpose of transmitting a respective transmission signal in a transverse direction across the direction of travel and receiving a respective received signal characteristic reflected from the lateral surroundings; identifying a number of echo signals in the respective received signal characteristic; trilaterating a bearing of a first reflection point in the lateral surroundings, from which the chronologically first echo signals in the respective received signal characteristic were reflected; selecting an echo signal for a double echo determination; and determining a height of an object as being tall if a double echo is detected or short if no double echo is detected.

Abstract: An ultrasonic measuring method involves activating an ultrasonic transceiver at a multiplicity of transmission/reception positions along a lateral direction to transmit a respective transmission signal in a transverse direction and receive a respective received signal waveform. Echo signals in the respective received signal waveform are identified and a set of reflection points are formed by trilaterating a respective reflection point multiple times based on two respective received signal waveforms and a respective echo signal from each of the two received signal waveforms. Multiple pairs made of a primary reflection point and a secondary reflection point are formed, identified on the basis of a position-based criterion as reflection points of a direct and/or indirect reflection from the same object section. An object height at one of the reflection points is characterized as high or low.

Abstract: The invention relates to an input device (1) for safety-relevant functions of a motor vehicle, having a switch contact (3) with a first connection (4) and a mating contact (5) with a second connection (6). A first resistor (9) is connected between a voltage supply connection (8) and one connection (4, 6) of the switch element (2) and a second voltage supply connection (7) is connected to the other connection (4, 6) of the switch element (2). A measuring node (10), via which an actuation-dependent voltage can be captured, is provided between the first resistor (9) and the associated connection (4, 6). The problem addressed by the invention is that of developing input devices of the type in question such that they can be used for safety-relevant applications in the motor vehicle. This problem is solved by the switch contact (3) having a third connection (12) at which a second resistor (13), which is connected to the second connection (6) of the switch element (2), is provided.

Abstract: The invention relates to a method for localizing and enhancing a digital map through a motor vehicle. The method includes receiving a digital partial map representing an environment of the motor vehicle and capturing an image of the environment of the motor vehicle by a sensor arrangement of the motor vehicle. The motor vehicle is localized in the environment by comparing the received digital partial map with the image of the environment of the motor vehicle. The digital partial map is enhanced on the basis of the image of the environment, and the enhanced digital partial map and/or the image of the environment (U) is transmitted to a database for enhancing the digital map.

Abstract: A method for operating a driver assistance system for a motor vehicle driven in an at least partially automated manner includes learning a trajectory in a learning mode for driving the vehicle in a first automated manner along the trajectory. Subsequently, the vehicle is driven in the first automated manner along the learnt trajectory in an operating mode following the learning mode. While the vehicle is being driven along the trajectory in the operating mode, at least one transition from a private area to a public area is detected. Additional data, including current traffic data related to driving the vehicle in the public area, is acquired and provided for the driver assistance system. The motor vehicle is driven along the learnt trajectory in a second automated manner in the public area using the additional data.

Abstract: The invention relates to a sensor assembly (10) for detecting rotation of a shaft about an axis of rotation (12), said sensor assembly having a housing (24) in which at least one magnetic field sensor (14) is arranged. The at least one magnetic field sensor (14) is designed to acquire a variation in a magnetic field generated by a magnet device (16) in the sensor assembly (10), which variation is associated with the rotation of the shaft about the axis of rotation (12). A shield device (30) arranged on the housing (24) is provided to shield the at least one magnetic field sensor (14) from the surroundings (28) of the sensor assembly (10). The shield device (30) can be removed from the housing (24), with the shield device (30) being retained on the housing (24) by means of a latching connection.

Abstract: An active sensor system (1) has a first and a second emitter unit (2, 2?), as well as a detector unit (3, 3?) and a computing unit (4). The emitter units (2, 2?) are configured to emit respective measurement signals into corresponding emission spatial regions (A1, A2). The detector unit (3, 3?) is configured to generate at least one detector signal on the basis of reflected portions of the measurement signals, and the computing unit (4) is configured to generate a measurement data set on the basis of the at least one detector signal. The computing unit (4) is configured to identify at least one section (T1, T1?, T2) that is shaded with respect to at least one of the emitter units (2, 2?). The computing unit (4) is configured to generate the measurement data set taking into account the section (T1, T1?, T2) and/or to generate correction data for correcting the measurement data set.

Abstract: A torque sensor device for detecting a torque applied to a shaft is disclosed. The torque sensor device has a magnetic arrangement, a stator arrangement and a flux guide arrangement, wherein the flux guide arrangement has a first flux guide and a second flux guide, and the first flux guide and the second flux guide each have a first collection surface and each have at least one transmission surface. The second flux guide has a second collection surface which is magnetically conductively coupled to the at least one transmission surface of the second flux guide. The first flux guide and the second flux guide are arranged relative to one another such that, if the torque sensor device is surrounded by a magnetic interference field, a first interference flux component a second interference flux component at least partially cancel one another out.

Abstract: (Camera, A-pillar arrangement having the camera and vehicle) Camera (3, 103, 203) for a vehicle (1), which camera is designed: to be mounted at least partially inside an A-pillar (7, 107, 207) of the vehicle (1), to record image data for an area in front of the vehicle (1), and to be arranged in the A-pillar (7, 107, 207) in such a way that a space (24, 124, 224) taken up by the camera (3, 103, 203) inside the A-pillar (7, 107, 207) has a smaller maximum dimension (A1, A3, A5) parallel to a line of sight (14, 114, 228) of the camera (3, 103, 203) than its maximum dimension (A2, A4, A6) parallel to a longitudinal direction (L) of the A-pillar (7, 107, 207).

Abstract: A method for determining an evasion trajectory for a vehicle to evade one or more objects is disclosed. The method involves recognizing a first object in a predicted trajectory of the vehicle, determining a lateral evasion distance left with respect to the first object, determining a lateral evasion distance right with respect to the first object, selecting the smaller one of the lateral evasion distance left and lateral evasion distance right as a first ideal lateral evasion distance, and determining a first ideal evasion trajectory on which the vehicle passes the object depending on the first ideal lateral evasion distance.

Abstract: The invention relates to a sensor arrangement (12), in particular for use for a driving assistance system of a vehicle (10), having a plurality of ultrasonic sensors (14) which are arranged along at least a front (20) and/or a rear (22) of the vehicle (10), wherein the ultrasonic sensors (14) are divided into a group (26) of right-hand ultrasonic sensors (14) and a group (24) of left-hand ultrasonic sensors (14), and the sensor arrangement (12) has asymmetric operation in which the ultrasonic sensors (14) in one group (24, 26) of ultrasonic sensors (14) at least partially have a lower receiving sensitivity than corresponding ultrasonic sensors (14) in the other group (26, 24) of ultrasonic sensors (14). The invention also relates to a method for operating such a sensor arrangement (12).

Abstract: A method for operating a contactlessly operating detection device for monitoring at least one monitoring area is described. In the method, transmission signals are successively sent into at least one monitoring area. Transmitted signals which are reflected in the monitoring area are received with the detection device, brought into a form to be processed with an evaluation device, and processed as received signals. Some of the signals are allocated to at least one signal block. Information about the monitoring area is determined from some of the received signals. Some of the received signals that follow one another in time are allocated to at least one received signal block at the receiving end of the detection device, independent of any allocations of transmission signals at the transmitting end of the detection device. Some of the received signals of the received signal blocks are subjected to signal processing in blocks.

Abstract: An ultrasonic transducer having a piezoelectric element for use on a vehicle is disclosed. The transducer has a control and evaluation circuit for generating a control voltage for the piezoelectric element, which generates and emits an ultrasonic signal based on the control voltage, and for outputting an output signal on the basis of an echo signal received at the piezoelectric element. A gyrator circuit is included for providing a compensation inductance for adapting the control and evaluation circuit, for compensating for a parasitic connection capacitance of the piezoelectric element. The gyrator circuit has a variable compensation inductance. A method for compensating for an ultrasonic transducer having a piezoelectric element for adapting a reception sensitivity is also disclosed.