Abstract: Various embodiments include a system for a vehicle having a body a door held on the body and pivotable about a pivot axis. An example includes: an obstacle identification system to detect a collision event occurring between the door and an object within surroundings of the vehicle; and a sensor pivotably held on the body, the sensor having a field of vision covering an angle about the pivot axis in plan view along the pivot axis. The field of vision covers a subregion of a total monitoring region of the obstacle identification system, wherein the field of vision is smaller than the total monitoring region.

Abstract: Various embodiments of the teachings herein include a system for a vehicle having a vehicle body and a vehicle door held pivotably on the vehicle body. An example system includes: an anti-trap protection device to detect a trapping event occurring between the vehicle door and the vehicle body; and an obstacle identification system to detect a collision event occurring between the vehicle door and an object in surroundings of the vehicle. At least one sensor operates both for detection of the trapping event and for detection of the collision event.

Abstract: A method and a system for contactless obstacle detection for a motor vehicle having a front side door and a rear side door, using a single primary obstacle sensor provided on the motor vehicle, preferably in the form of a ToF sensor, which is configured to monitor an opening region of the front side door, and, at least as long as the front side door is closed, also to monitor an opening region of the rear side door, the method comprising the following step, which is carried out repeatedly: determining a current maximum allowed opening angle for the rear side door based on an output of a monitoring of the opening region of the rear side door by the primary obstacle sensor and taking into account a current opening state of the front side door.

Abstract: A drum brake with a carrier, a deformation sensor, and at least one brake shoe. The carrier is connected to a supporting bearing for the at least one brake shoe. The deformation sensor is designed to determine a deformation of the carrier. A brake system includes at least one such drum brake, and a vehicle with such a brake system or with at least one such drum brake.

Abstract: A method and a system for contactless obstacle detection for a motor vehicle having a front side door and a rear side door, using a single primary obstacle sensor provided on the motor vehicle, preferably in the form of a ToF sensor, which is configured to monitor an opening region of the front side door, and, at least as long as the front side door is closed, also to monitor an opening region of the rear side door, the method comprising the following step, which is carried out repeatedly: determining a current maximum allowed opening angle for the rear side door based on an output of a monitoring of the opening region of the rear side door by the primary obstacle sensor and taking into account a current opening state of the front side door.

Abstract: Various embodiments of the teachings herein include a method for determining a target position of a surroundings sensor of a vehicle using a vehicle-side attachment element as a calibration object, wherein the sensor and the attachment element are movable relative to each other. The method includes: ascertaining a first position of the surroundings sensor in a first relative pose; moving the sensor and/or the element from the first pose to a second pose between the sensor and the element; ascertaining a second actual position of the surroundings sensor in the second relative pose; and determining the target position of the surroundings sensor by averaging the first position and the second position to form an averaged actual position and assigning the averaged actual position as the target position.

Abstract: Various embodiments include a catalyst measuring system for determining the aging of an SCR catalytic converter, the system comprising: a control device with a processor; an SCR catalytic converter for treating the exhaust gases of a vehicle; a high-frequency sensor for measuring a level of ammonia loading of the SCR catalytic converter; and an ammonia dosing system for injecting ammonia into an exhaust system of the vehicle. The control device instructs the ammonia dosing system to inject ammonia selectively into the exhaust system. The control device compares data measured by the high-frequency sensor with a predefined threshold value to determine the aging of the SCR catalytic converter.

Abstract: Various embodiments include a catalyst measuring system for on-board diagnostics and for determining the aging of an SCR catalytic converter for a vehicle comprising: a processor; an SCR catalytic converter for purifying exhaust gas of the vehicle; a high-frequency sensor for determining the ammonia loading of the SCR catalytic converter; a NOx sensor for sensing the NOx concentration downstream of the SCR catalytic converter; and an ammonia dosing system for injecting ammonia into an exhaust system of the vehicle. The control device instructs the ammonia dosing system to inject ammonia selectively into the exhaust system at a plurality of different dosing rates. The control device evaluates data received from the NOx sensor and of the high-frequency sensor to calculate the ammonia dosing rate.

Abstract: Various embodiments include a catalyst measuring system for determining the aging state of a catalytic converter comprising: an SCR catalytic converter; and a high-frequency measuring arrangement including a processor, a first antenna, and a second antenna. The first antenna is located upstream of the SCR catalytic converter in the exhaust tract and the second antenna is located downstream of the catalytic converter. The processor instructs the antennas to selectively emit and receive electromagnetic signals and evaluates the transmitted and the received electromagnetic signals to compare them with predefined threshold values. The processor determines an aging state of the SCR catalytic converter based on the comparison.

Abstract: Various embodiments include a catalyst measuring system for on-board diagnostics and for determining the aging of an SCR catalytic converter for a vehicle comprising: a processor; an SCR catalytic converter for purifying exhaust gas of the vehicle; a high-frequency sensor for determining the ammonia loading of the SCR catalytic converter; a NOx sensor for sensing the NOx concentration downstream of the SCR catalytic converter; and an ammonia dosing system for injecting ammonia into an exhaust system of the vehicle. The control device instructs the ammonia dosing system to inject ammonia selectively into the exhaust system at a plurality of different dosing rates. The control device evaluates data received from the NOx sensor and of the high-frequency sensor to calculate the ammonia dosing rate.

Abstract: Various embodiments may include a method for operating a catalytic converter device comprising: measuring electrical properties of the catalytic converter using high-frequency electromagnetic waves; determining a current operating state of the converter; acquiring reference points associated with the operating state; and checking a calibration of a measuring device. The operating states are selected from: an accumulator is completely emptied; an accumulator is completely filled; an accumulator is partially filled; a component to be stored is put into storage; a component to be stored is removed from storage; and an exhaust gas component to be converted or a quantity of the catalyst material in the exhaust gas which exceeds a threshold value is detected. The component to be stored is selected from the group consisting of: a catalyst material and the exhaust gas component.

Abstract: A sensor for detecting oxidizable gases may comprise a catalytically inactive surface and a catalytically active surface on opposite sides of a sensor element and a thermal element running through the sensor element to connect the two surfaces, with a device for measuring a thermoelectric voltage between the catalytically active surface and the inactive surface as a measure of the difference in temperature and therefore the gas concentration. The sensor may include a hot plate mounted on a base carrier by means of narrow arms, wherein the thermal element includes at least one via extending through the hot plate and connecting the two surfaces to one another, and in the region of which the thermoelectric voltage is measured.

Abstract: A sensor element may include a measuring element and a functional housing at least partially surrounding the measuring element including a plastic molded housing. The measuring element may include a hot plate mounted on a carrier substrate by means of narrow arms in a broadly thermally decoupled manner. The carrier substrate may be provided with contacts leading to the measuring element and terminating in contact/bonding points on the carrier substrate. The carrier substrate together with the contact/bonding points may be at least partially integrated into the plastic molded housing, leaving the hot plate exposed. The housing may include connection wiring for the contact/bonding points.

Abstract: A sensor element with air pressure measurement includes a layer stack from a plurality of layers arranged one on top of the other. At least one first layer contains a measurement sensor device for measuring a measurement parameter different from an ambient pressure of the sensor. The first or at least one second layer contains a pressure measurement device for measuring the air pressure in an environment on one side of the sensor element, or a channel for coupling a pressure measurement device to an environment on one side of the sensor element.

Abstract: A system for determining a regeneration phase of an exhaust gas particulate filter for an internal combustion engine may include a temperature sensor for detecting an elevated exhaust gas temperature, a sensor for detecting the particulate content in the exhaust gas stream exiting from the exhaust gas particulate filter, and a processing device for determining the regeneration phase on the basis of the detected values. A method for determining a regeneration phase of an exhaust gas particulate filter for an internal combustion engine may include detecting an elevated exhaust gas temperature, sampling a signal from a sensor for detecting the particulate content in the exhaust gas stream exiting from the exhaust gas particulate filter, detecting that the particulate content is elevated, and determining the regeneration phase.

Abstract: The present disclosure relates to a sensor for measuring a property of an aggressive liquid. The sensor may include a tube with a tube wall and a measuring device at least partially extending through the tube wall. The tube may be made of a chemically resistant polymer. The part of the measuring device extending through the tube wall may include an electrode guided through the tube wall and with an open electrode structure on and in the tube wall.

Abstract: A sensor element may include a measuring element and a functional housing at least partially surrounding the measuring element including a plastic molded housing. The measuring element may include a hot plate mounted on a carrier substrate by means of narrow arms in a broadly thermally decoupled manner. The carrier substrate may be provided with contacts leading to the measuring element and terminating in contact/bonding points on the carrier substrate. The carrier substrate together with the contact/bonding points may be at least partially integrated into the plastic molded housing, leaving the hot plate exposed. The housing may include connection wiring for the contact/bonding points.

Abstract: A particle sensor arranged in an exhaust duct such that particles from the exhaust-gas flow accumulate on and/or between at least two sensor electrodes when a voltage greater than a limit voltage is applied between the two sensor electrodes and substantially no particles accumulate if the voltage is lower than the limit voltage. During a first time period, a first voltage greater than the limit voltage is applied between the sensor electrodes. During a second time period, a second voltage, lower than the limit voltage, is applied between the sensor electrodes, and/or the particle sensor is heated to a predefined temperature, such that substantially no particles accumulate on and/or between the at least two sensor electrodes. Following the second time period, a third voltage greater than the limit voltage is applied between the sensor electrodes.

Abstract: A sensor for detecting oxidizable gases may comprise a catalytically inactive surface and a catalytically active surface on opposite sides of a sensor element and a thermal element running through the sensor element to connect the two surfaces, with a device for measuring a thermoelectric voltage between the catalytically active surface and the inactive surface as a measure of the difference in temperature and therefore the gas concentration. The sensor may include a hot plate mounted on a base carrier by means of narrow arms, wherein the thermal element includes at least one via extending through the hot plate and connecting the two surfaces to one another, and in the region of which the thermoelectric voltage is measured.

Abstract: A method for producing a sensor element for a sensor for detection of substances contained in a gas flow includes: providing a ceramic carrier; and producing an open measurement electrode, arranged on the carrier and exposed to the gas flow. The open measurement electrode is produced by: a combined printing technique from a cermet base print for a base layer of a ceramic-platinum cermet, arranged on the carrier, and a platinum upper printing for a cover layer of sintered platinum arranged on the base layer.