Abstract: Disclosed is a solution to the use of a speed limiter in a motorcycle that has a high capacity for acceleration, including a method for limiting the speed of a motorcycle using precise parameters of speed, acceleration and required engine torque and a single control button to manage the smart activation and deactivation of the limiter and to input new speed limits Vlim in a simple way. It thus allows the use of a speed-limiting system in a motorcycle that has a high power/weight ratio by avoiding the sources of interference with the riding and the effects liable to jeopardize its stability.

Abstract: A method for synchronizing acquisition of an analog signal value with a read signal for a state of an electrical contact of a motor vehicle. The method includes: controlling, at each start time of the first task, the power supply module so that the power supply module generates a read signal voltage pulse at the interface module input; at the same start time, triggering a counter for a predetermined duration shorter than the duration of the read signal voltage pulse; on the expiration of the counter duration, measuring the value of an analog signal generated by the interface module based on the state signal and of the read signal; and controlling, at the next start time of the second task, the power supply module so that the power supply module generates a zero voltage signal at the interface module input until the next start time of the first task.

Abstract: A vehicle electrical system, particularly for a motor vehicle. The vehicle electrical system has at least two electrical system branches, a disconnecting switch device between the two electrical system branches, wherein the disconnecting switch device has a first controllable switch unit and a series circuit having a second controllable switch unit and an overcurrent protection unit, wherein the first switch unit and the series circuit are electrically connected to each other in parallel between the two electrical system branches, and a control unit which in an idle mode of the vehicle electrical system, is equipped to switch the first switch unit into an open, current-disconnecting switching state and to keep it in the current-disconnecting switching state and to switch the second switch unit into a closed, current-carrying switching state and to keep it in this current-carrying switching state. A motor vehicle with the above-mentioned vehicle electrical system is also disclosed.

Abstract: A display device with self-luminous display elements, which are arranged in a panel. The panel is provided, on its rear side opposite the light-emitting surface used for display, with a heat distribution element, on the side of which facing away from the rear side at least one temperature sensor is arranged. The heat distribution element has at least one opening, behind which a light sensor is arranged, wherein the light sensor and the temperature sensor are arranged on a common carrier.

Abstract: A method for starting-up a device with an embedded multimedia card (eMMC) is provided. The method comprises providing power to the device, putting the eMMC in a Fast-Boot modus, reading a bootloader from the eMMC into a RAM of the device, starting the bootloader in a CPU of the device, terminating the Fast-Boot modus, resetting the eMMC, putting the eMMC in the Fast-Boot modus initializing hardware by the bootloader, while reading an operating system into the RAM using DMA, and starting the operating system from the RAM by the bootloader is provided. A device comprising an embedded eMMC is also disclosed.

Abstract: A method for generating a visual range collection includes determining a current position of at least one motor vehicle, determining a current visual range which describes how far a driver of the motor vehicle can see from the current position, transmitting the visual range from the motor vehicle to a visual range collecting device, generating the visual range collection based on the transmitted visual range, predetermining an expected change in visual obstruction at the position, and adjusting the visual range from the visual range collection based on the predetermined change in visual obstruction.

Abstract: A method for determining the elevation angle and/or azimuth angle of a signal received by an ultrasound sensor includes: providing an ultrasound sensor with a frequency-dependent radiation pattern; transmitting a first ultrasound wave at a first frequency; transmitting a second ultrasound wave at a second frequency different from the first frequency; receiving reflections of the first and second waves, the reflections being caused by an object; and determining the elevation angle of the first and second reflected waves based on amplitudes of the reflections of the first and second waves. Determining the elevation angle (and/or azimuth angle includes calculating a ratio between the amplitudes of received reflections of the first and second waves and mapping a calculated ratio to an elevation angle and/or azimuth angle. The mapping is based on a predetermined ratio curve or ratio dataset which associates a certain amplitude ratio to an elevation angle and/or azimuth angle.

Abstract: A method for determining a tread depth of a tread of a tire during operation of a vehicle having the tire, a control device for a vehicle for determining a tread depth of a tread of a tire of the vehicle, and a system for a vehicle having such a control device and at least one electronic wheel unit, are provided. Provision is made to determine the tread depth based on a determined instantaneous dynamic wheel radius of a wheel, having the tire, of the vehicle and a determined instantaneous dynamic inside radius of the tire. In addition, at least one further first operating parameter of the tire, selected from the group including an instantaneous roadway gradient, an instantaneous vehicle drive mode and an instantaneous tire material expansion, is determined and taken into consideration.

Abstract: Various embodiments include a system for determining a risk of an accident on a driving route comprising: a memory storing route risk parameters of the driving route, wherein at least one of the route risk parameters is assigned to route sections of the driving route, wherein each of the route risk parameters contains information relevant for road safety on the respective route section; and a processor in communication with the memory, programmed to determine a respective risk factor for each of the route risk parameters, wherein the respective risk factor indicates a measure of a risk of an accident on the respective assigned route section. The processor determines a total risk index of the driving route based on the respective risk factor of the respective risk parameter assigned to the respective route section, wherein the total risk index measures risk of an accident on the driving route.

Abstract: A method for determining a wet road condition includes receiving a value of a received signal strength index of an RF signal received from a sensor associated with a wheel of a vehicle, comparing the value to a predetermined threshold value, and if the value is less than the predetermined threshold value, determining that a wet road condition is met and outputting a pre-aquaplaning warning signal. A system for determining a wet road condition and a non-transitory computer program product are also provided.

Abstract: A motor vehicle comprises a towing vehicle and an antenna network which has at least two antenna units with identical network addresses, wherein the two antenna units are arranged on different side surfaces of the towing vehicles and are digitally connected.

Abstract: The present disclosure relates to an apparatus for monitoring the stability of an ego vehicle, including at least a first and a second driver assistance device, the at least first and second driver assistance device being designed to guide the ego vehicle; an evaluation unit which is designed to determine a degree of risk of a detected and/or anticipated pendulum motion of the ego vehicle. An assessment unit is further included, the assessment unit being designed to assess, on the basis of the determined degree of risk, whether the at least first and/or second driver assistance device in an active state will lead to pendulum initiation or pendulum intensification of the ego vehicle.

Abstract: Various embodiments include a correction method comprising: A) reading in data of an image of a calibration pattern recorded with an optical unit, the pattern including some structures; B) simulating a line through the image, the line extending through a reference point subdividing the line into half-lines, each intersecting the imaged structures; C) determining a first and a second sequence of measured values representing distances resulting from the intersection points on the half-lines line with respect to the reference point; D) determining a third and a fourth sequence of target values representing target distances of the intersection points; E) determining a mapping specification that at least approximately maps the target values of the third and fourth sequences to the measured values of the first and second sequences, or vice versa; and F) correcting image data of an image recorded using an optical unit using the mapping specification of step E).

Abstract: A potted electronic module includes an electronic assembly with a conductor such as a shunt that is arranged in a housing, and includes an electrical contact guided out through the housing wall, and a potting compound within the housing. The module may be produced by removing a protective layer from an area of the conductor by ablation, and then introducing a potting or casting compound into the housing, so that the potting compound covers a location at which the electrical contact passes through the housing wall, and the potting compound adheres directly onto the exposed conductor at the area at which the protective layer was removed.

Abstract: Various embodiments include a sensor data system for a vehicle, the system comprising: a sensor in the vehicle, the sensor configured to collect environment data; a communication device configured to receive second environment model data from another vehicle; and a processing unit. The processing unit is configured to: calculate a first localization position of at least one of the vehicle or an object in the environment of the vehicle; generate first environment model data based at least in part on the environment data collected, wherein the first environmental model data and the second environment model data both contain localization data; compare the first localization data with the second localization data; and from the comparison determine a correction to the first localization position.

Abstract: A vehicle alert device (10) executes alert control of determining, when a target is detected in a periphery of an own vehicle (C1), within a set calculation period, whether the target is an alert-target object that does not include a stationary object, determining, when the target is an alert-target object, whether the alert-target object exists in a blind spot area (RL, RR) of a driver, and alerting the driver when the alert-target object exists in the blind spot area. The vehicle alert device avoids executing the alert control when a relative speed of the own vehicle with respect to the alert-target object at a time when the own vehicle overtakes the alert-target object is equal to or higher than a predetermined threshold value.

Abstract: A method is disclosed for representing an obscured area of a mobile platform environment relative to an object area of a first and second imaging devices of the mobile platform, including determining a delta-area, being the difference of a second obscured area of the environment which is obscured in respect to the object area at a second time step, and a first obscured area of the environment which is obscured in respect to the object area at a first time step. First and second overlap-images, being an overlap of an image of the first imaging device respectively of an image of the second imaging device with the delta-area, are determined, wherein both images are taken at the first time step. A difference of an optical property of the images is determined, and the difference of the optical property is harmonized within at least one of the overlap-images.

Abstract: A device includes a processor configured to: issue an alarm when a movement path condition is met and a prohibition condition is not met, the movement path condition being met when an approaching object of which a predicted movement path is a path along which the object passes by a door of the host vehicle is present; and not issue the alarm when the prohibition condition is met, even when the movement path condition is met, wherein the prohibition condition includes a condition to be met when a difference between a distance in a transverse direction from the host vehicle to a stationary object and a distance in the transverse direction from the host vehicle to the approaching object is equal to or less than a predetermined value in a case where the stationary object is present, the stationary object being stationary at a side of the host vehicle.

Abstract: A battery sensor for sensing at least one battery parameter including at least two measuring units. The measuring units each include at least one sensing device for sensing at least one measured value and at least one evaluation circuit for determining at least one battery parameter from the respectively sensed at least one measured value. An evaluation unit is provided, which compares the battery parameters determined by the evaluation circuits and outputs an error signal in the event that a defined difference between the battery parameters is exceeded.

Abstract: A drop-off assist device includes: a processor configured to determine that there is a possibility that a target approaching object passes by a door of a host vehicle when a second object is not present between the target approaching object and the host vehicle, correct the predicted movement path based on a position of an edge of the second object when the second object is present between the target approaching object and the host vehicle at a timing of setting the target approaching object, determine that there is the possibility that the target approaching object passes by the door of the host vehicle when the corrected predicted movement path is the path that passes by the door of the host vehicle, and issue an alarm when determining that there is the possibility that the target approaching object passes by the door of the host vehicle.