The present disclosure provides a left and right wheel determination method, a wheel pressure monitoring chip and system, and related apparatuses. The left and right wheel determination method includes: obtaining a time duration for a wheel to rotate for a predetermined number of revolutions after the wheel being detected as rotating; sampling centrifugal acceleration and tangential acceleration of the wheel within the time duration; determining an overrun-lag relationship between the centrifugal acceleration and the tangential acceleration of the wheel based on a serial number of a sampling time-point corresponding to the centrifugal acceleration and a serial number of a sampling time-point corresponding to the tangential acceleration; and determining the wheel to be of a left wheel or a right wheel based on the overrun-lag relationship between the centrifugal acceleration and the tangential acceleration of the wheel.

An aspect of the disclosure provides an apparatus and a method for assisting driving capable of calculating a speed limit of a vehicle using curvature information of a road and accurately recognizing a traffic sign through this. The apparatus for assisting driving of a host vehicle includes a front sensor mounted to the host vehicle and having a field of view in front of the host vehicle, the front sensor configured to obtain front image data; and a controller including a processor configured to process the front image data. The controller may be configured to detect a speed displayed on a sign based on the front image data, to calculate a limit speed of the host vehicle on a driving road based on the front image data, and to display a sign speed smaller than the limit speed on a display of the host vehicle.

An interactive system for a vehicle using a display unit integrated on the windshield. The system receives user inputs and control the display unit based on the user input is disclosed. The system includes a display unit, which is present on the windshield of the rear window glazing, side window glazing or roof glazing of a vehicle. The display unit is composed of one or more illumination devices sandwiched between a first substrate and a second substrate of the glass assembly. The display unit is configured to display patterns, emoticons with varying intensity of illumination, frequency and color. The system further includes a sensor unit with a plurality of sensors that monitors condition and status of the vehicle. The processing unit is configured to control the display unit based on user actions and data received from the data retrieving unit.

A work vehicle includes an engine, a transmission to change a received rotational force to a rotational force at a gear ratio that corresponds to a desired vehicle speed and output the changed rotational force, a first operating tool to change the rotation speed of the engine and a deceleration rate of the transmission, a rotation speed controller to control the rotation speed of the engine based on an input provided to the first operating tool, and a second operating tool to receive a holding instruction to hold the rotation speed of the engine constant. In response to the holding instruction being inputted to the second operating tool, the rotation speed controller is configured or programmed to disable control of the rotation speed of the engine which control is based on the input provided to the first operating tool, and hold the rotation speed of the engine constant in accordance with the holding instruction.

A method for assisting a vision of a driver includes: receiving a signal indicating that weather information is emergency weather information from a navigation device according to setting by a vehicle driver, and turning on a vision assisting device included in the vehicle in response to the signal; obtaining an image of an infrared thermal camera of the vision assisting device, which photographs a front of the vehicle when the vehicle travels, and obtaining an image of a camera of the vision assisting device, which photographs the front of the vehicle when the vehicle travels; controlling an image processor of the vision assisting device to determine whether a matching rate between image data of the infrared thermal camera and image data of the camera is equal to or less than a first threshold; and, when the matching rate is equal to or less than the first threshold, using distances between the vehicle and respective objects located at the front, a rear, and sides of the traveling vehicle, speeds of the respective objects, which are detected by a radar sensor of the vision assisting device, and the images of the infrared thermal camera photographing the front of the vehicle to generate a surrounding state image of the vehicle, which includes the distances and the speeds.

A driving assistance method for assisting a power-intensive driving maneuver of a subject vehicle includes predicting the power-intensive driving maneuver of the subject vehicle, and determining whether driving maneuver criteria, which comprise at least one energy criterion and at least one traffic criterion, are satisfied for the predicted power-intensive driving maneuver. Determining if the at least one energy criterion is satisfied includes determining a peak power profile required for a full execution of the predicted power-intensive driving maneuver, determining an available drive power of the subject vehicle, and evaluating whether the available drive power is sufficient for the peak power profile, wherein the at least one energy criterion is satisfied if the available drive power is sufficient for the peak power profile. Determining if the at least one traffic criterion is satisfied includes detecting a traffic situation, which comprises at least one traffic condition and/or a route topology, in the surroundings of the subject vehicle, and evaluating whether the predicted power-intensive driving maneuver can be fully executed in the detected traffic situation, wherein the traffic criterion is satisfied if the predicted driving maneuver can be fully executed in detected traffic situation. The method further includes displaying a result of determining whether the driving maneuver criteria are satisfied for the predicted power-intensive driving maneuver.

In a method for operating a driver information system in an ego vehicle, environment data are detected in an environment of the ego vehicle. By using the environment data, it is determined whether a lane change of the ego vehicle from a current lane to an adjacent, additional lane may be safely carried out. A driver information display is generated and output, wherein the driver information display comprises a graphic adjacent lane object that represents the adjacent additional lane. The adjacent lane object has a graphic depiction feature that is generated according to whether the lane change may be safely carried out.

A driving system for an automated drive for a motor vehicle includes a steering wheel display with a lighting strip structure. The lighting strip structure of the steering wheel display is luminous in a defined lighting color for a duration which can be modified according to the actuation. The driving system is designed to control the steering wheel display such that the lighting strip structure is luminous in the lighting color over a starting length during the automated drive. Upon approaching an end of the automated drive lying ahead, the driving system determines that the vehicle has approached an end point of the automated drive lying ahead in such a manner that a specified approach condition has been satisfied. In response thereto, the steering wheel display is actuated such that the lighting strip structure is luminous in the lighting color with a successively decreasing length starting from the starting length as the distance to the end point of the automated drive decreases successively in order to prepare the driver to completely or at least partly take over control of the vehicle again.

A method for operating a driver information system in an ego-vehicle is disclosed. First environment data are detected in an environment of the ego-vehicle at a first time. At least one further road user is identified based on the detected first environment data. A driver information display is provided, wherein the driver information display comprises a first graphic road user object which is assigned to the further road user. Second environment data are recorded in the environment of the ego-vehicle at a second, later time. Based on the detected second environment data, the further road user is identified again, and a second graphic road user object is formed which replaces the first graphic road user object in the driver information display. In addition, the second graphic road user object has a higher specificity than the first graphic road user object.

A method for determining a maximum value for a parameter range of a driving operation parameter of a motor vehicle. The motor vehicle includes a control device, at least one electric traction motor, an electric energy storage device which can be operated in an operating temperature range for operating the traction motor, and at least one temperature sensor for determining a temperature of the energy storage device. The control device determines the maximum value as a function of a current temperature of the energy storage device determined by the temperature sensor in such a manner that, after the approach of a destination known to the control device and/or after a journey over a predetermined distance with the driving operation parameter restricted by the maximum value of the parameter range, a predicted temperature of the energy storage device lies within a charging temperature range.