An apparatus for cleaning of a brake disc may include: a processor; and a storage medium in which one or more programs configured to be executable by the processor are recorded, and the one or more programs includes instructions for: a determination unit configured to determine whether a mode change has occurred from a first mode of transporting a shipped vehicle to a second mode of delivering the vehicle to a customer; and a braking controller configured to remove rust generated on a surface of a brake disc by performing braking according to a cleaning mode of the brake disc when it is determined that the mode change has occurred.

While an autonomous mode is activated, a vehicle is operated based on operating parameters for the autonomous mode. The operating parameters include at least one of a vehicle speed or a following distance. Upon detecting a user input to control vehicle operation, vehicle operation is transitioned to a nonautonomous mode, and a count of a number of received user inputs to control vehicle operation is incremented. Upon determining that the count of received of user inputs to control vehicle operation is greater than a threshold, the operating parameters for the autonomous mode are updated. Then, upon determining to transition from the nonautonomous mode to the autonomous mode, the vehicle is operated based on the updated operating parameters.

According to an embodiment, a vehicle device where drawing is executed by a plurality of applications includes a GPU that executes drawing based on a drawing request from the plurality of applications, a normal queue to which a drawing request for the GPU is input, and a priority queue to which a drawing request of preferentially executing processing over the normal queue is input. The GPU is configured to process the drawing request input to the normal queue in a round-robin fashion while preferentially processing the drawing request input to the priority queue.

An electric vehicle includes a shift lever and a clutch pedal for simulating manual gear changes of a traditional vehicle equipped with an internal combustion engine and manual transmission, and includes a controller for controlling the operation of the electric vehicle. The driver operates the shift lever in a similar fashion to that of a traditional manual transmission shift lever, however the associated gear positions do not correspond to physical gears in a transmission but rather virtual gear stage modes that correspond to mapped torque characteristics with respect to the rotational speed of the electric motor. The clutch pedal is operated by the driver when the shift lever is operated. The controller calculates the virtual engine speed of the virtual engine based on the virtual gear stage mode selected by the shift lever and the operation amount of the clutch pedal, and displays the virtual engine speed on a display.

Aspects of the present disclosure relate switching between autonomous and manual driving modes. In order to do so, the vehicle's computer may conduct a series of environmental, system, and driver checks to identify certain conditions. The computer may correct some of these conditions and also provide a driver with a checklist of tasks for completion. Once the tasks have been completed and the conditions are changed, the computer may allow the driver to switch from the manual to the autonomous driving mode. The computer may also make a determination, under certain conditions, that it would be detrimental to the driver's safety or comfort to make a switch from the autonomous driving mode to the manual driving mode.

The invention relates to an automated driving system for a motor vehicle including a visual communication interface (30) intended for informing the driver about the state of said driving system and comprising a luminous indicator (31A, 31B) capable of emitting luminous signals on the steering wheel of said vehicle; characterized in that said visual communication interface (30) also includes a heads-up display capable of displaying other luminous signals (33) in the field of view of the driver beyond the dashboard of said vehicle.

An agricultural tracked vehicle has a ground drive including at least two ground drive wheels. Ground engagement elements are assigned to individual ground drive wheels and/or units comprising several ground drive wheels. An evaluation device is provided, which is configured for ascertaining an operating state of at least one of the ground engagement elements based at least on one or several state variables of the surroundings and/or vehicle-independent, device-specific sensor data.

Aspects of the disclosure provide an automated driving system and a method for providing an indication of a driver's responsibilities in a vehicle having an automated driving system. The system includes a display device for displaying information to a driver of the vehicle, and a controller configured to display, at the display device, a driver and vehicle responsibility matrix (DVR matrix). The DVR matrix includes a first set of indicators each indicating a driving responsibility of the driver, a second set of indicators each indicating a driving responsibility of the automated driving system. In one example, the controller is configured to display the DVR matrix corresponding to an automation state.

An apparatus and a method for controlling a driving mode of a vehicle are provided. The apparatus includes a mode converter that converts the driving mode of the vehicle based on an operation of a mode conversion input. When the driving mode is converted into a custom mode, a mode setting screen for adjusting a setting value of a driving characteristic preset is configured and the configured mode setting screen is displayed on a display of the vehicle. A tuning device then tunes a driving characteristic of the custom mode based on a setting value adjusted on the mode setting screen.

A computing device in a vehicle can be programmed to determine a time to a collision and a field of safe travel, select one of a first and a second haptic output based on (a) the field of safe travel and (b) a predetermined time threshold. The computing device can deliver the first haptic output via a steering wheel when the time to collision is greater than the predetermined time threshold and deliver the second haptic output via the steering wheel when the time to collision is less than or equal to the predetermined time threshold.