A cockpit display system includes a cockpit, a first display apparatus, a second display apparatus, a first light sensor, a second light sensor and a brightness distribution calculation module. The first light sensor is suitable for detecting a first ambient light brightness. The second light sensor is suitable for detecting a second ambient light brightness. The brightness distribution calculation module is suitable for respectively calculating a first brightness, a second brightness, a third brightness and a fourth brightness of the first display area and the second display area of the first display apparatus and the third display area and the fourth display area of the second display apparatus under a same display gray level according to the first ambient light brightness and the second ambient light brightness. The first brightness, the second brightness, the third brightness and the fourth brightness are different from each other.

A vehicle according to embodiments includes a display unit displaying information related to the vehicle, a sensor unit detecting a position of a user of the vehicle, and a processor controlling the display unit, wherein the sensor unit is located at a bottom end of the display unit and wherein the sensor unit includes at least one or more light emitting units emitting light and at least one or more sensors receiving the light.

A vehicle display control device includes: a display section that is configured to cause display at a plurality of display areas provided adjacent to each other inside a vehicle cabin; and a display item changing section that is configured to change respective display items displayed at the plurality of display areas by the display section.

A picture generation unit emits a light field. A mirror reflects the light field toward a windshield of a motor vehicle such that the light field is reflected off of the windshield and is visible to the driver as a virtual image. An infrared emitter transmits infrared energy through the mirror such that the infrared energy is substantially co-axial with the light field, and such that the infrared energy is reflected off of the windshield toward the human driver. An infrared camera captures infrared images based on the transmitted infrared energy reflected off of the human driver and received by the infrared camera. Eye tracking is performed based on the captured infrared images. The infrared energy is transmitted at a higher power level at a beginning of the eye tracking than after the beginning of the eye tracking.

An occupant detection system and method may include a user interface and at least one sensor to determine if there is an occupant in the vehicle. In one embodiment, the system and method use capacitive sensing sensors embedded into a cushion and/or back of seats in a vehicle. The capacitive sensor sends a sense signal to a controller and the controller would recognize various conditions such as an empty seat or a seat occupied by a person or animal. It could also determine if there was a child seat in a position on a vehicle seat and if there is a child in the child seat.

In a method for adjusting a display device and a motor vehicle having such a display device, the display device is arranged on a dashboard of the motor vehicle. The display device has at least two rimless screens. Each of the screens is connected to the dashboard by an adjustment element. The respective adjustment element can move the respective screens into a plurality of adjustment positions in all spatial directions. In a combined adjustment position, the screens are arranged as a combined display surface, and the screens are designed to display a uniform display image on the combined display surface. In at least one separated adjustment position, a first screen is assigned to a driver's position and a second screen is assigned to a passenger's position.

Guided driver positioning system and methods are disclosed herein. An example method can include determining gait for a user of a vehicle from images obtained from a camera, the gait being indicative of a posture of the user, determining a distance between the user and a display of the vehicle, and automatically adjusting a vehicle component in response to the gait and the distance to change a user position relative to the display.

An operating apparatus includes: a first display; a second display; and an electronic control unit. The electronic control unit is configured to output a second image onto the second display. The electronic control unit is configured to output a first image onto the first display. The electronic control unit is configured to switch between the first mode and the second mode. In a first mode, a first mode image independent of the second image is output as the first image. In the second mode, a second mode image having the same appearance as the second image is output as the first image. The electronic control unit is configured to execute a first predetermined function in the first mode and a second predetermined function in the second mode.

A motor vehicle operating device is presented that comprises a presence-sensitive sensor device and is configured to provide, in a motor vehicle, an activated first application and at least one deactivated further application. A driver can control an activated application by means of the presence-sensitive sensor device and cannot control a deactivated application by means of the presence-sensitive sensor device. The motor vehicle operating device is configured to receive an input signal, which refers to a number of input objects with which the input is made at the presence-sensitive sensor device, wherein different numbers of input objects are assigned to the applications. OIf the input signal refers to a number of input objects assigned to the first application, control of the first application takes place and, if the input signal refers to a number of input objects assigned to the further application, activation of the further application takes place.

An information presentation device, mounted on a vehicle for which automatic evacuation control functions when it is difficult for a driver to continue driving the vehicle, and presenting information to an occupant of the vehicle except the driver by a display in a display area that is visually recognizable by the occupant, includes: an operation information acquisition unit that acquires operation information of the automatic evacuation control; and a display generation unit that generates an occupant notification display that is displayed in the display area to notify information relating to the automatic evacuation control when the automatic evacuation control is in operation. The occupant notification display includes: an explanatory image that shows an explanation of a process executed currently; and a progress image that indicates a degree of progress in the automatic evacuation control.