A vehicle display control device, when a steering wheel is at a steering angle position of a neutral position or the vicinity thereof, if a right hand sensor detects gripping of the steering wheel, turns off light sources of memory buttons and operation buttons that can be operated with a right hand, and if a left hand sensor detects the gripping, turns off a light source of air conditioning related buttons and hides touch buttons of a touch panel display that can be operated with a left hand. The vehicle display control device, if the right hand sensor does not detect the gripping, turns on the light sources of the memory buttons and the operation buttons, and if the left hand sensor does not detect the gripping, turns on the light source of the air conditioning related buttons and displays the touch buttons on the touch panel display.

Provided is an in-vehicle information processing system that can be operated intuitively. An in-vehicle information processing system (10) includes a display (11), a touch operation interface (12), an imaging unit (13), and a controller (14). The display (11) includes at least one screen. The touch operation interface (12) detects contact by an operation hand of an operator. The imaging unit (13) captures an image of the touch operation interface (12) and at least a portion of the operation hand. The controller (14) associates position coordinates in an operation region (R2) on the screen with position coordinates in a predetermined region (R1) of the touch operation interface (12) and causes at least a portion of the operation hand to be displayed in overlap on the screen on the basis of the image captured by the imaging unit (13).

Provided is a soft upper trim of a vehicle door, in which an upper substrate, foam, and a transparent skin are laminated, and particularly, to a soft upper trim for switch assembly of a vehicle door, in which a switch, which is configured to preserve continuity of a transparent skin and display lock and unlock symbols on the transparent skin, is easily assembled to an upper substrate, and a method of manufacturing the same.

A determination is made as to whether a driver or a front-seat passenger of the motor vehicle would like to operate a display device. If it is detected that only the driver would like to operate the display device, the display device is put in a first operating mode in which a graphic user interface is displayed exclusively in a driver-side display region of the display device. If it is detected that only the front-seat passenger of the motor vehicle would like to operate the display device, the display device is put in a second operating mode in which the graphic user interface is displayed exclusively in a front-seat-passenger-side display region of the display device. If it is detected that the driver and the front-seat passenger of the motor vehicle both would like to operate the display device, the display device is put in a third operating mode in which the graphic user interface is displayed in the driver-side display region and at least part of the graphic user interface is additionally also displayed in the front-seat-passenger-side display region.

The invention relates to a method for calibrating an eye tracker unit of an operating device, wherein at least one apparatus is controlled by means of the operating device depending on at least one user input and wherein, in the case of the method, at least one graphical element is displayed respectively by a control unit of the operating device in at least one predetermined usage step of the operating device and at least one piece of viewing direction information is determined by means of the eye tracker unit for the user viewing a screen. The invention provides that, from the at least one displayed element, an optically salient element, on which the user must focus with their eyes in order to successfully perform the usage step, is established, and calibration data for the calibration of the eye tracker unit is generated depending on a display position of the optically salient element on the screen and depending on the at least one piece of viewing direction information.

A vehicle user interface including a vehicle steering wheel including a grip, a sensor mounted in the steering wheel grip detecting objects touching the steering wheel grip, a plurality of individually activatable illumination units illuminating respective locations on the steering wheel grip, and a processor receiving outputs from the sensor, selectively activating a subset of the illumination units adjacent to a detected object, and controlling a plurality of vehicle functions in response to outputs of the sensor.

Provided are a smart surface, a center console of a vehicle, and a vehicle. The smart surface includes a display device (10), a decorative cover plate (20) including a decorative pattern layer (21), a substrate layer (22), an optical adhesive layer (23), and a glass layer (24) stacked sequentially from top to bottom, an upper surface of the glass layer (24) being fitted to the optical adhesive layer (23), and a lower surface of the glass layer (24) being covered on the display device (10), and an AG fluorescent film (30) fitted to the decorative pattern layer (21), and the AG fluorescent film (30) is used for filtering ambient light or light emitted from the decorative pattern layer (21). The smart surface provided by the present application can reduce the obstruction of the image caused by the decorative pattern by providing the AG fluorescent film.

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

A command mechanism for vehicle includes: a support having a contact surface; a detection mechanism configured to detect a finger of a user in command position pressing on the contact surface; and a vibration mechanism that is configured to generate a distant-approach vibration when the detection mechanism detects the presence of the element at the first distance from the contact surface and a more intense, close-approach vibration when the detection mechanism detects the presence of the element at a second distance from the contact surface.

An ultrasonic haptic control system for a motor vehicle is provided. The system includes a steering wheel assembly comprising a ring-shaped member configured to be held by an occupant of the vehicle, and rotated about a central axis in order to steer the vehicle; and a plurality of ultrasound emitters associated with the steering wheel. The ultrasound emitters are configured to focus ultrasound waves within a central region about which the ring-shaped member circumferentially extends and/or radially outside of and adjacent to the ring-shaped member. The focused ultrasound waves are configured to form one or more haptic control surfaces. A method of operating a haptic control system is also provided.