Provided is an audio-video-navigation (AVN) monitor drive unit for a vehicle, which is configured to tilt an AVN monitor coupled to a crash pad in a direction toward a passenger seat. The AVN monitor drive unit includes a monitor assembly, a hinge bracket slidably positioned at a rear of the monitor assembly, and a tilting portion configured to connect the monitor assembly and the hinge bracket to each other and tilt the monitor assembly from the hinge bracket.

A switchable backlight for a switchable privacy display apparatus comprises a collimated waveguide, first and second light sources and an optical turning film comprising elongate prismatic elements with facet orientations that pupillate the output of the waveguide in two orthogonal directions for each of first and second light sources. High luminance uniformity is achieved for a head-on user in privacy and public viewing modes and high uniformity of security factor is achieved for off-axis snoopers, with increased speed of privacy switch-on in privacy mode.

A switchable backlight for a switchable privacy display apparatus comprises a collimated waveguide, first and second light sources and an optical turning film comprising elongate prismatic elements with facet orientations that pupillate the output of the waveguide in two orthogonal directions for each of first and second light sources. High luminance uniformity is achieved for a head-on user in privacy and public viewing modes and high uniformity of security factor is achieved for off-axis snoopers, with increased speed of privacy switch-on in privacy mode.

A vehicle is provided that includes a vehicle body, a plurality of RF signal receivers located at a plurality of locations within the vehicle, a portable pet bowl configured to be transported in the vehicle body, the pet bowl including a container for holding content such as water, an RF signal transmitter located on the pet bowl for transmitting an RF signal, and a controller for processing the RF signal received by each of the plurality of RF signal receivers and determining a location of the pet bowl based on the received RF signals.

A device for controlling an interior lighting system of a vehicle to produce ambient lighting and/or reading lighting involves the interior lighting system having an array of a plurality of light sources. The device includes a control unit, by means of which the light sources of the array can be individually controlled in order to produce the ambient lighting and/or the reading lighting, and an input unit that can be connected to the control unit. The input unit has a touch-sensitive screen for inputting a current set of control information for the control unit. The control unit controls the light sources on the basis of the current set of control information. Furthermore, the input unit, on the basis of the current set of control information, displays associated ambient lighting and/or reading lighting for an illuminable region in the vehicle interior on the screen.

A user interface for controlling a function of a vehicle is provided. The user interface comprises a manual input device for generating a user input signal in response to manual actuation by a user and one or more proximity sensors for being arranged in a vicinity of the manual input device, wherein each proximity sensor is configured to generate a proximity sensor signal in response to presence of a hand in a vicinity of the proximity sensor. Furthermore, the user interface comprises a processing circuitry configured to control the function of the vehicle based on the user input signal and the one or more proximity sensor signals.

An infotainment computer device for use in controlling an infotainment system in a vehicle is provided. The infotainment computer device includes at least one processor communicatively coupled to at least one memory device and a display device communicatively coupled to the at least one processor. The infotainment computer device is programmed to display an active page and a toolbar. The active page includes a plurality of buttons and the toolbar includes a shortcut area including at least one shortcut button. The infotainment computer device is also programmed to receive a first input requesting access to a customization mode, retrieve a current speed of the vehicle, activate the customization mode if the current speed of the vehicle is zero, receive a second input indicating a desired change to at least one of the active page and the toolbar, and change the display based on the desired change.

A method for a situation-controlled display of an actuation element for a function in a vehicle on a touch-sensitive display surface operable by a person using the vehicle involves the actuation element as a blocking element for a window lifter of the vehicle. The actuation element is always displayed if a child is detected on a seat in the vehicle, and a window lifter associated with the seat is actuated, if a contradicting actuation of window lifters for the same window is carried out, the window lifters being accessible to different people in the vehicle, and/or if the occurring actuation of the window lifters deviates from the conventional actuation type.

Techniques relating to multi-passenger interaction via display(s) of a vehicle are described. In an example, sensor data is received from a sensor associated with an interior of a vehicle. Based at least partly on the sensor data, a first occupancy state associated with a first seat of the vehicle and a second occupancy state associated with a second seat of the vehicle can be determined. Content to present via displays associated with the first seat and/or the second seat can be determined based at least in part on the first occupancy state and the second occupancy state and can be presented via each respective display.

A multi-view display device is provided for a collaborative co-pilot system (system) of a vehicle having a windshield. The system includes one or more input devices for generating an input signal associated with a road condition. The multi-view display device includes one or more single-user viewing devices, with each single-user viewing device including an Augmented Reality Head Up Display module (ARHUD) for generating a dedicated display associated with the road condition. The ARHUD projects the dedicated display onto an associated portion of the windshield that is visible to a corresponding single user and overlaying a road geometry associated with the road condition. The multi-view display device further includes an Extended View Display module (EV display module) for generating a common display that is visible to a plurality of users including each one of the single users.