Provided are a display device, a backlight source, and an automobile. The display device includes a view angle control panel; in a sharing mode phase, a same voltage is provided for the first electrode and the second electrode; in a privacy mode phase, a first voltage is provided for the first electrode, and an alternating voltage signal is provided for the second electrode, where a high voltage of the alternating voltage signal is greater than the first voltage, and a low voltage of the alternating voltage signal is less than the first voltage; in a transition phase, the first voltage is provided for the first electrode, and a voltage signal with gradually changing duty cycles is provided for the second electrode; where the transition phase is located between the sharing mode phase and the privacy mode phase.

A system for controlling visual protection for a display unit includes a camera which is configured to generate a video signal; a video signal processing unit which is configured, based on the video signal of the camera, to determine a particular position of each of one or more persons relative to the display unit and to determine a particular viewing direction of one of the one or more persons; a database which is configured to generate a prediction for a behaviour of each of the one or more persons based on the particular position and viewing direction of each of the one or more persons detected by the video signal processing unit, wherein the prediction includes one or more predicted viewing directions of the particular person; and a display control unit which is configured to control the visual protection for the display unit based on the prediction.

A display device includes: a display panel configured to display a parallax image including a first image to be viewed by a first eye of a user and a second image to be viewed by a second eye of the user; and an optical member including a plurality of optical elements arranged along a predetermined direction which includes a component in a parallax direction of the first eye and the second eye. A beam direction of the parallax image is defined by the plurality of optical elements. The display panel includes a plurality of subpixels including a plurality of minipixel. Each of the minipixels included in the plurality of subpixels is configured to be able to display different images.

A pair of outside view displays that are provided on an instrument panel, are located outside a steering in a vehicle width direction, and display captured outside view images and displays that are provided inside the outside view displays in the vehicle width direction and have display regions from a driver seat to a front passenger seat are provided, and the outside view displays are provided so as to face the inside in the vehicle width direction and are disposed such that inner ends of the outside view displays are located on a front side of the vehicle relative to closer left and right ends of the displays.

A vehicular driver monitoring system includes an interior rearview mirror assembly disposed in a vehicle and including a mirror reflective element. A camera is disposed at the interior rearview mirror assembly and views a driver sitting at a driver seat of the equipped vehicle. The camera is operable to capture image data. A control includes a vision system-on-a-chip image processor that processes image data captured by the camera. The control, via processing at the vision system-on-a-chip image processor of image data captured by the camera, determines driver movement. The vehicular driver monitoring system generates an output responsive at least in part to the determined driver movement.

The disclosure relates to vacuum forming methods, apparatuses and resulting displays that represent improvements in various key areas. The methods, for example, greatly improve manufacturing throughput through reduced curing times. The methods further facilitate improved control of glass shape to a targeted shape and improved control of bond line thickness, which result in improved survivability and long-term reliability, for example.

A vehicular driver monitoring system includes an interior rearview mirror assembly disposed in a vehicle and including a mirror reflective element. A camera is disposed at the interior rearview mirror assembly and views a driver sitting at a driver seat of the equipped vehicle. The camera is operable to capture image data. A control includes a vision system-on-a-chip image processor that processes image data captured by the camera. The control, via processing at the vision system-on-a-chip image processor of image data captured by the camera, determines driver movement. The vehicular driver monitoring system generates an output responsive at least in part to the determined driver movement.

A display module and a method for driving the same, a display apparatus, and a vehicle are provided. The display module includes a backlight component, and a display component and a light-adjusting component that are located at a side of the backlight component facing toward a light-emitting direction of the display module. The backlight component includes a first light guide structure and a light regulating structure. The light-adjusting component includes first and second electrodes, and a first liquid crystal. The display module has a sharing mode and an anti-peeping mode. In the sharing mode, the first electrode and the second electrode are not energized, and the first liquid crystal is in a wide viewing angle state. In the anti-peeping mode, the first electrode and the second electrode drive the first liquid crystal to be in a narrow viewing angle state.

The present disclosure relates to a robot provided in a vehicle capable of performing a function related to the vehicle. The robot includes a body, a head positioned above the body, an actuator configured to apply an external force to allow the head to move relative to the body, a camera disposed on the head to capture an image, a communication unit configured to perform communications with one or more devices provided in the vehicle, and a processor configured to control the actuator so that the camera is directed toward an inside or outside of the vehicle based on information received via the communication unit.

A head-up display system of a vehicle visually transmits information to eyes of a first occupant and eyes of a second occupant. The system includes an illumination device emitting first and second display lights having first and second polarizations, respectively. The system includes a windshield and a holographic panel including first and second layers. The display lights emit toward the holographic panel at an entrance angle relative to an axis normal to the holographic panel. The first layer diffracts the first display light having the first polarization in a first exit direction at a first exit angle relative to the axis toward the eyes of the first occupant. The second layer diffracts the second display light having the second polarization in a second exit direction at a second exit angle relative to the axis, and different than the first exit angle, toward the eyes of the second occupant.