A device that uses brainwave activity to allow a user to perform hands-free tasks is disclosed. For example, the device can include a transparent display, an electroencephalogram (EEG) sensor, and a processing circuitry coupled to the transparent display and the EEG sensor. The EEG sensor can be configured to sense an EEG signal corresponding to brain activity associated with a user of the device. The processing circuitry can be configured to display a visual stimulus on the transparent display and generate a control signal associated with a task of the user based on the EEG signal. Therefore, the user can use his brainwave activity to perform hands-free tasks.

The present disclosure relates to a portable, hand held and/or mountable control device for remote controlling at least one device provided by a vehicle. The control device comprises one or more control applications and indicator icons on a touch sensitive display and one or more motion and orientation detection sensors. The control application provided as keys on the display is selected based on user input and based on the user selected control application the device to be controlled can be controlled wirelessly by voice, steering tilt or motion based operation of the control device. Additionally, the control device can determine a fault or a correct completion of controlling by monitoring the devices. The present disclosure also provides a method for remote controlling the at least one device provided by the vehicle.

A vehicular camera monitoring system a driver-side camera, a driver-side video display screen disposed at a driver-side cabin region of an interior cabin of the vehicle, a passenger-side camera and a passenger-side video display screen disposed at a passenger-side cabin region of the interior cabin of the vehicle. Upon completion of a parking maneuver of the vehicle, and until a period of time elapses following powering down of the vehicle upon completion of the parking maneuver of the vehicle, the driver-side video display screen displays driver-side video images of a driver-side region sideward of the driver side of the vehicle and rearward of the vehicle and the passenger-side video display screen displays passenger-side video images of a passenger-side region sideward of the passenger side of the vehicle and rearward of the vehicle.

A reflectance/transmittance of an optical device disposed at a position through which image light emitted from a liquid crystal display displaying an icon passes is changed according to an anti-glare level to achieve anti-glare of the reflected image. A color of the icon displayed on the liquid crystal display is adjusted such that the higher the transmittance of the optical device is, the lower the lightness is, so that the icon of a similar color is visually recognized regardless of the reflectance/transmittance of the optical device.

A device control system includes a first input device and a gaze detector. The first input device allows a command to be entered with respect to a target device selected from one or more devices. The gaze detector detects a user's gaze direction. The gaze detector determines, based on the gaze direction detected by the gaze detector, one device, selected from the one or more devices, to be the target device. A gaze detector makes the target device change, based on the gaze direction detected by the gaze detector, the type of processing to be performed in accordance with the command entered through the first input device.

A vehicle information display apparatus includes: at least one processor configured to receive a vehicle state of a vehicle, and detect a forward object ahead of the vehicle; a flip-dot display installed in the vehicle and configured to implement a pixel by rotating a flip disk; and an illumination module installed around the flip-dot display, and configured to illuminate a surface of the flip-dot display.

The present disclosure relates to an apparatus for controlling a side mirror of an autonomous vehicle and a method thereof. According to an embodiment of the present disclosure, it is possible to detect whether a vehicle is autonomously driven and to fold the side mirror such that a mirror surface is in close contact with a vehicle body surface or side window glass or to insert the side mirror into the inner space of the vehicle when the vehicle is autonomously driven. Through the present disclosure, it is possible to notify an external vehicle of information indicating that the vehicle is driven in an autonomous driving mode.

The present application discloses a method and apparatus for controlling display in a screen projection scenario, a device, a medium and a program product, relating to the technical fields of autonomous driving, Internet of Vehicles, intelligent voice, and screen projection in artificial intelligence. The specific implementation is: receiving a voice interaction instruction corresponding to a voice application; if a first page corresponding to a first application in at least one non-voice application has been projected onto a screen of a terminal device, adding to-be-displayed content corresponding to the voice application to the first page to obtain a to-be-projected page corresponding to the first application; and projecting the to-be-projected page onto the screen of the terminal device. The above process can reduce a delay in displaying an image projected on the screen.

A head-up display system for a motor vehicle includes a projection unit for providing a display image; a transparent holographic light guide display panel with a display surface in order to output a display image coupled into the display panel via a coupling-in region on a display surface, and a light guide which runs in a non-linear manner in order to guide a display image from the projection unit to the coupling-in region of the display panel.

A vehicular lighting assembly includes an plurality of micro-LEDs disposed at a substrate. Width dimension of each individual micro-LED of the plurality of micro-LEDs is less than 500 microns, and length dimension of each individual micro-LED of the plurality of micro-LEDs is less than 500 microns. Packing density of micro-LEDs of the plurality of micro-LEDs at the substrate is at least 10 micro-LEDs per square centimeter. Each individual micro-LED of the plurality of micro-LEDs, when the vehicular lighting assembly is operated to emit light, passes less than 4 mA electrical current. The vehicular lighting assembly is configured to be disposed at a portion of a vehicle equipped with the vehicular lighting assembly, With the vehicular lighting assembly disposed at the portion of the vehicle, light emitted by the plurality of micro-LEDs, when the vehicular lighting assembly is operated to emit light, is viewable at the portion of the vehicle.