The present disclosure relates to a vehicle display device and a control method thereof, the vehicle display device comprising: a display unit; and a control unit that activates a navigation mode for guiding to a destination, and controls the display unit to display a virtual item indicating a driving direction that needs to be changed at a specific display angle when the driving direction needs to be changed within a preset distance on the basis of road information provided in the navigation mode while a vehicle is driving to the destination, wherein the control unit performs a control such that the display angle of the item changes on the basis of the angle of the driving direction that needs to be changed.

Often when there is a glare on a display screen the user may be able to mitigate the glare by tilting or otherwise moving the screen or changing their viewing position. However, when driving a car there are limited options for overcoming glares on the dashboard, especially when you are driving for a long distance in the same direction. Embodiments are directed to eliminating such glare. Other embodiments are related to mixed reality (MR) and filling in occluded areas.

Present invention discloses a night vision system for a vehicle and method of installation for the night vision system on the vehicle. The night vision system includes a mount, a night vision device detachably mountable on the vehicle using the mount. The night vision device is mounted pointing over a road for detecting one or more objects present on and alongside the road. The system further includes a display device configurable within an interior region of the vehicle for displaying a video stream received from the night vision device to a user driving the vehicle. The display device is configured to embody a program product for enabling the display device to receive, process and display the received video stream on the display device.

A vehicle display system according to an example embodiment of the present disclosure includes a camera configured to record images of an area outside a vehicle; a display configured to display a video feed of the recorded images to an occupant of the vehicle (e.g., on a display disposed within a vehicle cabin of the vehicle); and a processor operatively connected to the camera and display. The processor is configured to detect one or more objects in the recorded images; receive a selection of a particular one of the one or more objects from a vehicle occupant; and adjust the video feed based on the selection to keep the particular one of the one or more objects in a field of view of the video feed as the object moves relative to the vehicle.

A vehicle display system according to an example embodiment of the present disclosure includes a camera configured to record images of an area outside a vehicle; a display configured to display a video feed of the recorded images to an occupant of the vehicle (e.g., on a display disposed within a vehicle cabin of the vehicle); and a processor operatively connected to the camera and display. The processor is configured to detect one or more objects in the recorded images; receive a selection of a particular one of the one or more objects from a vehicle occupant; and adjust the video feed based on the selection to keep the particular one of the one or more objects in a field of view of the video feed as the object moves relative to the vehicle.

An imaging system of the present disclosure includes an event detection sensor that detects an event, and a controller that controls event detection at the event detection sensor. The event detection sensor is provided with a color filter on a per-pixel basis. In addition, the controller controls the event detection in a specific wavelength band based on the color filter. This makes it possible to detect information in various wavelength bands as events.

An imaging system of the present disclosure includes an event detection sensor that detects an event, and a controller that controls event detection at the event detection sensor. The event detection sensor is provided with a color filter on a per-pixel basis. In addition, the controller controls the event detection in a specific wavelength band based on the color filter. This makes it possible to detect information in various wavelength bands as events.

A digital imaging system and method of image data processing are provided. The system includes a main lens configured to focus light from a field of view for a plurality of depths of field and project a plurality of intermediary images representing the depths of field. An image sensor assembly is in a spaced relationship with the main lens and includes a light sensors grouped into sensor sub-arrays. An intermediate microlens array is disposed between the main lens and the image sensor assembly and includes intermediate micro lenses adjacent to and abutting one another to focus the intermediary images onto one of the sensor sub-arrays from a different perspective than another adjacent micro lens. A control unit captures and stores image data associated with the intermediary images and creates a three-dimensional depth map. The control unit also calculates distance information of objects to detect a gesture or obstacle.

A vehicle control device includes a display configured to display information, an inputter to which a user's operation is input, a driving controller configured to control at least one of a speed and steering of a vehicle, a determiner configured to determine a lane in which the vehicle is present when a first operation that allows a lane change by the vehicle is input to the inputter as a reference lane, and a display controller that is configured to cause the display to display a first image depicting a road on which the vehicle is present and a second image depicting the reference lane which are superimposed.

A detection system for vehicles adapted to record objects within a scenery at least in problematic viewing conditions includes a camera system establishing an optical path from a light entrance aperture via a lens system to an image recording unit with the image recording unit being adapted to record visible and IR light one or more of reflected or emitted from the scenery comprising at least one object, an IR filter arranged within the optical path to block at least a first part of the IR light not being the at least one object related from reaching the image recording unit, and a conversion filter arranged within the optical path to convert at least a second part of the IR light being the at least one object related to visible light of an image enhancing wavelength range.