An augmented reality information displaying device according to the embodiment includes a storage, a display-position deciding unit, and a display controller. The storage stores augmented reality information associated with a real position. The display-position deciding unit decides a display position of the augmented reality information on a display screen of a transmission-type display device based on a real position of a user that visually recognizes the display screen, a real position of the display screen, the real position in the scene through the display screen associated with the augmented reality information. The display controller controls to display, at a display position decided by the display-position deciding unit, the augmented reality information corresponding to a mode according to positional relationship between the real position of the user and the real position associated with the augmented reality information in the scene.

Disclosed herein are a display system of a vehicle and a method of driving the same. The display system includes a plurality of camera modules configured to capture a front side, a rear side, a rear left side, and a rear right side relative to the vehicle and generate image data, a plurality of display panels configured to receive the image data and display front side images, rear side images, rear left side images, and rear right side images relative to the vehicle, a driver pupil detection sensor configured to sense a pupil of a driver and generate pupil position data, a driver posture detection sensor configured to sense a position of the driver, a body direction thereof, and a head height thereof and generate posture data, a calculator configured to calculate a position of a field of view of the driver on the basis of the pupil position data and the posture data and generate a display correction value on the basis of the position of the field of view, and a display correction device configured to adjust a horizontal tilt and a vertical tilt of each of the plurality of display panels on the basis of the display correction value.

Provided is an electronic apparatus and method for providing an image of surroundings of a vehicle. The electronic apparatus for providing an image of surroundings of the vehicle includes a first image sensor creating a first image by capturing surroundings of the vehicle; a second image sensor creating a second image by capturing surroundings of the vehicle; and a processor configured to obtain feature information of each of the first image and the second image and use a portion of the first image and a portion of the second image to create a composite image that represents the surroundings of the vehicle, based on the obtained feature information.

A vehicular multi-camera surround view system includes a front camera, a driver-side camera, a passenger-side camera and a rear backup camera. Image data captured by the cameras is conveyed to an electronic control unit. The electronic control unit is operable to combine image data conveyed from the front camera, the driver-side camera, the passenger-side camera and the rear backup camera to form composite video images, which are output for display at a display device. Rear backup video images are displayed no later than two seconds after the driver of the vehicle first changes propulsion of the vehicle during a new ignition cycle to reverse mode. Upon changing propulsion of the vehicle during the new ignition cycle to reverse mode to commence a backup event subsequent to the first backup event, the video display screen displays video images derived, at least in part, from image data captured by the rear backup camera.

A movable carrier auxiliary system includes a state detecting device, a braking device, an environmental detecting device and an emergency brake controlling device. The state detecting device detects a movement state of a movable carrier. The environmental detecting device includes at least one image capturing module and an operation module. The brake controlling method thereof includes receive the movement state detected by the state detecting device, and deriving an operating distance based on the movement state with the operation module; capture the environmental image with the image capturing module; determine whether there is an obstruction within the operating distance based on the environmental image; automatically actuate the braking device with the emergency brake controlling device when there is the obstruction within the operating distance in the environmental image, thereby to stop the movable carrier within the operating distance.

A work vehicle fleet includes a first model of work vehicle and a second model of work vehicle, different than the first model. The first model includes a first set of display devices; a first set of cameras; and a first controller configured to display a standard set of feeds from the associated first side, second side, and central location of the first set of cameras at the first set of display devices so that the associated feeds are arranged at the first side, the second side, and the central location, respectively, relative to the first operator FOV. The second model includes a second set of display devices; a second set of cameras; and a second controller configured to display so that the associated feeds are arranged at the first side, the second side, and the central location, respectively, relative to the second operator FOV.

A camera device having an enlarged or wide-angle field of view generates images of surroundings simultaneously using only one image capturing unit, such as an image sensor, for example. The camera device uses a diverting unit disposed upstream of the image capturing unit. The diverting unit includes so-called holographic optical elements which, based on their deflection structures, divert or deflect light so that the camera device can capture the wide-angle field of view, without generating imaging aberrations on the resulting image(s). The deflection structures are wavelength-selective and/or angle-selective. The total field of view is subdivided into individual angle-of-incidence regions by virtue of the properties of the deflection structures.

A motor vehicle includes a motor vehicle body having an interior forming a passenger compartment. At least one camera is arranged on the outside of the motor vehicle body for imaging an area to the side and behind of the motor vehicle. In the interior of the motor vehicle, particularly in the region of an instrument panel, a monitor or display is arranged in or on an air outlet. The monitor is connected to the camera for continuously displaying the imaged area to occupants, and in particular a driver, in the passenger compartment.

A vehicle interior component configured to provide a user interface for interaction with a vehicle system is disclosed. The component may comprise a composite structure comprising a substrate, cover and functional layer. The user interface may comprise a light source/display and an input device comprising a switch and/or control element. The switch may project through a hole in the cover. The functional layer may comprise a soft layer, foam, fleece, fabric, textile, spacer, etc.; the functional layer may comprise a light-transmissive material. The light source/display may provide illumination through a light-transmissive section of the substrate, the functional layer and/or the cover. Illumination may indicate location of the input device. The light-transmissive section of the substrate may comprise illuminated display elements for the light display. Operation of the user interface may comprise an animation effect from illumination of display elements in a sequence.

A vehicular vision system includes a driver-side camera and a passenger-side camera each having a lens and a two dimensional imaging array sensor. The cameras are disposed at respective sides of a body of a vehicle and each have a field of view exterior of the vehicle and at least rearward of the vehicle. Each imaging array sensor has a center region. Each lens is configured to focus light at the respective imaging array sensor, and the lens has a center axis. The lens is disposed at the respective imaging array sensor with the center axis of the lens laterally offset from the center region of the imaging array sensor in a direction away from the respective body side. A video display disposed in the vehicle and viewable by a driver of the vehicle displays video images derived from image data captured by the cameras.