A vehicular display system includes a camera that is disposed in a vehicle and that views a hand of a driver of the vehicle. A heads up display system establishes a heads up display viewable by the driver and derived at least in part from image data captured by the camera. The heads up display includes (i) information representative of user actuatable inputs for controlling at least one accessory of the vehicle and (ii) images representative of at least a part of the driver's hand. The images representative of at least a part of the driver's hand are derived at least in part from image data captured by the camera. The images representative of at least a part of the driver's hand are partially transparent so the information representative of the user actuatable inputs are viewable through the images representative of at least a part of the driver's hand.

A video display system for a vehicle includes a video display device disposed in the vehicle so as to be viewable by a driver of the vehicle. A camera is disposed at the vehicle and having an exterior field of view and operable to capture image data. A control includes a data processor. The control, responsive at least in part to processing by the data processor of captured image data, detects an object present exterior of the vehicle that is in the field of view of the camera, and determines if the detected object constitutes a hazardous condition. Responsive to determination of the hazardous condition, the control controls the video display device to automatically display an alert to the driver of the vehicle, with the alert including display of video images of the object that are derived from captured image data or a graphic overlay on displayed video images.

A vehicle rear monitoring system includes a camera that captures an image of an area to a rear of a vehicle, and a processing unit that processes the image captured by the camera. The processing unit creates a first vehicle rear image that is displayed in a first display area that is a portion of a display area of a display device, when traveling forward, and creates a second vehicle rear image that is displayed in a second display area that is within the display area of the display device and that is an area that includes the first display area and is larger than the first display area, when traveling backward.

A vehicular interior rearview mirror assembly includes a mirror head having a mirror casing and a transflective reflective element. Individual user input elements of a plurality of user input elements are arranged in a row below the transflective reflective element. At least one of the individual user input elements is a user input element for an imaging system of the vehicle. Each individual display element of a plurality of display elements is associated with a respective user input element of the plurality of user input elements. Each individual display element of the plurality of display elements is selectively activated by activation of its respective user input element. Each individual display element and its respective user input element are located local to one another such that a cognitive relationship between actuation by a user of the respective user input element and activation of the associated individual display element is established.

In accordance with an example embodiment, a vehicle includes a moveable member, posture sensing system, bird's-eye camera system, display, and controller. The posture sensing system indicates the moveable member's posture. The bird's-eye camera system provides images of its field of view, including the ground adjacent to the vehicle. The controller receives a posture signal from the posture sensing system, receives images from the camera system, creates a rendered vehicle representation, creates a rendered path projection, and generates a dynamically augmented bird's-eye view then displays it on the display. The moveable member is positioned in the rendered vehicle representation using the posture signal. The rendered path projection includes an outer envelope line projecting the path of an outermost point of the vehicle, determined using the posture signal. The dynamically augmented bird's-eye view is generated using the images, rendered vehicle representation, and rendered path projection.

A multi-camera vision system utilized onboard a work vehicle includes, among other components, vehicle cameras and a display device utilized within an operator station of the work vehicle. The vehicle cameras provide vehicle camera feeds of the work vehicle's surrounding environment, as captured from different vantage points. A controller, which is coupled to the vehicle cameras and to the display device, is configured to: (i) generate, on the display device, a multi-camera display including framing icons, gallery display areas within the framing icons, and a main display area; (ii) identify a currently-selected vehicle camera feed and one or more non-selected vehicle camera feeds from the multiple vehicle camera feeds; and (iii) present the currently-selected vehicle camera feed in the main display area of the multi-camera display, while concurrently presenting the one or more non-selected vehicle camera feeds in a corresponding number of the gallery display areas.

A video processing unit generates a conversion video having the same angle of view as an angle of view of a mirror image by converting a camera video. The video processing unit causes the generated conversion video to be displayed in a display region such that the conversion video is superimposed on the mirror image.

Provided is a control method of an electronic apparatus. The control method of an electronic apparatus includes: calculating an average speed of a vehicle when a specific event occurs; generating an object indicating a relationship between the calculated average speed and an event speed corresponding to the specific event; and outputting the generated object through augmented reality.

A method displays information graphically on an image captured by a vehicular optical system. The method includes capturing the image and identifying an object in the image. The method the assigns a priority level to the object based on a predetermined criterion. The object is altered based on its priority level to create an altered object. An altered object may have a changed color, a colored halo surrounding it, or a colored object inside it. Other possible ways to alter the way the object looks are possible. The altered object is displayed in the image in place of the object on a mobile device to alert a person of its presence and the priority level associated therewith.

The present disclosure provides a rear view mirror arrangement for a motor vehicle. The rear view mirror arrangement includes an image capture unit. The image capture unit includes a housing and a camera disposed in the housing. The housing has a pane that switches between a transparent state and a reflecting state. The rear view mirror arrangement further includes a display unit for displaying an image captured by the camera. The rear view mirror arrangement operates under a camera mode and a mirror mode. When the rear view mirror arrangement is set in the camera mode, the pane is set in the transparent state so that the camera is configured to capture an image of the surroundings of the motor vehicle. When the rear view mirror arrangement is set in the mirror mode, the pane is set in the reflective state.