According to one embodiment, an image synthesis device for an electronic mirror includes a rear camera which obtains a first image from a first position, and a side camera which obtains a second image of the same direction with a view of the rear camera from a second position. The second image includes a view obstruction. When a part of the first image is connected as a complementary image to the view obstruction of the second image, an image processing device converts an image of the view obstruction into a translucent image, superimposes the complementary image on the translucent image, and obtains a third image which remains an outline of the complementary image.

A rearview display system is provided for a vehicle having: a rear camera generating a rearward video stream, a right-side camera generating a right-side stream, and a left-side camera generating a left-side stream. The system includes a processing circuit for generating a composite video stream from: (a) the rearward stream and the right-side stream, (b) the rearward stream and the left-side stream, and (c) at least the rearward stream. When the composite stream is formed from the rearward stream and the right-side stream, the rearward stream extends across the whole composite stream with the exception of a right corner where the right-side stream is superimposed over the rearward stream. When the composite stream is formed from the rearward stream and the left-side stream, the rearward stream extends across the whole composite stream with the exception of a left corner where the left-side stream is superimposed over the rearward stream.

A vehicular vision system includes a video display screen and a video processor operable to process captured video image data captured by a rearward-viewing color video camera at the vehicle. The video display screen includes a left display region at a left portion, a right display region at a right portion, and a middle display region that spans between the left and right display regions. The video display screen (i) displays at the left display region video images derived from captured image data to display a scene occurring in a left side lane, (ii) displays at the right display region video images derived from captured image data to display a scene occurring in a right side lane and (iii) displays at the middle display region video images derived from captured image data to display a scene occurring rearward of the vehicle in the lane the equipped vehicle is travelling in.

A vehicular collision mitigation method includes disposing at a vehicle a plurality of cameras, at least two non-camera sensors, and a control that processes data captured by the cameras and non-camera sensors. When the equipped vehicle is traveling forward, and via processing at the control of provided data captured by the forward viewing camera and the at least two non-camera sensors, it is determined if the vehicle is approaching a pedestrian or other vehicle forward of the vehicle. Responsive to such determination, braking by an automatic emergency braking system is controlled to mitigate collision with the pedestrian or other vehicle. Responsive to determination that a following vehicle is following the vehicle within a threshold distance from the vehicle and is approaching the vehicle above a threshold rate of approach, braking by the automatic emergency braking system is adjusted to mitigate collision at the rear of the vehicle by the following vehicle.

A vehicular trailer hitching assist system includes a rear backup camera disposed at a rear portion of a vehicle and a control disposed in the vehicle. A display device includes a video display screen operable to display video images for viewing by a driver of the vehicle. Responsive to the driver initiating a hitching maneuver event by engaging reverse gear of the vehicle, rear backup video images derived from image data captured by the rear backup camera are displayed at the video display screen. An overlay overlays the displayed rear backup video images and aids in guiding connection of a trailer hitch of the equipped vehicle to a trailer tongue of a trailer. Continued display of rear backup video images that are overlaid by the overlay is ceased upon elapse of a threshold period of time or upon exceeding a threshold speed or upon exceeding a threshold distance traveled.

Disclosed are a method of recognizing a vehicle based on an image and an apparatus and vehicle therefor. A method of recognizing a rear vehicle in a vehicle includes acquiring an image captured by a camera while driving, determining a time zone based on the acquired image, performing object recognition based on the determined time zone, determining image coordinates of the rear vehicle based on a result of the object recognition, and converting the determined image coordinates into a distance.

A vehicle includes a first sensor for acquiring image data of a rear side, a second sensor for acquiring gaze data of a user, a display for outputting a screen of the image data, an input device for setting a sensitivity to a movement of a user gaze, and a controller for determining reference vector data based on the gaze data at a point in time at which the gaze data starts to be acquired or the gaze data that is preset, for outputting a control signal to output a screen of the image data corresponding to the reference vector data, for acquiring result data including relative position data and relative velocity data of gaze movement data with respect to the reference vector data, and for controlling a signal to output a screen of the image data.

This image generation device is provided with: an image acquisition unit that acquires a rear-side image of the rear side of a vehicle; and an image generation unit. When the rear-side image includes an overlapped portion where an image region, in which an auxiliary line for assisting in the backward driving of the vehicle is overlaid, overlaps an image region in which a specific target is positioned, the image generation unit generates, in at least the overlapped portion, an image in which the auxiliary line is not overlaid or is overlaid in a semi-transparent state; and when the rear-side image does not include the overlapped portion, the image generation unit generates an image in which the auxiliary line is overlaid on the rear-side image.

An apparatus including an interface and a processor. The interface may be configured to receive video frames generated by a plurality of capture devices. The processor may be configured to perform operations to detect objects in the video frames received from a first of the capture devices, determine depth information corresponding to the objects detected, determine blending lines in response to the depth information, perform video stitching operations on the video frames from the capture devices based on the blending lines and generate panoramic video frames in response to the video stitching operations. The blending lines may correspond to gaps in a field of view of the panoramic video frames. The blending lines may be determined to prevent the objects from being in the gaps in the field of view. The panoramic video frames may be generated to fit a size of a display.

A vehicular video mirror system includes a video display screen disposed in a mirror head. The system includes a vehicle-mounted rear backup camera and a trailer-mounted rearward viewing camera. The trailer-mounted camera includes an imaging array with a first subset of pixels representative of an upper rearward-view region of the field of view and a second subset of pixels that represents a lower rearward-view region of the field of view. With the trailer hitched to the vehicle and responsive to the vehicle being set for forward propulsion, the video display screen displays images derived from the first subset of pixels and not from the second subset of pixels. With the trailer hitched to the vehicle and responsive to the vehicle being set for rearward propulsion, the video display screen displays images derived from the second subset of pixels and not from the first subset of pixels.