A method and apparatus for generating an image of vehicle surroundings are disclosed, including: capturing vehicle surroundings by vehicle cameras arranged on a vehicle body of a vehicle, and generating camera images by the cameras. The camera images of adjacent cameras have overlapping image regions), generating a virtual representation of the surroundings in a virtual three-dimensional space, during which the camera images are projected onto a virtual projection surface in the space. A non-stationary virtual camera in the virtual space determines a position and/or orientation thereof. A first selection region is placed on the surface in a first overlapping image region depending on a virtual camera field of vision, at least one image parameter of a first vehicle camera in the first selection region is calculated, and at least one second vehicle image parameter is adjusted to the at least one first vehicle image parameter in the first selection region.

A camera system is installed on the front end of a vehicle, either on the left front, the right front, or both sides. The camera is linked via wired or wireless connection to an onboard computer and a navigation display that is located within the passenger compartment of the vehicle. The driver reviews a visual description on the display of any oncoming traffic in the form of motor vehicles, pedestrians, cyclists, animals and the like on the navigation display via a single screen, split screen or alternating screens. The camera system can include a speed sensor that detects when the vehicle reaches a threshold speed to activate or de-activate the camera. Alternatively, the computer can activate the system when a turn signal is activated, and de-activate the system when the turn signal is no longer activated. This camera system can be retrofitted into older vehicles.

A display image is obtained in accordance with a deviation of a viewpoint position of a driver from a reference viewpoint position, on the basis of a captured image obtained by capturing an image on a rear side from a vehicle. The reference viewpoint position is updated on the basis of a long-term fluctuation of the viewpoint position. For example, the reference viewpoint position is not updated when a line-of-sight of the driver is in a certain region including a display unit that displays a display image. For example, when a viewpoint position of the driver enters a certain region corresponding to a seated state, there is registered, as an initial reference viewpoint position, a viewpoint position of the driver in a case where a line-of-sight of the driver is continuously present for a certain period of time on the display unit that displays a display image.

A measurement unit measures a first generation time of a first vanishing point of a plurality of radially diverging motion vectors generated in a front image region and a second generation time of a second vanishing point of a plurality of converging motion vectors generated in the front image region within a predetermined period of time in a state in which an image rotation unit adjusts positions of the front image region and a rear image region in a circumferential direction. The image rotation unit keeps the positions of the front image region and the rear image region in the circumferential direction when the first generation time measured by the measurement unit is longer than the second generation time, and rotates the captured image to reverse the front image region and the rear image region when the first generation time is not longer than the second generation time.

A vehicle electronic mirror system including: a rearward image capture section configured to capture a rearward video image from a vehicle; a video image processing section including: a computation section configured to extract a feature point in the rearward video image and to compute an optical flow direction of the feature point, a determination section configured to determine whether or not the optical flow direction of the feature point is heading toward a point-at-infinity side in the rearward video image, and a processed video image generation section configured to generate a processed video image in which visibility of a region in the rearward video image corresponding to a feature point heading toward the point-at-infinity side is reduced relative to a visibility of other regions in the rearward video image; and a display device configured to display the processed video image toward an occupant.

A viewing system for a vehicle having a towing vehicle (5) and a trailer (6) pivotally mounted on the towing vehicle (5), with a first acquisition device (2a, 2b) for capturing first image data of a first area; a second acquisition device (3a, 3b) for capturing second image data of a second area overlapping the first area, wherein the first and second acquisition devices (2a, 2b, 3a, 3b) have different optical characteristics; a device (4a, 4b) for processing the first and second image data to extract first (7) and second (8) image areas; display (1a, 1b) for same-filed displaying the image areas; a pivot angle determining device to determine pivot angle between towing vehicle (5) and trailer (6); and a display switch for switching display of the first area and second area on a switching condition.

A vehicular control system includes a central control module vehicle, a plurality of image capture sensors, at least one radar sensor and at least one lidar sensor disposed at an equipped. The central control module receives vehicle data relating to operation of the vehicle. During a driving maneuver of the vehicle, and responsive at least in part to fusion at the central control module of (i) captured image data, (ii) captured radar data and (iii) captured lidar data, a pedestrian or other vehicle may be detected or the speed of the equipped vehicle may be controlled. Responsive to the central control module determining that the detected pedestrian constitutes a potentially hazardous driving condition for the equipped vehicle, the central control module may control at least one selected from the group consisting of (i) braking of the equipped vehicle and (ii) steering of the equipped vehicle.

A display method is a display method performed by a display device that operates in conjunction with a mobile object, and includes: determining which one of first surrounding information, which is video showing a surrounding condition of the mobile object and is generated using two-dimensional information, and second surrounding information, which is video showing the surrounding condition of the mobile object and is generated using three-dimensional data, is to be displayed, based on a driving condition of the mobile object; and displaying the one of the first surrounding information and the second surrounding information that is determined to be displayed.

A display control device includes a display configured to display a peripheral image indicating a peripheral situation of a host vehicle in a display range viewed from a predetermined virtual viewpoint and a display range determiner configured to determine a viewpoint position of the virtual viewpoint, an angle of view from the virtual viewpoint, or a gaze direction from the virtual viewpoint in accordance with a traveling condition of the host vehicle.

A parking assistance device includes an imager that captures an image of a surrounding of a vehicle, and a display that displays a guidance image for guiding the vehicle from a parking start position to a target parking position and displays a moving area in which the vehicle can move during a parking operation. An area and dimension of the moving area displayed on the display changes based on a change in a steering angle of the vehicle.