A vehicular vision system includes a plurality of cameras and an ECU. The cameras are in communication with one another via a vehicle network and image data captured by the cameras is provided to the ECU. Responsive to a type of driving maneuver of the vehicle, (i) the ECU generates a first control signal that enables automatic control of exposure, gain and white balance of one camera of the plurality of cameras and (ii) the ECU generates respective second control signals that disable automatic control of exposure, gain and white balance of at least one other camera of the plurality of cameras. Responsive to processing of captured image data, composite video images derived from image data captured by the plurality of cameras are synthesized, and composite images are displayed that provides bird's eye view video images derived from video image data captured by the cameras.

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.

An image display apparatus has: a first imaging device (11B) for imaging an area on the rear of a vehicle (1); a second imaging device (11BL, 11BR) for imaging an area on the rear and side of the vehicle; a synthesizing device (12) for generating a synthesized image in which a first image captured by the first imaging device and a second image captured by the second imaging device are adjacent to each other and a vanishing point of the first image in the synthesized image is different from a vanishing point of the second image in the synthesized image; and a displaying device (13) for displaying the synthesized image.

A driving support device is configured to acquire a captured image from an imaging device configured to capture an image in surrounding of a moving body and to generate an instruction image based on the captured image such that a position of a predetermined portion of the moving body is fitted to a position of a reference line in the captured image. A driver may accurately grasp the position relationship between a moving body (e.g. a vehicle) and an obstacle with reference to the instruction 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.

Provided herein is an apparatus for displaying a forward blind spot situation. The apparatus for displaying a forward blind spot situation includes a front camera capturing a blind spot of a driver, a display device displaying image information on the blind spot of the driver captured through the front camera, and a processor controlling the image information on the blind spot of the driver captured through the front camera to be seamlessly output at a position of a driver's gaze.

The present technology relates to an image processing apparatus, an image processing method, and an image processing system enabling the presentation of more useful information. An image in a viewpoint direction corresponding to the state of an object is generated from a captured image. Alternatively, an image of the periphery of the object is captured at a wide angle, and then an image obtained by projecting a part of the wide-angle captured image thus obtained onto a plane in a viewpoint direction corresponding to the state of the object is displayed. For example, an image of the periphery of an object is captured at a wide angle, an image in a viewpoint direction corresponding to the state of the object is generated from the obtained captured image, and the generated image is displayed. The present disclosure can be applied to, for example, an information processing apparatus, an electronic apparatus, a vehicle, a computer, a server, a program, a storage medium, a system, or the like.

A driving assistance system includes a camera and at least one processor. The camera is disposed on a mounting apparatus that is rotatably coupled to a vehicle and that rotates about a rotation axis that is spaced apart from the camera. The camera is configured to rotate together with the mounting apparatus from a first point to a second point, and to capture an external image of the vehicle at the first point and the second point. The processor is configured to control the camera to capture a first image at the first point and a second image at the second point, detect an object around the vehicle based on the first image and the second image, and determine a distance between the object and the vehicle based on the first image and the second image.

An information processing apparatus includes a memory and a processor coupled to the memory that obtains projection information used for generating a three-dimensional overhead image by projecting a plurality of image data imaged by a plurality of imaging devices to a three-dimensional projection surface when the plurality of imaging devices are installed in a first mobile object, that inputs size information of a second mobile object that is different from the first mobile object, that corrects the projection information based on a size ratio between the first mobile object and the second mobile object, calculated based on the size information of the second mobile object, and that stores corrected projection information in the second mobile object.

A periphery monitoring device according to an embodiment includes, as an example, a processor that generates a display image obtained by viewing, from a virtual viewpoint, a point of gaze in a virtual space including a model obtained by pasting a captured image obtained by imaging a surrounding area of a vehicle using an imaging unit provided on the vehicle to a three-dimensional plane around the vehicle, and including a three-dimensional vehicle image; and outputs the display image to a display. The processor changes a height of the virtual viewpoint in conjunction with a movement including a directional component in a vehicle width direction of the vehicle image when an instruction is made through an operation input unit to move the virtual viewpoint.