Provided is an image pickup system including: a front camera sensor; and a camera sensor for image generation having a second horizontal angle of view. The latter camera sensor includes: an image sensor having an image pickup surface; and an optical system having a lens. The image sensor has: a specific region in which light from an object positioned within a diagonal lateral azimuth angle range is to be imaged onto the image pickup surface; and a residual region in which light from an object positioned within a residual azimuth angle range is to be imaged onto the image pickup surface, the residual azimuth angle range being obtained by excluding the diagonal lateral azimuth angle range from the second horizontal angle of view. The lens has a curved surface formed so that a horizontal pixel density in the specific region becomes larger than that in the residual region.

Techniques are disclosed for systems and methods for water non-water segmentation of navigational imagery to assist in the autonomous navigation of mobile structures. An imagery based navigation system includes a logic device configured to communicate with an imaging module coupled to a mobile structure and/or configured to capture images of an environment about the mobile structure. The logic device may be configured to receive at least one image from the imaging module; determine a water/non-water segmented image based, at least in part, on the received at least one image, and generate a range chart corresponding to the environment about the mobile structure based, at least in part, on the determined water/non-water segmented image and/or the received at least one image.

An imaging device of the present disclosure includes an event detection sensor that detects an event, and a control unit that controls the event detection sensor. Then, the control unit switches a resolution of the event detection sensor depending on a traveling state of a mobile body. Furthermore, the imaging system of the present disclosure includes an event detection sensor that detects an event; a control unit that switches a resolution of the event detection sensor depending on a traveling state of a mobile body; and an object recognition unit that performs event recognition on the basis of an event signal output from the event detection sensor.

A peripheral image generation device acquires a plurality of camera images obtained from a plurality of cameras each of which captures a periphery of the vehicle. The peripheral image generation device stores a traveling direction camera image that is a part or all of images included in the plurality of camera images and captured at least in a traveling direction of the vehicle. The peripheral image generation device generates an underfloor transparent image that is a composite image transmitting a bottom of the vehicle based on the plurality of camera images and the traveling direction camera image.

A vehicular vision system includes a rear backup camera at a vehicle. During a driving maneuver, the system partitions each frame of image data captured by the rear backup camera into (i) a left side image data portion, (ii) a right side image data portion and (iii) a rear image data portion. During the driving maneuver, and based at least in part on motion of the vehicle, the system (i) combines left side image data portions of multiple frames of captured image data and (ii) combines right side image data portions of multiple frames of captured image data. During the driving maneuver, the video display displays (i) video images derived from the rear image data portion, video images derived from the combined left side image data portions and the combined right side image data portions for viewing by the driver of the vehicle during the driving maneuver of the vehicle.

A vehicular display system includes an electronic control unit (ECU) and a plurality of cameras disposed at the vehicle. The cameras capture image data and provide captured image data to the ECU. The system includes a video display screen and a video mirror display screen that are operable to display video images derived from video images provided by the ECU. When the vehicle is traveling forward at a speed below a threshold speed, the ECU generates rearward view video images derived from image data captured by a rearward viewing camera and provides the rearward view video images to the video display screen. When the vehicle is traveling forward at a speed at or above the threshold speed, the ECU generates rearward view video images derived from image data captured by a rearward viewing camera and provides the rearward view video images to the video mirror display screen.

There is provided a periphery display device for a work machine, which displays a bird's-eye view image around the work machine. A display magnification of a region between a peripheral line having a turning radius of the work machine and an offset peripheral line surrounding the peripheral line is different from a display magnification of a region inside the peripheral line.

A trailer-camera system for a vehicle coupled to a trailer. The system includes a first plurality of cameras configured to capture a video image including a region of interest surrounding the trailer, a second plurality of cameras configured to capture a video image including a region of interest surrounding the vehicle, and an electronic processor. The processor is configured to receive images from the first and second plurality of cameras and determine a trailer angle. The processor is further configured to generate a first 360-degree image view of an area surrounding the trailer based on an image stitching of the first plurality of images, generate a second 360-degree image view of an area surrounding the vehicle based on an image stitching of the second plurality of images, and generate a combined 360-degree image view from the first and second views based on the trailer angle.

A vehicular trailer guidance system includes a human machine interface provided in the vehicle and operable by a driver of the vehicle during a backing up maneuver of the vehicle with a trailer hitched thereto. The human machine interface comprises a rotary knob and operates (i) in a backing up trailer left-backup mode when rotated counter-clockwise, (ii) in a backing up trailer straight-backup mode when the rotary knob is pushed or pulled and (iii) in a backing up trailer right-backup mode when rotated clockwise. Responsive to selection by the driver of the backup mode, the system sets a desired trailer angle relative to the longitudinal axis of the vehicle to an angle that is commensurate with a driver-selected setting of the rotary knob. The system controls steering of the vehicle to back up the trailer to have the determined trailer angle coincide with the set desired trailer angle.

A driving assistance apparatus is provided in which the detection range of a left-front-corner sonar (12a) located at the vehicle's left front corner is included in the field of view of a second imaging means (14) located at the vehicle's left front corner. When the left-front-corner sonar (12a) detects a three-dimensional object at the vehicle's left front corner, an image processing means (3) synthesizes an image of the image created using a second imaging means (14) and the images created with four cameras (7a-7d) for imaging the complete periphery of the vehicle, and creates a bird's-eye-view image (40b). The detection range of the left-front-corner sonar (12a) is included within a region of the bird's-eye image (40b) on the basis of the image created with the second imaging means (14).