A vehicular camera system includes a camera module having an imager assembly, a main circuit board and a camera housing. The imager assembly includes (i) an imager disposed on an imager circuit board and (ii) a lens holder having a lens assembly that includes a lens barrel accommodating a lens. The imager assembly includes a flexible ribbon cable that electrically connects to an electrical connector at a multilayered PCB of the main circuit board. The camera housing includes an upper cover and a lower cover and includes a forward portion and a rearward portion. The main circuit board is accommodated within the forward and rearward portions, and the imager is disposed at the rearward portion and is not disposed at the forward portion of the camera housing. The lens holder is attached at the upper cover of the camera housing.

A vehicular camera system includes an attaching structure configured to attach at an in-cabin side of a vehicle windshield. A camera module accommodates a circuit board and an imager and the camera module includes a lens aligned with the imager. The attaching structure includes a camera module receiving portion having an opening at a lower portion of the camera module receiving portion. With the attaching structure attached at the in-cabin side of the vehicle windshield, the camera module is inserted upward through the opening and is at least partially received in the camera module receiving portion to attach the camera module at the camera module receiving portion. With the attaching structure attached at the in-cabin side of the vehicle windshield and with the camera module at least partially received in the camera module receiving portion, the imager views through the vehicle windshield and forward of the vehicle.

An ECU generates an overhead image including a vehicle and a vehicle surrounding area, on the basis of a plurality of images taken by a plurality of cameras mounted on the vehicle. When a distance between an object existing in an overlapping portion of imaging areas of the plurality of cameras and the vehicle is within a threshold and the object exists in a traveling direction of the vehicle, the overlapping portion is divided into two pairs of a road surface image and an object image, and combination is performed by alpha blending with an α value for the object image being set to 1 and an α value for the road surface image being set to 0 for an area that is the object image in one of the two pairs and is the road surface image in the other of the two pairs, to generate the overhead image.

An around view monitoring system according to an embodiment of the present disclosure includes a first image processor configured to generate a top view image by stitching a plurality of images received from a plurality of cameras mounted to a vehicle, process the top view image based on a display setting, and control to display the processed top view image on a display; and a second image processor configured to process an image received from at least one camera among the plurality of cameras based on a recognition setting, and detect an object in the processed image.

A vehicle rearward monitoring system includes: a lower camera that captures a road surface behind the truck; an upper camera disposed above the lower camera in the truck to capture the road surface behind the truck; a conversion unit that converts lower and upper camera images G1 and G2 captured by the lower and upper cameras into lower and upper bird's-eye views T1 and T2; an object detection unit that compares upper and lower bird's-eye views T2 and T1 to detect the object on the road surface from a difference of a corrected portion hidden by the object on the road surface in upper and lower camera images G2 and G1; and a collision possibility determination unit that makes a driver of the truck recognize a possibility of collision when there is a possibility of collision with the object detected by the object detection unit with the truck.

A parking control apparatus includes a control unit capable of executing backward parking assist control based on surrounding information. In a case when a parking space is detected, when a specific condition to be satisfied when the parking space has a relatively narrow width is satisfied, the control unit executes guidance control as the backward parking assist control. The guidance control is control for moving a vehicle from a current position to a guidance target position in front of the parking space, so that the vehicle stops at the guidance target position in a posture in which: a vehicle’s longitudinal axis is parallel to a long-side direction of the parking space; a vehicle’s width is included in the width of the parking space when viewed from front; and the parking space is in closer proximity to a rear end portion than to a front end portion of the vehicle.

A vehicular control system includes a central control module vehicle, a plurality of vehicular cameras disposed at a vehicle and viewing exterior of the vehicle, and a plurality of radar sensors disposed at the vehicle and sensing exterior of the vehicle. The central control module receives vehicle data relating to operation of the vehicle. The central control module is operable to process (i) vehicle data, (ii) image data and (iii) radar data. The central control module at least in part controls at least one driver assistance system of the vehicle responsive to (i) processing at the central control module of vehicle data, (ii) processing at the central control module of image data captured by at least the forward-viewing vehicular camera and (iii) processing at the central control module of radar data captured by at least a front radar sensor.

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.

An image generation device includes: an image acquisition unit which acquires images taken by cameras installed in a vehicle; a storage unit which stores self vehicle data indicating the vehicle having such gloss that a certain region is higher in brightness than the other region; a bird's eye image generation unit which generates a neighborhood image that is an image of the vehicle and a neighborhood of the vehicle as viewed from a virtual point of view based on the acquired images; a 3D image generation unit which generates a three-dimensional self-vehicle image being a three-dimensional image of the vehicle; and an image synthesis unit which generates a synthesized image in which the self-vehicle image is superimposed on the neighborhood image, and the 3D image generation unit generates the three-dimensional self-vehicle image based on the self vehicle data that is read out from the storage unit.

Systems and methods for generating an image of the surroundings of an articulated vehicle are provided. According to an aspect of the invention, a processor determines a relative position between a first vehicle of an articulated vehicle and a second vehicle of the articulated vehicle; receives a first image from a first camera arranged on the first vehicle and a second image from a second camera arranged on the second vehicle; and combines the first image and the second image based on the relative position between the first vehicle and the second vehicle to generate a combined image of surroundings of the articulated vehicle.