A vehicular rear backup system includes a rear backup digital camera disposed at a vehicle and a display device having a video display screen disposed in an interior cabin of the vehicle and viewable by the driver of the vehicle. Rear backup video images that are derived from image data captured by the rear backup digital camera are displayed on the video display screen no later than two seconds after the driver of the vehicle first changes propulsion of the vehicle during a new ignition cycle to reverse mode to commence a first backup event. Until the first backup event is completed, the video display screen displays rear backup video images. During a backup event of the vehicle, image data captured by the rear backup digital camera is provided to and is processed by an image processor of the system to detect presence of an object rearward of the vehicle.

Provided is a driving support device configured to: generate a bird's-eye view image around an own vehicle from periphery images acquired from a plurality of periphery monitoring cameras, and generate a cropped bird's-eye view image by cropping an image of a cropping range including a blind spot range from the generated bird's-eye view image; generate a rear-lateral side converted image by converting a rear-lateral side direction image acquired from a rear-lateral side monitoring camera into an image in which left and right are inverted; and generate a combined image in which the generated cropped bird's-eye view image and the generated rear-lateral side converted image are arranged, and control a display device such that the generated combined image is displayed by the display device.

A view system for a vehicle (1) with a tractor (2) and a trailer (3). The view system has a capture unit (10) with an image sensor (12) for capturing image data of an area of view, around the vehicle, a processing unit (20) for processing the image data, and a reproduction unit (30) for reproducing at least one first image section (410) and one second image section (420) of the area of view (40) captured by the capture unit (10). The processing unit provides different resolutions of image data depending on the position of the tractor with respect to the trailer.

A vehicular trailer hitching assist system includes a camera disposed at a rear portion of a vehicle and viewing at least rearward of the vehicle. During a reversing maneuver of the vehicle toward a trailer that is spaced from the vehicle at a distance from the vehicle, the camera views at least a portion of a front profile of the trailer. An electronic control unit (ECU) includes an image processor operable to process image data captured by the camera. The vehicular trailer hitching assist system, via image processing at the ECU of image data captured by the camera during the reversing maneuver of the vehicle toward the trailer, determines a plurality of landmarks corresponding to the front profile of the trailer. Based at least in part on the determined plurality of landmarks, the vehicular trailer hitching assist system determines location of a trailer coupler of the trailer.

A rear-view mirror system comprises a mounting assembly arranged outside a motor vehicle, and a first image acquisition unit at least partially received within the mounting assembly configured to acquire a captured image from the exterior of the vehicle. A display device is provided inside the vehicle for displaying to a user a displayed image derived at least in part from the captured image. An electronics carrier comprises an electronic control unit (ECU) connected to the first image acquisition unit so as to generate an image signal for the display device to show the displayed image. The ECU is arranged, together with the electronics carrier, at least partially within the mounting assembly.

A dynamic imaging system is disclosed. The dynamic imaging system may comprise one or more imager, one or more input device, a controller, and/or a display. Each imager may be operable to capture a video stream having a field of view. In some embodiments, the controller may articulate the imager or crop the field of view to change the field of view in response to signals from the one or more input devices. For example, the signal may relate to the vehicle's speed. In other embodiments, the controller may apply a warp to the field of view. The warp may be applied in response to signals from the one or more input devices. In yet other embodiments, video streams from one or more imagers may be stitched together by the controller. Further, the controller may likewise move the stitch line in response to signals from the or more input devices.

A vehicular vision system includes a camera disposed at a vehicle, at least one non-vision sensor disposed at the vehicle, and a display system of the vehicle that displays video images for viewing by the driver of the vehicle. Image data captured by the camera and sensor data sensed by the non-vision sensor are provided to a control of the vehicle. Responsive at least in part to processing at the control of image data captured by the camera, video images are displayed by a video display screen of the display system. The vehicular vision system determines an augmented reality overlay and the video display screen also displays the augmented reality overlay. The displayed augmented reality overlay pertains to at least one accessory of the equipped vehicle and/or is responsive at least in part to a driving condition of the equipped vehicle.

Provided is an input unit to which input signals are inputted, the input signals including signals indicating operating states of switches used for operating the electronic mirror and used for selecting a display mode from among the plurality of display modes to be displayed by the electronic mirror; a storage unit that together with prioritizing and storing each of a plurality of display modes in a hierarchical structure, stores mode setting conditions that are conditions for setting each display mode; a determination unit for determining whether or not the mode setting conditions are satisfied for each of the plurality of display modes based on the input signals; and a setting unit that, of the plurality of display modes, sets a display mode from among the display modes for which the mode setting conditions are satisfied, as a display mode to be displayed on the electronic mirror.

The technology relates to an exterior sensor system for a vehicle configured to operate in an autonomous driving mode. The technology includes a close-in sensing (CIS) camera system to address blind spots around the vehicle. The CIS system is used to detect objects within a few meters of the vehicle. Based on object classification, the system is able to make real-time driving decisions. Classification is enhanced by employing cameras in conjunction with lidar sensors. The specific arrangement of multiple sensors in a single sensor housing is also important to object detection and classification. Thus, the positioning of the sensors and support components are selected to avoid occlusion and to otherwise prevent interference between the various sensor housing elements.

A vehicle camera system includes: an around view camera device including a front camera, a left camera, a right camera, and a rear camera, and configured to vary a field of view of one or more of the cameras in response to a control signal; and a control device configured to control the field of view by generating the control signal, in response to an operating mode.