A vehicle display control device includes a first image acquisition unit that acquires a first image by a first camera unit, a second image acquisition unit that acquires a second image by a second camera unit, a bird's-eye view image generation unit that generates a bird's-eye view image where a virtual vehicle image is synthesized at a center thereof based on the second image, a detection unit that performs an object recognition processing on the first image to detect a warning object, a direction calculation unit that calculates a direction of the warning object from the virtual vehicle image on a position of the warning object, and a display controller that displays the first image on a first monitor, and the bird's-eye view image and the direction of the warning object therein on a second monitor based on a position of the first camera unit in the vehicle image.

A system and method for a vehicle having a trailer hitch includes at least one camera mounted to a rear of the vehicle, a display device, and processing circuitry. The processing circuitry captures a video image from the at least one camera, generates a guide line in accordance with a steering angle of the vehicle, superimposes the guide line on the video image for guiding a direction from the trailer hitch towards a coupler of a trailer, displays the captured video image with the superimposed guide line, and enlarges a view of an area centered on an end of the guideline that is adjacent to the coupler.

A vehicular control system includes a camera having an exterior field of view at least forward of the vehicle. During a forward maneuver of the vehicle towing a trailer, the vehicular control system detects an object present exterior of the vehicle which ought not be impacted during the forward maneuver of the vehicle towing the trailer based at least in part on image processing by an image processor of image data captured by the camera. Responsive at least in part to detection of the object, the vehicular control system determines a forward driving path for the vehicle towing the trailer that avoids the detected object so that the trailer does not run over or contact the detected object. The vehicular control system determines the forward driving path at least in part responsive to (i) processing of captured image data and (ii) trailer data pertaining to physical characteristics of the trailer.

A warning output device includes a rear sensor unit and an electronic control unit. The electronic control unit is configured to, when a shift position is an R range, based on information from the sensor unit indicating that a first obstacle is detected, output a warning for informing an occupant of the presence of the first obstacle, in a first state, output first predetermined warning display and first predetermined warning sound; and in a second state, output second predetermined warning display and second predetermined warning sound. The ECU is configured to, in the second state, output the second predetermined warning sound for a predetermined time, then stop the output of the second predetermined warning sound, and output the second predetermined warning display for a longer time than the second predetermined warning sound.

A vehicle reflective device where the device reflectivity is adjustable by automatic or manual means, the variable reflectance element including a metallic mirror reflector on one side of a substrate. The variable reflectance function is automatically referenced to ambient light levels (day or night) and manually adjusted in response thereto. In an automatic mode, the variable reflectance assembly provides the user immediate eye protection from reflected high intensity glare by effecting near instantaneous adjustment in mirror reflectivity, such that the intensity of the reflected light impinging on the eye is automatically adjusted so as to be at comfortable levels. The mirror construction is one piece, and allows the viewing of a display monitor located behind the mirror, the mirror and monitor being operatively coupled together. In addition, the device houses a microprocessor that supports a number of software applications whose output is displayable on a designated portion of the device, the microprocessor also establishing a reflectance level within a relatively linear value of the ratio of glare light to ambient light to ensure that information displayed on the monitor screen is always available for viewing by the driver.

A virtual mirror arrangement, in particular for a vehicle, including at least one screen arranged in the interior of a vehicle for displaying a detection region of at least one camera, where an actuator connected to the camera is controllable by a movement of the display. The disclosure further relates to a method for adjusting a virtual mirror.

An in-vehicle monitoring camera device 100 includes: an obstacle detection unit 3 that detects, as first obstacles, obstacles detected by a millimeter-wave radar 11 which might collide with the host vehicle; a collision risk determination unit 4 that detects the time before the respective first obstacles and the vehicle come into contact with each other; a distortion correction unit 2 that generates image 2 by correcting distortion in image 1 captured using a wide-angle lens; and a camera-viewpoint display control unit 5 that generates image 3 by cutting out, from image 2, an image of the first obstacle having the shortest time to collision. Therein, a radar chart 31 indicating the visual field range or the center direction of the visual field of image 3 is superimposed on image 3.

A driver assistance system for a vehicle includes a rear-view camera constructed and arranged to obtain an image of an area behind a rear of the vehicle. A non-camera sensor system is constructed and arranged to obtain data regarding dynamic or static environmental features at opposing sides of the vehicle. An electronic control unit is electrically connected with the rear-view camera and with the sensor system. The electronic control unit is constructed and arranged to create an image from the data received from the sensor system. A display system is controlled by the electronic control unit and is constructed and arranged to display simultaneously to a driver of the vehicle at a single location, the image obtained by the rear-view camera and the image created by the electronic control system.

A cable connection system for use in a vehicle wherein the cable connects a rearview camera to the interior cabin of the vehicle. The cable connection system is designed such that the power converter module, a part of the cable system, can be easily replaced if damaged without the remainder of the cable harness rerouted or reinstalled.

A hitch assist system is provided herein. The hitch assist system includes a mobile device remotely disposed from a vehicle and configured to receive a user input for adjusting an alignment position of a hitch assembly of a vehicle. A controller is configured to generate commands for maneuvering the vehicle such that the hitch assembly is moved to an adjusted position at which the hitch assembly is aligned with a coupler of a trailer.