A vehicular control system includes a forward-viewing camera viewing through the windshield at least forward of the equipped vehicle, a left-side camera viewing at least sideward and rearward of the equipped vehicle, a right-side camera viewing at least sideward and rearward of the equipped vehicle, and an electronic control unit (ECU). Image data captured by the cameras is transferred to and is processed at the ECU. Responsive at least in part to processing at the ECU of transferred image data, the vehicular control system detects another vehicle present rearward of the equipped vehicle and approaching the equipped vehicle in the same traffic lane that the equipped vehicle is traveling in on the road the equipped vehicle is traveling along. The vehicular control system undertakes a pre-impact measure to prepare the equipped vehicle for impact by the other vehicle and/or controls the equipped vehicle to mitigate impact by the other vehicle.

A display system includes: a display that emits light corresponding to image information; a half mirror that receives the light emitted, reflects, as reflected light, a first component of the light received, and transmits a second component different from the first component; and a first reflecting mirror having a concave surface that receives and reflects the reflected light toward the half mirror. The half mirror includes a first retardation film, a first support substrate, and a reflective polarizing film stacked in this order from a side on which the light emitted is received. The first retardation film changes a phase of the light received. The first support substrate is light-transmissive. The reflective polarizing film reflects a first polarized component and transmits a second polarized component different from the first polarized component.

A vehicular driving assist system includes a rearward viewing camera, a driver-side camera, a passenger-side camera and at least one radar sensor. Image data captured by the cameras is provided to a control and radar data captured by the radar sensor is provided to the control. The control processes the provided captured data to determine a potential hazard presented by rear-approaching traffic. The control outputs video image data for display by a display device of the equipped vehicle. The display device includes a video display screen that displays video images for viewing by a driver of the equipped vehicle during operation of the equipped vehicle. The control processes provided captured image data and provided captured radar data to alert the driver to the determined potential hazard presented by the rear-approaching traffic in the side traffic lane adjacent to the traffic lane being traveled by the equipped vehicle.

A method for providing a driver of a vehicle towing a trailer with reversing information, comprising the steps of: capturing image data of a region behind the trailer; measuring an angle between the vehicle and the trailer; generating auxiliary data 5 comprising reversing aid information at least in part in accordance with the angle; generating display data in accordance with the image data and the auxiliary data; and presenting the display data on a display.

A method of assembling a camera assembly for a vehicle vision system includes providing a housing having a front housing portion and a rear housing portion that includes a connector portion configured for connecting to a vehicle wiring connector. An imager circuit board includes an imager is disposed at the front housing portion such that the imager is aligned with the lens of the front housing portion. A connector circuit board is disposed at the rear housing portion and electrically connected to a coaxial connector structure at the connector portion. The rear housing portion is mated with the front housing portion and circuitry of the connector circuit board is electrically connected to circuitry of the imager circuit board via at least one spring-loaded connector that electrically connects at the imager circuit board and at the connector circuit board.

A vehicular vision system includes a camera disposed at an exterior portion of a side of a vehicle and viewing at least sideward and rearward of the equipped vehicle. A video display screen is disposed in an interior cabin of the equipped vehicle and displays video images derived from frames of image data captured by the camera. When no other vehicle is detected in another traffic lane, the video display screen displays video images representative of a first portion of the exterior scene viewed by the camera. Responsive to determination that another vehicle is in the other traffic lane and approaching from rearward of the equipped vehicle, the video display screen displays video images representative of a second portion of the exterior scene that includes the determined other vehicle. Responsive to detection of the other vehicle, the video display screen displays a graphic overlay overlaying the displayed video images.

A method for detecting an object via a vehicular vision system includes disposing first and second cameras at respective locations at a vehicle so as to have respective first and second fields of view rearward of the vehicle. The locations are vertically and horizontally spaced apart by respective vertical and horizontal separation distances. With the first and second cameras disposed at the respective locations, the first field of view at least partially overlaps the second field of view. An electronic control unit (ECU) is provided that includes an image processor. Image data is captured by the cameras and provided to the ECU and processed at the ECU. The ECU, responsive to processing of captured image data and based on the separation distances, determines presence of an object in the overlapping region of the first and second fields of view and determines the location of the object relative to the vehicle.

A vehicle rear-view mirror and a method for control the same and a control system thereof are provided. The method for control the vehicle rear-view mirror includes: detecting a turning state of the vehicle; in the case that the vehicle is turning, controlling the driving mechanism to drive the deformable region of the rear-view panel to deform towards the driving mechanism.

A method and a device for controlling vehicle steering, a vehicle-mounted controller and a vehicle thereof are provided. The vehicle-mounted controller includes: detection module, image acquisition module, and display module; the detection module is provided at rubber hoses located between a left and right vehicle doors and the vehicle body, and is configured to detect whether an electrical signal is present in the rubber hose, which is energized when turn signal lamp in the vehicle is activated. The method includes: receiving the electrical signal detected by the detection module; determining the current turning direction of the vehicle after receiving the electrical signal; controlling the image acquisition module to acquire an image for the rear of the vehicle in the current turning direction, and sending the image acquired to the display module, so as to display the image for the rear of the vehicle in the current turning direction.

A vehicle display device provided in a vehicle includes a display 33 and a controller. The controller displays a video showing a side view and a rear view from a vehicle 1 on the display 33 when a passenger gets out of the vehicle 1 while the vehicle 1 is stopped.