Multi-camera vision system for a vehicle

The embodiments of the invention in which an exclusive property or privilege is claimed are defined as follows: 1. A multi-camera vision system for a vehicle, said multi-camera vision system comprising: a rear-mounted video camera at a rear portion of a vehicle equipped with said multi-camera vision system; said rear-mounted video camera having at least a rearward field of view external of the equipped vehicle; said rear-mounted video camera operable to capture video image data at least rearward of the equipped vehicle during a maneuver of the equipped vehicle; a front-mounted video camera at a front portion of the equipped vehicle; said front-mounted video camera having at least a forward field of view external of the equipped vehicle; said front-mounted video camera operable to capture video image data at least forward of the equipped vehicle during the maneuver of the equipped vehicle; a first side-mounted video camera at a driver-side side portion of the equipped vehicle; said first side-mounted video camera having at least a sideward field of view external of the equipped vehicle; said first side-mounted video camera operable to capture video image data at least sideward of the equipped vehicle during the maneuver of the equipped vehicle; a second side-mounted video camera at a passenger-side side portion of the equipped vehicle; said second side-mounted video camera having at least a sideward field of view external of the equipped vehicle; said second side-mounted video camera operable to capture video image data at least sideward of the equipped vehicle during the maneuver of the equipped vehicle; a central data processor disposed in the equipped vehicle; wherein captured image data is provided to said central data processor; wherein image data captured by said front-mounted video camera, said first side-mounted video camera, said second side-mounted video camera and said rear-mounted video camera is processed at said central data processor; wherein image data captured by at least some of said front-mounted video camera, said first side-mounted video camera, said second side-mounted video camera and said rear-mounted video camera is processed at said central data processor in order to detect objects that are within the field of view of at least some of said front-mounted video camera, said first side-mounted video camera, said second side-mounted video camera and said rear-mounted video camera; wherein detection of objects via processing at said central data processor of captured image data comprises use of an edge detection algorithm; wherein the equipped vehicle is further equipped with a sensor system comprising at least one non-visual sensor selected from the group consisting of (i) a radar sensor and (ii) an ultrasonic sensor; wherein said at least one non-visual sensor senses sensor data in a region external of the equipped vehicle; wherein sensed sensor data is provided to said central data processor; wherein data is provided to said central data processor via a vehicle network of the equipped vehicle; wherein, via processing at said central data processor of at least one of received image data and received sensor data, a potential hazard present exterior the equipped vehicle is determined to exist; wherein said rear-mounted video camera comprises a rear backup camera; and wherein said rear backup camera has a field of view that encompasses at least a portion of a vehicle bumper of the equipped vehicle. 2. The multi-camera vision system of claim 1 , wherein said potential hazard arises from presence of rear-approaching traffic in at least one of (i) a side lane to the equipped vehicle and (ii) a rear lane to the equipped vehicle. 3. The multi-camera vision system of claim 1 , wherein image data captured by at least some of said front-mounted video camera, said first side-mounted video camera, said second side-mounted video camera and said rear-mounted video camera is processed at said central data processor to generate an alert to warn a driver of the equipped vehicle who is operating the equipped vehicle of the potential hazard determined to be exterior the equipped vehicle. 4. The multi-camera vision system of claim 3 , wherein video images derived from image data captured by at least some of said front-mounted video camera, said first side-mounted video camera, said second side-mounted video camera and said rear-mounted video camera are output by said central data processor for display by a display device of the equipped vehicle, and wherein said display device comprises a video screen operable to display said video images for viewing by the driver of the equipped vehicle who is operating the equipped vehicle. 5. The multi-camera vision system of claim 4 , wherein said video images displayed by said video screen inform the driver of the environment in which the equipped vehicle is being operated. 6. The multi-camera vision system of claim 5 , wherein said display device is disposed at an interior rearview mirror assembly of the equipped vehicle, and wherein at least one of (a) said display device displays video images for viewing through a mirror reflective element of said interior rearview mirror assembly by the driver of the equipped vehicle and (b) said display device automatically extends from said interior rearview mirror assembly responsive to the vehicle transmission being shifted into reverse gear, and wherein said interior rearview mirror assembly comprises a molded plastic mounting arm having at least one ball member at at least one end thereof and having electrical conducting elements extending therethrough, and wherein a mirror mounting portion is molded over said ball member, and wherein said mounting arm comprises a mounting arm polymeric material having a first linear mold shrinkage factor and a first flexural modulus, and wherein said mirror mounting portion comprises a mirror mounting polymeric material having a second linear mold shrinkage factor and a second flexural modulus, and wherein said second linear mold shrinkage factor is greater than said first linear mold shrinkage factor, and wherein said second flexural modulus is lower than said first flexural modulus. 7. The multi-camera vision system of claim 5 , wherein said video images comprise an overlay that guides the driver of the equipped vehicle when hitching a trailer to a vehicle hitch of the equipped vehicle. 8. The multi-camera vision system of claim 7 , wherein said overlay aids in guiding connection of the vehicle hitch of the equipped vehicle to a trailer tongue of the trailer. 9. The multi-camera vision system of claim 8 , wherein said video screen of said display device comprises a backlit thin film transistor LCD video screen backlit by a plurality of white light emitting light emitting diodes. 10. The multi-camera vision system of claim 9 , wherein said plurality of white light emitting light emitting diodes comprises an array of at least four white light emitting light emitting diodes. 11. The multi-camera vision system of claim 10 , wherein said display device is operable to display video images with a display intensity, as viewed by the driver of the equipped vehicle, greater than 200 candelas/sq. meter. 12. The multi-camera vision system of claim 1 , wherein said at least one non-visual sensor comprises a radar sensor. 13. The multi-camera vision system of claim 1 , wherein said at least one non-visual sensor comprises an ultrasonic sensor. 14. The multi-camera vision system of claim 13 , wherein said sensor system detects the presence of an obstacle exterior the equipped vehicle. 15. The multi-