A vehicular vision system includes an electronic control unit (ECU) disposed at a vehicle and including an image processor that processes image data captured by at least one camera of the vehicle. An under-trailer camera is disposed at an underside of a trailer hitched to the vehicle. The under-trailer camera has a field of view under the trailer that includes a ground surface under the trailer that is traveled over by the trailer. The under-trailer camera captures image data as the vehicle and trailer are moving. The ECU, responsive to processing of image data captured by the under-trailer camera, detects an object under the trailer and determines that the detected object under the trailer is greater than a threshold size. The ECU, responsive to determination that the detected object under the trailer is greater than the threshold size, generates an output.

An underbody camera located beneath and within a wheel base of a vehicle includes a mounting bracket coupled to the vehicle, a camera housing, and a camera. The camera housing is coupled to the mounting bracket and defines an interior camera compartment. The camera is coupled to the camera housing and is arranged to lie within the interior camera compartment.

The present application relates to a method and apparatus for generating a graphical user interface indicative of a vehicle underbody view including a LIDAR operative to generate a depth map of an off-road surface, a camera for capturing an image of the off-road surface, a chassis sensor operative to detect an orientation of a host vehicle, a processor operative to generate an augmented image in response to the depth map, the image and the orientation, wherein the augmented image depicts an underbody view of the host vehicle and a graphic representative of a host vehicle suspension system, and a display operative to display the augmented image to a host vehicle operator. A static and dynamic model of the vehicle underbody is compared vs the 3-D terrain model to identify contact points between the underbody and terrain are highlighted.

A method of providing a visualization (152) of one or more areas obscured by a trailer (200) attached to a vehicle (100) is provided. The method includes receiving first image data (133, 133a) from a first camera (132) positioned on a front portion of the vehicle (100) when the vehicle and the trailer are moving in a forward direction or a rear portion of the trailer when the vehicle and the trailer are moving in a rearward direction. The method also includes storing the received first image data. The method includes receiving speed data (135) of the vehicle from a speed sensor (134). The method also includes determining a visualization (152) of an area (Area 2) underneath the trailer (200) based on the stored first image data (133, 133a) and the speed data (135), and sending instructions to a display (122) to display the visualization of the area underneath the trailer.

A vehicular vision system includes an underbody camera disposed at an underside of a body of a vehicle and viewing a ground surface under the body of the vehicle and being traveled on by the vehicle. The underbody camera captures image data as the vehicle is moving. An illumination source, when operated to emit light, emits near infrared light illuminating the ground surface under the body of the vehicle. An electronic control unit (ECU) is disposed at the vehicle and includes an image processor that processes image data captured by the underbody camera. The underbody camera views at least forward towards a front portion of the underside of the body of the vehicle. The vehicular vision system, via processing at the ECU of image data captured by the underbody camera, determines presence of an object forward of the underbody camera and having height greater than a threshold height.

A vehicular vision system includes an underbody camera disposed at an underside of a body of a vehicle and viewing a ground surface under the body of the vehicle and being traveled on by the vehicle. The underbody camera captures image data as the vehicle is moving, An illumination source, when operated to emit light, emits near infrared light illuminating the ground surface under the body of the vehicle. An electronic control unit (ECU) is disposed at the vehicle and includes an image processor that processes image data captured by the underbody camera. The underbody camera views at least forward towards a front portion of the underside of the body of the vehicle. The vehicular vision system, via processing at the ECU of image data captured by the underbody camera, determines presence of an object forward of the underbody camera and having height greater than a threshold height.

A vehicular vision system includes an electronic control unit (ECU) disposed at a vehicle and including an image processor that processes image data captured by at least one camera of the vehicle. An under-trailer camera is disposed at an underside of a trailer hitched to the vehicle. The under-trailer camera has a field of view under the trailer that includes a ground surface under the trailer that is traveled over by the trailer. The under-trailer camera captures image data as the vehicle and trailer are moving. The ECU, responsive to processing of image data captured by the under-trailer camera, detects an object under the trailer and determines that the detected object under the trailer is greater than a threshold size. The ECU, responsive to determination that the detected object under the trailer is greater than the threshold size, generates an output.

The present application relates to a method and apparatus for generating a graphical user interface indicative of a vehicle underbody view including a LIDAR operative to generate a depth map of an off-road surface, a camera for capturing an image of the off-road surface, a chassis sensor operative to detect an orientation of a host vehicle, a processor operative to generate an augmented image in response to the depth map, the image and the orientation, wherein the augmented image depicts an underbody view of the host vehicle and a graphic representative of a host vehicle suspension system, and a display operative to display the augmented image to a host vehicle operator. A static and dynamic model of the vehicle underbody is compared vs the 3-D terrain model to identify contact points between the underbody and terrain are highlighted.

A vehicular vision system includes an underbody camera disposed at an underside of a body of a vehicle such that a ground surface under the body of the vehicle and being traveled on by the vehicle is at least partially viewed by the underbody camera. A control includes an image processor for processing image data captured by the underbody camera. The underbody camera views at least forward or at least rearward, and the control, via processing of image data captured by the underbody camera, determines presence of an object forward or rearward of the underbody camera and having height greater than a threshold height. The control, responsive to determination of presence of the object under the body of the vehicle that has height greater than the threshold height, generates an output to inform a driver of the vehicle of presence of the determined object under the body of the vehicle.

A vehicular vision system includes an underbody camera disposed at an underside of a body of a vehicle such that a ground surface under the body of the vehicle and being traveled on by the vehicle is at least partially viewed by the underbody camera. A control includes an image processor for processing image data captured by the underbody camera. The underbody camera views at least forward or at least rearward, and the control, via processing of image data captured by the underbody camera, determines presence of an object forward or rearward of the underbody camera and having height greater than a threshold height. The control, responsive to determination of presence of the object under the body of the vehicle that has height greater than the threshold height, generates an output to inform a driver of the vehicle of presence of the determined object under the body of the vehicle.