A camera system is installed on the front end of a vehicle, either on the left front, the right front, or both sides. The camera is linked via wired or wireless connection to an onboard computer and a navigation display that is located within the passenger compartment of the vehicle. The driver reviews a visual description on the display of any oncoming traffic in the form of motor vehicles, pedestrians, cyclists, animals and the like on the navigation display via a single screen, split screen or alternating screens. The camera system can include a speed sensor that detects when the vehicle reaches a threshold speed to activate or de-activate the camera. Alternatively, the computer can activate the system when a turn signal is activated, and de-activate the system when the turn signal is no longer activated. This camera system can be retrofitted into older vehicles.

A camera mounting system and a method for processing images are disclosed. The system includes an external component configured to capture thermal images, and an internal component configured to receive the thermal images. The thermal images are wirelessly transmitted by the external component, the external component is coupled to the internal component via a glass, and the internal component is further configured to wirelessly power the external component.

A vehicular vision system includes a rear backup vehicle camera, a trailer camera disposed at a rear of a trailer, a display device disposed in the vehicle, and an electronic control unit (ECU) disposed in the vehicle. With the trailer not hitched to the vehicle and during a reversing maneuver of the vehicle, the ECU generates video images derived at least in part from image data captured by the rear backup vehicle camera and the display device displays the video images. With the trailer hitched to the vehicle, image data captured by the trailer camera is provided to the vehicle via data communication over powerline using a DC powerline, and the display device displays the video images derived at least in part from image data captured by the trailer camera for viewing by the driver of the vehicle during the driving maneuver of the vehicle with the trailer hitched thereto.

A blind spot detection system mounted to the vehicle license plate frame in one embodiment and to a trailer hitch in a second embodiment.

A communication system for vehicles includes a first communication device disposed at a first vehicle and a second communication device disposed at a second vehicle. The first communication device wirelessly transmits data indicative of a predicted path of travel of the first vehicle, and the second communication device receives the transmitted data from the first communication device. An ECU of the second vehicle processes data received from the first communication device and data indicative of a predicted path of travel of the second vehicle to determine a potential collision between the first vehicle and the second vehicle during a turning maneuver of the first vehicle toward the second vehicle. Responsive to determination of potential collision between the first vehicle and the second vehicle, the ECU controls braking and/or steering of the second vehicle.

The present disclosure relates to a vehicle imaging system (1). More particularly, the present disclosure relates to a video data transmitter (3) for use with a vehicle (V). The video data transmitter (3) comprises a camera (5) for generating video data (D.sub.V). An image processor (15) is configured to process the video data (D.sub.V) and a transmitter (14) is provided to transmit the processed video data (D.sub.VP) to a video data receiver (2). The image processor (15) is configured to process the video data (D.sub.V) in dependence on one or more operating parameter of the vehicle (V). The present disclosure also relates to a video data receiver (2); and to a method of controlling transmission of video data (D.sub.V).

Systems and methods are provided for using video/still images captured by continuously recording optical sensors mounted on waste collection vehicles used in in the waste collection, disposal and recycling industry for operational and customer service related purposes. Optical sensors are integrated into the in-cab monitor as well as the onboard computer, digital video recorder and other external devices.

A vehicular backup assist system includes an ultrasonic sensor disposed at a trailer hitch that is configured to be attached at a rear portion of the vehicle. A control includes a processor for processing sensor data captured by the ultrasonic sensor. The control, with the trailer hitch attached at the vehicle, and during a reversing maneuver of the vehicle, and responsive to processing of sensor data captured by the ultrasonic sensor, detects presence of an object rearward of the vehicle and in the vicinity of the trailer hitch. Responsive to detecting presence of the object, the control alerts a driver of the vehicle of the detection.

A head up display arrangement for a motor vehicle includes at least one camera capturing images of a scene outside of the motor vehicle, and wirelessly transmitting first video signals indicative of the captured images. A receiver wirelessly receives the first video signals and transmits second video signals dependent upon the first video signals. A head up display system is communicatively coupled to the receiver and receives the second video signals. The head up display system reflects a light field off of a windshield of the motor vehicle such that the reflection is visible to a driver of the vehicle as a virtual image. The light field is dependent upon the second video signals.

A vehicular vision system includes a forward viewing camera disposed behind a windshield of a vehicle and viewing forward of the vehicle through the windshield. A control is disposed at the vehicle and includes an image processor operable to process image data captured by the forward viewing camera. A drone includes a drone camera that captures image data. The drone is detachably disposed at the vehicle and is detachable from the vehicle and operable to fly above the vehicle. The drone camera captures image data representative of an area viewed by the drone camera with the drone flying above the vehicle. With the drone detached from the vehicle and flying above the vehicle, the drone communicates a signal to the control. Responsive to receiving the signal communicated by the drone, the control determines a traffic condition ahead of the equipped vehicle.