Systems including one or more sensors, coupled to a vehicle, may detect sensor information and provide the sensor information to another computing device for processing. The processing may include analyzing the sensor information to identify one or more risk objects, such as animals, pedestrians, potholes, etc. The processing may further include generating a three-dimensional (3D) risk map, which may be displayed to a passenger in the vehicle. The 3D risk map may illustrate the one or more risk objects as one or more point clouds, respectively, within a virtual world representation of the vehicle's surroundings. Such a display may be used to alert drivers to possible risks while driving. In case of an accident, the 3D risk map may also be leveraged by insurance providers to process insurance claims and to notify customers that an insurance claim has been established.

A vehicular electronic mirror system includes a rear imaging device configured to capture an image of a rear side of a vehicle, rear lateral imaging devices respectively configured to capture images of right and left rear sides of the vehicle, and an electronic control device configured to perform, according to at least one of a state of the vehicle and a situation around the vehicle, different image processing processes on a rear image captured by the rear imaging device and rear lateral images captured by the rear lateral imaging devices and selected according to at least one of the state of the vehicle and the situation around the vehicle, and to cause a display device to display the rear image and the rear lateral images.

An apparatus for stabilizing a camera of an autonomous vehicle includes: a sensor that detects vibration generated and applied to the camera due to a state of a road surface when the autonomous vehicle is traveling; a first actuator that attenuates roll vibration applied to the camera; a second actuator that attenuates pitch vibration applied to the camera; and a controller that controls the first actuator and the second actuator to attenuate the vibration detected by the sensor.

A method for transmitting event data from an event detection and reporting system in a vehicle to a backend server includes storing full resolution sensor data in a vehicle buffer memory and subsampling the full resolution sensor data to produce reduced resolution of the sensor data. A vehicle event is detected based on an analysis of the reduced resolution sensor data, and the vehicle event is classified based on the reduced resolution sensor data. A determination is made as to whether the vehicle event is classified as a particular type of event with a minimum degree of confidence. The method then includes transmitting an indication that the vehicle event has not been classified with the minimum degree of confidence when the vehicle event has not been classified with the minimum degree of confidence, and transmitting reduced resolution sensor data for the detected vehicle event when the vehicle event is classified with at least the minimum degree of confidence.

The invention relates to a management method of an assistance system for a windscreen of a cab of a vehicle, the vehicle comprising a camera assembly including at least one camera located on the top of the windscreen with an angle between 25° and 75° with respect to the windscreen, for providing a captured image of a wide angle field of view located in front of the vehicle, said wide angle field of view comprising a first front field of vision, a second field of vision of a front-view and a third rear field of the vision, the method comprising: Determining a state of the windscreen using the at least one camera and Processing the captured image, according to the state of the windscreen, to operate the windscreen system on the windscreen.

Systems and methods for obscuring glares that are present on a windshield, mirror other surface of a vehicle are presented. The systems and methods comprise first and second sets of CCD cameras, where the first set is used to provide information about a source of a glare and the second set is used to provide information about eyes of a driver, for example. Based on the information gathered, locations of the source of the glare and the driver's eyes can be triangulated, and a position where light from the source of the glare is incident on the windshield or other surface can be determined. A translucent spot can be generated at that position to obscure the glare (light) from reaching the driver's eyes.

A vehicular vision system includes a forward viewing camera at a windshield of a vehicle and a plurality of color cameras, and includes a display device operable to display video images derived from image data captured by the color cameras. A processing unit includes a first processing chip that has an image processor for machine-vision processing of captured image data, and a second processing chip that receives vehicle data and receives image data captured by the color cameras. The first processing chip machine-vision processes image data captured by the cameras for object detection and classification of objects. The first processing chip controls operating parameters of the color cameras to enhance object detection based on machine-vision processing by the first processing chip of image data captured by the color cameras. The second processing chip controls operating parameters of the color cameras for display at the display device of video images.

A collision avoidance and/or pedestrian detection system for a large passenger vehicle such as commuter bus, which includes one or more exterior and/or interior sensing devices positioned strategically around the exterior and interior of the vehicle for recording data, method for avoiding collisions and/or detecting pedestrians, and features/articles of manufacture for improving same, is described herein in various embodiments. The sensing devices may be responsive to one or more situational sensors, and may be connected to one or more interior and/or exterior warning systems configured to alert a driver inside the vehicle and/or a pedestrian outside the vehicle that a collision may be possible and/or imminent based on a path of the vehicle and/or a position of the pedestrian as detected by one or more sensing devices and/or situational sensors.

An improved video-based rear-view mirror system for vehicles including motorcycles (but also with application to other vehicles including cars, trucks, bicycles, and so on) includes at least one digital display screen configured to be mounted in a side-mirror positioned unit; and at least one camera unit coupled to the digital display screen, such that the digital display screen is configured to display video data captured by the camera unit; wherein the system is configured such that the video data displayed by the at least one display screen is tuned to provide a side-mirror proxy view.

A vehicular vision system includes a plurality of cameras including a forward viewing camera and multiple color cameras, and includes a display device operable to display video images derived from image data captured by the color cameras. A processing unit includes a first processing chip that has an image processor for machine-vision processing of captured image data, and a second processing chip that receives vehicle data and receives image data captured by the color cameras. The first processing chip machine-vision processes image data captured by the cameras for object detection and classification of objects. The first processing chip controls operating parameters of the color cameras to enhance object detection based on machine-vision processing by the first processing chip of image data captured by the color cameras. The second processing chip controls operating parameters of the color cameras for display at the display device of video images.