A system mounted on a vehicle for detecting an obstruction on a surface of a window of the vehicle, a primary camera is mounted inside the vehicle behind the window. The primary camera is configured to acquire images of the environment through the window. A secondary camera is focused on an external surface of the window, and operates to image the obstruction. A portion of the window, i.e. window region is subtended respectively by the field of view of the primary camera and the field of view of the secondary camera. A processor processes respective sequences of image data from both the primary camera and the secondary camera.

A vision system for a vehicle includes a driver-side exterior mirror assembly having a driver-side camera for capturing driver-side image data and a passenger-side exterior mirror assembly having a passenger-side camera for capturing passenger-side image data. A video display disposed at the vehicle displays video images derived from image data captured by the driver-side and passenger-side cameras. The video display includes a driver-side display portion and a passenger-side display portion. The driver-side display portion of the video display displays video images derived from driver-side image data captured by the driver-side camera and does not display video images derived from any passenger-side image data captured by the passenger-side camera. The passenger-side display portion of the video display displays video images derived from passenger-side image data captured by the passenger-side camera and does not display video images derived from any driver-side image data captured by the driver-side camera.

Systems and methods are provided, having sensing unit(s) configured to capture images of a surrounding of a vehicle, and a processing unit connected to a database which is configured to store imaging data relating to the surrounding of the vehicle together with metadata relating to capturing parameters of the stored imaging data. The processing unit enhances the captured images with stored imaging data according to a correspondence of metadata with vehicle situations, for example, according to a relation between capturing parameters of different sensing units. Sensing unit(s) may be gated infrared to indicate specified reflectivity parameters of regions in the captured images. Sensing unit(s) may comprise a controller applying changing patterned filters to the pixel array to enhance visibility and other image features. Multiple sensing units with gateable infrared sensors may communicate using modulated illumination spots.

The present disclosure provides a vehicle display device, configured to be mounted on a sun visor frame, including: a controller for receiving surrounding images, labeling a reference object in the surrounding images, and determining a first image to be displayed from the surrounding images according to a comparison of the reference object and a real object corresponding to the reference object; a non-transparent display screen for displaying the first image in a driver's sightline, wherein the non-transparent display screen is connected to the controller; and a plurality of image acquisition modules including a front camera, two side view cameras, and a rear view camera for capturing front images, left-side images, right-side images, and rear images of a vehicle.

A system mounted on a vehicle for detecting an obstruction on a surface of a window of the vehicle, a primary camera is mounted inside the vehicle behind the window. The primary camera is configured to acquire images of the environment through the window. A secondary camera is focused on an external surface of the window, and operates to image the obstruction. A portion of the window, i.e. window region is subtended respectively by the field of view of the primary camera and the field of view of the secondary camera. A processor processes respective sequences of image data from both the primary camera and the secondary camera.

A method for determining a snow covered surface condition of a path of travel. A beam of light is emitted at a surface of the path of travel by a light emitting source. An image of a path of travel surface is captured by an image capture device. The image capture device is mounted on the vehicle and captures an image in a downward direction. The captured image captures the beam of light emitted on the path of travel surface. Analyzing a subsurface scattering of the light generated on the path of travel surface by a processor. A determination is made whether snow is present on the path of travel. A snow covered path of travel surface signal is generated in response to the identification of snow on the path of travel.

A method for determining a wet surface condition of a road. Capturing an image of a wheel of a remote vehicle traveling in an adjacent lane by an image capture device of a host vehicle. Identifying in the captured image, by processor of a host vehicle, a region of interest relative to the wheel where the region of interest is representative of where precipitation dispersion occurs. A determination is made whether precipitation is present in the region of interest. A wet road surface signal is generated in response to the identification of precipitation in the adjacent lane.

A driver visibility detection system for a vehicle includes an indicator, an eye position obtainer, and a visible range calculator. The indicator indicates the driver to look at, through a windshield of the vehicle, a furthest ground position of a road on which the vehicle is traveling. The eye position obtainer recognizes an eye position of the driver when the driver looks at the furthest ground position. The visible range calculator calculates a visible range of the driver based on the eye position detected by the eye position obtainer.

A vision system for a vehicle includes a driver-side exterior mirror assembly having a driver-side camera for capturing driver-side image data and a passenger-side exterior mirror assembly having a passenger-side camera for capturing passenger-side image data. A video display disposed at the vehicle displays video images derived from image data captured by the driver-side and passenger-side cameras. The video display includes a driver-side display portion and a passenger-side display portion. The driver-side display portion of the video display displays video images derived from driver-side image data captured by the driver-side camera and does not display video images derived from any passenger-side image data captured by the passenger-side camera. The passenger-side display portion of the video display displays video images derived from passenger-side image data captured by the passenger-side camera and does not display video images derived from any driver-side image data captured by the driver-side camera.

There is provided a vehicular visual recognition device including: an imaging section that images vehicle surroundings through a region that a wiper blade passes through; a display section that displays an imaging result of the imaging section; a detection section that detects a position of the wiper blade; and a controller that performs display control to display an image of vehicle surroundings captured by the imaging section and, at a timing at which the wiper blade passes through the imaging section, to hold an imaging result of prior to the wiper blade passing the imaging section for display on the display section.