A driver assistance system for a vehicle includes an imager disposed at the vehicle and viewing exterior the vehicle. A control includes an image processor and is operable to process captured image data for at least a first application and a second application and to adjust the image sensor to at least two settings and to process captured image data via at least two processing techniques. The control is operable to synchronize the at least two settings of the image sensor and the at least two processing techniques to extract respective information from the captured image data for the first and second applications. The control adjusts a setting of the image sensor to capture image data suitable for the first application or the second application. The image processor processes captured image data via a processing technique suitable for the first application or the second application.

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 capturing camera has a lens block that includes a lens for focusing light from a vehicle as a subject, an image sensor that captures an image based on light from the vehicle focused by the lens, a filter unit that rotatably supports a polarization filter which limits the light from the vehicle received by the image sensor, a sensor that detects a daytime mode or a night mode, a processor that disposes the polarization filter on a front side of the image sensor in the daytime mode, and disposes a band pass filter on the front side of the image sensor in the night mode, and an illuminator that irradiates the subject with IR light in the night mode. The filter unit switchably supports the polarization filter and the band pass filter that transmits the IR light.

A light source unit includes a substrate and a light source. The light source is mounted on the substrate. At least one sensor is configured to detect the infrared light. The at least one sensor detects a wavelength component of the infrared light in a range of wavelengths from 920 nm to 960 nm better than a wavelength component of the infrared light out of the range. The light source device emits the infrared light having a peak wavelength smaller than 920 nm when the light source has a temperature of 25 C. or lower. The peak wavelength of the infrared light emitted from the light source device increases as the temperature of the light source increases from the temperature of 25 C.

An automobile head up display system and an obstacle prompt method thereof are provided. The method includes: acquiring a road condition video image, identifying obstacles from the acquired image after performing an enhancement processing on the acquired image; projecting and displaying a prompt information at corresponding positions of a front windshield of the automobile according to positions of the identified obstacles in the road condition video image.

A vehicle system, comprising a vehicle transceiver located in the host vehicle configured to receive data indicative of a driving path of one or more remote vehicles, a processor in communication with the vehicle transceiver and programmed to output graphical images indicative of lane markers on a road to the display utilizing at least the driving path data, and a display configured to display the graphical images.

A vehicle system, comprising a vehicle transceiver located in the host vehicle configured to receive data indicative of a driving path of one or more remote vehicles, a processor in communication with the vehicle transceiver and programmed to output graphical images indicative of lane markers on a road to the display utilizing at least the driving path data, and a display configured to display the graphical images.

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 display control device for a vehicle includes: a display controller that displays a predetermined display image on a windshield of the vehicle; a visibility reducing area detector that detects a presence or an absence of a visibility reducing area which reduces a visibility of the display image on the windshield; and a gaze detector that detects a gaze of a driver. When the display image overlaps with the visibility reducing area and the driver does not keep the gaze on the display image, the display controller moves the display image to an outside of the visibility reducing area.

One aspect of the present invention includes artificial vision system. The system includes an image system comprising a video source that is configured to capture sequential frames of image data of non-visible light and at least one processor configured as an image processing system. The image processing system includes a wavelet enhancement component configured to normalize each pixel of each of the sequential frames of image data and to decompose the normalized image data into a plurality of wavelet frequency bands. The image processing system also includes a video processor configured to convert the plurality of wavelet frequency bands in the sequential frames into respective visible color images. The system also includes a video display system configured to display the visible color images.