A glare detection apparatus for detection of at least one glare region within an image includes a processing unit configured to aggregate image pixels of the image having a high luminance intensity to bright image areas within the image and to calculate for image pixels around each bright image area gradients expected in case of a glare and actual gradients and configured to increase a glare diameter of a glare region around the respective bright image area as long as the calculated actual gradients match the calculated expected gradients.

An image processing device includes: an identification unit that identifies whether an attribute of a first light spot included in image information capturing a scenery in front of a vehicle is a facility related to a road, by referring to first feature information on the first light spot calculated by referring to the image information; and a storage unit that stores the first feature information when the attribute of the first light spot is identified as a facility related to the road. The identification unit identifies whether an attribute of a second light spot included in the image information is a facility related to the road, by using the first feature information stored.

In one embodiment, a safety system for playing vehicle monitored content in a vehicle while minimizing driver distraction is provided. When the driver selects a camera, such as a rear view camera, vehicle monitored content stream from the camera is displayed on a display in the vehicle. While the driver drives the vehicle, the eye-gaze of the driver is monitored. When the eye-gaze of the driver shows that the driver is looking at the display, a timer is started. The timer runs when the driver looks at the display. When the eye-gaze of the driver shows that the driver has looked at the road continuously for more than a threshold amount of time, the time associated with the vehicle monitored content is reset back to its initial value. If the timer runs out, indicating that the driver has been watching the vehicle monitored content too much without also looking at the road, the vehicle monitored content is stopped and the driver is prevented from watching the vehicle monitored content for some period of time.

Provided are a rear camera and a door camera provided at different positions and configured to image vehicle surroundings rearward from a vehicle, and a monitor configured to display a composite image merging captured images captured by the respective cameras and to display a blind spot advisory image to advise of a blind spot in the composite image.

The present invention relates to a night image output apparatus, comprising: a photographing unit comprising an optical pulse output unit for outputting optical pulses and an image sensor for forming a plurality of images using optical pulses reflected by an external object; a display unit for outputting a final image made by synthesizing the plurality of images; and a control unit for calculating object distance information displayed in each pixel of the final image, by using data of a light quantity ratio of the plurality of images to each pixel of the final image and a light quantity ratio related to distance.

An image display apparatus has: an imaging device (11L, 11R) that is placed at a door (15L, 15R) of a vehicle (1) and that is configured to image an external circumstance of the vehicle; a displaying device (14) that is configured to display an external image captured by the imaging device; and a controlling device (132, 133) that is configured to control an display aspect of the display when the display displays the external image, the controlling device is configured to control the display aspect such that the display aspect when the door is in an opened state is different from the display aspect when the door is in a closed state.

A method includes detecting, with a sensor, a gaze of an occupant of a vehicle. The gaze is directed to at least one vehicle displays. The method also includes determining, with a controller circuit in communication with the sensor, whether one or more features presented on the at vehicle displays are partially obstructed from a view of the occupant. When the one or more features presented on vehicle displays are partially obstructed from the view of the occupant, the controller circuit adjusts a presentation of at least one partially obstructed features to be viewable by the occupant.

Estimating a lane change intention of a vehicle includes capturing a plurality of different lane change indicator signals, transforming the respective lane change indicator signals into respective associated individual probabilities of a lane change using respective assigned transformation functions, weighting these individual probabilities of a lane change, determining a weighted overall probability of a lane change as the average of the weighted individual probabilities of a lane change, and estimating the existence of a lane change intention depending on the overall probability of a lane change, and outputting an associated lane change estimation signal.

A vehicle includes one or more sensors arranged on at least one of a dashboard, a roof, and a center console of the vehicle, or one or more image capturing devices for capturing one or more images from a left side and a right side of the vehicle, an electronic control unit (ECU) configured to communicate with the one or more sensors or the one or more image capturing devices, and at least one of a morphing surface, a windshield display, and one or more displays configured to be controlled by the ECU, where the one or more sensors are arranged under a black panel surface.

The present invention is a single camera or multiple cameras on telescoping pole that can be mounted on top surface of vehicles such as automobiles, trucks, buses, trains, airplanes, toys etc. For easier explanation of the invention, focus is given on the application of the camera system on automobiles (cars). Four cameras mounted in different directions on the pole give wider field of view for safe operation of the vehicle. The camera system also includes a radar. The telescoping pole helps to raise the cameras unit with radar(LDAR) above the top surface of the vehicle. The first camera points to the front direction of the car, the second camera points to the rear direction of the car, the third camera points to a blind spot on the left side of the car and the fourth camera points to a blind spot on the right side the car. The inventions can be easily modified to a single or dual camera on top of pole for a cheaper alternative camera system, first camera can be mounted on the pole to show front view and the second camera may be mounted on the pole to show the rear view. The system can also keep cameras that point to the blind spots and ignore cameras facing the front and rear views.