A method for displaying and processing an image includes capturing the image, calculating one or more of a size, a position, and a field of view of a first region of interest (ROI) of the captured image, calculating one or more of a size, a position, and a field of view of a second ROI of the captured image, calculating a blur factor for blurring the first ROI, manipulating an image gradient of the first ROI pixel by pixel using the blur factor to reduce at least one of a brightness or a contrast of one or more pixels of the ROI, manipulating the second ROI by changing a color of one or more pixel values from the second ROI, and displaying the processed image on a display. An imaging system which includes an image signal processor (ISP) is also described.

The present embodiment relates to image acquisition and, in particular, to an image acquisition apparatus for acquiring images by a camera installed in a vehicle, and a method therefor. The image acquisition apparatus according to the present embodiment comprises: a projector for illuminating a reference pattern to the ground; a first camera unit for capturing an image of the reference pattern illuminated by the projector; a second camera unit for capturing an image; and a control unit for analyzing a pattern captured by the first camera unit and processing the image captured by the second camera unit.

A display control device includes: an image data acquisition unit configured to acquire image data as a result of imaging by an imaging unit that images a situation around a vehicle; and a display processing unit configured to display, on a display unit, a peripheral image indicating the situation around the vehicle generated based on the image data and also display, on the peripheral image, a first vehicle image indicating a current state of the vehicle and a second vehicle image indicating a future state of the vehicle when the vehicle moves toward a target position and to change a display mode of at least one of the first vehicle image and the second vehicle image according to a remaining distance to the target position of the vehicle.

A warning system and a method for warning a driver of a vehicle of an object in a proximity of the vehicle. The system includes a device for detecting the object, a device for processing an image of the object based on the detection so that a representation indicative of the object is achieved, and a display for displaying the representation indicative of the object in the vehicle.

A peripheral monitoring apparatus includes a hardware processor that: acquires captured image data obtained by capturing, from a towing vehicle to which a towed vehicle is coupleable, a region behind the towing vehicle; acquires coupling information representing whether or not the towed vehicle is coupled to the towing vehicle; generates a reference line to be a reference for a movement of the towing vehicle when the towing vehicle moves backward; and switches display modes of the reference line to be displayed after being superimposed on an image being based on the captured image data, the switching of the display modes being performed between a case where the towed vehicle is coupled to the towing vehicle and a case where the towed vehicle is not coupled to the towing vehicle.

Example implementations as described herein are directed to the use and detection of asymmetrical markers in conjunction with an autonomous mode for a human operated vehicle system. In example implementations, the vehicle system adjusts at least one of a position, orientation and speed based on the detection of asymmetrical markers, which can be utilized for vehicle navigation as well as autonomous valet parking.

An image processing unit identifies the shape of an obstacle that is identified from an area that appears in a peripheral image based on an image captured by a camera. The shape of the obstacle includes at least a tilt of a section of the obstacle in a road-surface direction. The section of the obstacle faces a vehicle. The image processing unit generates a superimposed image in which a mark image that is generated as a pattern that indicates the identified obstacle is superimposed onto a position that corresponds to the obstacle in the peripheral image. At this time, the image processing unit variably changes properties of the mark image based on the tilt of the obstacle identified by an obstacle identifying unit. The image processing unit then displays the generated superimposed image on display apparatus.

Systems and methods are provided for generating a rear view image display for a motor vehicle. A rear view system includes an optical sensor disposed at the motor vehicle and configured to capture image data, a computational unit coupled to the optical sensor by a cable connection and configured to execute program instructions stored on a computer-readable medium to modify the image data for presentation, and a display device coupled to the computational unit and configured to receive the modified image data from the computational unit and display the modified image data to a driver of the motor vehicle. The computational unit is further configured to receive software calibration to optimize modification of the image data.

A vehicle vision system for a vehicle includes an image sensor having a field of view and capturing image data of a scene exterior of the vehicle. A monitor monitors electrical power consumption of the vehicle. At least one lighting system draws electrical power from the vehicle when operated. An image processor processes image data captured by the image sensor. The electrical power drawn by the at least one lighting system is varied at least in part responsive to processing of captured image data by the image processor in order to adjust fuel consumption by the vehicle.

The present invention is provided with: an outer housing configured from a housing having an opening, and a translucent cover closing the opening; a substrate disposed inside of the outer hosing; a camera module, which has an image pickup element, and is disposed on the substrate; and a light emitting element, which is provided as a light source, and is disposed on the substrate. Consequently, since the camera module and the light emitting element are disposed on the substrate that is disposed inside of the outer housing, the number of configuration components is small, thereby achieving reduction of the number of components, and size reduction.