A vehicle-mounted alert system includes display devices equipped to a vehicle, a sight line detection device detecting driver's sight line, a surrounding monitoring device detecting a presence of an object near the vehicle and a direction of the object with respect to the vehicle, and an alert control device controlling the display devices to display an alert image for informing the driver of the presence of the object detected by the surrounding monitoring device. The alert control device controls the display device located in a direction of the sight line of the driver to display the alert image, and then, controls the display devices so that the alert image successively moves from the display device located in the direction of the sight line of the driver to the display device determined based on the direction of the object detected by the surrounding monitoring device.

Provided is a vehicle display device configured to be mounted on a vehicle. The vehicle display device includes a curve detection unit, a road state categorization unit, and a display unit. The curve detection unit detects a curve that is included in a target traveling line and has a curvature. The road state categorization unit categorizes a state of the road on which the target traveling line including the curve is set, in one class out of a plurality of classes, according to possibility of presence of the curve having the curvature of a predetermined value or more. The display unit displays a representation that indicates the curvature of the curve. The curvature corresponds to the class in which the state of the road has been categorized.

A three-dimensional imaging system includes a first illumination source configured to project a first fan of light toward an object in a field of view, and a second illumination source configured to project a second fan of light substantially parallel to and spaced apart from the first fan of light. The first illumination source and the second illumination source are further configured to scan the first fan of light and the second fan of light synchronously laterally across the field of view. The three-dimensional imaging system further includes a camera configured to capture a plurality of image frames of the field of view as the first fan of light and the second fan of light are scanned over a plurality of regions the object, and a processor coupled to the camera and configured to construct a three-dimensional image of the object based on the plurality of image frames.

A multi-camera vision system for a vehicle includes a plurality of video cameras having respective fields of view external of the vehicle. Captured image data is provided to and processed at a central data processor in order to detect objects that are within the field of view of at least some of the video cameras. The vehicle is equipped with a sensor system having at least one non-visual sensor that senses sensor data in a region external of the vehicle. The sensed sensor data is provided to the central data processor. A potential hazard present exterior the vehicle is determined to exist via processing at the central data processor of at least one of received image data and received sensor data.

Provided is a vehicle control system capable of securing stability even in the event of a collision with a travel-path defining line such as a guardrail. The invention recognizes the travel-path defining line of a travel path from information about an area in a traveling direction of an ego vehicle, recognizes a traveling-direction virtual line extending from the ego vehicle in the traveling direction, and imparts a yaw moment control amount so that a formed angle between the traveling-direction virtual line and the travel-path defining line decreases after the ego vehicle collides with the travel-path defining line.

A vehicle reverse assistant includes a rear side sensor, a towed object detector, and a stop determination threshold distance setter. The rear side sensor is provided at a rear portion of an own vehicle. The rear side sensor senses a rear side sensing region. The towed object detector detects whether a towed object is connected to the rear portion of the own vehicle. The stop determination threshold distance setter sets one end of a stop determination threshold distance at a position spaced apart at a constant distance from a rear end of the towed object on a basis of a sensing signal supplied from the rear side sensor when the towed object detector detects connection of the towed object.

Techniques for road scene primitive detection using a vehicle camera system are disclosed. In one example implementation, a computer-implemented method includes receiving, by a processing device having at least two parallel processing cores, at least one image from a camera associated with a vehicle on a road. The processing device generates a plurality of views from the at least one image that include a feature primitive. The feature primitive is indicative of a vehicle or other road scene entities of interest. Using each of the parallel processing cores, a set of primitives are identified from one or more of the plurality of views. The feature primitives are identified using one or more of machine learning and classic computer vision techniques. The processing device outputs, based on the plurality of views, result primitives based on the plurality of identified primitives from multiple views based on the plurality of identified entities.

An image control unit of an image display device provides, on display screens of a display unit, a captured-image-only region in which only a captured image is displayed when the display unit displays the captured image, and multiple-image regions in which the captured image or a different image that is different from the captured image is selectively displayed when the display unit displays the captured image. In an embodiment, the image control unit fixes a position of the captured-image-only region on the display screens.

A method to equip a vehicle to perform object detection and tracking and a surround view camera system to perform the object detection and tracking involve two or more cameras arranged respectively at two or more locations of the vehicle. The cameras capture images within a field of view of the two or more cameras. A processing system obtains the images from the two or more cameras and performs image processing to detect and track objects in the field of view of the two or more cameras.

A vehicular vision system includes a camera module configured for mounting at an in-cabin portion of a windshield of a vehicle and including a circuit board and a camera that views forward of the vehicle and through the windshield. The camera includes an imaging sensor array. A data processor is operable to process image data captured by the imaging sensor array for at least one system of the vehicle. The imaging sensor array is electrically connected to circuitry of the circuit board via a flexible electrical connection. The imaging sensor array may be controlled via the flexible electrical connection. Image data captured by the imaging sensor array is carried via the flexible electrical connection. With the camera module mounted at the in-cabin portion of the windshield, the circuit board is tilted at an acute angle relative to the longitudinal axis of a lens barrel of the camera.