A first object approaching a vehicle in a first direction and a second object approaching the vehicle in a second direction are detected. In response to detection of the first object and the second object, the first object is notified about the presence of the second object by using a notification device, and the second object is notified about the presence of the first object by using the notification device.

A vehicle such as a motor car (V) equipped with a radio equipment (14) is provided with a rearview camera 5 (10). Video frames from the rearview camera (10) are received at the radio equipment (14) and transmitted to a mobile communication device (S) such as a smart phone equipped with a video screen (S1) so that video frames from the rearview camera (10) are displayed on the 10 video screen (S1) of the mobile communication device (S).

An ECU captures an image of an imaging region around an own vehicle, and acquires image data, the imaging region being configured by a plurality of imaging areas. The ECU determines whether the object is present in the imaging areas, on the basis of detection results of an object present around the own vehicle. The ECU selects a target area to be displayed in an easy-to-see state from among the plurality of imaging areas, on the basis of determination results. The ECU reduces and corrects the image data of each imaging area such that an image of the target area is displayed in the easy-to-see state compared to an image of each imaging area to generate display image data.

A vision system for a vehicle includes a forward viewing camera disposed at a mirror head of an interior rearview mirror assembly of the vehicle and having a forward field of view through the windshield of the vehicle. A sensor is disposed at the mirror head and determines a change in position of the mirror head relative to a mirror mount of the mirror assembly when the vehicle driver adjusts the mirror head. A control includes a processor operable to process image data captured by the forward viewing camera. Responsive to determination by the sensor of a change of position of the forward viewing camera relative to the mirror mount, the control selects an active sub-array of photosensors to provide an effective field of view of the forward viewing camera. The processor processes image data captured by the active sub-array of photosensors for a driver assistance system of the vehicle.

An image processing device for a vehicle includes: an acquisition unit acquiring a captured image of a periphery of a vehicle, which is captured by an imaging unit provided in the vehicle; a bird's eye view image generating unit generating a bird's eye view image in which the captured image is projected to a 3D virtual projection plane provided at a side opposite to the vehicle with reference to a ground and separated from the ground with distance from the vehicle; a guide line generating unit generating a guide line indicating a predicted course of the vehicle; a conversion unit converting the guide line into a virtual guide line indicating the predicted course on the virtual projection plane; and a superimposing unit superimposing the virtual guide line on the bird's eye view image.

When a first object is first detected during a second display process executed when a second object is detected, a vehicle display control apparatus of the invention starts a first display at a first detection of the first object, stop the first display at a termination of the second display process and start the first display process at a start of the next second display process.

A driving consciousness estimation device includes a driving readiness estimation unit configured to estimate a driving readiness relating to a driving consciousness of the driver from a driver's reaction to the travelling environment, a driving task demand estimation unit configured to estimate a driving task demand which is an index required for the driver with respect to the driving readiness from the travelling environment, and an attention awakening unit configured to execute awakening of attention for the driver relating to the driving of the vehicle based on the result of comparison between the driving readiness and the driving task demand.

An image generation apparatus includes an image processor and a detector. The image processor generates a composite image viewed from at least one virtual viewpoint, and outputs the generated composite image to a display. The detector detects an indication of a driver intention to drive the host vehicle to a right or to a left relative to a travelling direction of the host vehicle. The image processor generates the composite image viewed from a virtual viewpoint located in front of the host vehicle in the travelling direction, the composite image showing a lateral surface of the host vehicle on a side corresponding to the detected indication of the driver intention. Thus, it is possible to make it easier to check a situation at a time of a right turn, a left turn, or a travelling direction change.

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.