A visual system (1) for a vehicle (7) having a capturing unit (2) for capturing a field of view (8) and a calculation unit (3), which is adapted to generate image data to be displayed based on the captured image data, and to supply the same to an image display unit (4), wherein the image data to be displayed include the field of view (8) captured by the capturing unit (2), the image display unit (4) is adapted to display the image data to be displayed, so that they are visible for the driver of the vehicle (7), and the calculation unit (3) is adapted to superimpose at least one trajectory (10, 10′) of a future track/driving curve of the vehicle (7) on the image data to be displayed on the image display unit (4), if a steering angle of the vehicle (7) has a predetermined amount.

A display control device for a vehicle includes: a display controller that displays a determined display image including a display of a traveling state of the vehicle on a windshield of the vehicle; a visibility reducing area detector that detects a presence or an absence of a visibility reducing area on the windshield, the visibility reducing area reduces visibility of a driver; and a gaze detector that detects a gaze of the driver. When the visibility reducing area is detected, but the display of the traveling state does not overlap with the visibility reducing area, and the driver keeps the gaze on the visibility reducing area, the display controller displays, on the visibility reducing area, a traveling direction information necessary for driving the vehicle.

In a method, an area surrounding a first motor vehicle is scanned optically on the part of the first motor vehicle; a message is determined on the basis of the scanned information; the message is transmitted from the first motor vehicle to a second motor vehicle, a distance between the first and the second motor vehicle not exceeding a predetermined maximum value; a graphic representation of the area surrounding the first motor vehicle is determined on the basis of the message; and the representation is output on board the second motor vehicle.

A driver assistance system for a vehicle includes a camera disposed at a vehicle and having a field of view forward of the vehicle. A control includes an image processor that is operable to process image data captured by the camera. Responsive to processing by the image processor of image data captured by the camera, the image processor is operable to determine lane markings demarcating the lane in which the vehicle is traveling. Responsive to processing by the image processor of captured image data and responsive to at least one of (i) a map input and (ii) a location input, the control estimates a path of travel for the vehicle to maintain the vehicle in the lane in which the vehicle is traveling in situations where the lane markings demarcating the lane in which the vehicle is traveling are not readily determinable.

Methods and devices for actively modifying a field of view of an autonomous vehicle in view of constraints are disclosed. In one embodiment, an example method is disclosed that includes causing a sensor in an autonomous vehicle to sense information about an environment in a first field of view, where a portion of the environment is obscured in the first field of view. The example method further includes determining a desired field of view in which the portion of the environment is not obscured and, based on the desired field of view and a set of constraints for the vehicle, determining a second field of view in which the portion of the environment is less obscured than in the first field of view. The example method further includes modifying a position of the vehicle, thereby causing the sensor to sense information in the second field of view.

Apparatuses, systems and methods are provided for determining vehicle driver distractions. More particularly, apparatuses, systems and methods are provided for determining distracted drivers associated with vehicle driving routes based on postures of vehicle occupants.

The invention relates to a method for providing environmental data wherein first environmental data are captured at a first time, objects being detected on the basis of the captured first environmental data, and object parameters being determined for each of the objects, wherein the object parameters are associated with the objects. In addition, a traffic situation is determined on the basis of the captured first environmental data, and filter criteria are determined according to the determined traffic situation. The filter criteria comprise prioritizations and predictions for the objects and the object parameters associated therewith. At a second time, second, updated environmental data are captured and transmission data are generated on the basis of the second, updated environmental data and the filter criteria. The transmission data are output.

A method of displaying a top view image of a vehicle includes: extracting, by a controller, a location of maximum resolution of a top view image of a vehicle generated by cameras; setting, by the controller, a replacement image area that is larger than an image area of the vehicle included in the top view image of the vehicle by a reference value at the location of the maximum resolution of the top view image of the vehicle; and replacing, by the controller, a non-obtainable mage area of the top view image of the vehicle with the replacement image area, in which the reference value is a value larger than the non-obtainable image area.

An off-road vehicle that travels on the off-road ground includes: a sensor group configured to detect unevenness of the ground; a camera configured to capture the unevenness of the ground; a ground unevenness degree calculation unit configured to calculate a ground unevenness degree indicating an unevenness degree of the ground based on an input parameter; an input parameter setting unit configured to set, as the input parameter, data selected from among data detected by the sensor group and image data captured by the camera; an unevenness-position data generation unit configured to associate the actual vehicle position with the ground unevenness degree to generate ground unevenness-position data; and a data storage unit configured to store the ground unevenness-position data.

A display controller controls a display device provided for a mobile object to display a display image including at least one item of contents of data. The display controller includes an image data acquisition unit configured to obtain image data from an imaging device configured to capture an image around the mobile object, and a display-image generation unit configured to generate the display image. The display-image generation unit changes a display mode of the at least one item of contents of data included in the display image to increase visual recognizability of a desired item of contents of data included in the at least one item of contents of data to a level at least higher than visual recognizability of an area in the image data not including the desired item of contents of data.