An automatic parking control unit comprises a recognizing section recognizing an outer world outside a vehicle, a vehicle operation control section performing an operation control on the vehicle, an automatic parking control section performing a parking operation to park the vehicle at a target parking position and a display control section synthesizing images taken by a camera group into an image of a surrounding area of the vehicle and displaying the image on an output device group. The display control section displays an image of the surrounding area of the vehicle and a vehicle body image of the vehicle with a portion of the vehicle made translucent, the portion of the vehicle making a blind area to a driver in the surrounding area of the vehicle and the portion of the vehicle is changed according to a direction in which the vehicle is running.

An in-vehicle performance device is an in-vehicle performance device that performs a game that is played by an occupant in a vehicle, and includes a motion detector configured to detect a motion of the occupant irrelevant to driving the vehicle, a display configured to display an image visually recognizable by the occupant, and a display controller configured to display a response image according to the motion of the occupant on the display on the basis of the motion of the occupant detected by the motion detector, and output a result of a game based on a predetermined rule.

Presented are intelligent vehicle systems with networked on-body vehicle cameras with camera-view augmentation capabilities, methods for making/using such systems, and vehicles equipped with such systems. A method for operating a motor vehicle includes a system controller receiving, from a network of vehicle-mounted cameras, camera image data containing a target object from a perspective of one or more cameras. The controller analyzes the camera image to identify characteristics of the target object and classify these characteristics to a corresponding model collection set associated with the type of target object. The controller then identifies a 3D object model assigned to the model collection set associated with the target object type. A new “virtual” image is generated by replacing the target object with the 3D object model positioned in a new orientation. The controller commands a resident vehicle system to execute a control operation using the new image.

A head-up display system includes a projection module including a display panel to project an image displayed on the display panel, a reflective optical element that reflects at least a part of the image, an optical member located between the projection module and the reflective optical element and having light-shielding capability, and a controller that controls the light-shielding capability of the optical member.

A head-up display module is mountable on a movable body. The head-up display module includes a first display panel, a first optical element, a drive, a first input unit, and a controller. The first display panel displays a first image. The first optical element reflects image light from the first image emitted from the first display panel. The drive drives the first optical element to change a direction in which the image light from the first image is reflected. The first input unit receives an input of a speed of the movable body. The controller drives the drive in accordance with the speed and controls a display image to be displayed on the first display panel.

A vehicle (10) for a driver (14) of the vehicle (10) and a display device (16) are provided. The display device (16) includes a projection surface (18) extending in the horizontal and vertical direction and a projector (20) that is configured so as to project a projection (24) onto the projection surface (18). The projection surface (18) is curved in the horizontal direction and surrounds the driver (14) in the horizontal direction by at least one hundred degrees. A method for displaying a projection (24) on a projection surface (18) for a driver (14) of a vehicle (10) is also provided. The method includes: d) determining a viewing direction and/or head orientation (26) of the driver (14) towards the projection surface (18); and f) projecting the projection (24) onto the projection surface (18) in the viewing direction and/or head orientation (26) of the driver (14).

A communication link is established from a motor vehicle to an other vehicle in the vicinity of the motor vehicle by receiving configuration data from the other vehicle, and determining a relative position of the other vehicle relative to the motor vehicle. A virtual display, which indicates the other vehicle as a possible communication partner, is provided for a user of the motor vehicle by at least partially using the relative position of the other vehicle and the configuration data. A communication command is received from the user, by which the other vehicle is selected as the communication partner. A direct communication link is then established with the other vehicle having been selected as the communication partner.

A display system of a vehicle displays a virtual image. The display system has a projection device, which is configured to emit display light in order to generate an image, and a reflecting device, which is configured for a first reflection of display light of the projection device arranged above the reflecting device by way of the reflecting device attached in or on an instrument panel of the vehicle. The display light of the projection device incident on the reflecting device is substantially retroreflected. The display system further includes a windshield of the vehicle, which windshield is configured for a second reflection of at least part of the display light, which was reflected by the reflecting device, to the eyes of an observer in the vehicle in order to allow the observer to see, behind the windshield, the virtual image of the image generated by the projection device.

In an information display system that allows an observer to visually recognize image information displayed on an image display apparatus by superimposing the image on an external scenery through a window glass and a combiner, the system includes a light source apparatus that supplies light having a specific polarization direction at a narrow divergence angle to the image display apparatus, a reflection position of the image is changed by arranging a position and an angle of the image display apparatus with respect to the window glass so that the position and the angle change while a monitoring angle of the image visually recognized by the observer is constant, and a virtual image display distance of the image visually recognized by the observer and a size of the image of the virtual image can be changed by the arrangement state in the vehicle.

A vehicle display device includes: an obstacle information acquisition section configured to acquire information relating to a plurality of obstacles in surroundings of a vehicle; and a mark display section configured to display a predetermined individual mark prompting caution toward an individual obstacle among the plurality of obstacles by superimposed display in a display region inside a vehicle cabin, and to display a predetermined cluster mark prompting caution toward a plurality of the obstacles by superimposed display in the display region in a case in which a predetermined condition has been satisfied.