A multi-layer display system may include three, four, or more display panels/screens arranged in an overlapping manner, a backlight configured to provide light to the plurality of display screens, and a processing system. The processing system may be configured to display, on a first display screen of the plurality of display screens, a first image including a first gradient area, display, on a second display screen of the plurality of display screens, a second image including a second gradient area, and display, on a third display screen arranged in an overlapping manner between the first display screen and the second display screen, a third image including. The third image may include a third gradient area overlapping at least a portion of the first gradient area displayed on the first display screen and at least a portion of the second gradient area displayed on the second display screen.

A method of emergency braking of a vehicle includes: displaying a brake button in a vehicle; determining pre-touch information on a distance before the brake button is touched by a user; determining post-touch information on a distance after the brake button is touched; and performing any one of a first brake control in which general braking is performed according to the degree of the pressing of the brake button and braking force is added from a first time point after the brake button is pressed, a second brake control in which the general braking is performed and braking force is added from a second time point that is after the first time point, and a third brake control in which the general braking is performed according to the pre-touch information and the post-touch information.

Embodiments are disclosed for display configurations for providing an augmented reality heads up display. In one example, a heads up display device includes at least one display, at least one micro lens array, at least one optical element comprising a lenticular lens or parallax barrier positioned between the display and the at least one micro lens array, and a display controller comprising a processor and memory storing instructions executable by the processor to control the at least one display to output image light that passes through the at least one optical element and the at least one micro lens array and impinges on a transparent plane to form a first three-dimensional image in a first plane and a second three-dimensional image in a second plane.

A hologram display control apparatus may include a determination device turning on a hologram display control depending on an input signal of a user, a hologram projection device projecting a first hologram image corresponding to an image of a manipulating device of a steering wheel onto a first area predefined based on a space coordinate system of a vehicle, when the hologram display control is turned on, a detector recognizing a set operation in a second area predefined for operation recognition with respect to button manipulation in the first hologram image, a manipulation button recognizing device recognizing a manipulation button in the first hologram image based on a location at which the set operation is recognized by the detector, and a signal processing device transmitting a control signal to a driving device of the vehicle operated by the manipulation button.

An operating knob for an operating apparatus extends away from a reference plane that delimits the operating knob on a rear side. The operating knob is in the form of a three-dimensionally protruding body in relation to the reference plane up to a knob height. The operating knob has at least one side wall extending between the reference plane and the knob height at an angle greater than 20 with respect to the reference plane as a placement surface for at least one finger operating the operating knob. Luminous outputs of at least one luminous segment or a pixel matrix are provided on the side wall.

A method for operating a display arrangement of a motor vehicle, which includes at least two display devices each with a display surface. A visible display content can be shifted here three-dimensionally between two display planes. A detection and evaluation device of an operator control device carries out: acquisition of an operator control action by a touch-sensitive operator control surface, preferably a pulling and/or shifting gesture, and of its extension direction, and, on the basis of the determined extension direction, determination of a data set which describes the display content, as well as determination of a predetermined shift of a virtual image of the display content from one of the display planes to the other of the display planes.

A vehicular control system includes a camera having an exterior field of view at least rearward of the vehicle and operable to capture image data. A trailer is attached to the vehicle and image data captured by the camera includes image data captured when the vehicle is maneuvered with the trailer at an angle relative to the vehicle. The vehicular control system determines a path of the trailer responsive at least to a steering angle of the vehicle. The vehicular control system detects an object present exterior of the vehicle during maneuvering of the vehicle and the trailer and based at least in part on image processing of captured image data. The vehicular control system plans a driving path for the vehicle that avoids the detected object so that the vehicle and the trailer do not run over or contact the detected object.

A vehicle includes: a cluster including a display panel, and a barrier panel disposed adjacent the display panel and having a plurality of barriers; an image obtainer acquiring an image; a steering wheel disposed adjacent the cluster and the image obtainer; and a controller configured to determine whether or not a condition for performing a three-dimensional image mode is satisfied based on a manipulation state of the steering wheel, to control operations of the display panel and the barrier panel to recognize a user's line of sight based on the image of the image obtainer, perform the three-dimensional image mode based on the recognized line of sight of the user when the condition is satisfied, and to control the operations of the display panel and the barrier panel to perform a two-dimensional image mode when the is not satisfied.

An illumination assembly for a vehicle is provided herein. The illumination assembly may employ a projection assembly that may be disposed within a housing extending from a portion of a vehicle. A window is disposed on the vehicle and may be optically coupled with the projection assembly. A luminescent structure may be disposed within the window and is excited by the projection assembly. A controller may be configured to activate the projection assembly to selectively illuminate indicia on the window.

A user interface and a method for the inputting and outputting of information in the vehicle includes an image generation unit which generates a projected image. A means for gesture recognition is arranged as a means for detecting an input, and that a means for view detection and following is arranged such that the recognition of the viewing direction and an association of the viewing direction of the driver with an area in the vehicle is carried out. Information about this area is generated in the viewing direction in the form of a projected image and is displayed floating over the area. Recognition of gestures of the driver is carried out. Upon a coincidence of a position of a hand of the driver, detected by the gesture recognition, with the projected image or a component of the projected image, a signal is generated by the central control unit and outputted.