A method comprises obtaining autonomous vehicle sensor data of an autonomous vehicle. One or more autonomous vehicle actions of the autonomous vehicle are predicted based on the autonomous vehicle sensor data. Interactive content is identified from a library of interactive content. The interactive content is adjusted based on the predicted one or more autonomous vehicle actions, and the adjusted interactive content is presented within the autonomous vehicle.

A display of roadside objects on a vehicle windshield within a primary field of view of a driver, with an indication of a level of importance of the object is provided. A method includes: detecting, by a computer device, a roadside object in a vehicle driver's peripheral view; analyzing, by the computer device, the detected roadside object to assign a level of importance to the object based on predefined levels of importance; and displaying, by the computer device, the roadside object as a semi-transparent object in a display area of a windshield of the vehicle with an indication of the level of importance of the object.

Method and apparatus are disclosed for gaze detection of occupants for vehicle displays. An example vehicle includes a panoramic display including polarized displays. The example vehicle also includes a controller to identify a primary operator interface and a primary passenger interface and detect, via one or more cameras, an operator gaze and a passenger gaze. The controller also is to present the primary operator interface to an operator via one of the polarized displays corresponding with the operator gaze and present the primary passenger interface to a passenger via one of the polarized displays corresponding with the passenger gaze.

Method and apparatus are disclosed for gaze detection of occupants for vehicle displays. An example vehicle includes a panoramic display including polarized displays. The example vehicle also includes a controller to identify a primary operator interface and a primary passenger interface and detect, via one or more cameras, an operator gaze and a passenger gaze. The controller also is to present the primary operator interface to an operator via one of the polarized displays corresponding with the operator gaze and present the primary passenger interface to a passenger via one of the polarized displays corresponding with the passenger gaze.

Provided is a method for use by a driving assistance apparatus that assists a transition from an autonomous driving mode in which a vehicle is driven under autonomous control to a manual driving mode in which the vehicle is driven by a driver. The method includes: detecting an activity by the driver; detecting conditions of the driver; and determining a take-over request method which is a method of presenting, in the vehicle, a take-over request that informs the driver that the autonomous driving mode is going to be cancelled, the determining being based on at least the detected activity by the driver and the detected conditions.

A vehicle display device includes a display unit that displays at least an image relating to a driving state of a vehicle, a controller that generates image data of an image to be displayed on the display unit, and a temperature sensor that measures a temperature of the controller. The controller has a function of performing a first processing other than generating image data relating to the driving state. When the temperature of the controller is equal to or higher than a predetermined first value, the controller generates the image data relating to the driving state while reducing an amount of first processing performed by the controller.

Disclosed are methods and systems for adjusting pixels of a display screen in a vehicle. The methods and systems may include determining a position of the sun relative to a position of the vehicle, determining potential incident light rays from the sun striking the display screen based on the position of the sun, and adjusting one or more characteristics of one or more of the pixels of the display screen based on the potential incident light rays.

A display device includes a liquid crystal panel providing a display surface where an image is displayed, a backlight emitting light to the liquid crystal panel from behind, a real object placed between the liquid crystal panel and the backlight and visible through the liquid crystal panel, and a controller controlling the liquid crystal panel such that a specific pixel region of the display surface behind which the real object is positioned is higher in light transmittance than another pixel region of the display surface.

A display of roadside objects on a vehicle windshield within a primary field of view of a driver, with an indication of a level of importance of the object is provided. A method includes: detecting, by a computer device, a roadside object in a vehicle driver's peripheral view; analyzing, by the computer device, the detected roadside object to assign a level of importance to the object based on predefined levels of importance; and displaying, by the computer device, the roadside object as a semi-transparent object in a display area of a windshield of the vehicle with an indication of the level of importance of the object.

A graphic meter mounted on a vehicle is provided with a display unit of an image display type, which displays an instrument of the vehicle, an acquisition unit which acquires a course information indicating a course of the vehicle and a control unit which is connected to the display unit and the acquisition unit. The control unit controls a display content of a highlight which is displayed in the instrument of the display unit based on a position of a virtual light source located in a virtual space projected on a plane surface. The control unit identifies a change of the course of the vehicle based on the course information acquired by the acquisition unit, and causes the virtual light source to move, according to a result of the identification.