A display control device includes: a state acquisition unit that acquires a vehicle state; and a display control unit that when a vehicle state is a warning state requiring a warning to a driver, displays a warning icon on a first display device and displays a type of the warning state and relevant information on a second display device provided closer to a center in a vehicle width direction relative to the first display device.

Provided is a vehicle, comprising: a voice receiver configured to acquire a user voice input; a speaker provided inside the vehicle; a display provided inside the vehicle; and a controller configured to control the voice receiver, the speaker and the display, wherein the controller is configured to: acquire a control command from the user voice input, wait for receiving a subsequent control command for a predetermined waiting time after operating a control target based on the control command, and control at least one of the speaker or the display to provide a feedback for notifying that the control target is in a subsequent controllable state.

A sun visor assembly for a vehicle according to an exemplary aspect of the present disclosure includes, among other things, a visor having a transparent portion and a circuit configured to control at least one function of the visor. The visor is pivotable between a first position and a second position.

A vehicle control device includes: a first detection unit that detects a traveling state of a host vehicle; a merging detection unit that detects that the host vehicle approaches within a predetermined area of a merging point when the host vehicle travels on the merging road toward the merging point at which a main road joins with the merging road; a second detection unit that detects a speed of a lane flow by another vehicle that travels on the main road toward the merging point; a position detection unit that obtains a position of a pre-merging point as a virtual point on the main road reaching the merging point when the host vehicle reaches the merging point; and a display control unit that controls a display device to display the position of the host vehicle and the pre-merging point.

A display system includes an optical element through which light diverges and an imaging optical system configured to form an image by projecting diverging light diverging through the optical element. In the display system, the image formed by the imaging optical system is visually recognized by a viewer, and a condition in an equation tan 0≥(T×B)/(S×O) is satisfied, where θ denotes a divergence angle of the optical element, T denotes distance between the image forming optical system and the formed image, B denotes a range of an eye box that is an area through which the formed image can visually be recognized, S denotes distance between the formed image and a viewpoint of the viewer of the formed image, and O denotes distance between the optical element and the image forming optical system. In the above equation, each distance indicates length of an optical path that passes through a center of an image formed by the light when an object is observed from a reference eyepoint.

The action schedule item creation ECU creates action schedule items demanded of an ego vehicle capable of switching between autonomous driving and manual driving. The HUD and the meter display are provided inside a cabin of the ego vehicle. The display control ECU displays the action schedule items created by the action schedule item creation ECU on the HUD and the meter display, and emphasizes display of action schedule items to be performed by manual driving compared to display of action schedule items to be performed by autonomous driving.

A system for controlling a vehicle includes: an occupant gaze recognition unit to recognize a gaze of an occupant in the vehicle; a point of interest determination unit to determine the point of interest among an external object visible through a side window of the vehicle based on the gaze of the occupant; and a seat position control unit to change a seat position of the occupant to enable a continuous stare at the point of interest according to a movement of the vehicle.

In a display control device, in a case in which a total number of image pages displayable at a meter display is equal to or less than a predetermined value, the display control device displays a same number of dots as the total number of image pages, and displays a page indicator that specifies a dot corresponding to the displayed image page. Further, in a case in which the total number of image pages exceeds the predetermined value, a page indicator is displayed in which a cursor is arranged at a position corresponding to the displayed image page together with a scroll bar. As a result, even if the total number of image pages is large, the display of the page indicator is not complicated.

A distracted driver can be informed of his or her distraction by a visual notification. It can be detected whether a driver of a vehicle is focused on a non-critical object located within the vehicle. In response to detecting that the driver of the vehicle is focused on a non-critical object located within the vehicle, an amount of time the driver is focused on the non-critical object can be determined. When the amount of time exceeds a threshold amount of time, a visual notification of distracted driving can be caused to be presented on or visually adjacent to the non-critical object.

An augmented reality head-up display system for displaying graphics upon a windscreen of a vehicle includes one or more image-capturing devices that capture image data of an environment surrounding the vehicle, a graphic projection device for generating images upon the windscreen of the vehicle, and a controller in electronic communication with the one or more image-capturing devices and the graphic projection device. The controller executes instructions to receive object detection data indicating a current position of objects located within the environment surrounding the vehicle. The controller executes instructions to compare the current position of the objects within the environment with a visual location of the objects within the environment determined based on the image data to identify a visually occluded object located within the environment. In response to identifying the visually occluded object, the controller determines a contextual graphic that signifies the visually occluded object.