A plurality of displays; a display controller configured to determine each content of information to be displayed by each of the plurality of displays and to display the determined each content of information on each of the plurality of displays; and a receptor configured to receive a selection operation of an occupant, and in a case where an operation of selecting one of a plurality of options in a first mode is received by the receptor in a state where list information including the plurality of options is displayed on a first display included in the plurality of displays, the display controller is configured to display relevant information related to the option selected in the first mode on a second display different from the first display among the plurality of displays.

Technologies and techniques for operating of a touch-sensitive display device of a vehicle. A processor display generates content on the touch-sensitive display device, wherein the content includes assigned elements configured to function in a display mode and an operating mode, depending on a user's presence in at least one of a first position and a second position of the vehicle. A sensing apparatus detects an approach by a user toward the touch-sensitive display device. The processor identifies that the user is in the second position relative to the display device, and, based on the identifying, changes an operating state of the display device to change at least one display mode element of the display content assigned to the second position from display mode to operating mode.

An object is to provide a display system with a novel structure and a vehicle. The display system includes a display and a control IC. The control IC includes a frame memory, an arithmetic circuit, and a memory circuit. The display has a curved display surface. The frame memory has a function of holding first image data dedicated to displaying an image on a flat surface. The memory circuit has a function of storing shape data on the display. The arithmetic circuit has a function of converting first coordinates of the curved display surface into second coordinates of the flat surface included in the first image data, by performing arithmetic operation in accordance with the shape data. The arithmetic circuit has a function of outputting the first image data stored in the frame memory to the display as second image data on the basis of the second coordinates.

A vehicle display device includes a projection device including a light-transmitting image display unit displaying an image, a light source emitting light to the image display unit from a back surface side or a front surface side, and a light-shielding cover disposed on a front surface of the image display unit and including an opening. The projection device projects an image onto a reflection unit disposed in front of an occupant in a vehicle. When the projection device is viewed from the front surface side, a shape of the opening is a shape similar to a shape of an image display region in the image display unit, and the opening is separated from an outer edge of the image display region and surrounds the image display region.

Embodiments are described of an apparatus including a computer to which are coupled a user identification device to identify an authorized user, a transceiver to receive and transmit user data between the computer and one or more user data sources associated with the authorized user, a navigation system, and one or more displays coupled to the computer. The computer constructs a timeline for the authorized user based on the user data over a specified time interval, wherein the timeline displays every user event that falls within the specified time interval, and simultaneously display the timeline and a map on one of the one or more displays, wherein the user's current position and the position of at least one user event from the timeline are identified on the map. Other embodiments are disclosed and claimed.

An image generation apparatus that generates an image notifying an occupant of a vehicle about a notification target located in a traveling direction of the vehicle, and outputs a virtual image of the image to a head-up display device that displays the virtual image while superimposing the virtual image on a foreground of the vehicle. The image generation apparatus includes: a target information acquisition part that obtains positional information and a moving direction of the notification target; an image generation part that generates a ripple image displayed by the head-up display device while superimposed on a road surface where the notification target is located when the target information acquisition part obtains at least one positional information; and a subject vehicle information acquisition part that obtains a traveling speed. The image generation part stops generation of the ripple image when the traveling speed exceeds a threshold speed specified beforehand.

A vehicular manipulation apparatus, which manipulates a different apparatus, includes a manipulation unit, a communication unit, a display unit, and a controller. The manipulation unit accepts a manipulation and inputs a set value step-by-step for controlling the different apparatus. The communication unit communicates with the different apparatus, transmits manipulation information to the different apparatus, and receives a set value of the different apparatus. The display unit digitally displays the set value. The controller controls an image on the display unit using the set value. In displaying change due to the manipulation step-by-step, the controller broadens a change width between steps in cases where the manipulation amount within a threshold period of time is equal to or greater than a threshold manipulation amount, as compared with cases where the manipulation amount within the threshold period of time is less than the threshold manipulation amount.

Vehicle systems and methods for redirecting the direction of gaze of a driver towards an object are disclosed. In one embodiment, a vehicle includes an object detection system configured to output an object signal in response to detecting an object, a driver gaze monitoring system configured to output a direction signal, a heads-up display configured to generate a visual indicator, one or more processors and one or more non-transitory memory modules communicatively coupled to the one or more processors and storing machine-readable instructions that, when executed, cause the one or more processors to perform at least at the following: determine an object and a respective location of the object based at least in part on the object signal from the object detection system, and determine a direction of gaze of a driver based at least in part on the direction signal from the driver gaze monitoring system.

The invention is directed to a head-up display 2 having a light source 231, a diffuser 232,235,236, a transmissive display 3, a mirror element 251 and a transmissive screen 21. According to the invention the head-up display 2 is further provided with a contrast enhancer display 4 that is arranged adjacent to the transmissive display 3.

According to one aspect, systems and techniques for driving mode control may include a steering wheel, a sensor, a display, and a controller. The steering wheel may have a button coupled thereto. The button may have a depressed state. When the button is in the depressed state, the steering wheel may be movable between a first position and a second position. The sensor may detect whether the steering wheel is in the first position or the second position. The display may display a display content. The controller may set the display content for the display or a driving mode of a vehicle, such as an autonomous driving mode or a manual driving mode, based on the detected position of the steering wheel.