A vehicle includes a vehicle body having a cabin, a first seat and a second seat arranged in the cabin, a planar transparent member placed on a side surface of the cabin, and that separates an interior of the cabin and a vehicle exterior from each other, and a display device placed on the side surface of the cabin and arranged along the planar transparent member, the display device having a plurality of pixels. At least a part of the display device is placed on the side surface and between the first seat and the second seat.

A vehicle system includes: a battery; a display; an input; and a processor configured to display a user interface for setting a distance-to-empty (DTE) value after charging or a charge time on the display, to receive a user input for setting a distance-to-empty (DTE) value after charging or for setting a charge time through the user interface, and to charge the battery according to the set DTE after charging or charge time.

A display device includes a display panel including a plurality of data lines; a plurality of data drive ICs configured to provide data voltages to the data lines; and a controller configured to rearrange video data received from an external device and transmit region-wise video data to the plurality of data drive ICs, to receive coordinates of information regions included in the video data and store video data of the information regions in advance, to calculate a checksum for checking an error in the region-wise video data based on the coordinates, to transmit the coordinates and the checksum to the data drive ICs and receive feedbacks about comparison results with respect to the checksum, and when a data drive IC that has failed is confirmed based on the feedback results, to update video data of the information region displayed by the data drive IC to region-wise video data of a normal data drive IC and output the video data.

A microlens array includes N lenses ranging from a 1.sup.st lens to an N.sup.th lens and a lens arrangement area. N is a positive integer. The lens arrangement area has the N lenses arranged in array. The lens arrangement area receives light emitted from a light source. An i.sup.th (i being 1.sup.st to N.sup.th) lens satisfies a conditional expression below:
2020 where denotes an angle formed by a main-axis orientation of double refraction and a reference orientation.

A motor vehicle control system that includes a first user-operable transmission selector for selecting a transmission operating mode and a user-operable gear selector, such as paddle input controls. The gear selector is operable in a first functional mode to select between a plurality of forward direction gear ratios. The gear selector is also operable in a second functional mode to select between a forward direction and reverse direction. This allows a user to use the gear selector to control travel in forward and reverse directions.

In one embodiment, a vehicle mirror includes an on-board diagnostics (OBD) transceiver and one or more processors. The processors access OBD data received by the OBD transceiver from an OBD port of a vehicle. The processors further determine, from the OBD data, a vehicle type, a change in voltage of the vehicle's battery, and a secondary vehicle factor. When the vehicle is determined to be a combustion engine vehicle, the processors transition the vehicle mirror from a sleep power state to an awake power state when the change in voltage is greater than a predetermined amount and the secondary factor of the vehicle is greater than a predetermined threshold. When the vehicle is determined to be an electric vehicle, the processors transition the vehicle mirror from the sleep power state to the awake power state when any activity is detected in the OBD data and the secondary factor of the vehicle is greater than the predetermined threshold.

A display device is provided and may include a light source that emits a light beam, a scanner that causes the light beam to scan, a movable screen in which an image is formed by transmitting the light beam from scanner, an optical system configured to project the image on a display medium, and a driver configured to cause the movable screen to reciprocate in moving directions. The image includes a first image and a second image. The movable screen reciprocates in a posture inclined with respect to the moving directions such that a second end of the movable screen is positioned closer to the scanner than a first end of the movable screen. The scanner forms the second image in the movable screen while the movable screen moves such that a forming direction of the second image is inclined with respect to a direction approaching the scanner.

A display apparatus mountable on a mobile object, which: obtains a display location and a movement direction of a virtual object to be displayed in a display area of the display apparatus so as to be overlaid in a real world, the virtual object to be moved relative to movement of the mobile object; estimates a time it will take for the virtual object to move from the display location to a border of the display area, or a distance between the display location of the virtual object and the border of the display area, each based on the display location and the moving direction of the virtual object; determines a display form of the virtual object based on the estimated time or the estimated distance; and causes the virtual object be displayed in the determined display form, such that the virtual object changes the display form while moving in the display area.

In one embodiment, a vehicle mirror includes a heads-up display (HUD) projector, an on-board diagnostics (OBD) transceiver, and one or more processors. The processors access OBD data received by the OBD transceiver from an OBD port of a vehicle. The processors further determine an identification of the vehicle from the accessed OBD data and determine one or more calibration parameters for the HUD projector based on the determined identification of the vehicle. The one or more calibration parameters are operable to position a displayed image from the HUD projector onto a HUD reflector within a line-of-sight of a driver of the vehicle. The processors further send one or more instructions based on the one or more calibration parameters to the HUD projector.

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.