A display system of a vehicle, and a control method thereof includes: a user input device; a head-up display configured to project a virtual image including augmented reality contents and to adjust a projection position of the augmented reality contents according to predetermined driver viewpoint information and left and right direction offset; and a controller configured to correct the driver viewpoint information or the left and right direction offset according to a control input received through the user input device, wherein the left and right direction offset indicates a degree to which the augmented reality contents are shifted left or right.

Systems and methods for improving the brightness of a transparent display are disclosed herein. One embodiment collects ambient light using an array of Fresnel lenses disposed on an external surface of a vehicle; collects internal light from the vehicle's headlights; filters the ambient light and the internal light to produce filtered ambient light and filtered internal light; generates primary-source light using a light-emitting-diode (LED) light source; and injects, into a transparent edge-lit liquid crystal waveguide display deployed in at least a portion of a window of the vehicle, the primary-source light, the filtered ambient light, and the filtered internal light in a color-synchronized manner. The filtered ambient light and the filtered internal light improve the brightness of the transparent edge-lit liquid crystal waveguide display.

A automobile laminated glass according to the present invention includes: a first glass plate that is formed into a rectangular shape; a second glass plate that is disposed so as to face the first glass plate, and is formed into a rectangular shape; an intermediate film that is disposed between the first glass plate and the second glass plate; a functional layer that is disposed between the first glass plate and the second glass plate; and an obstructing layer that is laminated on a peripheral edge portion of at least one of the first glass plate and the second glass plate, wherein the functional layer is formed so that an outer edge of at least a portion of the functional layer is located outward of an inner edge of the obstructing layer.

A head-up display for displaying graphics upon a windscreen of a vehicle includes a graphic projection module for generating images upon the windscreen of the vehicle, a user input device for receiving user-generated commands created by a user of the vehicle, and one or more controllers in electronic communication with the graphic projection module and the user input device. The controller executes instructions to instruct the graphic projection module to generate a luminance adjustment graphic, where the luminance adjustment graphic includes an adaptive color palette graphic including two or more colors. The controller receives, from the user input device, a user-generated luminance input indicating a change in a level of luminance in a selected color, where the change in the level of luminance in the selected color is selected by the user to discern differences between the two or more colors caused by a color vision deficiency.

Provided are a projection image display member having a high visible light transmittance, suppressing a double image of a display image, and having excellent suitability of polarized sunglasses for incident light reflected from external light, a windshield glass using the projection image display member, and a head-up display system. The problem is solved such that one or more phase difference layers, one or more selective reflection layers, and one or more polarization conversion layers are provided in this order, the polarization conversion layer being a layer in which a helical alignment structure of a liquid crystal compound is fixed, and the number of pitches x of the helical alignment structure and a film thickness y (m) of the polarization conversion layer satisfying 0.3x7.0, 0.5y6.0, y0.7x+3.2, and y0.7x1.4.

There is provided a method of providing contents for a vehicle passenger, including: detecting, from a vehicle sensor, location information of the passenger, and location information and state information of a display where contents are being reproduced; acquiring, from the vehicle sensor, first data relating to contents being reproduced on the display, based on the detected location information and state information of the display; determining whether a degree of similarity between the first data and contents input into the display is equal to or more than a first threshold value; and changing an area in which the contents are reproduced based on the determined results.

It is aimed to provide a system for alerting a driver of a driver cabin of a motor vehicle, said system comprising: a plurality of light sources arranged in array to project a signal light against the windshield and/or side window, provided in the driver cabin along a horizontal contour of windshield and side windows, outside a line of sight of the driver, and arranged to show a mirror image of the light source in the windshield or side window, visible to the driver; a tracking controller, arranged to identify one or more objects to be tracked in the perimeter of the motor vehicle; a control system, coupled to the tracking controller for activating a number of light sources of the plurality of light sources, arranged to project a signal light indicative of said tracked object substantially centered along a virtual line of sight from the driver towards the identified object.

Certain configurations are described of methods, systems and devices that can be used to assist in mounting a vehicle safety device in an automobile, truck, train or other vehicle. In some examples, an augmented reality device designed to permit viewing of a virtual template on a windshield or a bumper can be used to mount or align a safety device to the windshield. In some instances, the virtual template may comprise one or more virtual alignment indicators or markings that facilitate mounting of the vehicle safety device in a selected position or to the windshield.

A laminated vehicle glazing includes within the laminate an AMOLED screen and an electrical connection element of the AMOLED screen connected to an interface housing on the face F4 and containing one or more electronic components notably for controlling the AMOLED screen, the interface housing also being connected to a wired power supply system.

Embodiments are disclosed for display configurations for providing an augmented reality heads up display. In one example, a mirrorless heads up display device includes a display, at least one micro lens array, an 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 display to output image light that passes through the lenticular lens or parallax barrier and the at least one micro lens array and impinges on a transparent plane to form a three-dimensional image.