Light emitting devices are aligned along one alignment direction. A first diffusion plate diffuses the illumination light from each of the light emitting devices. A condensing unit exerts a condensing action on the illumination light diffused with the first diffusion plate in a vertical direction perpendicular to the alignment direction. An image forming unit has an illumination target surface illuminated with the illumination light, which is condensed with the condensing unit, and allows a part of the illumination light incident on the illumination target surface to pass therethrough to form the image and to emit display light of the image as a light flux. A second diffusion plate is located on an optical path between the condensing unit and the image forming unit to again diffuse the illumination light condensed with the condensing unit and to cause the diffused illumination light to incident on the illumination target surface.

A projection display device includes an image data control unit that controls image data to be input to a light modulation unit, and a situation determination unit that determines, in a state where an automated driving mode is set, whether or not a situation has occurred where an operation device mounted in a vehicle and used for driving needs to be operated. When it is determined that the situation has occurred where the operation device needs to be operated, the image data control unit inputs, to a driving unit, first image data for displaying images corresponding to a plurality of operation devices in a positional relationship corresponding to an arrangement of the plurality of operation devices and displaying, in an emphasized manner, the image corresponding to the operation device that needs to be operated, and displays an operation assisting image that is based on the first image data.

A head-up display system includes a housing having an interior surface and defining a cavity configured for receiving a ray of light. The head-up display system also includes a lens disposed within the cavity and configured for reflecting the ray of light towards the interior surface. Further, the head-up display system includes a first cured film formed from a coating composition, disposed on the interior surface, and configured for absorbing a ray of light within the cavity. The head-up display system also includes a second deposited film formed by an ionized gas treatment of the first cured film. The second deposited film is configured for transmitting the ray of light to the first cured film to thereby minimize scatter of the ray of light within the cavity. A device including the head-up display system is also described.

Provided is a head-up display device which has a virtual image plane shape becoming a part of a concave shape as viewed from the driver side. This head-up display device (30) includes: an image forming unit (10) that displays image information; and a projection optical system including an ocular optical system (5) that displays a virtual image by reflecting light emitted from the image forming unit (10). The ocular optical system (5) includes spherical lenses (51), (52), (53), and a free-form curved surface mirror (56), and is configured by arranging the spherical lenses (51), (52), (53) and the free-form curved surface mirror (56) in this order along the light emission direction.

A head-up display device is provided with: a combined light output unit which outputs combined light obtained by combining light emitted by a plurality of light sources which emit light having different wavelengths; and a heat dissipator which dissipates heat emitted by the light sources. The head-up display device displays a virtual image by means of the combined light. The plurality of light sources include a first light source which operates in a first operation guaranteed temperature band, and second light sources which operate in a second operation guaranteed temperature band having an upper limit higher than that of the first operation guaranteed temperature band. The first light source is provided in a location on the heat dissipator having a higher heat dissipation characteristic than the locations of the second light sources.

A method for providing a machine operator with an augmented reality view of an environment includes determining a location and orientation of a vehicle. An eye position and gaze of an operator of the vehicle are also determined. Job information to be displayed to the operator of the vehicle is determined based on the location of the vehicle and the orientation of the vehicle. The job information is displayed to the operator based on the eye position and gaze of the operator of the vehicle. In one embodiment, environmental features that can be seen through the windscreen are determined. The job information displayed to the operator is modified based on the environmental features.

A method for computing a display of additional information for display on a display unit. The insertion of additional information supports the driver in the longitudinal guidance of a transportation vehicle. The insertion of the additional information takes place as an augmented reality display, so that the additional information is computed contact-analogously to one or more objects in the environment of the transportation vehicle. The position of a transportation vehicle traveling in front is detected. When the observer transportation vehicle is approaching the transportation vehicle in front, an animated graphic is displayed section by section in a periodically recurring manner starting from the observer transportation vehicle.

A system and method for identifying content relevant to a vehicle occupant using a rotatably-mounted sensor in a field of view of the vehicle occupant. The rotatably-mounted sensor collects information and data from its surroundings. The information and data is processes to identify relevant content to be presented to the vehicle occupant. The rotatably-mounted sensor is configured to rotate in a manner that directs the occupants gaze in a direction of the relevant content being presented. The relevant content may be selected based on information that is known about the vehicle occupant, the vehicle location, the vehicle destination, the vehicle surroundings associated with the location and/or destination, and vendor relationships.

The present invention makes it possible to reduce a difference in resolution between respective regions of a virtual image while reducing distortion of an image. A translucent screen is disposed to be inclined with respect to an optical axis of projection light such that a difference between a first optical path length to a first reflection part of the display light emitted from a first end far from display light reflected toward a second reflection part by the first reflection part, and a second optical path length of display light emitted from a second end closer to reflected toward the second reflection part by the first reflection part than the first end becomes smaller.

An image display apparatus includes an image forming unit and a vehicle provided with the image display apparatus. The image forming unit includes a light source unit configured to emit light, an optical scanner configured to scan the light emitted from the light source unit two-dimensionally in a main scanning direction and a sub-scanning direction, and an intermediate image forming unit configured to form an intermediate image by the light scanned by the optical scanner. The image forming unit satisfies 0.3<Rm/L<3, where Rm denotes a radius of curvature of the intermediate image forming unit in the main scanning direction, and L denotes distance between a reference point when the optical scanner deflects and scans the light and a center of the intermediate image formed on the intermediate image forming unit. In the vehicle, the image display apparatus indicates the intermediate image to a driver as a virtual image.