Provided are a projection-type display device, an electronic device, a driver viewing image sharing method, and a non-transitory computer readable recording medium storing a driver viewing image sharing program. An HUD comprises a captured image data acquisition unit that acquires captured image data from an imaging unit that captures ahead of a windshield, a projection image data generation unit that analyzes the acquired captured image data and generates projection image data, a projection unit that modulates light emitted from a light source unit according to the projection image data and projects the modulated light onto a combiner, a driver viewing image data generation unit that generates driver viewing image data in which the projection image data is overlapped on the captured image data, and a communication unit that transmits the driver viewing image data to an electronic device that includes a display unit and exists in the motor vehicle.

The embodiments disclosed in this application describe a displaying system, a displaying method, and a head-up display. The displaying system includes a display window including a transflective film, an image source for emitting s-polarized light incident on the transflective film, where the transflective film has an average reflectivity more than 50% for the s-polarized light, and where the imaging window is further used to transmit ambient light. The embodiments disclosed herein can reduce the demand on the brightness of the image source, can eliminate ghost image, obtain better visual effect, and reduce cost.

The present invention relates to a separate head-up display device, an adhesive paste set on a bottom side of the base of a display module is provided to adhere on a windshield, to reduce shakes that a reflective sheet of a reflective sheet adjustment module is fixed on the dashboard and the windshield, and rotary joint structures are further set between the display module and the reflective sheet adjustment module, so that a driver may easily adjust the direction of the reflective sheet to obtain an optimal viewing angle, to thereby improve driving safety.

The embodiments disclosed in this application describe a displaying system, a displaying method, and a head-up display. The heads-up displaying system includes a display window including a transflective film, an image source emitting light incident on the imaging window, and the light emitted by the image source before reaching the transflective film only comprising s-polarized light. The transflective film is configured to directly reflect a first portion of the s-polarized light emitted from the image source. The transparent substrate reflects a second portion of the s-polarized light, and transmits a third portion of the s-polarized light to the air, the first portion of the s-polarized light, the second portion of the s-polarized light and the third portion of the s-polarized light are all s-polarized light.

A motor vehicle includes a rearview camera capturing images of a scene behind the motor vehicle. An electronic processor receives the images captured by the camera. A virtual image projection arrangement is communicatively coupled to the electronic processor and presents a virtual image dependent upon the images captured by the camera. The virtual image is visible by a driver of the vehicle after being reflected by a windshield.

A head-up display device that is to be mounted in a moving vehicle and enables an occupant in the moving vehicle to view a virtual image based on a reflected image of projection light in a projection section. The projection section includes an interlayer film, a first glass plate disposed closer to an outside of the moving vehicle, and a second glass plate disposed closer to an inside of the moving vehicle, the first glass plate and the second glass plate disposed opposite each other with the interlayer film therebetween. The first glass plate and the second glass plate each have a tin surface on which tin is detected and a non-tin surface whose tin concentration is lower than the tin concentration on the tin surface.

A head-up display system for a motor vehicle includes a projection unit for providing a display image; a transparent holographic light guide display panel with a display surface in order to output a display image coupled into the display panel via a coupling-in region on a display surface, and a light guide which runs in a non-linear manner in order to guide a display image from the projection unit to the coupling-in region of the display panel.

A head-up display for a vehicle. The head-up display comprises a picture generating unit configured to project an image onto a glass surface and an optical stack. The optical stack comprises an infrared reflective waveplate and a dual brightness enhancement film. The infrared reflective waveplate transforms an incoming solar light beam from unpolarized light to incoming polarized light having an incoming S-polarization component and an incoming P-polarization component. The dual brightness enhancement film receives the incoming polarized light from the infrared reflective waveplate and eliminates substantially all of the incoming P-polarization component. The dual brightness enhancement film transmits substantially all of the incoming S-polarization component.

A system includes a first multilayer surface that includes a plurality of layers. The system further includes a plurality of sensors and circuitry. The circuitry receives a plurality of signals from the plurality of sensors and projection data associated with a media content projectable by a projection device. The projection data includes contrast control information associated with the media content. The circuitry determines ambient condition of an enclosed space based on the received plurality of signals. The circuitry selects one or more portions of the plurality of layers of the first multilayer surface based on the determined ambient condition or the projection data. The circuitry controls an opacity level of the selected one or more portions of the first multilayer surface to provide dynamic shade control in the enclosed space or improve contrast of the projected media content based on the determined ambient condition or the projection data.

An information processing device includes an acquisition unit configured to acquire a detection result on light outside a mobile object; an analyzer configured to determine a position of projection of content in the mobile object based on the detection result on the light outside the mobile object; and a display controller configured to perform control on projection of the content onto the determined position of projection.