To provide a semiconductor device in which a layer to be peeled is attached to a base having a curved surface, and a method of manufacturing the same, and more particularly, a display having a curved surface, and more specifically a light-emitting device having a light emitting element attached to a base with a curved surface. A layer to be peeled, which contains a light emitting element furnished to a substrate using a laminate of a first material layer which is a metallic layer or nitride layer, and a second material layer which is an oxide layer, is transferred onto a film, and then the film and the layer to be peeled are curved, to thereby produce a display having a curved surface.

A light field (LF) display system for augmentation of a vehicle. The LF display system includes LF display modules that form a surface (e.g., interior and/or exterior) of a vehicle. The LF display modules each have a display area and are tiled together to form a seamless display surface that has an effective display area that is larger than the display area. The LF display modules present holographic content from the effective display area.

Provided is an imaging apparatus (10) including an imaging optical system (20), an image sensor (31), one or more circuit boards including at least one of the image sensor and an electronic component mounted thereon, a housing (11) including an opening that exposes the imaging optical system to a subject and supporting the imaging optical system, the image sensor, and the one or more circuit boards, a signal terminals (41) that transmit an image signal of the subject image captured by the image sensor to an outside of the housing, and a heat transfer unit (44) having heat conductivity connected to the plurality of terminals, the heat transfer unit that transfers heat generated from at least one of the image sensor and the electronic component to the plurality of terminals.

A shading device comprises: a shading member formed using a dimming glass plate capable of changing light transmittance, the shading member having a plate shape; a display apparatus being capable of transmitting light and disposed on a surface of the shading member, the surface being to face an operator during use of the shading member, in such a manner that a display portion faces the operator; an image pickup device to pick up, as an image, a region which an opposite surface of the surface faces, and generate image pickup data; a data processing circuit to generate display image data to be displayed on the display portion during use of the shading member, based on the image pickup data generated by the image pickup device; and a switch to change light transmittance of the dimming glass plate.

A shading device comprises: a shading member; a display apparatus disposed on a surface of the shading member in such a manner that a display portion faces to an operator; an image pickup device to pick up, as an image, a region which an opposite surface of the surface faces, and generate image pickup data; and a data processing circuit to generate display image data, based on the image pickup data. An image display module comprises: a display apparatus to be disposed on a surface of a shading device in such a manner that a display portion faces an operator; an image pickup device to pick up, as an image, a region to which an opposite surface of the surface faces, and generate image pickup data; and a data processing circuit to generate display image data, based on the image pickup data.

A cloaking device includes an object-side, an image-side, an object-side curved cloaking region (CR) boundary having an outward facing mirror surface and an inward facing surface, and an image-side curved CR boundary an outward facing mirror surface and an inward facing surface. A cloaked region is bounded by the inward facing surfaces of the object-side curved CR boundary and the image-side curved CR boundary. At least one exterior boundary with an inward facing mirror surface is spaced apart from the object-side curved CR boundary and the image-side curved CR boundary. Light from an object positioned on the object-side of the cloaking device and obscured by the cloaked region is redirected around the cloaked region to form an image of the object on the image-side of the cloaking device such that the light from the object appears to pass through the CR.

A system for optically cloaking an object includes a photophoretic optical trap display including a trap light source and an illumination light source; and a visual sensor at a first visual sensor location. The visual sensor captures an image of a scene, the trap light source is configured to generate a trap beam to control one or more of a position and an orientation of a scattering particle, and the illumination light source is configured to generate an illumination beam to illuminate the scattering particle to generate a reproduction image based on the image of the scene captured by the visual sensor.

A viewing device for a vehicle is provided with plural cameras, an image generation unit, a display and a switching control unit. The plural cameras have different imaging ranges. On the basis of captured images from one or a plural number of the cameras, the image generation unit generates plural viewing images that differ in at least one of viewpoint or viewing angle. The display displays the viewing images. The switching control unit is capable of switching a viewing image being displayed at the display to another of the viewing images.

A power consumption of a screen can be lowered while a motor vehicle is traveling, based on a line of vision of a user of the motor vehicle. An image of a surrounding area of the motor vehicle is captured, and a line of vision of the user of the motor vehicle is determined. The screen is switched to a normal mode of operation or a power-saving mode based on the determined line of vision. The power consumption of the screen in the power-saving mode is less than a power consumption of the screen in the normal mode of operation. The image of the surrounding area is displayed by use of the screen, at least while the screen is operated in the normal mode of operation.

An AR assist glasses system for vehicles includes a MCU (Microcontroller Unit) linked respectively with a camera for taking the images, a display device for showing the images either from the camera or other existing driving assist systems, a wireless communication module for sending the images or information of the specific zone which the driver pays attention to, a gyroscope for detecting the displacement of the head of the driver to decide which specific zone the driver pays attention to, a wireless charging module for charging the battery, a touch control for inputting the control information, and a micro vibration motor for warning the driver.