The object of the present invention is to provide an ultraviolet-emitting device which achieves suppresses deterioration, and prolonged life of the components used in a light-emitting device while monitoring a light emitting state of the light-emitting element and maintaining an emission intensity. The ultraviolet-emitting device is provided with a light-emitting element configured to emit an ultraviolet ray, a mounting board on which the light-emitting element is placed, and a fluorescent glass element placed at a position irradiated with the ultraviolet ray emitted by the light-emitting element, and placed in a through hole formed through the mounting board, emitting fluorescence in a visible range by excitation of an ultraviolet ray.

An optoelectronic device is specified, with a radiation-emitting semiconductor chip configured to generate electromagnetic radiation, and an active element configured to change a physical state, wherein the active element is embedded in a component of the component, and the physical change of state comprises the following: temperature change, sound generation, mechanical motion.

An optoelectronic device is specified, with a radiation-emitting semiconductor chip configured to generate electromagnetic radiation, and an active element configured to change a physical state, wherein the active element is embedded in a component of the component, and the physical change of state comprises the following: temperature change, sound generation, mechanical motion.

A light emitting device with on-chip optical power readout includes a light emitting mesa and a light detecting mesa formed adjacent to each other on the same substrate of a chip, and a portion of the light emitted from the light emitting mesa is transmitted to the light detecting mesa at least through the substrate. The light emitting mesa and the light detecting mesa have exactly the same epitaxial structure and can be electrically isolated from each other by an insulation layer, or an airgap formed therebetween, or by ion implantation. The light emitting mesa and the light detecting mesa can also share an n-type structure and a common n-electrode while having their own p-electrode, respectively.

Systems and methods for detection of incident light are described. An optical imaging sensor is positioned at least partially within an active display area of a display and is configured to detect and characterize one or more properties of light incident to the active display area of the display.

Systems and methods for detection of incident light are described. An optical imaging sensor is positioned at least partially within an active display area of a display and is configured to detect and characterize one or more properties of light incident to the active display area of the display.

An optical coupling device includes a light receiving element provided with a first output terminal and a second output terminal, a light emitting element provided on the light receiving element, a first switching element, a first electrode plate, and a sealing member. The first switching element is provided side by side on the light receiving element. A first main terminal and a control terminal are provided on an upper surface of the first switching element. A second main terminal is provided on a lower surface of the first switching element. The first main terminal is connected to the first output terminal. The control terminal is connected to the second output terminal. An upper surface of the first electrode plate is connected to the second main terminal. The sealing member covers the light receiving element, the light emitting element, and the first switching element.

There is provided an imaging device capable of further improving image quality of a subject, particularly a lesion portion such as cancer. There is provided an imaging device including: a first substrate including a first pixel array unit in which a plurality of pixels having at least a first photoelectric conversion unit is arranged in a two-dimensional manner, a first wiring layer, and a first support layer stacked in this order; and a second substrate including a second pixel array unit in which a plurality of pixels having at least a second photoelectric conversion unit is arranged in a two-dimensional manner, a second wiring layer, and a second support layer stacked in this order, in which the first support layer and the second support layer are bonded to each other to form a stacked structure, and at least one of the support layers includes an antireflection layer.

There is provided an imaging device capable of further improving image quality of a subject, particularly a lesion portion such as cancer. There is provided an imaging device including: a first substrate including a first pixel array unit in which a plurality of pixels having at least a first photoelectric conversion unit is arranged in a two-dimensional manner, a first wiring layer, and a first support layer stacked in this order; and a second substrate including a second pixel array unit in which a plurality of pixels having at least a second photoelectric conversion unit is arranged in a two-dimensional manner, a second wiring layer, and a second support layer stacked in this order, in which the first support layer and the second support layer are bonded to each other to form a stacked structure, and at least one of the support layers includes an antireflection layer.

A display panel and an operation method thereof are disclosed. In the display panel, a second light-emitting device is configured to emit a second light ray to the non-display side, and a second photosensitive element is configured to allow the second light ray to be incident therein and detect the second light ray. A first light-emitting device and the second light-emitting device are configured to emit a first light ray to the display side, and a first photosensitive element is configured to allow the first light ray reflected by an external object to be incident therein and detect the reflected first light ray. The second light ray is of a type different from that of the first light ray.