A wearable computing device includes an electronic display with a configurable brightness level setting, a physiological metric sensor system including a light source configured to direct light into tissue of a user wearing the wearable computing device and a light detector configured to detect light from the light source that reflects back from the user. The device may further include control circuitry configured to activate the light source during a first period, generate a first light detector signal indicating a first amount of light detected by the light detector during the first period, deactivate the light source during a second period, generate a second light detector signal indicating a second amount of light detected by the light detector during the second period, generate a physiological metric based at least in part on the first light detector signal and the second light detector signal, and modify the configurable brightness level setting based on the second light detector signal.

Embodiments of this application disclose a terminal, The terminal includes a bezel, a screen, a lampshade, and a proximity light assembly. A periphery of the screen is fixedly connected to the bezel. The bezel is provided with a through hole. The lampshade is located on an inner side of the bezel and partially accommodated in the through hole. The proximity light assembly is located on the inner side of the bezel. The proximity light assembly is configured to emit emitted light into the lampshade and receive induced light passing through the lampshade. The emitted light passes through the lampshade to form emergent light. The emergent light intersects with a plane on which the screen is located. The terminal has a relatively high screen-to-body ratio.

The disclosure provides a small photoelectric sensor that can secure a capacity for accommodating optical components and secure sealing properties. The small photoelectric sensor includes a holder in which an opening, an edge that defines the opening, and four fixing parts that are independently provided at four corners of a front surface are formed on the front surface; a cover lens that is provided at a position interposed between the four fixing parts, and is connected to the edge in a region overlapping the edge; and an optical component that is held by the holder and projects or receives light through the opening.

A metal-insulator-metal (MIM) high-sensitivity plasmon polariton (SPP) terahertz wave detector includes a rectangular cavity, an absorption cavity, a silver block, two waveguides, three metal films, a terahertz probe light, a signal light, and an opto-electric detector; the terahertz probe light is located at an upper end of the rectangular cavity; the rectangular cavity is located at an input end of the terahertz probe wave; and the absorption cavity is connected with a first waveguide; the silver block is disposed within the first waveguide, and is movable; and the first waveguide is connected with a second waveguide.

A display device includes: a display panel including a display region where a user image is displayed and a measurement region; a transparent front panel disposed on a front side of the display panel; a bonding layer provided between the display panel and the front panel to avoid a first space and cover the display region, and bonding the display panel and the front panel together; and a component placed in the first space, the component including a detector configured to detect a physical property of the measurement region in the first space and flexible print circuits with the detector mounted thereon, and the flexible print circuits extending from the first space to an outside of an interspace between the display panel and the front panel.

A superconductor device is manufactured by depositing a barrier layer over a substrate including silicon, the barrier layer including silicon and nitrogen; depositing a seed layer for a superconductor layer over the barrier layer, the seed layer including aluminum and nitrogen; depositing the superconductor layer over the seed layer, the superconductor layer including a layer of a superconductor material, the barrier layer serving as an oxidation barrier between the layer superconductor material and the substrate; and depositing a silicon cap layer over the superconductor layer. In some embodiments, the superconductor device includes a waveguide and a metal contact at a sufficient distance from the waveguide to prevent optical coupling between the metal contact and the waveguide.

An IC integrated structure for an optical mouse of the invention comprises a bracket configured for being connected with a PCB, an LED wafer for emitting light, a main control IC wafer and an optical lens; wherein the LED wafer and the main control IC wafer are respectively mounted at two ends of a terminal surface inside a bracket frame, the LED wafer and the main control IC wafer are connected with the PCB by the bracket, and the optical lens is mounted above the LED wafer and the main control IC wafer; a light shield configured for shielding an external light source is arranged between the optical lens and the main control IC wafer, and a through hole configured for transmitting light is formed in the light shield.

An optical assembly for an optical sensor device has a lens plate, a light source, and a light receiving unit. The lens plate includes a lens structure on a side associated with the light source and a light extraction structure on a side facing away from the light source. The lens structure has different local radii of curvature.

An optical package assembly can include: a first circuit board; a second circuit board and a first structure arranged on the first circuit board, where the second circuit board is adjacent to the first structure; and a second structure arranged on the second circuit board, where a thickness of the first structure is equal to a combined thickness of the second circuit board and the second structure.

Imaging systems may include tunable polarization filters. A tunable polarization filter may be integrated directly into an image sensor package. For example, the tunable polarization filter may serve as cover glass for the image sensor package. Tunable polarization package glass may be incorporated into image sensor packages that have air gaps between the image sensor and the cover glass or that have transparent adhesive between the image sensor and the cover glass. The tunable polarization layer may be controlled at a global level, at a sub-array level, or at a pixel level. In some cases, the tunable polarization layer may be a tunable polarization filter. In this example, the direction of the polarization filter is tuned. In other cases, the tunable polarization layer may be a tunable polarization rotator. In this example, the tunable polarization layer selectively rotates the polarization of light that passes through the tunable polarization layer.