Systems and methods for providing invisible sensor aperture for electronic devices. In one embodiment, an example device may have a display that includes a cover layer, a first layer disposed on the cover layer, the first layer having a substantially white ink that is translucent, a second layer disposed on the first layer, the second layer having the substantially white ink, a third layer disposed on the second layer, the third layer having the substantially white ink, and a fourth layer comprising a dark-colored ink, wherein the fourth layer includes a first aperture aligned with a sensor of the device located beneath the fourth layer.

A method of assessment of renal function by monitoring a time-varying fluorescence signal emitted from a fluorescent agent from within a diffuse reflecting medium with time-varying optical properties is provided that includes using a renal monitoring system comprising at least one light source, at least one light detector, at least one optical filter, and at least one controller to provide a measurement data set comprising a plurality of measurement entries, each measurement data entry comprising at least two measurements obtained at one data acquisition time from a patient before and after administration of the fluorescent agent.

Embodiments provide a proximity sensor located at a side edge of a terminal or a top side edge of the terminal. A first included angle is formed between light emitted by the proximity sensor and a touchscreen of the terminal. The terminal obtains data detected by a motion sensor, and motion data of the terminal based on the data detected by the motion sensor. The terminal determines whether the motion data is less than a first threshold. If the motion data is less than the first threshold, the terminal determines that no external object is currently approaching, and skips performing a mistouch prevention action. If the motion data is greater than or equal to the first threshold, the terminal determines, based on data detected by the proximity sensor, whether an external object is approaching, and determines, based on a determining result, whether to subsequently perform the mistouch prevention action.

An electromagnetic wave sensor cover includes a cover body. The cover body includes a base layer made of synthetic resin and permitting passage of an electromagnetic wave, one or more metal oxide layers permitting passage of the electromagnetic wave and being conductive, one or more low refractive index layers permitting passage of the electromagnetic wave and made of material that has a lower refractive index than material of the metal oxide layer, and two electrodes. The base layer includes a front surface and a rear surface in a transmission direction of the electromagnetic wave. The metal oxide layer and the low refractive index layer are laminated adjacent to each other in the transmission direction. A laminate of the metal oxide layer and the low refractive index layer is laminated on the front surface or the rear surface of the base layer.

Systems and methods for optical imaging are disclosed. An optical sensor for imaging a biometric input object on a sensing region includes a transparent layer having a first side and a second side opposite the first side; a set of apertures disposed above the first side of the transparent layer; a first set of reflective surfaces disposed below the second side of the transparent layer configured to receive light transmitted through the first set of apertures and to reflect the received light; a second set of reflective surfaces disposed above the first side of the transparent layer configured to receive the light reflected from the first set of reflective surfaces and to further reflect the light; and a plurality of detector elements positioned to receive the further reflected light from the second set of reflective surfaces.

Disclosed are a light emitting device configured to control the light output of a light emitting unit and a curing apparatus employing the same. The disclosed light emitting device may comprise: a main body having a window; a light source installed in the main body, for generating light of a predetermined wavelength and irradiating the generated light to the outside of the main body through the window; a photodetector installed in the main body, for receiving part of the light irradiated from the light source and monitoring the intensity of the light source; a light path converting unit installed between the light source and the photodetector, for transferring the part of the light irradiated from the light source to the photodetector; and an intensity adjusting unit for adjusting the intensity of the light source based on the signal detected from the photodetector.

The various embodiments described herein include methods, devices, and systems for fabricating and operating superconducting photon detectors. In one aspect, a photon detector includes: (1) a first waveguide configured to guide photons from a photon source; (2) a second waveguide that is distinct and separate from the first waveguide and optically-coupled to the first waveguide; and (3) a superconducting component positioned adjacent to the second waveguide and configured to detect photons within the second waveguide.

A flame detector that includes a spacer, a UV transparent window, and a UV sensing elements. The spacer has a spacer wall that extends along a first axis between a first spacer end and a second spacer end. The UV transparent window is disposed at the first spacer end. The spacer wall and the UV transparent window define a gas space. The UV sensing elements is disposed within the gas space.

It would be helpful to provide an optical body having excellent antireflection performance over a wide wavelength range from the visible light region to the near-infrared region. The present disclosure discloses an optical body 1 including a transparent substrate 10 and a fine uneven layer 20 with a fine uneven structure in at least one surface of the substrate 10. A maximum value (Ra) of reflectance for light in a wavelength region of 400 nm to 950 nm is 1 % or less, and a wavelength at which the reflectance is at a local minimum value (Rb) is 650 nm or more.

Methods and apparatus for using an indicator window of a handheld scanner as a trigger are disclosed herein. An example handheld scanner includes: a housing; an image sensor to capture image data through a front-facing opening; an indicia decoder; an indicator window positioned to face generally away from the front-facing opening and toward a user when the handheld scanner is in a handheld position; a light source disposed inside the housing to emit indication light through the window to provide an indication; a light detector disposed inside the housing and positioned to detect a reflection of the indication light received from an object positioned in front of or on the window outside the housing; and a processor configured to control a mode of the handheld scanner and/or a device in communication with the handheld scanner in response to the light detector detecting the reflection of the emitted indication light.