The invention relates to a method for calibrating a light source (104) of a medical device (102), wherein the light source (104) is connectable to at least one light-guiding fiber (112) such that electromagnetic radiation of a defined light power that is generated by the light source (104) is at least partly coupled into the light-guiding fiber (112). The medical device (102) is connected to at least one calibration port (108), wherein the calibration port (108) comprises sensor means for determining a spatial emission characteristic of a light-guiding fiber (112) introduced into the calibration port (108). In this case, the method avoids an improper treatment on account of an incorrectly chosen coupled-out intensity of the electromagnetic radiation used.

A flicker measurement device includes a first processing unit that performs a first process of calculating respective flicker values of a plurality of measurement regions set on a measurement object based on a photometric quantity of the measurement object obtained from the measurement object under a measurement condition of a flicker for each of the plurality of measurement conditions stored in advance in a measurement condition storage unit, a second processing unit that performs a second process of generating linked data in which data composed of the respective flicker values of the plurality of measurement regions calculated by the first processing unit and the measurement conditions are linked for each of the plurality of measurement conditions, and a third processing unit that performs a third process of storing the linked data generated by the second processing unit in a linked data storage unit for each of the plurality of measurement conditions.

The present disclosure includes an electronic device and a method thereof. The electronic device includes a display, an ambient light sensor, and at least one processor, operatively connected to the display and the ambient light sensor. The at least one processor is configured to detect, by using the ambient light sensor, ambient light of the electronic device during a first duration in a state in which the display is turned off, identify a setting for being used for the ambient light sensor, based at least in part on a characteristic of the ambient light, detect, by using the ambient light sensor, ambient light of the electronic device during a second duration based at least in part on the identified setting, and control a function of the display, based at least in part on the characteristic of the ambient light detected during the second duration.

A laser detection system and method of two way communication comprising: a Mach Zehnder interferometer, the Mach Zehnder interferometer comprising: an entry beam splitter for splitting incident light into a first arm, having an arm length L1 and a second arm having an arm length L2; a modulation stage for receiving a modulation signal and applying a phase difference to the second arm, the magnitude of the phase difference depending upon the magnitude of the modulation signal; an exit beam splitter for recombining light from the first arm with light from the second arm to create a first output and a second output; a detection stage comprising a first detector at the first output for detecting intensity modulation caused by interference of the recombined light; and a signal processor communicably connected to both the modulation stage and the detection stage.

A sensing system comprising a light filtering apparatus configured to pass a first wavelength of light corresponding to an emission spectrum characteristic of Mercury. The sensing system comprises a sensor configured to receive light passed by the light filtering apparatus and produce a sensor response that is indicative of the light passed by the light filtering apparatus. The sensing system comprises a processor configured to use the sensor response to distinguish between light emitted by a fluorescent light source and light emitted by a light emitting diode.

A laser-line-generating system generates and process a laser light to illuminate a capillary array. The laser-line-generating system includes a laser-light source, focusing optics, a first optical scanner, and a second optical scanner. The laser-light source outputs a first laser light. The focusing optics receives the first laser light and reduces a beam width of the first laser light. The first optical scanner receives the first laser light and output a first optical-scanner-outputted light by varying an angle of outputted light along a first dimension. The second optical scanner receives the first optical-scanner-outputted light and outputs a second optical-scanner-outputted light by varying an angle of outputted light along a second dimension. The second optical-scanner-outputted light includes a line with dimensional components in both the first dimension and the second dimension.

A device including a plurality of epitaxial chips is disclosed. An epitaxial chip can have one or more of a light source and a detector, where the detector can be configured to measure the optical properties of the light emitted by a light source. In some examples, one or more epitaxial chips can have one or more optical properties that differ from other epitaxial chips. The epitaxial chips can be dependently operable. For example, the detector located on one epitaxial chip can be configured for measuring the optical properties of light emitted by a light source located on another epitaxial chip by way of one or more optical signals. The collection of epitaxial chips can also allow detection of a plurality of laser outputs, where two or more epitaxial chips can have different material and/or optical properties.

A high-resolution optical spectrometer with multiple diffractive optical elements operates under broadband light and enables spectral splitting with 3D diffractive optical elements. Diffractive optical elements are used to provide concentration of light as well as spectral splitting. Depending on the application, the high-resolution optical spectrometer operates with a reflection or transmission diffractive optical element. The number of operating wavelengths, spectral resolution, and operating bandwidth of diffractive optical elements are flexible depending on application.

A mode control system and method for controlling an output mode of a broadband radiation source including a photonic crystal fiber (PCF). The mode control system includes at least one detection unit configured to measure one or more parameters of radiation emitted from the broadband radiation source to generate measurement data, and a processing unit configured to evaluate mode purity of the radiation emitted from the broadband radiation source, from the measurement data. Based on the evaluation, the mode control system is configured to generate a control signal for optimization of one or more pump coupling conditions of the broadband radiation source. The one or more pump coupling conditions relate to the coupling of a pump laser beam with respect to a fiber core of the photonic crystal fiber.

A method for operating an illuminating device of a motor vehicle, wherein light is radiated into a lighting volume by the illuminating device, wherein a control condition is evaluated, the fulfillment of which depends on whether the lighting volume comprises a partial lighting volume by which an area and/or an environment volume is illuminated that is illuminated or can be illuminated by an infrastructure luminaire, wherein when the control condition is fulfilled, the illuminating device is controlled in such a way that light is radiated into the partial lighting volume with a different light intensity than into a residual lighting volume of the lighting volume, which residual lighting volume lies outside the partial lighting volume.