A method for identifying minerals and other materials illuminates a mineral with monochromatic light for an illumination duration and a true Raman spectrum is determined. The true Raman spectrum data is compared to reference spectrums to identify the mineral or material by calculating an identification score for each reference Raman spectrum relative to the Raman spectrum data of the unknown material using a formula that includes both a coincident-peak term and a missing-peak-penalty term.

A sensor configured to determine a physical state of a vehicle occupant within a vehicle includes an electrode containing nanoscale metal fibers. The electrode is located within the vehicle to be in contact with the vehicle occupant. The sensor also includes a controller configured to determine the physical state of the vehicle occupant based on an output of the electrode.

An optical sensor and a method of operating the optical sensor are provided. The optical sensor includes a light source configured to emit a light, and a path adjuster configured to adjust a traveling path of the light to reflect the light at a first time, and allow the light to pass through the path adjuster at a second time. The optical sensor further includes a light receiver configured to receive a reference light among the reflected light, and receive, among the light passing through the path adjuster, a measurement light related to a target material.

A method for identifying minerals and other materials illuminates a mineral with monochromatic light for an illumination duration and a true Raman spectrum is determined. The true Raman spectrum data is compared to reference spectrums to identify the mineral or material by calculating an identification score for each reference Raman spectrum relative to the Raman spectrum data of the unknown material using a formula that includes both a coincident-peak term and a missing-peak-penalty term.

A target sample to be chemically analyzed is received at a microfluidic device which is part of an analysis card. The microfluidic device includes at least one input layer configured to receive the target sample, at least one intermediary layer, and at least one readout layer configured to present one or more color attributes at one or more readout regions in response to one or more colorimetric reactions to the target sample. An image of the readout layer of the microfluidic device is obtained. A calibration file that corresponds to the analysis card is obtained. The calibration file includes a calibrated model of at least one color attribute based on data from at least one known chemical attribute of at least one standard sample processed by a calibration card. A data processing function is executed on the obtained image by comparing the one or more color attributes at the one or more readout regions to the calibrated model of the at least one color attribute to determine at least one chemical attribute of the target sample.

Provided is an imaging ellipsometry (IE)-based inspection method including selecting a mode from among a first mode of an IE-based inspection device having a first field of view (FOV) and a second mode of an IE-based inspection device having a second FOV, measuring an inspection target by the IE-based inspection device based on the selected mode, and determining whether the inspection target is normal based on a result of the measuring, wherein the measuring of the inspection target comprises simultaneously measuring patterns included in a plurality of cells provided in a region of the inspection target, the region corresponding to an FOV of the selected mode.

An optical sensor and a method of operating the optical sensor are provided. The optical sensor includes a light source configured to emit a light, and a path adjuster configured to adjust a traveling path of the light to reflect the light at a first time, and allow the light to pass through the path adjuster at a second time. The optical sensor further includes a light receiver configured to receive a reference light among the reflected light, and receive, among the light passing through the path adjuster, a measurement light related to a target material.

A hand-held microfluidic testing device is provided that includes a housing having a cartridge receiving port, a cartridge for input to the cartridge receiving port having a sample input and a channel, where the channel includes a mixture of Raman-scattering nanoparticles and a calibration solution, where the calibration solution includes chemical compounds capable of interacting with a sample under test input to the cartridge and the Raman-scattering nanoparticles, and an optical detection system in the housing, where the optical detection system is capable of providing an illuminated electric field, where the illuminating electric field is capable of being used for Raman spectroscopy with the Raman-scattering nanoparticles and the calibration solution to analyze the sample under test input to the cartridge.

An apparatus for processing crop, animal feed or components with a drivable tool and at least one NIR sensor system for determining at least feed values, having a scanning head with a spectrometric sensor and at least one light source behind a transparent pane which can be passed by the feed, comprises in a housing of the NIR sensor system a calibration surface, the appearance of which is different from the appearance of the feed to be scanned on the pane, wherein the scanning head is actively adjustable for calibration between a scanning position aligned with the pane and a calibration position aligned with the respective calibration surface.

A calibrator of an OES may include a cover, a reference light source and a controller. The cover may be detachably combined with a ceiling of a plasma chamber of a plasma processing apparatus. The reference light source may be installed at the cover to irradiate a reference light to the OES through an inner space of the plasma chamber. The controller may compare a spectrum of the reference light inputted into the OES with a spectrum of an actual light inputted into the OES during a plasma process in the plasma chamber to calibrate the OES. Thus, the OES may be calibrated without disassembling of the OES from the plasma chamber to decrease a time for calibrating the OES.