A method of obtaining a plurality of infrared images of a banknote that involves simultaneously illuminating the banknote with infrared light at a first wavelength and infrared light at a second wavelength, capturing an image of the banknote with an RGB camera, obtaining from both a first output channel signal and a second output channel signal of the RGB camera sensor where the intensity distribution of the infrared light at the first wavelength and the intensity distribution of the infrared light at the second wavelength uses a first calibration coefficient and a second calibration coefficient of the RGB camera sensor, producing separate infrared images of the banknote at the first wavelength and the second wavelength from the respective intensity distributions.

An optical sensor system may include a light source. The optical sensor system may include a concentrator component proximate to the light source and configured to concentrate light from the light source with respect to a measurement target. The optical sensor system may include a collection component that includes an array of at least two components configured to receive light reflected or transmitted from the measurement target. The optical sensor system may include may a sensor. The optical sensor system may include a filter provided between the collection component and the sensor.

A breath analyte capture device includes a breath input port into which a user exhales a breath sample, and a cartridge insertion port for receiving a disposable cartridge containing an interactant. During exhalation of a breath sample, at least a portion of the breath sample is routed through the cartridge such that the analyte (such as breath acetone) is captured by the interactant. In some embodiments, the concentration of the analyte in the breath sample is measured by monitoring a chemical reaction that occurs in the disposable cartridge. The chemical reaction may be monitored by illuminating the cartridge at each of multiple light wavelengths while measuring reflected light.

An observation device includes an illumination optical system provided on a lower side of an installation position of a multi-well plate, a reflector that reflects light emitted from the illumination optical system, the reflector being provided on an upper side of the installation position, and an observation optical system that condenses the light reflected by the reflector, the observation optical system being provided on the lower side of the installation position. The reflector includes a plurality of curved surfaces where the light emitted from the illumination optical system enters. Each of the plurality of curved surfaces corresponds to one or more wells included in the multi-well plate, has positive power in a first direction in which the illumination optical system and the observation optical system are aligned, and has a center of curvature at a position deviating from a central axis of a well of the multi-well plate.

A light emitting apparatus has light emitting units. The light emitting units can be respectively provided with current densities, so that the light emitted by each of the light emitting unit has a light intensity, wherein the current densities are different from each other, or partial of the current densities are different from each other. A number of the light emitting units can be larger than or equal to four, all of the four lighting frequencies of the four light emitting units are different from each other, or partial of the four lighting frequencies of the four light emitting units are identical to each other, and the light emitting apparatus and the object under test rotate relative to each other. A light emitting method, a spectrum detection method and a lighting correction method are also illustrated for increasing SNR, correcting the light intensity or the spectrum signal.

Systems and methods for monitoring, characterizing and controlling operation of LEDs are provided herein. Methods includes measuring a voltage across the LED, and correlating the voltage to a junction temperature of the LED. This correlation can be used to improve operation of the LED by increasing the signal to noise ratio of the LED signal, characterize the LED by comparing to an I-V curve, control LED operation to compensate for LED degradation and avoid crosstalk, and/or to generally improve performance and life expectancy of the LED. Improved performance of the LED can include stabilizing the photon output during performance of an assay to provide a desired dye reporter signal required for the assay and/or reducing an intra-shot during of the LED output during the assay. System and device with control units configured to perform these methods are also described herein.

A spectroscopic analyzer includes: an irradiator that irradiates a target measurement object with lights of a plurality of different wavelengths sequentially as a pre-irradiation, and, after the pre-irradiation, further irradiates the target measurement object with lights of a plurality of different wavelengths sequentially as a measurement-irradiation; a detector that, during the measurement-irradiation, detects reflected light, transmitted light, or a transmitted reflected light from the target measurement object at each of the plurality of different wavelengths of the measurement-irradiation and that outputs absorbance spectral data; a data analyzer that analyzes the absorbance spectral data; and a result display that displays analysis results related to components of the target measurement object.

An exemplary urinalysis device for non-clinical use is described as having: a housing; a touchscreen on the housing; a test strip holder, which is removably, slidably engaged with the housing; at least two light emitting diode (LED) light sources, housed in the housing and including a white LED and a red-blue-green (RBG) LED; a camera module housed in the housing, both the plurality of LEDs and the camera module directed to an illumination and detection zone; a timer system; and/or a computational system in electronic communication with the plurality of LEDs, the camera module and the timer system, the computational system including a processor and a memory. Related methods and systems also are described.

An apparatus for measuring the absorbance of a substance in a solution includes at least one sample cell arranged to contain the solution that is at least partially transparent to light of a predefined wavelength spectrum, at least two light passages through the at least one sample cell, each of the light passages having a known path length, an LED light source arrangement including at least two LEDs, each arranged to emit a light output with a wavelength within the predefined wavelength spectrum. A plurality of optical fibers, one for each light passage, is arranged at each LED for receiving the light output and guiding it to the light passages. A method for measuring the absorbance of a substance in a solution includes providing the LED light source arrangement with an associate fiber bundle for each LED.

Sensor systems, and flow cells for use with them, which can provide for a universal sensor housing. The senor housing includes a first section which is designed to remain statically in position and a selectable sensor head that may be swapped out as necessary. The specific head is selected based on the types of measurement to be performed at the sensor location and the sensor head can integrate with the housing so only a single wire connection needs to be made to obtain all data from the housing.