Devices and methods for non-dispersive infrared (NDIR) sensing are disclosed. In one aspect, a non-dispersive infrared sensor is disclosed which, in one embodiment includes a nanophotonic infrared emitting metamaterial (NIREM) emitter configured to selectively emit radiation corresponding to a respective vibrational resonance frequency for each of a plurality of different analytes of interest. The broadband detector can be configured to detect photons associated with vibrational resonance of each of the plurality of analytes of interest in response to the emitted radiation from the NIREM emitter, in order to determine properties of one or more of the analytes of interest.

Provided are a concentration measuring method of an optically active substance and a concentration measuring device of an optically active substance, which can easily and accurately measure a concentration of the optically active substance in aqueous humor. The concentration measuring method of an optically active substance includes: a first step of measuring a polarization state of a first reflected light that is obtained by irradiating an aqueous humor in an eye with an incidence light which is polarized and reflecting the incidence light at an interface between the aqueous humor and a lens, in which the polarization state of the first reflected light is measured by irradiating a first incidence light such that an angle between a normal line to a point where the incidence light intersects a surface of the lens, and the incidence light is equal to or smaller than a Brewster angle; a second step of measuring a polarization state of a second reflected light by irradiating with a second incidence light such that an angle of the incidence light is equal to or larger than the Brewster angle; a third step of calculating an optical rotation of the aqueous humor with information on the polarization state of the first reflected light and information on the polarization state of the second reflected light; and a fourth step of calculating a concentration of an optically active substance in the aqueous humor from the optical rotation of the aqueous humor.

This disclosure includes an imaging system that is configured to image in parallel multiple focal planes in a sample uniquely onto its corresponding detector while simultaneously reducing blur on adjacent image planes. For example, the focal planes can be staggered such that fluorescence detected by a detector for one of the focal planes is not detected, or is detected with significantly reduced intensity, by a detector for another focal plane. This enables the imaging system to increase the volumetric image acquisition rate without requiring a stronger fluorescence signal. Additionally or alternatively, the imaging system may be operated at a slower volumetric image acquisition rate (e.g., that of a conventional microscope) while providing longer exposure times with lower excitation power. This may reduce or delay photo-bleaching (e.g., a photochemical alteration of the dye that causes it to no longer be able to fluoresce), thereby extending the useful life of the sample.

Embodiments of this invention relate generally to a miniature multi-spectral system to detection pathogen, biomarkers, or any compound from a sample. In one example, a miniature multi-spectral system comprises a first miniature spectrometer to generate a first spectral output based on a sample, a second miniature spectrometer to generate a second spectral output based on the sample, and a processor coupled to the first and the second miniature spectrometers. The processor is configured to execute instructions to perform data fusion of the first and second spectral outputs to generate fused data, and to apply artificial intelligence (AI) of an AI module to the fused data to identify a pathogen, biomarker, or any compound from the sample.

An automatic analysis apparatus comprises: a light source generating light having a center wavelength equal to or shorter than 340 nm; a fluorescent substance excited by the light source light, and generates light together with transmitted light from the light source, having a wavelength of 340 nm to 800 nm; a condenser lens; at least one slit; a reaction cell holding a reaction solution where a specimen and reagent are mixed, and that the light source light and the light from the fluorescent substance enter; and a detector that detects light transmitted through the reaction cell. The light source, fluorescent substance, condenser lens, and slit are provided along a straight light corresponding to the optical axis. The width of the slit's opening is equal to or narrower than the width of a ray forming an image of the light source at the position of the slit.

Embodiments disclosed herein relate to methods and systems for determining thermal properties of materials by using frequency modulated pump light intensity to cyclically heat a sample, and using probe light to induce fluorescent signals from fluorescent indicators on the surface of the material during the cyclic 5 heating. The methods and systems utilize the phase delay between the frequency modulated pump light and the corresponding fluorescent signals to determine the thermal properties of the material at one or more locations on the material sample.

A measuring device for measuring the absorbance of a substance in at least one solution provided in at least two flow cells of the measuring device, wherein said measuring device comprises: —a light source transmitting a first light ray; —said at least two flow cells; —an optical arrangement comprising at least two semi-transparent mirrors with different transmission properties, said optical arrangement being arranged for dividing the first light ray coming from the light source into separate light parts, one for passing each flow cell and one for entering directly after the optical arrangement a reference detector; and —one detector provided after each flow cell for detecting light having passed through the flow cells.

A method for manufacturing a gas concentration calculation device including a housing made of a synthetic resin and configured to include a cylindrical portion including first and second openings, respectively, at axial both ends thereof, and first and second mirrors, respectively, arranged facing each other at the first and second openings to form an optical path of infrared light inside the cylindrical portion. The method includes a step of preparing a precursor including respective sticking-out portions made of a synthetic resin sticking more outward than respective installation positions of first and second mirrors in a cylindrical portion and a step of bonding the first and second mirrors to the respective installation positions by arranging the first and second mirrors, respectively, at the respective installation positions of the precursor and then bending the sticking-out portions while melting with heat to cause them to adhere to the first and second mirrors.

An apparatus for producing an infrared spectrum according to one example of the present disclosure includes: a toxic chemical gas and background infrared spectrum acquisition portion of acquiring a background of a target area and an infrared spectroscopic signal of a gas contaminant plume existing in the background; and a toxic chemical gas infrared spectrum generation portion of training a Generative Adversarial Network (GAN) using acquired background radiation intensity data as learning data, and automatically generating a toxic chemical gas simulation infrared spectrum signal according to an environment setting inputted from a user using a learned GAN. According to the present disclosure, there is an effect that an infrared spectrum of atmosphere contaminated by a toxic chemical gas may be acquired without outdoor experiments using a real toxic chemical gas.

A multi-mode illumination system, including: a first illumination module; a second illumination module; and a third illumination module, as disclosed herein.