A device may receive information identifying results of a spectroscopic measurement performed on an unknown sample. The device may determine a decision boundary for a quantification model based on a configurable parameter, such that a first plurality of training set samples of the quantification model is within the decision boundary and a second plurality of training set samples of the quantification model is not within the decision boundary. The device may determine a distance metric for the spectroscopic measurement performed on the unknown sample relative to the decision boundary. The device may determine a plurality of distance metrics for the second plurality of training set samples of the quantification model relative to the decision boundary. The device may provide information indicating whether the spectroscopic measurement performed on the unknown sample corresponds to the quantification model.

The present invention relates to methods for determining the change in concentration of a substance in solution over time by continuously monitoring in real time. In particular, the present invention relates to methods for continuously monitoring the concentration of compounds during the manufacturing process of biomolecules.

The present invention relates to methods for determining the change in concentration of a substance in solution over time by continuously monitoring in real time. In particular, the present invention relates to methods for continuously monitoring the concentration of compounds during the manufacturing process of biomolecules.

The present invention provides a system for measuring concentrations of trace gases in gas mixtures using the absorption spectroscopy method. The system comprising an optical cell containing a gas mixture, a continuous-wave tunable laser, a detector system for measuring an absorption of laser light by the gas in the optical cell, and a processor to conduct an absorption spectroscopy analysis of the gas mixture based on light intensity measured by the detector system at one or more laser frequencies.

A method for measuring molecular interactions on a plurality of regions of interest (ROIs) of a sensor surface of a biosensor device. The method can include receiving respective biosensor response data for each ROI of the plurality of ROIs. The method further can include determining a sample group and a reference group for the plurality of ROIs. The sample group can include sample group ROIs of the plurality of ROIs, and the reference group can include reference group ROIs of the plurality of ROIs. The method also can include generating one or more sample data distributions based on one or more respective sample group binding parameters for each of the sample group ROIs derived from the respective biosensor response data for the each of the sample group ROIs. The method further can include generating one or more reference data distributions based on one or more respective reference group binding parameters for each of the reference group ROIs derived from the respective biosensor response data for the each of the reference group ROIs. Other embodiments are disclosed.

The present invention provides systems and methods for measuring the isotope ratios of one or more trace gases based on optical absorption spectroscopy methods. The system includes an optical cavity containing a gas. The system also includes a laser optically coupled with the optical cavity, and a detector system for measuring absorption of laser light by the gas in the cavity.

The present invention provides a system for measuring concentrations of trace gases in gas mixtures using an absorption spectroscopy method. The system comprising: a resonant optical cavity containing a gas mixture, a continuous-wave external cavity laser, a detector system for measuring an absorption of laser light by the gas in the resonant optical cavity, wherein the ratio of the round-trip length of the external cavity laser to the round-trip length of the resonant optical cavity or its inverse value is between N−0.2 and N+0.2, where N is a positive integer number.

The present invention provides a system for measuring concentrations of trace gases in gas mixtures using an absorption spectroscopy method. The system comprising: a resonant optical cavity containing a gas mixture, a continuous-wave external cavity laser, a detector system for measuring an absorption of laser light by the gas in the resonant optical cavity, wherein the ratio of the round-trip length of the external cavity laser to the round-trip length of the resonant optical cavity or its inverse value is between N−0.2 and N+0.2, where N is a positive integer number.

The invention relates to a method for determining a value quantifying the effect of an optical filter on a parameter linked to an eye, this optical filter blocking at least partially the transmission of light over a predetermined wavelength range, comprising the following steps: a) at least one spectral feature of the optical filter related to the transmittance of this optical filter at at least one wavelength in said predetermined wavelength range is provided, b) the value quantifying the effect of the optical filter on said parameter is calculated as a function of said at least one spectral feature of the optical filter provided in step a).

Systems and methods for measuring the isotope ratio of one or more gaseous oxides produced during combustion of drugs, pharmaceuticals, or medicines aiming to detect counterfeit drugs, pharmaceuticals, or medicines based on comparison of the isotopic composition of the tested drugs, pharmaceuticals, or medicines with the isotopic composition of the authentic products.