The present disclosure relates to an optical sensor comprising at least one light source for emitting transmission light into a medium, at least one detector, wherein the transmission light is at least partially converted in the medium by fluorescence into fluorescent light and the detector receives the fluorescent light, wherein a first receiver signal can be generated from the fluorescent light, and wherein a first measured value can be determined from the first receiver signal, wherein the transmission light is at least partially scattered by means of the medium to form scattered light, and the detector receives the scattered light, wherein a second receiver signal can be generated from the scattered light, and wherein a second measured value can be determined from the second receiver signal. The present disclosure further relates to a method for determining a first and second measured value of a medium.

An assay device is disclosed comprising a housing (10) and a test portion (2), electronic circuitry (30) and an optical assembly (41), each at least partially located in the housing (10). The test portion (2) comprises one or more test zones (2E, 2F) adapted to receive an analyte (22) and a fluorescent label associated with the analyte, the fluorescent label being excitable by excitation light and adapted to emit emission light upon excitation by excitation light. The electronic circuitry (30) comprises one or more light sources (31, 32) and one or more light detectors (33). The optical assembly (41-44) comprises one or more excitation light guides (41, 44) adapted to guide excitation light from the one or more light sources (31, 32) to the one or more test zones (2e, 2f), and/or one or more emission light guides (43, 44) adapted to guide emission light from the one or more test zones (2e, 2f) to the one or more light detectors (33). The sets of emission light guides (43, 44) and excitation light guides (41, 44) may also take the form of individual integral one-piece light guide units where the emission light guide unit rests within the excitation light guide unit.

The present invention concerns a device constituted by a planar optical antenna which allows to beam and collect light emitted from various light sources, including light-emitting devices (LEDs), fluorescent markers and single-photon sources. By considering the light source as a light receiver and using reciprocity, the device can also be used to improve the absorption of light by various receivers, including molecules. This device is in particular suitable for in-vitro diagnostics (IVD).

A waveguide sensor system is provided. The system includes a light source and a waveguide formed from a light transmitting material. Light from the light source enters the waveguide at an input area and travels within the waveguide by total internal reflection to an analyte area and light to be analyzed travels within the waveguide from the analyte area by total internal reflection to an output area. An optical sensor is coupled to the output area and is configured to interact with the light to be analyzed. The system includes a plurality of pores located along the outer surface within the analyte area and formed in the light transmitting material of the waveguide, and the pores are configured to enhance light interaction with the analyte within the analyte area.

Various claims of a multi-laser system are disclosed. In some claims, the multi-laser system includes a plurality of lasers, a plurality of laser beams, a beam positioning system, a thermally stable enclosure, and a temperature controller. Various claims of an optical system for directing light for optical measurements such laser-induced fluorescence and spectroscopic analysis are disclosed. In some claims, the optical system includes a beam shaping element configured to generate an illumination profile having a flat top.

A waveguide sensor system is provided. The system includes a light source and a waveguide formed from a light transmitting material. Light from the light source enters the waveguide at an input area and travels within the waveguide by total internal reflection to an analyte area and light to be analyzed travels within the waveguide from the analyte area by total internal reflection to an output area. An optical sensor is coupled to the output area and is configured to interact with the light to be analyzed. The system includes a plurality of pores located along the outer surface within the analyte area and formed in the light transmitting material of the waveguide, and the pores are configured to enhance light interaction with the analyte within the analyte area.

Optical sensing techniques and devices based on detection of fluorescent emissions at different optical wavelengths by nonlinear optical absorption of different excitation beams at different excitation wavelengths that interact with fluorescently-labeled structures within the sample to cause nonlinear optical absorption of two or more photons at each excitation wavelength. The fluorescent light at different fluorescent emission wavelengths by nonlinear optical absorption of excitation light at a particular excitation wavelength is spectrally separated into different optical channel output beams along different optical channel optical paths at different designated fluorescent imaging wavelength bands and the fluorescent light at different fluorescent imaging wavelengths within each designated fluorescent imaging wavelength is detected. This two-stage spectral separation in obtaining fluorescent images at different fluorescent imaging wavelengths in different fluorescent imaging wavelength bands enables highly sensitive hyperspectral imaging based on two-photo or multi-photon nonlinear absorption.

Method for observing an emission of light (14, 15) from a sample (10) in a medium (11) of refractive index n.sub.L disposed against a surface (20a) of a transparent support (20) of refractive index n.sub.S, greater than n.sub.L, the emission of light comprising luminous components oriented toward the support and forming an angle with a direction (20b) perpendicular to the surface (20a), said components including supercritical luminous components and critical or subcritical luminous components, the method implementing an observation device (100) capable of collecting at least part of the emission of light, of applying filters (170) to the luminous signal collected; and of transforming the filtered luminous signal into an image zone of the sample (6a, 6b); the method being characterized in that: A modulation of the filtered luminous signal is carried out, in which luminous components arising from the critical or subcritical luminous components of the emission of light are allowed to pass through so as to obtain image zones (6a, 6b) of one and the same region of interest of the sample, the modulation pertaining to all or some of the luminous components of the collected luminous signal which arise from the supercritical luminous components of the emission of light; and At least one useful image zone (6c) of the sample is produced by combining image zones (6a, 6b), the combination evidencing differences between the image zones (6a, 6b) related to the modulation.

The present disclosure relates to an optical sensor comprising at least one light source for emitting transmission light into a medium, at least one detector, wherein the transmission light is at least partially converted in the medium by fluorescence into fluorescent light and the detector receives the fluorescent light, wherein a first receiver signal can be generated from the fluorescent light, and wherein a first measured value can be determined from the first receiver signal, wherein the transmission light is at least partially scattered by means of the medium to form scattered light, and the detector receives the scattered light, wherein a second receiver signal can be generated from the scattered light, and wherein a second measured value can be determined from the second receiver signal. The present disclosure further relates to a method for determining a first and second measured value of a medium.

The present invention provides an apparatus for detecting photoluminescent light emitted from a sample, said apparatus (200; 300) comprising at least one light source (210; 310, 318), which is configured to emit light of a first and a second wavelength towards a sample comprising photoluminescent particles, wherein said first wavelength is an excitation wavelength for inducing photoluminescent light from said photoluminescent particles, and wherein said second wavelength is longer than said first wavelength and for gathering background noise information from said sample. The apparatus further comprises a photo-detector (206) for detecting light incident on the photo-detector (206); and an interference filter (204; 304) arranged on the photo-detector (206), wherein the interference filter (204; 304) is configured to selectively collect and transmit light towards the photo-detector (206) based on an angle of incidence of the light towards the interference filter (204; 304), wherein the interference filter (204; 304) is configured to selectively transmit supercritical angle light from the sample towards the photo-detector (206) and suppress undercritical angle light from the sample.