The present disclosure relates to a reflective FPM using a parabolic mirror, and particularly to a reflective FPM using a parabolic mirror including: a first illuminator having a first panel that is provided with numerous LED light sources and composed of a first LED array irradiating a plurality of first LED beams to a measurement object sequentially at different angles through an objective lens; a second illuminator having a second panel that is provided with numerous LED light sources and composed of a second LED array irradiating a plurality of second LED beams to the measurement object sequentially at different angles, following irradiation from the first illuminator; a parabolic mirror reflecting each of second beams generated from the second illuminator, allowing being incident on the measurement object; a lens configured to collect a beam from the measurement object to which the first and second LED beams were irradiated; and a photodetector receiving light from the lens and acquires images for each of a plurality of first and second beams.

Microscopic analysis of a sample includes a system using dark-field illumination. A mid-IR optical source generates a mid-infrared beam, which is directed onto the sample to induce a temperature change by absorption of the mid-infrared beam. A visible light source generates a light illuminating the sample on a substrate and creating a scattered field and a reflected field along a collection path of the system. A pupil mask is positioned along the collection path to block the reflected field while allowing the scattered field to pass therethrough. A camera is positioned at an end of the collection path to collect the scattered field and generate a dark-field image of the sample.

A SPIM-microscope (Selective Plane Imaging Microscopy) and a method of operating the same having a y-direction illumination light source and a z-direction detection light camera. An x-scanner generates a sequential light sheet by scanning the illumination light beam in the x-direction. An electronic zoom is provided that is adapted to change the scanning length in the x-direction independently of a focal length of the illumination light beam and a size of the light sheet in the y-direction and in the z-direction, wherein the number of image pixels in x-direction is maintained unchanged by the electronic zoom independently of the scanning length in x-direction that has been selected.

A SPIM-microscope (Selective Plane Imaging Microscopy) and a method of operating the same having a y-direction illumination light source and a z-direction detection light camera. An x-scanner generates a sequential light sheet by scanning the illumination light beam in the x-direction. An electronic zoom is provided that is adapted to change the scanning length in the x-direction independently of a focal length of the illumination light beam and a size of the light sheet in the y-direction and in the z-direction, wherein the number of image pixels in x-direction is maintained unchanged by the electronic zoom independently of the scanning length in x-direction that has been selected.

The invention relates to a method in the preparation of samples for microscopic examination onto which a coverslip is applied. The method is notable for the fact that the coverslipping quality is checked automatically and at least partly optically. The invention further relates to an apparatus for carrying out the method, and to an apparatus for checking the coverslipping quality of samples onto which a coverslip is applied.

A mobile phone-based dark field microscope (MDFM) apparatus suitable for quantifying nanoparticle signals is provided. The MDFM apparatus includes an electrically operated light source, a dark-field condenser, a slide housing configured to receive an analytical slide, and an adapter housing configured to receive an objective lens and receive a portable electronic communication device. The slide housing positions the analytical slide between the objective lens and the dark-field condenser. The adapter housing registers the objective lens with a camera lens of the portable electronic communication device. A method for performing a biological quantitative study using the dark-field microscope apparatus is further provided.

A mobile phone-based dark field microscope (MDFM) apparatus suitable for quantifying nanoparticle signals is provided. The MDFM apparatus includes an electrically operated light source, a dark-field condenser, a slide housing configured to receive an analytical slide, and an adapter housing configured to receive an objective lens and receive a portable electronic communication device. The slide housing positions the analytical slide between the objective lens and the dark-field condenser. The adapter housing registers the objective lens with a camera lens of the portable electronic communication device. A method for performing a biological quantitative study using the dark-field microscope apparatus is further provided.

An optical system for a light-sheet microscope comprises transporting optics configured to project, into a sample, a light sheet for illuminating a sample plane positioned obliquely to an optical axis of the transporting optics and to project the illuminated sample plane into an intermediate image space. The transporting optics comprises an interchanging system that includes a first light-deflection element and a second light-deflection element. The interchanging system is configured to switch an illumination direction along which the light sheet illuminates the sample by alternately introducing the first light-deflection element and the second light-deflection element into a beam path of the transporting optics. The first light-deflection element causes a partial image inversion in only one direction. The second light-deflection element causes a complete image inversion in two directions.

An optical imaging system includes a light source, a light detector and an aperture plate. The light source includes a plurality of light emitting devices which emit light that is directed toward an object to be illuminated. The light detector is positioned to view the object illuminated by the light source. The aperture plate is positioned relative to the light source to block a first portion of the light emitted by the light source and to allow a second portion of the light emitted by the light source to pass therethrough to illuminate a pre-defined area of the object. The aperture plate includes a plurality of spaced apart apertures formed through the thickness thereof. Each aperture corresponds to a respective light emitting device. Each aperture of the aperture plate is defined by a first opening formed in the thickness of the aperture plate and a second opening formed in the thickness of the aperture plate. The second opening partially overlaps the first opening and is partially offset from the first opening. The first and second openings' planar shapes match the shape of the desired illumination area, with the first openings being smaller than the second openings. A method for illuminating a defined area of an object includes the steps of energizing one or more light emitting devices of a light source in an optical imaging system, which energized light emitting device or devices emit light that is directed toward the object to be illuminated. The light is passed through particularly-shaped apertures, such as described above, formed in an aperture plate positioned between the light source and the object to be illuminated. The apertures in the plate only allow light passing therethrough to impinge on the object at a pre-defined area thereof.

An optical imaging system includes a light source, a light detector and an aperture plate. The light source includes a plurality of light emitting devices which emit light that is directed toward an object to be illuminated. The light detector is positioned to view the object illuminated by the light source. The aperture plate is positioned relative to the light source to block a first portion of the light emitted by the light source and to allow a second portion of the light emitted by the light source to pass therethrough to illuminate a pre-defined area of the object. The aperture plate includes a plurality of spaced apart apertures formed through the thickness thereof. Each aperture corresponds to a respective light emitting device. Each aperture of the aperture plate is defined by a first opening formed in the thickness of the aperture plate and a second opening formed in the thickness of the aperture plate. The second opening partially overlaps the first opening and is partially offset from the first opening. The first and second openings' planar shapes match the shape of the desired illumination area, with the first openings being smaller than the second openings. A method for illuminating a defined area of an object includes the steps of energizing one or more light emitting devices of a light source in an optical imaging system, which energized light emitting device or devices emit light that is directed toward the object to be illuminated. The light is passed through particularly-shaped apertures, such as described above, formed in an aperture plate positioned between the light source and the object to be illuminated. The apertures in the plate only allow light passing therethrough to impinge on the object at a pre-defined area thereof.