A multichannel tunable lens system may include a review channel with a fluidic focusing device, which can adjust the focus of the channel rapidly to mitigate environmental vibrations. The review channel may generate high resolution images with reduced blur caused by vibrations or air turbulence while increasing the operating speed of the system. The review channel may include a telescope objective and eyepiece with telecentricity to generate a real image of the pupil in the fluidic focusing device. The system may also include an inspection channel to generate lower resolution images in parallel and a focus channel to determine contour information.

A method for viewing a microscopy specimen is described. The method includes receiving a request to change a field of view of an optical microscope system that images the microscopy specimen. In response to the request, a current field of view is automatically changed to a new field of view. Parameters of the optical microscope system are automatically adjusted to align an illumination plane of a light sheet of the optical microscope system and a detection plane of the optical microscope system. The adjustment of parameters to align the illumination plane with the detection plane is based at least on precalibrated parameters that correspond to the new field of view, the illumination path objective, and the detection path objective.

A method may include measuring a formation sample using a Raman spectrometer to determine a formation sample characteristic, wherein the formation sample characteristic is mineral ID and distribution, carbon ID and distribution, thermal maturity, rock texture, fossil characterization, or combinations thereof.

A microscope comprises a microscope objective, a camera and an imaging optical system for imaging an object through the objective to the camera along a first optical path. A projection optical system is provided for projecting a test image onto the object through the objective, and the imaging optical system is configured to image the projected test image from the object to the camera through the objective and along at least part of the first optical path. A focus adjustment system is provided for focusing the test image at the camera. Using the same objective and the same camera for both imaging and focusing allows reduction of the cost of the microscope in comparison with known microscopes that provide separate focusing systems.

An imaging device includes an alignment platform configured to hold a cell culture plate having a plurality of wells and an imaging assembly including a plurality of imaging units, each of which is configured to image one well of the plurality of wells.

An imaging system includes an imaging device having a holder configured to hold a cell culture plate with a plurality of wells. The imaging device also includes an imaging assembly having a plurality of imaging units, each of which is configured to image one well of the plurality of wells. The imaging system also includes a storage platform in communication with the imaging device configured to receive a plurality of images from the imaging device. The system further includes a computer in communication with the imaging device and the storage platform. The computer is configured to control the imaging device and to display at least one image of the plurality of images.

A telepathology system is associated with an edge network shared among participating users for remote control of a microscope. The microscope includes a camera operable to receive image data of a specimen. The telepathology system is capable of receiving image data from the microscope, pre-processing the image data at network edge, sending the pre-processed image digitally to the participating users via a web server on the edge network, and controlling the image data, via instructions from the participating users.

An observation system includes an observation apparatus including a housing having an arrangement surface for placement of a sample, the sample including a culture medium, and an external illumination unit which is disposed outside the housing and includes at least one light source configured to emit illumination light. At least a part of the arrangement surface is formed of a transparent member having an optically transparent property. The observation apparatus includes an imaging unit which is provided in the housing and includes an image sensor configured to image, via the transparent member, the sample illuminated by the illumination light from the external illumination unit to acquire images of at least three colors.

The present disclosure relates to method, computer programs with instructions, and apparatus for determining positions of two or more spaced-apart molecules in one or more spatial directions in a sample by means of a localization microscope. The present disclosure also relates to localization microscopes using such an apparatus. Light distributions arising due to interference of coherent light are used for determining the positions of the molecules. In the method, a plurality of light distributions are generated (S1) using a first light modulator having a plurality of switchable pixels. The first light modulator is arranged in an image plane of the localization microscope. Each light distribution has a local intensity minimum and regions with an intensity increase adjacent thereto. Each of the two or more molecules is illuminated (S2) with one light distribution. For each of the light distributions, photons emitted by the molecules are detected (S4) for different positionings of the light distribution. The light distributions are positioned (S3) independently of each other. Based on the photons detected for the different positionings of the light distributions, the positions of the molecules are finally derived (S5).

The present disclosure discloses a method and a system for imaging. The method for imaging objects using the system for imaging. The system for imaging comprises a lens. The objects comprise a first object, a second object and a third object located at different positions on a first preset track. The method for imaging comprises: allowing the lens and the first preset track to move relatively in a first predetermined relationship to acquire a clear image of the third object using the system for imaging without focusing, the first predetermined relationship is determined by a focal plane position of the first object and a focal plane position of the second object. The aforementioned method for imaging is high in imaging efficiency and is capable of fast focusing according to the first predetermined relationship even if focus tracking fails so that the blurring of a photographed image due to defocusing is avoided.