A holographic interferometer, comprising: at least one imaging device capturing an interference pattern created by at least two light beams; and at least one aperture located in an optical path of at least one light beam of the at least two light beams; wherein the at least one aperture is located away from an axis of the at least one light beam, thus transmitting a subset of the at least one light beam collected at an angle range.

Proposed are an image reproduction device, an image reproduction method, and a digital holography device, by which the calculation load is reduced and a time required to reproduce an object image from hologram image data is shortened, compared with a conventional technology. An image reproduction device (17) can reproduce an object image or a phase image thereof from hologram image data without performing conventional two-dimensional Fourier transform or two-dimensional inverse Fourier transform. Since no two-dimensional Fourier transform or no two-dimensional inverse Fourier transform is performed, the calculation load can be accordingly reduced, and a time required to reproduce an object image from hologram image data can be accordingly shortened, compared with a conventional technology.

The disclosed invention describes a new apparatus performing a new data acquisition for quantitative refractive index tomography. It is based on a linear scanning of the specimen, opposed to the classical approaches based on rotations of either the sample or the illumination beam, which are based on the illumination with plane waves, which orientation is successively modified in order to acquire angular information. On the contrary, the inventive apparatus and method rely on a specially shaped illumination, which provides straightforwardly an angular distribution in the illumination of the specimen. The specimen can thus be linearly scanned in the object plane in order to acquire the data set enabling tomographic reconstruction, where the different positions directly possess the information on various angles for the incoming wave vectors.

A digital holography microscope, a method, and a system are provided. The digital holography microscope comprising two microscope objectives configured in a bi-telecentric configuration; a sample holder configured to receive a sample; a couple charged device configured to capture one or more images; a display; and a processor configured to retrieve a Convolutional Neural Network (CNN) model associated with a type of the sample, mitigate aberrations in the one or more images using at least the CNN model having as input an unwrapped phase associated with each of the one or more images, and output the mitigated one or more images via the display.

A system for performing quantitative phase-contrast confocal microscopy includes a light source that emits light, a first beam splitter that splits the emitted light into an illumination path and a hologram path, means provided along the illumination path for delivering a first part of the emitted light to an object as a collimated line, a light sensor that captures light reflected off of the object to obtain an intensity image for the collimated line, and means provided along the hologram path for delivering a second part of the emitted light to the light sensor at an off-axis angle to obtain an off-axis hologram for the collimated line.

Various systems for imaging are provided. An electronic device includes a biometric sensor and a processing system. The biometric sensor includes an illuminator, a mirror, a biometric sensor array and a beam splitter. The beam splitter splits a beam received from the illuminator into a first beam incident on a biometric sensing area and a second beam incident on the mirror. The beam splitter combines the reflected beams from the biometric sensing area and the mirror. Thereafter, the processing system receives data from the sensor array and reconstructs the biometric image.

A method for defect inspection of a transparent substrate comprises (a) providing an optical system for performing a diffraction process of object wave passing through a transparent substrate, (b) interfering and wavefront recording for the diffracted object wave and a reference wave to reconstruct the defect complex images (including amplitude and phase) of the transparent substrate, (c) characteristics analyzing, features classifying and sieving for the defect complex images of the transparent substrate, and (d) creating defect complex images database based-on the defect complex images for comparison and detection of the defect complex images of the transparent substrate.

An apparatus for, and method of, image reconstruction. The method includes first breaking a holographic image into a plurality of interlaced sample sets corresponding to color separation images; and independently sampling, filtering, and reconstructing all sets. The resulting demodulated images contain no fringes. Notably, range-clipped tonal rendering curves are used to choose pixel regions of the demodulated images that will replace saturated regions. The image is reconstructed by integrating all un-saturated images into one.

Both a hologram and fluorescence are simultaneously captured in a state in which they can be reconstructed separately. A recording device (10) includes: a laser light source (LS1) which irradiates a subject (13) with object illumination light so that object light is generated; and an image capturing device (12) which captures (i) a hologram formed by interference between reference light and object light and (ii) an image of fluorescence, and the object illumination light further excites a fluorescent material (14) contained in the subject (13).

Motility contrast imaging (MCI) is a depth-resolved holographic technique to extract cellular and subcellular motion inside tissue. The holographic basis of the measurement technique makes it highly susceptible to mechanical motion. The motility contrast application, in particular, preferably includes increased mechanical stability because the signal is based on time-varying changes caused by cellular motion, not to be confused with mechanical motion of the system. The use of the resulting spectrogram response signatures, or fingerprint data, of known compounds is disclosed to screen new compounds for leads as to those having potentially beneficial mechanisms of action. The fingerprint data of known toxic compounds can be used to screen new compounds for toxicity.