This flow cytometer includes a flow path through which an observation object flows with a fluid; an optical illumination system including a spatial optical modulation device, and a first optical element; and an optical detection system including a first light detector, wherein the optical illumination system further includes a first spatial filter disposed in a first optical path between a light source and an image position of light imaged in the flow path by the first optical element and having a first region which hinders traveling of light emitted from the light source towards the observation object, the optical detection system further includes a second light detector disposed in a second optical path between the first light detector and the image position and having a second region which directs the light modulated by the observation object towards the first light detector, and the position of the first region and the position of the second region are in a substantially optically conjugate relationship.

A powder flow monitoring system may include a computing device configured to receive image data representing illuminated powder of a powder stream between a powder delivery device and a build surface of a component, generate a representation of the powder stream based on the image data, and output the representation of the powder stream for display at a display device.

An additive manufacturing system may include a powder delivery device configured to direct a powder stream toward a build surface of a component, and a powder flow monitoring system. The powder delivery device defines a longitudinal axis oriented toward the build surface. The powder flow monitoring system includes an illumination device configured to illuminate at least some powder the powder stream between the powder delivery device and the build surface; and an imaging device configured to image the illuminated powder at an image plane that intersects the longitudinal axis. The illumination device and the imaging device may be registered to the powder delivery device in a plane substantially orthogonal to the longitudinal axis.

An information processing apparatus that executes processing of obtaining, from an interference fringe image that is a two-dimensional distribution of intensity of interference fringes of object light and reference light, a phase difference image that is a two-dimensional distribution of a phase difference between the object light and the reference light, and obtaining a shape of an object to be observed based on the phase difference image includes at least one processor configured to acquire object-related information regarding the object to be observed, read out, from a storage unit in which the object-related information and a shape profile indicating the shape of the object to be observed are stored in association with each other, the shape profile corresponding to the acquired object-related information, and perform phase connection with respect to the phase difference image with reference to the read-out shape profile.

Embodiments of the invention are directed to an optoelectronic device for detection and identification of individual water droplets, ice crystals, dust particles and volcanic ash particles, the device comprising a source of ultraviolet collimated monochromatic radiation that illuminates an area of air external to the aircraft through which freely pass individual atmospheric particles to create an illuminated sample volume of air; an optical surveillance system for monitoring the clarity of light transmission through the light transmissive window to indicate a need for preventive maintenance; a first optical detection system that is constructed and arranged to collect light scattered from individual particles over an explicit angle ranging from 137° to 173° that defines the illuminated sample volume for measurement of S and P components of return scattered light from the sample volume to photodetectors that provide signals representative of intensity and change in polarization state caused by the interaction of particles with the incident illumination in the sample volume; a second optical detection system for selectively detecting fluorescence emanating from individual ash particles over an explicit angle ranging from 137° to 173° that defines the illuminated sample volume for measurement of fluoresence from the sample volume to a photodetector that provide a signal representative of intensity caused by the interaction of particles with the incident illumination in the sample volume; a signal processor that is constructed and arranged to condition the signals from the photodetectors by removing electronic noise, restoring baseline shifts and analyzing the pulse shapes to provide processed signals; a signal analyzer configured to operate upon the processed signals for extraction of data representing maximum amplitude, width, rise time and fall time of individual pulses in the S and P components, and the magnitude of the fluorescence signal which correlates to the size and/or composition of ash particles present; an information synthesizer that receives the data and produces analytical results allocated to particles by particle type including equivalent optical diameter (EOD), number and mass size distributions, and number and mass concentrations, the particle type being selected as at least one member among the group consisting of individual water droplets, ice crystals, dust particles and volcanic ash particles; and a report generator that creates an information packet utilizing information from the information synthesizer to assist in decision making related to hazard avoidance for aircraft flight, the optoelectronic system being adapted for mounting

A particle separating device includes at least three liquid chambers adapted to store a liquid therein; at least two liquid passages, each connecting adjacent two of the liquid chambers; an inlet adapted to introduce a liquid in which multiple particles of different sizes are dispersed into one of the liquid chambers; and at least two electrodes disposed inside at least two of the liquid chambers, respectively, the electrodes adapted to apply different electrical potentials to the liquid. The cross-sectional areas of the at least two liquid passages are different from each other.

An optical method of characterizing an object comprises providing an object to be characterized, the object having at least one nanoscale feature; illuminating the object with coherent plane wave optical radiation having a wavelength larger than the nanoscale feature; capturing a diffraction intensity pattern of the radiation which is scattered by the object; supplying the diffraction intensity pattern to a neural network trained with a training set of diffraction intensity patterns corresponding to other objects with a same nanoscale feature as the object to be characterized, the neural network configured to recover information about the object from the diffraction intensity pattern; and making a characterization of the object based on the recovered information.

A bio-substance analysis method using a sensing substrate having a fluid channel is disclosed. The method includes mixing retroreflective particles with a detection solution containing a target bio-substance, wherein a first bio-recognition substance selectively reacting with the target bio-substance is modified on the retroreflective particles; placing the sensing substrate so that a bottom is located under a cover in a direction of gravity; injecting the detection solution containing therein the retroreflective particles into a fluid channel and maintaining the solution in the channel for a first time duration; turning the sensing substrate upside down so that the bottom is located above the cover in the direction of gravity and maintaining the sensing substrate in the turned state for a second time duration; irradiating light into the fluid channel through the bottom; and generating and analyzing an image based on light retroreflected from the retroreflective particles.

A particle analysis device includes a liquid space adapted to store a liquid; a chip disposed above the liquid space, the chip having a connection pore extending vertically and communicating with the liquid space; an upper hole disposed above the chip, the upper hole extending vertically and communicating with the connection pore; a first electrode adapted to apply an electric potential to a liquid in the upper hole; and a second electrode adapted to apply an electric potential to the liquid in the liquid space. The upper hole having a diameter that is equal to or greater than the maximum width of the connection pore, and the entirety of the connection pore falling within the range of the upper hole.

To improve a determination accuracy when determining each particle contained in an image of an object. An image analysis apparatus according to an embodiment of the present invention includes: a shape determination unit configured to determine a shape of a particle included in a particle image that is extracted from an image of an object, so that an OK particle image which is a particle image of an OK particle that satisfies a predetermined standard for shape and a provisional NG particle image which is a particle image of a provisional NG particle that does not satisfy the predetermined standard, are obtained; a pseudo image generation unit configured to generate a pseudo image; and a similarity determination unit configured to determine whether the provisional NG image and the pseudo image are similar.