Disclosed herein are a particle sorting device capable of simply detecting bubbles, foreign substances, or the like in droplets, a method for analyzing particles, a program, and a particle sorting system. The particle sorting device includes a judgment unit, and the judgment unit judges whether or not captured image information including captured droplet image information about a brightness of an image of particle-containing droplets captured after discharge from an orifice has changed with respect to previously-set reference image information including reference droplet image information about a brightness of an image of droplets captured after discharge from the orifice.

A foreign substance detection device includes a flow path unit through which a fluid is flown; an optical system configured to flatten a laser light from a laser source to be lengthened in a direction intersecting with a flow direction of the fluid; a laser light irradiation unit provided such that an optical path intersects with the flow direction and configured to irradiate the laser light into the flow path unit; a light detection unit which is provided on the optical path having passed through the flow path unit and includes light receiving elements arranged in a lengthwise direction of a transversal cross section of the optical path; a foreign substance detection unit configured to compare a signal level corresponding to intensity of light received by each light receiving element with a threshold value and configured to detect the foreign substance based on a comparison result.

A sensor system for inspecting oil, which comprises a micromechanical cell defining a cavity for allowing the entrance/outcome of oil within/from said cavity through respective inlet and outlet. Inside said micromechanical cell there are: first and second transparent protective means; a light source configured to emit incoherent light towards said oil; an opaque plate disposed between said light source and said first transparent protective means, having a pin-hole configured to permit the passage of illumination towards said oil, said pin-hole being located at a first distance from a focussing plane defined by said oil in cavity; an image sensor to capture images of the oil disposed within said cavity located at a second distance from said focussing plane defined by said oil in cavity.

A particle measurement system and method of operation thereof are described. The system and method render a characteristic for a set of particles measured while passing through a measurement volume. The system includes a source that generates a particle-laden field containing the set of particles. The system further includes a sensor that generates a raw particle data corresponding to the set particles passing through the measurement volume of the particle measurement system, where the raw particle data comprises a set of raw particle records and each of one of the raw particle records includes a particle data content. A preconditioning stage carries out a preconditioning operation on the particle data content of the set of raw particle records to render a conditioned input data. A machine learning stage processes the conditioned input data to render an output characteristic parameter value for the set of particles.

The present disclosure provides apparatuses, systems, and methods for performing particle analysis through flow cytometry at comparatively high event rates and for gathering high resolution images of particles.

The present disclosure provides apparatuses, systems, and methods for performing particle analysis through flow cytometry at comparatively high event rates and for gathering high resolution images of particles.

The present disclosure provides apparatuses, systems, and methods for performing particle analysis through flow cytometry at comparatively high event rates and for gathering high resolution images of particles.

To enable the particle size distribution of a measurement target to be accurately measured regardless of the presence of a particle which is similar in shape to the measurement target and which is not the measurement target, a particle size distribution measuring device includes an image processing unit that receives image data obtained by capturing an image of a particle group including a first particle and a second particle of a type different from the first particle, at least the first particle being translucent; and a particle discriminating unit that discriminates whether a particle depicted in the image is the first particle or the second particle on the basis of light and dark regions that appear as a result of refraction of light passing through the particle.

An air bubble measurement device is a device that measures the air bubbles moving in the liquid. The air bubble measurement device includes a measurement chamber that holds a liquid. The measurement chamber includes an introduction port to introduce the air bubbles in the liquid from a lower side and a transparent inclined surface that faces obliquely downward and is disposed at a position to which the air bubbles present inside the liquid move up. The transparent inclined surface includes a hydrophilic membrane. The hydrophilic membrane has a contact angle with water of 20 degrees or less. This structural arrangement allows for reducing an attachment of the air bubbles on the transparent inclined surface even when the air bubbles become small. This allows for reducing stay of the air bubbles on the transparent inclined surface and allows for accurately measuring the states of the air bubbles (that is, the size and quantity of the air bubbles).

The systems and methods provided herein relate generally to the improvement of data quality in optical liquid particle counters and control of optical particle counters to achieve longer expected lifetime, for example by avoiding damage caused by electromagnetic radiation and heat. The systems and methods incorporate sensors which characterize the fluid flowing through the flow cell, thereby enhancing accuracy and reducing the number of false positives.