A system and method are described for rendering a characteristic for a set of particles passing through a measurement volume of a particle optical measurement system. The method includes acquiring raw particle data for the particles passing through the measurement volume. The raw particle data comprises a set of raw particle records. Each particle record comprises at least: a trajectory of at least one particle, and a second primary mark of the at least one particle whose value influences an effective sampling area corresponding to the measurement volume. The method includes generating and storing an effective sampling area based upon: the trajectory of the at least one particle, and the second primary mark. Thereafter, an ensemble characteristic is rendered for the set of particles by performing an operation on the sampling area-corrected set of particle records.

An apparatus for monitoring and controlling a haze and/or particulate level in the air is disclosed. The apparatus comprises a detecting unit (sensor) and a controller. The detecting unit is configured to detect the haze and/or particulate level in real time. The controller in communication with the detecting unit is configured to receive data related to a haze level from the detecting unit. The apparatus further comprises a display and a control switch. The display in communication with the controller is configured to display data related to the haze level monitored by one or more sensors. The sensors are laser based particulate sensors. The control switch in communication with the controller is configured to send a signal to control a haze generator, thereby monitoring the haze level in real time and controlling the haze generator at predetermined time periods using the control switch for attaining and maintaining a desired haze level.

A gas detection device manufactured by a semiconductor process includes a substrate, a microelectromechanical element, a light-emitting element, a particle-sensing element, a gas-sensing element, a driving-chip element and an encapsulation layer. The driving-chip element controls driving operations of the microelectromechanical element, the light-emitting element, the particle-sensing element and the gas-sensing element, respectively. When the microelectromechanical element is enabled to actuate transportation of gas, the gas is introduced into the gas detection device through an inlet aperture of the substrate. Scattered light spots generated by the light beam of the light-emitting element irradiating on suspended particles contained in the gas are received by the particle-sensing element to generate a detection datum of the suspended particles. The gas-sensing element detects the gas passing through and generates a detection datum of hazardous gas contained in the gas. Finally, the gas is discharged from an outlet aperture of the encapsulation layer.

In a bubble measurement device for measuring bubbles moving in a liquid, the bubble measurement device includes a measurement chamber in which the bubbles in the liquid containing solid materials are introduced into the measurement chamber from below the measurement chamber, and providing a transparent slope facing diagonally downward at a position where the introduced bubbles rise, an image capturing device to capture an image of the bubbles passing the transparent slope, an introduction pipe provided below the measurement chamber to introduce the bubbles into the measurement chamber, and a bubble introduction valve that is immersed in the liquid to be measured and performs the introduction and blocking of the bubbles into the introduction pipe.

The present invention relates to a hazardous material measuring apparatus capable of analyzing concentration and components of various hazardous materials. The hazardous material measuring apparatus analyzes an optical spectrum obtained by a spectrometer or a hyperspectral image obtained by a hyperspectral camera, thereby analyzing concentration and components of the hazardous materials to be measured.

An apparatus for detecting the approximate number of leukocytes in a dialysate after the use thereof in peritoneal dialysis and for the analysis thereof, where the apparatus includes a housing having a through-opening for inserting a light-permeable tube and having an integrated tube clamping device, at least one laser light source directed onto the tube, a light detector device having a signal evaluation device, a display, and a power supply for the light source, the light detector device having the light signal evaluation device, and the display. The laser light source and the light detector device are arranged at an angle to one another such that the light detector device only detects the scattered radiation reflected from scattering surfaces of solid particles and in that an LED light source is also arranged, which directs the light thereof onto the light detector device which measures the transmitted light intensity and, after detecting turbidity of the dialysate, increases the value of the detected scattered radiation accordingly.

One variation of a system includes a cartridge comprising: a substrate; a sample well integrated into the substrate, defining an upper opening and a lower opening, and configured to receive a test solution comprising a user sample and an amount of a fluorescent probe configured to bind with a target bioparticle to form a target complex; a filter membrane extending across the lower opening and defining a network of pores configured to convey fluid from the sample well and prevent passage of the target complex through the filter membrane. The system further includes a reader comprising: a housing; a cartridge receptacle configured to receive the cartridge; an excitation source configured to illuminate a detection region within the housing; and a detector defining a field of view intersecting the detection region and configured to detect a signal generated by fluid in the sample well and representing presence of the target bioparticle.

This fluid evaluation device is provided with an irradiation unit for irradiating a fluid with light, a light reception unit for receiving scattered light from the fluid and outputting a light reception signal, and an estimation unit for estimating at least one from among flow rate and density by mapping input points, which are on a first plane defined by flow rate and frequency and are expressed by light amount information indicating the amount of scattered light included in the light reception signal and frequency information indicating a frequency for a beat signal resulting from the Doppler shifting of the light included in the light reception signal, onto a second plane defined by fluid flow rate and fluid density.

An evaluation method is a method for evaluating a cell mass containing a plurality of aggregated cells, and includes an imaging step of capturing an image of light obtained from the cell mass by irradiating the cell mass with light, an analysis step of setting a reference point for the cell mass included in image data obtained by the imaging step, setting sampling circles centered on the reference point, and determining a parameter for a state of the cell mass based on image data included in regions on the sampling circles, and an evaluation step of evaluating the cell mass based on the parameter.

Device for detecting reactive luminescent particles embedded in a substrate or surface having an infrared or ultraviolet illuminator; a near-infrared photodiode sensor; a dark chamber, inside which the illuminator and photodiode sensor are mounted; a logarithm amplifier; an electronic data processor configured to detect the reactive luminescent particles by carrying out the steps of: illuminating the substrate or surface with the illuminator; acquiring the amplified linearized signal captured by the photodiode sensor; detecting the presence of luminescent particles in the substrate or surface from the linearized decay of the acquired signal. A further near-infrared photodiode sensor, a further logarithm amplifier, and a differentiator for obtaining a difference between amplified signals received by each photodiode sensor can be utilized.