An apparatus (1) for determining quality of a platelet concentrate (PC) (15) in a PC bag (10) comprises a movable bag holder (2) to carry the PC bag (10), a light system (20) with a light source (21, 24) to direct light (22) into the platelet concentrate (15) in the PC bag (10) for a measurement interval, and a detector system (30) with a light detector (31, 32) configured to detect light (23) from the platelet concentrate 15 during the measurement interval and generate a real-time detection signal. The apparatus (1) also comprises a controller (40) configured to determine platelet swirling based on the real-time detection signal and determine a quality parameter for the platelet concentrate (15) in the PC bag (10) based on the platelet swirling.

A light inspection method for a quantitative analysis on a filling level of a vapor producing section of an aerosol generating product is provided. The light inspection method includes: providing a light inspection device for holding an aerosol generating product and a surface light source for emitting a horizontal beam; and an angle between an axis of the aerosol generating product held by the light inspection device and a horizontal plane is 0-90°; the axis of the aerosol generating product held by the light inspection device is perpendicular to the horizontal beam emitted by surface light source. A light inspection device for a quantitative analysis on a filling level of a vapor producing section of an aerosol generating product is further provided. The light inspection device can accurately detect the filling level of a vapor producing section of an aerosol generating product.

A light inspection method for a quantitative analysis on a filling level of a vapor producing section of an aerosol generating product is provided. The light inspection method includes: providing a light inspection device for holding an aerosol generating product and a surface light source for emitting a horizontal beam; and an angle between an axis of the aerosol generating product held by the light inspection device and a horizontal plane is 0-90°; the axis of the aerosol generating product held by the light inspection device is perpendicular to the horizontal beam emitted by surface light source. A light inspection device for a quantitative analysis on a filling level of a vapor producing section of an aerosol generating product is further provided. The light inspection device can accurately detect the filling level of a vapor producing section of an aerosol generating product.

Methods, systems, and apparatus, including computer programs encoded on a computer storage medium, that generate from a first pair and a second pair of images of livestock that are within an enclosure and that are taken at different times using a stereoscopic camera, at least two distance distributions of the aquatic livestock within the enclosure. The distance distributions can be used to determine a measure associated with an optical property of the water within the enclosure. A signal associated with the measure can be provided.

A particle detection device includes a detection tube, a light emitter, a light receiver, and a processing unit. The detection tube is for a detection solution to pass through. The light emitter generates a detection light and emits the detection light to the detection solution. The light receiver receives the detection light scattered from the detection solution. The processing unit generates a received light intensity value according to the detection signal generated by the light receiver, and determines whether the received light intensity value is greater than a first threshold value: if greater, generating a detection result of particles; otherwise, generating a detection result of no particles. Then it provides a basis for semiconductor manufacturing companies to evaluate whether the detection solution can be used in a high-precision manufacturing processes, thereby optimizing the manufacturing process and improving the yield rate of the high-precision manufacturing process.

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.

In a sample observation device, an image acquisition unit 6 acquires a plurality of pieces of image data of a sample in a Y-axis direction, and an image generation unit generates luminance image data on luminance of the sample on the basis of the plurality of pieces of image data, binarizes luminance values of each of the plurality of pieces of image data to generate a plurality of pieces of binarized image data, and generates area image data on an existing area of the sample on the basis of the plurality of pieces of binarized image data.

A fire detection apparatus 1 includes a first light emitting unit 101 that irradiates a detection space located inside or outside the fire detection apparatus 1 with first detection light, a second light emitting unit 102 that irradiates the detection space with second detection light having a different wavelength from a wavelength of the first detection light, a light receiving unit 103 that receives scattered light of the first detection light irradiated from the first light emitting unit 101 due to smoke, outputs a first light receiving signal according to the received scattered light, receives scattered light of the second detection light irradiated from the second light emitting unit 102 with respect to smoke, and outputs a second light receiving signal according to the received scattered light, and an identification unit 107a that identifies a type of smoke present in the detection space on the basis of an output ratio of an output value of the first light receiving signal to an output value of the second light receiving signal output from the light receiving unit 103 and a rising rate of the output value of the first light receiving signal or the second light receiving signal.

A fire detection apparatus 1 includes a first light emitting unit 101 that irradiates a detection space located inside or outside the fire detection apparatus 1 with first detection light, a second light emitting unit 102 that irradiates the detection space with second detection light having a different wavelength from a wavelength of the first detection light, a light receiving unit 103 that receives scattered light of the first detection light irradiated from the first light emitting unit 101 due to smoke, outputs a first light receiving signal according to the received scattered light, receives scattered light of the second detection light irradiated from the second light emitting unit 102 with respect to smoke, and outputs a second light receiving signal according to the received scattered light, and an identification unit 107a that identifies a type of smoke present in the detection space on the basis of an output ratio of an output value of the first light receiving signal to an output value of the second light receiving signal output from the light receiving unit 103 and a rising rate of the output value of the first light receiving signal or the second light receiving signal.

A method for a wearable device to determine a biological parameter of a tissue of a person. To apply an emitting of a first and a second wavelength of light towards the tissue. To collect and sense a first and a second set of frequency bands from the signals received back from the first and the second wavelengths respectively. The first set of frequency bands represents a first signal which corresponds to a combination of the biological parameter and an extraneous noise. The second set of frequency bands represents a second signal mainly comprising the extraneous noise. To subtract the first set of frequency bands from the second set of frequency bands in the frequency domain to obtain a third set of frequency bands. The third set of frequency bands represents a third signal corresponding to the biological parameter.