A laminated fluorescent sensor includes a sealable sensor housing and an optical sensing system embedded inside the sensor housing. The optical sensing system includes a light source (7), a short wave pass filter (8), an air chamber (10), a sensing unit, a long wave pass filter set (12) and an optical signal collecting unit from top to bottom all of which are coaxially set. The optical signal collecting unit is connected with a signal processing system (14); the sensor housing has air inlets (2, 201) and an air pumping port (3), the air inlets (2, 201) are communicated with the air chamber (10) through an air intake passage, the air chamber (10) is communicated with the air pumping port (3) through an air pumping passage. The laminated fluorescent sensor is compact and easy to be arrayed for simultaneously detecting two or more detected objects, has a high signal-to-noise ratio, is applicable in quick detection of micro-trace chemicals including but not limited to explosives and narcotics, provides great detection effects, has distinctly distinguishable signal responses to objects not being detected and to objects being detected, and provides stable and accurate detection.

This invention relates to a method of and system for facilitating detection of a particular predetermined gas in a scene under observation. The gas in the scene is typically associated with a gas leak in equipment. To this end, the system comprises an infrared camera arrangement; a strobing illuminator device having a strobing frequency matched to a frame rate of the camera; and a processing arrangement. The processing arrangement is configured to store a prior frame obtained via the infrared camera arrangement; and compare a current frame with the stored prior frame and generate an output signal in response to said comparison. The system also comprises a display device configured to display an output image based at least on the output signal generated by the processing arrangement so as to facilitate detection of the particular predetermined gas, in use.

A plurality of images of a sample are simultaneously captured at different focal lengths by a plurality of cameras. An analysis apparatus includes: a branch section configured to cause light passing through the sample containing a material component to branch off into a plurality of optical paths; a plurality of imaging devices for simultaneously capturing images of the sample in a flow path at different focal points by using the light caused to branch off into the plurality of optical paths; and a controller configured to process the captured images.

A plurality of images of a sample are simultaneously captured at different focal lengths by a plurality of cameras. An analysis apparatus includes: a branch section configured to cause light passing through the sample containing a material component to branch off into a plurality of optical paths; a plurality of imaging devices for simultaneously capturing images of the sample in a flow path at different focal points by using the light caused to branch off into the plurality of optical paths; and a controller configured to process the captured images.

To provide an inspection apparatus and an inspection method that are suitable for inspection of a surface state of an inspection target surface. An inspection apparatus according to the present technology includes an irradiation unit, a polarization separation unit, an imaging unit, and a processing unit. The irradiation unit irradiates an inspection target surface with light. The polarization separation unit separates light obtained from the inspection target surface irradiated with the light into a plurality of polarization components in different polarization directions. The imaging unit includes a plurality of pixels that receives the light of the plurality of different polarization components and outputs a pixel signal, the light being separated by the polarization separation unit. The processing unit performs filtering processing on a polarization phase difference image at a predetermined spatial frequency, the polarization phase difference image being generated using the pixel signal output from the imaging unit.

A semiconductor material emitting device is positioned such that its output flux impinges on a substrate at a non-perpendicular angle, so as to grow a first epilayer which is linearly graded in the direction perpendicular to the growth direction. The linear grading can be arranged such that, for example, each row of pixels has a different cutoff wavelength, thereby making it possible to provide a spectroscopic FPA without the use of filters. The non-perpendicular angle and/or the flux intensity can be adjusted to achieve a desired compositional grading. A spectral ellipsometer may be used to monitor the composition of the epilayer during the fabrication process, and to control the intensity of the flux.

An imaging system for imaging a sample in a medium carried in a container WP as an imaging object comprises: an imaging object includes an imager which obtains an original image by imaging the imaging object; and a data processor which generates multi-gradation image data by performing a gradation correction on the original image, wherein the data processor associates a luminance value corresponding to a luminance of the medium in the original image with a maximum gradation value in the gradation correction.

A model-based method for quantifying a specimen. The method includes providing a specimen, capturing images of the specimen while illuminated by multiple spectra at different nominal wavelengths, and exposures, and classifying the specimen into various class types comprising one or more of serum or plasma portion, settled blood portion, gel separator (if used), air, tube, label, or cap; and quantifying of the specimen. Quantifying includes determining one or more of: a location of a liquid-air interface, a location of a serum-blood interface, a location of a serum-gel interface, a location of a blood-gel interface, a volume and/or a depth of the serum or plasma portion, or a volume and/or a depth of the settled blood portion. Quality check modules and specimen testing apparatus adapted to carry out the method are described, as are other aspects.

The disclosure relates to the technique, including systems and methods, for use in optical topographical and/or tomographic 3D imaging of a sample. The system may include (a) a lens unit, chromatically dispersive so that its focal length varies depending on a light wavelength, the lens unit being configured to pass therethrough polychromatic light arriving from and originated at a sample, while selectively collimating those spectral components of the polychromatic light which are in focus based on their wavelengths and origins; and (b) an etalon structure accommodated in an optical path of light being output from the lens unit to receive the collimated light, said etalon structure being configured to operate with multiple resonant wavelengths and to provide respective spectral transmittance peaks at said resonant wavelengths.

A detecting device for a medium inside a tube portion comprises at least one light source being arranged at a first position relative to the tube portion adapted to be transilluminated with light and being configured to irradiate light onto the tube portion, a detector unit being arranged at a second position relative to the tube portion and being configured to receive light from the at least one light source passed through the tube portion and to analyze a medium inside the tube portion in a spatially resolving manner, and a homogenizing device being arranged at a position between the at least one light source and the tube portion and being configured, for detecting and quantifying differences in brightness due to local differences of the medium inside the tube portion, to create a homogenous and/or isotropic distribution of the light from the at least one light source before the light enters into the tube portion.