In order to enable concentrations of components to be measured to be accurately calculated even when higher boiling compounds are contained in a test gas, a gas analysis device that analyzes components to be measured that are contained in a test gas using a light spectrum obtained by irradiating light onto the test gas is provided with a calibration curve data storage section in which is stored first calibration curve data in which effects on concentrations of the components to be measured from higher boiling compounds whose boiling point is higher than a heating temperature of an analyzer into which the test gas has been introduced have been corrected, and with a concentration calculation section that calculates concentrations of components to be measured using the first calibration curve data.

A chemical and/or biochemical apparatus (10) for receiving a plurality of reaction vessels in which chemical and/or biochemical reactions may take place includes a thermal mount (14) having a plurality of wells (26) for receiving the reaction vessels (12), a thermal module (16) having a first side thermally coupled to the thermal mount (14), a first heat sink (18) thermally coupled to a second side of the thermal module, the heat sink (18) having a body and a plurality of thermally conductive fins (32) extending outwards from the body of the first heat sink (18), and a printed circuit board (54) having electronic components for controlling at least the thermal module (16), an excitation light source (62), and a light sensor (52). A first set of light waveguides (60) is provided for delivering excitation light to a reaction vessel, and a second set of light waveguides (38) is provided for receiving light from a reaction vessel and for delivering the light to the light sensor (52). The first heat sink (18) comprises an interior space (5) and the printed circuit board (54), the excitation light source (62), the light sensor (52) and the light waveguides (38, 60) are arranged within the interior space (5).

Systems and methods of the present disclosure are directed to detecting species within a fluid using a multi-pass absorption cell and a spectrometer. The absorption cell includes a plurality of mirrors arranged in a manner such that a detection light traverses multiple passes through the fluid within the absorption cell. In some implementations, the detection light is reflected by the plurality of mirrors to form optical paths in more than one plane. The system also includes an electronic unit configured to receive and process spectral data from the spectrometer. In some implementations, the electronic unit communicates with at least one computational unit over a communication interface to send a portion of the spectral data for processing. The electronic unit may also receive processed data from the computational unit.

Systems and methods of the present disclosure are directed to detecting species within a fluid using a multi-pass absorption cell and a spectrometer. The absorption cell includes a plurality of mirrors arranged in a manner such that a detection light traverses multiple passes through the fluid within the absorption cell. In some implementations, the detection light is reflected by the plurality of mirrors to form optical paths in more than one plane. The system also includes an electronic unit configured to receive and process spectral data from the spectrometer. In some implementations, the electronic unit communicates with at least one computational unit over a communication interface to send a portion of the spectral data for processing. The electronic unit may also receive processed data from the computational unit.

A method for correcting a wavelength and a tuning range of a laser spectrometer in which the light from a wavelength-tunable laser diode, after being radiating through a gas, is detected and evaluated, wherein the laser diode is periodically driven with a current ramp, such that a time-resolved absorption spectrum of the gas is obtained upon the detection of the light, where in order to correct the wavelength and the tuning range of the laser spectrometer, a first step involves readjusting the central wavelength of the laser diode via the temperature thereof and based on the position of one of two different selected absorption lines in the detected absorption spectrum, and a second step involves correcting the tuning range of the laser diode via the gradient of the current ramp such that the spacing of the two absorption lines in the detected absorption spectrum remains constant.

A gas analyzer for measuring two gas components of a measuring gas includes two light-emitting diodes, a beam splitter, a measuring chamber through which the measuring gas circulates, a measurement detector, a reference detector, and a control and evaluation device for controlling the light-emitting diodes in an alternating manner and for evaluating the signals supplied by the measurement detector and the reference detector in terms of measuring results for the two gas components, wherein the beam splitter is arranged in a rectangular metal block, where the measuring chamber is formed as a long hollow body consisting of metal and open on both sides, the measurement detector is held on a detector block consisting of metal, and where the rectangular metal block and the detector block are interconnected via tension rods between which the measuring chamber is clamped.

A cell detector and detecting method enhance detection sensitivity for microbes according to the ATP method and reduce the detection period. The cell detector includes a sealing container having a culture portion for containing a culture medium containing the specimen, a sealable specimen introducing portion, and a luminescent reagent portion that emits light upon contact with the culture medium, a contact mechanism for controlling the contact between the culture medium and the luminescent reagent portion, a photodetector for detecting a luminescence resulting from the contact between the culture medium and the luminescent reagent portion, and a calculation unit for calculating a luminescent quantity from detection signals of the photodetector to determine cell proliferation on the basis of change in the luminescent quantity over time. The culture portion and the luminescent reagent portion are separately positioned, and the contact mechanism intermittently brings the culture medium and the luminescent reagent into contact.

Apparatuses, systems, method, reagents, and kits for conducting assays as well as process for their preparation are described. The apparatuses, systems, method, reagents, and kits may be employed in conducting automated analysis in a multi-well plate assay format.

A method of analysing an at least partially transparent object, such as a gemstone, includes fixing the object in a holder; immersing the object in the holder in an immersion material; and analysing internal and/or external features of the object. Analysing comprises visualizing an internal and/or external portion of the object using light rays while the object is immersed in the immersion material, and determining characteristics of the object based on the visualized internal and/or external portion of the object. During the analysing step, the difference between the refractive index (RI) of the immersion material and the RI of at least an immersed portion of the holder, which is in contact with the object, is less than 0.3.

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.