An erosion detector for an exterior aircraft lighting device is configured for detecting the state of erosion of an at least partially transparent cover of an exterior aircraft lighting device and includes: at least one light source, which is configured for radiating light onto the at least partially transparent cover; at least one light detection element, which is configured for detecting light reflected by the at least partially transparent cover and for providing a corresponding detection signal; and an evaluation unit, which is configured for evaluating the detection signal for determining the state of erosion of the at least partially transparent cover.

A computer-implemented device and method for identifying hardware Trojans and defects based on light emissions from Integrated Circuits (ICs) is provided. A measured emissions map is received based on light emissions captured from a sacrificial test IC. The sacrificial test IC is a partially manufactured IC fabricated to include a set of frontend layers of an IC architecture but not a set of backend layers of the IC architecture. The sacrificial test IC also includes a sacrificial layer for powering devices in the partially manufactured IC without the set of backend layers. An expected emissions map is derived from the sacrificial test IC and the measured emissions map is compared with the expected emissions map to identify deviations from the IC architecture in the frontend layers.

In order to inspect a substrate, an image information of a substrate before applying solder is displayed. Then, at least one inspection region on the substrate is image-captured to obtain an image of the inspection region that is image-captured. Then, image information that is to be displayed is renewed and the renewed image information is displayed. And, in order to inspect a foreign substance, obtained image of the inspection region is compared with a reference image of the substrate. Therefore, an operator can easily catch a region corresponding to a specific region of the image that is displayed, and easily detect a foreign substance on the substrate.

In one exemplary embodiment, a method for calibrating an instrument is provided. The instrument includes an optical system capable of imaging fluorescence emission from a plurality of reaction sites. The method includes performing a region-of-interest (ROI) calibration to determine reaction site positions in an image. The method further includes performing a pure dye calibration to determine the contribution of a fluorescent dye used in each reaction site by comparing a raw spectrum of the fluorescent dye to a pure spectrum calibration data of the fluorescent dye. The method further includes performing an instrument normalization calibration to determine a filter normalization factor. The method includes performing an RNase P validation to validate the instrument is capable of distinguishing between two different quantities of sample.

A method of preparing a reference material for fluorescence spectroscopy by impregnating or otherwise placing one or more fluorophores into a solid polymethyl methacrylate (PMMA) matrix. The method can include impregnating or otherwise placing the one or more fluorophores into the solid PMMA matrix by melt mixing a powder of each of the one or more fluorophores with the solid PMMA matrix to provide a mixed product comprising a homogeneous distribution of the one or more fluorophores in the PMMA and injection molding the mixed product to provide the reference material having a final shape; and/or polymerizing MMA in the presence of one or more fluorophores to form the solid PMMA matrix.

Compositions and methods for increasing fluorescent signals generated by biomarkers are described. This serves to increase the accuracy of results when the biomarkers are used for the detection and diagnosis of physiological conditions, such as organ function and plasma volume.

Provided herein are techniques for improved optical absorption measurements in the presence of time-varying etalons. In one aspect, a method for dynamic etalon fitting for adaptive background noise reduction in an optical sensor is provided. The method includes the steps of: obtaining a zero-gas spectrum measured using the optical sensor; obtaining an analyte gas spectrum of a target trace gas measured using the optical sensor; comparing the zero-gas spectrum and the analyte gas spectrum using fit parameters that compensate for drifting etalons in the optical sensor; and dynamically extracting the drifting etalons from the analyte gas spectrum to retrieve concentration of the target trace gas.

The present invention provides an adulterated peanut oil detector and an adulterated peanut oil detection method, and pertains to the technical domain of product analysis. The detector comprises a casing, a LCD and Return key, Enter key, Up key, Down key, a power switch, a power socket, and a USB interface arranged on the casing, and a microprocessor and a power supply unit mounted in the casing and electrically connected to the components on the casing, wherein, a module cover is arranged on the top surface of the casing, and a pretreatment module and a detection module are mounted in the space under the module cover. The pretreatment module comprises a heating body and cuvette slots, and the detection module comprises an axial fan, a radiating plate, a refrigerating plate, and cuvette slots. The detection method comprises sample preheating procedure and slow refrigeration procedure. The detector and method provided in the present invention can quickly and easily detect whether the peanut oil sample is adulterated and the percentage of adulteration, and is applicable to quick on-spot detection of rapeseed oil, sunflower oil, maize oil, cotton oil, palm oil, and soybean oil, etc. admixed in peanut oil.

In order to inspect a substrate, an image information of a substrate before applying solder is displayed. Then, at least one inspection region on the substrate is image-captured to obtain an image of the inspection region that is image-captured. Then, image information that is to be displayed is renewed and the renewed image information is displayed. And, in order to inspect a foreign substance, obtained image of the inspection region is compared with a reference image of the substrate. Therefore, an operator can easily catch a region corresponding to a specific region of the image that is displayed, and easily detect a foreign substance on the substrate.

A substrate processing apparatus includes a substrate retaining mechanism; a detecting unit detecting a placed state of the substrate retained by the substrate retaining mechanism; a first determination unit comparing detection data of the substrate obtained by the detecting unit with master data that is a reference to determine if the detection data is within a first allowed value; a confirmation unit confirming substrate type; a second determination unit comparing the detection data of the substrate with the master data to determine if the detection data is within a second allowed value; and a transfer control unit controlling the substrate retaining mechanism depending on a determination result of the second determination unit when substrate type is confirmed as a predetermined type by the confirmation unit when it is determined that the detection data is not within the first allowed value as determined by the first determination unit.