The present invention is related to the field of bio/chemical sensing, assays and applications. Particularly, the present invention is related to collecting a small amount of a vapor condensate sample (e.g. the exhaled breath condensate (EBC) from a subject of a volume as small as 10 fL (femto-Liter) in a single drop), preventing or significantly reducing an evaporation of the collected vapor condensate sample, analyzing the sample, analyzing the sample by mobile-phone, and performing such collection and analysis by a person without any professionals.

A trace evidence material (TEM) collection device is disclosed that enables crime scene investigators to quickly and easily collect, analyze, annotate, securely store and electronically distribute images of large amounts of trace evidence materials and related crime scene information while also helping to comply with required trace evidence recovery procedures and documentation requirements. The TEM collection device includes a reusable handle and cassette drive mechanism, which may be used with a plurality of single-use cassettes. Each cassette includes a TEM collection media (such as a collection tape or swabbing pads attached to a substrate) that when moved across a surface is capable of collecting TEMs located on the surface. Preferably, each cassette also includes a sealing assembly that seals the TEM collection media after collection of the TEMs so as to preserve the collected TEMs.

One embodiment of the present invention can provide a method of analyzing a measured spectrum image including the steps of obtaining a measured spectrum image; creating an analysis model by learning the spectrum image with artificial intelligence; and predicting the feature of a test sample of an analyte by inputting the spectrum image of the test sample to the analysis model.

The invention refers to a system for assessing the visual appearance of a reflective surface. The system comprises a visual capturing device, adapted to capture at least one image focusing the reflective surface and at least one complementary image focusing a reflection of a test image reflected from the reflective surface. The system further comprises a data processing unit, capable of assessing visual appearance of the reflective surface by deriving objective quality parameters from the one image and the complementary image and by comparing the objective quality parameters with data of a database. The invention further refers to a method of assessing the visual appearance of a reflective surface using the system.

The present inventive concept relates to a method (100) for identifying a set of candidate substances of a sample (10) using a Raman spectroscopy device (200). The method (100) comprises recording (120) a Raman spectrum using an exposure time, and recording (162) a further Raman spectrum using a further exposure time. The further Raman spectrum may exhibit Raman peaks not recorded/detected in the Raman spectrum which possibly reduces the set of candidate substances. If necessary, one or more additional Raman spectra are recorded to further reduce the set of candidate substances, such that a single candidate substance eventually remains, thereby deemed to be a substance of the sample (10). A Raman spectroscopy device (200), a computer program and a non-transitory computer-readable storage medium are also provided

In some implementations, a method for authenticating and classifying a set of materials comprises: determining a set of characteristics of light spectra reflected or transmitted by a set of materials when the set of materials is illuminated by a plurality of light wavelengths; constructing one or more classifiers configured to classify each material of the set of materials based on the set of characteristics of the light spectra; using the classifiers, mapping each of the light spectra onto an area of an image sensor; based on the mapping, generating a holographic optical element that has a plurality of regions, that receives input light reflected or transmitted through a new material, and that filters the input light to a filtered light by each characteristic light spectra, and mapping the filtered light onto the area of the image sensor.

A device for optically identifying surfaces, in particular for optically identifying structured and/or pictorial surfaces, spaces and/or e.g. paintings or sculptures is simple to use independently of the location. For this purpose, the device includes a housing in which light-emitting and light-receiving elements are arranged, and the device also includes a first portion having at least one lens, a portion that follows the first portion in the longitudinal direction and has a screen, and an adjoining handle portion.

Systems and methods for powder bed additive manufacturing can include sensing a powder bed with an eddy current (EC) sensor to obtain an EC sensor measurement, sensing the powder bed with a secondary sensor to obtain a topographical measurement, and determining a property in the powder bed based on the EC sensor measurement and the topographical measurement.

Apparatus and methods may provide for determining a value of chemical parameter. One or more light emitters may be positioned within a housing to emit light through an aperture of the housing. The emitted light may illuminate a color area of a structure that is separable from the housing, such as a test strip, a printed color reference, and so on. A color sensor may be positioned within the housing to capture reflected light and to convert the reflected light to an initial digitized color space that may be usable to determine a color shade of a color area. The reflected light may, for example, be captured independently at least of a dimension (e.g., predetermined size, shape, etc.) of the color area.

Disclosed is an imaging system which includes an imaging device to be used by multiple users, allows each user to perform imaging at an appropriate timing, and is capable of efficiently using the imaging device. An imaging system includes an imaging device, a plurality of terminal devices, and an authorization unit which gives the terminal devices the authority to specify controllable functions of the imaging device. The authorization unit switches between a first state where the terminal devices are given a first authority to exclusively occupy a part of functions of the imaging device with a controllable state and a second state where one terminal device is given a second authority to exclusively occupy and control the part of functions and to release the occupation, and the terminal devices other than one terminal device are given a third authority with the restriction of the control of the part of functions.