In one example, an additive manufacturing process includes: making an object slice by slice, including dispensing a first quantity of each of multiple liquid functional agents on to a layer of fusable build material and then irradiating the layer of build material; while making the object, identifying a deviant region in a slice; and dispensing a second quantity different from the first quantity of at least one of the functional agents into a location corresponding to the deviant region.

In one example, an additive manufacturing process includes: making an object slice by slice, including dispensing a first quantity of each of multiple liquid functional agents on to a layer of fusable build material and then irradiating the layer of build material; while making the object, identifying a deviant region in a slice; and dispensing a second quantity different from the first quantity of at least one of the functional agents into a location corresponding to the deviant region.

Disclosed are a one-pot biosensor and an immunoassay method using the same. The one-pot biosensor includes a photocatalyst substrate deposited with metal nanoparticles; and a reaction pad which is disposed on an upper surface of the photocatalyst substrate and includes a first binding material-fluorescent material complex specifically binding to a molecule to be detected, and the immunoassay method using the same. The one-pot biosensor may detect a target by once solution injection and has a size enough to be portable. Accordingly, since the one-pot biosensor can detect the target by only once solution injection without a washing step, because of a sensor platform capable of being easily used by an individual other than a diagnostic expert, it is predicted to be positioned as a means capable of confirming the health condition of the individual without seeing the doctor, such as a pregnancy diagnostic kit which has been currently commercialized.

A nephelometric turbidimeter for measuring a turbidity of a liquid sample in a sample cuvette. The nephelometric turbidimeter includes a measurement light source configured to emit an axial parallel light beam directed to the sample cuvette, a scattering light detector arranged to receive a scattered light from the sample cuvette, and a diffuser comprising a diffuser body and a diffuser actuator. The diffuser actuator is configured to move the diffuser body between a parking position in which the diffuser body does not interfere with the axial parallel light beam and a test position where the diffuser body is arranged between the measurement light source and the sample cuvette so that the diffuser body interferes with the axial parallel light beam and generates a diffuse test light entering the sample cuvette.

A computer-implemented method and corresponding system for determining the concentration of one or more scale inhibiting polymers in a fluid received from one or more porous and permeable hydrocarbon-bearing rock formations is provided. Each polymer comprises a different chemical marker and the fluid comprises a plurality of commingled said scale inhibiting polymers. The method comprises receiving first input data representing a measured absorption spectrum, within a predetermined wavelength range, of the commingled scale inhibiting polymers, wherein the measured absorption spectrum is measured using a detector after chromatographic separation of the fluid; receiving second input data representing reference absorption spectra, the reference absorption spectra comprising: a) an absorption spectrum, over the predetermined wavelength range, of each of the scale inhibiting polymers; and b) baseline reference absorption spectra of other chemicals having absorbance values within the predetermined wavelength range that are expected to be present in the fluid; inputting the first and second input data into a computer program; and operating the computer program. The computer program is operated to, at each of a plurality of discrete time steps over an elution time from the separation, determine a factor for each reference absorption spectrum that results in a modelled spectrum comprising a best-fit linear combination of the second input data to the first input data. For each scale inhibiting polymer, the computer program also operates to use the factors corresponding to the absorption spectrum of said scale inhibiting polymer that have been determined for a predetermined number of said discrete time steps to determine an indication of the concentration of the scale inhibiting polymer.

An exterior aircraft lighting device comprises: at least one light source; an optical element having a light entry side facing the at least one light source and a light exit side and being configured for modifying light emitted by the at least one light source; at least one photo detector, which is configured and arranged for detecting a portion of the light emitted by the at least one light source, which is reflected by the light entry side of the at least one optical element, the photo detector providing a detection value, representing the amount of detected light; and a control and evaluation unit which is configured for evaluating the state of wear of the at least one light source based on the detection value provided by the at least one photo detector.

Inspection scopes suitable for use in connection with mobile electronic devices are disclosed. The inspection scope may utilize an optical connection to the mobile electronic device and/or an electrical connection to the mobile electronic device. Software operative on the mobile electronic device is configured for control of inspection scope components and for acquisition of video and/or image data.

Inspection scopes suitable for use in connection with mobile electronic devices are disclosed. The inspection scope may utilize an optical connection to the mobile electronic device and/or an electrical connection to the mobile electronic device. Software operative on the mobile electronic device is configured for control of inspection scope components and for acquisition of video and/or image data.

An optical metrology device is capable of detection of any combination of photoluminescence light, specular reflection of broadband light, and scattered light from a line across the width of a sample. The metrology device includes a first light source that produces a first illumination line on the sample. A scanning system may be used to scan an illumination spot across the sample to form the illumination line. A detector collects the photoluminescence light emitted along the illumination line. Additionally, a broadband illumination source may be used to produce a second illumination line on the sample, where the detector collects the broadband illumination reflected along the second illumination line. A signal collecting optic may collect the photoluminescence light and broadband light and focus it into a line, which is received by an optical conduit. The output end of the optical conduit has a shape that matches the entrance of the detector.

A 3D-printing method for the additive production of components includes supplying a modelling material to a 3D-printing device, determining quality characteristics of the modelling material using a monitoring device, analyzing a product quality of the modelling material, using an analysis device, on the basis of the determined quality characteristics, depositing and liquefying the modelling material layer by layer, and curing the liquefied modelling material layer by layer.