Systems and methods for evaluating hydrocarbon properties. At least one of the systems includes: a drilling machine configured to drill a borehole; a plurality of infrared cameras configured to capture infrared image data representing a plurality of infrared images of at least one core sample extracted from the borehole; a computer-readable memory comprising computer-executable instructions; and at least one processor configured to execute the computer-executable instructions, in which when the at least one processor is executing the computer-executable instructions, the at least one processor is configured to carry out operations including: receiving the infrared image data captured by the plurality of infrared cameras; determining, based on the infrared image data, at least one hydrocarbon weight value of the at least one core sample.

Disclosed are calibration techniques that can be implemented by a device that conducts biological tests. In certain embodiments, the device for testing a biological specimen includes a receiving mechanism to receive a carrier, a camera module arranged to capture imagery of the carrier, and a processor. Some examples of the processor can detect a calibration mode trigger. In calibration mode, the processor can divide the captured imagery into segments and selectively perform one or more calibration procedures for each segment. Then, the processor records a calibration result for each segment.

Provided herein are systems, devices and methods for the rapid and accurate measurement of analytes by assay of binding events, by direct, digital measurement of individually resolved analyte/reporter binding events. The digital molecular assay systems, devices and methods disclosed herein are capable of particle-by-particle readout using optical reporter molecules that detect and report the binding of a single analyte molecule, and report each such binding in binary format. Such digital molecular assay systems, devices and methods are useful in a variety of applications, such as on mobile electronic devices for use in the field.

Systems and methods for evaluating hydrocarbon properties. At least one of the systems includes: a drilling machine configured to drill a borehole; a plurality of infrared cameras configured to capture infrared image data representing a plurality of infrared images of at least one core sample extracted from the borehole; a computer-readable memory comprising computer-executable instructions; and at least one processor configured to execute the computer-executable instructions, in which when the at least one processor is executing the computer-executable instructions, the at least one processor is configured to carry out operations including: receiving the infrared image data captured by the plurality of infrared cameras; determining, based on the infrared image data, at least one hydrocarbon weight value of the at least one core sample.

A method of manipulating and/or investigating cellular bodies (9) is provided. The method comprises the steps of: providing a sample holder (3) comprising a holding space (5) for holding a fluid medium (11); providing a sample (7) comprising one or more cellular bodies (9) in a fluid medium (11) in the holding space (5); generating an acoustic wave in the holding space exerting a force (F) on the sample (7) in the holding space (5). The method further comprises providing the holding space (5) with a functionalised wall surface portion (17) to be contacted by the sample (7) and the sample (7) is in contact with the functionalised wall surface portion (17) during at least part of the step of application of the acoustic wave. A system and a sample holder (3) are also provided.

A method of analyzing a tissue specimen is provided. The method includes imaging a tissue specimen to produce autofluorescence images acquired at different excitation and emission wavelengths, and/or reflectance images, using data produced during the imaging to identify one or more regions of interest within the tissue specimen, and performing an omics profiling on the identified one or more regions of interest within the tissue specimen to produce information relating to the tissue specimen.

The portable device (1) for quality control of semen comprises a housing (10) and within an inner space (11) of the housing, an accumulator (20), a processor unit (30) and a sample storing unit (40) for fixing a sample transporting cell (90), wherein the device (1) is further provided with a microscope unit (50) comprising a camera unit (51) secured to the housing (10), an optical unit (52) connected to the camera unit (51) and a light source (53) illuminating the sample transporting cell (90) during use, and wherein the sample storing unit (40) is arranged inside the housing (10) at the upper side of the housing (10) or adjacent thereto, wherein the light source (53) is arranged on the outer side of the sample storing unit (40) and connected to the housing (10), wherein the camera unit (51) is arranged in the inner space (11) of the housing, on the inner side of the sample storing unit (40) in such a configuration that the distance between the supporting plane (41) of the sample storing unit (40) and the light sensor of the camera unit (51) is at most 35 mm, and wherein the optical unit (52) is arranged between the camera unit (51) and the sample storing unit (40).

A method and a measuring equipment of the degree of crystallinity of a polymer coating on a metallic substrate using a hyperspectral camera as well as representing or mapping the degree of crystallinity is provided. An equipment for online measurement of crystallinity of polymers, including at least one hyperspectral camera, at least one lighting source, a polymer layer deposited on a substrate and means to convey the substrate, the lighting source and the hyperspectral camera being set-up in specular reflection towards the polymer layer.

A method for monitoring and controlling multi-phase condition of reactant in manufacturing process is provided. The monitoring and controlling method includes the following steps. A plurality of clusters of monitoring images is captured corresponding to a plurality of process reaction time points in a plurality of observation regions. According to the clusters of the monitoring images, a plurality of image index features is extracted. According to the image index features, a plurality of phase modes corresponding to the observation regions is determined. According to the image index features, a cluster of generation characteristics of the reactant corresponding to the phase modes is determined. According to the cluster of generation characteristics, an adjustment of the manufacturing process is performed.

Provided are a portable electronic device, an accessory, and an operation method thereof. The portable electronic device includes a light source irradiating light to skin, at least one light detector detecting light received from the skin, at least one memory storing an instruction, and a processor, by executing the instruction, controlling the light source to irradiate the light and analyzing a skin state based on light detected by the light detector.