A system includes a structure and a material applied to a portion of the structure. The material may be adapted to change color locally in response to localized heating of the portion of the structure to a first threshold temperature due to an electrical current within the structure. The system may further include a detector configured to receive light from the structure to enable detection of a pathway of the electrical current through the structure based on a position of the color.

A roll object inspection apparatus includes a shooting part that shoots a surface of a roll molded body which is the uncut roll object and is injection-molded and then continuously fed in a predetermined feeding direction.

An optical characterization apparatus for imaging a specimen container containing a specimen. The optical characterization apparatus includes a moveable hood configured to move between an open state and a closed state relative to a specimen container imaging location and having an interior, wherein when the moveable hood is in the closed state, a specimen container positioned at the specimen container imaging location is at least partially located within the interior of the moveable hood. One or more optical devices coupled to or within the interior of the moveable hood are positioned, when the moveable hood is in the closed state, to allow imaging of a specimen container positioned at the specimen container imaging location. Automated specimen testing systems, optical characterization apparatus, and methods of measuring characteristics of specimen containers are provided, as are other aspects.

Disclosed herein are devices comprising: a sample conduit providing a path for fluid flow extending from a sample inlet to a sample outlet; a thermal housing enclosing the sample conduit, wherein the thermal housing comprises a plurality of measurement regions; and a motorized stage translatable along the thermal housing from a first location to a second location so as to align a detector with one or more of the plurality of measurement regions. Also disclosed are methods of use of the devices described herein.

An irradiation unit configured to scan and irradiate a sample with pulse waves; a reception unit configured to receive reflected waves of the pulse waves from the sample; a waveform generation unit configured to generate time waveforms of a signal representing the reflected waves at respective scan positions of the pulse waves; and a waveform correction unit configured to detect at least one peak in each of the time waveforms, and correct each of the time waveforms on a basis of each of positions of the at least one peak in the time waveforms are included.

A method and device for the optical scanning of a chromatographic sample (3), where a sample plate (2) holding the sample (3) is illuminated with light from a first illumination device (13) and the light emitted by the sample plate (2) is detected by an optical detector device (15) which detects in cell form or area form, a second illumination device (14) is preferably firstly activated in a preparation step. The sample plate (2) is displaced in a first displacement direction relative to the detector device (15), illuminated by the first illumination device (13) and a first measurement image is recorded. The sample plate (2) is displaced in a second displacement direction relative to the detector device (15), illuminated by the second illumination device (14), and a second measurement image is recorded.

An optical measuring device includes a light source, an optical sensing module, a positioning frame, a carrier, and a linking device. The optical sensing module includes a plurality of optical sensors. The light source and the optical sensing module are relatively disposed on the positioning frame. The carrier includes a plurality of hole rows, and the hole rows are arranged along a predetermined direction. Each of the hole rows includes a plurality of containing concaves for containing a measured object. The linking device is connected to the positioning frame and for driving the light source and the optical sensing module to move along the predetermined direction. The light source emits a light toward a side of the carrier, the light passes through the containing concaves to form a plurality of measured lights, and each of the optical sensors receives each of the measured lights.

A system includes a structure and a material applied to a portion of the structure. The material may be adapted to change color locally in response to localized heating of the portion of the structure to a first threshold temperature due to an electrical current within the structure. The system may further include a detector configured to receive light from the structure to enable detection of a pathway of the electrical current through the structure based on a position of the color.

An optical scanning system adapted to scan a sample on a chip is provided. The optical scanning system includes at least one optical scanning head, at least one scanning light source, a light receiving device and a processor. Each of at least one optical scanning head includes a focusing light source, a first optical guiding structure, and a control unit. The first optical guiding structure is configured to guide the focusing light emitted from the focusing light source to travel to the sample, and the first optical guiding structure is configured to guide the at least one scanning light emitted from the at least one scanning light source to the sample to generate a secondary light. The control unit is configured to control the first optical guiding structure to keep the focusing light and at least one scanning light focusing on a surface of the chip. The light receiving device receives the secondary light and generates a scanning electronic signal. The processor is electrically coupled to the light receiving device to dispose the scanning electronic signal.

Disclosed are a device of complex gas mixture detection based on optical-path-adjustable spectrum detection and a method therefor, and the device includes: a light source configured for generating an incident beam and emitting the incident beam into an optical gas cell; the optical gas cell, including a cavity configured for accommodating a gas sample, and a reflection module group configured for reflecting the incident beam and a track arranged in the cavity, where the track is consistent with a light path of the light beam in the cavity; a detector module that is connected with the track in a relatively movable manner and is configured for receiving light beams and obtaining spectral data, where an optical path is changed by moving the detector module relative to the track; and a data acquisition unit that is configured for acquiring the spectral data obtained by the detector module.