A thermographic camera control method includes periodically correcting a display temperature of a temperature distribution image at a first interval; and acquiring the temperature distribution image by periodically imaging a temperature measurement target by the thermographic camera at a second interval. The acquiring the temperature distribution image includes imaging the temperature measurement target after elapse of a standby time. The standby time is shorter than the second interval and starts from the correcting the display temperature.

A thermographic camera control method includes periodically correcting a display temperature of a temperature distribution image at a first interval; and acquiring the temperature distribution image by periodically imaging a temperature measurement target by the thermographic camera at a second interval. The acquiring the temperature distribution image includes imaging the temperature measurement target after elapse of a standby time. The standby time is shorter than the second interval and starts from the correcting the display temperature.

In an image processing apparatus, a first correction unit corrects imaging data acquired from an infrared imaging device, based on a first correction table, and outputs first corrected data. A second correction unit generates a second correction table for the imaging data in a state in which a shutter is closed, and outputs second corrected data based on the second correction table. A saturated region detection unit detects a saturated region in the imaging data. A shutter control unit performs closing control for the shutter, based on a result of detection of the saturated region. An abnormal pixel detection unit detects whether or not the imaging data acquired in the state in which the shutter is closed includes an abnormal pixel. A selection unit selects and outputs either the first corrected data or the second corrected data in accordance with a result of detection by the abnormal pixel detection unit.

Described herein is a modulation device for periodically modulating light emitted by a light source. The modulation device includes at least one enclosing tube being rotatable about a cylinder axis of the enclosing tube. The enclosing tube includes at least one aperture disposed within a cylindrical wall of the enclosing tube. The modulation device further includes at least one driving system for rotating the enclosing tube about the cylinder axis. Also described herein are a modulated illumination device and a spectrometer device.

A temperature measuring device using a thermal imaging camera according to an embodiment of the present invention may comprise: a first operation module for obtaining, for the thermal imaging camera, a curve of temperature difference versus output code difference where the X axis represents the output code difference and the Y axis represents the temperature difference indicated by a plurality of measured values; a second operation module for obtaining a function of temperature difference versus output code difference, the function curve-fitted by using the curve of temperature difference versus output code difference; and a third operation module for measuring the temperature of an object by applying the curve-fitted function of temperature difference versus output code difference.

A temperature measuring device includes a device main body, a signal control module, a movable shutter module, and a first and a second non-contacting temperature sensing module. The movable shutter module includes an electric control driver, a movable shutter structure, and an electric control heater, and the movable shutter structure includes a black substance for generating a predetermined heating temperature from being heated by the electric control heater. The first non-contacting temperature sensing module is configured for measuring an object temperature of an object so as to obtain object temperature information of the object. The second non-contacting temperature sensing module is configured for measuring the predetermined heating temperature generated by the black substance of the movable shutter structure so as to obtain black body temperature information of the black substance. The first non-contacting temperature sensing module can be calibrated according to the black body temperature information.

A temperature measuring device includes a device main body, a signal control module, a movable shutter module, and a first and a second non-contacting temperature sensing module. The movable shutter module includes an electric control driver, a movable shutter structure, and an electric control heater, and the movable shutter structure includes a black substance for generating a predetermined heating temperature from being heated by the electric control heater. The first non-contacting temperature sensing module is configured for measuring an object temperature of an object so as to obtain object temperature information of the object. The second non-contacting temperature sensing module is configured for measuring the predetermined heating temperature generated by the black substance of the movable shutter structure so as to obtain black body temperature information of the black substance. The first non-contacting temperature sensing module can be calibrated according to the black body temperature information.

A system for monitoring a petrochemical installation is disclosed. The system can include an optical imaging system comprising an array of optical detectors. The system can comprise processing electronics configured to process image data detected by the optical imaging system. The processing electronics can be configured to detect a target species based at least in part on the processed image data. The processing electronics can further be configured to, based on a detected amount of the target species, transmit an alarm notification to an external computing device over a communications network indicating that the target species has been detected at the petrochemical installation.

A system for monitoring a petrochemical installation is disclosed. The system can include an optical imaging system comprising an array of optical detectors. The system can comprise processing electronics configured to process image data detected by the optical imaging system. The processing electronics can be configured to detect a target species based at least in part on the processed image data. The processing electronics can further be configured to, based on a detected amount of the target species, transmit an alarm notification to an external computing device over a communications network indicating that the target species has been detected at the petrochemical installation.

A self-referenced ambient radiation thermometer determines a temperature of a blackbody object and includes a temperature stabilized detector; a detector lens; a Lyot stop; a collimating lens; a field stop; an optical chopper such that the central radiation received by the temperature stabilized detector is modulated at a modulation frequency of the optical chopper; an objective lens in optical communication with the blackbody object and the temperature stabilized detector, optically interposed between the blackbody object and the field stop and that: receives the central radiation from the blackbody object and communicates the central radiation to the field stop; and a temperature-stabilized isothermal enclosure that provides a stable temperature and isothermal environment to elements disposed in the temperature-stabilized isothermal enclosure, wherein the elements disposed in the temperature-stabilized isothermal enclosure comprise: the temperature stabilized detector, the detector lens, the collimating lens, the Lyot stop, and the field stop.