A temperature measurement footprint device, a mobile temperature measurement device, and a method for determining a temperature measurement footprint are described. In an implementation, a temperature measurement footprint device includes a thermopile configured to measure a temperature of an object; a camera configured to capture an image of the object, the camera disposed proximate to and in communication with the thermopile; and a light source configured to illuminate the object, the light source disposed proximate to and in communication with the thermopile and the camera.

A screening method includes controlling a heat source of a screening device to reach a selected temperature, determining a location of a subject, and determining that the location is a desired distance from the screening device. The method also includes based at least in part on determining that the location is the desired distance from the screening device, simultaneously determining a temperature of the subject and a temperature of the heat source using a temperature sensor of the screening device.

The present disclosure discusses various systems and methods for screening individuals for an elevated skin temperature, including substantially reducing the footprint of conventional thermal imaging system. The footprint of the currently available thermal imaging system is reduced in part because rather than having a blackbody and a person being screened simultaneously located within the thermal camera's field of view, the present disclosure discusses a unique thermal imaging system that provides a reference temperature to the system for subsequent comparison to the thermal camera, using a blackbody, prior to the thermal scanning and imaging the person.

Techniques for facilitating uncertainty gauging for imaging systems and methods are provided. In one example, a method includes determining temperature data associated with infrared image data of a scene. The method further includes receiving at least one parameter associated with the infrared image data. The method further includes determining an uncertainty factor associated with the temperature data based on the at least one parameter. Related devices and systems are also provided.

A microelectromechanical infrared sensing apparatus includes a substrate, a sensing plate, a plurality of supporting elements and a plurality of stoppers. The substrate includes an infrared reflecting layer. The sensing plate includes an infrared absorbing layer. The supporting elements are disposed on the substrate, and each of the supporting elements is connected to the sensing plate, such that the sensing plate is suspended above the infrared reflecting layer. The stoppers are disposed between the substrate and the sensing plate. When the sensing plate moves toward the infrared reflecting layer and the stoppers contact both the substrate and the sensing plate, the distance between the sensing plate and the infrared reflecting layer is substantially equal to the height of at least one of the stoppers.

A security sensor device includes: a plurality of sensor units each of which includes an infrared ray detection element having a visual field in a predetermined target direction, the plurality of sensor units aligned in a predetermined arrangement direction; a plurality of optical systems through which detection rays transmit from a corresponding detection area to each infrared ray detection element, the plurality of optical systems aligned in the predetermined arrangement direction; a target object detection circuit into which an output signal is input from each infrared ray detection element; and a switching unit which is configured to change a configuration between each of the plurality of sensor units and the plurality of optical systems according to a user operation, so that two detections of low-place mounting detection and high-place mounting detection are respectively performed.

A thermal imaging apparatus for measuring a temperature of a target in a monitored area comprises a thermal imager, an optical image capturing device and a computing processing device. The thermal imager is configured to capture a thermal image of the monitored area. The optical image capturing device is configured to capture optical images of the monitored area. The computing processing device is configured to determine one of the optical images as a determined optical image synchronizing with the thermal image according to positions of blocks corresponding to the target in the thermal image and the optical images, perform calculation according to the thermal image and the determined optical image to obtain a measured distance between the target and the thermal imaging apparatus, and perform calibration according to the measured distance and the thermal image to obtain a calibrated temperature value of the target.

A method and device for measuring body temperature and a smart apparatus are disclosed. The method comprises: when a temperature measuring instruction is received, starting a camera and a first infrared thermometer; photographing a user by using the camera to obtain an image, and identifying the image to determine a part to be measured of the user; acquiring a distance between the first infrared thermometer and the user; when the distance is equal to a preset distance threshold, controlling the first infrared thermometer to measure the temperature of the part to be measured of the user; wherein the preset distance threshold is set according to a focal length of a Fresnel lens of the first infrared thermometer; and according to a preset rule and the measured temperature, determining a value or a value range of the user's body temperature.

The problem to be solved by the invention is to accurately detect a distant object while preventing an increase in cost. An object recognition device includes: an imaging unit configured to acquire a plurality of thermal images having an object captured therein; a stereo matching unit configured to perform stereo matching using the plurality of thermal images and calculate a distance to the object; a specific temperature region extracting unit configured to extract a specific temperature region from the thermal images; and an area ratio estimating unit configured to estimate, based on the distance to the object calculated by the stereo matching unit, a ratio of an area of the object included in a pixel for the specific temperature region.

An example system includes a thermal camera, a memory, and processing circuitry coupled to the thermal camera and the memory. The processing circuitry is configured to acquire a core temperature of a patient and acquire a first thermal image associated with the patient. The processing circuitry is configured to determine, based on the first thermal image, a first sensed temperature of a location associated with the patient. The processing circuitry is configured to determine a core temperature delta between the core temperature and the first sensed temperature. The processing circuitry is configured to acquire a second thermal image associated with the patient. The processing circuitry is configured to determine, based on the second thermal image, a second sensed temperature. The processing circuitry is configured to determine, based on the second sensed temperature and the core temperature delta, a measure of the core temperature.