One embodiment can provide a heating system with thermal-visual-servo control. The system can include a heat source configured to emit localized heat to an object, a thermal camera configured to capture thermal images of the object, and a motion-control module coupled to the heat source and configured to control movement and focus of the heat source based on temperature information extracted from the thermal images, thereby facilitating controlled heating of the object.

A system for screening persons' temperatures comprises an imaging device configured to generate imagery data, including infrared image data, of a first scene and a second scene. The system receives imagery data from the first scene, identifies persons in the scene using the imagery data, and determines each person's temperature. The system further compares the persons' temperatures to a threshold and indicates a person should be directed to the second scene if the person's temperature is above a threshold. Subsequently, the system determines and compares the person's temperature in the second scene and provides an indication if the person's temperature exceeds a second threshold. Further, a confidence factor can be associated with determinations of persons' temperatures.

A calibration method, device for infrared temperature measurement, an electronic apparatus and a storage medium are provided. The method includes: obtaining a monitoring temperature and an actual temperature of a black body, wherein the monitoring temperature of the black body is monitored by an infrared thermal imager, and the black body is an object having a thermal conductivity greater than a first threshold and being uniformly heated; calculating a difference between the monitoring temperature and the actual temperature; and calibrating the infrared thermal imager with the difference. In the embodiment of the present application, the cost of the black body is reduced and the stability of a measurement result is improved, thereby improving using effect of the calibration method for the infrared temperature measurement.

A non-contact body temperature detection system of a vehicle includes: a thermography camera configured to generate an image of a user within a passenger cabin of the vehicle; a head detection module configured to determine a first area of the image including a head of the user; an eye detection module configured to determine a second area of the first area of the image including an eye of the user; a tear duct detection module configured to determine a third area of the second area of the image including a tear duct of the user; a temperature module configured to determine a body temperature of the user based on pixels of the third area of the image; and an indicator module configured to indicate whether the user has an elevated body temperature when the body temperature of the user is greater than a temperature threshold.

Systems and methods include an infrared camera configured to capture an infrared image of a scene, a display configured to display a portion of the captured infrared image and at least one graphic indicia to guide a person being scanned, and a logic device configured to scan a region of interest using an infrared camera, detect a person in the region of interest, instruct the person to move into a scanning position, initiate temperature scanning of person if scanning criteria is satisfied, determine temperature of the person and compare to at least one temperature threshold, and perform a task associated with determined temperature. The system may further comprise a dual-image camera comprising the infrared camera and a visible image camera, wherein the dual-image camera comprises a beamsplitter arranged to reflect visible light towards the visible image camera and pass through an infrared image to the infrared camera.

In at least some cases, an embodiment of an electric power industry structure monitor is arranged as a distribution transformer monitor. In at least some cases, an electric power industry structure monitor is arranged as a tilt sensor monitor. In at least some cases an electric power industry structure monitor is arranged as a high-voltage tower (e.g., power pole) monitor. In some cases, the electric power industry structure monitor includes a housing arranged for positioning on an electric power industry structure, and a sensor arranged in the housing. The sensor is positioned to generate digital data associated with at least one environmental condition that exists proximal to the electric power industry structure monitor. The monitor also includes a processing circuit arranged to determine from the generated digital data that the at least one environmental condition has crossed a threshold.

In at least some cases, an embodiment of an electric power industry structure monitor is arranged as a distribution transformer monitor. In at least some cases, an electric power industry structure monitor is arranged as a tilt sensor monitor. In at least some cases an electric power industry structure monitor is arranged as a high-voltage tower (e.g., power pole) monitor. In some cases, the electric power industry structure monitor includes a housing arranged for positioning on an electric power industry structure, and a sensor arranged in the housing. The sensor is positioned to generate digital data associated with at least one environmental condition that exists proximal to the electric power industry structure monitor. The monitor also includes a processing circuit arranged to determine from the generated digital data that the at least one environmental condition has crossed a threshold.

Examples of non-invasive inspection of a mechanical system are described. In an example implementation, a first operational data from a detector mounted on an item being handled by a mechanical system is retrieved. The detector may include one or more sensors, and the first operational data is indicative of a current operational condition of the mechanical system. The first operational data can be compared with a corresponding historical first operational data and an error in the current operational condition of the mechanical system is determined based on the comparison. In response to the identification of the error, a notification is generated to perform a non-invasive inspection of the mechanical system.

Examples of non-invasive inspection of a mechanical system are described. In an example implementation, a first operational data from a detector mounted on an item being handled by a mechanical system is retrieved. The detector may include one or more sensors, and the first operational data is indicative of a current operational condition of the mechanical system. The first operational data can be compared with a corresponding historical first operational data and an error in the current operational condition of the mechanical system is determined based on the comparison. In response to the identification of the error, a notification is generated to perform a non-invasive inspection of the mechanical system.

A cellular trail camera system is disclosed and may include a housing; a mounting bracket for mounting the camera; a visible sensor; an infrared sensor; and a plurality of Fresnel lenses each operable to be individually mounted to or with the infrared sensor and to focus infrared light to the infrared sensor from a different direction. One of the Fresnel lenses may be mounted to or with the housing during operation. The housing may include a wireless transceiver, which may communicate via a cellular network. The camera may communicate with a wireless communication device via the wireless transceiver. The camera may communicate images and/or video to the wireless device. The infrared sensor may include a plurality of elements. The camera may be powered by a solar cell that is mounted on the camera or remote from the camera. The visible sensor may be activated when the infrared sensor detects a heat-generating object.