A temperature sensing system including a head unit comprising a thermal sensor for acquiring thermal data from a surface, a wireless transmitter wirelessly transmitting the thermal data, and a mounting interface; and a non-conductive pole connected to the mounting interface of the head unit.

The system is configured to locate, track and/or analyze activities of living beings in an environment. The system does not require the input of personal biometric data. The sensor system detects infrared (IR) energy from a living being moving in an environment, determines a temperature of the living being based on IR energy data of the IR energy, projects the temperature onto a grid having sequential pixels, determines serial changes of the temperature in the sequential pixels and determines a trajectory of the living being based on the serial changes of the temperature in the sequential pixels.

A thermal monitoring system includes thermal monitoring devices that generate sensor data including thermal images depicting monitored elements (e.g. of an electrical switchgear system). The sensor data for all monitoring devices installed at a local deployment is collected by a gateway device, and relevant data from multiple local deployments is further aggregated by a cloud management system for further analysis. New event triggering rules determining how the thermal monitoring devices filter or record the sensor data are generated based on the aggregated data during a continuous learning process. The system detects patterns in the sensor data for the monitoring devices and/or local deployments as a whole and tracks deviations from these patterns, improving the accuracy of the event detection over time.

The present invention relates to a method for generating a security identifier for a control unit (10) of a battery system (100), comprising the steps of supplying an operation voltage to the control unit (10), outputting calibration data from a non-volatile memory element (15a) of the control unit (10), and generating a security identifier from the calibration data using a security algorithm. Therein, the calibration data is based on at least one testing process performed on the control unit (10) and is required for a faultless operation of the control unit (10). Further, according to a method for generating an activation key for a control unit (10) of a battery system (100) an activation key is generated based on such security identifier and output from the control unit (10). The invention further relates to an activation method for such control unit (10), wherein a control unit (10) is activated in response to the validation of such security identifier. The present invention further relates to a control unit (10) for performing such methods and further relates to the use of calibration data for generating a security identifier.

A secure portable patrol system including a portable patrol device and a base unit is revealed. The patrol device is a portable rectangular body disposed with a multi-image display screen on a front surface thereof. The patrol device is disposed with an IR image capture unit, a wireless call unit and a first SIM card communication unit so that users can perform multiple tasks by the single patrol device such as checking whether there is area that overheats or abnormal conditions that occur. The base unit includes a specific transmitter while the patrol device is set with a specific port for electrical connection to the specific transmitter. Thereby the patrol device and the base unit are electrically connected for secure data transmission.

The present invention discloses a PIR sensor, including an infrared probe and a lens located between the infrared probe and a detected area, wherein a baffle is provided between the lens and the detected area, a plurality of through holes evenly provided on the baffle. The through holes of the baffle are arranged in a meshy patterns. According to the PIR sensor disclosed by the present invention, the baffle can block the lens, without affecting the performances of the PIR sensor at all, thereby not only improving the aesthetic degree of the product, but also further improving the concealment property of a photographing device.

Ultra-low power methods and sensor devices are provided for determining the presence and magnitude of electromagnetic radiation or other signals. The sensor devices and methods provide both qualitative and quantitative analyses and can be deployed in remote locations for continuous monitoring over years without requiring a replacement power supply.

A secure portable patrol system including a portable patrol device and a base unit is revealed. The patrol device is a portable rectangular body disposed with a multi-image display screen on a front surface thereof. The patrol device is disposed with an IR image capture unit, a wireless call unit and a first SIM card communication unit so that users can perform multiple tasks by the single patrol device such as checking whether there is area that overheats or abnormal conditions that occur. The base unit includes a specific transmitter while the patrol device is set with a specific port for electrical connection to the specific transmitter. Thereby the patrol device and the base unit are electrically connected for secure data transmission.

The present disclosure relates to the technical field of temperature measuring guns and discloses a temperature measuring gun base charging structure and a temperature measuring gun applying the same. The temperature measuring gun base charging structure includes a base, a base bottom is integrally formed on a lower side of the base, a placement cavity is formed in one side of an upper portion of the base, base side walls are arranged on other side surfaces of the base, a charging module is arranged in the placement cavity, and a charging cable extends out of the base bottom. By arranging the placement cavity with an oblique inner wall, a lower end of the temperature measuring gun may be placed in the placement cavity, and the temperature measuring gun is placed obliquely and uprightly, which is not prone to falling and convenient to take for use.

A handheld LIBS analysis method features a moveable laser focusing lens, and a laser beam directed to a sample via the laser focusing lens. A first mirror includes an aperture for the laser beam. This mirror is oriented to re-direct plasma radiation for delivery to a detection fiber.