The present application discloses a Bluetooth temperature probe and temperature measurement device, comprising a handle assembly, a printed circuit board, a probe housing, a battery, an antenna, and a probe tip. It is characterized in that: the Bluetooth temperature probe is provided with a field-configurable thermocouple assembly. The field-configurable thermocouple assembly is formed by spot-welding a constantan spring contact to a copper-clad pad on the printed circuit board, wherein the constantan spring contact abuts against the probe housing. A metal ball formed by the spot welding serves as a temperature sensing junction of the field-configurable thermocouple assembly for temperature measurement.

A charge system for wireless temperature probe includes a probe body and a charging relay box detachably connected with the probe body, the probe body is provided with a first wireless charging component and a sealing structure. The charging relay box is internally provided with a power supply module, a control module and a second wireless charging component configured to establish a near field communication path with the first wireless charging component, and the control module is used to control the power supply module to adaptively supply power to the probe body through the near field communication path.

A charge system for wireless temperature probe includes a probe body and a charging relay box detachably connected with the probe body, the probe body is provided with a first wireless charging component and a sealing structure. The charging relay box is internally provided with a power supply module, a control module and a second wireless charging component configured to establish a near field communication path with the first wireless charging component, and the control module is used to control the power supply module to adaptively supply power to the probe body through the near field communication path, the probe body comprises a handle, a sealing ring, a probe tube and an internal assembly, a head of the internal assembly is inserted in the probe tube, and a tail of the internal assembly is inserted in the handle.

The present disclosure describes an instant-read thermometer. The instant-read thermometer comprises a needle and a body configured to house circuitry. The needle may include one or more sensors configured to detect a temperature of food, a cooking liquid, ambient temperature, and the like. The housing may include circuitry, including a printed circuit board comprising one or more processors, memory, and/or a haptic feedback mechanism. The housing may also store one or more batteries. The circuitry may be configured to provide feedback (e.g., haptic, tactile, audible, or visual) to a user based on the temperature detected by the one or more sensors.

A charge system for wireless temperature probe includes a probe body and a charging relay box detachably connected with the probe body, the probe body is provided with a first wireless charging component and a sealing structure. The charging relay box is internally provided with a power supply module, a control module and a second wireless charging component configured to establish a near field communication path with the first wireless charging component, and the control module is used to control the power supply module to adaptively supply power to the probe body through the near field communication path, the probe body comprises a handle, a sealing ring, a probe tube and an internal assembly, a head of the internal assembly is inserted in the probe tube, and a tail of the internal assembly is inserted in the handle.

A charge system for wireless temperature probe includes a probe body and a charging relay box detachably connected with the probe body, the probe body is provided with a first wireless charging component and a sealing structure. The charging relay box is internally provided with a power supply module, a control module and a second wireless charging component configured to establish a near field communication path with the first wireless charging component, and the control module is used to control the power supply module to adaptively supply power to the probe body through the near field communication path.

An electronic diagnostics device can detect and report environmental conditions from manufacture to use. The device can include a reaction chamber configured to receive a biological sample and contain a reaction with the biological sample. A component of the biological sample can be detected based on the reaction. The device can also include one or more environmental sensors, such as a temperature sensor and a humidity sensor, to detect the environmental conditions. A processor can read data from the environmental sensors and compare the measured conditions to specified ranges. If an environmental parameter falls outside the specified range, the processor can disable the device or communicate to a user that the device should not be used to perform a diagnostic test.

A monitor is provided, which is capable of continuously monitoring a monitoring target in a batteryless and maintenance free manner even with a small storage capacity. The monitor is a device using, as a sensor, a thermal battery including a thermoelectric power generation element which outputs a voltage according to a temperature difference between a temperature of an atmosphere covering the monitoring target and a temperature of a contact part with the monitoring target. The monitor includes a boost circuit outputting a boost voltage obtained by boosting a voltage input from the thermal battery; an energy storage element connected to an output port of the boost circuit, and storing power supplied from the thermal battery as a sensor and boosted by the boost circuit; a voltage detection circuit outputting a control signal which includes signal levels respectively corresponding to whether or not the detected boost voltage exceeds a predetermined voltage; and a switch opening and closing a path connecting a first terminal and a second terminal connected to the output port.

Devices and methods for dynamic power configuration (e.g., reduction) for thermal management (e.g., mitigation) in a wearable electronic device such as an eyewear device. The wearable electronic device monitors its temperature and, responsive to the temperature, configures the services it provides to operate in different modes for thermal mitigation (e.g., to prevent overheating). For example, based on temperature, the wearable electronic device adjusts sensors (e.g., turns cameras on or off, changes the sampling rate, or a combination thereof) and adjusts display components (e.g., adjusted rate at which a graphical processing unit generates images and a visual display is updated). This enables the wearable electronic device to consume less power when temperatures are too high in order to provide thermal mitigation.