The invention relates to a device for measuring the temperature in the anus or in the vagina of an animal, wherein a front longitudinal part, an abutment part and a rear longitudinal part lie in succession on the device, wherein the front longitudinal part is equipped with a temperature sensor and, when used as intended, it is intended to be inserted into the anus or the vagina of the animal until the abutment part approximately rests against the outside of the body of the animal. One or more further temperature sensors are attached to the rear longitudinal part and/or to the abutment part, which, when used as intended, are provided for measuring the temperature in the surroundings of the animal.

A core body temperature measurement device includes a fixing frame and a measurement unit. The fixing frame is fixed to an earflap of user. The measurement unit is detachably inserted into the fixing frame and includes an extending part and a temperature sensor. The extending part is bent according to a structure of an ear canal of user and is inserted into the ear canal. The temperature sensor is disposed at an end of the extending part to measure a core body temperature of user.

This invention discloses a probe structure and a thermometer, simply-structured but easy to use for users in a dark environment. The technique solution adopted in this invention is a probe structure, including a probe main body, a temperature sensor module and an optical assembly. The probe main body includes a detection end and a configuration end. The detection end is configured for touching or approaching an object. The configuration end is configured for connecting to an external thermometer body. The probe main body has a chamber for storing the temperature sensor module. The optical assembly is positioned at the configuration end. The optical assembly includes at least one lamp, a lamp panel and a light transmitting component. The at-least-one lamp is positioned at the lamp panel and the light transmitting component is disposed at the periphery of the lamp panel. Light emitted by the lamp passes through the light transmitting component.

In some examples, a temperature distribution sensor may include a laser source to emit a laser beam that is tunable over a wavelength range. The wavelength range may be less than a Raman bandwidth in a device under test (DUT), or of-the-order-of the Raman bandwidth in the DUT. A pulsed source may apply a pulse drive signal to the laser beam or to a modulator to modulate the laser beam that is to be injected into the DUT. A bandpass filter may be operatively disposed between the laser source and the DUT, and may be configured to an anti-Stokes wavelength that is narrower than the Raman bandwidth. A photodiode may be operatively disposed between the bandpass filter and the DUT to acquire, from the DUT, anti-Stokes optical time-domain reflectometer traces for two preset wavelengths of the laser beam to determine a temperature distribution for the DUT.

A method, applied to an electronic device comprising a camera and a temperature sensor, wherein the method comprises displaying a temperature measurement interface, receiving, from a user, a temperature measurement operation, measuring, in response to the temperature measurement operation and using the temperature sensor, a first temperature of a measured object, collecting, using the camera, a picture of the measured object, determining, based on the picture, a type of the measured object, matching, based on the type, a first temperature algorithm for the measured object, and determining, based on the first temperature and first algorithm, a second temperature of the measured object.

A fever-causing disease outbreak detection system for an early warning of the outbreak of an infectious disease. The system uses an array of infrared detectors to measure the temperatures of individuals in a population. The measured temperatures are used to create a measured population temperature distribution. A central control unit generates a predicted population temperature distribution using environmental data such as local atmospheric conditions and compares the predicted population temperature distribution to the measured population temperature distribution. If an outbreak is detected, an alert is issued.

The present invention relates to an infrared thermometer (1) able to project the detected temperature directly on the surface (6a) of the body (2) to be measured. The determination of the ideal distance of the thermometer from the body, necessary for the correct detection of the temperature thereof, being visually identifiable by means of the relative position of luminous shapes (8a, 8b) projected on the body to be measured (6).

The present disclosure discloses a multi-sensor synchronous non-contact measuring probe of an infrared thermometer, comprising a sensor fixing sleeve and a pressing block arranged at the inner end of the sensor fixing sleeve, wherein at least two infrared sensors are arranged on the pressing block, the sensor fixing sleeve is provided with optical channels with the same number as that of the infrared sensors, the detection surface of each of the infrared sensors is interfaced with a corresponding optical channel, and the infrared sensors are connected with MCU chips.

A temperature measuring method capable of switching calculation based on displacement detection includes a temperature measuring instrument and a displacement detecting unit. When the displacement detecting unit feeds back that the temperature measuring instrument is under an inactive state, a point calculation formula A is used to calculate and obtain a body temperature value. When the displacement detecting unit feeds back that the temperature measuring instrument is under an active state, a scanning calculation formula B is used to calculate and obtain the body temperature value.

[Object] To achieve the high performance of an electronic apparatus and ensure the safety of a user at the same time. [Solving Means] An electronic apparatus includes a temperature sensor that detects a temperature of a specified portion of the electronic apparatus; and a mode controller that turns on an endurance mode that is a mode that permits a surface temperature of the electronic apparatus to be increased to a second upper limit when the electronic apparatus is used out of contact with a human body, the surface temperature being calculated on the basis of the temperature detected by the temperature sensor, the second upper limit being higher than a first upper limit that is an upper limit of a temperature in a normal mode.