An ear thermometer includes a probe including an infrared sensor for measuring a temperature of an eardrum of a target person in a non-contact manner and attached to an ear hole of the target person. The probe includes a probe body inserted into the ear hole, a housing supporting the probe body, and an in-ear type earpiece attached to the probe body and coming into contact inside the ear hole. The earpiece includes a base portion including an engaging portion engaging with the probe body and partially exhibiting a hollow conical shape, and a substantially cylindrical tip portion provided at one end of the base portion and extending in a direction away from the housing. The base portion and the tip portion are integrally formed of a flexible material. An outer diameter of the tip portion is set to be smaller than a maximum outer diameter of the base portion.

A process and a device are provided for a contactless determination of a measuring location (32) on a body, which point is intended for the measurement of a skin temperature of a human being (10). A signature (36) indicating a measuring location (32) on the body is detected by means of a sensor system (16). A skin temperature measurement is carried out on the measuring location (32) on the body. A signature (36) detectable in the infrared range and a sensor system (16) sensitive in the infrared range are used. Both the detection of the infrared range signature (36) and the measurement of the skin temperature at the measuring location (32) on the body are carried out by means of the sensor system (16) sensitive in the infrared range.

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.

A non-invasive and a non-contact core body temperature monitoring method and system including an infrared camera, a processor, and a non-transitory computer readable medium with a program for analyzing thermal images of the human eye. The method for using the system that includes isolating ocular thermal images from a facial image; extracting thermal information about the surface of the eye; transitioning the thermal information to a selected model of the eye; estimating a temperature at the back of the eye; optimizing the estimated temperature at the back of the eye, and transmitting the optimized temperature information to an output device.

A method of determining a temperature of a patient includes measuring a first temperature of the patient with a temperature device, and measuring a second temperature of an environment with the temperature device. The method includes determining if a change in the ambient temperature exceeds a threshold. If the change does exceed the threshold, the method also includes applying a correction factor to the first temperature of the patient to account for the change in ambient temperature.

A thermometer includes a probe to be fitted into an ear of a patient, the probe having an infrared sensor for measuring the temperature of an eardrum of the ear of the patient in a non-contact manner, a signal cable connected to the infrared sensor and drawn out of the probe, a gripping part provided in the probe to be gripped when the probe is inserted inside a tragus of the ear, and a groove portion provided in the gripping part to hold the signal cable in a curved state and to allow a curved portion of the signal cable to fit in and along a cavum conchae of the ear.

A cap for a thermometer having a probe configured to be placed in contact with a patients body or to be inserted into a body cavity of the patient and a temperature sensor includes a cap housing, a proximity sensor and a proximity sensor electrical conductor. The cap housing is configured to selectively connect with and to be selectively detached from the thermometer and at least partially surround the probe of the thermometer when connected with the thermometer. The proximity sensor is connected with the cap. The proximity sensor electrical conductor is connected with the cap and electrically connected with the proximity sensor. A thermometer including the cap is also provided.

A method of regulating thermal comfort of an occupant of a vehicle cabin uses a radiant heating tile powered via an energy storage device to generate thermal energy. The method also includes detecting the occupant's position via a position sensor and detecting the occupant's surface temperature and detecting a temperature of the tile via at least one temperature sensor. The method additionally includes determining, via an electronic controller, a rate of change of occupant's surface temperature and a difference between the tile temperature and the occupant's surface temperature relative to a predetermined temperature set-point. The method further includes regulating, via the electronic controller, a power input from the energy storage device to the tile in response to the determined rate of change of the surface temperature and the determined difference between the tile temperature and the occupant's surface temperature to thereby regulate the occupant's surface temperature.

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 of determining a temperature of a patient includes measuring a first temperature of the patient with a temperature device, and measuring a second temperature of an environment with the temperature device. The method includes determining if a change in the ambient temperature exceeds a threshold. If the change does exceed the threshold, the method also includes applying a correction factor to the first temperature of the patient to account for the change in ambient temperature.