A thermometer is provided that includes a main body having a first body including first and second regions and a second body mounted on the first body, the main body extending in a first direction; a rubber cap surrounding the second region and formed to be inserted into the ear; a temperature sensor disposed in the second region and having a specific temperature sensing range with respect to the first direction; and first and second circuit boards electrically connected to the temperature sensor and disposed in the second region in a second direction intersecting the first direction.

An infrared thermopile sensor includes a silicon cover having an infrared lens, an infrared sensing chip having duo-thermopile sensing elements, and a microcontroller chip calculating a temperature of an object. The components are in a stacked 3D package to decrease the size of the infrared thermopile sensor. The infrared sensing chip and the microcontroller chip have metal layers to shield the thermal radiation. To measure object temperature accurately under acute change in environmental temperature, this disclosure uses the duo-thermopile sensing elements, that one is the active unit for measuring the object temperature and another one is the dummy unit for compensating the effect from the package structure.

This document describes techniques for, and systems that enable, in-ear health monitoring. The techniques described herein enable early detection of health conditions (e.g., contagious disease) through use of an in-ear health-monitoring and audio device. These techniques prompt a user, often through the user's smart phone, to listen to audio content through the device, which also takes the user's temperature. Through repetitive use, the techniques are capable of determining a temperature differential for the user, which aids in early detection of a contagious disease or other malady.

An infrared imaging device includes a plurality of electronic components, a phase change material, and a heat transfer structure. The plurality of electronic components is configured to collect data and have a predetermined temperature parameter. The plurality of electronic components is disposed within the phase change material. The phase change material has a first material phase and a second material phase. The phase change material has a first material phase and a second material phase. The phase change material is configured to absorb heat through changing from the first material phase to the second material phase. The heat transfer structure is disposed within the phase change material. The heat transfer structure is configured to conduct heat within the phase change material. The phase change material and the heat transfer structure are further configured to regulate a temperature of the electronic components below the predetermined temperature parameter.

This document describes techniques for, and systems that enable, in-ear health monitoring. The techniques described herein enable early detection of health conditions (e.g., contagious disease) through use of an in-ear health-monitoring and audio device. These techniques prompt a user, often through the user's smart phone, to listen to audio content through the device, which also takes the user's temperature. Through repetitive use, the techniques are capable of determining a temperature differential for the user, which aids in early detection of a contagious disease or other malady.

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 box-packed ear thermometer probe cover capable of preventing contact infection comprises a packing box, a plurality of stacked ear thermometer probe covers, and a cover holder, wherein an opening which can be opened and closed is formed in the top of the packing box, a long slot is formed in a side face of the packing box, ear thermometer probe covers are placed in the packing box, each ear thermometer probe cover comprises a container structure and a container space, a cover holder is disposed below the lowest ear thermometer probe cover and comprises a sealing wall, a top surface and a suspension structure suspended on the top surface, the ear thermometer probe covers are supported by the cover holder, and the sealing wall extends upwards to the opening and seals the long slot.

An infrared thermometer (10), comprising a handheld part (12) and a head (11) connected to the handheld part (12). The head (11) comprises a bottom shell (112); an infrared sensor (113) configured to measure the temperature of an object to be measured; a holder (114) configured to hold the infrared sensor (113) in the bottom shell (112); a housing (111) configured to accommodate the infrared sensor (113) and the holder (114), and combined with the bottom shell (112); a first conductor (115) arranged on the housing (111); and a second conductor (116) arranged between the first conductor (115) and the handheld part (12) and adjacent to the holder (114) wherein the first conductor (115) and the second conductor (116) are capacitive sensors.

A thermometer device for temporal artery area measurement, configured to be used in a skin-touching stationary position, comprising an elongated body and a front portion having an end border arranged on a sensing plane (P), an array of N infrared sensors, with N greater than 8, a sensing region (SR) extending in the sensing plane over an area denoted SRA, at a distance denoted LF from a plane P2 containing the infrared sensors, the sensing region being encompassed within the border of the front end, an optical lens, interposed between the infrared sensors and the sensing region, to deviate light rays, wherein LF.sup.2<KSRA, with K=3.

An insertion detector for monitoring a position of a medical probe relative to a body cavity of a patient, the probe incorporates a proximity sensor that is responsive to a predetermined property of the patient's body. The proximity sensor may include a light emitter and a light detector. When the medical probe is inserted into the body cavity, a light flux between the light emitter and light detector is changed due to either obstruction by the cavity walls or reflection by the patient's skin. A response from the proximity sensor may be used to adjust a temperature measured from the body cavity to correct for errors due to non-insertion or partial insertion of the probe into the body cavity.