Disclosed are a method and an apparatus for body temperature measurement, a robot and storage medium. The method includes: when it is determined that there is a target user moving in a detection area of a robot, determining an orientation of the target user; adjusting a head of the robot according to the orientation of the target user so that a device for body temperature measurement arranged on the head of the robot faces the target user; and measuring a body temperature of the target user by using the device for body temperature measurement and reporting to a target processor, so that the target processor outputs and displays a result of the body temperature measurement. The method can reduce the time spent on temperature measurement and improve the efficiency of body temperature measurement.

This invention offers a fully protective cowl neck garment with various fasteners designed to attach additional protective gear, such as gloves and shoe coverings. Additionally, a temperature sensor shield is located on the hat and protective mask. This allows the clients or patients the ability to see and to monitor the temperature of their caregivers. The caregiver's temperature is visible on the hat, as well as the face mask. This makes the caregivers accountable to their clients or patients, as well as their colleagues and coworkers. This invention eliminates the worry of contact with infectious diseases or dangerous liquids, by utilizing elastic manual ties and hook-and-loop fasteners to ensure the garment is secured fully on a user's body. Overall, this invention ensures medical professionals, firemen, emergency medical personnel, government workers, and so forth, are protected fully from contagious and infectious diseases, liquids, and so forth.

This invention offers a fully protective cowl neck garment with various fasteners designed to attach additional protective gear, such as gloves and shoe coverings. Additionally, a temperature sensor shield is located on the hat and protective mask. This allows the clients or patients the ability to see and to monitor the temperature of their caregivers. The caregiver's temperature is visible on the hat, as well as the face mask. This makes the caregivers accountable to their clients or patients, as well as their colleagues and coworkers. This invention eliminates the worry of contact with infectious diseases or dangerous liquids, by utilizing elastic manual ties and hook-and-loop fasteners to ensure the garment is secured fully on a user's body. Overall, this invention ensures medical professionals, firemen, emergency medical personnel, government workers, and so forth, are protected fully from contagious and infectious diseases, liquids, and so forth.

The present invention pertains to an integrated wound dressing device for treatment of an insertion site of percutaneous and drug delivery devices. The integrated wound dressing device preferably comprises a transparent film layer having a bottom side, a top side and a perimeter. The bottom side is coated with an adhesive impregnated with an antimicrobial agent. The transparent film has a radius cutout between a central opening and the perimeter. A liquid crystal temperature sensitive film with an adhesive placed on the top side of the transparent film layer is preferably near and around the central opening. The dressing also has a layer of double folded release paper below the bottom side of the transparent film layer. The preferred TLCs used are cholesteryl esters with a preferable temperature detection range of 35-40° C. The preferred antimicrobial agent is chlorohexidine gluconate (CHG).

An apparatus for estimating body temperature includes a sensor including a first sensor board; an object contact surface provided below the first sensor board; a thermally conductive material provided on an upper end of the first sensor board; a second sensor board provided on an upper end of the thermally conductive material; at least one first temperature sensor provided on the first sensor board and being configured to measure a surface temperature of the object; and at least one second temperature sensor provided on the second sensor board and being configured to measure a surface temperature of the thermally conductive material; and a processor configured to: measure a heat flux based on the surface temperature of the object and the surface temperature of the thermally conductive material; and estimate core temperature based on the measured heat flux and the surface temperature of the object.

An apparatus for estimating body temperature includes a sensor including a first sensor board; an object contact surface provided below the first sensor board; a thermally conductive material provided on an upper end of the first sensor board; a second sensor board provided on an upper end of the thermally conductive material; at least one first temperature sensor provided on the first sensor board and being configured to measure a surface temperature of the object; and at least one second temperature sensor provided on the second sensor board and being configured to measure a surface temperature of the thermally conductive material; and a processor configured to: measure a heat flux based on the surface temperature of the object and the surface temperature of the thermally conductive material; and estimate core temperature based on the measured heat flux and the surface temperature of the object.

A measurement device includes: a sensor having a temperature sensor and a heat flux sensor; a first thermal rectification member that is disposed on a side of the sensor opposite from a side of the sensor configured to be in contact with a surface of a skin of a living body which is a measurement surface of a measurement target, and that is composed of a material having a higher thermal conductivity than air; and a structural member that is placed to be in contact with the measurement surface and that is spaced from the sensor and encloses the sensor.

An effective and highly accurate method for measuring temperature during thermal tumor ablation to increase ablation accuracy includes installing a fiber optic temperature sensor with a linearly chirped (the variation of the refractive index has a period growing in an algebraic progression) Bragg grating with a length of 1.4-6 cm and a diameter of 80-300 μm using a catheter directly on the tumor. Through the fiber optic sensor with a length of 1.4-6 cm and a diameter of 80-300 μm is passed a light spectrum, which undergoes backscatter due to the Bragg grating, dependent on the temperature acting on the sensor. Subsequently, using the backscatter light spectrum decoding software, developed according to the fiber optic cable parameters, the temperature profile is displayed on the computer. The method has applications in medicine, in particular oncology.

An effective and highly accurate method for measuring temperature during thermal tumor ablation to increase ablation accuracy includes installing a fiber optic temperature sensor with a linearly chirped (the variation of the refractive index has a period growing in an algebraic progression) Bragg grating with a length of 1.4-6 cm and a diameter of 80-300 μm using a catheter directly on the tumor. Through the fiber optic sensor with a length of 1.4-6 cm and a diameter of 80-300 μm is passed a light spectrum, which undergoes backscatter due to the Bragg grating, dependent on the temperature acting on the sensor. Subsequently, using the backscatter light spectrum decoding software, developed according to the fiber optic cable parameters, the temperature profile is displayed on the computer. The method has applications in medicine, in particular oncology.

Provided is a system for correcting a sweat analyte measurement for temperature. The system comprises a sweat collector (106) for collecting sweat from skin (102). The collected sweat is drawn from the sweat collector to an outlet (110) via a capillary (108). The sweat is drawn through the capillary by capillary action and evaporation of the sweat from the outlet. The evaporation of the sweat from the outlet depends on the temperature. A flow sensor (112) measures a flow rate of the sweat being drawn through the capillary. An analyte sensor (114) obtains the sweat analyte measurement. The system further comprises a controller which is configured to determine a temperature from the measured flow rate. The sweat analyte measurement is then corrected using the determined temperature. Further provided is a method for correcting a temperature-dependent sweat analyte measurement