A method for testing a temperature measuring instrument is presented, where the instrument includes at least one sensor that changes its electrical resistance, and/or an electrical voltage that it produces, in response to being exposed to a change in temperature, and where the instrument is configured to be coupled to an object of interest. The method includes changing the temperature of at least one sensor by an amount that is detectable given the measurement resolution of the at least one sensor, by driving an electrical manipulation current through this sensor; obtaining one or measurement values from at least one sensor; and evaluating a state of the measuring instrument, a state of one or more of its sensors, and/or a state of a coupling to an object of interest, from the one or more measurement values.

A method of calibrating a thermal sensor device is provided. The method includes extracting an incremental voltage to temperature curve for a diode array from a first incremental voltage of the diode array at a first temperature. The diode array and a device under test (DUT) which includes a thermal sensor are heated. After heating the diode array, a first incremental temperature is determined from the incremental voltage to temperature curve for the diode array and a second incremental voltage of the diode array after heating the diode array. An incremental voltage to temperature curve is extracted for the DUT from the first incremental temperature, a first incremental voltage for the DUT at the first temperature, and a second incremental voltage of the DUT after heating the device under test. A temperature error for the thermal sensor is determined from the incremental voltage to temperature curve for the DUT.

Systems and methods of body temperature measurement obtain a first temperature from a first temperature sensor. The first temperature sensor is separated from a second temperature sensor by a first insulator. A second temperature is obtained from the second temperature sensor. A heat transfer rate between the first temperature and the second temperature sensor is calculated and a body temperature determined from the heat transfer rate.

The present disclosure relates to a method for estimating parameters of a junction of a power semi-conductor element comprising: •—Detecting at least one stable on-line operating condition through measurements (2, 3, 4) of Von, Ion, Tc on a semi-conductor module (1) where Ion is a current for which the on-state voltage Von of the semi-conductor is sensitive to the temperature and Tc is the temperature of the casing of said semi-conductor element; •—Measuring and storing at least one parameter set Von, Ion, Tc of said at least one stable operating condition; •—in a calculating unit (52), providing calculations for minimizing the error between a junction temperature estimation Tj of an electrical model Tj=F(Von, Ion, θelec) comprising a first set of unknown parameters θelec and another junction temperature estimation Tjmod of a loss/thermal model Tj=G(lon, Tc, θ mod) comprising a second set of unknown parameters θ mod and obtaining at least one set of parameters θelec and at least one parameter θ mod providing minimization of said error; •—providing the calculated value of Tj with at least one of the calculated parameters sets θelec and/or θ mod and the measured Von, Ion, Tc; •—Storing the at least one parameters set θelec and/or θ mod and/or Tj.

The application provides a temperature calibration method, including: under a condition that first temperature data of a temperature sensor and second temperature data of a temperature controller meet a temperature equilibrium condition, calibrating real-time temperature data of the temperature controller; and under a condition that the first temperature data and the second temperature data do not meet the temperature equilibrium condition, determining a temperature calibration constant value according to third temperature data of the temperature sensor and fourth temperature data of the temperature controller when temperature control is not performed and performing temperature calibration, by using a temperature calibration formula including the temperature calibration constant value, on the real-time temperature data obtained by the temperature controller. The application can solve the problem of insufficient accuracy of the temperature measured. The application further provides a temperature calibration system, and an electronic device, which have the beneficial effects.

The present disclosure relates to an apparatus for determining and/or monitoring temperature of a liquid and to a method for manufacturing a corresponding apparatus. The apparatus comprises at least one temperature sensor and a measuring element, wherein at least the temperature sensor and the measuring element are arranged in a single sensor head. Further arranged at least partially within the sensor head is at least one unit comprising a material with anisotropic thermal conductivity.

A method, apparatus and system for measuring a temperature can involve measuring a voltage with a resistance temperature detector using a variable excitation current, and deriving a process temperature from the voltage measured by the resistance temperature detector. The process temperature can be further derived by applying a plurality of values of the variable excitation current, measuring corresponding values of voltage, and estimating a resistance by applying a least square estimation. The process temperature can also be derived by applying a different value of the variable excitation current at every iteration, using a recursive least square estimation to measure a resistance, and using confidence intervals for instrument diagnostics.

A reference load includes a parallel connection of a resistor load having a resistor and a transistor load having a plurality of transistors, wherein a temperature coefficient of the resistor load is positive, and a temperature coefficient of the transistor load is negative.

Various implementations include a Human Thermoregulation Simulator (HTRS) that simulates the natural and primary thermoregulatory functions of a patient that are relevant during therapeutic hypothermia procedures. For example, in various implementations, a HTRS includes a core container configured to be at least partially filled with water, and the core container includes a heat generator configured to heat the water inside the core container. A middle container is disposed concentrically around the core container, and the middle container includes a foam layer configured to be saturated by water. An outer container is disposed concentrically around the middle container, and the outer container includes a network of tubing disposed on at least a portion of an inner surface of the outer container. The HTRS also includes a pump configured to circulate water from the core container through the network of tubing.

The present invention provides an adaptive temperature slope calibration method of a thermal sensor, wherein the method includes the steps of: obtaining a parameter of the thermal sensor under a temperature environment; calibrating a temperature slope of the thermal sensor by using the parameter of the thermal sensor obtained under the temperature environment without using parameter(s) of the thermal sensor under other temperature environment(s); and storing the temperature slope of the thermal sensor for subsequent use of detecting temperature.