Digital Thermometer of antimicrobial copper, meant for medical use, consisting externally of the body (1), the battery cover that is the removable part through which the battery is inserted into the thermometer (2), the power button i.e. ON-OFF button (3), the display (4) and the tip, that is the sensor for measuring temperature (5) and is characterized by the fact that the outer surface of these components except of the display, is made of antimicrobial copper, or bears antimicrobial copper. Due to the antimicrobial-bacteriostatic properties of copper and its alloys with antimicrobial properties, it is achieved naturally—without any further interference, i.e. without disinfectants use—the neutralization of pathogenic microbes that infest the thermometer body, therefore it is achieved limitation of their further dispersion.

Techniques and circuitry, in one embodiment, determine a temperature of a battery by applying a calibration packet to the battery's terminals and at the battery's first SOC, wherein the calibration packet includes a first pulse (charge or discharge) which temporally precedes a rest period. In one embodiment, measurement circuitry measures a first terminal voltage at a time immediately prior to or at a beginning of the first pulse of the calibration packet, and a second terminal voltage, in response to the calibration packet, at a time during the partial relaxation time period of a battery. Control circuitry determines a partial relaxation time voltage (V.sub.PRT) at the battery's first SOC using the first and second terminal voltages and determines a temperature of the battery by correlating the V.sub.PRT at the first SOC to a temperature of the battery at the battery's current SOH.

Disclosed is an intelligent measurement cup, comprising a cup body and a cup cover, which covers the cup body and has an electronic module provided therein. The electronic module comprises a battery, a main control circuit board electrically connected to the battery, and a laser detection unit electrically connected to the main control circuit board. The laser detection unit comprises a laser probe and a transparent shielding sheet which covers the laser probe. The laser probe is arranged at a side facing toward the cup body. A through hole is formed in the cup cover in a manner of corresponding to the laser probe so as to allow light of the laser probe to pass through. A laser emitted from the laser probe penetrates the shielding sheet and is then incident in the cup body in a scattered manner, so as to ensure that sufficient feedback photons are formed. The spectra reflected back through different emission media are different, therefore, the conditions of a liquid, conditions comprising the remaining amount, the type, whether the liquid has deteriorated, etc., in the cup body can be accurately detected.

A method for producing a sensor on the surface of a functional layer, in which suitable sensor material in the form of powder or a wire is melted in a laser beam by way of a method similar to laser cladding and subsequently is applied to the surface of the functional layer. There is provided a considerably improved method for producing sensors, and in particular in-situ sensors, wherein the sensors can also be deposited onto a functional layer that, in part, is very coarse, without having to employ complex masks, as has previously been customary. The ease of adapting the method parameters ensures broad use both with respect to the sensor to be produced and the functional layer to be detected. The sensors thus produced are used, in particular, to detect components that are subject to high temperatures or the functional layers thereof. The sensors that can be produced in accordance with the invention include, in particular, temperature, pressure or voltage sensors, as well as acceleration sensors.

A temperature-determining device for determining a temperature (TMED) of a medium via a temperature of a surface includes: an ambient-temperature sensor, arranged in surroundings of the surface, for measuring an ambient temperature (TU); a surface-temperature sensor, lying on the surface, for measuring a mixed temperature (TM) lying between the temperature (TMED) of a medium and the ambient temperature (TU); and an arithmetic-logic unit having an approximation formula electronically stored thereon for calculating an approximation (TMEDN) of a temperature of a medium. The approximation formula is a sum of the mixed temperature (TM) and a product of two factors. The first factor results from a difference between the mixed temperature (TM) and the ambient temperature (TU) and the second factor results from a ratio of a dividend to a quotient. The dividend results from a difference between a calibration temperature (TMEDKAL) of a medium and a calibration mixed temperature (TMKAL).

A temperature sensor includes a pair of thermocouple wires, a temperature measuring junction formed by joining tip ends of the pair of thermocouple wires together, an outer tube having a tip end provided with a tip end cover in which the temperature measuring junction is held, an insulator insulating the pair of thermocouple wires from the outer tube, and a glass seal filled in a base end of the outer tube to seal the outer tube from inside thereof. The glass seal contains bubbles which are independent of each other.

A method for evaluating a measurement result of a thermal analysis. A program-controlled computer unit is used to calculate at least one probability of the agreement of the measurement result with at least one dataset previously stored in the computer unit, wherein this calculation is based on a comparison of effect data previously extracted from a measurement curve of the thermal analysis with corresponding stored effect data of the dataset. The evaluation can advantageously include, an automatic recognition and classification of measurement curves and can be carried out in particular more efficiently, more economically and more quickly than previously, with at the same time a high quality of evaluation.

A system, method and machine-readable instructions for monitoring a power electronics device. The system involves a semiconductor device, at least one sensor and a processor. The processor is configured to monitor a junction temperature of the semiconductor device by determining from the at least one sensor an on-state resistance of the semiconductor device and calculating the junction temperature of the semiconductor device according to a relationship between the on-state resistance of the semiconductor device and the junction temperature of the semiconductor device. The processor may apply an ageing coefficient to the on-state resistance.

Method and apparatus for sustaining process temperature measurement with respect to a lead wire break. A resistance temperature device can include a group of lead wire arms including lead wire arms of a first lead wire type and a second lead wire type. An operation can occur to automatically switch from a first lead wire type configuration to a second lead wire type configuration in the resistance temperature device having the plurality of lead wire arms including the first lead wire type and the second lead wire type, if one or more wire breaks occurs in one or more the lead wire arms.

A passive and wireless sensor is provided for sensing at least one of magnetic field, temperature or humidity. The sensor can provide only one of the sensing functions, individually or any combination of them simultaneously. It can be used for various applications where magnetic field changes, temperature and/or humidity need to be measured. In one or more embodiments, a surface acoustic wave (SAW) sensor is provided that can measure one or more of a magnetic field (or current that generates the magnetic field), temperature and humidity. In one or more embodiments, a magnetoimpedence (MI) sensor (for example a thin film giant magnetoimpedance (GMI) sensor), a thermally sensitive (for example a Lithium Niobite (LiNbO.sub.3)) substrate, and a humidity sensitive film (for example a hydrogel film) can be used as sensing elements.