A temperature calibrator for calibrating temperature function devices has an outer and an inner housing as well as a calibrator block. The calibrator block is radially spaced from the inner housing to form a flow space. The flow space is in communication with the environment at the upper end and at the lower end to generate a flow. A fan having a fan wheel that can be driven by a motor is connected to the flow space. The fan wheel is formed from a heat-resistant material; and the fan forms a predominantly closed surface in a plan view.

A temperature sensor peripheral generates an output voltage that is proportional to temperature, whose temperature coefficient can be adjusted to any desired value, whose temperature coefficient can be either positive or negative, whose room temperature voltage can be adjusted to any desired value, and whose temperature coefficient and room temperature voltage adjustments are independent from one another.

The embodiments described herein generally relate to methods of noise compensation for proper temperature detection in thermal processing chambers and devices for achieving the same. Methods can include determining noise produced by a lamp zone and extrapolating the noise from the detected photocurrent. Devices can include a processing chamber, a substrate support disposed in the processing chamber, the substrate support having a high thermal mass, a pyrometer below the substrate support and oriented to view radiation emitted by the substrate and a controller configured to subtract a time invariant noise component and a time variant noise component from the pyrometer signal.

A device that measures a temperature of a heat plate for heating a target substrate mounted thereon, includes: a temperature measurement substrate including a substrate body and temperature sensors installed in the substrate body; a memory part to store correction parameters over a plurality of time zones after the temperature measurement substrate is mounted on the heat plate; and a data processing part configured to acquire time transition data of a temperature by correcting respective temperature detection values sampled at predetermined time intervals after the temperature measurement substrate is mounted on the heat plate, using the correction parameters stored in the memory part in a corresponding relationship with the temperature sensors and the time zones. The correction parameters are obtained in advance based on a standard temperature transition data acquired in advance using the temperature sensors and a time transition data acquired by each of the temperature sensors.

A method and a device for automatically detecting an incorrect measurement of a total temperature on an aircraft. The detection device comprises several monitoring units configured to monitor the variations of the measured total temperature, provided by a temperature probe, and current values of the Mach number and of the altitude of the aircraft over a predetermined monitoring period of time, and a detection unit configured to detect an incorrect measurement of the total temperature when said monitoring units simultaneously detect particular conditions relative to said variations.

A method for calibrating a temperature sensor arranged in a vapor compression system is disclosed. The opening degree of an expansion device is alternatingly increased and decreased. Simultaneously a temperature of refrigerant entering the evaporator and a temperature of refrigerant leaving the evaporator are monitored. For each cycle of the opening degree of the expansion device, a maximum temperature, T.sub.1, max, of refrigerant entering the evaporator, and a minimum temperature, T.sub.2, min, of refrigerant leaving the evaporator are registered. A calibration value, ΔT.sub.1, is calculated as ΔT.sub.1=C−(T.sub.2, min−T.sub.1, max) for each cycle, and a maximum calibration value, among the calculated values is selected. Finally, temperature measurements performed by the first temperature sensor are adjusted by an amount defined by ΔT.sub.1, max.

A body of a thermometer (1001), a first location to be measured (1002), a second location to be measured (1003) and a third installation location (1004) is established by the thermometer management system. Further, communication lines (1005) are connected to network units at each location to be measured. Network units relay the sensor output from a sensor part to the communication lines. A sensor part is fixed to an object to be measured and sends a sensor output in response to the temperature of the object to be measured. A network unit has a radio frequency identifier (RFID) reader and transmits to the thermometer body commands and the like stored in the memory of an RFID card in response to approach of the RFID card arranged corresponding to a location to be measured. The thermometer body receives the commands and the like and performs predetermined operations.

According to an embodiment there is provided a distributed optical sensing apparatus for determining of a primary quantity along a waveguide, the distributed optical sensing apparatus comprising: an electromagnetic radiation source adapted for coupling electromagnetic radiation into the waveguide to thereby generate in the waveguide (e.g. by interaction with the waveguide) a first response radiation and a different second response radiation; a detector device adapted for providing a first measurement signal indicative of the first response radiation and a second measurement signal indicative of the second response radiation; an evaluation unit adapted for deriving a secondary quantity (e.g. a loss) based on the first measurement signal and the second measurement signal; the evaluation unit being further adapted for deriving the primary quantity based on the secondary quantity and at least one of the first measurement signal and the second measurement signal.

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.

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).