Remote temperature measurement of cookware through a ceramic glass plate using an infrared sensor, taking into account the emissivity of the cookware which is continuously evaluated, and taking into account the temperature of the ceramic glass plate.

Apparatus and methods are disclosed utilizing selected infrared waveband observations to determine selected profiles of interest. A correlative system is constructed and installed at a processor. Thermal and refractivity profiles and structure in a waveband of interest are extracted from observed infrared spectrum single waveband observations received for processing at the processor by the correlative system. The output provides the selected profiles of interest in the waveband of interest. The apparatus includes an infrared receiver and means for measuring angular displacement of received emissions relative to a horizon. The processor converts received emission into equivalent Planck blackbody temperatures across the observations and correlates structure and vertical distribution of the temperatures to provide thermodynamic and refractivity profiles of interest.

An apparatus for measuring surface temperature of a substrate being illuminated by a pulsed light beam configured to heat the substrate and by a beam of probing light, wherein the heated substrate emits a radiated beam of thermal radiation, wherein the apparatus includes an optical system configured to collect the radiated beam and a reflected beam of probing light propagating in substantially close directions, wherein the collected radiated beam and the collected reflected beam are separately routed to a respective detector via a respective routing element, the respective detectors being configured to measure the intensity of the collected radiated beam and collected reflected beam simultaneously and at the same wavelength, wherein the surface temperature is calculated based on the collected radiated beam and on the collected reflected beam.

In some examples, a method for generating an interactive three-dimensional quantitative thermal heat flow mapping of an environment comprises generating a three-dimensional representation of the environment, the representation comprising multiple surfaces defining respective boundaries of the environment, generating a thermal image representing a surface temperature at multiple points on respective ones of the surfaces of the environment within the three-dimensional representation, determining a measure for an ambient temperature within the environment, determining respective measures for incident radiant temperature of the surfaces, determining respective measures for the emissivity of the surfaces, providing a measure of temperature outside of a surface, calculating, at each of the multiple points, a value for the instantaneous heat flow per unit area using the measures for surface temperature, ambient temperature within the environment and incident radiant temperature of the surfaces, and using the values for the instantaneous heat flow per unit area, and the measure of temperature outside of a surface, calculating respective measures for thermal transmittance at the multiple points.

A cavity blackbody radiation source is provide. A cavity blackbody radiation source comprises a blackbody radiation cavity and a carbon nanotube layer. The blackbody radiation cavity comprises an inner surface. The carbon nanotube layer is located on the inner surface. The carbon nanotube carbon nanotube layer comprises a plurality of carbon nanotubes and a plurality of microporous. A method of making the cavity blackbody radiation source is also provide.

The invention relates to a method and to a device for the in-situ determination of the temperature ϑ of a sample, in particular to a method and to a device for the surface-corrected determination of the temperature ϑ of a sample by means of the band-edge method.

It is provided that, for the in-situ determination of the temperature ϑ of a sample (10) when growing a layer stack (12) in a deposition system, a surface-corrected transmission spectrum T′(λ) is calculated by determining the quotient of the transmission spectrum T(λ) and a correction function K(λ), the correction function K(λ) being calculated from a determined reflection spectrum R(λ). Subsequently, the spectral position of the band-edge λ.sub.BE is determined from the transmission spectrum T′(λ), and the temperature ϑ is determined from the spectral position of the band-edge λ.sub.BE by means of a known dependency ϑ(λ.sub.BE).

A method of measuring spectral emissivity of materials is provided. The method comprises placing material in a controlled chamber and exposing the material to an energy source to heat the material. At least one multi-wavelength pyrometer measures emitted thermal radiation from the material produced by heating by the energy source.

A cold-tunnel system is disclosed for recovery of thermal emissivity of extended targets. The cold-tunnel system is comprised of an infrared camera having a thermal imaging lens; an aperture plate having a hole aligned with the thermal imaging lens; four cold-wall panels assembled in a box pattern as a cold-tunnel assembly to form a cold tunnel; an air-blowing desiccator affixed to each cold-wall panel; an external liquid chiller to chill a reservoir of working fluid; a target under test; and an extended source blackbody reference disposed directly behind the target under test.

A cold-tunnel system is disclosed for recovery of thermal emissivity of extended targets. The cold-tunnel system is comprised of an infrared camera having a thermal imaging lens; an aperture plate having a hole aligned with the thermal imaging lens; four cold-wall panels assembled in a box pattern as a cold-tunnel assembly to form a cold tunnel; an air-blowing desiccator affixed to each cold-wall panel; an external liquid chiller to chill a reservoir of working fluid; a target under test; and an extended source blackbody reference disposed directly behind the target under test.

A burner work measurement system configured to measure work using a burner is provided. The burner work measurement system includes one or more cameras configured to capture the work and a control unit configured to perform computing processing on images captured by the cameras, the control unit is configured to create work data obtained by calculating, based on the images captured by the cameras, at least one of a positional relation between a work object and the burner or flame, a positional relation between the work object and a brazing filler metal, and a positional relation between the burner or the flame and the brazing filler metal.