A computer-implemented method for indoor-outdoor detection by an electronic device includes: receiving, from an ambient light sensor in the electronic device, light intensity data. The electronic device determines an indoor-outdoor feature indicator based on the light intensity data. The electronic device determines whether the electronic device is in an indoor environment or an outdoor environment based on the indoor-outdoor feature indicator.

A computer-implemented method for indoor-outdoor detection by an electronic device includes: receiving, from an ambient light sensor in the electronic device, light intensity data. The electronic device determines an indoor-outdoor feature indicator based on the light intensity data. The electronic device determines whether the electronic device is in an indoor environment or an outdoor environment based on the indoor-outdoor feature indicator.

Process for measuring emission for a flame in an open combustion environment. A captured image is received from each of a plurality of image capturing devices in at least one selected spectral band. Each of the plurality of image capturing devices is trained on the flame from the combustion process from a different perspective view angle. A spectral path length of the flame in the at least one spectral band is estimated from the captured images. Emitted radiance of the flame is estimated from the captured images, and a temperature of the flame is estimated from the estimated emitted radiance. A gas species concentration of the flame is estimated from the temperature of the flame and the spectral path length of the flame. Emission for the flame is measured from the gas species concentration.

Systems and methods disclosed herein use a multi-color pyrometer configured to determine a first temperature in a high temperature range and a single-color pyrometer configured to determine second temperature in a low temperature range. The system uses information gained from determination of the first temperature in the high temperature range to facilitate later determining the second temperature in the low temperature range. The first temperature in the high temperature range and the second temperature in the low temperature range are used to monitor and control different engine operations that occur at different times.

For generating a diagnosis, a method irradiates a product surface of a product with infrared light, the product surface including a stress sensitive pigment. The method detects an activation of the stress sensitive pigment as a color change at an infrared visible activation location. The method generates a diagnosis based on the activation.

For generating a diagnosis, a method irradiates a product surface of a product with infrared light, the product surface including a stress sensitive pigment. The method detects an activation of the stress sensitive pigment as a color change at an infrared visible activation location. The method generates a diagnosis based on the activation.

An oxide layer thickness measurement device according to the present invention stores, for each of layer thickness measurement sub-ranges constituting a layer thickness measurement range, layer thickness conversion information representing a correlation between a layer thickness and an emitting light luminance where a ratio of a change in the emitting light luminance to a change in the layer thickness in the layer thickness measurement sub-range falls within a set extent. The device includes a plurality of emitting light luminance measurement parts for measuring emitting light luminances of a surface of a steel sheet at respective measurement wavelengths different from each other. Calculated in connection with each of the emitting light luminances of the surface of the steel sheet measured by the emitting light luminance measurement parts are the layer thickness corresponding to the measured emitting light luminance and a ratio at the layer thickness by using the layer thickness conversion information corresponding to each of the emitting light luminance measurement parts. The calculated layer thickness is extracted as a candidate value for an actual thickness layer when the calculated ratio is within the set extent assigned for the layer thickness conversion information.

A calibration method for a temperature measurement device, the method including: measuring dispersed spectrum information of radiation energy from a black body furnace and dark current data with a first temperature measurement device and with a second temperature measurement device that is to be swapped with the first temperature measurement device, at each of a plurality of different temperatures; generating, using information thus measured, a second temperature measurement value to be measured by a second contact thermometer included in the second temperature measurement device, and a second dispersed spectrum information corresponding to the second temperature measurement value, from a first temperature measurement value measured by a first contact thermometer included in the first temperature measurement device and a first dispersed spectrum information corresponding to the first temperature measurement value; and determining, using the information thus generated, the basis spectrum and the calibration line for the second temperature measurement device.

A calibration method for a temperature measurement device, the method including: measuring dispersed spectrum information of radiation energy from a black body furnace and dark current data with a first temperature measurement device and with a second temperature measurement device that is to be swapped with the first temperature measurement device, at each of a plurality of different temperatures; generating, using information thus measured, a second temperature measurement value to be measured by a second contact thermometer included in the second temperature measurement device, and a second dispersed spectrum information corresponding to the second temperature measurement value, from a first temperature measurement value measured by a first contact thermometer included in the first temperature measurement device and a first dispersed spectrum information corresponding to the first temperature measurement value; and determining, using the information thus generated, the basis spectrum and the calibration line for the second temperature measurement device.

An oxide layer thickness measurement device according to the present invention stores, for each of layer thickness measurement sub-ranges constituting a layer thickness measurement range, layer thickness conversion information representing a correlation between a layer thickness and an emitting light luminance where a ratio of a change in the emitting light luminance to a change in the layer thickness in the layer thickness measurement sub-range falls within a set extent. The device includes a plurality of emitting light luminance measurement parts for measuring emitting light luminances of a surface of a steel sheet at respective measurement wavelengths different from each other. Calculated in connection with each of the emitting light luminances of the surface of the steel sheet measured by the emitting light luminance measurement parts are the layer thickness corresponding to the measured emitting light luminance and a ratio at the layer thickness by using the layer thickness conversion information corresponding to each of the emitting light luminance measurement parts. The calculated layer thickness is extracted as a candidate value for an actual thickness layer when the calculated ratio is within the set extent assigned for the layer thickness conversion information.