Various embodiments disclosed herein describe an infrared (IR) imaging system for detecting a gas. The imaging system can include an optical filter that selectively passes light having a wavelength in a range of 1585 nm to 1595 nm while attenuating light at wavelengths above 1600 nm and below 1580 nm. The system can include an optical detector array sensitive to light having a wavelength of 1590 that is positioned rear of the optical filter.

A heating device includes a combustion chamber, a housing in fluid communication with the combustion chamber, a burner disposed in the housing, a blower assembly connected to the housing for directing air into the interior of the housing, a valve assembly connected to the housing for controlling a flow of fuel into the burner, an optical color sensor for sensing a color profile of a surface of the burner, and a control unit configured to control the valve assembly in dependence upon the color profile of the surface of the burner.

Techniques are disclosed for calibrating display devices, such as head-mounted augmented reality (AR) devices. For each of a set of primary color light sources disposed in a unit, measurement points are obtained including chromaticity and luminance values as a function of temperature of the unit and drive currents of the primary color light sources. The measurement points are converted to an XYZ color space to produce XYZ values. For each of a set of target luminances and a set of discrete temperatures, primary luminances are calculated for each of the set of primary color light sources, and the drive currents and the XYZ values are interpolated or extrapolated for each of the primary luminances to obtain calculated currents.

Techniques are disclosed for calibrating display devices, such as head-mounted augmented reality (AR) devices. For each of a set of primary color light sources disposed in a unit, measurement points are obtained including chromaticity and luminance values as a function of temperature of the unit and drive currents of the primary color light sources. The measurement points are converted to an XYZ color space to produce XYZ values. For each of a set of target luminances and a set of discrete temperatures, primary luminances are calculated for each of the set of primary color light sources, and the drive currents and the XYZ values are interpolated or extrapolated for each of the primary luminances to obtain calculated currents.

An information handling system manages operation of an infrared time of flight sensor to provide accurate and timely user presence and absence detection through adjustments of the time of flight sensor detection sensitivity based upon ambient light brightness and color temperature sensed by an ambient light sensor. An integrated sensor hub in a central processing unit disables infrared illumination by the time of flight sensor, senses ambient light conditions with the ambient light sensor, looks up sensitivity settings from a lookup table that associates infrared time of flight sensor sensitivity and ambient light conditions, applies the associated sensitivity at the infrared time of flight sensor and then re-enables infrared illumination to detect end user presence and absence with the infrared time of flight sensor.

An information handling system manages operation of an infrared time of flight sensor to provide accurate and timely user presence and absence detection through adjustments of the time of flight sensor detection sensitivity based upon ambient light brightness and color temperature sensed by an ambient light sensor. An integrated sensor hub in a central processing unit disables infrared illumination by the time of flight sensor, senses ambient light conditions with the ambient light sensor, looks up sensitivity settings from a lookup table that associates infrared time of flight sensor sensitivity and ambient light conditions, applies the associated sensitivity at the infrared time of flight sensor and then re-enables infrared illumination to detect end user presence and absence with the infrared time of flight sensor.

A measurement system is provided for predicting a future status of a refractory lining that is lined over an inner surface of an outer wall of a manufacturing vessel and exposed to an operational cycle during which the refractory lining is exposed to a high-temperature environment for producing a non-metal and the produced non-metal. The system includes one or more laser scanners and a processor. The laser scanners are configured to conduct one or more pre-operational laser scans of the refractory lining prior to the operational cycle to collect data related to pre-operational cycle structural conditions, and one or more post-operational laser scans of the refractory lining after the operational cycle to collect data related to post-operational cycle structural conditions of the refractory lining. The processor is configured to predict future status of the refractory lining after subsequent operational cycles based on the determined exposure impact of the operational cycle.

An optical sensing method and an optical sensor module thereof. The optical sensing method includes obtaining an optical signal by sensing with a first optical sensor and a second optical sensor, respectively. The first optical sensor and the second optical sensor have different optical sensing wavelength ranges. Furthermore, a color temperature determination unit receives the optical signals of the first and second optical sensors and calculates a color temperature value by substituting an equation. In this way, the optical sensing method and its optical sensor module can obtain color temperature calculations with high accuracy and can effectively reduce the system computational complexity.

An optical sensing method and an optical sensor module thereof. The optical sensing method includes obtaining an optical signal by sensing with a first optical sensor and a second optical sensor, respectively. The first optical sensor and the second optical sensor have different optical sensing wavelength ranges. Furthermore, a color temperature determination unit receives the optical signals of the first and second optical sensors and calculates a color temperature value by substituting an equation. In this way, the optical sensing method and its optical sensor module can obtain color temperature calculations with high accuracy and can effectively reduce the system computational complexity.

A combined optical system for determining temperature of the surface of an object or material and its distance with respect to a predetermined reference point associated with the system includes an optical radiation source emitting optical probe radiation at a predetermined wavelength or in a predetermined wavelength range, a source control unit controlling switching of the source from an operative condition, in which it emits optical probe radiation, to an inoperative condition, in which it does not emit optical probe radiation, optical detectors acquiring scattered optical radiation and thermally emitted optical radiation from the surface of the object or material, and a processing unit determining the distance of the surface of the object/material based on scattered optical probe radiation when the source is operative, and the local temperature of the surface of the object/material on the basis of thermally emitted optical radiation when the source is inoperative.