Temperature measurement system for furnaces

What is claimed is: 1. A method for measuring furnace temperatures, the method comprising: obtaining radiance measurements from a plurality of regions of interest (ROls) of a furnace, using a plurality of thermal imaging cameras; measuring a surface temperature of the furnace using a radiance measurement obtained from an ROI selected from the plurality of ROIs, comprising: determining an effective background radiance affecting the selected ROI, using radiance measurements obtained from ROIs different from the selected ROI; obtaining a compensated radiance by removing the effective background radiance from the radiance measurement obtained from the selected ROI; correcting the compensated radiance for an atmospheric absorption and an atmospheric emission; and converting the corrected compensated radiance to the measured surface temperature of the furnace, wherein the correction for the atmospheric absorption is determined based on characteristics of the furnace atmosphere that is traversed for the radiance measurement of the selected ROI, the characteristics of the furnace atmosphere comprising at least one selected from the group consisting of: the atmospheric distance traversed between the ROI and the one or more thermal imaging cameras; a linear relationship between distance and atmospheric absorption; and a level of water vapor in the furnace atmosphere, the correction for the atmospheric emission is determined based on characteristics of a flame front that is traversed for the radiance measurement of the selected ROI, the characteristics of the flame front comprising at least one selected from the group consisting of: a length of the traversed flame front; a type of fuel fed to a burner generating the flame front; and a fuel flow to the burner generating the flame front, and the correction of the atmospheric emission is dynamically updated based on the fuel flow to the burner. 2. The method of claim 1 , wherein each of the plurality of ROIs is a surface region of the furnace on one selected from a group consisting of a reformer tube, a wall, a floor, a ceiling and the flame front. 3. The method of claim 1 , wherein the radiance measurement obtained from the selected ROI is obtained from a plurality of pixels in the ROI, averaged over at least one selected from the group consisting of space and time. 4. The method of claim 1 , wherein the radiance measurement obtained from the selected ROI is obtained from a single pixel in the ROI. 5. The method of claim 1 , wherein a thermal imaging camera of a plurality of thermal imaging cameras obtains radiance measurements from multiple ROIs that are a subset of the plurality of ROIs. 6. The method of claim 1 , wherein the radiance measurements are concurrently obtained; and wherein the surface temperature is measured in real-time. 7. The method of claim 1 , further comprising: adjusting the measured surface temperature to match a reference surface temperature. 8. The method of claim 1 , wherein determining the effective background radiance for the selected ROI comprises: selecting surrounding surfaces that add reflected radiance to the radiance measurement obtained from the selected ROI, wherein each of the surrounding surfaces comprises at least one ROI of the plurality of ROIs; determining mean radiances of the surrounding surfaces, based on radiance measurements from the at least one ROI on each of the surrounding surfaces; and determining a weighted average of the mean radiances of the surrounding surfaces, wherein the weighted average is the effective background radiance. 9. The method of claim 8 , wherein the weighted average is determined based on geometric view factors of the surrounding surfaces. 10. The method of claim 1 , further comprising: correcting the radiance measurement obtained from the selected ROI for an emissivity of the selected ROI. 11. The method of claim 10 , wherein the emissivity is determined through comparison of the radiance measurement obtained from the selected ROI with a radiance measurement obtained from a reference body with a known emissivity, wherein a temperature of the reference body with the known emissivity is identical to a temperature of the ROI. 12. A non-transitory computer readable medium (CRM) storing instructions for measuring furnace temperatures, the instructions comprising functionality for: obtaining radiance measurements from a plurality of regions of interest (ROIs) of a furnace, using a plurality of thermal imaging cameras; measuring a surface temperature of the furnace using a radiance measurement obtained from an ROI selected from the plurality of ROIs, comprising: determining an effective background radiance affecting the selected ROI, using radiance measurements obtained from ROIs different from the selected ROI; obtaining a compensated radiance by removing the effective background radiance from the radiance measurement obtained from the selected ROI; correcting the compensated radiance for an atmospheric absorption and an atmospheric emission; and converting the corrected compensated radiance to the measured surface temperature of the furnace, wherein the correction for the atmospheric absorption is determined based on characteristics of the furnace atmosphere that is traversed for the radiance measurement of the selected ROI, the characteristics of the furnace atmosphere comprising at least one selected from the group consisting of: the atmospheric distance traversed between the ROI and the one or more thermal imaging cameras; a linear relationship between distance and atmospheric absorption; and a level of water vapor in the furnace atmosphere, the correction for the atmospheric emission is determined based on characteristics of a flame front that is traversed for the radiance measurement of the selected ROI, the characteristics of the flame front comprising at least one selected from the group consisting of: a length of the traversed flame front; a type of fuel fed to a burner generating the flame front; and a fuel flow to the burner generating the flame front, and the correction of the atmospheric emission is dynamically updated based on the fuel flow to the burner. 13. The non-transitory CRM of claim 12 , wherein the radiance measurements are concurrently obtained; and wherein the surface temperature is measured in real-time. 14. A system for measuring furnace temperatures, comprising: a plurality of thermal imaging cameras; and a processing unit configured to: obtain radiance measurements from a plurality of regions of interest (ROIs) of a furnace, using a plurality of thermal imaging cameras; measure a surface temperature of the furnace using a radiance measurement obtained from an ROI selected from the plurality of ROIs, comprising: determining an effective background radiance affecting the selected ROI, using radiance measurements obtained from ROIs different from the selected ROI; obtaining a compensated radiance by removing the effective background radiance from the radiance measurement obtained from the selected ROI; correcting the compensated radiance for an atmospheric absorption and an atmospheric emission; and converting the corrected compensated radiance to the measured surface temperature of the furnace, wherein the correction for the atmospheric absorption is determined based on characteristics of the furnace atmosphere that is traversed for the radiance measurement of the selected ROI, the characteristics of the furnace atmosphere comprising at least one selected from the group consisting of: the atmospheric distance traversed b