The Imaging Optical Setup in the Spectral Radiance Facility

Zhi Feng Wu; Cai Hong Dai; Bo Huang; Jia Lin Yu; Hui Quan Ouyang

doi:10.4028/www.scientific.net/AMR.571.406

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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 571The Imaging Optical Setup in the Spectral Radiance...

The Imaging Optical Setup in the Spectral Radiance Facility

Abstract:

The spectral radiance of the lamps are calibrated in the experiment. Different from the spectral irradiance mode, the spectral radiance involves mirror imaging optics and some instructions must be followed strictly. During the experiment, several different imaging parameters in the spectral radiance transfer were investigated, such as the imaging area, the width of the entrance slits, the solid angle, and the object distance of the imaging optics.

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Periodical:

Advanced Materials Research (Volume 571)

Pages:

406-410

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.571.406

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Online since:

September 2012

Authors:

Zhi Feng Wu, Cai Hong Dai, Bo Huang, Jia Lin Yu, Hui Quan Ouyang

Keywords:

Solid Angle, Spectral Radiance

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References

[1] B. Khlevnoy, V. Sapritsky, B. Rougie, C. Gibson, H. Yoon, A. Gaertner, D. Taubert, and J. Hartmann, CCPR-S1 Supplementary Comparison for Spectral Radiance in the range of 220 nm to 2500 nm, Metrologia, vol. 46, 2009, pp. S174-S180, doi: 10. 1088/0026-1394/46/4/S08.

DOI: 10.1088/0026-1394/46/4/s08

Google Scholar

[2] R. Friedrich and J. Fischer. New Spectral Radiance Scale from 220 nm to 2500 nm, Metrologica, vol. 37, 2000, pp.539-542, doi: 10. 1088/0026-1394/37/5/43.

DOI: 10.1088/0026-1394/37/5/43

Google Scholar

[3] R. D. Saunders, C. E. Gibson, K. D. Mielenz, V. I. Sapritsky, K. A. Sudarev, B. B. Khlevnoy, S. N. Mekhonstev, and G. D. Harchenko, Results of a NIST/VNIIOFI comparison of spectral radiance measurement, Metrologica, vol. 32, 1995, pp.449-453.

DOI: 10.1088/0026-1394/32/6/9

Google Scholar

[4] A. A. Gaertner, and C. K. Ma, Experimental investigation on the establishment of a spectral-radiance scale based on a copper-freezing-point blackbody radiator, Metrologica, vol. 37, 2000, pp.535-538, doi: 10. 1088/0026-1394/37/5/42.

DOI: 10.1088/0026-1394/37/5/42

Google Scholar

[5] S. W. Brown, G. P. Eppeldauer, and K. R. Lykke, NIST Facility for Spectral Irradiance and Radiance Responsivity Calibrations with Uniform Sources, Metrologia, vol, 37, 2000, pp.579-582, doi: 10. 1088/0026-1394/37/5/53.

DOI: 10.1088/0026-1394/37/5/53

Google Scholar

[6] N. Fox, A. Kaiser-Weiss, W. Schmutz, K. Thome, D. Young, B. Wielicki, R. Winkler, and E. Woolliams, Accurate Radiometry from Space: an accurate Tool for Climate Studies, Phil. Trans. R. Soc. A, vol. 369, 2011, pp.4028-4063.

DOI: 10.1098/rsta.2011.0246

Google Scholar