An indirect skin emissivity measurement in the infrared thermal range through reflection of a CO2 laser beam

Villaseñor-Mora, C.; Sánchez-Marin, F.J.; Calixto-Carrera, S.

Services on Demand

Journal

Article

Indicators

Cited by SciELO
Access statistics

Revista mexicana de física

Print version ISSN 0035-001X

Rev. mex. fis. vol.55 n.5 México Oct. 2009

Investigación

An indirect skin emissivity measurement in the infrared thermal range through reflection of a CO₂ laser beam

C. Villaseñor–Mora, F.J. Sánchez–Marin, and S. Calixto–Carrera

Centro de Investigaciones en óptica, Loma del Bosque 115, Lomas del Campestre, León, Gto., México 37150, Phone: 52 477 4414200, Fax: 52 477 4414209

Recibido el 7 de mayo de 2009
Aceptado el 25 de septiembre de 2009

Abstract

An indirect procedure to measure human skin emissivity is proposed. This procedure uses a 10.6 µm CO₂ laser, to project a controlled energy on the skin, and a power meter to measure the projected, reflected, emitted and background energies. To eliminate the effects of background radiation, two power measurements are taken: one of the skin and background emission and another that includes the skin emission itself, the background radiation, as well as the reflection of the laser beam by the skin. Those two measurements are subtracted to obtain the reflected energy and, with this, the corresponding reflectivity of the skin. With such subtraction, background and other sources of noise are eliminated, and using the Kirchhoff law the emissivity is calculated. The emissivity values obtained with this procedure were corroborated using a theoretical blackbody. Both methods give practically the same values, which validates our procedure. In addition, our values are in accordance with those previously reported by other researchers, but our procedure is simpler, faster and innocuous. An additional contribution of this work is the analysis of the way the skin reflects the infrared radiation, in the mid range. It was found that the reflection of the skin is more specular than Lambertian, for the wavelength that was used in this work.

Keywords: Skin emissivity; skin reflection; skin reflectivity; emissivity without blackbody; Lambertian surfaces.

Resumen

En el presente trabajo se propone un procedimiento indirecto para medir la emisividad de la piel humana. Este procedimiento usa un láser de CO₂ de 10.6 µm para proyectar una energía controlada sobre la piel, y un radiómetro para medir las energías proyectadas, reflejadas, emitidas y de fondo. Para eliminar la influencia de la radiación de fondo, se toman dos lecturas con el radiómetro: una que incluye la energía de la piel y la emisión de fondo y otra inmediatamente después que incluye la energía de la piel, la radiación de fondo, y la reflexión de la piel. Se obtiene la diferencia de esas dos mediciones para obtener la energía reflejada y, con esto, la reflectividad correspondiente de la piel. Al obtener la diferencia, la radiación de fondo y otras fuentes de ruido se eliminan, y usando la ley de Kirchhoff la emisividad es calculada. Los valores de emisividad obtenidos con este procedimiento fueron corroborados con el método directo usando un cuerpo negro teórico. Ambos métodos arrojan prácticamente los mismos valores, lo cual valida nuestro procedimiento. Adicionalmente nuestros resultados están acordes con aquellos obtenidos por otros investigadores, pero nuestro procedimiento es más simple, más rápido e inocuo. Una aportación adicional de este trabajo, es el análisis de la forma en que la piel refleja la radiación infrarroja en el rango medio. Se encontró que la reflexión de piel en esta longitud de onda es mas especular que Lambertiana.

Descriptores: Emisividad de la piel; energía de la piel; reflectividad de la piel; emisividad sin cuerpo negro; superficies Lambertianas.

PACS: 78.20.Ci; 06.20.Jr; 92C50

DESCARGAR ARTÍCULO EN FORMATO PDF

References

1. H.L. Hackforth, Infrared Radiation (McGraw Hill, New York,1960). [ Links ]

2. R.P. Madding, Proc. SPIE 3700 (Thermosense XXI) (1999) 393. [ Links ]

3. A. Kribus, I. Vishnevetsky, E. Rotenberg, and D. Yakir, Applied Optics 42 (2003) 1839. [ Links ]

4. A. Mazikowski and K. Chrzanowski, Infrared Physics & Technology 44 (2003) 9. [ Links ]

5. C. Yang, D. Zhao, and J. Dai, IEEE Transactions on instrumentation and measurement 54 (2005) 2549. [ Links ]

6. D.J. Watmoungh and R. Oliver, Phys. Med. Biol. 14 (1969)201. [ Links ]

7. J. Steketee, Phys. Med Biol. 18 (1973) 686. [ Links ]

8. W.L. Wolfe, G.L. Zissis, The Infrared Handbook, Office Naval Research (Department of the Navy, Washington, DC, 1978). [ Links ]

9. Wolfe, WL in: Methods of Experimental Physics 26 (Ed.) by D. Malacara, (Academic Press, 1988). [ Links ]

10. M. Sirouxy, E. Tang–Kworz, and S. Matte, Meas. Sci. Technol. 9 (1998) 1956. [ Links ]

11. D. Especel and S. Mattei, Infrared Physics & Technology 37 (1996)777. [ Links ]

12. L. Palchetti, G. Bianchini, and F. Castagnoli, Infrared Physics & Technology 51 (2008) 207. [ Links ]

13. V. I. Sapritsky et al., Applied Optics 36 (1997) 5403. [ Links ]

14. E. Lindermeir, P. Haschberger, V. Tank, and H. Dietl, Applied Optics 31 (1992)4527. [ Links ]

15. T. Togawa, Clin. Phys. Physiol. Meas. 10 (1989) 39.1 [ Links ]

16. T. Togawa and H. Saito, Annual International Conference of the IEEE Engineering in Medicine and Biology Society 13 (1991) 1734. 4 [ Links ]

17. K. Yoshimori, S. Tamba, and R. Yokoyama, Applied Optics 41 (2002) 4937. [ Links ]

18. P.P. Woskov, K. Hadidi, S.K. Sundaram, and W.E. Daniel, IEEE Infrared and Millimeter Waves (Conference Digest. Twenty Seventh International Conference on 2002). 211. [ Links ]

19. A. Hunter, B. Adams, and R. Ramanujam, IEEE 11^th International Conference on Advanced Thermal Processing Of semiconductors (2003) 85. [ Links ]

20. M. Marchetti et al., Thermography 1 (2004) I.2.1. [ Links ]

21. B.F. Jones and P. Plassmann, IEEE Engineering in Medicine and Biology 21 (2002) 41. [ Links ]

22. T. Togawa and H. Saito, Physiol. Meas. 15 (1994) 291. [ Links ]

23. B.F. Jones, IEEE transactions in medical imaging 17 (1998) 1019. [ Links ]

24. S. Bornmyr, H. Svensson, B. Lilja, and G. Sundkvist, Clinical physiology 17 (1997)71. [ Links ]

25. R. Magjarevic and J.H. Nagel, Thermographic analysis of short and long term modifications due to the application of tattoos and body piercing, IFMBE Proceedings, World Congress on Medical Physics and Biomedical Engineering (2006, Springer Berlin Heidelberg, 2007) p. 2468. [ Links ]

26. G.R. Ivanitsky, E.P Khizhnyak, A.A. Deev, and L.N. Khizhnyak, Doklady Biochemistry and Biophysics 407 (2006) 59. [ Links ]

27. J.D. Hardy and C. Muschenheim, The Journal of Clinical Investigation 13 (1934) 817. [ Links ]

28. R.W. Boyd, Radiometry and the Detection of Optical Radiation (John Wiley and Sons, New York, 1983). [ Links ]

29. D.J. Watmough and R. Oliver, Nature 219 (1968) 622. [ Links ]

30. W.K. Pratt, Digital Image Processing (John Wiley & Sons, New York, 1978). [ Links ]