Investigation of brightness correlation regularities in infrared and visible spectral ranges
DOI:
https://doi.org/10.3103/S0735272707040024Abstract
The new analytical relationships establish the dependence of correlation characteristics (coefficients of correlation and of linear regression) of brightness fields in IR and visible ranges of wavelengths on optico-physical parameters of the surveyed surface, natural heat exchange conditions, and spectral intervals of the surveillance devices. The paper presents results of calculations of the daytime behavior of correlation characteristics of brightness for landscape fragments with flat relief and for technogenic three-dimensional objects.References
S. N. Gowerd, G. D. Cruickshanks, and S. Hope, Remote Sens. Environ. 18, 137 (1985).
Zhiyong Li, Zhi-Hui Liu, Weiping Yang, “Method of visual-infrared sensor fusion for target recognition,” in Proc. SPIE, Signal Processing, Sensor Fusion and Target Recognition (1997), Vol. 3068, pp. 591–596.
E. Agassi and N. Ben-Josef, Opt. Eng. 36, No. 3, 862 (1997).
N. I. Pavlov, V. A. Shevoldin, Yu. A. Shuba, and G. I. Yasinskii, Opticheskii Zhurnal 65(12), 113 (1998).
D. Schribner, “Infrared color vision: separating objects from backgrounds,” in Proc. SPIE (1998), Vol. 3379, pp. 2–13.
N. I. Pavlov and G. I. Yasinskii, Izv. VUZ. Radioelektronika 45(3), 25 (2002).
N. I. Pavlov, Optics Communications 161, 193 (1999).
N. I. Pavlov, Opticheskii Zhurnal 71(4), 65 (2004).
V. Ye. Gmurman, Probability Theory and Mathematical Statistics, 4th ed. (Vysshaya Shkola, Moscow, 1972) [in Russian].
N. I. Pavlov, A. S. Sakyan, N. V. Sidorovskii, et al., Opticheskii Zhurnal 67(10), 13 (2000).
