Indexing
All Issues
Submission
Author Guidelines
Reviewers
Editorial Members
Publication Fee
Vol.5 , No. 1, Publication Date: Feb. 12, 2018, Page: 1-4
 was performed and following photographic recording, i.e. photographic image imposition. As a result was obtained a contrast inverted image of the object without spatial filtration or phase contrast method by the diffraction on the superimposed to each other holographic phase grating and the phase image of the object. The sequentially holographic and photographic recording at the same area of the dichromate gelatin layer (DCG) was performed for this.&picture=http://www.aascit.org/aascit/decorators/img/journal/916.jpg)
| [1] | Zurab Vakhtang Wardosanidze, Research Department of Radiophysics and Electronic Systems Modeling, Legal Entity of Public Law (LEPL) Ilia Vekua Sukhumi Institute of Physics and Technology, Tbilisi, Georgia; Department of Light Controlled Anisotropic Systems, Vladimir Chavchanidze Institute of Cybernetics of the Georgian Technical University, Tbilisi, Georgia. |
| [2] | Vladimir Andro Kuchukhidze, Department of Management, Legal Entity of Public Law (LEPL) Ilia Vekua Sukhumi Institute of Physics and Technology, Tbilisi, Georgia. |
| [3] | Giorgi Levan Archuadze, Research Department of Radiophysics and Electronic Systems Modeling, Legal Entity of Public Law (LEPL) Ilia Vekua Sukhumi Institute of Physics and Technology, Tbilisi, Georgia. |
| [4] | Anzor Georgi Inalishvili, Production Department, Legal Entity of Public Law (LEPL) Ilia Vekua Sukhumi Institute of Physics and Technology, Tbilisi, Georgia. |
A complex experiment was carried out for the first time by combining holographic and photographic recording on the registering medium. The aim of the work was the verification of the relevant assumption and in general observation of influence of additional modulation on the diffraction characteristics of the holographic structure. For the beginning the recording of the elementary hologram (diffraction grating) was performed and following photographic recording, i.e. photographic image imposition. As a result was obtained a contrast inverted image of the object without spatial filtration or phase contrast method by the diffraction on the superimposed to each other holographic phase grating and the phase image of the object. The sequentially holographic and photographic recording at the same area of the dichromate gelatin layer (DCG) was performed for this.
Keywords
Phase Contrast, Spatial Filtration, Phase Image, Amplitude Image, Photography, Holography
Reference
| [01] | M. Born, E. Wolf, Principles of Optics, Pergamon press, New York, (1964). |
| [02] | R. W. Ditchburn, “Light”, 3rd ed., Academic Press, New York (1976). |
| [03] | J. W. Goodman, Introduction to Fourier Optics, McGrew-Hill, New York, (1968). |
| [04] | Xia J., Dunn D., Poon T.-C., Banerjee P. P., Image edge enhancement by Bragg diffraction, Opt. Commun., v. 128, №1, pp. 1-7, (1996). |
| [05] | Yunxin Wang, ShaGuo, Dayong Wang, Qiaowen Lin, Lu Rong, Jie, Zhao, Resolution enhancement phase-contrast imaging by microsphere digital holography, Optics Communications, Vol. 366, pp. 81-87, 2016. |
| [06] | Jean-Michel Desse, Pascal Picart, and François Olchewsky, Quantitative phase imaging in flows with high resolution holographic diffraction grating, Optics Express, Vol. 23, Issue 18, pp. 23726-23737, 2015. |
| [07] | Tatiana Latychevskaia, Hans-Werner Fink, Reconstruction of purely absorbing, absorbing and phase-shifting, and strong phase-shifting objects from their single-shot in-line holograms, Applied Optics, Vol. 54, Issue 13, pp. 3925-3932 (2015). |
| [08] | C. Falldorf, M. Agour, and R. B. Bergmann, “Digital holography and quantitative phase contrast imaging usingcomputational shear interferometry,” Opt. Eng. 54 (2), 024110 (2015). |
| [09] | Sh. D. Kakichashvili, Z. V. Vardosanidze, D. V. Leselidze, Spectrally nonselective dichromated-gelatin holographic mirrors, Sov. Tech. Phys. Lett, vol. 14, No. 4, pp. 268-270, (1988). |
| [10] | C. E. K. Mees and T. H. James, “The theory of the photographic process”, 3rd edition, New York: Macmillan, p. 591, (1966). |
| [11] | H. Lin, “Hologram Formation In The Hardened Dichromate Gelatin Films”, Appl. Opt., vol. 8, Issue 5, 963-966, (1969). |
| [12] | T. D. Ebralidze, N. A. Ebralidze, M. A. Bazadze, “Weigert’s effect Mechanism Observed In Dyes”, Appl. Opt., vol. 41, No. 1, 78-79, (2002). |
| [13] | I. D. Shatalin, "To the Mechanisms of Photoanisotropy In Photochemical Trans-Cisisomerisation", Optica I Spectr (Optics and Spectr.)., vol. 66, No. 2, 362-364 (1989), (Russian). |
| [14] | Z. V. Wardosanidze, “On more possible mechanism of Weigert’s effect in azo-dye-colored materials”, Applied Optics, vol. 45, Issue 3, 438-444, (2006). |
| [15] | Z. V. Wardosanidze, Polarization photography at the partial polarization of the light fluxes (Photopolarimetry), Sov. Tech. Phys. Letters, v. 18, issue 2, pp. 52-56, (1992). |
| [16] | Z. V. Wardosanidze, Holographic recording in the general case of linear polarization, Optical Engineering, Volume 45, Issue 8, pp. 085801-085807, (2006). |
