This work presents a Fourier transform method for the sequence of holograms
recorded at different time points. The possibility of measuring the deformations of composite
materials during heating is shown using low-power laser radiation. The use of holographic
methods to solve this problem will significantly increase the storage life of data with the same or
higher data storage density in the future. In previous works, the use of computer synthesis
methods of holographic structures has been proposed as an alternative to the classical two-beam
method of recording holograms.
This work presents a Fourier transform method for the sequence of holograms
recorded at different time points. The possibility of measuring the deformations of composite
materials during heating is shown using low-power laser radiation. The use of holographic
methods to solve this problem will significantly increase the storage life of data with the same or
higher data storage density in the future. In previous works, the use of computer synthesis
methods of holographic structures has been proposed as an alternative to the classical two-beam
method of recording holograms.
| № | Имя автора | Должность | Наименование организации |
|---|---|---|---|
| 1 | Akbarova N.. | teacher | TSTU |
| 2 | Abdulkhaeva D.. | researcher | TSTU |
| № | Название ссылки |
|---|---|
| 1 | J.W. Goodman., R.W. Lawrence. Digital image formation from electronically detected holograms. “Applied physics letters”, American Institute of Physics, 1967. 77 |
| 2 | M. A. Kronrod. “Reconstruction of a Hologram with a Computer”, Soviet Physics Technical Physics, 1972. 333. |
| 3 | U. Schnars., W. Jüptner. Direct recording of holograms by a CCD target and numerical reconstruction. “Applied optics”, 1994. 179. |
| 4 | G.A. Mills., I. Yamaguchi. Phase-shifting digital holography. “Digital holography and threedimensional display”, 2005. 1216. |
| 5 | J.C. Wyant. Phase-shifting holographic interferometry. “Optics and Photonics News”, 2003. 36. |
| 6 | U. Schnars. Direct phase determination in hologram interferometry with use of digitally recorded holograms. “Optica Publishing Group”, 1994. 2011. |
| 7 | E. Cuche. Tomographie optique par une technique d'holographie numérique en faible cohérence Optical tomography by means of a numerical low-coherence holographic technique. “Journal of optics Lett”, 1999. 291. |
| 8 | M. Liebling. Autofocus for digital Fresnel holograms by use of a Fresnelet-sparsity criterion. “Optica publishing group”, 2004. 367. |
| 9 | E. Cuche. Digital holography for quantitative phase CODITgSl imaging. “Optics Letters”, 1999. 6994. |
| 10 | F. Dubois. Pattern recognition with a digital holographic microscope working in partially coherent illumination. “Applied Optics”, 2002. 4108. |
| 11 | D. Carl. Parameter-optimized digital holographic microscope for high-resolution living-cell analysis. “Applied Optics”, 2004. 6536. |
| 12 | G. Coppola. Extended focused image in microscopy by digital holography. “Optica publishing group”, 2004. 529. |
| 13 | L. Yu., M.K. Kim. Wavelength scanning digital interference holography for variable tomographic scanning. “Optics express”, 2005. 5621. |
| 14 | F. Charrière. Cell refractive index tomography by digital holographic microscopy. “Optics Letters”, 2006. 178. |
| 15 | B. Javidi. Three-dimensional image fusion by use of multiwavelength digital holography. “Optics letters”, 2005. 144. |
| 16 | A. Stadelmaier., J.H. Massig. Compensation of lens aberrations in digital holography. “Optics Letters”, 2000. 1630. |
| 17 | T. Colomb. Automatic procedure for aberration compensation in digital holographic microscopy and applications to specimen shape compensation. “Applied Optics”, 2006. 851. |
| 18 | L.H. Ma. Numerical reconstruction of digital holograms for three-dimensional shape measurement. “Journal of optics”, 2004. 396. |
| 19 | J. Müller. Characterization of spatial particle distributions in a spray-forming process using digital holography. “Measurement science and technology”, 2004. 706. |
| 20 | G. Situ., J. Zhang. Multiple-image encryption by wavelength multiplexing. “Optics Letters”, 2005. 1306. |
| 21 | M. Sebesta, M. Gustafsson. Object characterization with refractometric digital fourier holography. “Optics Letters”, 2005. 471 |
| 22 | M.Y. Gusev., A.A. Voronin., V.S. Gurevich., A.M. Isayev., I.V. Alekseyenko. Modern methods of registration, restoration and presentation of results in digital holographic interferometry. Sat. Proceedings of the 7th International Scientific and Practical Conference. “Holography science and practice” 2010. 83. |
| 23 | D.N. Borza. Mechanical vibration measurement by high-resolution time-averaged digital holography. “Measurement science and technology”, 2005. 1853 |
| 24 | V.S. Gurevich., V.I. Redkorechev., A.M. Isayev., V.Y. Gaponov., M.Y. Gusev., I.V. Alekseyenko., V.A. Melnikov., V.A. Kalinin. Application of holographic interferometry for measuring interference fields in the nanometer range. Proceedings and official materials of the scientific and practical conference Holography in Russia for application, science and practice. “5th International Conference Holography Expo” 2008. 100. |
| 25 | R.A. Muminov., Z.T. Azamatov., N.A. Akbarova., V.I. Redkorechev., O.F. Tukfatullin., I.A. Khusainov. Effect of holographic coatings on the efficiency of silicon photoconverters. “Applied solar energy”, 2014. 156. |