pp. 1945-1959 | Article Number: iejme.2016.174
Published Online: September 01, 2016
Article Views: 110 | Article Download: 102
In order to determine resolving power of electronic and optical devices and photo materials, first and foremost interference methods are considered to be used. For further development of the transmission of television systems with high-resolution there have been considered use of the following ranks of instruments: laser interference rezolvometer dissector, the laser polarization interferometer of longitudinal shear and acoustic and optical correlator. Authors mark the main advantages of LIR that works according to the scheme of polarization interferometer compared to LIR that works according the scheme based on the projective technique. Interference method gives much greater contrast. This proves that in the projection method with an increase in spatial frequency contrast of the test pattern falls and the results obtained by this method are be recalculated with taking into account dependence of ratio of transmission contrast focusing optics on the spatial frequency.
Keywords: Bifocal lens; laser beam; resolvometer; interferometer; acoustic and optical correlator
Akhmanov, S. А. (2004) Physics optics. In S.A. Akhmanov and S.Yu. Nysin (Eds.). Moscow: Moscow State University. 407p.
Bass, M. & Decusatis, C. (2010) Design, Fabrication and Testing, Sources and Third Edition. New York: The McGraw-Hill. 1264p.
Batyrakov, A. S. (1981) Laser measurement systems. Moscow: Radio and Telecom. 355p.
Beuth, T. (2015) Revision of an Optical Engineering Lecture Based on Students' Evaluation of University Teaching. International Journal of Information and Education Technology, 5(12), 890-902.
Bretenaker, F. (2015) Laser: 50 Years of Discoveries. In F. Bretenaker and N. Treps (Eds.). Stanford: Stanford University. 185p.
Bykov, V. P. (2006) Laser electrodynamics and interaction of laser radiation with the matter. Moscow: Fizmatlit. 384p.
Chang, W. S. (2005) Principles of lasers and optics. Cambridge: Cambridge University Press, 262 p.
Devaux, F., Huignard, J. P., & Ramaz, F. (2014) Modelization and optimized speckle detection scheme in photorefractive self-referenced acousto-optic imaging. Optics express, 22(9), 10682-10692.
Ersoy, O. K. (2006) Diffraction, Fourier optics and imaging. Wiley. 413p.
Fedorov F. I. (1976) Reflection and Deflection of the light by transparent crystals. Minsk:Science. 276p.
Girard, A. (1960) Nouveaux dispostitifs de spectrascope o grande luminosite. Optica Acta, 7, 817-825.
Karmakar, B., & Mandal, S. (2015) Glass development and production at CSIR-CGCRI for optical applications: some success stories. Science and Culture, 81, 327-336.
Kim, E. (2014) Power profiles measured on NIMO TR1504: repeatability and effects of lens decentration for single vision, bifocal and multifocal contact lenses. Investigative Ophthalmology & Visual Science, 55(13), 6072-6072.
Koliteevskyy, P. Ye. (2006) Wave optics. Moscow: Deer. 480p.
Makushev, A. A (2000). Basis of crystal optics and the rock-forming mineral. Moscow: Scientific world, 316 p.
Meschede, D. (2004) Optics, Light and Lasers. New Jersey: Wiley. 345p.
Rosenfield, M. (2016) Computer vision syndrome. Optometry, 17(1), 1-10.
Toma, T. (2014) Development of a household high-definition video transmission system based on ballpoint-pen technology. Synthesiology, 7(2), 118-128.
Vasavada, A. R. (2014) Technology and Intraocular Lenses to Enhance Cataract Surgery Outcomes—Annual Review. The Asia-Pacific Journal of Ophthalmology, 3(5), 308-321.
Vedral, V. (2005) Modern foundations of quant urn optics. London: Imperial College. 378p.