Перегляд за автором "Filipenko, A."
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Публікація Monitoring of Photonic-Crystal Fibers Positioning in the Connection Process(ХНУРЭ, 2008) Filipenko, A.; Sychova, O.In this report the monitoring method of PCF positioning at the connection process is offered. It is based on the matched filtration principle in the form of autoconvolution. Equations which connected PCF core axis coordinates with the maximum value of optical field intensity autoconvolution was obtained. It is shown that optical fiber displacement relatively base coordinates corresponds to half coordinates of autoconvolution maximum. Researches have shown that the offered method possesses high noiseproof factor and much higher accuracy in comparison with an integrated method.Публікація The analysis of creation perspectives of photonic crystal fiber components(Kharkiv National University of Radio Electronics, 2006) Filipenko, A.; Sychova, O.The creation perspectives of components on fibers of new type - photonic crystal fibers, possible areas of their application are considered. Comparative analysis PCF and standard quartz fibers are carried out. Advantages and limitations of PCF use in electronic techniques are selected. The further direction of researches is determined.Публікація The analysis of photonic crystal fibers opticalgeometrical properties and their impact on transfer parameters(Технологический центр, 2012) Filipenko, A.; Donskov, A.; Sychova, O.In microstructured optical fibers some defects are inherent to the fabrication process. One can mention, for example, the inhomogeneity of the initial preform: diameter, position of the inclusions (when the hexagonal stack is assembled before drawing) and refractive index that evolves along its axis. These defects will lead to transverse disorders in the final fiber. Therefore, the analysis of photonic crystal fibers optical-geometric properties and their impact on transfer parameters is very important. We note that in our investigation we use finite-element method. The obtained results show that at any of considered defect types the mode field will have two pronounced maximums. The results presented in this work show that total mode field power increases with decreasing the mean diameter of air holes. Another important result is that random variations of diameter of inclusions (air holes) can lead to an increase of total mode field power. We also have shown that random variations of inclusions diameter can increase the total mode field power. In the part 2 the signal losses caused by the difference of mode fields effective areas of connected fibers are determined. Further research in this sphere is directed to the study of influence of other optical-geometric PCF parameters, as well as their connection to the signal transmission. All presented results will be helpful for tolerance of fabrication processes and for better understanding the role of random variation of geometrical behaviors (arising at fabrication processes) on operation parameters of microstructured optical fibers.