MATHEMATICAL MODELING OF THE PROCESS OF DRAWING AN OPTICAL FIBER USING THE LANGEVIN EQUATION
Aliya Tergeussizova
aliya55@mail.ruAl-Farabi Kazakh National University, Faculty of Information technology/Department Artificial intelligence and Big Date (Kazakhstan)
http://orcid.org/0000-0002-5084-8937
Abstract
In order to design stochastic pulse frequency systems for automatic control of objects with delay, this article shows how we obtained their models in the form of stochastic differential equations. The method of dynamic compensation of objects with delay is considered. A stochastic differential system in the Langevin form is obtained.
Keywords:
transport delay, object with delay, dynamic compensation method, Langevin differential equationsReferences
Aitchanov B.H., Aitchanova Sh.K., Baimuratov O.A., Aldibekova A.N.: A Simplified Model of the Control System with PFM. XII International Conference on Information Technology and Engineerin. 17(5)/2015, 1465–1468.
Google Scholar
Aitchanov B.H., Aldibekova A.N.: Primenenie dinamicheskogo chastotnoimpulsnogo modulyatora v sistemah upravleniya s ispolzovaniem yadernogo magnitnogo rezonansa v ustroystvah omagnichivaniya zhidkostey. Vestnik KazNTU.
Google Scholar
Aitchanov B.H., Baimuratov O.A., Aldibekova A.N.: Pulse – Frequency control system of the fluids magnetization of the used nulear magnetic resonance. The 2nd International Virtual Conference on Advanced Scientific Results (SCIECONF – 2014), 473–477.
Google Scholar
Aitchanov B.H., Tergeusizova A.S.: Tehnologicheskij process vytjazhki opticheskih sterzhnej kak objekt avtomatizirovannogo upravlenija. Doklady Nacional'noj akademii nauk Respubliki Kazahstan 2/2017, 91–95.
Google Scholar
Aitchanov B.H.: Metody matematicheskogo opisanija chastotno-impulsnyh sistem upravlenija obektami s zapazdyvaniem. Vestnik KazNTU 2(30)/2002, 72–82.
Google Scholar
Aitchanov B.H.: Time-domain quantization in dynamic pulse-frequency systems with transport delay. Poisk, Natural and technical sciences series, 209–214.
Google Scholar
Aitzhanov B.Kh., Kurmanov B.K., Umarov T.F.: Dynamic Pulse Frequency Modulation in Objects Control with Delay. Asian Journal of Control 14(6)/2012, 1662–1668.
Google Scholar
Aitzhanov B.Kh., Nikulin V.V., Baimuratov O.A.: Mathematical Modeling of Digital Pulse-Frequency Modulation Control Systems Developed for Objects with Transport Delay. The Chinese Control and Decision Conference 2013, 1407–1411.
Google Scholar
Chostkovskij D.B.: Strukturnyj sintez sistemy upravlenija processom vytjazhki gradientnyh opticheskih volokon. Vestnik SamGTU. Serija Tehnicheskie nauki 4(27)/2010, 73–78.
Google Scholar
Friman R.: Volokonno-opticheskie sistemy svjazi. Tehnosfera, Moscow 2003.
Google Scholar
http://oplib.ru – Open Library – Open library of educational information (available 15.05.2019).
Google Scholar
Listvin A.V., Listvin V.N., Shvyrkov D.V.: Opticheskie volokna dla liniy sviazi. LESARart, Moscow 2003.
Google Scholar
Roy P., et al.: Active Optical Fibers: New design and alternative method of fabrication. Photonics, Dehli 2008.
Google Scholar
Sandoz F., et al.: A Novel process to manufacture high efficiency laser fibers. Photonics, Dehli 2008.
Google Scholar
Sarkar A., Orchanian B., Chan A.: A Novel VAD process. Proceedings of the International Wire & Cable Symposium, Providence 2008.
Google Scholar
Zhiro A.: Tehnologii proizvodstva opticheskih volokon. Obzor poslednih razrabotok. Nauka i tehnika 4/2009, 22–27.
Google Scholar
Authors
Aliya Tergeussizovaaliya55@mail.ru
Al-Farabi Kazakh National University, Faculty of Information technology/Department Artificial intelligence and Big Date Kazakhstan
http://orcid.org/0000-0002-5084-8937
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