Article 8-8-2019

PHOTON SWITCH OF FULL OPTICAL NETWORKS

Mehman Huseyn Hasanov, Azerbaijan Technical University,
Baku, Azerbaijan,  mhasanovnew@gmail.com

Abstract
The future development of OFTN is due to the creation of complete optical photon networks and optical communication lines. In such systems, without the use of electronic devices and electronic processes, signal transmission, reception and processing will be fully photonized. For this purpose, optically controlled optical switches, new high-capacity optical cross-switches, remote optical feeder optical amplifiers, optical pulse generators, optical passive elements: optical level channel separators, couplers, optical vents, chromatic dispersion compensators, optical filters, polarizers and circulators, multiplexers and demultiplexors, optical processors, etc. new optical devices are created along with optical devices. Thus, it is advisable to look at the application of all components of the new generation OFTN, including the creation of new photon switches based on theoretical, experimental, and computer modeling. The article discusses the principles and methods of layout, routing and methods for constructing compressed information channels over fiber-optic networks, as well as the parameters of the photon switches used. In principle, a new controllable photon switch for high capacity photo switches is proposed.

Keywords: optical fiber networks, photon switches,  microelectromechanical systems, optical channel, wavelength.

References

1. Gaivorovskaya G.S., Ryabtsov A.V. (2011). Features of the use of optical switches in modern information networks. Applicable İnformation Models. Sofia. İTHEA, no. 22, pp. 169-181.
2. Hasanov M.H. (2017). Multichannel piezoelectric switch for adaptive optical networks. Bulletin of the Azerbaijan Engineering Academy. Vol. 9, no. 4, pp. 107-113.
3. Hasanov M.H., Hajiyeva K.R., Godjaeva S.F. (2018). Multifunctional adaptive piezoelectric switch of optical channels.
   T-Comm. Vol. 13, no. 29.
4. Vladimir Makkaveev. (2006). Photon switches. Components And Technologies. No. 2, 2006, pp. 142-146.
5. Maharramov V.A., Hasanov M.H. (2017). “Principles of dataflow commutation of optical networks”, Intenational Journal of Research-Granthaalayah. Volume 5 (Iss.12): December, pp. 348-356.
6. Barabanova E.A. (2018). Optical two-stage switching system for processing large amounts of data. Informatıcs, computer engıneerıng and management. Scientific Bulletin of NSTU, Vol. 70, no. 1, pp. 7-18.

7. Ryabtsov A.V. (2013). Piezo-optical scanning switches. International Journal “Information Theories and Applications”,
Vol. 20, no. 3, pp. 295-299.

1. Landau L.D. and Lifshitz E.M. (1984). Electrodynamics of Continuous Media. Pergamon, Oxford and New York. 460 p.
2. van de Hulst H.C. (1957). Light scattering by small particles. New York (John Wiley and Sons), London (Chapman and Hall. 4-512.
3. Demin D.B., Klemation. Sci. Technol. Vol. 13,
   рр. 256-262.

Information about author:
Mehman Huseyn Hasanov, Candidate of Technical Sciences, PhD, Department of “Telecommunication systems and information security”, Azerbaijan Technical University, Baku, Azerbaijan