SYNCHROINFO 2019 Systems of Signal Synchronization, Generating and Processing in Telecommunications, IEEE Conference # 47541
The international scientific and engineering conference “Systems of Signal Synchronization, Generating and Processing in Telecommunications” has been held since 1974. For 46 years of work the conference has become a widely known forum for specialists of the field.
The papers which are discussed at the conference can be divided into the following chapters:
– Synchronization Systems and Devices;
– Signal Generating and Shaping Devices;
– Signal Processing Devices.
– Special chapter: “Problems of microwave electronics” them. V.A. Solntsev
The chapters content is concerned with fundamental problems of signal synchronization, generating and processing in the field of communications, broadcasting, radar, radio guidance and radio control. The questions of the practical issues are also including.
The presentations are made by the scientists and developers from 10 countries: Belarus, Azerbaijan, Germany, Kazakhstan, China, Lebanon, Mongolia, Russia, Uzbekistan and Ukraine.
Branch Director of the IEEE Worldwide Limited in the Russian Federation and Scientific Secretary of Russian (Moscow) IEEE Circuits and Systems (CAS04) Chapter Roman Y. Ivanyushkin promotes this conference among the Engineers in the field of Telecommunications. He also organizes the work of conference Chapter “Signals Generating and Shaping Devices”.
Chairman of Russian (Moscow) IEEE Circuits and Systems (CAS04) Chapter Valentin Kuleshov is the Chairman of the Technical Program Committee.
Every year Director and Chairman of Russian Branch IEEE Circuits and System Society are participate as co-Chairs of the Chapter “Signals Generating and Shaping Devices”.
Chairman of the Steering Committee Alexander Pestryakov (Doctor of Technical Science, Professor, Radio and Broadcasting Faculty Dean of the Moscow Technical University of Communications and Informatics) in cooperation with Director and Chairman of Russian Branch IEEE Circuits and System Society appoints the conference committee chairs and other key members.
Conference will produce a publication.
Modern level of technology development leads to higher requirements for parameters of devices. Deviations, inaccuracies and unwanted inhomogeneity can cause not only significant malfunction and errors, but a complete failure of the device. In this paper we propose to use a metamaterial-based frequency-selective surface for control of physical parameters of matter and for inhomogeneity detection. We used CST STUDIO SUITE 2015 to simulate the FSS and show that it can be used to accomplish the tasks stated.
This paper discusses an important component of the radio frequency identification (RFID) system, namely, the RFID-tag and the bending effect on its electrodynamic parameters. The RFID tag was modeled and the following parameters were calculated: Scattering Coefficients (parameter S11), Voltage Standing Wave Ratio (VSWR), vertical and horizontal radiation patterns and total. The results of the work will allow optimizing the design of the RFID-tag in such a way as to achieve optimal quantitative indicators of electrodynamic parameters.
In this paper, an overview of slow wave systems and metamaterials using in devices intended for application in the area of biomedical engineering is presented. Short characteristic of physical and engineering specifications of slow waves systems and metamaterials are listed. In addition, possible variants of upgrading an exciting engineering solution by dint of slow wave systems and metamaterials application are offered.
The concept of building a software system for designing traveling-wave tubes (TWTs) with resonator slow-wave structures (SWSs) and models for its implementation is described. The cm- and mm-wave TWT designs developed on the basis of the VEGA software are presented.
The subject of consideration of this work is the development of the design, algorithm and program for calculating the dispersion characteristics of the coaxial-radial line (CRL). The selected design of the CRL allows to optimize the coupling impedance and the dispersion of the SWS.