Synthesis of resonator designs according to the criterion of ensuring the maximum correctness

Abstract

The study is linking Q oscillation system and its frequency response. At the same time also studied construction algorithm of changing design parameters for the cavity length and its criteria of maximum Qfactor. Relationship between the quality factor of the resonator will determine the design parameters dependent on the length of transmission lines and the necessary frequency response. Resonators are an important part of the frequency-filtering devices whose characteristics depend on the characteristics of the transmitting and receiving devices. Filter characteristics greatly influence the quality of the resonator and characterized by steep slopes amplitude-frequency characteristics of the filter. The higher quality response slope inclination increases and selective filter properties improved. An obstacle in the development of quality resonators filter is lost in the construction of the resonator loss conductors and insulator. Thus, the problem of synthesis of the resonator is reduced to geometrical parameters of irregular lines, which can be divided into two stages. The first stage ‒ at the required frequency characteristics to find
the corresponding values of zeros and poles. Thus, the synthesis of the resonator with the highest possible quality factor proposed method allows to form objective function. Depending on the minimum possible number of variable parameters increases the efficiency of the synthesis of the resonator. It is shown that the implementation of a design change of the resonator impedance is achieved by changing the design parameters of the resonator along its length.

Keywords: resonant systems, synthesis of resonator designs, segments of homogeneous and inhomogeneous lines, resonant frequency, transmission lines, quality factor, resistance.

References
1. Howard V., Johnson G. (2005) High-speed transmission of digital data-the highest degree of black magic. Williams. 1024 Print.
2. Lytvynenko O.N., Soshnikov V.I. (1964) Theory of inhomogeneous lines and their application in radio engineering. Sov. Radio. 535 Print.
3. Mattey D.L., Young E.M., John L.T. (1971) T. Filters microwave, matching the chains and chains of the saints. Communication. 437 Print.
4. Klimenko D.N., Plavsky L.G. (2015) Use of irregular lines in bandwidth filters as resonant elements. Modern problems in radio electronics: Sat. scientific Art. – Krasnoyarsk: Siberian Federal Unitary Enterprise. 148 Print.
5. Budaragin R.V., Radionov A.A., Titarenko A.A. (2001) Calculation of smooth transitions in a coaxial transmission line // Physics of wave processes and radio engineering systems, № 2, 53–57 Print.
6. Nikolsky V.V., Nikolskaya T.I. (2014) Electrodynamics and the propagation of radio waves. Publishing group URSS. 544 Print.
7. Ilyin V.A., Levitan M.L. (1991) Spectral theory of differential operators. Science. 368 Print.
8. Levitan M.L., Sargsyan I.S. (1990). Introduction to the spectral theory: self-conjugate ordinary differential operators. Moscow: Science. 671 Print.
9. Bychkova Y.A., Zolotnitsky V.A., Chernyshova E.P. (2008) Theoretical foundations of electrical engineering. A guide to the theory of electrical circuits. [ed.] St. Petersburg: Peter. 868 Print.
10. Falkovskii O.I. (2009) Technical electrodynamics. St. Petersburg: "Lan". 432 Print.
11. Herald K. Alexander, Andreas Weisshaas, Vijay C. Tripati, Philippe Magnusson, Philip Cooper. (2000) Lines of transmission and propagation of waves. CRC Press. 536 Print.
12. Belov A.S., Gribov E.F., (1988) Representation of parasitic bandwidths of bandwidth microwave filters caused by many of its own frequencies of resonators. Part 1 Communication techniques. RTS series. Vol. 1. 18–24 Print.