• Українська
  • English
  • Русский
ISSN 2415-3400 (Online)
ISSN 1028-821X (Print)

REFLECTION RESONANCES IN A RECTANGULAR WAVEGUIDE SECTION WITH A PAIR OF ANTIPODAL RECTANGULAR POSTS

heading: 
MICROWAVE ELECTRODYNAMICS
Mospan, LP, Prikolotin, SA, Кirilenko, АА
Organization: 

O. Ya. Usikov Institute for Radiophysics and Electronics of the National Academy of Sciences of Ukraine
12, Proskura st., Kharkov, 61085, Ukraine
E-mail: lyudmila.mospan@gmail.com
https://doi.org/10.15407/rej2016.01.015
Language: Russian
Abstract: 

Intentional and controllable introduction of attenuation poles into the frequency responses of frequency-selective devices is in the great demand in the design of modern filters with complicated performance. Successful implementation of such an approach is possible using rectangular waveguide sections with metallic inserts. Here, the scattering characteristics of such sections with a pair of antipodal rectangular posts as waveguide units with rotational symmetry are studied. Comparative analysis with the characteristics of a section with a pair of unidirectional posts is performed. Spectral theory of open waveguide resonators is used in order to interpret the resonant phenomena. Within the frames of spectral theory the reflection resonances formed by such sections are the responses to the excitation of eigen oscillations of complex frequencies. It is shown that the spectral theory enables an order of magnitude more accurate (in comparison with the conventional modal analysis) evaluation for basic parameters of the resonance reflection, namely its frequency and the quality factor. The results obtained make preliminary synthesis of frequency selective devices based on such sections physically transparent and more accurate.
Keywords: eigen oscillation, rectangular waveguide, reflection resonances, waveguide filter

Manuscript submitted  24.12.2015
PACS 84.40 Az; 84.40 Dc
Radiofiz. elektron. 2016, 21(1): 15-21
Full text (PDF)

References: 
  1. Politi, M. and Fossati, A., 2010. Direct coupled waveguide filters with generalized Chebyshev response by resonating coupling structures. In: 40th European Microwave Conf. (EuMC): proc. Paris, France, 28-30 Sept. 2010, pp. 966-969.
  2. Tomassoni, C. and Sorrentino, R., 2013. A new class of pseudoelliptic waveguide filters using dual-post resonators. IEEE Trans. Microwave Theory Tech., 61(6), pp. 2332-2339. DOI: https://doi.org/10.1109/TMTT.2013.2258171
  3. Kirilenko, A. A., Kulik, D. Y., Mospan, L. P. and Rud’, L. A., 2008. Reflection resonances in a waveguide section with two uneven posts. In: V. M. Yakovenko, ed. 2008. Radiofizika i elektronika. Kharkov: IRE NAS of Ukraine Publ. 13(2), pp. 154-158 (in Russian).
  4. Shestopalov, V. and Shestopalov, Yu., 1996. Spectral Theory and Excitation of Open Structures. London: Peter Peregrinus. DOI: https://doi.org/10.1049/PBEW042E
  5. Rud’, L. A., Sirenko, Yu. K., Yatsyk, V. V. and Yashina, N. P., 1988. A Spectral method of analyzing the effects of total wave transformation by open-periodic and waveguide resonators. Radiophysics & Quantum Electronics, 31(10), pp. 894-899. DOI: https://doi.org/10.1007/BF01040024
  6. Kirilenko, A. A. and Yashina, N. P., 1980. Coupling of “trapped”-mode resonances with excitation of quasi-normal modes of open volumes. Pisʼma Zh. Eksp. Teor. Fiz., 6(12), pp. 1512-1515 (in Russian).
  7. Kirilenko, A. A. and Tysik, B. G., 1993. Connection of S-matrix of waveguide and periodical structures with complex frequency spectrum. Electromagnetics, 13(3), pp. 301-318. DOI: https://doi.org/10.1080/02726349308908352
  8. Prikolotin, S. A., Steshenko, S. A., Kulik, D. Yu., Rud’, L. A., Kirilenko, A. A., 2012. Fast full 3D EM CAD of waveguide units based on the generalized mode-matching technique. In: Int. Conf. on Mathematical Methods in Electromagnetic Theory (MMET-2012): proc. Kharkiv, Ukraine, 28-30 Aug. 2012, pp. 109-112.
  9. Kirilenko, A. A. and Prikolotin, S. A., 2009. A thin step-bended conductor in the rectangular waveguide cross-section plane as a simple reflector. In: V. M. Yakovenko, ed. 2009. Radiofizika i elektronika. Kharkov: IRE NAS of Ukraine Publ. 14(2), pp. 119-127 (in Russian).