Wideband waveguide loading impedance matching on the basis of photonic crystals with nanometer metal layers
DOI:
https://doi.org/10.3103/S0735272709010087Abstract
Theoretically shown and experimentally proven is the possibility of creating wideband matched loading on the basis of photonic crystals, composed of alternating nanometer metal and isolator layers with different electro-physical parameters.
References
J. Xelszajn, “Passive and Active Microwave Circuits,” (John Wiley & Sons, New York–Chichester–Brisbane–Toronto, 1978).
K. A. Lee, Y. Guo, Ph. A. Stimson, et al., “Thin–Film Power–Density Meter for Millimeter Wavelengths,” IEEE Trans. Antennas Propag. 39, No. 3, 425 (1991).
E. Yablonovitch, “Inhibited spontaneous emission in solid–state physics and electronics,” Phys. Rev. Lett. 58, No. 20, 2059 (1987).
J. M. Duchamp, A. L. Perrier, P. Ferrari, “MS,CPWand Fin-line attenuators and dispersion effects on microwave and millimeter wave PBG structure parameters,” in Proc. of 34rd European Microwave Conference, 2004 (2004), Vol. 2, pp. 877–880.
Tae-Yeoul and Kai Chang, “Uniplanar one-dimensional photonic-bandgap structures and resonators,” IEEE Trans. Microwave Theory Tech. 49, No. 3, 549 (2001).
C.-S. Kee, J.-E. Kim, H. Y. Park, and H. Lim, “Roles of Wave Impedance and Refractive Index in Photonic Crystals with Magnetic and Dielectric Properties,” IEEE Trans. Microwave Theory Tech. 47, No. 11, 2148 (1999).
C. A. Kuriazidou, H. F. Contopanagos, N. G. Alexopolos, “Monolithic waveguide filters using printed photonic-bandgap materials,” IEEE Trans. Microwave Theory Tech. 49, No. 2, 297 (2001).
D. Usanov, A. Skripal, A. Abramov, et al., “Measurement of the Metal Nanometer Layer Parameters on Dielectric Substrates using Photonic Crystals based on the Waveguide Structures with Controlled Irregularity in the Microwave Band,” in Proc. of 37rd European Microwave Conference, 2007 (2007), pp. 198–201.
C. G. W. Burns, I. G. Thayne, and J. M. Arnold, “Improvement of Planar Antenna Efficiency when Integrated with a Millimetre–Wave Photonic,” in Proc. of European Conf. on Wireless Technology, Amsterdam, Netherlands, 11–12th October 2004 (Amsterdam–Netherlands, 2004), pp. 229–232.
P. H.-S. Wu and C.-K. C. Tzuang, “Miniaturized High-Gain Synthetic Rectangular Waveguide Antenna of
Near-Omnidirectional Radiation,” in Proc. of 34rd European Microwave Conf., Amsterdam, Netherlands, 12–14th October 2004 (Amsterdam–Netherlands, 2004), Vol. 2, pp. 1189–1192.
B. A. Bel’ayev, A. S. Voloshin, and V. F. Shabanov, “Study of micro strip models of band-pass filters on one-dimensional photonic crystals,” Reports of Academy of Sciences 400, No. 2, 181 (2005).
D. A. Usanov, A. V. Skripal, A. V. Abramov, and A. S. Bogolubov, “Change of the resonant reflection type of electromagnetic radiation in structures nanometer metal film–isolator,” Pisma v ZhTF 3, No. 2, 13 (2007).
D. A. Usanov, A. V. Skripal, A. V. Abramov, et al., “Measurements of thickness of metal films in sandwich structures by the microwave reflection spectrum,” in Proc. of 36rd European Microwave Conference, Manchester, UK, 10–15th September 2006 (Manchester, 2006), pp. 921–924.
Yu. A. Chaplygin, D. A. Usanov, A. V. Skripal, et al., “Methodology of measuring conductivity of nanometer metal films in the layered structures using the reflected spectrums of electromagnetic radiation,” Izv. Vyssh. Uchebn. Zaved., Elektronika, No. 6, 27 (2006).
