EM POLARIZERS BASED ON PRINTED GRATINGS OF MEANDER LINES AT MICROWAVES
Keywords:
Polarization transformation, meander-line polarizer, ransmission of electromagnetic waves, grating, printed array, microwave range, re-radiator, axial ratio, voltage standing wave ratio, mathematical simulation, multilayered EM structureAbstract
The problem of printed gratings application is considered as converters of electromagnetic waves
polarization and polarizing modulators. Two directions in development of antenna engineering are
considered in this paper. In each of them the scattering fields control of an antenna arrays allows essentially
to expand functionalities of radio engineering sets. The first direction is the creation of auxiliary
depolarizing reflectors for two-mirror reflector antennas and folded lenses. In addition, in meanderline
polarizers based on printed gratings, it is possible to constructively realize the necessary phase distributions of the field on their surfaces. Thus, it becomes possible to use such meanderline polarizers to create
multifunctional microwave antenna radomes. The second direction is connected to application of
antenna arrays for a reduction of a radar cross section of the radar-tracking targets. Transformation of
a field polarization by an antenna array allows to achieve both these purposes. In an aspect of high cost
and complexity of arrays experimental researches as a method of the analysis the mathematical simulation
is selected. Besides, it is shown that introduction of impedance loads in the construction of the reradiating
elements of the printed grating opens additional possibilities for controlling the field scattered
by it. Thus, meanderline polarizers with improved characteristics can be realized on the basis of
microstrip-pin gratings. The given results can be used for choosing the most of rational electrodynamic
structure geometry variant at decision of particular problems by antennas engineering. The possible flat
arrays based on printed complicated shape elements application area is also discussed and it's shown
these arrays are the very attractive type for controllable radioelectronic covers designing at microwaves.
Some numerical results presented prove the possibility of a printed arrays application as smart
covers microwave modules.
References
