Investigation of dual-band bandpass filter inspired by a pair of square coupled interlinked asymmetric tapered metamaterial resonator for X-band microwave applications

Advanced studies on modern electronic devices using the filter function show the impact of multi-band filters on the electrical qualities of these devices. Due to the importance of its electromagnetic characteristics, the dual-band bandpass microwave filters can be used in several high-quality elect...

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Bibliographic Details
Published in:Bulletin of materials science 2022-09, Vol.45 (3), p.118, Article 118
Main Authors: Rouabhi, Ahmed Yacine, Berka, Mohammed, Benadaoudi, Amina, Mahdjoub, Zoubir
Format: Article
Language:English
Subjects:
Asymmetry
Bandpass filters
Chemistry and Materials Science
Design
Electromagnetic properties
Electronic devices
Engineering
Finite element method
Magnetic resonance
Materials Science
Mathematical analysis
Metamaterials
Microstrip transmission lines
Microwave filters
Permeability
Resonators
Substrates
Superhigh frequencies
Symmetry
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Summary:Advanced studies on modern electronic devices using the filter function show the impact of multi-band filters on the electrical qualities of these devices. Due to the importance of its electromagnetic characteristics, the dual-band bandpass microwave filters can be used in several high-quality electronic devices. In this paper, a dual-band bandpass filter (DBBPF) is provided. The proposed filter is inspired by a pair of tapered split-ring metamaterial resonators of the same asymmetric square coupled interlinked shape (SCI-SRR) and of different sizes. The choice of the two resonators, which have a negative permeability ( μ < 0), is made such that the magnetic resonance of each resonator appears in X-band. The designed filter consisting of these SCI-SRRs is fed in parallel mode by two microstrip lines and etched on the upper face of the used substrate. Both SCI-SRRs which are coupled to the feed lines are interconnected by a folded microstrip line to have the necessary miniaturization of the filter. The electrical dimensions of our DBBPF are (1.305 λ 0 × 0.913 λ 0 ) mm 2 , for which λ 0 is the wavelength of the lowest frequency calculated at 9.89 GHz. Numerical calculations using the finite element method (FEM) based on high-frequency structure simulator software are performed to design this filter. The two filter bandwidths, which are obtained as a function of the rings widths of the tapered metamaterial resonators ( α , β ), are considered in the X-band, they are of the order of 186.2 and 89.7 MHz, respectively. To validate our work, we compared our obtained results with the other recent work results for the same field of research.
ISSN:0973-7669
0250-4707
0973-7669
DOI:10.1007/s12034-022-02693-6