Analysis of the Compact Graded Dumbbell Coaxial Resonator With Its Filter Design Applications

This article presented a modified coaxial resonator, i.e., the graded dumbbell coaxial resonator (GDCR), which can be constructed by concaving the lateral surface of the inner metal cylinder from both ends to the center. The modification will not increase the design complexity for the classical topo...

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Bibliographic Details
Published inIEEE transactions on microwave theory and techniques Vol. 72; no. 6; pp. 3577 - 3587
Main Authors Rao, Jiayu, Sun, Cong, Chen, Zhuyang, Xue, Bo, Zhang, Gang, Hong, Jiasheng, Aliqab, Khaled
Format Journal Article
LanguageEnglish
Published New York IEEE 01.06.2024
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
3-D metal printing
Band-pass filters
Bandpass filters
coaxial bandpass filter (BPF)
coaxial resonator
Conductors
Controllability
Coupling
Couplings
Design
Filter design (mathematics)
graded dumbbell coaxial resonator (GDCR)
inline topology
Metals
mixed coupling
Rapid prototyping
Resonant frequency
Resonator filters
Resonators
Topology
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Summary:This article presented a modified coaxial resonator, i.e., the graded dumbbell coaxial resonator (GDCR), which can be constructed by concaving the lateral surface of the inner metal cylinder from both ends to the center. The modification will not increase the design complexity for the classical topology coaxial bandpass filters (BPFs). Compared with the conventional coaxial resonator (CCR), the GDCR can provide a volume saving of 35%-38% while maintaining comparable unloaded quality values. The analytical expression was given in detail. Three fourth-order filters with simple inline cascading were designed to prove the merits of the GDCR. On the other hand, the GDCR showed some interesting features for the inline mixed-coupling topology. Then, a simple novel spout-shaped structure was introduced and analyzed for constructing electrical magnetic (EM) mixed coupling. For demonstration, a fourth-order cascaded quarter (CQ) and a sixth-order inline mixed-coupling topology filter were designed. Both filters achieved controllable transmission zeros (TZs) that highly improved the stopband performance. The complete design methodology of all filters is also discussed in detail. For rapid prototyping, the filters with TZs were fabricated by direct metal 3-D printing technology. The printing tolerance is acceptable, and the tested results agreed well with the simulated ones.
ISSN:0018-9480
1557-9670
DOI:10.1109/TMTT.2023.3327474