Abstract
A dual-band bandpass filter (BPF) composed of a coupling structure and a bent T-shaped resonator loaded by small L-shaped stubs is presented in this paper. The first band of the proposed BPF covers 4.6 to 10.6 GHz, showing 78.9% fractional bandwidth (FBW) at 7.6 GHz, and the second passband is cantered at 11.5 GHz with a FBW of 2.34%. The bent T-shaped resonator generates two transmission zeros (TZs) near the wide passband edges, which are used to tune the bandwidth of the first band, and the L-shaped stubs are used to create and control the narrow passband. The selectivity performance of the BPF is analyzed using the transfer function extracted from the lumped circuit model verified by a detailed even/odd mode analysis. The BPF presents a flat group delay (GD) of 0.45 ns and an insertion loss (IL) less than 0.6 dB in the wide passband and a 0.92 IL in the narrow passband. A prototype of the proposed BPF is fabricated and tested, showing very good agreement between the numerically predicted and measured results.
Highlights
The development of wide-band communications has increased the application of wide-band microwave filters
The advantage of introducing L-shaped resonators to the bent T-shaped resonator is the addition of a second controllable passband without affecting the filter’s total footprint. If such a narrow band is not required, the L-shaped resonators can be harmlessly removed from the filter configuration without affecting the primary passband performance
Some of the properties of recently published papers and the filter area transmission lines andimportant a bent T-shaped resonator loaded by L-shaped stubs
Summary
Ali Lalbakhsh 1 , Seyed Morteza Alizadeh 2, *, Amirhossein Ghaderi 3 , Alireza Golestanifar 3 , Bahare Mohamadzade 1 , Mohammad (Behdad) Jamshidi 4,5 , Kaushik Mandal 6 and.
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