Multiband Filter Design Using Generalized Mapping Functions and Synthesis with Lumped Resonators

Yildiz, Serkan; Aksen, Ahmet; Kılınç, Sedat; Yarman, Binboğa Sıddık

doi:10.13164/re.2020.0343

Cited by 1 publication

(1 citation statement)

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“…The literature is large in kinds of configurations. Therefore, there are structures such as microwave photonic filters [17][18][19], filters with lumped elements [20,21], mixed lumped components [22], transfer-function (TF) [23,24], filters with defected ground structure (DGS) [2,25], multiple mode resonators (MMR) [26][27][28], spoof surface plasmon polaritons (SSPP) [29], stub loaded resonators (SLR) [30][31][32][33], stepped impedance resonators (SIR) [32][33][34] which can use transmission zeros (TZs) [31] with symmetric [32,33] or asymmetric structure's geometry [35]. Designers' innovative ideas allowed several filters' shapes such as square [36,37], T-shapes, L-shapes, and U-shapes [6,37].…”

Section: Introductionmentioning

confidence: 99%

Tri-Band Bandpass Filter Using Mixed Short/Open Circuited Stubs and Q-Factor With Controllable Bandwidth for Was, Ism, and 5g Applications

Massamba¹,

Mpele²,

Mbango³

2022

PIER C

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Designing a multi-band bandpass filter (BPF) with controllable bandwidths is an alternative process to several technologies suggested by researchers. Hence, this paper presents a tri-band BPF in microstrip technology where T-shaped short-and-open stubs have alternating positions to use the maximally flat theory, based on the overall ABCD parameters of the circuit. The combination of the design Q-factor and operating frequency to mismatch the design is the technique basis. The proposed structure comprises quarter wavelength (λ/4) line section to develop a tri-band BPF frequency. All stubs are symmetrical relative to the center axis, while the prototype has been fabricated on a wafer of 22.42 × 7.62 mm 2 . Using an FR4 HTG-175 with a thickness 1-mm, dielectric constant ε r = 4.4, and loss tangent tan δ = 0.02, the (4.06-4.283) GHz, (5.877-6.408) GHz,) GHz are obtained referring to a 10-dB of the return loss. In contrast, the insertion losses at the center frequencies are 2.107/1.354/4.08 dB and the fractional bandwidths of 2.134%, 5.346%, and 8.645%, respectively. This covers WAS (including RLAN), ISM, and 5G applications. However, the attenuation coefficient is between 1.326 dB and 4.368 dB. The tri-band BPF prototype was validated using the Anritsu MS4642B 20 GHz Vector Network Analyzer. The measured and E-simulated results have been compared with good agreement.

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