A 1.8 GHz wideband high power amplifier with flat gain response by exploiting microstrip high‐pass‐filter

Malik, Waqar; Sheta, Abdel Fattah; Elshafiey, Ibrahim

doi:10.1002/mop.31048

Cited by 5 publications

(3 citation statements)

References 9 publications

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“…In [3], a microstrip BPF with more than 20% fractional bandwidth (FBW) is employed as the PA OMN with good frequency selectivity. In [4], a high‐pass filter is used in the input matching network to provide flat gain and extended bandwidth over the entire band. A PA based on a hairpin filter matching network is already analysed in our previous work [5].…”

Section: Introductionmentioning

confidence: 99%

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Broadband power amplifier using hairpin bandpass filter matching network

et al. 2020

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This Letter presents a new combination of a broadband power amplifier (PA) and an output microstrip hairpin bandpass filter. The filter is designed based on the fifth-order Chebyshev low-pass prototype element values. Even-odd mode impedance analysis is used to calculate the filter parameters. Meanwhile, only the fundamental impedance matching is considered for this design. Therefore, a highly selective bandpass response is obtained to provide a spurious-free fundamental impedance matching. For verification, a broadband PA-filter component across 1.9-3.1 GHz (48%) is designed and fabricated. Measurements have shown a drain efficiency of 48-56.6% with 39.3-40.5 dBm of maximum output power.

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Section: Introductionmentioning

confidence: 99%

“…can cause sufficient degradation in the overall structure. For this reason, several co-designs of PAs and BPFs have been proposed to compensate for such losses [1][2][3][4][5]. Likewise, in [1,2], a co-design of high-selectivity cavity resonators are employed in Class-F PA.…”

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confidence: 99%

Broadband power amplifier using hairpin bandpass filter matching network

et al. 2020

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“…However, this scheme is good for VSWR performance and gain flatness up to about a two octave bandwidth [21][22]. On the other hand, the traveling-wave and distributed amplifiers have flat gain and wide frequency range, but the main drawbacks for these techniques reside in the moderate small signal gain, high dc power consumption, high noise figure and the large chip size owing to the high number of components used to achieve the same performance as a single stage PA [24][25][26].…”

Section: Introductionmentioning

confidence: 99%

Design of L-S band broadband power amplifier using microstip lines

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Mandry

Zbitou

et al. 2020

IJECE

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This contribution introduces a novel broadband power amplifier design, operating in the frequency band ranging from 1.5 GHz to 3 GHz which cover the mainstream applications running in L and S bands. Both matching and biasing networks are synthesized by using microstrip transmission lines. In order to provide a wide bandwidth, two broadband matching techniques are deployed for this purpose, the first technique is an approximate transformation of a previously designed lumped elements matching networks into microstrip matching circuits, and the second technique is a binomial multi-sections quarter wave impedance transformer. The proposed work is based on ATF-13786 active device. The simulation results depict a maximum power gain of 16.40 dB with an excellent input and output matching across 1.5 GHz ~ 3 GHz. At 2.2 GHz, the introduced BPA achieves a saturated output power of 16.26 dBm with a PAE of 21.74%, and a 1-dB compression point of 4.5 dBm input power level. The whole circuitry is unconditionally stable over the overall bandwidth. By considering the broadband matching, the proposed design compares positively with the most recently published BPA.

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