A Tradeoff Design of Broadband Power Amplifier in Doherty Configuration Utilizing a Novel Coupled-Line Coupler

In this paper, the design of a Broadband Power Amplifier for UHF applications is presented. The proposed BPA is based on ATF13876 Agilent active device. The biasing and matching networks both are implemented by using microstrip transmission lines. The input and output matching circuits are designed by combining two broadband matching techniques: a binomial multi-section quarter wave impedance transformer and an approximate transformation of previously designed lumped elements. The proposed BPA shows excellent performances in terms of impedance matching, power gain and unconditionally stability over the operating bandwidth ranging from 1.2 GHz to 3.3 GHz. At 2.2 GHz, the large signal simulation shows a saturated output power of 18.875 dBm with an output 1-dB compression point of 6.5 dBm of input level and a maximum PAE of 36.26%. Electronics in Faculty of sciences and techniques, University Hassan 1st, Settat, Morocco. He is involved in the design of hybrid, monolithic active and passive microwave electronic circuits Ahmed Errkik was born in July 1960 in Morocco. He received the Ph.D. degree in physics from the University of Technology Compiegne (UTC), France. He is currently an associate Professor of physics in FST University Hassan 1st, Settat, Morocco. He is involved in the design of hybrid, monolithic active and passive microwave electronic circuits.Int J Elec & Comp Eng ISSN: 2088-8708  A trade-off design of microstrip broadband power amplifier for UHF applications (Mohamed Ribate) 927 Mohamed Latrach was born in Douar Ksiba, Sless, Morocco, in 1958. He received the Ph.D. degree in electronics from the University of Limoges, Limoges, France, in 1990. He is currently a Professor of microwave engineering with the Ecole Suprieure d'Electronique de l'Ouest (ESEO), Angers, France, where his research involves RF and microwaves. His field of interest is the design of hybrid, monolithic active, and passive microwave circuits, metamaterials, LH materials, antennas and their applications in wireless Communications. Ahmed Lakhssassi received the B.Eng. and M.Sc. in electrical engineering from University of Quebec à Trois-Rivières, Quebec, Canada in 1988 and 1990 respectively. He also received the Ph. D in Energy and Material sciences in 1995 from INRS-Energie et Matériaux, Quebec, Canada. His research interest is the fields of bio-heat thermal modeling. Also, his research interest is in Design of fully automated tool for porting analog and mixed signal circuits within different technology nodes.

Section: Introductionmentioning

confidence: 99%

A trade-off design of microstrip broadband power amplifier for UHF applications

Ribate

Mandry

Zbitou

et al. 2020

“…On the other hand, the cellular mobile communication has reached tremendous advances in terms of technology and innovation as well as commercial accomplishment [9]. However, with the explosive proliferation of the RF and wireless communication standards, driven mostly by the growing demands to transmit an increasing amount of data, besides the growing need of rapid transport of signals in the next generation communication systems as well as the wider signal channels requirement, will lead in a deeply interest in broadband power amplifiers (BPAs) [10][11][12][13][14]. Such devices can supersede multi narrowband and 5401 single channel PAs, and inherently reduce the hardware research and develop fee due to the incompatibility of the new and previous telecommunication standards.…”

Section: Introductionmentioning

confidence: 99%

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

Ribate

Mandry

Zbitou

et al. 2020

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.

“…On other hand, the PA design requires an accurate active device-mostly a Radio Frequency Transistor -, stability in operation, impedance matching technique that depends on the operating frequency band, and a simple configuration for practical realization purpose. The active device bias conditions-that are commonly different for efficiency or linearity improvementdepend on the active device technology and the operating class of the PA [17][18].…”

Section: Introductionmentioning

confidence: 99%

1.25 GHz – 3.3 GHz broadband solid state power amplifier for L and S bands applications

Ribate¹,

Mandry²,

Zbitou³

et al. 2019

The research of a single stage broadband solid state power amplifier based on ATF13876 transistor, which operates in the frequency ranging from 1.25 GHz - 3.3 GHz is presented in this paper. To achieve the broadband performance of the operating bandwidth, a multi-section quarter wave impedance transformer and an approximate transformation of previously synthesized lumped elements into transmission lines are adopted. With neatly design of broadband matching networks and biasing circuit, excellent matching performances and unconditionally stability are achieved over the whole operating bandwidth with a maximum gain of 17.2 dB. The large signal simulation shows that the proposed circuit reaches a saturated output power of 18.12 dBm with a maximum PAE of 27.55% and a 1-dB compression point at 5 dBm input power level. Considering the wide frequency coverage, the features of the proposed design compares favorably with the contemporary state-of-the-art.