Broadband Power Amplifier Design via Fictitious Matching

Sedat Kilinc*, B. S. Yarman, Serdar Ozoguz

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

4 Citations (Scopus)

Abstract

In this brief, we introduce a new matching concept, so called Fictitious Matching (FM), which may be defined between the artificially generated non-Foster passive immittances, namely KGF and KLF , over a lossless two-port or equivalently equalizer [E]. These immittances may not necessarily belong to physical devices, rather, they are fabricated like a source-pull or load-pull impedances to maximize the gain, the output power, the efficiency, and to minimize the output harmonics of a nonlinear-active device. In FM problems, [E] is constructed to optimize the power transfer from KGF to KLF in the passband. In this regard, [E] is described by means of its back end driving point input immittance K (λ) in Darlington sense, and it is determined as the outcome of the optimization process, where the complex variable λ = Σ+jΩ refers to Richards variable. Synthesis of Kλ results in [E], consists of commensurate transmission lines. It is demonstrated that the new concept of FM can be utilized to build broadband power amplifiers. In this brief, solving FM problem successively, the input and the output matching networks of a power amplifier are designed over 500 MHz-3 GHz with the average gain of 11.5dB , the output power of 40.5dBm , and the average drain efficiency of 61.7%. The Power Amplifier was manufactured with microstrip lines using Wolfspeed's CGH40010F GaN transistor.

Original languageEnglish
Pages (from-to)4844-4848
Number of pages5
JournalIEEE Transactions on Circuits and Systems II: Express Briefs
Volume69
Issue number12
DOIs
Publication statusPublished - 1 Dec 2022

Bibliographical note

Publisher Copyright:
© 2004-2012 IEEE.

Keywords

  • Broadband matching
  • commensurate transmission lines
  • GaN power amplifiers
  • load pull impedance
  • microstrip lines
  • parametric approach
  • real frequency techniques
  • richards synthesis
  • richards variable
  • source pull impedance

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