Volume 32 Issue 4
Jul.  2023
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Aysu Belen, Mehmet A. Belen, Merih Palandöken, et al., “Design and Realization of Broadband Active Inductor Based Band Pass Filter,” Chinese Journal of Electronics, vol. 32, no. 4, pp. 731-735, 2023, doi: 10.23919/cje.2021.00.322
Citation: Aysu Belen, Mehmet A. Belen, Merih Palandöken, et al., “Design and Realization of Broadband Active Inductor Based Band Pass Filter,” Chinese Journal of Electronics, vol. 32, no. 4, pp. 731-735, 2023, doi: 10.23919/cje.2021.00.322

Design and Realization of Broadband Active Inductor Based Band Pass Filter

doi: 10.23919/cje.2021.00.322
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  • Author Bio:

    Belen Aysu received the M.S. degree in electronics and communication engineering from the Yıldız Technical University in 2016. She has been currently in the Ph.D. program of Yıldız Technical University. Her main research areas are optimization of microwave circuits, device modeling, and computer aided circuit design and microwave amplifiers. (Email: aysu.belen@iste.edu.tr)

    A. Belen Mehmet received the Ph.D. degree in electronics and communication engineering from the Yıldız Technical University in 2016. He is currently an Associated Professor in İskenderun Technical University. His current activities include teaching and researching electromagnetics and microwaves along with developing additive manufacturing 3D printed microwave components for rapid prototyping. His current research interests are in the areas of multivariable network theory, device modeling, computer aided microwave circuit design, monolithic microwave integrated circuits, and antenna arrays, active/passive microwave components especially in the field of metamaterial-based antennas and microwave filters. (Email: mali.belen@iste.edu.tr)

    Palandöken Merih received the M.S. degree in microelectronics and microsystems engineering from Technical University of Hamburg, Germany, in 2005 and Ph.D. degree in theoretical electrical engineering from Technical University of Berlin, Germany, in 2012. He has been working in the analytical and numerical design and modeling of active/passive wireless components in the micro/millimeter wave frequencies especially in the field of metamaterial-based antennas and microwave filters. (Email: merih.palandoken@ikc.edu.tr)

    Mahouti Peyman received the M.S. and Ph.D. degree in electronics and communication engineering from the Yıldız Technical University, Turkey, in 2013 and 2016, respectively. He is currently an Associated Professor with the Department of Electronic and Communication, Istanbul University - Cerrahpasa, Turkey. The main research areas are analytical and numerical modelling of microwave devices, optimization techniques for microwave stages, and application of artificial intelligence-based algorithms. (Email: pmahouti@iuc.edu.tr)

    Tari Özlem received the B.S., M.S., and Ph.D. degrees in physics engineering from the Istanbul Technical University (ITU). She was the recipient of the Universidad Carlos III de Madrid Research Fellowship award before accepting her position at Istanbul Arel University in 2010. Her research areas are the phase transitions and phase diagram of some physical systems, multi-objective optimization problems and development of meta-heuristic optimization algorithms. (Email: ozlemilgin@arel.edu.tr)

  • Received Date: 2021-09-02
  • Accepted Date: 2022-03-28
  • Available Online: 2022-04-13
  • Publish Date: 2023-07-05
  • With the latest developments in the wireless communication systems, the alternative design methodologies are required for the broadband design of microwave components. In this paper, a compact broad band pass filter (BPF) design is introduced through the microwave design technique based on the active inductor (AIN) with the numerical computation and experimental measurement studies. The proposed AIN based BPF has operating frequency band extending from 0.8 GHz to 2.7 GHz in compact size with high selectivity in comparison to conventional LC based BPF. The experimental measurement results agree well with the numerical computation results. The proposed AIN based BPF design has technical capability to be conveniently tuned to operate at different frequency bands.
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