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A microstrip switched-band impedance transformer for frequency-dependent complex load

Published online by Cambridge University Press:  03 August 2020

Ming-Lin Chuang*
Affiliation:
Department of Communication Engineering, National Penghu University of Science and Technology, Penghu, Taiwan
Ming-Tien Wu
Affiliation:
Department of Communication Engineering, National Penghu University of Science and Technology, Penghu, Taiwan
Shu-Min Tsai
Affiliation:
Department of Communication Engineering, National Penghu University of Science and Technology, Penghu, Taiwan
*
Author for correspondence: Ming-Lin Chuang, E-mail: [email protected]

Abstract

This study presents a simple switched-band impedance transformer using microstrip lines. The proposed circuit is suitable for loads with frequency-dependent complex impedances at two arbitrary operating frequencies. The transformer comprises two cascaded microstrip lines and two detachable shunt stepped-impedance stubs, which are separately connected to the main line via switching diodes such that provide good matching at one of the two operating frequencies and suppress unwanted signal at the other frequencies. The structure contains several user-set parameters such that designers can create a smaller circuit. The circuit parameters, except the user-set ones, are obtained using the derived design formula. The numerical simulations and experimental results agree well such that validate the proposed structure and the design formula.

Type
Passive Components and Circuits
Copyright
Copyright © Cambridge University Press and the European Microwave Association 2020

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References

Wu, Y, Liu, Y and Li, S (2009) A dual-frequency transformer for complex impedances with two unequal sections. IEEE Microwave and Wireless Components Letters 2, 7779.Google Scholar
Liu, X, Liu, Y, Li, S, Wu, F and Wu, Y (2009) A three-section dual-band transformer for frequency-dependent complex load impedance. IEEE Microwave and Wireless Components Letters 10, 611613.Google Scholar
Rawat, K and Ghannouchi, FM (2011) Dual-band matching technique based on dual-characteristic impedance transformers for dual-band power amplifiers design. IET Microwave Transactions on Antennas and Propagation 14, 17201729.CrossRefGoogle Scholar
Fu, X, Bespalko, DT and Boumaiza, S (2012) Novel dual-band matching network topology and its application for the design of dual-band class J power amplifiers. 2012 IEEE MTT-S Microwave Symposium Digest, Montreal, Canada, June 2012.Google Scholar
Fu, X, Bespalko, D and Boumaiza, S (2014) Novel dual-band matching network for effective design of concurrent dual-band power amplifiers. IEEE Transactions on Circuits and Systems I 1, 293301.CrossRefGoogle Scholar
Manoochehri, O, Asoodeh, A and Forooraghi, K (2015) PI-model dual-band impedance transformer for unequal complex impedance loads. IEEE Microwave and Wireless Components Letters 4, 238240.CrossRefGoogle Scholar
Maktoomi, MA, Panwar, V, Hashmi, MS and Ghannouchi, FM (2016) Improving load range of dual-band impedance matching networks using novel load-healing concept. IEEE Transactions on Circuits and Systems II 2, 126130.Google Scholar
Liu, J, Zhang, XY and Yang, C-L (2018) Analysis and design of dual-band rectifier using novel matching network. IEEE Transactions on Circuits and System II 3, 431435.CrossRefGoogle Scholar
Chuang, M-L and Wu, M-T (2016) General dual-band impedance transformer with a selectable transmission zero. IEEE Transactions on Components Packaging and Manufacturing Technology 7, 11131119.CrossRefGoogle Scholar
Chuang, M-L and Wu, M-T (2017) Transmission zero embedded dual-band impedance transformer with three shunt stubs. IEEE Microwave and Wireless Components Letters 9, 788790.CrossRefGoogle Scholar
Wang, X, Ma, Z and Ohira, M (2017) Dual-band design theory for dual transmission-line transformer. IEEE Microwave and Wireless Components Letters 9, 782784.CrossRefGoogle Scholar
Candra, P and Xia, T (2016) SiGe HBT X-band and Ka-band switchable dual-band low noise amplifier. IEEE International Symposium on Circuits and Systems, Montréal, QC, Canada, May 2016.CrossRefGoogle Scholar
Ko, J, Lee, S and An, SN (2017) S/X-Band CMOS power amplifier using a transformer-based reconfigurable output matching network. IEEE International Symposium on Radio Frequency Integrated Circuits, Honolulu, HI, USA, July 2017.Google Scholar
Fukuda, A, Okazaki, H, Hirota, T and Yamao, Y (2004) Novel 900 MHz/1.9 GHz dual-mode power amplifier employing MEMS switches for optimum matching. IEEE Microwave and Wireless Components Letters 3, 121123.CrossRefGoogle Scholar
Fukuda, A, Okazaki, H, Narahashi, S, Hirota, T and Yamao, Y (2005) A 900/1500/2000–MHz triple-band reconfigurable power amplifier employing RF-MEM switches. 2005 IEEE MTT-S Microwave Symposium Digest, Long Beach, CA, USA, June 2005.CrossRefGoogle Scholar
Norouzian, F (2015) Dual-Band and Switched-Band Highly Efficient Power Amplifiers. (Ph.D. Thesis), University of Birmingham, UK.Google Scholar
Norouzian, F and Gardner, P (2012) Analytical solution for switched band matching networks. 3rd Annual Seminar on Passive RF and Microwave Components, London, UK, March 2012.CrossRefGoogle Scholar