PRACTICAL IMPLEMENTATION AND TESTING OF A 3.6 MHZ BANDPASS FILTER

Authors

  • Anas A. Bisu Department of Physics, Bayero University, Kano-Nigeria Author

DOI:

https://doi.org/10.60787/jnamp-v66-326

Keywords:

Filter, Implementation, Testing, Bandpass, Bandwidth, Frequency, Performance, Order, Components, Attenuation, Signal

Abstract

In this paper, a practical implementation and testing of a 3.6MHz Bandpass Filter (BPF) is presented. This circuit was design using butterwort filter design method and simulated using microwave office before the practical implementation and testing using real-world components and equipment. BPF is one of the arrays of components shaping the efficiency of communications systems that play a critical role in refining signal, mitigating interference, and enhancing the overall communication performance. Radio Frequency (RF) BPF has always been an indispensable part of RADAR and other wireless communication systems. The BPF have major functions of frequency band and channel selection, filtering harmonics, and suppress spurious. Therefore, RF BPF has always been a research hotspot in the field of wireless communication systems. The results indicated better performance of the at 3.6 MHz with -14.3 dBm and -13.3 dBm at 3.4MHz with excellent attenuation at cut-off frequencies or reject bands.

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References

C. Laporte, L. Schwartz, E. Saugier, S. Charley, and H. Ezzeddine, “Compact 5G N77 bandpass filter design mixing IPD and MIS technologies”, in Proc. Of European Microve Conference, pp. 203-206, 2022.

Y. Wu, E. Fourn and P. Besnier, “A Planar Quad-band Band-Pass Filter Employing Dual-Mode Band-Stop Resonators”, in Proc. IEEE MTT-S International Microwave Filter Workshop (IMFW), pp. 79-81, 2021.

V. S. Kushwa and G. S. Tomar, “Design of First Order Parallel Coupled Microstrip Band Pass Filter in Mobile Band”, in Proc. Of IEEE International Conference on Computational Intelligence and Communication Networks, pp. 31-39, 2018.

R. Gómez-García, L. Yang, and D. Psychogiou, “A Frequency Transformation for Co-Designed Multi-Passband/Multi-Embedded-Notch RF Filters”, IEEE Transactions on Circuits And Systems—II: Express Briefs, Vol. 68, (7), pp. 2429-2433, 2021.

F. Wang and B. Luo, “A Novel Design of Wi-Fi Band-pass Filter with Symmetrical Zeros” in Proc. Of IEEE International Conference on Communications, Information System and Computer Engineering (CISCE), pp. 231-234, 2022.

LIN J Y, WONG S W, WU Y M, et al: “Three-way multiple-mode cavity filtering crossover for narrowband and broadband applications”, IEEE Trans. Microwave Theory Technology, 67(3) :896-905, 2019.

L. Zirui,C. Zhongrong, “Design of 400 MHz Ultra⁃narrowband Microwave Filter”, Modern Electronics Technique, Vol. 44 (11), pp. 19–22, 2021.

R. R. Mansour, “Filter technologies for Wireless Base Station Filters,” IEEE Microwave Mag., Vol. 5 (1), pp. 68–74, 2004.

A. A. Bisu, “Design and Simulation of a 4th Order High Frequency Bandpass Filter for RADAR Communication Systems”, Journal of the Nigerian Association of Mathematical Physics (JNAMP), 2024

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Published

2024-05-27

How to Cite

PRACTICAL IMPLEMENTATION AND TESTING OF A 3.6 MHZ BANDPASS FILTER. (2024). The Journals of the Nigerian Association of Mathematical Physics, 66, 191-196. https://doi.org/10.60787/jnamp-v66-326

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