Design of multiband microstrip patch antenna with bandwidth enhancement for wireless communication system
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Abstract
This research work presents analysis of multiband rectangular microstrip patch antenna for globalsystem for mobile communications at 0.9455GHz and 1.7595GHz and wireless local area Network at 2.4635 GHZ and 5.15 GHz and WiMAX at 3.5745GHz and international mobile telecommunications (IMT) at 4.46 GHz . An antenna is designed using FR4-(epoxy) substrate material with thickness1.6 mm and dielectric constant of 4.3. The microstrip antenna has a patch dimension of 83.33mm×45mm. The antenna has minimum return loss of - 32.563 dB at 0.9455GHz, -27.226 dB at 1.7595 GHz, -29.136 dB at 2.4635GHz, -31.621 dB at 3.5745GHz, -36.531dB at 4.46 GHz, -25.613 at 5.15 GHz. In this antenna designed the maximum gain of 2.20 dB at 0.9455GHz, 3.17 dB at 1.7595 GHz, 5.68 dB at 2.4635GHz , 7.04 dB at 3.5745 GHz, 6.08 dB at 4.46GHz, 5.26 dB at 5.15 GHz. The simulation of the design antenna is done using the software computer simulation technology CST
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References
[1] Srifi, M. N. et al. (2019). Novel Design of Multiband Microstrip Patch Antenna for Wire-less Communication. Advances in Science, Technology and Engineering Systems Journa, 4(3):63-68. [2] Yadav, D. K.; Rai, B. S. and Bharti, G. D. (2016). Design of Multiband Microstrip Antenna for
Wireless Application. Madan Mohan Malaviya University of Technology, Gorakhapur, 2(5):1447-1449. [3] An, W.; Li, Y.; Fu, H.; Ma, J.; Chen, W. and Feng, B. (2018). Low-profile and wideband microstrip antenna with stable gain for 5G wireless applications. IEEE Antennas and Wireless Propagation. Letters, 17(4): 621-624.. [4] Balanis, C. A. (2008). modern antenna handbook, A John Wiley and Sons. Inc., Publication.
[5] Mejda, Ms. G. (2018). Multiband Microstrip Patch Antenna for 4G (LTE). M. Sc. Thesis, Mohamed Khider University of Biskra, Biskra, Algeria: 85pp. [6] Banding, M. and Notching, S. (2017). A review of various multi-frequency antenna design techniques. Indian Journal of Science and Technology, (10)16:1-7.
[7] Huang, Yi, and Boyle, K. (2008). Antennas: from theory to practice. John Wiley and Sons.
[8] Khan, B. (2016). Adaptive vehicular antenna system for extended range cellular access. M.Sc. thesis, University of Oulu, Oulu Finland: 53pp. [9] Pandey, A. (2019). Practical Microstrip and Printed Antenna Design. Artech House.
[10] Mäki, H. (2018). MIMO Antenna Designs for Handsets. M.Sc. thesis, Alto university, Espoo, Finland: 55pp. [11] Abdulhasan, R. A. (2015). Design of microstrip ultra wide band antenna with two notch filters for wireless communication. M.Sc. thesis, University Tun Hussein, Parit raja, Malaysia: 42pp. [12] Chatterjee, S. (2018). A 77 GHz BCB Based High Performance Antenna Array for Autonomous Vehicle Radars. M.Sc. thesis, University of Windsor, Ontario, Canada: 144pp. [13] Shumba, P. (2017). Design and characterization of a microstrip patch antenna for Wi-Fi. M.Sc. thesis, Midlands State University, Gweru, Zimbabwe: 59pp. [14] Rizwan, M. (2015). Performance evaluation of wearable antennas using flexible substrates. M.Sc. thesis, Tampere University of technology, Tampere, Finland: 65pp. [15] AboJalambo, M. I. (2017). Design of Frequency and Pattern Reconfigurable Antenna for UWB Applications. M.Sc. thesis, The Islamic University–Gaza, Gaza, Palestine: 79pp. [16] Moonshiram, A. (2016). Phased Array Antenna with Dielectric Phase Shifters. Ph.D. thesis, University of Luxembourg, Luxembourg, Luxembourg: 140pp. [17] Kumar, G and Ray, K. P. (2003). Broadband microstrip antennas. Artech house.