Bandwidth and Return Loss Improvement Technique Using Double-Material Substrate Cylindrical Surrounding Patch Antenna:Part-I

Bandwidth and Return Loss Improvement Technique Using DoubleMaterial Substrate Cylindrical Surrounding Patch Antenna:PartI

  IJETT-book-cover           
  
© 2021 by IJETT Journal
Volume-69 Issue-12
Year of Publication : 2021
Authors : Elliot O. Omoru, Viranjay M. Srivastava
DOI :  10.14445/22315381/IJETT-V69I12P230

How to Cite?

Elliot O. Omoru, Viranjay M. Srivastava, "Bandwidth and Return Loss Improvement Technique Using DoubleMaterial Substrate Cylindrical Surrounding Patch Antenna:PartI," International Journal of Engineering Trends and Technology, vol. 69, no. 12, pp. 252-256, 2021. Crossref, https://doi.org/10.14445/22315381/IJETT-V69I12P230

Abstract
For the purpose of bandwidth enhancement, return loss improvement, and providing a solution to the negative effect of dimension inaccuracy, a Double Material Substrate (DMS) antenna composed of FR-4 (lossy), polyimide (lossy), and a partial ground plane of copper (annealed) has been presented in this work. The proposed antenna has been compared with a Single Material Substrate (SMS) antenna composed of FR-4 (lossy) and a partial ground plane of copper (annealed). Findings reveal that the cylindrical conformal antennas designed with DMS are significantly better in terms of bandwidth and return loss. The antenna with SMS presented a return loss and bandwidth value of -27 dB and 0.783 GHz (1962 MHz ~ 2745MHz), respectively, at a resonance frequency of 2.4 GHz. Also, at the same resonance frequency, the DMS antenna presented an enhanced return loss and bandwidth of -35.2 dB and 0.862 GHz (1844 MHz ~ 2700 MHz), respectively.

Keywords
Bandwidth, Returns Loss, WiMAX, WLAN, Cylindrical Surrounding Patch Antenna (CSPA).

Reference
[1] J. Anguera, A. Andújar, and J. Jayasinghe, High directivity microstrip patch antennas based on TModd-0 Modes, IEEE Antennas and Wireless Propagation Letters, 19(1) (2020) 39-43.
[2] A. S. Oluwole and Viranjay M. Srivastava, Design of smart antenna by circular pin-fed linearly-polarized patch antenna, International Journal of Wireless and Microwave, 3 (2016) 40-49.
[3] C. A. Balanis, Antenna theory analysis and design, 4th Edition, John Wiley & Sons, Hoboken, New Jersey, (2016).
[4] Y. Liu, L. M. Si, M. Wei, P. Yan, P. Yang, H. Lu,C. Zheng, Y. Yuan, J. Mou, L. Xin, and H. Sun, Some recent developments of microstrip antenna, International Journal of Antennas and Propagation, 2012 (2012) 1-10.
[5] A. Elrashidi, K. Elleithy, and Hassan Bajwa, The Performance of a cylindrical microstrip printed antenna for TM10 Mode as a function of temperature for different substrates, International Journal of Next-Generation, 3(3) (2011) 1-18.
[6] W. Geyi, A method for the evaluation of small antenna Q, IEEE Transactions on Antennas and Propagation, 51(8) (2003) 2124-2129.
[7] H. F. Abutarboush, W. Li, and A. Shamim, "Flexible-screen-printed antenna with enhanced bandwidth by employing defected ground structure," IEEE Antennas and Wireless Propagation Letters, vol. 19, no. 10, pp. 1803-1807, Oct. 2020.
[8] KwaiM. Luk and KaiF. Lee, Characteristics of the cylindrical-circular patch antenna, IEEE Transactions on Antennas and Propagation, 38(7) (1990) 1119-1123.
[9] Gurpreet Singh, R. Rajni, and Ranjit S. Momi, “Microstrip patch antenna with the defected ground structure for bandwidth enhancement, "International Journal of Computer Applications vol. 73, no. 9, pp. 14-18, July 2013.
[10] Elliot O. Omoru and Viranjay M. Srivastava, MOSFET based absorber for reflected signal in 5G massive MIMO base station - A circuit perspective, Journal of Communications, 15(11) (2020) 833-840.
[11] Elliot O. Omoru and Viranjay M. Srivastava, Simulation analysis of MOSFET based absorber for reflected RF signal in 5G massive MIMO base station, International Journal of Emerging Trends in Engineering Research, 8(251) (2020) 6488-6495.
[12] Elliot O. Omoru and Viranjay M. Srivastava., Parametric analysis of SiO2 MOSFET based absorber for 5G massive MIMO base Station, 6th International Conference on Material Engineering and Application, Jakarta, Indonesia, (2021) 20-22.
[13] L. C. Paul, M. S. Hossain, and S. Sarker, The effect of changing substrate material and thickness on the performance of inset feed microstrip patch antenna, American Journal of Networks and Communications, 4(3) (2015) 54-58.
[14] M. Karthigai Pandian and T. Chinnadurai, Design and optimization of rectangular patch antenna based on FR4, Teflon and Ceramic substrates, Recent Advances in Electrical & Electronic Engineering, 12(1) (2019) 1-6.
[15] N. Jayarenjiniand C. Unni, A novel microstrip slotted patch antenna using different dielectric substrates for multiple applications, International Journal of Applied Engineering Research, 13(16) (2018) 12591-12596.
[16] Dhawan Singh and Viranjay M. Srivastava., An analysis of RCS for dual-band slotted patch antenna with a thin dielectric using shorted stubs metamaterial absorber, International Journal of Electronics and Communications, 90 (2018) 53-62.
[17] S. K. Kundu, S. Jaiswal, and P. K. Singhal, Study and comparison of a planar and cylindrical patch antenna, 8th International Conference on Communication Systems and Network Technologies (CSNT), India, (2018) 10-16, 24-26.
[18] A. Elrashidi, K. Elleithy, H. Bajwa., Performance analysis of a microstrip antenna conformed on the cylindrical body at resonance frequency 4.6 GHz for TM01 mode, Procedia Computer Science, 10, (2012) 775-784.
[19] Ahmed I. Imran and Taha A. Elwi, A cylindrical wideband slotted patch antenna loaded with frequency selective surface for MRI applications, Engineering Science and Technology, an International Journal, 20(3) (2017) 990-996.
[20] Dhawan Singh, Aditi Thakur, and Viranjay M. Srivastava, Miniaturization and gain enhancement of microstrip patch antenna using defected ground with EBG, Journal of Communications,13(12) (2018) 730-736.
[21] A. Elrashidi, K. Elleithy, and H. Bajwa, Performance analysis of a microstrip antenna conformed on the cylindrical body at resonance frequency 4.6 GHz for TM01 mode, Procedia Computer Science, 10 (2012) 775-784.
[22] Erhiega N. Umayah and Viranjay M. Srivastava, Radiation pattern of novel cylindrical surrounding patch antenna for 2.4 GHz applications, International Journal of Electrical and Electronic Engineering and Telecommunications, 8(4) (2019) 213-220.
[23] Erhiega N. Umayah and Viranjay M. Srivastava, Comparative analysis of feeding techniques for cylindrical surrounding patch antenna, International Journal of Electrical and Computer Engineering, 10(5) (2020) 5377-5384.
[24] Zhijun Zhang, Antenna measurement, Antenna design for mobile devices, 2nd Ed, Wiley-IEEE Press, (2017) 229-275.
[25] Abdelmonem Abdelaziz, Bandwidth enhancement of microstrip antenna, Progress In Electromagnetics Research, 63 (2006) 311-317.
[26] S. Chakraborty and U. Mukherjee, Comparative study of microstrip patch line feed and coaxial feed antenna design using genetic algorithms, 2ndInternational Conference on Computer and Communication Technology, India, (2011) 203-208.
[27] C. L. Wen and Q. X. Chu, A Bandwidth enhanced broadband patch antenna for LTE700/GSM850/GSM900 applications, Cross-Strait Radio Science & Wireless Technology Conference (CSRSWT), China, 1-3 (2020) 13-16.
[28] P. Kumar Deb, T. Moyra, and P. Bhowmik, Return loss and bandwidth enhancement of microstrip antenna using defected ground structure, 2nd International Conference on Signal Processing and Integrated Networks (SPIN), India, 25(29) (2015) 19-20.
[29] A. A. Qureshi, M. U. Afzal, T. Tauqeer, and M. A. Tarar, Performance analysis of FR-4 substrate for high-frequency microstrip antennas, Joint Microwave Conference, China, 1(4) (2011) 20-22.
[30] S. B. Yeap and Z. N. Chen, Microstrip patch antennas with enhanced gain by partial substrate removal, IEEE Transactions on Antennas and Propagation, 58(9) (2010) 2811-2816.