Performance Improvement of Fractal Microstrip Antenna with Metamaterial
الموضوعات : Majlesi Journal of Telecommunication DevicesGohar Varamini 1 , Mehdi Khatir 2 , Mohammad Naser-Moghadasi 3
1 - Department of Electrical Engineering, Beyza Branch, Islamic Azad University, Beyza, Iran
2 - Department of Electrical and Computer Engineering, Science and Research Branch, Islamic Azad University, Tehran, Iran
3 - Department of Electrical and Computer Engineering, Science and Research Branch, Islamic Azad University, Tehran, Iran
الکلمات المفتاحية: circular polarization, Metamaterial, Fractal Microstrip,
ملخص المقالة :
This study was carried out to design, simulate, and develop an ultra wideband (UWB) fractal microstrip patch antenna (MPA). The antenna designed for broadband telecommunications had smaller dimensions, omnidirectional pattern, and good gain/return loss. The miniaturization was realized through a metamaterial transmission line and antenna power supply by an electromagnetic coupling system. In order to cover the desired frequency bandwidth, a new fractal was designed and combined with the circular polarization of disturbances in certain parts of the fractal structure. Furthermore, the quality of antenna bandwidth was improved deforming the ground plane. Finally, the results of the development, simulation, and measurement of input return losses and radiation patterns were explored. The results demonstrated that the proposed model involves a compact, simple fractal MPA that provides ideal bandwidth and impedance matching.
[1] Garg, Ramesh, Microstrip Antenna Design Hand Book, Artech house, 2001.
[2] Pozar, David M. “Scanning Characteristics of Infinite Arrays of Printed Antenna,” EEE transactions on antennas and propagation 40.6 (1992): 666-674.
[3] Mookiah, Prathaban, and Kapil R. Dandekar. “Performance Analysis of Metamaterial Substrate Based MIMO Antenna Arrays,” Global Telecommunications Conference, 2008. IEEE GLOBECOM 2008. IEEE. IEEE, 2008.
[4] Lui, H-S., and H. T. Hui. “Improved Mutual Coupling Compensation in Compact Antenna Arrays,” IET microwaves, antennas & propagation 4.10 (2010): 1506-1516.
[5] Cruz, Catarina C., Jorge R. Costa, and Carlos A. Fernandes.”Hybrid UHF/UWB Antenna for Passive Indoor Identification and Localization Systems,” IEEE Transactions on Antennas and Propagation 61.1 (2013): 354-361.
[6] Zaker, Reza, Changiz Ghobadi, and Javad Nourinia. “Novel Modified UWB Planar Monopole Antenna With Variable Frequency Band-Notch Function,” IEEE Antennas and Wireless Propagation Letters 7 (2008): 112-114.
[7] Kasi, Baskaran, Lee Chia Ping, and Chandan Kumar Chakrabarty. “A Compact Microstrip Antenna for Ultra Wideband Application,” European Journal of Scientific Research 67.1 (2011): 45-51.
[8] Ha, Jaegeun, et al. “Hybrid Mode Wideband Patch Antenna Loaded With a Planar Meta material Unit Cell,” IEEE Transactions on Antennas and Propagation 60.2 (2012): 1143-1147.
[9] Bakariya, Pritam S., Santanu Dwari, and Manas Sarkar “Triple Band Notch UWB Printed Monopole Antenna With Enhanced Bandwidth,“ AEU-International Journal of Electronics and Communications 69.1 (2015): 26-30.
[10] Raju, Salahuddin, et al.” Modeling of Mutual Coupling Between Planar Inductors in Wireless Power Applications,” IEEE Transactions on Power Electronics 29.1 (2014): 481-490.
[11] Ouedraogo, Raoul O., et al. “Miniaturization of Patch Antennas Using a Metamaterial-Inspired Technique,” IEEE Transactions on Antennas and Propagation 60.5 (2012): 2175-2182.
[12] Naser‐Moghadasi, M., et al. “Small Circular-Shaped UWB Antenna for Wireless Communication Applications,” Microwave and Optical Technology Letters 54.12 (2012): 2885-2888.
[13] Rybin, Oleg, and Shengxiang Wang. “Substrate Application of Electrically Enhanced Microwave Metamaterials,” Mathematical Methods in Electromagnetic Theory (MMET), 2014 International Conference on. IEEE, 2014.
[14] Mohammed, Beada'A. Jasem, et al. “Compact Wideband Antenna for Microwave Imaging of Brain,” Progress In Electromagnetics Research C 27 (2012): 27-39.
[15] Abu Bakar, Aslina, et al. “Experimental Assessment Of Microwave Diagnostic Tool for Ultra-Wideband Breast Cancer Detection,” Progress in Electromagnetics Research M 23 (2012): 109-121.
[16] Rybin, Oleg. “Effective Microwave Magnetic Response of Two-Component Metaferrite,” International Journal of Applied Electromagnetics and Mechanics 40.3 (2012): 185-193.
[17] Rybin, Oleg. “Microwave Effective Medium Theory for Two-Component Magnetic Metamaterials,” International Journal of Applied Electromagnetics and Mechanics 35.2 (2011): 93-101.
[18] Wang, Ping, et al.”A Wideband Conformal End-Fire Antenna Array Mounted on a Large Conducting Cylinder” IEEE Transactions on Antennas and Propagation 61.9 (2013): 4857-4861.
[19] Mahfouz, Mohamed R., et al. “Investigation Of High-Accuracy Indoor 3-D Positioning Using UWB Technology” IEEE Transactions on Microwave Theory and Techniques 56.6 (2008): 1316-1330.
[20] Elsherbini, Adel, et al.”UWB Antipodal Vivaldi Antennas With Protruded Dielectric Rods For Higher Gain, Symmetric Patterns And Minimal Phase Center Variations,” Antennas and Propagation Society International Symposium, 2007 IEEE. IEEE, 2007.
[21] Alhawari, Adam Reda Hasan, et al. “Antipodal Vivaldi Antenna Performance Booster Exploiting Snug-In Negative Index Metamaterial,” Progress In Electromagnetics Research C 27 (2012): 265-279.
[22] Rao, Neeraj, and Dinesh Kumar. “Modified Sierpinski Fractal Patch Antenna.” Antennas and Propagation Conference (LAPC), 2014 Loughborough. IEEE, 2014.
[23] Rybin, O., and S. Shulga. “Substrate Application of Magnetic Metamaterial ,” Antenna Theory and Techniques (ICATT), 2015 International Conference on. IEEE, 2015.
[24] Ghatak, Rowdra, et al. “Moore Curve Fractal-shaped Miniaturized Complementary Spiral Resonator”, Microwave and Optical Technology Letters 55.8 (2013): 1950-1954.
[25] Kim, Oleksiy S., and Olav Breinbjerg. "Miniaturized self-Resonant Split-ring Resonator Antenna," Electronics letters 45.4 (2009): 196-197.
[26] Erentok, Aycan, and Richard W. Ziolkowski. "Metamaterial-inspired Efficient Electrically Small Antennas," IEEE Transactions on Antennas and Propagation 56.3 (2008): 691-707.
