In this paper, a pentagon slot inside fractal circular patch microstrip resonator to design compact antenna over partial ground plane is introduced using 3rd iteration of adopted fractal geometry. This antenna is modeled on FR4 substrate with a size of (20 x 18) mm2, thickness of 1.5mm, permittivity of 4.3 and loss tangent of 0.02. The used type of feeding is microstrip line feed. It is designed to operate at wide frequency range of (4.5-9.3) GHz at resonant frequencies of 5.7GHz and 7.9GHz with impedance bandwidth of 4.8 GHz. Both lengths of ground plane Lg and width of feed line Wf are optimized in order to acquire optimum bandwidth. The simulated return loss values are -33 and -41 dB at two resonant frequencies of 5.7 and 7.9 GHz with gain of 3.2 dB. The simulated results offered noteworthy compatibility with measured results. Also, the proposed wideband microstrip antenna has substantial compactness that can be integrated within numerous wireless devices and systems.
In this paper, a miniature rectangular microstrip antenna over partial ground plane is presented by utilizing a space-filling property of fractal geometry in this design. It is simulated by High Frequency Software Simulator (HFSS) software, fabricated and tested by Vector Network Analyzer (VNA).Two types of slots are introduced in order to enhance antenna parameters such as bandwidth and return loss S1.1. This antenna is fabricated on FR4 substrate with a small size of (18 x 16 x 1.5) mm3, 1.5mm substrate thickness, 4.3 permittivity and 0.02 loss tangent. To feed this antenna, microstrip line feed is used. This antenna is implemented for wide bandwidth (4.8-11.6) GHz, and has three resonant frequencies at 5.5GHz, 8.3GHz and 10.7GHz with impedance bandwidth of 6.8GHz. The gap value g between partial ground plane and rectangular patch at top layer is optimized in order to achieve optimal simulated return loss S1.1 is (-46,-32,-14) dB at three resonant frequencies (5.5, 8.3, 10.7) GHz and optimal radiation efficiency of 93.42% with gain of 3.63dB. The simulated results have tolerable agreement with measured results. This antenna is suitable for wireless computer applications within C and X band communications.
In this paper, a square Sierpinski fractal microstrip patch antenna over a rectangular-shaped partial ground plane is introduced. A self-similar property of fractal geometry is used based on the iteration algorithm that reaches up to four iterations. It is simulated by High-Frequency Structure Simulator (HFSS) software package version.14. A square slot is used to enhance antenna performance such as bandwidth and reflection coefficient S11. This antenna has been designed on an FR4 substrate with a compact size of (34×34) mm2, 1.5mm substrate thickness h, a permittivity of 4.3 and 0.02 loss tangent. Microstrip line feed is implemented to excite the proposed antenna. This antenna is designed for wide bandwidth (2.7-5.7) GHz, and it has two resonant frequencies at 3.2GHz and 4.8GHz with an impedance bandwidth of 3GHz. Four parameters are optimized in order to achieve wider bandwidth such as length of ground Lg , the width of feed line Wf , square slot area, and feed point position X. Also, the surface current distribution at various frequencies is presented. Simulation results indicate a good reflection coefficient S11 values equal to -17.7 dB and -43.1dB at two resonant frequencies (3.2, 4.8) GHz and radiation efficiency about 75% with a peak gain of 3.72dB. This antenna is suitable for various wireless applications such as S-band applications like radar and some communication satellite such as (wireless LAN, Bluetooth, GPS, microwave devices/communications and mobile phone), also it can be used in the lower portion of C-band.
In this paper; a wideband fractal circular rings shaped microstrip antenna over partial rectangular ground plane is presented. Fractal geometry technique is used in order to take advantage of its selfsimilar property which lead to attain not only size miniaturization but also wider bandwidth and iteration method is utilized that reach up to third iteration. The proposed model is simulated by High Frequency Structural Simulator (HFSS) package. Such model is designed on FR4 substrate with a compact size of (20×18×1.5) mm 3 , 4.3 permittivity and 0.02 loss tangent. The microstrip line feed is used to feed this antenna with a length of 4.65mm and width of 3mm, in order to increase the impedance bandwidth of proposed model to 67.64%. This model is designed to operate at a range of frequency (4.5-9.1) GHz with two resonant frequencies at 5.6GHz and 8GHz. The length of ground plane Lg is optimized for enhance antenna parameters such as input reflection coefficient and Bandwidth. The simulation results show that the input reflection coefficient values are-54.5 dB and-46.5 dB at two resonant frequencies 5.6GHz and 8GHz. Also, radiation efficiency of proposed antenna is 97.29% with peak gain of 4.34dB. This antenna is appropriate for various wireless Applications such as satellite communication, weather radar, (Industrial Scientific Medical) ISM band and (Wireless Fidelity) Wi-Fi.
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