A Wideband Hybrid Fractal Ring Antenna for WLAN Applications

Jamil, Atif; Rauf, Muhammad; Sami, Abdul; Ansari, Arsalan; Dawood Idrees, Muhammad

doi:https://doi.org/10.1155/2022/6136916

International Journal of Antennas and Propagation

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Antennas for 5G and Future Communication Systems

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Research Article | Open Access

Volume 2022 | Article ID 6136916 | https://doi.org/10.1155/2022/6136916

A Wideband Hybrid Fractal Ring Antenna for WLAN Applications

Atif Jamil,¹Muhammad Rauf,¹Abdul Sami,¹Arsalan Ansari,¹and Muhammad Dawood Idrees²

Academic Editor: Muhammad Inam Abbasi

Received17 Sept 2021

Revised03 Jan 2022

Accepted08 Jan 2022

Published21 Feb 2022

Abstract

We propose the design of a novel fractal antenna that is both unique and performance-driven. Two important antenna design features, miniaturization and wideband operation, are combined in this work. A ring-shaped antenna is designed using the well-known fractal geometry. This hybrid geometry is a fusion of meander and Koch curve shapes. The geometrical construction of the proposed antenna is compared to the standard Koch curve geometry. It is shown that combining the meander and Koch curve shapes increases the effective electrical length. The wider bandwidth is achieved by bringing the higher modes together. The overall dimensions of proposed meander Koch curve fractal ring antenna are 45 × 25 × 1.6 mm³. The resonance frequency of the antenna is between 4.94 and 6.12 GHz (% BW = 21.83), which covers the entire 5 GHz WLAN band. The prototype has been fabricated and experimentally verified.

1. Introduction

The advancement of wireless communication technology has raised the bar for modern living. The sophisticated devices have brought a great degree of freedom to the conventional stationary working styles. The demand for data-hungry applications and multimedia streaming videos has given rise to the improved quality of service (QoS) in wireless communication systems. Antenna, an essential part of wireless communication system, must respond to the call of QoS improvement by enhancing its performance by aiming wide bandwidth, high gain, reduced return loss, omnidirectional radiation pattern, low cross-polarization, and reduced cost for fabrication. Fractal geometry has a long history; since its inception, fractals have been practically deployed in various technical fields. Mandelbrot introduced the term fractal from the Latin word “Fractus” in 1975 [1, 2]. Fractals shapes are nowhere differentiable as they are resultant of a recursive process. The increased bandwidth has been linked to fractal geometry’s self-similar, convoluted and jagged structures. Additionally, fractal geometry is used in antennas because of its unique properties, including small size and multiband/wideband behavior [3]. Numerous researchers have advocated incorporating fractal geometry into their antenna research. Several antenna geometries have been examined, including Koch, Cantor, Sierpinski, fractal tree, and Minkowski. In [4], an octagonal Fractal microstrip patch antenna with a superwideband bandwidth range of 10 GHz–50 GHz has been presented. For numerous applications such as PCS, WLAN, WiFi, WiMax, and other communication systems, a Koch-like fractal curve has been proposed [5]. A Pythagorean tree was placed in a T-patch to form an ultrawideband (UWB) antenna [6]. Grounded coplanar waveguides have been used to enhance the bandwidth of conventional Sierpinski carpet antenna [7]. Additionally, various fractal shapes have been used to improve the properties of the dielectric resonator antennas [8–13].

Numerous fractal geometries have been combined to enhance the properties of fractal antennas such as multiband/wideband operation and size reduction. Using Koch curves as inductive loading and Sierpinski carpet as a slot loading, the resonant frequency and the size of a patch antenna can be reduced, as shown by experiments in [14]. Fractal shapes have been modified to alter the characteristics of the antenna which are driven by the shape of antenna. A perturbed Sierpinski fractal antenna with slotted ground plane has been proposed for GSM/DCS/PCS/IMT-2000/ISM/satellite DMB bands [15]. For a WLAN USB dongle, the hybrid meander-Koch monopole antenna was presented in [16]. The antenna is multiband-capable, operating throughout the whole IEEE 802.11 a/b/g spectrum. In [17], a UWB antenna based on Giuseppe Peano and Sierpinski carpet fractal geometries was proposed. Two different fractal antennas have been fused together to design a multiband antenna for Wi-Max and C-band applications [18]. A multiband hybrid fractal antenna based on Koch–Minkowski geometry has been developed for use in a variety of wireless applications [19]. A report on the construction of a hybrid fractal antenna comprising Giuseppe Peano, Cantor set, and Sierpinski carpet for industrial, scientific, and medical (ISM) band has been presented in [20]. A hybrid fractal antenna based on Moore, Minkowski, and Koch curve for multiband applications such as Wi-Fi, Bluetooth, and Wi-MAX has been reported in [21]. A hybrid fractal antenna with a defected ground structure (DGS) was optimized for S, C, and X applications using artificial neural networks (ANNs) [22]. An ultrawideband hybrid fractal antenna based on Koch and Sierpinski Fractals has been reported in [23]. Using the well-known Minkowski and Hilbert curves, a hybrid fractal antenna has been designed [24].

In this paper a hybrid Fractal antenna geometry has been proposed for 5 GHz WLAN band. The antenna has been constructed by merging the meander and Koch curve geometries. The antenna has been experimentally studied to optimize its performance impedance bandwidth. The proposed antenna has been designed to operate in the IEEE 802.11a (WLAN) i.e., 5.15–5.825 band. The antenna prototype has been physically analysed and the actual measurement results have been found to be in good agreement with the simulation results. The simulation and measurement results indicate that the proposed antenna can achieve an impedance bandwidth of more than 1 GHz at –10 dB scale. The configuration of the proposed antenna has been described in Section 2. Section 3 presents a study on the parametric optimization of the proposed meander-Koch Fractal ring antenna. Experimental results have been presented in Section 4. The conclusion follows in Section 5.

2. Antenna Design

Figure 1 illustrates the suggested antenna design. The hybrid meander-Koch Fractal ring antenna measures 45 × 25 mm² in total and is printed on top of FR-4 dielectric substrate. The dielectric substrate has a height of h = 1.6 mm and a relative dielectric constant of = 4.34. The antenna is fed with a microstrip transmission line terminated with a 50 Ω feeder. The proposed antenna has a ground plane on the opposite side of the radiating hybrid meander-Koch Fractal ring element.

The construction of the hybrid meander-Koch Fractal ring antenna is defined by using the iteration function system (IFS) algorithm [25–30]. To justify the complex design and construction of a new Fractal shape, the proposed hybrid meander-Koch Fractal antenna’s generator is compared to that of a standard Koch curve Fractal antenna. The shapes are compared according to their ability to increase the effective electrical length.

2.1. Construction of Standard Koch Curve Using IFS

Helge von Koch, a Swedish mathematician, invented the standard Koch curve geometry in 1904 [28]. The standard Koch is constructed using the initiator-generator method. As illustrated in Figures 1(a)–1(c), this method applies several transformations to a straight line in order to convert it to a Koch shape. A straight line (initiator) is divided into three equal sections, with the middle section further subdivided into two equal sections. The resultant shape is called the generator, and this procedure can be repeated to achieve the higher iterations.

The IFS algorithm is used to construct the standard Koch curve shown in Figures 1(a)–1(c). The IFS is formed by the set of affine transformations to generate the standard Koch. In its construction, it is assumed that a straight line of unit length is placed along the x-axis with its left end placed at the origin. The transformations used to construct the Koch curve antenna’s generator are as follows:

The generator is obtained by combining the segments as

The procedure described previously can be used to generate iterations of higher order. To generate self-similar geometry, the distance between the start and end points of all iterations must be the same. The dimensions of self-similarity are calculated as

This implies that four identical copies are scaled by a factor of three during each iteration.

2.2. Construction of Hybrid Meander-Koch Curve Using IFS

Hybrid fractal geometries are created by fusing two fractal geometries together or by fusing a fractal shape with a nonfractal shape. Additionally, certain hybrid fractal shapes can be created by combining multiple shapes. As illustrated in Figures 2(a)–2(c), the hybrid meander-Koch curve generator is created by combining the meander and Koch curve shapes. The meander and Koch curve generators (first iteration) each contain four and five segments, respectively. However, as illustrated in Figure 2(b), when the two shapes are combined, the resulting generator contain eight segments. This method clearly contributes to antenna's size reduction by increasing the effective electric length. The IFS algorithm for constructing the segments of the meander-Koch curve fractal antenna is as follows:where the generator W(A) is obtained by combining W₁ to W₈ which are the set of linear affine transformations and A is the initial geometry. The fractal dimension D for the 1^st transformation of the meander-Koch curve Fractal antenna is calculated aswhere N is the total number of segments at each iteration and r is number by which the initiator is divided at each iteration.

2.3. Development of Hybrid Meander-Koch Fractal Ring Antenna

The proposed antenna in this section has a ring type structure, and it has been formed by following the basis of the fractal geometry. The generator is a meander-Koch curve shape, and the initiator is a trapezoid-like shape with three linear strips that are presented for transformation, as shown in Figure 3(a). The transformation has been carried out in two-steps: in the first step, a meander pattern is applied on each leg of the trapezoid resembling shape. In the next step, the Koch fractal pattern is applied at the top of the meander element, and this is achieved by forming an upper portion of the equilateral triangle in the middle of the meander shape. As a result of this two-step transformation, all the three linear segments have been replaced by the meander-Koch elements, and the obtained shape is illustrated in Figure 3(b). In Figure 3(c), a segment of the microstrip line has been used to interconnect the two arms through the open ends to form a closed loop radiating structure. Practical limitations exist in terms of applying the higher order iterations to design the fractal antennas. These include the overlap between the strips of the adjacent segments in the geometry which consequently deforms its shape. To avoid this situation, the line width should be very narrow; however, this could give rise to the conductor losses which reduces the radiation efficiency. Therefore, the iterative transformation on the meander-Koch Fractal ring antenna has been limited up to the second iteration. Moreover, the dimensions of the proposed meander-Koch fractal ring antenna have been presented in Figure 4 and Table 1.

3. Parametric Optimization

After the design of the proposed antenna using IFS, it has been analysed in commercial full-wave simulator CST Microwave Studio (MWS) for studying the effects of the variation of the design parameters. Design goals have been set to achieve an impedance bandwidth that can cover the entire 5 GHz band. In order to realize such an antenna with desired performance, a series of parametric studies have been performed on important design parameters. As elaborated in Section 2.3, the geometric construction of the resultant antenna shape started from an initiator that resembles a trapezoid shape which was presented for transformations using the meander-Koch curve shape. Figure 5 shows the optimization study which has been carried on different lengths of the ring-type antenna. The length L_M-kr of the radiating element has been optimized to make the antenna resonant on the entire 5 GHz band.

A similar study has been conducted to study the effects of the variation of the fractal ring in Figure 6. The thickness W_M-kr of the ring has been varied from 1.1 mm to 1.3 mm with a step size of 0.1 mm. It has been noticed that, as the strip thickness increases, the effective perimeter of the ring geometry also increases which results in frequency reduction.

Figure 7 shows the parametric study on the width of the transmission feed line W_f. It has been optimized to maintain the reflection coefficient at −10 dB level for the bandwidth covering from 4.94 GHz to 6.12 GHz. The width of the transmission line is also a crucial parameter that needs optimization because it is a known reason for impedance mismatch between the antenna and feed line.

The ground plane plays a significant role in the radiation of small antennas. Certain parameters are adversely affected by the small ground plane size. These degradations include a shift in resonant frequencies, impedance mismatch, narrow impedance bandwidth, low gain, low efficiency, and distorted radiation patterns. As illustrated in Figure 8, the final parametric study has been performed by varying the size of the ground plane to avoid the inaccurate measurement results due to cable effects. However, in the optimization process on the size of the ground plane G, it was noticed that the width of the ground plane has a considerable effect on the resonant frequency and the input impedance, whereas the length has negligible effect on the said parameters. Therefore, for this study the length ( = 26 mm) of the ground plane has been kept constant to perform this study.

4. Experimental Results

In Figure 9, the fabricated prototype of the proposed meander-Koch Fractal ring antenna has been presented. It can be noticed from the comparison curves (simulation and measurement), presented in Figure 10, that antenna has satisfactory return loss result. The antenna is designed to operate on the 5 GHz WLAN band. The measured S₁₁ plot, as shown in Figure 10, of the proposed antenna shows an impedance bandwidth of 1.18 GHz at −10 dB scale.

(a)

(b)

The simulated and measured far-field radiation patterns of the proposed meander-Koch ring fractal antenna are presented in Figure 11. From the results, the radiation patterns of the meander-Koch fractal ring antenna are omnidirectional, and the antenna has a considerable gain from 0 to 2π radians in both the X-Z and Y-Z planes. Moreover, the measured far-field plot of the proposed antenna in Figure 11(a) illustrates that the proposed meander-Koch fractal ring antenna has symmetric radiation patterns in both the X-Z and Y-Z planes. Figure 11(a) depicts the simulated X-Z plane radiation patterns for the meander-Koch ring fractal antenna, where it has a maximum gain of 3.5 dBi and doughnut-shaped radiation pattern could be easily noticed. In case of measured results, the maximum gain is 3 dBi. Furthermore, Figure 11(b) shows the radiation patterns of the meander-Koch fractal ring antenna in the Y-Z plane. The simulation result shows that the maximum gain is 1.8 dBi, whereas the measurement result shows a maximum gain of 1.43 dBi.

(a)

(b)

5. Conclusion

In this paper, a hybrid meander-Koch fractal ring antenna has been proposed for 5 GHz WLAN band. The IFS algorithm to construct the generator of the proposed antenna has been compared to the standard Koch curve antenna. Due to an increase in the number of segments of the resulting convoluted shape, the electrical length has been increased, thus miniaturizing the antenna size. Several antenna dimensions have been optimized through the parametric study in CST MWS. The antenna prototype has been realized, and the comparison between the simulated and measurement results has been presented, which confirms the practicality of the proposed antenna.

Data Availability

No data were used to support this study.

Conflicts of Interest

All authors declare that they have no conflicts of interest.

Authors’ Contributions

All authors contributed equally in this work.

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Copyright

Copyright © 2022 Atif Jamil et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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