Open access peer-reviewed chapter

Metamaterial Based Ultra-Wideband Antennas for Portable Wireless Applications

Written By

Mohammad Alibakhshikenari, Mohammad Naser-Moghadasi, Ramazan Ali Sadeghzadeh, Bal Singh Virdee and Ernesto Limiti

Submitted: 09 April 2016 Reviewed: 31 October 2016 Published: 26 April 2017

DOI: 10.5772/66674

From the Edited Volume

Metamaterials - Devices and Applications

Edited by Alejandro Lucas Borja

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Abstract

Antennas are essential for wireless communication systems. The size of a conventional antenna is dictated mainly by its operating frequency. With the advent of ultra-wideband systems (UWB), the size of antennas has become a critical issue in the design of portable wireless devices. Consequently, research and development of suitably small and highly compact antennas are challenging and have become an area of great interest among researchers and radio frequency (RF) design engineers. Various approaches have been reported to reduce the physical size of RF antennas including using high permittivity substrates, shorting pins, reactive components, and more recently, metamaterials (MTM) based on composite right-/left-handed transmission-lines (CRLH-TLs). MTM exhibit unique electromagnetic response that cannot be found in the nature. In this chapter, the properties of CRLH-TL are used to synthesize novel and highly compact planar UWB antennas with radiation properties suitable for wireless mobile devices and systems.

Keywords

  • antennas
  • ultra-wideband
  • metamaterials
  • composite right-/left-hand transmission-lines
  • microstrip

1. Introduction

Electronic circuitry in portable wireless devices is incorporated inside a small and highly integrated transceiver unit [14]. Miniaturization of such a system is precluded by the size of the antenna as its dimensions are related to the operating frequency. The most challenging aspect in the development of such systems is the design of miniature antennas [58]. In this chapter, this issue is addressed by using metamaterial technology. Several different antenna configurations are presented based on CRLH-TL/MTM unit cells [922].

In part 2, antenna designs are described based on simplified CRLH-TLs that are implemented using F-shaped and T-shaped dielectric slits embedded on the antenna’s ground-plane and radiating arms, respectively. This antenna is shown to operate across 0.65–9.2 GHz with a maximum gain and radiation efficiency of 3.5 dBi, and 70% at 4.5 GHz, respectively. This antenna has dimensions of 25 × 15 × 1.6 mm3. In another example, how size reduction and bandwidth extension can be achieved using CRLH-TL unit cells that are composed of a U-shaped slit and grounded spiral microstrip stub are shown.

In part 3, the antenna is implemented by cascading together in series several identical MTM unit cells. The unit cell is composed of a transmission line that has engraved on its patch a mirror image of E-shaped slits and high impedance spiral stub that is grounded through a metal via-hole. Two antennas implemented using this technique have dimensions of 0.017λ0 × 0.006λ0 × 0.001λ0 and 0.028λ0 × 0.008λ0 × 0.001λ0, where λ0 is free space wavelength at 500 and 650 MHz, respectively. The respective antennas have bandwidths of 850 MHz (0.5–1.35 GHz) and 1.2 GHz (0.65–1.85 GHz), which correspond to fractional bandwidths of 91.9% and 96.0%, respectively. Besides the small dimensions and wide bandwidth characteristics, the measured gain and efficiency of one antenna at 1 GHz are 5.3 dBi and 85%, respectively; and the second antenna has a gain and efficiency of 5.7 dBi and 90%, respectively, at 1.4 GHz.

In part 4, antenna size reduction and bandwidth extension is realized with MTM unit cells that are composed of U-shaped dielectric slit and spiral conductor that is grounded using via-holes. The design of the antenna presented here functions over the frequency range of 5.8–7.3 GHz, i.e. it has a fractional bandwidth of 23%. The antenna’s performance was measured to verify it has a wide bandwidth, high gain, and high radiation efficiency properties. At 6.6 GHz, the antenna is shown to exhibit a radiation gain of 4.8 dBi, fractional bandwidth of 23%, and efficiency of 78%. Furthermore, the proposed antenna is very compact and has dimensions of 0.39λ0 × 0.13λ0 × 0.015λ0.

In part 5, the MTM unit-cell is composed of T-shaped dielectric slit that is etched on the radiating patch and includes a grounded conductive spiral stub. The T-shaped slit antenna is shown to operate over 1.1–6.85 GHz (fractional bandwidth ~ 145%) with a maximum gain and efficiency of 7.1 dBi and 91%, respectively, at 3.7 GHz. This antenna has an electrical size of 0.05λ0 × 0.02λ0 × 0.002λ0.

The aforementioned MTM antennas exhibit superior performance compared to conventional antennas in terms of fractional bandwidth, gain, and efficiency. These antennas are suitable for UWB wireless communication systems, portable microwave handsets, and transceivers.

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2. UWB antenna based on simplified CRLH-TL

The simplified composite right-/left-handed transmission-lines (SCRLH-TL) used here in the design are a novel planar antenna. The SCRLH-TL is implemented by loading the radiation patch and ground-plane with dielectric T-shaped and F-shaped slits, respectively, as shown in Figure 1. With the assistance of 3D full-wave electromagnetic simulator (HFSS™), the dimensions of the dielectric slits can be optimized. The design of Antenna#1 consists of two identical structures that can be considered to be a mirror image, where one of the structures has been flipped sideways, as shown in Figure 1(a). The F-shaped dielectric slits embedded in the ground-plane essentially behave like left-handed series capacitance; and the T-shaped dielectric slits embedded in the radiation patch are used to enhance the radiation characteristics of the antenna. To improve the impedance matching of the feed-line to the antenna, it is necessary to load the feed-line with an H-shaped microstrip stub, as shown in Figure 1. The two SMA connectors on the opposite sides of antenna are used to excite the antenna through the conductor-backed coplanar waveguide (CPW) transmission-lines.

Figure 1.

Antenna configurations, (a) Antenna#1 and (b) Antenna#2. Design parameters of both antennas are identical. Dimensions (in mm) are annotated.

The gain and radiation efficiency of any antenna can be improved by simply increasing the aperture of the antenna. To increase the magnitude of these two characterizing parameters, the number of patches in the proposed design was increased from two to four, as shown in Figure 1(b). The advantage of the technique presented here in comparison to conventional methods is that it does not affect the physical size of the antenna as the additional patches are contained within the antenna structure. To enhance the antenna’s impedance bandwidth, the number of F-shaped slits in the ground-plane was halved from four to two, thus effectively reducing the left-handed series capacitance.

The antennas were fabricated on RD/duroid® RO4003 substrate with dielectric constantof 3.38, thickness of 1.6 mm, and tanδ of 22 × 10−4. The dimensions of the two antennas are: 25 × 15 × 1.6 mm3 which is equivalent to an electrical size of 0.054λ0 × 0.032λ0 × 0.003λ0, where λ0 corresponds to 0.65 GHz. The antenna’s reflection-coefficient response (simulated and measured) is shown in Figure 2. The antenna’s frequency of operation and bandwidth is given in Table 1. Antenna#1 has a measured bandwidth of 7.4 GHz and Antenna#2 has a bandwidth of 8.55 GHz. The fractional bandwidth of Antenna#2 is 16% greater than Antenna#1. Figure 3 shows the measured antenna gain and efficiency response of both antennas. The antenna gain and efficiency values at spot frequencies are also tabulated in Table 2. Results show that Antenna#2 has a maximum gain and radiation efficiency of 3.5 dBi and 70% at 4.5 GHz, which is higher than Antenna#1 by 25% and 27%, respectively.

Operating frequency range (fractional bandwidth)
SimulatedMeasured
Antenna#10.82–8.6 GHz (165.2%)1–8.4 GHz (157.4%)
Antenna#20.5–9.45 GHz (179.9%)0.65–9.2 GHz (173.6%)

Table 1.

Operating frequency range and impedance bandwidth of the proposed antennas.

AntennasGain (dBi)Efficiency (%)
Ant.#1 @ 1, 4, and 8.4 GHz0.4, 2.8, and 1.515, 55, and 40
Ant.#2 @ 0.65, 4.5, and 9.2 GHz0.2, 3.5, and 1.712, 70, and 42

Table 2.

Gain and radiation characteristics of the two antennas.

Figure 2.

Simulated and measured reflection-coefficient response of the two antennas.

Figure 3.

Measured gain and efficiency response of both antennas.

Radiation characteristics (copolarization and crosspolarization) of the two antennas in the E-plane and H-plane at 2.5 GHz, 4 GHz, and 4.5 GHz are shown in Figure 4. The results show both antennas radiate omnidirectionally in the E-plane and bidirectionally in the H-plane. The low profile UWB antennas facilitate easy integration in wireless systems and can be flush mounted on various structures.

Figure 4.

Measured radiation patterns at 2.5, 4, and 4.5 GHz.

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3. Wideband antenna using E-shaped slit MTM unit cells

The goal in this section is to design antennas that can fit within an area of 15 × 5 mm2 for flush mounting on various structures including vehicles and portable wireless devices, and possess characteristics of wide operational bandwidth with good radiation properties. The unique antenna design is based on MTM unit cell, shown in Figure 5, and comprises a microstrip patch on which is etched mirror image of E-shaped dielectric slits and the unit cell is grounded using a conductive spiral stub. The E-shaped slits and spiral stub act as left-handed (LH) capacitance (CL) and shunt inductance (LL), respectively, corresponding to the negative permeability (μ < 0) and the negative permittivity (ε < 0), respectively, and are represented by [2326]:

μ=Zjω=1ω2CL+LRZ:seriesimpedenceE1
ε=Yjω=1ω2LL+CRY:shuntadmittanceE2

Figure 5.

MTM unit cell geometry.

Surface current flow on the patch constituting the unit cell introduces right-handed (RH) series inductance (LR), and the gap between patch and the ground plane introduces shunt RH capacitance (CR), which are related to positive permeability (μ > 0) and positive permittivity (ε > 0), respectively, defined by Eqs. (3) and (4). The loss in the unit cell structure can be modeled by series RH resistance (RR), shunt LH resistance (RL), shunt RH conductance (GR), and series LH conductance (GL). The equivalent circuit model of the unit cell is shown in Figure 6. The values for the electrical parameters CL, LL, CR, LR, RR, RL, GR, and GL are 4.2 pF, 5.4 nH, 2.1 pF, 2.9 nH, 1.2 Ω, 1.85 Ω, 0.85 Ω, and 1.15 Ω, respectively.

µ=Zjω=LR1ω2CLE3
ε=Yjω=CR1ω2LLE4

Figure 6.

Equivalent circuit model of the MTM unit cell.

Restriction in the antenna size required its characteristics to be optimized by full wave simulators, i.e., Keysight Technologies Advanced Design System (ADS) and Ansys High Frequency Structure Simulator (HFSS™). The antenna’s characteristics were tuned by modifying the dimensions of the E-shaped slit, the gap between slits, the dimensions of the spiral, and the number of spiral turns. The optimized MTM unit cell is shown in Figure 5. The two antenna designs use two and three MTM unit cells, respectively, that are cascaded together in series. The antennas are constructed using standard manufacturing techniques on FR4 substrate with dielectric constant of 4.6, thickness of 0.8 mm, and tanδ of 0.01. The prototype antenna designs are shown in Figure 7. Port 1 is used to excite both antennas, and port 2 is matched to 50 Ω load impedance (SMD1206).

Figure 7.

Fabricated MTM antennas.

The physical size of the Antenna#3 (two unit cell) is 10.2 × 3.9 × 0.8 mm3 (0.017λ0 × 0.006λ0 × 0.001λ0, where λ0 is the free space wavelength at 500 MHz); and the size of the Antenna#4 (three unit cell) is 13.2 ×3.9 × 0.8 mm3 (0.028λ0 × 0.008λ0 × 0.001λ0, where λ0 is the free space wavelength at 650 MHz. The simulated and measured bandwidth of both antennas is given in Table 3, and its reflection coefficient response is shown in Figures 8 and 9.

Antenna#3Antenna#4
ADS1.4 GHz (200 MHz–1.60 GHz)1.6 GHz (400 MHz–2 GHz)
HFSS1.2 GHz (350 MHz–1.55 GHz)1.55 GHz (350 MHz–1.9 GHz)
Measured0.85 GHz (500 MHz–1.35 GHz)1.2 GHz (650 MHz–1.85 GHz)

Table 3.

Simulated and measured impedance bandwidth for Antenna#3 and #4.

Figure 8.

Simulated and measured S11 of Antenna#3.

Figure 9.

Simulated and measured S11 of Antenna#4.

The simulated and measured gain and efficiency response of the Antenna#3 and Antenna#4 are shown in Figures 10 and 11, as well as tabulated in Tables 4 and 5. The results show the three unit cell antenna offers better gain and efficiency than the two unit cell; however, this is at the cost of slightly larger antenna size. The radiation pattern of both antennas in the E- and H-planes at various spot frequencies is shown in Figure 12. Both antennas radiate power omnidirectionally; however, Antenna#4 radiates bidirectionally at 1.85 GHz. The radiation properties were measured using a network analyzer in a standard microwave anechoic chamber. Properties of the two antennas are compared with other planar MTM antennas in Table 6. Table 6 shows that Antennas#3 and #4 are smaller in size and have a high gain and efficiency than other reported antennas.

Freq. (GHz)0.511.35
ADS3.1 dBi/53%5.8 dBi/88%4.9 dBi/75%
HFSS2.8 dBi/51%5.5 dBi/90%5.1 dBi/79%
Measured2.6 dBi/48%5.3 dBi/85%4.7 dBi/73%

Table 4.

Radiation characteristics (gain/efficiency) of Antenna#3.

Freq. (GHz)0.651.41.85
ADS3.2 dBi/57%5.9 dBi/94%5.3 dBi/81%
HFSS™3.0 dBi/55%6.1 dBi/93%5.2 dBi/80%
Measured 2.8 dBi/51%5.7 dBi/90%4.9 dBi/78%

Table 5.

Radiation characteristics (gain/efficiency) of Antenna#3.

ReferenceDimensionsBandwidthGain (max)Eff. (max)
[27] b-shaped antenna with 4 × UCES: 0.047λ0 × 0.021λ0 × 0.002λ0 at 1GHz
PHS: 14.2 × 6.32 × 0.8 mm3
104.76% (1–3.2 GHz)2.3 dBi62%
[27] b-shaped antenna with 6 × UCES: 0.051λ0 × 0.016λ0 × 0.002λ0 at 800 MHz
PHS: 19.2 × 6.32 × 0.8 mm3
123.8% (0.8–3.4 GHz)2.8 dBi70%
[28] J-shaped antenna with 8 × UCES: 0.564λ0 × 0.175λ0 × 0.02λ0 at 7.5GHz
PHS: 22.6 × 7 × 0.8 mm3
84.23% (7.25–17.8 GHz)2.4 dBi48.2%
[28] I-shaped antenna with 7 × UCES: 0.556λ0 × 0.179λ0 × 0.041λ0 at 7.7GHz
PHS: 21.7 × 7 × 1.6 mm3
87.16% (7.8–19.85 GHz)3.4 dBi68.1%
E-shaped slit antenna with 2 × UCES: 0.017λ0 × 0.006λ0 × 0.001λ0 at 500 MHz
PHS: 10.2 × 3.9 × 0.8 mm3
91.89% (0.5–1.35 GHz)5.3 dBi85%
E-shaped slit antenna with 3 × UCES: 0.028λ0 × 0.008λ0 × 0.001λ0 at 650 MHz
PHS: 13.2 ×3.9 × 0.8 mm3
96% (0.65–1.85 GHz)5.7 dBi90%

Table 6.

Antenna characteristics.

UC, unit cells; ES, electrical size; PHS, physical size.

Figure 10.

Gain and efficiency of Antenna#3.

Figure 11.

Gain and efficiency of Antenna#4.

Figure 12.

Measured E- and H-plane co- and cross-polarization radiation patterns.

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4. Wideband antenna using U-shaped slit MTM unit cells

A novel and compact planar antenna is described that promotes size reduction and bandwidth extension. The antenna is essentially a rectangular patch which is loaded with six MTM unit cells, where each unit cell consists of a U-shaped dielectric slit and a spiral conductor that is grounded using a metallic via-hole, as shown in Figure 13. The antenna is terminated on the right-hand side to a matched load of 20 Ω using SMD1206. The load is terminated to the ground-plane through a via-hole.

Figure 13.

Fabricated prototype MTM antenna.

The U-shaped slit and spiral act like left-handed series capacitance (CL) and shunt inductance (LL), respectively. The current flow on the antenna structure and the voltage gradient created between the antenna and the ground-plane induces parasitic right-handed (RH) series inductance (LR) and shunt capacitance (CR), respectively. The equivalent circuit model of the MTM unit-cell is shown in Figure 14. In addition to the four reactive components (CL, LL, LR, and CR), right-handed lossy components RR and GR and left-handed lossy components GL and RL are included, which account for the dielectric loss associated with CL and the ohmic loss associated with LL. The metamaterial antenna was fabricated on a RT/duroid™ RO4003 substrate with dielectric constant of 3.38, thickness of 0.8 mm, and tanδ = 0.0022. The magnitudes of the unit-cell parameters were determined from simulation and these are: CL = 3.2 pF, LL = 4.5 nH, CR = 1.5 pF, LR = 3.44 nH, GL = 5.6 S, GR = 3.2 S, RL = 6 Ω, and RR = 4.2 Ω.

Figure 14.

Reflection-coefficient response of the MTM antenna for various number of unit cells.

Trade-off between the antenna size, bandwidth, and radiation properties was used to determine the number of MTM unit cells. In the example presented here, the aim was to design and construct an antenna that had a length of 20 mm and operated over a wide frequency range with good unidirectional radiation characteristics. It was necessary to use HFSS™ to optimize the antenna design. The antenna’s reflection-coefficient response as a function of number of unit cells is shown in Figure 15. Six unit cells provide the widest impedance bandwidth of 1.75 GHz for a reflection-coefficient of 10 dB. Therefore, six unit cells were used here in the antenna design.

Figure 15.

Equivalent circuit model of the MTM unit cell.

The antenna’s reflection-coefficient (simulated and measured) is shown in Figure 16. The impedance bandwidth of the antenna is 29%, 26.8%, and 26.6% using ADS, HFSS™, and CST MWS, respectively. The measured impedance bandwidth is 1.5 GHz (5.8–7.3 GHz) for |S11| <−10 dB, which corresponds to 23.7%. There is 13.7% differential between the averaged simulation and measurement results.

Figure 16.

Measured and simulated of |S11| of the MTM antenna.

Future wireless systems require antennas that possess good radiation characteristics such as gain and efficiency in addition to compact size and wide bandwidth. The effective aperture of the antenna determines its gain and radiation efficiency. The magnitude of these two characterizing parameters can be improved simply by increasing the antenna’s effective cross-sectional area. However, this traditional technique increases the dimensions of the antenna which is undesirable. Figure 17 shows the effective aperture of the antenna can be increased by loading it with several MTM unit cells without increasing the antenna size. Results show that with four unit cells the gain and efficiency of the antenna at 7 GHz are 4.94 dBi and 74%, respectively. In fact, by increasing in the number of MTM unit cells from four to six improves the gain to 6.1 dBi and the efficiency to 85%. Table 7 provides the parameters of the optimized antenna and its equivalent electrical circuit. The measured E-plane and H-plane radiation pattern at 5.8 GHz, 6.6 GHz, and 7.3 GHz is shown in Figure 18. The antenna radiates unidirectionally with 3 dB angular beamwidth of 90 degrees.

Number of unit cells6
Length (LCL)2.50 mm
Width (WCL)0.50 mm
Gap between slits0.60 mm
Width of spiral0.25 mm
Spacing of spirals0.25 mm
Spiral turns2
Height of via-hole0.80 mm
Length of SMD12064.20 mm
SMD120620 Ω
CL3.2 pF
LL4.5 nH
CR1.5 pF
LR3.4 nH
GL5.6 S
GR3.2 S
RL6.0 Ω
RR4.2 Ω

Table 7.

Dimensions of the MTM antenna and parameter values.

Figure 17.

Gain and efficiency performance as a function of number of MTM unit cells.

Figure 18.

E- and H-plane radiation patterns at 5.8, 6.6, and 7.3 GHz.

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5. UWB antenna using T-shaped slit MTM unit cells

In this section, a miniature and compact antenna design is described for integration in UWB wireless systems. The antenna exhibits good overall performance in terms of radiation patterns, gain, and efficiency. The proposed antennas are based on metamaterial unit cells that are implemented using T-shaped dielectric slits that were etched directly on the radiating patch, and include a spiral stub which is grounded using a via-hole. The T-shaped slit behaves as a left-handed series capacitance, and the grounded spiral acts as a left-handed shunt inductance. Results show just two unit cells were sufficient to realize the desired antenna performance.

The equivalent circuit model of the T-shaped slit antenna is based on the composite right-/left-handed transmission-line structure shown in Figure 19. Standard printed circuit board manufacturing techniques were employed in the fabrication of the left-handed series capacitors (CL) and the left-handed shunt inductors (LL). The T-shaped dielectric slits and the spiral-shaped conductors were implemented on the radiation patch. The MTM unit-cell consists of two T-shaped dielectric slits etched on a rectangular patch with a conductive spiral located between the two slits. The spiral is grounded using a metallic via-hole. This technique substantially reduces the size of the UWB antenna because, unlike conventional antennas, its size is not dependent on the operating wavelength. The parasitic right-handed series inductance (LR) and shunt capacitance (CR) result from the current flowing over the antenna and the voltage gradient created between the microstrip and the ground-plane.

Figure 19.

(a) Equivalent circuit model of the T-shaped slit MTM unit cell (b) Simulation model of the T-shaped slit antenna (c) Fabricated antenna prototype.

The proposed antenna was designed and fabricated on RT/duroid® RO4003 substrate with dielectric constant of 3.38 and 0.8 mm thickness. Figure 19(c) shows the configuration of the antenna, which is excited from left-hand side through a 50 Ω microstrip feed-line. The right-hand side of the patch is terminated with a matched load of 50 Ω (SMD1206) that is connected to the ground-plane through a metallic via-hole. The total electrical length, width, and height of antenna are 0.05λ0, 0.02λ0, and 0.002λ0, which correspond to 15.5 mm, 6.9 mm, and 0.8 mm, respectively. The optimized parameters of the antenna are given in Table 8, whose equivalent circuit parameters are CL, LL, CR, and LR are 5 pF, 6.4 nH, 1 pF, and 2.8 nH, respectively.

Length of T slits3.0 mm
Width of T slits0.4 mm
Distance between slits0.4 mm
Width of spirals0.2 mm
Spacing of spirals0.2 mm
Turns of spirals2
Height of via-hole0.8 mm
Length of 50 Ω load (SMD1206)4.2 mm

Table 8.

T-shaped slit MTM antenna parameters.

The antenna resonates at three frequencies, i.e., 2, 3.7, and 5.8 GHz, as shown in Figure 20. The measured gain and efficiency of antenna have a maximum value of 7.1 dBi and 91%, respectively, at 3.7 GHz.

Figure 20.

Simulated and measured reflection-coefficient response of the T-shaped slit antenna.

The measured radiation patterns at three spot frequencies in Figure 21 show the antenna radiates directionally. The measured gain and efficiency response of the antenna in Figure 22 show the antenna operates from 0 to 7 GHz with a maximum gain and efficiency of 7.1 dBi and 91%, respectively, at 3.7 GHz.

Figure 21.

Measured radiation patterns of the T-shaped slit antenna.

Figure 22.

Measured gain and efficiency response of the T- shaped slit MTM antenna.

Comparison of the proposed antennas with other conventional antennas is given in Table 9. It is evident the T-shaped antenna offers superior performance.

Ref.DimensionsFractional bandwidthMax. gainMax. eff.
[27]-a0.04λ0 × 0.021λ0 × 0.002λ0105%2.3 dBi62%
[27]-b0.05λ0 × 0.01λ0 × 0.002λ0124%2.8 dBi70%
[28]-a0.45λ0 × 0.17λ0 × 0.02λ074%2.1 dBi44%
[28]-b0.42λ0 × 0.17λ0 × 0.041λ083%3.1 dBi59%
[19]0.44λ0 × 0.22λ0 × 0.008λ018%2.2 dBi17%
[29]0.24λ0 × 0.3λ0 × 0.009λ08%1.5 dBi58%
T-slit ant.0.05λ0 × 0.02λ0 × 0.002λ0144%7.1 dBi91%

Table 9.

Comparison of the proposed antennas.

The effect of the slit dimensions on the antenna characteristics was investigated. It is evident from Figure 23 that increasing the length and width of slits improves the antenna’s impedance bandwidth and matching performance. In fact, the bandwidth improves by 25% from 119 to 149% for increase in slit length from 1 to 3 mm, and width from 0.2 to 0.4 mm.

Figure 23.

Effect of slit length and width on the antenna bandwidth.

The number of slits and spiral were also investigated. By increasing the number of slits in each unit-cell, the number of spirals had a positive impact on the antenna’s bandwidth and matching properties, as shown in Figure 24. It is also observed that by increasing the number of slits causes the number of resonance frequencies to increase as well as its bandwidth. The gain and radiation efficiency of the antenna as a function of slit dimensions, the number of slits in the unit-cell, and number of spirals were also investigated. From Figures 25 and 26, it is evident that by increasing the length and width of the slits, and increasing the number of slits, the gain and radiation efficiency increase considerably. This is attributed to increase in the antenna aperture.

Figure 24.

Impedance bandwidth as a function of number of slits in each of the unit cells and number of spirals.

Figure 25.

Gain and radiation efficiency as a function of slit dimensions.

Figure 26.

Gain and radiation efficiency as a function of number of slits and number of spirals.

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Acknowledgments

The authors would like to give their special thanks to faculty of microelectronics for the financial supports.

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Written By

Mohammad Alibakhshikenari, Mohammad Naser-Moghadasi, Ramazan Ali Sadeghzadeh, Bal Singh Virdee and Ernesto Limiti

Submitted: 09 April 2016 Reviewed: 31 October 2016 Published: 26 April 2017