A novel composite left-and-right-composite-handed leaky wave antenna is proposed based on Spoof Surface Plasmon Polaritons slow-wave transmission line at microwave band in this paper. Wide-angle frequency scanning of the antenna is achieved by combining the slow-wave dispersion characteristics of Spoof Surface Plasmon Polaritons and the left-and-right-composite-handed characteristics of the complementary split ring resonator structure. The simulated and experimental results show that, with the increase of frequency, the radiation mode of the antenna gradually changed from slow-wave mode to fast-wave radiation mode, and the pattern changed continuously. The scanning region of the main beams proposed covers 110° in φ=0° plane when the frequency increases from 8GHz to 15GHz, and the gain of the antenna kept between 7dBi and 10.4dBi.
National Natural Science Foundation of China614710941. Introduction
Surface Plasmon Polariton (SPP) is a type of surface wave system whose permittivity is completely opposite between two different media. Because of the interaction between electrons and the incident field, electromagnetic wave can propagate along the surface direction with exponential attenuation perpendicular to the surface of a material interface. Metal materials have plasma characteristics in optical and infrared frequency band. Hence SPP is widely used in optical and infrared fields. Because the metal can be equivalent to the perfect conductor in the microwave and millimeter wave band, it is sometimes difficult to achieve SPP slow-wave transmission in the microwave and terahertz frequency band. In [1], however, periodic metal grooves are used to realize the equivalent plasma structure in the microwave frequency band. The quasi-surface wave transmission is realized. The equivalent transmission mode is realized by the periodic metal through-hole array in [2]. The circuit that uses the periodic structure to realize the equivalent plasma to transmit surface waves is called Spoof Surface Plasmon Polaritons (SSPP). In [3], a planar SSPP structure is realized by etching cyclic U-type patches on substrates to achieve low profile and miniaturization. Because of the advantageous application prospect of SPP in high frequency, the concept of SSPP has attracted many scholars to research since it was put forward. SSPP dispersion characteristics of one-dimensional periodic structures are researched in [4]. Reference [5] presents a method to analyze the dispersion and loss characteristics of SSPP in terahertz band. Considering the metal conductivity and high order mode effect of SSPP, this method is very accurate. Reference [6] analyzes the theoretical model of SSPP. In addition, more research is dedicated to using SSPP to achieve filter [7], power divider [8], and radiation [9] performance, etc. Reference [10] realizes the end fire of SSPP transmission line through gradual structure. There are also many researches dedicated to the design of leaky wave antennas based on SSPP transmission line [11–14].
Left-and-right-composite-handed (CRLH) material is also a concept introduced from optics. Propagation of electromagnetic waves in equivalent left-handed or right-handed media through periodic resonant structure has been introduced. In the leaky wave antenna, which loaded CRLH radiation structure, the backward wave radiation can be understood in the specific frequency band. Using complementary split ring resonator (CSRR) [15, 16] or interdigital capacitance (IDC) [17, 18] resonant structure, the left-handed radiation characteristics of leaky wave antenna can be properly realized.
In this paper, a novel wide-angle frequency scanning CRLH leaky wave antenna based on SSPP transmission line is proposed. Combining the CRLH dispersion characteristics of CSRR resonators and the broadband characteristics of SSPP slow-wave transmission line, the CSRR resonates with the left-handed slow-wave band, the left-handed fast-wave band, and the right-handed fast-wave band successively by frequency scanning, and the 110° pattern main beam broadband scanning is realized. The simulated results match well with the measured results. In the frequency scanning region, the gain of the proposed antenna is kept within the range of 3.4dB.
2. SSPP Design
Unlike traditional microstrip lines, SSPP is an artificial surface wave transmission line that binds electromagnetic fields to metal surfaces through periodic metal structures, so there is no grounding part. Therefore, the coplanar waveguide (CPW) is more convenient to integrate with SSPP, to achieve impedance matching between connector and SSPP. This paper adopts the gradient matching circuit proposed in [19].
The layout of the SSPP transmission line is illustrated in Figure 1. By adjusting the size and spacing of the U-type metal patches, SSPP work is achieved in the target frequency band. Figure 2 shows the difference between the dispersion curve of the SSPP transmission line and the air dispersion curve by CST eigenmode solved. It can be seen from Figure 2 that with the decrease of B2, the slow-wave cutoff frequency of SSPP transmission line moved to a low frequency. When the dispersion curve slope is 0, the cutoff frequency of SSPP is reached. Because SSPP has the dispersion characteristics illustrated in Figure 2, with the increase of frequency, the phase change of SSPP increased in unit length. So, when SSPP is invoked as the feed transmission line of leaky wave antenna, the antenna has the characteristics of wide-angle scanning.
Layout of proposed SSPP.
Comparison of dispersion curves between SSPP and air.
Figure 3 shows the electric field distribution of SSPP in slow-wave mode achieved by full wave simulation software HFSS. The electric field propagates in the direction of transmission and declines rapidly in the direction perpendicular to the transmission direction. It shows that the proposed SSPP has good electric field constraint.
Electric field distribution of SSPP by HFSS.
3. CRLH Theory of CSRR
The layout and equivalent circuit of CSRR resonant structure of SSPP is shown in Figures 4 and 5. The CSRR equivalent circuit in Figure 5 can be divided into perfect left-handed (PLH) equivalent circuit and perfect right-handed (PRH) equivalent circuit. PRH can be equivalent to a series inductor and a parallel grounding capacitor as shown in Figure 5(a). The equivalent schematic diagram of PLH is obtained by PRH duality principle, which is equivalent to series capacitor and parallel grounding inductance as shown in Figure 5(b).
Layout of loading CSRR resonant structure. (a) Distribution of linear array. (b) Layout of CSRR.
Equivalent schematic diagram. (a) Equivalent schematic diagram of PRH. (b) Equivalent schematic diagram of PLH. (c) Equivalent schematic diagram of CSRR.
The dispersion relation of CSRR can be obtained from (1).(1)β=sωω2LRCR+1ω2LLCL-LRLL+CRCL(2)sω=-1,ifω<min1LRCLand1LLCR+1,ifω>max1LRCLand1LLCRIn (1), CR and LR are equivalent series capacitance and parallel inductance of CSRR. CL and LL are equivalent parallel capacitors and series inductors of CSRR. The cutoff frequencies of left-handed region and right-handed region are shown in formula (3) and (4) as follows:(3)ωse=1LRCL(4)ωsh=1LLCRFrom formula (3) and (4), when LL/CL=LR/CR, ωse=ωsh, the dispersion of β is continuous. In this case, the state that conforms to the CRLH transmission lines is called the balanced state. When LL/CL≠LR/CR, ωse≠ωsh. Hence, there is a frequency stopband. In this case, the CRLH transmission line is unbalanced. From (1) and (2), the equivalent phase constant β is a function of frequency ω. When ω>maxωse,ωsh, β>0, CSRR is in the right-hand region. When ω<minωse,ωsh, β<0, CSRR is in the left-hand region.
4. Wide-Angle Scanning Theory
Leaky wave radiation of SSPP can be realized by loading parasitic patches on the SSPP opening side [19–21]. Because of the slow-wave dispersion of SSPP transmission line, SSPP leaky wave antenna holds the characteristics of wideband frequency sweep. By loading CSRR patches, the leakage radiation of SSPP is achieved on the one hand. On the other hand, the dispersion characteristics of CSRR and SSPP determine that antennas emit forward radiation to backward radiation. Left-handed slow-wave radiation, left-handed fast-wave radiation, and right-handed fast-wave radiation can be realized, respectively, by loading CSRR resonant element in SSPP.
Figure 6 shows the working principle of the SSPP CRLH antenna. The radiation of the proposed antenna consists of two parts. First, energy of SSPP is spatially coupled to the CSRR radiation patches. Further, CSRR patches radiate energy into space. The radiation main beam direction of the antenna depends on the feed phase of SSPP and the compensation phase of CSRR. Feed phase Φi(i=-1,0,1) of SSPP changed with frequency increasing. Because of the change of feed frequency, the response mode of CSRR also changes. When CSRR’s resonance mode n >0, CSRR has a positive electrical length; that is to say, CSRR’s compensation phase φi is positive. When CSRR is in the left-handed band, its resonance mode n< 0. The electrical length of CSRR is negative and Φi is compensated negatively.
Working principle of proposed antenna.
The compensation phase φi of CSRR is obtained by formula (5).(5)φi=βl=2πλnπ=2nπThe radiation pattern of antenna can be obtained by formula (6) proposed in [19].(6)E=Ce-jkrrfθr,φ∑n=-iiInejnkdsinθr+ΦiWhere f(θ,φ) is the radiation pattern of CSRR unit, θr is the scanning angle of proposed antenna. k is the wavenumber of proposed antenna.
When Φi∈[-kd,0], the main beam radiation direction θr= 90°~180°, antenna produces backward radiation. The radiation direction of proposed antenna is shown in the blue line in Figure 6. When Φi∈[0,kd], the main beam radiation direction θr= 0°~90°, antenna produces forward radiation. The radiation direction of proposed antenna is shown in the brown line in Figure 6, where d is the distance of the radiating elements.
Figure 7 shows the radiation field of the slow-wave (at 8GHz), left-hand fast-wave (at 10GHz), broadside (at 12.5GHz), and right-hand fast-wave (at 15GHz) radiation mode, respectively, by HFSS. It can be observed in Figure 7 that CSRR will support the slow-wave mode at a frequency point, and then it will no longer radiate in free space but will propagate along the surface wave delay transmission line, thus realizing the surface wave radiation. In Figure 7(a), the antenna is on the left-hand slow-wave region, so the radiation main beam is opposite to the traveling wave direction. Because the electrical length of CSRR increases at high frequencies, the CSRR cannot be equivalent to an ideal subwavelength resonant structure, so there is no right-handed slow-wave region of the proposed antenna.
Antenna pattern in different dispersion regions. (a) Slow wave. (b) Left-handed fast wave. (c) Broadside. (d) Right-handed fast wave.
The above theory is the principle of wide-angle scanning at the microscopy of the proposed antenna. Macroscopically, the wide-angle scanning characteristic of the proposed antenna is due to its dispersion in different regions. The dispersion curve of the antenna radiation element is illustrated in Figure 8. There is an open stopband between the slow-wave and fast-wave regions. Therefore, the gain of the proposed antenna at 9GHz to 10.5GHz will be attenuated.
Dispersion curve of antenna radiation unit.
5. Parameter Study
The radiation characteristics of leaky wave antenna are directly affected by the dispersion of radiation element and the coupling between radiation element and the transmission line. Therefore, it is necessary to examine the coupling between the radiation element and the transmission line, the size of the patch, and the spacing between elements for the leaky wave antenna loaded with parasitic patches.
5.1. Patch Gap Orientation Factor
Deflection angle of CSRR resonator affects the coupling between transmission line and radiation element, so the influence of the deflection angle of antenna radiation should be considered. The CSRR structure corresponding to discrete theta values is shown in Figure 9. Figure 10 shows the relationship between CSRR patches deflection and the frequency sweep gain of the proposed antenna. It can be seen that the antenna gain fluctuates greatly during the frequency scanning process due to the asymmetry of CSRR patches in the direction of traveling wave when the patch rotates (±90°) and cannot be applied to the antenna design. When θ=0°, the antenna gain is higher and has a better consistency.
Deflection state of CSRR with θ changing.
Influence of patch gap orientation on proposed antenna gain.
5.2. Gap Size Factor
As shown in Figure 8, the antenna has an open stopband between 9GHz and 10.5GHz. The value of D3 directly affects the value of equivalent CR, LRCL, and LL of CSRR. Then the resonance characteristics of CSRR are affected. As can be observed in Figure 11, the gain curve of the antenna decreases significantly from 8GHz to 10GHz, which is transition band from left-handed slow-wave region to left-handed fast-wave region. By adjusting D3, the gain from 8GHz to 9GHz can be effectively improved. When D3=1mm, the antenna gain fluctuates little.
Influence of D3 on proposed antenna gain.
5.3. Patch Size Factor
According to the above theory, the beam angle of the presented antenna is determined by φi and Φi together. However, the resonant frequency band of CSRR unit is limited. The effective radiation band of CSRR can be changed by enlarging the size of CSRR cell to n times of the original one. Figure 12 shows the deflection angle of the antenna beam with frequency when n = 0.5, 0.7, 1, and 1.3. When n = 1, the size of CSRR is shown in Table 1. Unmarked frequencies in the figure indicate that the maximum gain of the antenna is significantly reduced (>4dB) or that the pattern has grating lobe.
Design parameters of the proposed antenna in Figure 11 (unit: mm).
L1
W1
L2
W2
S
D
A1
A2
191
40
23.86
18.86
16
3
0.5
2
S1
D1
S2
D2
D3
B1
B2
10
10
8
8
1
2
0.2
Influence of CSRR size on beam deflection angle. (a) n=0.5. (b) n=0.7. (c) n=1. (d) n=1.3.
When the frequency is constant, the compensation phase φi of the patch is constant, and the beam scanning step of the antenna is only related to the dispersion of the SSPP transmission line. As shown in Figure 2, when the dispersion characteristics of SSPP tend to slow wave, the step of phase Φi difference changed larger.
As shown in Figure 12, the beam direction of the proposed antenna is different in different frequency bands and is not linear. When the frequency is between 8 GHz and 9 GHz, the beam scanning step of the antenna reaches 48°/GHz. However, when the frequency is between 12GHz and 13GHz, the beam scanning step of the antenna reaches 6°/GHz. Therefore, when the effective radiation band of CSRR is in the frequency band with larger deflection step, the scanning angle of the proposed antenna increased accordingly. When the size of CSRR decreases, the applicable radiation band of antenna moves to high frequency. When n <1, the effective radiation frequency band of the antenna is higher than 9 GHz, and the pattern deflection angle is smaller. When n exceeds 1, the low cutoff frequency of the effective radiation band of the antenna is less than 8 GHz. At this point, the antenna is at the stop band, which reduces the scanning angle of the proposed antenna.
5.4. Coupling Factor
Figure 13 shows the effect of patch and SSPP transmission line spacing D of antenna return wave characteristic and gain. When D = 3mm, the average gain of the proposed antenna is the largest. When D becomes larger, the radiation efficiency of the proposed antenna is reduced. This phenomenon is explained by the weak coupling between CSRR and SSPP. Conversely, when D becomes smaller, the coupling between CSRR and SSPP becomes stronger, and matching between CSRR and SSPP transmission lines becomes worse. Therefore, the radiation gain of the antenna is also reduced.
Influence of D on proposed antenna gain and reflection coefficient: (a) gain and (b) reflection coefficient.
6. Results and Discussion
Considering the constraints of measuring environment and assembly process, the length of the antenna is limited. Finally, a linear array composed of 9 CSRR patches is adopted in this paper. According to the above principle, the absolute size of the antenna is determined in Table 1. The circuit is etched on a Rogers 5880 substrate with a small dielectric constant (ε=2.2,tanδ=0.0009) to reduce the wave impedance between substrate and free space. The photograph of the proposed antenna is shown in Figure 14. Figure 15 shows the antenna pattern measured environment. Antenna was fed by the N5242a vector network analyser of Agilent Co during the measure.
Photograph of proposed antenna.
Measured environment of proposed antenna.
The simulated and measured results of S parameters are presented in Figure 16. Figure 17 displays the simulated and measured results of the antenna normalized φ=0° plane pattern. The test platform reflected the electromagnetic radiation of the proposed antenna. Therefore, there are unnecessary side lobes and unevenness in the radiation pattern in Figure 17(b). When the antenna frequency changes from 8 GHz to 15 GHz, the antenna passes through the left-handed slow-wave region, left-handed fast-wave region, and right-handed region, and the φ=0° plane scanning angle achieves 110° wide-angle scanning. The gain of the proposed antenna remains between 7dBi and 10.4dBi from 8 to 15GHz. Figure 18 indicates the gain and main valve deflection angle of the antenna varied by frequency scanning.
Simulated and measured results of S parameters of proposed antenna.
φ=0° plane simulated and measured results of antenna. (a) Simulated result. (b) Measured result.
Gain and scanning angle of the proposed antenna.
7. Conclusions
In this paper, a novel wide-angle frequency scanning CRLH leaky wave antenna based on SSPP transmission line is presented. The antenna combines the slow-wave dispersion characteristic of SSPP and the CRLH characteristics of CSRR resonator to realize the wide-angle frequency scanning characteristics. By changing the frequency from 8GHz to 15GHz, the radiation mode of the antenna is modified into left-handed slow-wave region, left-handed fast-wave region, and right-handed fast-wave region successively. The pattern scanning of the main beam of the φ=0° plane is realized. Simulated results are in agreement with the measured results. The gain fluctuation is less than 3.4dB, and the direction of the main beam pattern changes 110° from 8GHz to 15GHz.
Data Availability
The data used to support the findings of this study are available from the corresponding author upon request.
Conflicts of Interest
The authors declare that there are no conflicts of interest regarding the publication of this article.
Acknowledgments
This work was supported by the Natural Science Foundation of China (61471094).
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