Design method and analysis

The design procedure for a broadband dual-polarized antenna starts from a square metal patch of width W _s, as illustrated in Fig. 1. The width W _s depends on the center frequency (f ₀) of the operation frequency band. To construct a dual-polarized antenna, the square patch is trimmed into two dipoles, i.e., the $+45^{\circ}$ polarized dipole fed by Port 1 and the $-45^{\circ}$ polarized dipole fed by Port 2, along its center with a trimming angle θ. The trimmed square patch is placed above a ground plane (or a reflector) with a height H for unidirectional radiation patterns.

When the $+45^{\circ}$ polarized dipole is driven by an ideal voltage source alone (removing the $-45^{\circ}$ polarized dipole and the ground plane), a resonance is created at f _r, as shown in Fig. 2. The square width is about a quarter-wavelength ($\lambda _{\rm r}/4$) at f _r. As the $-45^{\circ}$ polarized dipole is moved in, the resonant frequency f _r moves to a higher resonant frequency ${f_{\rm r}}^{\prime}$. Note that there is only one resonance for the dual-polarized antenna without the ground plane.

Figure 1. Development of a broadband dual-polarized antenna based on a square patch: (a) square patch and (b) dual-polarized antenna.

Figure 2. A resonance created by the $+45^{\circ}$ polarized dipole alone compared to the resonance with the $-45^{\circ}$ polarized dipole moved in.

The shift of resonant frequency from f _r up to ${f_{\rm r}}^{\prime}$ is due to the mutual coupling between the $\pm 45^{\circ}$ polarized dipoles. Consider an isolated planar dipole whose resonant frequency is f _r, see Fig. 3. When a parasitic square patch is introduced nearby, the resonant frequency of the dipole is shifted up to ${f_{\rm r}}^{\prime}$, as does the $+45^{\circ}$ polarized dipole with the $-45^{\circ}$ polarized dipole moved in. The mechanism for the frequency upshifting can be explained by an equivalent-circuit analysis. The inductance of the dipole at f _r is assumed to be L _e, while its capacitance C _e is

(1)\begin{align} C_{\rm e}= C_{\rm s}+C_{f}\approx C_{\rm s}, \end{align}

where C _s and C _f are the surface-to-surface and the edge-to-edge capacitances, respectively, between the two arms of the planar dipole, as sketched in Fig. 4. Since the edge-to-edge capacitance C _f is much smaller than the surface-to-surface capacitance C _s, C _f is negligible for the resonance. The resonant frequency f _r of the dipole can be expressed as

Figure 3. The resonant frequency f _r of a planar dipole shifted up to ${f_{\rm r}}^{\prime}$ as a parasitic square patch is introduced nearby ($L_{\rm d}=0.48\lambda_{\rm r}$, $W_{\rm d}=0.05\lambda_{\rm r}$, $W_{\rm p}=0.24\lambda_{\rm r}$, and $G_{\rm d}=0.02\lambda_{\rm r}$).

Figure 4. The equivalent circuit for the resonant frequency of a dipole.

(2)\begin{align} f_{\rm r}=\frac{1}{2\pi \sqrt{L_{\rm e}C_{\rm e}}}. \end{align}

When a parasitic square patch is placed nearby the planar dipole, the capacitance of the dipole becomes ${C_{\rm e}}^{\prime}$:

(3)\begin{align} {C_{\rm e}}^{\prime}=C_{\rm s}+C_{\rm f}/2+{C_{\rm f}}^{\prime}\approx C_{\rm s}, \end{align}

where ${C_{\rm f}}^{\prime}$ is the capacitance between the edges of the dipole and the square patch, as depicted in Fig. 5. ${C_{\rm f}}^{\prime}$ is also negligible; thus, ${C_{\rm e}}^{\prime}\cong C_{\rm e}$. Due to the mutual coupling (mutual inductance M) between the dipole and the square patch, the inductance ${L_{\rm e}}^{\prime}$ of the dipole nearby the square patch decreases as

Figure 5. The equivalent circuit for the resonant frequency of a dipole nearby a parasitic square patch.

(4)

where ${L_{\rm p}}$ is the self-inductance of the square patch. As a result, the resonant frequency ${f_{\rm r}}^{\prime}$ of the dipole with a parasitic element increases as

(5)

The $-45^{\circ}$ polarized dipole plays the same role for the resonance of the $+45^{\circ}$ polarized dipole as does the square patch for the planar dipole. It is predicted that the resonance length of a dual-polarized dipole antenna will be longer than half the wavelength due to the mutual coupling.

Only the dipole with a parasitic element above a ground plane can create two resonances at $f_{\rm r1}$ and $f_{\rm r2}$. A combination of the two resonances leads to a broadband operation. Therefore, the mutual couplings between the $+45^{\circ}$ and the $-45^{\circ}$ polarized dipoles and between the $\pm 45^{\circ}$ polarized dipoles and the ground plane play a critical role for the broadband performance. The trimming angle θ is related to the coupling between the $+45^{\circ}$ and the $-45^{\circ}$ polarized dipoles, while the height H is associated with the coupling between the $\pm 45^{\circ}$ polarized dipoles and the ground plane. By adjusting the critical geometric parameters θ and H, a broadband dual-polarized antenna can be obtained.

When the dual-polarized antenna is placed above the ground plane, a new resonance at ${f_{\rm r}}^{\prime\prime}$ is generated, as exhibited in Fig. 6. This resonance is attributed to the mutual coupling between the dual-polarized antenna and the ground plane. Note that an isolated dipole above a ground plane will not generate a new resonance, as demonstrated in Fig. 7.

Fig. 8 demonstrates the evolution of a dual-polarized antenna from the $+45^{\circ}$ polarized dipole alone to $\pm 45^{\circ}$ polarized dipoles without the ground plane and eventually to the broadband antenna. Two resonances at $f_{\rm r1}$ and $f_{\rm r2}$ are observed for the broadband antenna. A bandwidth of 54% for ${\rm RL} \gt 15\,{\rm dB}$ is obtained. The broadband antenna operates as a half-wave dipole at $f_{\rm r1}$ and a three-quarter-wavelength dipole at $f_{\rm r2}$ as verified by the current distributions displayed in Fig. 9.

Figure 6. A new resonance generated at ${f_{\rm r}}^{\prime\prime}$ for the dual-polarized antenna above a ground plane.

Figure 7. Two resonances of a dipole created at $f_{\rm r1}$ and $f_{\rm r2}$ by a parasitic element and a ground plane.

Figure 8. Evolution of a dual-polarized antenna from the $+45^{\circ}$ polarized dipole to the broadband antenna.

Figure 9. Current distributions on the dual-polarized broadband antenna at (a) $f_{\rm r1}$ and (b) $f_{\rm r2}$.

The broadband antenna involves three geometric parameters, i.e., the width W _s of the square patch, the trimming angle θ, and the height H above the ground plane. The square width W _s is decided by the operation frequency band, which is found to be $W_{\rm s}=0.414\lambda_{0}$, where λ ₀ is the wavelength in free space at f ₀. The critical geometric parameters θ and H are adjusted for a broadband operation. Fig. 10 shows the effect of trimming angle θ on the S-parameter $\left | S11\right |$ of the broadband antenna. The widest bandwidth is obtained when $\theta=4^{\circ}$ for ${\rm RL} \gt 15\,{\rm dB}$. The effect of the height H on the S-parameter of the broadband antenna is plotted in Fig. 11. The widest bandwidth is found when $H=0.29\lambda_{0}$ for ${\rm RL} \gt 15\,{\rm dB}$. Stable radiation patterns are observed from $f=0.73f_{0}$ to $f=1.27f_{0}$ as displayed in Fig. 12. The antenna gain is about 8.5 dBi and the HPBW is $68\pm 5^{\circ}$ as demonstrated in Fig. 13.

Figure 10. The effect of the trimming angle θ on the S-parameter $\left | S11\right |$ of the broadband antenna.

Figure 11. The effect of the height H on the S-parameter $\left | S11\right |$ of the broadband antenna.

Figure 12. Radiation patterns of the broadband antenna for $+45^{\circ}$ polarization at (a) $f=0.73f_{0}$, (b)$f=f_{0}$, and (c)$f=1.27f_{0}$.

Figure 13. Gain and HPBW of the broadband antenna.

Realization and verification

The broadband dual-polarized antenna is realized on a thin substrate (Taconic TLY-5, $\varepsilon _{\rm r}=2.2$, ${\rm thickness}=0.5\,{\rm mm}$) for the 2 GHz band (1.7–2.7 GHz). The configuration of the realized broadband antenna is illustrated in Fig. 14. Three geometric parameters associated with the broadband antenna are found to be $W_{\rm s}=53$ mm, $\theta=4^{\circ}$, and H = 36 mm. One arm of each dipole (the $+45^{\circ}/-45^{\circ}$ polarized dipole) is printed on one side of the substrate while the other arm is etched on the other side of the substrate. The voltage source is simply realized with a shot stub. Each stub with one arm of the dipole serves as a microstrip line, which can be connected to the coaxial cable. The width of the stub is determined to be 1.6 mm for a characteristic impedance of 50 Ω. Each stub extends a short length from the dipole arms in order to separate the two feeding points for the dual-polarized antenna from being overlapped. Each dipole is fed by a coaxial cable whose outer conductor is soldered to an arm while its inner conductor is connected to the other arm through a short stub. The feeding coaxial cables have little effect on the performance of the broadband antenna. Fig. 15 shows (A) the S-parameters and (B) gain and HPBW when the broadband antenna is fed with an ideal voltage source, with two coaxial cables or with two coaxial cables plus two supporting metal poles. Little differences can be seen.

Figure 14. Broadband antenna realized on a thin substrate ($W_{\rm s}=53$ mm, $\theta=4^{\circ}$, H = 36 mm, and L = 150 mm).

Figure 15. The effect of the coaxial cables on the performance of the broadband antenna: (a) S-parameters and (b) gain and HPBW.

A prototype of the realized broadband antenna is pictured in Fig. 16. The simulated and measured S-parameters are compared in Fig. 17; good agreement is observed. The measured bandwidth for $\left | S11\right |$ and $\left | S22\right |$ $ \lt -15$ dB (or ${\rm RL} \gt 15$) is about 50%, covering the frequency band 1.69–2.81 GHz for 2G/3G/4G base stations. The measured isolation ($-\!\left | S21\right |$ in dB) is higher than 35 dB. The radiation patterns simulated and measured for $+45^{\circ}$ polarization at 1.7, 2.2, and 2.8 GHz are plotted in Fig. 18; stable radiation patterns are observed from 1.7 to 2.8 GHz. The gain and the HPBW of the broadband antenna are presented in Fig. 19. The antenna gain realized is about $8\pm0.5$ dBi and the HPBW is $70\pm5^{\circ}$.

Figure 16. A prototype of the realized broadband antenna.

Figure 17. Simulated and measured S-parameters of the broadband antenna.

Figure 18. Radiation patterns of the broadband antenna simulated and measured for $+45^{\circ}$ polarization at (a) 1.7 GHz, (b) 2.2 GHz, and (c) 2.8 GHz.

Figure 19. Gain and HPBW of the broadband antenna.

Bandwidth Enhancement

The bandwidth of the broadband antenna can be enhanced by introducing a Γ slot on every arm of the dipoles, as illustrated in Fig. 20. The bandwidth-enhanced broadband antenna is designed to cover the 2 GHz band (1.7–2.7 GHz) for 2G/3G/4G systems and the 1427–1518 MHz band for international mobile telecommunications (IMT) services. Three new geometric parameters are involved in the design of the bandwidth-enhanced broadband antenna, including the slot lengths (L ₁ and L ₂) and the slot width (w). The third resonance is created by the introduction of the slots at $f_{\rm r3}$, as shown in Fig. 21, thus resulting in a bandwidth enhancement. Each dipole of the bandwidth-enhanced broadband antenna acts at $f_{\rm r3}$ as a top-loaded half-wave dipole, as suggested by the current distribution displayed in Fig. 22.

Figure 20. Bandwidth-enhanced broadband antenna with four Γ slots ($W_{\rm s} = 63$ mm, $\theta=3^{\circ}$, H = 45 mm, $L_{1}= 28$ mm, $L_{2}= 19$ mm, w = 4.3 mm, and L = 160 mm).

Figure 21. The third resonance at $f_{r3}$ created by the Γ slots.

Figure 22. Current distribution on the bandwidth-enhanced broadband antenna at $f_{\rm r3}$.

A prototype of the bandwidth-enhanced broadband antenna is presented in Fig. 23. The simulated and measured S-parameters are plotted in Fig. 24. The measured bandwidth for ${\rm RL} \gt 15$ is about 67% (1.39–2.71 GHz), covering the frequency band for 2G/3G/4G systems and IMT services. The measured isolation is higher than 35 dB for most parts of the frequency band. The radiation patterns simulated and measured at 1.4, 2.2, and 2.7 GHz are plotted in Fig. 25; stable radiation patterns are observed. The gain and the HPBW of the bandwidth-enhanced broadband antenna are presented in Fig. 26. The measured antenna gain is about $8\pm0.5$ dBi and the HPBW is $70\pm5^{\circ}$.

Figure 23. A prototype of the bandwidth-enhanced broadband antenna.

Figure 24. Measured and simulated S-parameters of the bandwidth-enhanced broadband antenna.

Figure 25. Radiation patterns of the bandwidth-enhanced broadband antenna for $+45^{\circ}$ polarization at (a) 1.4 GHz, (b) 2.2 GHz, and (c) 2.7 GHz.

Figure 26. Gain and HPBW of the bandwidth-enhanced broadband antenna.

A comparison of the broadband antennas developed in this work with those published in literature in terms of bandwidth (BW), the number of geometric parameters involved (not including the ground plane), and antenna complexity is presented in Table 1. For a bandwidth of ~45%, the dual-polarized antennas proposed in [Reference Liu, Yi, Wang and Gong2–Reference Wen, Gao, Luo, Mao, Hu, Yin, Zhou and Wang4] have used 7–8 geometric parameters, while the design of the broadband antenna (Ant. I) in this work has only 3 geometry parameters involved. The bandwidth-enhanced broadband antennas presented in [Reference Bao, Nie and Zong5–Reference Ye, Zhang, Gao and Xue13] adopted a variety of numbers of geometry parameters from 10 to 34, while the bandwidth-enhanced broadband antenna (Ant. II) in this work only needs 6 geometric parameters. Both broadband antennas developed in this work feature a simple planar configuration, high isolation, and stable radiation patterns.

Table 1. Comparison of this work with published literature.