SISL technology

The SISL technology is a transmission line that combines the advantages of suspended and planar structures. While retaining the benefits of traditional suspended lines, it uses standard printed circuit board manufacturing processes to solve the difficulties in grounding and high processing costs associated with traditional suspended line designs. Due to the advantages of SISL technology, such as low loss, high isolation, miniaturization, and easy integration with other planar circuits, it is widely applied in wireless communication systems.

The structure of the filtering balun based on the SISL technology is shown in Figs. 1 and 2. This structure is composed of six substrate layers (from substrate 1 to substrate 6) and 12 metal layers (from G1 to G12).

Figure 1. 3D structure of the proposed filtering balun.

Figure 2. Detail layouts of the proposed SISL filtering balun.

The main circuit is designed on substrates 3 and 4, which are using Rogers RO4003C with thickness $h_3 = h_4 = 0.813$ mm and $\varepsilon_{r1} = 3.55$. Substrates 1, 2, 5, and 6 are using FR-4 with thickness $h_1 = h_2 = h_5 = h_6 = 0.6$ mm and $\varepsilon_{r2} = 4.4$. Substrates 2 and 5 are hollowed with rectangle shapes, and all the substrates are placed in the order shown in Fig. 3 to form the two air cavities for the main circuit. The EM shielding box consists of air cavities, metal via holes, and mental layers surrounding the air cavity.

Figure 3. Cross-section view of the proposed filtering balun.

For circuits containing dual dielectric substrates, the λg/4 suspended stripline open-circuited stub on G5, and λg/2 suspended stripline resonator on G8 are connected to 50 Ω feeding lines as unbalanced signal input port and balanced signal output port, respectively. As shown in Fig. 3, when a random unbalanced signal is input, the electric field distribution generated by the perpendicular coupling of the suspended stripline resonator and the λg/2 suspended slotline resonators on G6 and G7 can generate a 180^∘ phase difference between the two output ports in a wide frequency range [Reference Feng and Zhu20].

Equivalent circuit

Since the balun’s output is balanced, the two output ports can be combined into one port on the circuit [Reference Feng and Zhu21]. Therefore, the three-port network can be equivalent to a two-port network. As shown in Fig. 4(a), the equivalent circuit uses transmission lines and ideal transformers to analyze the frequency response of the model. The λg/2 suspended stripline open-circuited stub and λg/2 suspended slotline resonator are represented by the series open-ended stub, shunt short-ended stub. Moreover, replace the λg/2 suspended stripline resonator for cascading functions with transmission lines. The energy transfer between them is equivalent through ideal transformers N ₁, N ₂, and N ₃. The electrical lengths of the series open-ended stub, shunt short-ended stubs, and cascaded transmission lines are defined as $\theta = 90^{\circ}$ at central frequency. Moreover, the characteristic impedance of the 50  Ω feeding lines per port is defined as Z ₀. The signal is input into the equivalent circuit network through the feeding line with the input impedance Z ₀ and through the series open-ended stub, shunt short-ended stubs, and cascaded transmission line with characteristic impedance Z_m, Z_s, and $Z_{m1}$ and finally output through the feeding line with the output impedance of 2Z ₀.

Figure 4. (a) Equivalent circuit with transformer. (b) Simplified equivalent circuit with $Z_{\mathrm{m}}^{\prime}=N_1^2 \times Z_{\mathrm{m}},\ Z_{\mathrm{s}}^{\prime}=N_2^2 \times Z_{\mathrm{s}},\ Z_{m1}^{\prime} = N_3^2 \times Z_{m1}$.

Synthesis design

This two-port network can be equivalent to an ideal transmission-line network with $N_1 = N_2 = N_3 = 1$. By multiplying the ABCD matrices of all the involved sections [Reference Yang, Zhu, Choi, Tam, Zhang and Wang22], the ABCD matrix of the whole structure can be expressed as

(1)\begin{equation} M=\left[\begin{array}{ll} A & B \\ C & D \end{array}\right] \end{equation}

where

(2a)\begin{equation} A=\left(1+\frac{z_m}{2 z_{m 1}}\right) \frac{\cos \theta}{\sin ^2 \theta}-\left(1+\frac{z_m}{2 z_{m 1}}+\frac{2 z_m}{z_s}\right) \frac{\cos ^3 \theta}{\sin ^2 \theta}, \end{equation}

(2b)\begin{equation} B=j\left[\frac{2 z_{m 1}}{\sin \theta}-\left(2 z_{m 1}+z_m+\frac{4 z_m z_{m 1}}{z_s}\right) \frac{\cos ^2 \theta}{\sin \theta}\right], \end{equation}

(2c)\begin{equation} C=j\left[\frac{1}{2 z_{m 1}} \frac{1}{\sin \theta}-\left(\frac{1}{2 z_{m 1}}+\frac{2}{z_s}\right) \frac{\cos ^2 \theta}{\sin \theta}\right], \end{equation}

(2d)\begin{equation} D=\left(1+\frac{4 z_{m 1}}{z_s}\right) \frac{\cos \theta}{\sin ^2 \theta}-\left(1+\frac{4 z_{m 1}}{z_s}\right) \frac{\cos ^3 \theta}{\sin ^2 \theta}. \end{equation}

Based on [Reference Wu and Zhu23], the scattering matrix of the two-port ideal transmission line network can be expressed as

(3)\begin{equation} S_{11}=\frac{A z_L+B-C z_F z_L-D z_F}{A z_L+B+C z_F z_L+D z_F}, \end{equation}

(4)\begin{equation} S_{21}=\frac{2 \sqrt{z_F z_L}}{A z_L+B+C z_F z_L+D z_F}, \end{equation}

where $F_M=\mathrm{S}_{11} / \mathrm{S}_{21}$

Based on (1) and (2a) and the ABCD matrix of the whole structure, the mathematical expression of the characteristic function FM can be determined. Due to the introduction of (2a)–(2d), both real and imaginary parts are included in F_M, and the Chebyshev polynomial function cannot be directly analyzed and solved. Therefore, ignoring the existence of the imaginary part in F_M, F_M can be expressed as

(5)\begin{equation} F_M=K_1 \frac{\cos \theta}{\sin ^2 \theta}+K_2 \frac{\cos ^3 \theta}{\sin ^2 \theta} \end{equation}

and

(6a)\begin{equation} K_1=\frac{1}{2 \sqrt{z_F z_L}}\left[z_L\left(1+\frac{z_m}{2 z_{m 1}}\right)-z_F\left(1+\frac{4 z_{m 1}}{z_s}\right)\right], \end{equation}

(6b)\begin{equation} K_2=\frac{1}{2 \sqrt{z_F z_L}}\left[-z_L\left(1+\frac{z_m}{2 z_{m 1}}+\frac{2 z_m}{z_s}\right)+z_F\left(1+\frac{4 z_{m 1}}{z_s}\right)\right]. \end{equation}

In (2a)–(6a), Z_F and Z_L are defined as the source and load impedances of this two-port ideal transmission line network, and $Z_F = Z_0$, $Z_L = 2Z_0$. z_m, z_S, $z_{m1}$, z_F, and z_L represent the impedance parameters, which are normalized by the source impedance Z_F, respectively. The equivalent circuit designed using the quasi-Chebyshev polynomial design method can be expressed as

(7)\begin{equation} \left|\mathrm{S}_{21}\right|^2=\frac{1}{\left|F_M\right|^2+1}=\frac{1}{\left|F_L\right|^2+1}=\frac{1}{\varepsilon^2 \,\cos ^2(q \xi+n \phi)+1}, \end{equation}

(8)\begin{equation} \varepsilon=\sqrt{10^{0.1 L_A}-1}, \end{equation}

(9)\begin{equation} \cos \xi=\cos \phi \sqrt{\frac{\alpha^2-1}{\alpha^2-\cos ^2 \phi}}, \end{equation}

(10)\begin{equation} \cos \phi=\alpha \cos \theta, \end{equation}

(11)\begin{equation} \alpha=1 / \cos \theta_c.\end{equation}

In (7)–(11), LA is the ripple-level factor, ɛ is the ripple coefficient, θ_c is the electrical length at the lower cutoff frequency, and f_c is the lower cutoff frequency. Since the equivalent circuit contains a transmission line that functions as a cascade, a filtering balun with a quasi-Chebyshev frequency response with n = 1 and q = 2 is comprehensively designed, and its characteristic impedance F_L can be expressed as

(12)\begin{equation} F_L=K_3 \frac{\cos \theta}{\sin ^2 \theta}+K_4 \frac{\cos ^3 \theta}{\sin ^2 \theta}\end{equation}

and

(13a)\begin{equation} K_3=-\varepsilon\left(\alpha+2\left(\alpha^2-1\right)^{1 / 2}\right),\end{equation}

(13b)\begin{equation} K_4=\varepsilon\left(2 \alpha^3+2 \alpha^2\left(\alpha^2-1\right)^{1 / 2}-\alpha\right).\end{equation}

When $K_1 = - K_3$ and $K_2 = - K_4$, the normalized impedance values of Z_m and Z_s can be determined by calculating L_A and θ_c.