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1. Introduction

With the rapid development of information and communication technology, electromagnetic information leakage associated with telecommunication devices, such as transmission lines, brings increasingly strong impacts on information security. Transient electromagnetic pulse emission monitoring technology (TEMPEST) is known for using reverse technology to collect and restore the transmitting source signals and preventing potential security threats of information equipment [1]. Nowadays, many scholars have begun to actively research and develop TEMPEST [2–6], especially TEMPEST protection. Many methods of TEMPEST protection have been achieved, for example, low-radiation equipment [7–10], noise interference [11], electromagnetic shielding [12–14], filtering technology [15], and optical fiber technology [16, 17]. Low-radiation equipment, noise interference, electromagnetic shielding, and optical fiber technology mainly prevent electromagnetic information leakage caused by electromagnetic radiation. Filtering technology is the only way to prevent electromagnetic information leakage caused by conduction.

With the development of high-speed communication technology, the leakage of electromagnetic information in high-frequency band should be widely concerned. In 2005, the electromagnetic information leakage up to 3 GHz was measured by K. Hoffmann and Skvor [18]. Traditional electromagnetic interference (EMI) filters at their operation frequency can block information only in the frequency range of 150KHz-30 MHz and carry a current of 10 A and withstand a voltage of 250 V. What is worse, EMI filter designed by using lumped components has greater volume and weight and cannot prevent information leakage of information equipment in high-frequency band (∼GHz).

The microstrip filter made of PCB has the advantages of light weight and small volume, which has been studied by many scholars. In addition, based on a triple path signal interference mechanism, Song et al. [19] proposed a compact broadband bandstop filter with the insertion loss of 30 dB for use in modern wireless systems. A broadband common-mode filter with the insertion loss of 10 dB was designed for solving electromagnetic interference in high-speed differential digital systems and discussed by Chan et al. [20]. Phudpong and Hunter [21] projected a prototype of a single-resonator bandstop limiter with an insertion loss of 32 dB, a resonant frequency of 2 GHz, and a limiting bandwidth of approximately 200 MHz. The dual-wideband bandstop filters, which are used in multi-wideband wireless systems, were demonstrated by Feng et al. [22]. A planar high insertion loss bandstop filter within a frequency band from 2.79 to 3.21 GHz was developed by Wu et al. [23]. However, those microstrip filters are used in low-power communication circuits and devices. To the authors’ best knowledge, microstrip filters for preventing conduction electromagnetic information leakage of high-power transmission lines are rarely reported.

Because of the importance of TEMPEST protection, a method to prevent electromagnetic information leakage of high-power transmission lines based on the microstrip bandstop filter (MSBSF) is proposed in this paper. The MSBSF with high insertion loss at 2.40–2.49 GHz is designed, fabricated, and measured. The results show that it can carry the current greater than 10A, withstand the voltage of 1.7 kV, and have the insertion loss of 38 dB at 2.41–2.49 GHz. Compared with the EMI filter, the MSBSF can more effectively prevent the conduction electromagnetic information leakage of high-power transmission lines in high-frequency band apart from carrying greater current subject to higher voltage, having lighter weight and smaller volume. The MSBSF has a good application in preventing conducted electromagnetic information leakage in high frequency.

2. Design Ideas

2.1. Schematic

As shown in Figure 1, when transmitting electromagnetic signal or energy over a long distance, the transmission line of an information device may carry electromagnetic information, and the information leakage will be caused by the process of probe detection and spectrum analysis. To prevent information leakage, the filter should be connected before the information device is connected to the transmission line.

[figure omitted; refer to PDF]

Based on Kirchhoff’s low, each segment transmission line is expressed as$$\begin{array}{}\text{(2)}& \frac{\partial ux,t}{\partial x}+L\frac{\partial ix,t}{\partial t}+Rix,t=0,\text{(3)}& \frac{\partial ix,t}{\partial x}+C\frac{\partial ux,t}{\partial t}+Gux,t=0,\end{array}$$where u (x, t) is the voltage at time t and position x on the transmission line; i (x, t) is the current at time t and position x on the transmission line. When u (x, t) and i (x, t) change as a sine function of time, u (x, t) and i (x, t) can be expressed as$$\begin{array}{c}\text{(4)}& ux,t=\text{u\hspace{0.17em}max\hspace{0.17em}cos}wt+yux=\text{u\hspace{0.17em}max}{e}^{i\omega t}{e}^{yux}\\ =ux{e}^{i\omega t},\\ \text{(5)}& ix,t=\text{i\hspace{0.17em}max\hspace{0.17em}cos}wt+yix=\text{i\hspace{0.17em}max}{e}^{i\omega t}{e}^{yix}\\ =ix{e}^{i\omega t},\end{array}$$where u(x) is the voltage at position x on the transmission line; i(x) is the current at the position x on the transmission line.

Equations (6) and (7) can be derived from the combined equations (2)–(5).$$\begin{array}{}\text{(6)}& \frac{\text{d}ux}{\text{d}x}=-j\omega L+Rix,\text{(7)}& \frac{dix}{dx}=-j\omega C+Gux.\end{array}$$

The derivative of equations (6) and (7) with respect to x, respectively, gives us the following:$$\begin{array}{c}\text{(8)}& -\frac{d^{2}ux}{\text{d}{x}^2}=j\omega L+Rj\omega C+Gux={\gamma }^{2}ux,\\ \text{(9)}& -\frac{d^{2}ix}{\text{d}{x}^2}=j\omega L+Rj\omega C+Gix={\gamma }^{2}ix,\end{array}$$where γ is the propagation coefficient of voltage and current on the transmission line. By solving (8) and (9), the general solutions (10) and (11) can be obtained.$$\begin{array}{}\text{(10)}& ux=A1e^{\gamma x}+A2e^{\gamma x},\text{(11)}& ix=\sqrt{\frac{G+j\omega L}{R+j\omega C}}A1e^{-\gamma x}+A2e^{-\gamma x}.\end{array}$$

When the voltage and current at x = 0 on the transmission line are known, the voltage and current at any part of the transmission line can be obtained. The equation is described as follows:$$\begin{array}{c}\text{(12)}& ux=\frac{1}{2}u0+\sqrt{\frac{R+j\omega L}{G+j\omega C}}i0e^{-\gamma x}+\frac{1}{2}u0-\sqrt{\frac{R+j\omega L}{G+j\omega C}}i0e^{\gamma x},ix=\frac{1}{2}\sqrt{\frac{G+j\omega C}{R+j\omega L}}u0+i0e^{-\gamma x}-\frac{1}{2}\sqrt{\frac{G+j\omega C}{R+j\omega L}}u0-i0e^{\gamma x}.\end{array}$$

When the voltage or current on the transmission line is detected by a probe, information leakage will occur.

The schematic diagram of the filter is shown in Figure 3. It can be found that filter is a two-port network, the input voltage and current of port 1 are u₁ and i₁, respectively, and the output voltage and current of port 2 are u₂ and i₂, respectively. When the filter ports match, the forward voltage transmission of the filter can be expressed as [24]$$\begin{array}{}\text{(13)}& S_{21}=\frac{u_2-i_2{Z}_0}{u_1+i_1{Z}_0}.\end{array}$$

[figure omitted; refer to PDF]

When the filter is a bandstop filter, the filter can reduce the voltage and current containing information on the transmission line. Hence, the bandstop filter can prevent information leakage before the information device is connected to the transmission line.

Based on the previously mentioned analysis, the bandstop filter is important to prevent the transmission line conducting electromagnetic information leakage. Therefore, it is worthy to research bandstop filter and the design of bandstop filter is mainly introduced in the following paper.

3. Filter Structure

The structure diagram of the traditional bandstop filter is shown in Figure 4(a). It is composed of connected and open stubs. The filter with connected and open stubs can achieve high insertion loss, but the physical width of connected stubs is too narrow to carry a high current. According to [23], the structure of the traditional bandstop filter can be transformed into that of Figure 4(c) by using the structure of Figure 4(b), and the unequal width of the coupled structure can be used in the structure of Figure 4(c), which enables the connected stubs to carry a high current. Hence, Figure 4(c) is the structure of the proposed MSBSF for preventing conduction electromagnetic information leakage of high-power transmission line in this paper.

[figures omitted; refer to PDF]

As is shown in Figure 4(c), the proposed MSBSF consists of n parts, and each part consists of a parallel coupling line with an open stub. To realize a high insertion loss (>40 dB) and has a simple structure, the MSBSF consists of only five parts. The reason MSBSF consists of only five parts is shown in Figure 5. It can be found that the MSBSF consists of only part1, or part1 + part2, or part1 + part2 + part3, or part1 + part2 + part3 + part4 cannot realize high insertion loss, so the structure of the filter is composed of five parts, and the structure diagram in shown in Figure 2(d). The odd and even mode characteristic impedances of the parallel coupling lines are Z_o1 and Z_e1, Z_o2 and Z_e2, Z_o3 and Z_e3, Z_o4 and Z_e4, Z_o5 and Z_e5, respectively. The characteristic impedances of the open stubs are Z₁, Z₂, Z₃, Z₄, Z₅, respectively. The characteristic impedances of the port are Z₀, Z₀ = 50 Ω. The electrical lengths of the parallel coupling lines and open stubs all are θ. θ = π/2 at the center frequency of the stopband. The MSBSF is symmetrical around part 3 for the convenience of design and analysis. Because the MSBSF is symmetrical around part 3, Z₁ = Z₅, Z₂ = Z₄, Z_o1 = Z_o5, Z_e1 = Z_e5, Z_o2 = Z_o4, and Z_e2 = Z_e4.

[figure omitted; refer to PDF]

The relationship between the current that an external microstrip line can carry and the width of the line is shown in Figure 9. The higher the current, the larger the width required for the external microstrip line. When the current is 10 A, the width of the external microstrip line is 3.58 mm. Thus, if the external microstrip line carries a current more than 10 A, the width of the line needs to be larger than 3.58 mm.

[figure omitted; refer to PDF]

According to [26–28], when the characteristic impedance of the external microstrip line is a fixed value, the width of the line is related to the dielectric constant and thickness of the substrate. The specific relationship between the width of the external microstrip line and the dielectric constant and the thickness of the substrate is as follows [24]:$$\begin{array}{}\text{(19)}& Z=\frac{120\pi }{\sqrt{\epsilon }}{\frac{W}{H}+1\text{.}393+\text{0}\text{.}677\ln \frac{W}{H}+1.444}^{-1},\frac{W}{H}\ge 1,\end{array}$$where Z is the characteristic impedance of the external microstrip line and ε is the dielectric constant of the substrate.

To clearly show the relationship between the width of the external microstrip line and the dielectric constant and the thickness of the substrate, the relevant data calculated by line calculation software are shown in Figures 10(a) and 10(b). Figure 10(a) reveals the relationship between the dielectric constant of the substrate and the width of the external microstrip line. With the increase of the dielectric constant of the substrate, the width of the external microstrip line decreases. When the dielectric constant of the substrate is less than 3.1, the width of the external microstrip line is larger than 3.58 mm, and the current flowing through the external microstrip line is greater than 10A. The relationship between the thickness of the substrate and the width of the external microstrip line is plotted in Figure 10(b). With the increase of the substrate thickness, the width of the external microstrip line also increases. When the thickness of the substrate is greater than 1.35 mm, the width of the external microstrip line is greater than 3.58 mm, and the current flowing through the external microstrip line is greater than 10A.

[figures omitted; refer to PDF]

By analyzing the performance of the external microstrip line passing through the current, it can be found that when the characteristic impedance of the external microstrip line is 50 Ω and the external microstrip line can carry a current of 10A, the PCB with a substrate thickness of 1.5 mm and a dielectric constant of the substrate less than 3.1 can be used, or the PCB with a dielectric constant of 2.65 and a thickness of substrate greater than 1.35 mm can be used.

Several commonly used PCBs for fabricating MSBSF are shown in Table 1. It can be found that the dielectric constant and substrate thickness of the PCBs meet the requirements, but the cost of F4B is less than that of Rogers.

Table 1

Several commonly used PCBS.

6. Experiment and Discussion

Based on the analysis in Sections 4 and 5, a MSBSF with an insertion loss of 50 dB in the frequency range of 2.4-2.49 GHz is designed. According to Figures 6 and 7, z₁ = Z₅ = 90 Ω, Z₂ = Z₄ = 66 Ω, Z₃ = 81.3 Ω, k₁ = k₅ = 0.48, k₂ = k₄ = 0.37, and k₃ = 0.46. After simulation and optimization by HFSS, the final characteristic impedance parameters of the MSBSF are Z₀ = 50 Ω, Z₁ = Z₅ = 91.33 Ω, Z₂ = Z₄ = 66.28 Ω, Z₃ = 81.3 Ω, Z_o1 = Z_o5 = 44.1 Ω, Z_e1 = Z_e5 = 124 Ω, Z_o2 = Z_o4 = 38.84 Ω, Z_e2 = Z_e4 = 83.74 Ω, Z_o3 = 40.24 Ω, and Z_e3 = 108 Ω. According to Section 5, considering the low cost, the MSBSF is made of F4BM265, and its dielectric constant, thickness of the substrate, and thickness of external microstrip line are 2.65, 1.5 mm, and 0.07 mm, respectively. To make the transmission line of the MSBSF pass through the current of 10A, the unequal width of the coupled structure [23, 29] is used. The final layout and the dimensions of the MSBSF are shown in Figure 11(a) and Table 2, respectively. The manufactured MSBSF is presented in Figure 11(b).

[figures omitted; refer to PDF]

Table 2

The optimized dimensions of the MSBSF.

To verify the filtering effect of the MSBSF, a vector network analyzer is utilized. The experimental equipment for measuring the filtering effect of the MSBSF is shown in Figures 12(a) and 12(b). The electromagnetic (EM) simulation and measurement results of the MSBSF are plotted in Figure 13. The bandstop filter designed in this paper can produce transmission zeros, but there are no zeros at the center frequency, so the bandwidth of the stopband is narrow. The EM simulation results show that an insertion loss more than 50 dB can be achieved in the frequency range of 2.40-2.49 GHz, and three transmission zeros can be realized in the stopband, which are located at 2.41 GHz, 2.44 GHz, and 2.48 GHz, respectively. Impedance matching must be considered when the microstrip filter is connected to the transmission line to prevent the transmission line conducting electromagnetic information leakage, but impedance matching is not the main research in this paper. Therefore, for matching the impedance, the coaxial transmission line is used as the power transmission line. The measurement results of the MSBSFs with and without power transmission line show that the insertion losses of the fabricated MSBSF are all 38 dB, and the frequency ranges are all 2.41–2.49 GHz. The insertion loss and frequency range of measurement with power line and that without power transmission line are in good agreement, but the passband insertion loss measured with power line is larger than that without power line. The results of simulation and measurement are different. The differences between them may come from a tiny dimensional error during the fabrication of MSBSF. The measurement results with and without power transmission line are in good agreement, but there are a few differences. The differences between them may come from the effect of power transmission lines.

[figures omitted; refer to PDF]

[figure omitted; refer to PDF]

To verify that the MSBSF can pass through a current greater than 10A, a current tester and an electromagnet are used. The current tester provides current, the electromagnet is the load resistance, and the MSBSF is connected in series with the power transmission lines. The experimental equipment for measuring the current is shown in Figure 14(a). It can be found that the MSBSF can carry a current greater than 10A. To test the withstand voltage performance of the MSBSF, a high-voltage generator is applied. The experimental equipment is shown in Figure 14(b). It can be found that MSBSF can withstand a voltage of 1.7 kV.

[figures omitted; refer to PDF]

Through the previously mentioned experiments, it can be found that the MSBSF can achieve an attenuation of 38 dB to block 2.41–2.49 GHz high-frequency signal and can be used in transmission lines with a power of at least 17544 W.

The comparison among the MSBSF in this paper and the reported filters is provided in Table 3. It can be found that the insertion loss of MSBSF is better than that given in [19, 20], and the current and voltage of the filter are analyzed and verified. The comparison between the MSBSF and the EMI filter is provided in Table 4. It can be found that the MSBSF withstands higher voltage and carries greater current than EMI filters in addition to being used in high-frequency bands.

Table 3

Comparison with previously reported filters.

NA: the current and voltage of the filters are not analyzed.

Table 4

Comparison between MSBSF and EMI filter.

7. Conclusion

In this paper, a high insertion loss microstrip bandstop filter (MSBSF), which can be applied to high-power transmission lines, is designed. According to the structure of the traditional branch load band stop filter, the equivalent structure and the unequal-width technology of the parallel coupled microstrip line are used to realize the filter can carry large current and have high insertion loss by increasing the filter order. The MSBSF is composed of n parts, and each part consists of a parallel coupling line with an open stub. To produce the MSBSF with a high insertion loss, an analysis is carried out, and it is found that the MSBSF consisting of five parts can realize an insertion loss more than 40 dB and has a simple structure. Then, the MSBSF is analyzed from both theory and simulation aspects, and the design process is summarized. Besides, the width of the external microstrip line which can carry a current of 10A is analyzed, and the characteristics of PCB which can carry a current of 10A are summarized. Finally, according to the design process of MSBSF, the requirements of the external microstrip line carrying a current of 10A, and the characteristics of PCB which can carry a current of 10A, MSBSF with an insertion loss of 50 dB in the frequency range of 2.40–2.49 GHz is designed and fabricated with low cost F4BM265. To test the performance of MSBSF, a vector network analyzer, a current tester, and a high-voltage generator are used. It is found that the attenuation of MSBSF is 38 dB at 2.412.49 GHz, and the MSBSF can carry a current greater than 10A and withstand the voltage of 1.7 kV. Hence, the designed MSBSF may be used in preventing high-frequency conduction electromagnetic information leakage of high-power transmission lines. Microstrip filter has good performance in microwave frequency band, and because of its unique structure, it is convenient to connect with transmission line and has unique advantages in preventing transmission line conduction electromagnetic information leakage. In order to better filter electromagnetic information in transmission line, the filter used to prevent transmission line conduction electromagnetic information leakage should have high insertion loss. Therefore, the research of filter with high insertion loss has research value in preventing transmission line conduction electromagnetic information leakage and should become one of the performance improvements of band stop filter in the future. Although the range of work frequency of the filter that we discuss in this paper is very narrow (2.41-2.49 GHz), it is a part of our current research work. The range of work frequency of this filter has the possibility of broadening, but it requires further simulation and verification, which is also what we will do in the future.

Authors’ Contributions

Xueyun Han is responsible for conceptualization and methodology and funding acquisition. Pengfei Zheng was responsible for software, validation, formal analysis, and original draft preparation. Xiaosong Li was responsible for review and editing. Yingping Zhou was responsible for project administration. Xueyun Han and Pengfei Zheng contributed equally to this work. All authors have read and agreed to the published version of the manuscript.

Acknowledgments

The Key Discipline Open Lab of Electromagnetic Wave Characteristic Information Detection of Henan Province provided the equipment. This work was supported by the Key Projects of Science and Technology of Henan Province (Grant nos. 212102210218 and 202102210316) and Foundation of Henan Educational Committee (Grant nos. 22A510007 and 22A430025).