基于戟形人工表面等离激元的紧凑型宽带外抑制带通滤波器

孙淑鹏; 程用志; 罗辉; 陈浮; 李享成

doi:10.7498/aps.72.20222291

摘要

提出了一种基于戟形人工表面等离激元(spoof surface plasmon polaritons, SSPPs)的具有宽频带外抑制特性的紧凑型宽带带通滤波器. 设计的滤波结构是通过在基板底层蚀刻周期性的戟形槽和在顶层加载带有月牙形贴片的微带到槽线过渡结构实现的. 与传统的I形SSPPs相比, 戟形SSPPs具有更好的慢波特性, 基于戟形SSPPs设计的带通滤波器可以实现更紧凑的结构. 设计的滤波器通带的上下截止频率可以分别通过调整SSPPs结构和微带到槽线过渡结构来调节. 仿真结果表明, 宽带带通滤波器中心频率为2.85 GHz, 相对带宽为130%, 通带内的回波损耗优于–10 dB, 在5.6—20.0 GHz之间具有极强的–40 dB带外抑制. 设计的宽带带通滤波器结构尺寸紧凑, 仅为1.08λ_g× 0.39λ_g, 其中λ_g是中心频率处的波长. 为了验证宽带带通滤波器的有效性, 采用传统的印刷电路板技术加工了宽带带通滤波器. 测量结果与仿真结果吻合较好, 验证了设计的可行性. 本文所提出的宽带带通滤波器显示了在微波频率下开发SSPPs功能器件和电路的良好前景.

关键词:

Abstract

In this paper, a compact broadband bandpass filter with wide out-of-band rejection characteristics based on halberd-shaped spoof surface plasmon polariton (SSPP) is proposed. The filtering structure is achieved by etching a periodic halberd-shaped groove at the bottom of the substrate and a microstrip-to-slot line transition with a crescent-shaped patch at the top. Compared with the traditional dumbbell-shaped SSPP, the halberd-shaped SSPP has good slow-wave property, and the designed bandpass filter based on halberd-shaped SSPP can achieve a more compact size. The upper cutoff frequency and lower cutoff frequency of the passband can be adjusted by regulating the SSPP structure and the transition structure from microstrip-to-slot line, respectively. The simulation results show that the center frequency of broadband bandpass filter is 2.85 GHz, with the relative bandwidth of 130%, and the return loss in the passband is better than –10 dB, and the extreme strong out-of-band rejection of –40 dB from 5.6 GHz to 20.0 GHz. The size of the broadband bandpass filter is compact, only 1.08λ_g× 0.39λ_g, where λ_g is the wavelength at the center frequency. In order to verify the effectiveness of the wideband bandpass filter, the traditional printed circuit board technology is used to fabricate the wideband bandpass filter. The measurement results are in good agreement with the simulation results, verifying the feasibility of the design. The proposed broadband bandpass filter shows promising prospects for developing SSPP functional devices and circuits at microwave frequencies.

Keywords:

spoof surface plasmon polariton /
broadband bandpass filter /
microstrip-to-slotline transition structure

作者及机构信息

1.
武汉科技大学信息科学与工程学院, 武汉　430081

2.
武汉科技大学, 耐火材料与冶金国家重点实验室, 武汉　430081

通信作者: 程用志, chengyz@wust.edu.cn

基金项目: 湖北省自然科学基金创新群体项目 (批准号: 2020CFA038)和湖北省重点研发计划(批准号: 2020BAA028)资助的课题.

Authors and contacts

1.
School of Information Science and Engineering, Wuhan University of Science and Technology, Wuhan 430081, China

2.
State Key Laboratory of Refractory Materials and Metallurgy, Wuhan University of Science and Technology, Wuhan 430081, China

Corresponding author: Cheng Yong-Zhi, chengyz@wust.edu.cn

Funds: Project supported by the Natural Science Foundation Innovation Group Project of Hubei Province, China (Grant No. 2020CFA038) and the Key R&D Project of Hubei Province, China (Grant No. 2020BAA028).

文章全文 : translate this paragraph

参考文献

[1]	Noura A, Benaissa M, Abri M, Badaoui H, Vuong T H, Tao J 2019 Microw. Opt. Techn. Lett. 61 1473 Google Scholar
[2]	Shen G X, Che W Q, Feng W J, Shi Y R, Shen Y M, Xu F 2021 IEEE Trans. Circuits Syst. II 68 1778 Google Scholar
[3]	兰峰, 高喜, 亓丽梅 2014 63 104209 Google Scholar Lan F, Gao X, Qi L M 2014 Acta Phys. Sin. 63 104209 Google Scholar
[4]	Pendry J B, Martin-Moreno L, Garcia-Vidal F J 2004 Science 305 847 Google Scholar
[5]	Liao Z, Zhao J, Pan B C, Shen X P, Cui T J 2014 J. Phys. D 47 315103 Google Scholar
[6]	罗宇轩, 程用志, 陈浮, 罗辉, 李享成 2023 72 044101 Google Scholar Luo Y X, Cheng Y Z, Chen F, Luo H, Li X C 2023 Acta Phys. Sin. 72 044101 Google Scholar
[7]	盛世威, 李康, 孔繁敏, 岳庆炀, 庄华伟, 赵佳 2015 64 108402 Google Scholar Sheng S W, Li K, Kong F M, Yue Q Y, Zhuang H W, Zhao J 2015 Acta Phys. Sin. 64 108402 Google Scholar
[8]	Chen P, Li L P, Yang K, Chen Q 2018 IEEE Microw. Wirel. Compon. Lett. 28 984 Google Scholar
[9]	Sun S P, Cheng Y Z, Luo H, Chen F, Li X C 2023 Plasmonics 18 165
[10]	Wang J, Zhao L, Hao Z C, Shen X, Cui T J 2019 Opt. Lett 44 3374 Google Scholar
[11]	Kianinejad A, Chen Z N, Qiu C W 2015 IEEE Trans. Microw. Theory Tech. 63 1817 Google Scholar
[12]	Yin J Y, Ren J, Zhang Q, Zhang H C, Liu Y Q, Li Y B, Cui T J 2016 IEEE Trans. Antennas Propagat. 64 5181 Google Scholar
[13]	Wang J, Zhao L, Hao Z C 2019 IEEE Access 7 35089 Google Scholar
[14]	Guan D F, You P, Zhang Q F, Xiao K, Yong S W 2017 IEEE Trans. Microw. Theory Tech. 65 4925 Google Scholar
[15]	Moznebi A R, Afrooz K, Arsanjani A 2022 Int. J. Electron. Commun. 145 154084 Google Scholar
[16]	Luo Y X, Yu J W, Cheng Y Z, Chen F, Luo H 2022 Appl. Phys. A 128 1 Google Scholar
[17]	Guan D F, You P, Zhang Q F, Yang Z B, Liu H W, Yong S W 2018 IEEE Trans. Microw. Theory Tech. 66 2946 Google Scholar
[18]	Sangam R S, Kshetrimayum R S 2021 IET Microw. Antennas Propag. 15 289 Google Scholar
[19]	Liu H, Wang Z B, Zhang Q F, Ma H F, Ren B P, Wen P 2019 IEEE Access 7 44212 Google Scholar
[20]	Guo Y J, Xu K D, Liu Y H, Tang X H 2018 IEEE Access 6 10249 Google Scholar

施引文献

图 1 (a)矩形SSPP单元; (b) I形SSPP单元; (c)戟形SSPP单元; (d)色散曲线的比较

Fig. 1. (a) Rectangular-shaped SSPP unit cell; (b) I-shaped SSPP unit cell; (c) halberd-shaped SSPP unit cell; (d) comparison of dispersion curves.

下载: 全尺寸图片幻灯片

图 2 宽带带通滤波器的示意图　(a)顶视图; (b)底视图

Fig. 2. Schematic of broadband bandpass filter: (a) Top view; (b) bottom view.

下载: 全尺寸图片幻灯片

图 3 (a)宽带带通滤波器的示意图(N = 1, 2, 3, 4); (b)不同SSPP单元数量下的宽带带通滤波器的S参数

Fig. 3. (a) Schematic of broadband bandpass filter (N = 1, 2, 3, 4); (b) S-parameters of broadband bandpass filters with different SSPP element numbers.

下载: 全尺寸图片幻灯片

图 4 模拟了(a) 0.5 GHz, (b) 3.0 GHz和(c) 7.0 GHz处的宽带带通滤波器z分量电场分布

Fig. 4. Simulated z-component electric field distributions of the broadband bandpass filter at (a) 0.5 GHz, (b) 3.0 GHz, and (c) 7.0 GHz.

下载: 全尺寸图片幻灯片

图 5 (a)宽带带通滤波器的等效LC电路; (b)电磁仿真和等效LC电路S参数的对比曲线

Fig. 5. (a) Equivalent LC circuit of broadband bandpass filter; (b) comparison of electromagnetic simulation and equivalent LC circuit S-parameters.

下载: 全尺寸图片幻灯片

图 6 (a)不同戟形槽深度下戟形SSPP的色散曲线; (b)不同戟形槽深度下宽带带通滤波器的透射系数(S₂₁)

Fig. 6. (a) Dispersion curves of halberd-shaped SSPP at different depth of halberd grooves; (b) transmission coefficient (S₂₁) of broadband bandpass filter at different depth of halberd grooves.

下载: 全尺寸图片幻灯片

图 7 (a)不同开槽线宽度下戟形SSPP的色散曲线; (b)不同开槽线宽度下宽带带通滤波器的透射系数(S₂₁)

Fig. 7. (a) Dispersion curves of halberd-shaped SSPP at different slotline widths; (b) transmission coefficients (S₂₁) of broadband bandpass filters at different slotline widths.

下载: 全尺寸图片幻灯片

图 8 模拟了不同月牙槽r_d下宽带带通滤波器的透射系数(S₂₁)

Fig. 8. Transmission coefficient (S₂₁) of broadband bandpass filter under different crescent r_d.

下载: 全尺寸图片幻灯片

图 9 (a), (b)制备的宽带带通滤波器的正面和背面视图; (c)模拟和实测的S参数的对比曲线

Fig. 9. (a), (b) Top view and bottom view of the broadband bandpass filter; (c) comparison of simulated and measured S-parameters.

下载: 全尺寸图片幻灯片

图 10 模拟了不同介质基板下宽带带通滤波器的S参数(S₂₁和S₁₁).

Fig. 10. Simulated S-parameters (S₂₁ and S₁₁) of wideband bandpass filters on different dielectric substrates

下载: 全尺寸图片幻灯片

表 1 与参考文献中带通滤波器的性能对比(FBW, 分数带宽)

Table 1. Comparison of our proposed bandpass filters with bandpass filters in references (FBW, fractional bandwidth).

参考文献	频率范围	FBW/%	带外抑制	尺寸(λ_g×λ_g)
[8]	7.3—11.2	42.2	–40 dB@11.8—19.8 GHz	2.85×0.67
[15]	1.18—6.18	135.8	–31 dB@6.9—18.0 GHz	1.83×0.46
[17]	8—16	67.0	–7 dB@16.2—17.0 GHz	2.64×0.29
[18]	8.0—13.5	51.0	–40 dB@14.0—19.5 GHz	1.87×0.63
[19]	2.1—8.0	16.8	–30 dB@8.9—20.0 GHz	1.47×0.42
[20]	1.1—7.3	147.6	–30 dB@7.5—20.0 GHz	2.95×0.89
本文	1.0—4.7	130.0	–40 dB@5.6—20.0 GHz	1.08×0.39

下载: 导出CSV

map

[1]	Noura A, Benaissa M, Abri M, Badaoui H, Vuong T H, Tao J 2019 Microw. Opt. Techn. Lett. 61 1473 Google Scholar
[2]	Shen G X, Che W Q, Feng W J, Shi Y R, Shen Y M, Xu F 2021 IEEE Trans. Circuits Syst. II 68 1778 Google Scholar
[3]	兰峰, 高喜, 亓丽梅 2014 63 104209 Google Scholar Lan F, Gao X, Qi L M 2014 Acta Phys. Sin. 63 104209 Google Scholar
[4]	Pendry J B, Martin-Moreno L, Garcia-Vidal F J 2004 Science 305 847 Google Scholar
[5]	Liao Z, Zhao J, Pan B C, Shen X P, Cui T J 2014 J. Phys. D 47 315103 Google Scholar
[6]	罗宇轩, 程用志, 陈浮, 罗辉, 李享成 2023 72 044101 Google Scholar Luo Y X, Cheng Y Z, Chen F, Luo H, Li X C 2023 Acta Phys. Sin. 72 044101 Google Scholar
[7]	盛世威, 李康, 孔繁敏, 岳庆炀, 庄华伟, 赵佳 2015 64 108402 Google Scholar Sheng S W, Li K, Kong F M, Yue Q Y, Zhuang H W, Zhao J 2015 Acta Phys. Sin. 64 108402 Google Scholar
[8]	Chen P, Li L P, Yang K, Chen Q 2018 IEEE Microw. Wirel. Compon. Lett. 28 984 Google Scholar
[9]	Sun S P, Cheng Y Z, Luo H, Chen F, Li X C 2023 Plasmonics 18 165
[10]	Wang J, Zhao L, Hao Z C, Shen X, Cui T J 2019 Opt. Lett 44 3374 Google Scholar
[11]	Kianinejad A, Chen Z N, Qiu C W 2015 IEEE Trans. Microw. Theory Tech. 63 1817 Google Scholar
[12]	Yin J Y, Ren J, Zhang Q, Zhang H C, Liu Y Q, Li Y B, Cui T J 2016 IEEE Trans. Antennas Propagat. 64 5181 Google Scholar
[13]	Wang J, Zhao L, Hao Z C 2019 IEEE Access 7 35089 Google Scholar
[14]	Guan D F, You P, Zhang Q F, Xiao K, Yong S W 2017 IEEE Trans. Microw. Theory Tech. 65 4925 Google Scholar
[15]	Moznebi A R, Afrooz K, Arsanjani A 2022 Int. J. Electron. Commun. 145 154084 Google Scholar
[16]	Luo Y X, Yu J W, Cheng Y Z, Chen F, Luo H 2022 Appl. Phys. A 128 1 Google Scholar
[17]	Guan D F, You P, Zhang Q F, Yang Z B, Liu H W, Yong S W 2018 IEEE Trans. Microw. Theory Tech. 66 2946 Google Scholar
[18]	Sangam R S, Kshetrimayum R S 2021 IET Microw. Antennas Propag. 15 289 Google Scholar
[19]	Liu H, Wang Z B, Zhang Q F, Ma H F, Ren B P, Wen P 2019 IEEE Access 7 44212 Google Scholar
[20]	Guo Y J, Xu K D, Liu Y H, Tang X H 2018 IEEE Access 6 10249 Google Scholar

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