基于新型四模谐振器的双通带带通滤波器设计

孙久会; 张德伟; 王树兴; 吕大龙

doi:doi:10.11884/hplpb201931.180371

强激光与粒子束, 2019, 31 (5): 053005, 网络出版: 2019-06-10

基于新型四模谐振器的双通带带通滤波器设计

Design of dual-band bandpass filter based on novel quad-mode resonator

论文大纲

孙久会 ^*张德伟王树兴吕大龙

作者单位

信息工程大学信息系统工程学院, 郑州 450001

摘要

提出了一种新型的基于双枝节加载的T型四模谐振器，并且利用该谐振器设计了一款双模双通带带通滤波器。首先利用奇偶模分析法以及场分布分析法对四模谐振器的频率特性进行分析，谐振器的每一个谐振模式均可以被独立调节。然后对馈线枝节的参数进行了详细的分析，得到馈线对滤波器外部耦合系数的影响，以调整滤波器通带的带通宽度。接着分析滤波器传输零点产生的原因，得到零点变化的规律，从而调整零点位置，提高滤波器的选择性。缺陷地结构(DGS)被蚀刻在滤波器的金属层底面，以引入非谐振节点，提供源与负载的耦合，可以产生额外的传输零点，进一步提高滤波器的选择性，而且不会增大滤波器的体积。对该滤波器进行加工和测试，仿真结果与测试结果基本吻合。

Abstract

In this paper, a novel dual-mode dual-band bandpass filter using a quad-mode dual-stub loaded T-type resonator is proposed. The quad-mode resonator is analyzed using odd-/even-mode method. Field distribution of each mode is illustrated, and each mode can be independently controlled. The required extra quality factor (Qe) can be realized by determining the proper feed-lines parameters, and detail analysis is provided to adjust bandwidth of filter passbands. Then the cause of the zero point of the filter transmission is analyzed get the rule of the zero point change is got for adjusting the zero position and improving the selectivity of the filter. defected ground structure (DGS), etched on the bottom metal surface of the filter, working as a non-resonant node (NRN) and proving source-to-load coupling, are utilized to introduce extra transmission zero to improve the passband selectivity without increasing filter volume. The filter was designed and fabricated, and the simulated results are in accordance with the measured results.

参考文献

[1] Qiang T, Wang C, Kim N Y. Highly selective dual-wideband bandpass filter using quad-mode resonators for WLAN and WIMAX applications［J］. Microwave & Optical Technology Letters, 2015, 57(6):1417-1423.

[2] Chen Y F, Dai Z J, Chiu C T, et al. Compact dual-band bandpass filter based on quarter wavelength stepped impedance resonators［J］. World Academy of Science, Engineering and Technology, International Journal of Electrical, Computer, Energetic, Electronic and Communication Engineering, 2016, 10(4):517-520.

[3] Wu G, Yang L, Xu Q. Miniaturised dual-band filter with high selectivity using split ring scheme［J］. Electronics Letters, 2015, 51(7):570-572.

[4] Gao S S, Sun S, Li J L, et al. Compact dual-mode dual-band bandpass filter with inside-outside-reversed dual-ring topology［J］. Electronics Letters, 2017, 53(9):624-626.

[5] Chen J X, Yum T Y, Li J L, et al. Dual-mode dual-band bandpass filter using stacked-loop structure［J］. IEEE Microwave & Wireless Components Letters, 2006, 16(9):502-504.

[6] Zhang Y P, Sun M. Dual-band microstrip bandpass filter using stepped-impedance resonators with new coupling schemes［J］. IEEE Transactions on Microwave Theory & Techniques, 2006, 54(10):3779-3785.

[7] Chuang M L, Wu M T, Tsai S M. Dual-band filter design using L-shaped stepped impedance resonators［J］. IET Microwaves, Antennas & Propagation, 2010, 4(7):855-0.

[8] Liu H, Liu F, Qin F, et al. Compact dual-band HTS bandpass filter using spirally asymmetric stepped-impedance resonators［J］. IEEE Transactions on Applied Superconductivity, 2016, 26(7):1-5.

[9] Zhang X Y, Chen J X, Xue Q, et al. Dual-band bandpass filters using stub-loaded resonators［J］. IEEE Microwave and Wireless Components Letters, 2007, 17(8):583-585.

[10] Yang S, Lin L, Chen J, et al. Design of compact dual-band bandpass filter using dual-mode stepped-impedance stub resonators［J］. Electronics Letters, 2014, 50(8):611-613.

[11] Chu Qing Xin, Li, et al. Dual-band filter using asymmetrical stub-loaded resonator with independently controllable frequencies and bandwidths［J］. Let Microwaves Antennas & Propagation, 2013, 7(9):729-734.

[12] Zhou K, Zhou C, Wu W. Substrate integrated waveguide dual-band filter with wide-stopband performance［J］. Electronics Letters, 2017, 53(16):1121-1123.

[13] Azad A R, Mohan A. Substrate integrated waveguide dual-band and wide-stopband bandpass filters［J］. IEEE Microwave & Wireless Components Letters, 2018, PP(99):1-3.

[14] Zhou K, Zhou C X, Wu W. Resonance characteristics of substrate-integrated rectangular cavity and their applications to dual-band and wide-stopband bandpass filters design［J］. IEEE Transactions on Microwave Theory & Techniques, 2017(99):1-14.

[15] Gao L, Zhang X Y. High-selectivity dual-band bandpass filter using a quad-mode resonator with source-load coupling［J］. IEEE Microwave and Wireless Components Letters, 2013, 23(9):474-476.

[16] Peng Y, Zhang L, Zheng Z, et al. High selective compact dual-band filter using ring resonator with quarter-wavelength stubs［J］. Electronics Letters, 2017, 53(24):1589-1591.

[17] Peng Y, Zhang L, Fu J, et al. Compact dual-band bandpass filter using coupled lines multimode resonator［J］. IEEE Microwave and Wireless Components Letters, 2015, 25(4):235-237.

[18] Liao C K, Chi P L, Chang C Y. Microstrip realization of generalized Chebyshev filters with box-like coupling schemes［J］. IEEE Transactions on Microwave Theory & Techniques, 2007, 55(1):147-153.

孙久会, 张德伟, 王树兴, 吕大龙. 基于新型四模谐振器的双通带带通滤波器设计[J]. 强激光与粒子束, 2019, 31(5): 053005. Sun Jiuhui, Zhang Dewei, Wang Shuxing, Lü Dalong. Design of dual-band bandpass filter based on novel quad-mode resonator[J]. High Power Laser and Particle Beams, 2019, 31(5): 053005.

基于新型四模谐振器的双通带带通滤波器设计

关于本站 Cookie 的使用提示

全站搜索

基于新型四模谐振器的双通带带通滤波器设计

相关论文

相关资讯

关于本站 Cookie 的使用提示

全站搜索