为解决高速数据采集终端的抗干扰问题,该文基于阶梯阻抗谐振器,提出了一种分布式印制差分低通滤波器,其中高阻抗传输线利用松耦合的差分线对实现,低阻抗传输线利用紧耦合的差分线对实现。为减小滤波器尺寸,高低阻抗传输线均以折叠线形式实现。作为示例,采用分布式印制方法,利用FR4三层印制电路板设计了低成本的差分低通滤波器,截止频率为3.5 GHz,可有效覆盖高速数据采集终端的工作频率。该差分低通滤波器可应用于高速数据采集终端,解决高速采集和无线互联之间的互扰问题。
[Objective] In high-speed data acquisition terminals, differential lines are commonly employed to carry high-speed digital signals, enhancing anti-interference performance. However, mutual interference frequently occurs when high-speed acquisition terminals and wireless devices coexist. For instance, 5G base stations and Gbps high-speed signal acquisition terminals in current 5G high-speed acquisition systems interfere with each other. This issue is addressed by installing electromagnetic interference (EMI) filters on a printed circuit board (PCB); however, EMI filters have disadvantages, including fixed frequency points and high cost, which hinder their practicability. In this work, a design method for a low-cost, easy-to-implement distributed printed differential low-pass filter is proposed based on a step impedance filter that can be designed using simple synthesis tools and applied to multilayer PCBs of various radiofrequency systems.[Methods] Based on a typical LC low-pass filter, step impedance resonators were introduced as a solution to high-frequency parasitic parameters and harmonic suppression. The high- and low-impedance transmission lines serve as an inductor and capacitor, respectively, realizing the transformation from a single-end LC filter to a single-end microstrip filter. Due to the common-mode suppression requirements of differential circuits, symmetrical design and equivalent processing were performed for conversion into a microstrip differential low-pass filter, where the high-impedance line is realized by loosely coupled differential lines and the low-impedance line is realized by tightly coupled differential lines. The larger the impedance difference between high and low impedance in the design, the more it contributes to reducing the filter size, and the device size can be further reduced by adhering to this principle. In addition, considering the influence of the transmission line on the ground impedance, an independent non-grounded pair of differential lines was selected for the design. The PCB board used FR4 with a dielectric constant of 4.2 and a multilayer structure with thicknesses of 0.127 mm and 0.508 mm for the two dielectric layers. The final dimensions were 22 mm×16 mm.[Results] Simulation results showed that the distributed differential filter is a 0-3.5 GHz low-pass filter under ideal conditions. The passband and return loss values were less than 0.5 dB and greater than 20 dB, respectively. Two baluns were added to the circuit design used for differential circuit measurement. Test results revealed that the balun possesses considerable interference of approximately 600 MHz, but the curve without the balun's influence is highly consistent with the simulated curve. The passband and return loss values were <5 dB and <17 dB, respectively.[Conclusions] The findings of this work indicate that the method of using differential step impedance to realize a distributed printed filter based on a multilayer PCB board is feasible and can be effectively applied in high-speed data acquisition terminals as a solution to the mutual interference between high-speed acquisition and wireless interconnection.
[1] ZHU L, SUN S, MENZEL W. Ultra-wideband (UWB) bandpass filters using multiple-mode resonator[J]. IEEE Microwave and Wireless Components Letters, 2005, 15(11):796-798.
[2] WANG X H, ZHANG H L, WANG B Z. A novel ultra-wideband differential filter based on microstrip line structures[J]. IEEE Microwave and Wireless Components Letters, 2013, 23(3):128-130.
[3] TIRADOSSI D, AQUINO F, PELLICCIA L, et al. Ku-band differential lossy filter manufactured in thin-film on alumina technology[C]//IEEE MTT-S International Microwave Filter Workshop. Perugia, Italy:IEEE, 2021:95-97.
[4] YANG L, CHEONG P, CHOI W W, et al. Differential microstrip bandpass filter with dual-band responses using parallel-coupled line structure[C]//2012 Asia Pacific Microwave Conference Proceedings. Kaohsiung, China:IEEE, 2012:28-30.
[5] YANG L, GÓMEZ-GARCÍA R. Multilayered balanced wideband bandpass filter with high filtering selectivity[C]//2021 IEEE MTT-S International Microwave Filter Workshop (IMFW). Perugia, Italy:IEEE, 2021:17-19.
[6] SHI J, SHAO C, CHEN J X, et al. Compact low-loss wideband differential bandpass filter with high common-mode suppression[J]. IEEE Microwave and Wireless Components Letters, 2013, 23(9):480-482.
[7] PANG Y Y, FENG Z H. A compact common-mode filter for GHz differential signals using defected ground structure and shorted microstrip stubs[C]//2012 International Conference on Microwave and Millimeter Wave Technology (ICMMT). Shenzhen, China:IEEE, 2012:1-4.
[8] 甘本祓, 吴万春. 现代微波滤波器的结构与设计[M]. 北京:科学出版社, 1973. GAN B F, WU W C. Structure and design of modern microwave filter[M]. Beijing:Science Press, 1973. (in Chinese)
[9] MAKIMOTO M, YAMASHITA S. 无线通信中的微波谐振器与滤波器[M]. 赵宏锦, 译. 北京:国防工业出版社, 2002. MAKIMOTO M, YAMASHITA S. Microwave resonators and filters for wireless communication[M]. ZHAO H J, Trans. Beijing:National Defense Industry Press, 2002. (in Chinese)
[10] 尚阳阳, 李小珍, 邢孟江. 基于LTCC技术的差分滤波器设计[J]. 电子元件与材料, 2022, 41(7):736-739. SHANG Y Y, LI X Z, XING M J. Design of differential filter based on LTCC[J]. Electronic Components and Materials, 2022, 41(7):736-739. (in Chinese)
