一种抑制SSN的新型宽带平面电磁带隙结构

随着现代高速数字电路的快速发展,同步开关噪声(SSN)问题变得越来越突出。该文提出了一种适用于高速数字电路中抑制同步开关噪声的新型宽带平面电磁带隙(EBG)结构,并用Ansoft HFSS软件对该电磁带隙结构进行数据仿真分析。仿真结果表明,在抑制深度为-30dB时,其阻带范围为0.2~5.6 GHz,与传统的L-bridge型电磁带隙结构比较,阻带下限截止频率下降了500 MHz,阻带带宽增加了1.4GHz,相对带宽增加了38.1%,且能全向抑制同步开关噪声。     

一种抑制同步开关噪声的新颖电磁带隙结构

电源平面与接地平面间的同步开关噪声是现代高速、高性能数字电路应用的瓶颈之一。文中提出了一种应用于印刷电路板的新颖二维电磁带隙（MS-EBG）结构,其单位晶格由折线缝隙组合与正方形贴片桥接构成,以抑制同步开关噪声。结果表明,抑制深度为-30 dB时,与传统L-bridged EBG结构比较,新EBG结构的阻带宽度增加1.3 GHz,相对带宽提高了约10%,能够有效抑制0.6～5.9 GHz的同步开关噪声。     

一种基于互补环缝谐振器抑制SSN的新方法

针对高速PCB上抑制同步开关噪声(SSN)的问题,提出了一种将互补环缝谐振器(CSRR)刻蚀在电源平面上,抑制电源/地平面间的电场波动噪声传播的方法。采用基于有限元算法的HFSS软件对该结构进行仿真分析,结果表明:与理想参考平面和电磁带隙结构相比,刻蚀了该CSRR结构的电源分配网络具有较好的宽带全向SSN噪声抑制能力,在抑制深度为-40 dB时,其阻带覆盖从0.26 GHz到超过20 GHz以上的频率范围。     

一种新型多周期平面电磁带隙结构

根据不同周期平面电磁带隙(EBG)结构所具有的不同带隙特性以及平面EBG结构的等效电路,提出一种新型多周期平面EBG结构。通过Ansoft HFSS软件对该EBG结构的电磁带隙特性进行仿真验证。结果表明:所提出的EBG结构抑制深度为-30dB时,阻带范围为0.7～8.4GHz,阻带宽度为7.7GHz.相对于传统大周期和小周期平面EBG结构,其阻带宽度分别增加2.1GHz和1.2GHz.仿真结果也表明新型EBG结构可以有效抑制同步开关噪声(SSN),并为展宽平面EBG结构的禁带带宽提供一种新方法。最后,通过时域仿真验证新结构具有较好的信号完整性。     

一种适用于高速电路中SSN抑制的紧凑型电磁带隙新结构

该文根据电磁带隙(EBG)结构的带隙形成机理以及共面EBG结构的等效电路,提出了一种适用于高速电路中同步开关噪声(SSN)抑制的紧凑型EBG结构,使用Ansoft HFSS对该结构进行仿真分析。仿真结果表明在抑制深度为-30 dB时,阻带范围为0.6-6.4 GHz,阻带带宽为5.8 GHz,与传统的L-bridge结构相比,阻带带宽增加了1.8 GHz,相对带宽增加了45%,实现了较低的带隙中心频率以及较宽的阻带带宽,并用Ansoft Designer通过时域仿真验证该结构具有较好的信号完整性。     

抑制同步开关噪声的超带宽电磁带隙结构研究

针对抑制印刷电路板中电源平面与接地平面之间的同步开关噪声问题,提出了一种新型的二维电磁带隙结构（BSEBG）。这一新型结构的设计基于在正方形金属贴片的四角刻蚀出折线型缝隙以降低贴片的有效电容,应用折线以增加相邻贴片的有效电感,单元晶格由折线与含有缝隙的正方形金属贴片桥接构成。仿真分析结果表明：相比于同参数的ZbridgedEBG电磁带隙结构,当抑制深度定义为-30dB时,BSEBG结构阻带范围从220MHz到超过20GHz,相对带宽增加了约15％,阻带下限截止频率降低了110MHz。     

基于三种尺寸L-Bridge单元的超宽带电磁带隙结构

通过把3 种不同尺寸的L-bridge 单元进行组合,在多层PCB 板的电源层上,设计了一种新的多周期平面型超宽带电磁带隙(Electromagnetic Band Gap, EBG)结构,可用于抑制数字电路系统中的同步开关噪声(Simultaneous Switching Noise, SSN)。利用HFSS 软件对该EBG 结构进行了建模和仿真,并在仿真基础上制作了电路实物,实测与仿真结果吻合良好。组合结构EBG 比传统L-bridge EBG 的阻带宽度有明显提高,当抑制深度为-40 dB 时,具有从0.8 GHz 到9.5 GHz 的超宽带阻带特性。     

一种扩展蘑菇型EBG结构阻带带宽的新方法

该文根据蘑菇型电磁带隙(EBG)结构的等效电路原理提出一种插入交指电容的方法,实现扩宽蘑菇型EBG结构阻带宽度,并设计一种T型交指电容EBG结构验证该方法的有效性。-30 dB时该结构相对于蘑菇型EBG结构,阻带下截止频率从0.9 GHz降到290 MHz,带宽从6.1 GHz提高到7.1 GHz。在不改变EBG结构单元面积,并增加交指单元层数和降低单元厚度的情况下,通过仿真验证该方法可有效提高抑制同步开关噪声的能力。     

介质型EBG结构对同步开关噪声抑制的有限元分析

研究了介质型电磁带隙结构对高速电路中电源/ 地平面间同步开关噪声的抑制作用。该介质型电磁带隙结构在抑制同步开关噪声的同时未破坏高速信号的电流返回路径,使高速信号的信号完整性得以保持。利用电磁场有限元方法将电源/地平面间同步开关噪声抑制的三维问题转化成二维问题进行处理,提高了计算效率。分析了介质型电磁带隙结构的介电常数对噪声抑制带宽的影响,利用了三维全波电磁场仿真软件HFSS对二维数值结 果进行仿真验证,仿真结果与数值计算结果基本吻合,验证了二维数值算法的正确性。     

一款紧凑增强型可变阻抗电磁带隙结构

基于传统AI-EBG结构,提出了一种小尺寸的增强型电磁带隙结构,实现了从0.5~9.4 GHz的宽频带-40 dB噪声抑制深度,且下截止频率减少到数百MHz,可有效抑制多层PCB板间地弹噪声。文中同时研究了EBG结构在高速电路应用时的信号完整性问题,使用差分信号方案可改善信号完整性。     

A Double-Surface Electromagnetic Bandgap Structure With One Surface Embedded in Power Plane for Ultra-Wideband SSN Suppression

In this letter, a double-surface electromagnetic bandgap (EBG) structure with one EBG surface embedded in power plane is proposed for ultra-wideband simultaneous switching noise (SSN) suppression in printed circuit boards. The SSN suppression bandwidth is broadened to wider than 30 GHz with a low start frequency by combining traditional EBG structure and the coplanar EBG structure which is embedded in the power plane. Because the coplanar EBG surface is embedded in the power plane, no additional metal layer is introduced by the double-surface EBG structure. Simulations and measurements are performed to verify the broadband SSN suppression, high performance is observed.     

Double-Stacked EBG Structure for Wideband Suppression of Simultaneous Switching Noise in LTCC-Based SiP Applications

We propose a novel electromagnetic bandgap (EBG) structure with a significantly extended noise isolation bandwidth, called a double-stacked EBG (DS-EBG) structure, fabricated on a low-temperature co-fired ceramic (LTCC) multilayer substrate. The DS-EBG structure was devised for wideband suppression of simultaneous switching noise (SSN) coupling in system-in-package (SiP) applications. Our design approach was enabled by combining two EBG layers embedded between the power and ground planes. The two EBG layers had different bandgaps from using different cell sizes. Enhanced wideband suppression of the SSN coupling was validated using a 11.4-GHz noise stop bandwidth with 30-dB isolation in time and frequency domain measurements up to 20GHz.     

Analysis and suppression of SSN noise coupling between power/ground plane cavities through cutouts in multilayer packages and PCBs

The authors introduced a model of simultaneous switching noise (SSN) coupling between the power/ground plane cavities through cutouts in high-speed and high-density multilayer pack-ages and printed circuit boards (PCBs). Usually, the cutouts are used in multilayer plane structures to isolate the SSN of noisy digital circuits from sensitive analog circuits or to provide multiple voltage levels. The noise-coupling model is expressed in terms of the transfer impedance. The proposed modeling and analysis results are compared with measured data up to 10 GHz to demonstrate the validity of the model. It is demonstrated that the cutout is the major gate for SSN coupling between the plane cavities, and that substantial SSN coupling occurs between the plane cavities through the cutout at the resonant frequencies of the plane cavities. The coupling mechanism and characteristics of the noise coupling, from which a method of suppression of the SSN coupling evaluated was also analyzed and discussed. Proper positioning of the cutout and the devices at each plane cavity achieves significant noise suppression at certain resonant frequencies. The suggested suppression method of the SSN coupling was successfully proved by frequency domain measurement and time domain analysis.     

Ultra-Wideband Mitigation of Simultaneous Switching Noise Using Novel Planar Electromagnetic Bandgap Structures

A novel design of power/ground plane with planar electromagnetic bandgap (EBG) structures for suppressing simultaneous switching noise (SSN) is presented. The novel design is based on using meander lines to increase the effective inductance of EBG patches. A super cell EBG structure, comprising two different topologies on the same board, is proposed to extend the lower edge of the band. Both novel designs proposed here are validated experimentally. A$-$28dB suppression bandwidth starting at 250MHz and extending to 12GHz and beyond is achieved.     

A Power Plane With Wideband SSN Suppression Using a Multi-Via Electromagnetic Bandgap Structure

In this letter, a power plane with wideband simultaneous switching noise (SSN) suppression using a novel multi-via electromagnetic bandgap (EBG) structure is proposed. The -40dB stopband of the proposed EBG structure is about two to six times wider than the one-via structure, and the relative bandwidth is increased by about two times. It is implemented by only adding some vias between patches and the reference plane without changing any other geometrical parameters from one-via EBG structures. The excellent SSN suppression performance was verified by simulations and measurements     

电磁带隙结构在同步开关噪声抑制中的应用分析

随着数字电路的噪声容限和时序容限不断减小,电源地平面上的同步开关噪声(SSN)成为高速设计的主要瓶颈之一.而现有抑制SSN的方法存在各自的不足,因而提出采用电磁带隙结构(EBG)设计来抑制SSN,软件仿真证明该方法是有效的.基于对多种不同结构EBG的研究,给出了EBG的设计思路和最新发展趋势,为今后的实际应用研究提供一定的参考与指导.