Study of Wide Band Electromagnetic Bandgap Structure for Ground Bounce Noise Suppression in Package-level

Chin, Ta-Cheng

26 October 2010

With electronic devices trending toward higher clock rates, lower voltage levels, and smaller form factors, the simultaneously switching noise (SSN), which is induced in package and printed circuit board, is one of the major factors affecting the performance and design of the high speed digital circuits. This noise will lead to false switching and malfunctioning in digital and/or analog circuits, and causes serious signal integrity (SI) and electromagnetic interference (EMI) problems for the high speed digital systems. Therefore, mitigating the SSN becomes a major challenge for the high speed circuits design. In this thesis, first of all, we introduce and discuss previously proposed solutions to suppress the SSN. These solutions include the use of decoupling capacitors, isolation moats, and electromagnetic bnadgap (EBG) structures. We analyzed the EBG structures and generated some EBG design rules. As the speed of digital circuits moving toward higher frequencies, the Double L-bridge EBG structure can be used to improve the performance of Hybrid EBG structure by employing the EBG design rules that were generated. The Double L-bridge EBG structure design improved the behavior at the high frequencies, which also maintained the low frequency performance. It is demonstrated numerically and experimentally. For fast estimating the stopband, we use one-dimensional lump circuit model. Then, we propose another structure, named Double Cross EBG structure. This design, compared to the Double L-bridge EBG structure, not only maintained the high frequency performance, but also improved the low frequency behavior. It is also both experimentally and numerically validated.

Ground Bounce Noise

Electromagnetic Bandgap Structure

Power Delivery Network

A Package-level Power Plane with Ultra-wide band Ground Bounce Noise Rejection

Wang, Ting-Kuang

11 July 2005

Transient current surges resulted from the simultaneous switching of output buffers in the high-speed digital circuits can induce significant ground bounce noise (GBN) on the chip, package, and printed circuit board (PCB). The GBN not only causes the signal integrity (SI) problems, such as glitches or timing push-out of signal traces, but also increases the electromagnetic interference (EMI) in the high-speed digital circuits. With the design trends of digital circuits toward higher speed, low voltage level, smaller volume, the impact of GBN has become one of the most important issues that determine the performance of electronic products. Adding decoupling capacitors between the power and ground planes is a typical way to suppress the GBN. However, they are not effective at the frequencies higher than 600MHz due to their inherent lead inductance. Recently, a new idea for eliminating the GBN is proposed by designing electromagnetic bandgap (EBG) structure with high impedance surface (HIS) on the ground or power plane. Several new EBG power/ground plane designs have been proposed to broaden the stopband bandwidth for suppressing the GBN. However there are some drawbacks, such as high cost, large area occupation and complicated fabrication process. In this paper, we propose a novel Hybrid EBG power planes for PCB or package to suppress the GBN. Its extinctive behavior of broadband suppression of GBN (over 10GHz) is demonstrated experientially and numerically. Finally, we combine the periodic high-low dielectric material with the EBG power plane to control the position and bandwidth of stopband.

Ground bounce noise

Finite-Difference Time-Domain

Electromagnetic bandgap structure

A Fast Method with the Genetic Algorithm to Evaluate Power Delivery Networks

Lee, Fu-Tien

20 July 2007

In recent high-speed digital circuits, the simultaneous switching noise (SSN) or ground bounce noise (GBN) is induced due to the transient currents flowing between power and ground planes during the state transitions of the logic gates. In order to¡@analyze the effect of GBN on power delivery systems effectively and accurately, the impedance of power/ground is an important index to evaluate power delivery systems. In the operating frequency bandwidth, the power impedance must be less than the target impedance. The typical way to suppress the SSN is adding decoupling capacitors to create a low impedance path between power and ground planes. By using the admittance matrix method, we can evaluate the effect of decoupling capacitors mounted on PCB fast and accurately reducing the time needed from the empirical or try-and-error design cycle. In order to reduce the cost of decoupling capacitors, the genetic algorithm is employed to optimize the placement of decoupling capacitors to suppress the GBN. The decoupling capacitor are not effective in the GHz frequency range due to their inherent lead inductance. The electromagnetic bandgap(EBG) structure can produce a stopband to prevent the noise from disperseing at higher frequency. Combining decoupling capacitors with EBG structure to find the optimum placement for suppression of the SSN by using the genetic algorithm.

Decoupling Capacitor

Genetic Algorithm

Admittance Matrix Method

Ground Bounce Noise

Power Integrity Analysis for High-Speed Circuit Package Using Transmission Line Method

Jhong, Ming-Fong

28 June 2006

In recent high-speed digital circuits with pico-second rising/falling edges, it is reasonable to consider the power/ground planes as a dynamic electromagnetic system. The simultaneous switching noise (SSN) or ground bounce noise (GBN), resulting from the transient currents which flow between power/ground planes during the state transitions of the logic gates, has become a critical factor to degrade the signal integrity (SI) and power integrity (PI) in PCB or package design. In order to accurately perform overall system-level power integrity simulation, extracting the SPICE-compatible models with the resonant effect being considered in the power/ground planes and incorporating the model into the conventional circuit simulator, such as SPICE, is essential. In this thesis, a two-dimensional transmission line (2D-TL) model is proposed for constructing the SPICE-compatible model of the power/ground planes. Based on this model, the ground bounce noise for the BGA package mounted on a PCB can be efficiently evaluated. It is found that the behavior of GBN between the only package and package mounted on a PCB (hybrid structure) is obvious different. Then, we combine the SPICE-compatible model of the power/ground planes with decoupling capacitors to fast evaluate the behavior of GBN. It also has a good agreement between our model and the measured result. Adding decoupling capacitors between the power and ground planes is a typical way to suppress the GBN. However, they are not effective at the frequency higher than GHz due to their inherent lead inductance. In recent, a new method for eliminating the GBN at higher frequency is proposed by electromagnetic bandgap (EBG) structure with high impedance surface (HIS). Finally, we utilize 2D-TL model to fast analyze the behavior of the EBG, and combine decoupling capacitors with EBG structure to research the suppression of the GBN.

Electromagnetic Bandgap Structure

Decoupling Capacitor

Ground Bounce Noise

Transmission Line Model

Effect of Ground Bounce Noise on the Power Integrity and EMI Performance in Multi-Layered High-Speed Digital PCB: FDTD Modeling and Measurement

Hwang, Jiunn-Nan

20 June 2002

In this thesis, we study the electromagnetic effect of the high-speed digital PCB in three sections. In first section, based on the FDTD modeling approach, the bridging effect of the isolation moat on the EMI caused by the ground bounce noise is investigated. We find that isolating the noise source by slits is effective to eliminate the EMI, but bridges connecting between two sides of the slits will significantly degrade the effect of EMI protection. In second section, we investigate both in time and frequency domains the power plane noise coupling to signal trace with via transition in multi-layered PCB. Separating the power plane with slits is effective in reducing noise coupling in high frequency but a new resonant mode will be excited at lower frequency. Current distribution pattern of this new resonant mode between the power planes helps us to understand this phenomenon more clearly. In final section, by using FDTD link SPICE method, we can predict the electromagnetic behavior of the PCB with active device effectively.

Ground Bounce Noise

Power Plane

Finite-Difference Time-Domain

Via

Signal Integrity

Electromagnetic Interference

Modeling and Solutions for Ground Bounce Noise and Electromagnetic Radiation in High-Speed Digital Circuits

Lin, Yen-hui

12 July 2005

With the trends of fast edge rates, high clock frequencies, and low voltage levels for the high-speed digital computer systems, the ground bounce noise (GBN) or simultaneously switching noise (SSN) on the power/ground planes is becoming one of the major challenges for designing the high-speed circuits. In order to analyze the impact of the GBN on signal integrity (SI) and electromagnetic interference (EMI), an accurate and efficient modeling approach that considers the active devices and passive interconnects is required. This thesis focuses on two points. One is developing modeling approaches for analyzing the GBN effects, and the other is proposing solutions to reduce it. First, based on the FDTD algorithm several efficient modeling approaches including equivalent current-source method (ECSM), Kirchoff surface integral representation (KSIR), and slot-corrected 2D-FDTD are developed. After that, a power/ground-planes design for efficiently eliminating the GBN in high-speed digital circuits is proposed by using low-period coplanar electromagnetic bandgap (LPC-EBG) structure. Its extinctive behaviors of low radiation and broadband suppression of the GBN is demonstrated numerically and experimentally. Good agreements are seen.

Electromagnetic Interference

Electromagnetic Bandgap

Ground Bounce Noise

Signal Integrity

High-Speed Digital Circuit

Finite-Difference Time-Domain