Title :
Wideband and Compact EBG Structure With Balanced Slots
Author :
Myunghoi Kim ; Dong Gun Kam
Author_Institution :
Electron. & Telecommun. Res. Inst., Daejeon, South Korea
Abstract :
We propose a new wideband and compact electromagnetic bandgap (EBG) structure with balanced slots (BS-EBG). In conventional EBG structures, a significant number of cells are required to ensure periodicity and to meet noise-suppression requirements. However, the large space requirements of conventional EBG structures limit their use in practical designs. The balanced slots force power/ground noise to pass through each and every EBG cell, improving the periodicity and thereby enhancing the noise-suppression characteristics. An analytical model for the proposed BS-EBG structure is developed based on a segmentation method and a cavity-mode resonator model. The proposed BS-EBG structure achieves a 111% improvement in the stopband bandwidth and a 73% size reduction over the conventional EBG structure. Finally, we suggest a simple method to avoid discontinuity in the return current path in the BS-EBG structure.
Keywords :
cavity resonators; noise abatement; photonic band gap; BS-EBG structure; balanced slot electromagnetic bandgap; balanced slot force power-ground noise; cavity-mode resonator model; compact EBG structure; noise-suppression requirement; segmentation method; wideband EBG structure; Analytical models; Cavity resonators; Couplings; Integrated circuit modeling; Metamaterials; Noise; Periodic structures; Balanced slots; cavity model; electromagnetic bandgap (EBG); power/ground (P/G) noise; segmentation method; signal integrity; size reduction; stopband enhancement; stopband enhancement.;
Journal_Title :
Components, Packaging and Manufacturing Technology, IEEE Transactions on
DOI :
10.1109/TCPMT.2015.2436404
