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Journal of Electromagnetic Waves and Applications Volume 36, 2022 - Issue 16
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Research Article

Noise mitigation in high-speed PCB applications: experimental verification and validation of electromagnetic band gap filters

Y. Uma Maheswaria Department of EEE, Karpagam Academy of Higher Education, Coimbatore, Tamil Nadu, IndiaCorrespondence[email protected]
,
A. Amudhaa Department of EEE, Karpagam Academy of Higher Education, Coimbatore, Tamil Nadu, India
&
L. Ashok Kumarb Department of EEE, PSG College of Technology, Coimbatore, Tamil Nadu, India
Pages 2320-2340 | Received 15 Sep 2021, Accepted 07 May 2022, Published online: 19 May 2022

References

  • Karuppiah V, Srinivasan R. Novel electromagnetic bandgap structure to mitigate simultaneous switching noise for mixed-signal system applications. Int J Micro Wireless Technol. 2016. DOI:10.1017/S1759078716000040.
  • Kang H-d, Kim H, Kim S-G, et al. A localized enhanced power plane topology for wideband suppression of simultaneous switching noise. IEEE Trans Electromagnetic Compatibility. 2010;52(2). DOI:10.1109/TEMC.2010.2044415.
  • Sindhadevi M, Kanagasabai M, Arun H, et al. Signal integrity analysis of high speed interconnects in PCB embedded with EBG structures. J Electr Eng Technol. 2016. DOI:10.5370/JEET.2016.11.1.175.
  • Maria MI, Yazmin WW, Zainoz Z, et al. A review on electromagnetic band gap application in medical devices. Mater Today Proc. 2019;16:2047–2051.
  • Mustafa AB, Rajendran T. Wearable multilayer patch antenna with electromagnetic band gap structure for public safety systems. IETE J Res. 2020. DOI: 10.1080/03772063.2020.1739572.
  • Kushwaha N, Kumar R. Study of different shape electromagnetic band gap (EBG) structures for single and dual band applications. J Microw Optoelectron Electromag Appl. 2014;13(1).
  • Shahparnia S, Ramahi O. Simultaneous switching noise mitigation in PCB using cascaded high31 impedance surfaces. Electron Lett. 2004;40(2):98–100. DOI:10.1049/el:20040077.
  • Alnaiemy Y, Nagy L. Improved antenna gain and efficiency using novel EBG layer. IEEE 2020 15th 33 International Conference of System of Systems engineering; Budapest, Hungary; 2020. p. 271–276.
  • Abdulhamid M, Rahim MKA, Musa U. Electromagnetic bandgap structure for antenna design. IOSR J Electron Commun Eng. 2015. DOI: 10.9790/2834-10612527.
  • Yang L, Fan M, Chen F, et al. A novel compact electromagnetic-bandgap (EBG) 38 structure and its applications for microwave circuits. IEEE Trans Microw Theor Techn. 2005;53(1):183–190. DOI:10.1109/TMTT.2004.839322.
  • Gagare SR, Labade RP, Kachare AE. Evaluation and minimization of radiated EMI of high frequency RF devices. SSRG Int J Electron Commun Eng. 2015;2(7). DOI:10.14445/23488549/IJECE-V2I7P115.
  • Zhang Y-y, Zhao W-S, Liu Q, et al. Novel electromagnetic bandgap structure for wideband 2 suppression of simultaneous switching noise. Electron Lett. 2019;55(23):1243–1245.
  • Ashyap AY, Elamin NI, Dahlan SH, et al. Via-less electromagnetic band-gap-enabled antenna based on textile material for wearable applications. PLoS One. 2021;16(1):e0246057. DOI:10.1371/journal.pone.0246057.
  • MohajerIravani B, Ramahi OM. Suppression of EMI and electromagnetic noise in packages using 7 embedded capacitance and miniaturized electromagnetic bandgap structures with high-k dielectrics. IEEE 8 Trans Adv Pack. 2007;30(4):776–788. DOI:10.1109/TADVP.2007.908028.
  • Shahparnia S, Mohajer-Iravani B, Ramahi OM. Electromagnetic noise mitigation in high-speed printed circuit 10 boards and packaging using electromagnetic band gap structures. Proceedings 54th Electronic Components 11 and Technology Conference; Las Vegas, USA; 2004. p. 1831–1836.
  • Ahmadian R, Zarrabi FB, Mansouri Z. Investigation of EBG array performance on decreasing 13 the mutual coupling and improve shield factor. J Electr Syst Inform Technol. 2015;2(14):184–196.
  • Arora A, Kumar N. To reduce mutual coupling in microstrip patch antenna arrays elements using electro16 magnetic band gap structures for X-band. International Conference on Nextgen Electronic Technologies: 17 Silicon to Software; Vellore, Chennai; 2017. p. 228–230.
  • Alam MS, Islam MT, Misran N. Design analysis of an electromagnetic band gap 19 microstrip antenna. Am J Appl Sci. 2011;8:1374–1377. DOI:10.3844/ajassp.2011.1374.1377.
  • Khan HA, Ullah S, Afridi MA, et al. Patch antenna using EBG structure for 21 ISM band wearable applications. International Conference on Intelligent Systems Engineering; Islamabad, 22 Pakistan; 2016. p. 157–160.
  • Ashyap AY, Abidin ZZ, Dahlan SH, et al. Compact and low-profile 24 textile EBG-based antenna for wearable medical applications. IEEE Antenna Wirel Propag Lett. 2017;16:2550–2553. DOI:10.1109/LAWP.2017.2732355.
  • Santos D´ıazAranza M, GalazLarios Martha C, Ram´ırezGarćıa E. Analysis and design of electromagnetic band 27 gap structures with application in planar antennas. 42nd International Conference on Infrared, Millimeter 28 and Terahertz Waves (IRMMW-THz); Cancun, Mexico; 2017. p. 1–2. DOI:10.1109/IRMMW-THz.2017.8067190.
  • Venkatesh MN, Mandhe M, Kumar BN, et al. Experimental design and illustration of 30 narrow band compact microwave notch filter using EBG structure. Int J Recent Technol Eng. 2019;7:32.
  • Hajlaoui EA. New triple band electromagnetic band gap microstrip patch antenna with two shaped parasitic 33 elements. J Comput Electron. 2018;17:452–457.
  • Wu T-L, Wang C-C, Lin Y-H, et al. A novel power plane with super-wideband elimination of ground bounce noise on high speed circuits. IEEE Microw Wirel Compon Lett. 2005;15(3):174–176.
  • Joo S, Kim D, Lee H. A S-bridge inductive electromagnetic bandgap power plane for suppression of ground bounce noise. IEEE Microw Wirel Compon Lett. 2007 Oct;17(10):709–711.
  • Shi L, Li K, Hu H, et al. Novel L-EBG embedded structure for the suppression of SSN. IEEE Trans Electromagn Compat. 2016;58(1):241–248.
  • Kang H, Kim H, Kim S, et al. A localized enhanced power plane topology for wideband suppression of simultaneous switching noise. IEEE Trans Electromagn Compat. 2010;52(2):373–380.

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