A bandwidth enhanced multilayer electromagnetic bandgap structure to reduce the simultaneous switching noise

Manisha R. Bansode; Surendra S. Rathod; Manisha R. Bansode; Surendra S. Rathod

doi:10.3934/electreng.2023021

AIMS Electronics and Electrical Engineering

2023, Volume 7, Issue 4: 406-420. doi: 10.3934/electreng.2023021

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Research article

A bandwidth enhanced multilayer electromagnetic bandgap structure to reduce the simultaneous switching noise

Manisha R. Bansode ^{1
,
,},
Surendra S. Rathod ²

1.
Department of Electronics Engineering, Sardar Patel Institute of Technology, Andheri(W), Mumbai 400058, India
2.
Department of Electronics and Computer Science, Fr. Conceicao Rodrigues College of Engineering, Bandra (West), Mumbai-400050, India

Received: 09 September 2023 Revised: 08 December 2023 Accepted: 19 December 2023 Published: 28 December 2023

A bandwidth enhanced multilayer Electromagnetic Band Gap (EBG) structure to reduce the simultaneous switching noise (SSN) in high frequency operating circuits, which useful for the satellite communication application, is presented in this paper. A proposed stack structure is mathematically analyzed by the dispersion method and transmission matrix method. Simulation results show good mitigation of SSN in scattering parameters and signal integrity in terms of eye diagrams. We have also checked for power integrity analysis using self-impedance. The proposed structure gives a good SSN suppression at -30 dB from 817 MHz to 26.32 GHz, around 25.50 GHz bandwidth and also reduces the cavity mode resonance within the stopband range. The proposed multilayer structure is compared with planar EBG plane and reference board. It is also compared with published results.
- Electromagnetic Band Gap (EBG) structures,
- Simultaneous Switching Noise (SSN),
- Signal Integrity (SI),
- Power Integrity (PI)
Citation: Manisha R. Bansode, Surendra S. Rathod. A bandwidth enhanced multilayer electromagnetic bandgap structure to reduce the simultaneous switching noise[J]. AIMS Electronics and Electrical Engineering, 2023, 7(4): 406-420. doi: 10.3934/electreng.2023021

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Abstract

A bandwidth enhanced multilayer Electromagnetic Band Gap (EBG) structure to reduce the simultaneous switching noise (SSN) in high frequency operating circuits, which useful for the satellite communication application, is presented in this paper. A proposed stack structure is mathematically analyzed by the dispersion method and transmission matrix method. Simulation results show good mitigation of SSN in scattering parameters and signal integrity in terms of eye diagrams. We have also checked for power integrity analysis using self-impedance. The proposed structure gives a good SSN suppression at -30 dB from 817 MHz to 26.32 GHz, around 25.50 GHz bandwidth and also reduces the cavity mode resonance within the stopband range. The proposed multilayer structure is compared with planar EBG plane and reference board. It is also compared with published results.

References

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