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A Tri-band Angularly Stable Frequency Selective Surface with Controllable Resonances for EM Shielding

  • Fei Wang EMAIL logo
Published/Copyright: September 10, 2019
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Frequenz
From the journal Frequenz Volume 74 Issue 1-2

Abstract

In the paper, a tri-band angularly stable frequency selective surface (FSS) with controllable resonances for electromagnetic shielding is proposed. Different from traditional single-layer structure, the FSS proposed is based on cascaded structure that creates three adjustable blocking bands around frequency 5.93 GHz, 7.33 GHz and 9.17 GHz, respectively. The designed FSS has a low profile with thickness of λ0/100, where the λ0 represents wavelength of the first band-stop resonance frequency. Besides, the proposed FSS exhibits stable frequency response up to 70° with respect to different polarizations. Therefore, this FSS is flexible and can be used in electromagnetic shielding field where needs conformal screen. To investigate and understand the operating mechanism better, a equivalent circuit model (ECM) is deduced and given in the Section 2, the calculated results match the full-wave EM simulation results perfectly. Finally, a prototype of this FSS is fabricated and measured, the measurement results are in accordance with the simulation results.

Keywords: Frequency selective surfaces (FSSs); spatial filter; periodic structure; tri-band; angle stability

References

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Received: 2018-11-04
Published Online: 2019-09-10
Published in Print: 2020-01-28

© 2020 Walter de Gruyter GmbH, Berlin/Boston

Articles in the same Issue

  1. Frontmatter
  2. Research Articles
  3. Wide-Angle RCS Enhanced Tag Based on Dielectric Resonator – Lens Combination
  4. 4-Channel Tunable Optical Demultiplexer Based on Nonlinearity Phenomenon in 2D Resonant Cavity Photonic Crystals
  5. Near Zero Parameter Metamaterial Inspired Superstrate for Isolation Improvement in MIMO Wireless Application
  6. A Tri-band Angularly Stable Frequency Selective Surface with Controllable Resonances for EM Shielding
  7. Dual-Polarization and Low-Sidelobe Corrugated Rectangular Horn Antennas for Outdoor RCS Measurement
  8. Circularly Polarized Microstrip Antenna Using SLPD Electromagnetic Band Gap Structure
  9. Design of Novel Compact Quad-Band Bandpass Filter with High Selectivity
  10. Compact Ultra-Wide Upper Stopband Microstrip Dual-Band BPF Using Tapered and Octagonal Loop Resonators
  11. Modelling of Acoustic Wave Propagation Due to Partial Discharge and Its Detection and Localization in an Oil-Filled Distribution Transformer
  12. A 5.7 mW, UWB LNA for Wireless Applications Using Noise Canceling Technique in 90 nm CMOS
https://doi.org/10.1515/freq-2018-0231
Keywords for this article
Frequency selective surfaces (FSSs); spatial filter; periodic structure; tri-band; angle stability

Articles in the same Issue

  1. Frontmatter
  2. Research Articles
  3. Wide-Angle RCS Enhanced Tag Based on Dielectric Resonator – Lens Combination
  4. 4-Channel Tunable Optical Demultiplexer Based on Nonlinearity Phenomenon in 2D Resonant Cavity Photonic Crystals
  5. Near Zero Parameter Metamaterial Inspired Superstrate for Isolation Improvement in MIMO Wireless Application
  6. A Tri-band Angularly Stable Frequency Selective Surface with Controllable Resonances for EM Shielding
  7. Dual-Polarization and Low-Sidelobe Corrugated Rectangular Horn Antennas for Outdoor RCS Measurement
  8. Circularly Polarized Microstrip Antenna Using SLPD Electromagnetic Band Gap Structure
  9. Design of Novel Compact Quad-Band Bandpass Filter with High Selectivity
  10. Compact Ultra-Wide Upper Stopband Microstrip Dual-Band BPF Using Tapered and Octagonal Loop Resonators
  11. Modelling of Acoustic Wave Propagation Due to Partial Discharge and Its Detection and Localization in an Oil-Filled Distribution Transformer
  12. A 5.7 mW, UWB LNA for Wireless Applications Using Noise Canceling Technique in 90 nm CMOS
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