Startseite Decoupling of Dual-band Closely Spaced MIMO Antennas Based on Novel Coupled Resonator Structure
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Decoupling of Dual-band Closely Spaced MIMO Antennas Based on Novel Coupled Resonator Structure

  • XiaoJun Zou , GuangMing Wang EMAIL logo , YaWei Wang und BinFeng Zong
Veröffentlicht/Copyright: 13. März 2018
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Abstract

A pair of dual-band closely spaced MIMO monopole antenna array working at WLAN 2.45/5.25GHz with a dual-band coupled resonator structure for decoupling is proposed, the edge-to-edge distance of which is 0.0735λ0 at 2.45GHz and 0.1575λ0 at 5.25GHz. Simulation and measurement on coupled antennas and decoupled antennas indicate that mutual coupling reductions of 24.52dB and 26.57dB at two frequencies are achieved. With good impedance matching, improved total efficiency and increased channel capacity, the proposed structure owns good applicability, compact size and effective decoupling capability, and is promising in the application of wireless terminal MIMO system.

Keywords: decoupling; dual-band; coupled resonator structure; MIMO

Funding statement: This work was supported by the National Natural Science Foundation of China under Grant No. 61372034 and No. 61601498.

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Received: 2017-08-29
Published Online: 2018-03-13
Published in Print: 2018-08-28

© 2018 Walter de Gruyter GmbH, Berlin/Boston

Artikel in diesem Heft

  1. Frontmatter
  2. Research Articles
  3. A Differential UWB Quasi-Yagi Antenna with A Reconfigurable Notched Band
  5. Design of Hybrid Antenna System for User Terminal Applications
  6. High Isolation Compact Four-Port MIMO Antenna Loaded with CSRR for Multiband Applications
  7. Compact 4-Port MIMO/Diversity Antenna with Low Correlation for UWB Application
  8. Decoupling of Dual-band Closely Spaced MIMO Antennas Based on Novel Coupled Resonator Structure
  9. Hexagonal Fractal Antenna using Koch for Wireless Applications
  10. Short Communication
  11. Miniaturized Bandpass Filter with Wide Stopband using Spiral Configuration of Stepped Impedance Resonator
  12. Research Articles
  13. Studying Photonics Crystal Cavities by Design and Simulation of a 1 to 8 Optical Demultiplexer
  15. Application of Photonic Crystal Ring Resonators for Realizing All Optical Demultiplexers
  16. Second Order Solutions of THz Response of Gated Two-Dimensional Electron Gas in Magnetic Field
https://doi.org/10.1515/freq-2017-0199
Schlagwörter für diesen Artikel
decoupling; dual-band; coupled resonator structure; MIMO

Artikel in diesem Heft

  1. Frontmatter
  2. Research Articles
  3. A Differential UWB Quasi-Yagi Antenna with A Reconfigurable Notched Band
  5. Design of Hybrid Antenna System for User Terminal Applications
  6. High Isolation Compact Four-Port MIMO Antenna Loaded with CSRR for Multiband Applications
  7. Compact 4-Port MIMO/Diversity Antenna with Low Correlation for UWB Application
  8. Decoupling of Dual-band Closely Spaced MIMO Antennas Based on Novel Coupled Resonator Structure
  9. Hexagonal Fractal Antenna using Koch for Wireless Applications
  10. Short Communication
  11. Miniaturized Bandpass Filter with Wide Stopband using Spiral Configuration of Stepped Impedance Resonator
  12. Research Articles
  13. Studying Photonics Crystal Cavities by Design and Simulation of a 1 to 8 Optical Demultiplexer
  15. Application of Photonic Crystal Ring Resonators for Realizing All Optical Demultiplexers
  16. Second Order Solutions of THz Response of Gated Two-Dimensional Electron Gas in Magnetic Field
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