Electromagnetic Band Gap Structures in Antenna Engineering by Fan Yang, Yahya Rahmat-Samii

Electromagnetic Band Gap Structures in Antenna Engineering



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Electromagnetic Band Gap Structures in Antenna Engineering Fan Yang, Yahya Rahmat-Samii ebook
Page: 282
Publisher: Cambridge University Press
Format: pdf
ISBN: 052188991X, 9780521889919


Electromagnetic Bandgap Structure, Wideband switching, High speed circuits, Power distribution system, Noise mitigation, Switching noise, Signal integrity. When optimizing some complicated electromagnetic (4) Optimized a wideband microstrip antenna and a compact multiband folded loop chip antenna for small-size mobile phone, designed a double-layer EBG (Electromagnetic Band Gap) structure filter successfully based on PSO algorithm and HFSS. Keywords:microstrip antennaYagi antennaelectromagnetic band-gap(EBG)relative bandwidth. The EBG structure has been designed and st udied. Scattering, Diffraction, and RCS C13. Shielding, Filtering & Grounding E15. Electromagnetic Band Gap Structures in Antenna Engineering (The Cambridge RF and Microwave Engineering Series) $55.96. Packed with hands-on guidance from noted experts, this volume will be indispensable to all engineers involved in designing, testing, and improving body-centric communication systems. Nano- EMC in Power Engineering E12. Categories: Telecommunication engineering. A microstrip Yagi antenna that employs a 2-D EBG(Electromagnetic Band-gap) groun d plane as the reflector is presented in this paper. Optimization is often met in engineering technology, scientific research, economic management, and many other fields. Inverse Problems and Imaging C12. Metamaterials and Electromagnetic Bandgap Structures C14. Electromagnetic Band Gap Structures in Antenna Engineering (The Cambridge RF and Microwave Engineering Series). For the design used non-optimal in terms of size reduction), artificial dielectric substrate structure reduces the filter length by 33%, the area of the coupler by 42% and the surface of the antenna by 24.5%. The metamaterial, on the other hand, makes the antenna behave as if it were much larger than it really is, because the novel antenna structure stores energy, and re-radiates it. Electromagnetic band gap structures antenna engineering. Assistant professor Yang Wang from Georgia Tech's School of Civil and Environmental Engineering displays a strain-testing specimen mounted with a wireless antenna sensor.