Metamaterial based high impedance surface with band-pass frequency response

Aldo De Sabata*, Ladislau Matekovits, Ildiko Peter, Ulrich L. Rohde, Alexandru M. Silaghi

*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceedingConference proceeding contribution

Abstract

We introduce a metamaterial based parallel-plate waveguide, devised in microstrip technology that features two electromagnetic band-gaps. Since one of the band-gaps extends from zero frequency, the structure can be used as a band-pass filter. We perform a parametric study in view of facilitating design and optimisation.

Original languageEnglish
Title of host publicationApplied electromagnetic engineering for magnetic, superconducting and nano materials
Subtitle of host publicationselected peer reviewed papers from the seventh Japanese-Mediterranean and central european workshop on applied electromagnetic engineering for magnetic, superconducting and nano materials (JAPMED'7) July 6-9 2011, Budapest, Hungary
EditorsA. G. Mamalis, A. Kladas, M. Enokizono
Place of PublicationZurich
PublisherTrans Tech Publications
Pages59-64
Number of pages6
ISBN (Electronic)9783038138341
ISBN (Print)9783037854204
DOIs
Publication statusPublished - Sep 2012
Externally publishedYes
Event7th Japanese-Mediterranean and Central European Workshop on Applied Electromagnetic Engineering for Magnetic, Superconducting and Nano Materials, JAPMED'7 - Budapest, Hungary
Duration: 6 Jul 20119 Jul 2011

Publication series

NameMaterials science forum
Volume721
ISSN (Print)0255-5476

Other

Other7th Japanese-Mediterranean and Central European Workshop on Applied Electromagnetic Engineering for Magnetic, Superconducting and Nano Materials, JAPMED'7
CountryHungary
CityBudapest
Period6/07/119/07/11

Keywords

  • metamaterial
  • parallel-plate waveguide
  • high impedance surface
  • electromagnetic band-gap
  • microstrip
  • microwave filter

Fingerprint Dive into the research topics of 'Metamaterial based high impedance surface with band-pass frequency response'. Together they form a unique fingerprint.

Cite this