Detail publikace

Milimeter-wave Propagation in 3D Knitted Fabrics

Originální název

Milimeter-wave Propagation in 3D Knitted Fabrics

Anglický název

Milimeter-wave Propagation in 3D Knitted Fabrics

Jazyk

en

Originální abstrakt

The paper deals with the characterization of EM wave propagation in 3D knitted fabrics made from polyester yarns. Due to the periodic structure of the knitted fabrics, band gaps can be identified at higher frequencies. Due to the vertical orientation of yarns, certain anisotropy can be expected. In order to characterize band gaps and anisotropy, numerical models of knitted fabrics have been developed considering the micro-structure of the material. EM wave propagation was simulated in frequency band from 80 GHz to 200 GHz in CST Microwave Studio.

Anglický abstrakt

The paper deals with the characterization of EM wave propagation in 3D knitted fabrics made from polyester yarns. Due to the periodic structure of the knitted fabrics, band gaps can be identified at higher frequencies. Due to the vertical orientation of yarns, certain anisotropy can be expected. In order to characterize band gaps and anisotropy, numerical models of knitted fabrics have been developed considering the micro-structure of the material. EM wave propagation was simulated in frequency band from 80 GHz to 200 GHz in CST Microwave Studio.

BibTex


@inproceedings{BUT147197,
  author="Martin {Kokolia} and Zbyněk {Raida}",
  title="Milimeter-wave Propagation in 3D Knitted Fabrics",
  annote="The paper deals with the characterization of EM wave propagation in 3D knitted fabrics made from
polyester yarns. Due to the periodic structure of the knitted fabrics, band gaps can be identified at higher frequencies. Due to the vertical orientation of yarns, certain anisotropy can be expected. In order to characterize band gaps and anisotropy, numerical models of knitted fabrics have been developed considering the micro-structure of the material. EM wave propagation was simulated in frequency band from 80 GHz to 200 GHz in CST Microwave Studio.",
  booktitle="Proceedings of MIKON 2018",
  chapter="147197",
  doi="10.23919/MIKON.2018.8405319",
  howpublished="online",
  number="1",
  year="2018",
  month="may",
  pages="172--175",
  type="conference paper"
}