• DocumentCode
    1432399
  • Title

    Variational formulation of open-ended coaxial line in contact with layered biological medium

  • Author

    Alanen, Esko ; Lahtinen, Tapani ; Nuutinen, Jouni

  • Author_Institution
    Dept. of Oncology, Kuopio Univ., Finland
  • Volume
    45
  • Issue
    10
  • fYear
    1998
  • Firstpage
    1241
  • Lastpage
    1248
  • Abstract
    An open-ended coaxial probe designed to measure layered biological media is analyzed with a new method. The probe is considered as an electrostatic circuit element whose capacitance is solved using a stationary functional. The fundamental transverse electric and magnetic field (TEM)-mode and the series of evanescent wavemodes in the coaxial cable are used as basis functions. The field outside the probe is solved using a Hankel transform. The capacitance is calculated for homogeneous materials and two-layer structures and the results are compared with values measured with a phantom model. The method can be easily extended for structures with an arbitrary number of layers. A practical approximation for two-layer cases, originally developed to take into account the effect of subcutaneous fat in skin measurements, is presented and its validity for different combinations of dielectric constants and the thickness of the first layer is demonstrated. The static approximation limits the frequency range, but it covers biological measurements up to 500 MHz. The developed method is accurate and easy to adopt in practice.
  • Keywords
    biological techniques; coaxial cables; microwave measurement; permittivity measurement; probes; skin; 500 MHz; Hankel transform; coaxial line; electrostatic circuit element; frequency range; layer thickness; layered biological media measurement; open-ended coaxial probe; phantom model; stationary functional; variational formulation; Capacitance; Circuits; Coaxial cables; Coaxial components; Dielectric measurements; Electrostatic measurements; Magnetic analysis; Magnetic field measurement; Magnetic materials; Probes; Adipose Tissue; Calibration; Electric Conductivity; Electric Impedance; Electromagnetic Fields; Models, Biological; Skin; Surface Properties;
  • fLanguage
    English
  • Journal_Title
    Biomedical Engineering, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0018-9294
  • Type

    jour

  • DOI
    10.1109/10.720202
  • Filename
    720202