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A three-dimensional iterative scheme for an electromagnetic inductive applicator.

M J Sowiński1, P M van den Berg

  • 1Laboratory for Electromagnetic Research, Department of Electrical Engineering, Delft, The Netherlands.

IEEE Transactions on Bio-Medical Engineering
|December 1, 1992
PubMed
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This study introduces an efficient iterative method for solving quasi-static electromagnetic field problems, utilizing a novel relaxation function for improved accuracy in tissue modeling.

Area of Science:

  • Electromagnetism
  • Computational Physics
  • Biomedical Engineering

Background:

  • Quasi-static electromagnetic field problems are crucial in applications like medical imaging and therapeutic devices.
  • Existing methods for solving these problems can be computationally intensive and may lack efficiency for complex geometries.

Purpose of the Study:

  • To develop and present an efficient iterative method for solving quasi-static electromagnetic field problems.
  • To accurately model electromagnetic fields generated by inductive applicators in the presence of biological tissues.

Main Methods:

  • The electromagnetic field is decomposed into primary and secondary field components.
  • A quasi-static approximation is applied to the secondary field.
  • A relaxation function is introduced into the quasi-static field equations to enable iterative solutions.

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Main Results:

  • The proposed iterative method demonstrates efficiency in solving quasi-static electromagnetic field problems.
  • Numerical results are presented for a realistic three-dimensional model of a human hand.
  • The method effectively handles the superposition of primary and secondary electromagnetic fields.

Conclusions:

  • The developed iterative method offers an efficient approach for quasi-static electromagnetic field simulations.
  • The technique is suitable for modeling complex scenarios, such as inductive heating of biological tissues.
  • This method provides a valuable tool for research and development in electromagnetics and biomedical applications.