Exact solution and high frequency asymptotic methods in the wedge diffraction problem

Authors

DOI:

https://doi.org/10.18046/syt.v14i38.2285

Keywords:

Geometrical Theory of Diffraction, Asymptotic Methods, Computational Electromagnetics.

Abstract

Abstract

The Sommerfeld exact solution for canonical 2D wedge diffraction problem with perfectly conducting surfaces is presented. From the integral formulation of the problem, the Malyuzhinets solution is obtained and this result is extended to obtain the general impedance solution of canonical 2D wedge problem. Keller’s asymptotic solution is developed and the general formulation of exact solution it’s used to obtain general asymptotic methods for approximate solutions useful from the computational point of view. A simulation tool is used to compare numerical calculations of exact and asymptotic solutions. The numerical simulation of exact solution is compared to numerical simulation of an asymptoticmethod, and a satisfactory agreement found.  Accuracy dependence with frequency is verified.

Author Biographies

  • Hernan G. Triana, Icesi University
    Professor (Physics and Technology Department) and researcher, member of i2t (informatics and telecommunications research group) at the Universidad Icesi (Cali, Colombia). Physicist from the Universidad del Valle (Cali, Colombia), currently pursuing a Master of Research in Computer Science and Telecommunications at the Universidad Icesi. His main areas of interest are: theory of diffraction, computational electromagnetism and radio-propagation
  • Andrés Navarro Cadavid, Icesi University
    Full professor and Director of i2t (informatics and telecommunications research group) at the Universidad Icesi (Cali, Colombia). Electronics Engineer and Master in Technology Management (Universidad Pontificia Bolivariana de Medellín (Colombia), and Ph.D. in Telecommunications (Universidad Politécnica de Valencia, España). His main areas of interest are: spectrum management, radio propagation and m-health

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Published

2016-10-06

Issue

Vol. 14 No. 38 (2016)

Section

Original Research

License

This journal is licensed under the terms of the CC BY 4.0 licence (https://creativecommons.org/licenses/by/4.0/legalcode).