Title :
Finite element solution for scatterers with unbounded geometries
Author :
Ramahi, O.M. ; Mittra, R.
Author_Institution :
Electromagn. Commun. Lab., Illinois Univ., Urbana, IL, USA
Abstract :
The class of scattering geometries that comprise a metallic cavity embedded in a perfectly conducting wedge is discussed. The absorbing boundary conditions (ABCs) approximate the behavior of outgoing waves only; consequently, these available ABCs are at a particular disadvantage when dealing with unbounded scatterers, for which the wave becomes outgoing except in the infinite limit. An additional difficulty with these scatterers is that the asymptotic behavior of their scattered field cannot be predicted a priori. To circumvent these difficulties, the combination of the surface integral equation approach with the finite element method is proposed. The versatility and validity of the surface integral equation technique are demonstrated. The bistatic and monostatic radar cross sections were calculated and found to compare favorably with results obtained using other methods.<>
Keywords :
electromagnetic wave scattering; finite element analysis; integral equations; radar cross-sections; EM wave scattering; RCS; absorbing boundary conditions; bistatic radar cross sections; finite element method; finite element solution; metallic cavity; monostatic radar cross sections; perfectly conducting wedge; scattered field; scattering geometries; surface integral equation; unbounded geometries; Acoustic scattering; Boundary conditions; Electromagnetic scattering; Finite element methods; Geometry; Green´s function methods; H infinity control; Integral equations; Laboratories; Partial differential equations;
Conference_Titel :
Antennas and Propagation Society International Symposium, 1990. AP-S. Merging Technologies for the 90's. Digest.
Conference_Location :
Dallas, TX, USA
DOI :
10.1109/APS.1990.115368
