Title :
New iterative integral equation technique for multilayered printed array antennas
Author :
Brand, Y. ; Skrivervik, A.K. ; Mosig, J.R. ; Gardiol, F.E.
Author_Institution :
Lab. of Electromagn. & Acoust., Ecole Polytech. Fed. de Lausanne, Switzerland
Abstract :
When analyzing large printed antenna arrays with irregularly located radiating elements, the method of moments yields a very large system of equations, which cannot be solved by matrix inversion. An iterative scheme was therefore developed, in which each element is first analyzed independently, to determine the surface current flowing on it. The coupling between elements is then introduced as a perturbation, yielding an iterative process based on the Jacobi decomposition of a matrix linear equation. However the convergence of the process is not guaranteed, but can be "restored" by coupling the iterative scheme with a convergence accelerator algorithm. The interest of the proposed technique is illustrated by the analysis of a slot-fed array of printed patches.
Keywords :
Jacobian matrices; antenna feeds; convergence of numerical methods; electromagnetic coupling; integral equations; iterative methods; matrix decomposition; microstrip antenna arrays; perturbation techniques; planar antenna arrays; Jacobi decomposition; antenna elements coupling; convergence accelerator algorithm; irregularly located radiating elements; iterative integral equation; large printed antenna arrays; matrix linear equation; method of moments; multilayered printed array antennas; perturbation; planar arrays; printed patches; slot-fed array; surface current; Acoustics; Antenna arrays; Integral equations; Iterative algorithms; Iterative methods; Jacobian matrices; Moment methods; Patch antennas; Shape; Transmission line matrix methods;
Conference_Titel :
Mathematical Methods in Electromagnetic Theory, 1998. MMET 98. 1998 International Conference on
Conference_Location :
Kharkov, Ukraine
Print_ISBN :
0-7803-4360-3
DOI :
10.1109/MMET.1998.709835
