Generalized neural method to determine resonant frequencies of various microstrip antennas

finite-difference time-domain methods, Int J Numer Mod-Ž . elling 12 1999 . 10. K.S. Yee, Numerical solution of initial boundary value problems involving Maxwell's equations in isotropic media, IEEE Trans Ž .

Resonant frequency is an important parameter in designing microstrip antenna (MSA). Selective neural network ensemble (NNE) methods based on decimal particle swarm optimization (PSO) algorithm and binary PSO algorithm are proposed in this study. The basic idea of the methods is to optimally select n

Fonnulas based on transmission-line, cauiiy, and magnetic-wall models to determine the resonant fie quencks of u rectungular microstrip antenna element haue been studied and their ualidiiy assessed. Their cariations were experimentally r;erifred by analyzing u set of newly designed untennu elements

## Abstract A generalized method is presented to determine the resonant frequency of slot‐loaded rectangular microstrip patch antenna by equating its area to an equivalent area of a rectangular microstrip patch antenna. The computed results are in good agreement with the reported simulated and meas

## Abstract Formulations to determine the resonance frequencies of hexagonal and half hexagonal microstrip antennas have been proposed based on their equivalence with circular and semicircular microstrip antennas, respectively. The new configuration of half hexagonal patch formed by bisecting the f

## Abstract The mathematical formulation of empirically developed formulas for the calculation of the resonant frequency of a thick‐substrate (h ≥ 0.08151λ~0~) microstrip antenna has been analyzed. With the use of tunnel‐based artificial neural networks (ANNs), the resonant frequency of antennas wi