Empirical formulas for the computation of the physical properties of rectangular microstrip antenna elements with thick substrates

Formulas based on the two-slot, the ca¨ity, and the surface current models to compute the far-field radiation patterns in both the E and H planes for rectangular microstrip antenna elements are studied and their ¨alidity assessed. Three closed-form formulas are presented for the calculation of the r

Simple techniques ha¨e been de¨eloped for e¨aluating mutual coupling coefficients between two identical probe-fed rectangular antenna elements with thick substrates. They are based on the ¨olume equi¨alence theorem and a theoretical model equi¨alent to a lossy transmission line, and they take into a

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

In this work, a fuzzy hybrid approach FHA for the synthesis of rectangular microstrip antenna elements with thick substrates ( ) is presented. The FHA is based on a fuzzy genetic algorithm FGA and a controlled random search algorithm. The results obtained from the FHA are compared with the results o

Several formulas based on the cavity model and the transmission-line model are combined to produce closed-form expressions for calculating the bandwidth of probe-fed rectanguhr microstrip antenna elements with various thicknesses and various relatiue permittiuities of substrate materials. The formul

A new method for calculating the resonant frequency of electrically thin and thick rectangular microstrip antennas, based on the fuzzy inference systems, is presented. The optimum design parameters of the fuzzy inference systems are determined by using the classical, modified, and improved tabu sear