A simple and accurate expression for the bandwidth of electrically thick rectangular microstrip antennas

A new, simple approach for calculating bandwidth of electrically thin and thick rectangular microstrip patch antennas, based on multilayered perceptrons network, is presented. Four learning algorithms, backpropagation, delta-bar-delta, quick propagation, and extended-delta-bar-delta are used to trai

## Abstract New, very simple closed‐form formulas for calculating the patch length and width of electrically thin and thick rectangular microstrip antennas (MSAs) are presented. They are obtained by means of a curve‐fitting technique, and are useful for the computer‐aided design of microstrip anten

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

Existing methods to compute the bandwidth of probe-fed rectangular microstrip antenna elements are inaccurate for the range of substrate thicknesses considered for this research. When 0.0815h0 5 h (A0 is the free-space wacrelength and h is the substrate thickness) the effect of surface wacies is pre

tially. However, steeples of tuning is little at closer distances between the ring and anode block. The reason of this phenomena is arising of capacitive component of conductance carry in with ring to circuit. Because it moves resonant frequency to opposite direction, the summary variety on little d

## Abstract A new and accurate expression for the edge extension in accurately predicting the resonant frequency of electrically thin and thick rectangular microstrip antennas is presented. First, a closed‐form model for the edge extension is constructed by utilizing a differential evolution algori