Artificial neural networks for calculating the input resistance of circular microstrip antennas

A new method based on artificial neural networks for calculating the resonant frequency of circular microstrip patch antennas is presented. This neural method is simple ( ) and is useful for the computer-aided design CAD of microstrip antennas. The theoretical resonant frequency results obtained by

## Abstract A new method of using artificial neural networks (ANNs) for the calculation of the input impedance of rectangular microstrip patch antennas has been adopted in this paper. The results obtained using ANNs are compared with the experimental findings, theoretical values, and with the simul

## Abstract A method based on adaptive‐network‐based fuzzy inference system (ANFIS) for computing the input resistance of circular microstrip antennas (MSAs) is presented. The ANFIS is a class of adaptive networks which are functionally equivalent to fuzzy inference systems (FISs). Seven optimizati

## Abstract In this paper, an artificial neural network (ANN) model for computing the resonant frequency of circular patch antennas (CPA) based on the feed‐forward network and back‐propagation algorithm is presented. The network is trained with the data obtained from CPA measurements. The network i

proposed structure reduces not only the number of semiconductor switches, but also the size of the phase shifter. ## CONCLUSION A shunt-connected single-switch structure has been presented for phase-shifting applications. Starting from analytic results, design criteria have been given. The perfor

## Abstract A novel method of using artificial neural networks (ANNS) for the calculation of the radiation resistance of a coax‐fed rectangular microstrip antenna is presented in this Letter. The network is trained with the results of three different antennas and tested for the fourth antenna. The