Radiation resistance of coax-fed rectangular microstrip patch antenna with the use of artificial neural networks

## 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 artificial neural networks (ANNs) for calculating the input resistance of circular microstrip patch antennas is presented. The Levenberg–Marquardt algorithm is used to train the networks. The theoretical input resistance results obtained by using this method are in ver

## Abstract In this paper, an efficient neural network model is suggested to determine the input resonant resistance of coaxial fed rectangular microstrip antennas (MSAs) with thin and thick substrates. The NN results are in good agreement with experimental results reported in literature. This meth

## Abstract The modified Wolff model (MWM)‐based cavity model is presented for the simple and accurate computation of the input impedance of a probe‐fed multilayer rectangular microstrip patch antenna. Results of the MWM are compared with both the experimental data and data of the MoM, with agreeme

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

In this article, an efficient application of a genetic algorithm (GA) in an artificial neural network (ANN) to calculate the resonant frequency of a coaxially-fed tunable rectangular microstrip-patch antenna is presented. For a normal feed-forward back-propagation algorithm, with a compromise betwee