Electromagnetic detection of dielectric cylinders by a neural network approach

The unit vector s was chosen arbitrarily, and ˆ0 z f L. The precision was set to 1.0 = 10 y3 . For each L, the function T was evaluated at 2 L 2 observation points. This is L in accordance with the demands of MLFMA. The results are presented in Table 2. In the table, entries marked ''direct'' refer

## Abstract The wavelet matrix transform approach, in combination with the conventional method of moments, is used to solve the problem of electromagnetic scattering by a dielectric cylinder. First, the problem is formulated in terms of the integral equation for the field of a harmonic source in th

measured resonant frequency of 1021 MHz is in good agreement with the theoretical value of 1040 MHz. The theoretical and measured radiation patterns in the E-and H-planes are Ž . shown in Figure 2 d . In the measured pattern, a dip of about 8 dB is observed in the broadside direction instead of a co

An analysis of the performances of the neural-network approach for the geometric and dielectric characterization of buried cylinders is carried out. The neural-network process data are obtained from the time-domain formulation of the electromagnetic scattering problem. This analysis is based on the