Abstract

The word radome is a contraction of radar and dome. The function of radomes is to protect antennas from atmospheric agents. Radomes are closed structures that protect the antennas from environmental factors such as wind, rain, ice, sand, and ultraviolet rays, among others. The radomes are passive structures that introduce return losses, and whose proper design would relax the requirement of complex front-end elements such as amplifiers. The radome consists mostly in a thin dielectric curved shape cover and sometimes needs to be tuned using metal inserts to cancel the capacitive performance of the dielectric. Radomes are in the near field region of the antennas and a full wave analysis of the antenna with the radome is the best approach to analyze its performance. A major numerical problem is the full wave modeling of a large radome-antenna-array system, as optimization of the radome parameters minimize return losses. In the present work, the finite difference time domain (FDTD) combined with a genetic algorithm is used to find the optimal radome for a large radome-antenna-array system. FDTD uses general curvilinear coordinates and sub-cell features as a thin dielectric slab approach and a thin wire approach. Both approximations are generally required if a problem of practical electrical size is to be solved using a manageable number of cells and time steps in FDTD inside a repetitive optimization loop. These approaches are used in the full wave analysis of a large array of crossed dipoles covered with a thin and cylindrical dielectric radome. The radome dielectric has a thickness of ~λ/10 at its central operating frequency. To reduce return loss a thin helical wire is introduced in the radome, whose diameter is ~0.0017λ and the spacing between each turn is ~0.3λ. The genetic algorithm was implemented to find the best parameters to minimize return losses. The inclusion of a helical wire reduces return losses by ~10 dB, however some minor changes of radiation pattern could distort the performance of the whole radome-array-antenna system. A further analysis shows that desired specifications of the system are preserved.

Highlights

  • This work presents the design procedure of a large radome, to cover an array with a large number of antennas, up to 48, whose height is of the order of 24 wavelengths and with small elements for adaptation of the order of 0.002 wavelengths

  • We present the technique we consider most suitable, finite difference time domain (FDTD), with sub-cell elements and curvilinear coordinates

  • In this work we address aofcomplex problem, thearray design optimizaoptimization a large electromagnetic radome to protect a large of and crossed dipoles

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Summary

Introduction

This work presents the design procedure of a large radome, to cover an array with a large number of antennas, up to 48, whose height is of the order of 24 wavelengths and with small elements for adaptation of the order of 0.002 wavelengths. We present the technique we consider most suitable, finite difference time domain (FDTD), with sub-cell elements and curvilinear coordinates. This technique is combined with an optimization process based on a genetic algorithm, and the combination of procedures proves to be appropriate for several specific cases. The antenna is not in open space, usually is covered with a case, wrapped in a large structure, or protected by a plastic radome which may be designed as a polarizer rotator or frequency filter [1,2].

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