SBIR-STTR Award

This advanced development programis devoted to the development of computer models for analyzing 1) antenna patttern performance, 2) antenna coupling, and 3) RADHAZ for antennas that are enclosed or embedded in composite structures, and 4) the resultant RCS of the integrated antenna/composite structures. The computer models will be based on the Spherical Angular Function (SAF) analysis technique for near-field scattering and coupling. Proprietary adaptive asymptotic subroutines will be adapted for efficient analysis of the complex near-field scattering geometries involving micro/millimeter wave antennas enclosed or embedded in the topside composite structures. The computer models will be applicable to the following types of enclosed or embedded antennas: horns, reflectors, traveling wave antennas, planar arrays, and curved arrays. In Phase I, the proof-of-principle for the SAF adaptive asymptotic technique will be demonstrated for flat polygonally-shaped and flat elliptically-shaped multilayer composite and metallic plates. In particular, antenna pattern performance, antenna coupling, RADHAZ, and RCS will be computed for the plates and validated with government-furnished measured data. The approach to be taken to apply the SAF adaptive asymptotic technique to antennas enclosed or embedded in multilayer composite masts having the following cross-sectional shapes, that are either encountered now or are expected to be encountered in the near future, will be presented and discussed: 1) general "n-gon" polygonal cross sections, 2) circular cross sections, and 3) general curved cross sections.

Phase II is devoted to the development of a synergistic suite of computer codes, referred to as GSUITE, for the efficient analysis and design of integrated antenna/composite topsides. GSUITE will be obtained by developing advanced frequency domain and time domain analysis codes for use in conjunction with Spherical Angular Function (SAF) and Plane Wave Spectrum (PWS) analysis techniques to determine the total electromagnetic (EM) effectiveness of present and future integrated antenna/composite antennas. Electromagnetic effectiveness encompasses near-field (NF) and far-field (FF) antenna pattern performance, antenna coupling, EMC, RADHAZ, HERO, and RCS. GSUITE will provide the capability to model the EM effectiveness of antennas that are enclosed by or embedded in finite composite walls. The finite (truncated) composite walls may consist of multilayer dielectrics with inhomogenieties and either thin or thick FSS elements. The embedded antenna array elements modeled includes rectangular and/or circular patches, spirals, Vivaldi notches, slots and waveguides. The enclosed antennas include all of the aforementioned types of array antennas as well as current and future reflector and horn antennas. The effects of interactions between the embedded or enclosed antennas and the FSS will be modeled. The composite mast structure can be faceted or curved (radius of curvature>5 wavelenths).