Existing and future Naval vessels require multiple antenna apertures for applications such as communications, electronic warfare (EW), and electronic sensor measures (ESM) at S-Band and higher frequencies. Since space is limited on a vessel, the radio frequency (RF) apertures are required to operate in close physical proximity to each other and often in-band with other systems. This can result in interference between transmitting and receiving apertures. The objective of this proposal is to develop an integrated, intuitive modeling and simulation tool to accurately analyze RF aperture performance in complex environments in a cost effective manner. This tool will characterize coupling between multiple RF apertures, installed transmit and receive performance of apertures, and radiation hazard (RADHAZ) zones due to RF apertures. The tool will also accurately characterize the effect of structures such as masts, railings, and other antenna structures including radomes composed of frequency selective surface (FSS) materials. The accuracy of the new toolsuite will be thoroughly validated using multiple empirical and deterministic modeling and simulation tools. The resulting RF aperture integrated tool suite will revolutionize the Navy's ability to install new systems on existing vessels and next-generation vessels. The resulting physics-based antenna modeling tool will revolutionize the developer's and the warfighter's ability to maintain effective communication links. This tool will enable the user to perform analysis of extremely diverse environments with multiple systems over wide frequency ranges. Additionally, the analyst and the system designer will be able to use this tool to assess and guide the development of new RF systems with orders of magnitude in improved accuracy and reduction of cost, production, and testing for multiple high frequency systems.
Keywords: Emi Coupling, Antennas, Modeling And Simulation, Scattering, Radiation Hazards, Electromagnetic Compatibility (Emc), Apertures, Radio Frequency
