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A Method for Seeking Low-Redundancy Large Linear Arrays in Aperture Synthesis Microwave Radiometers | IEEE Journals & Magazine | IEEE Xplore

A Method for Seeking Low-Redundancy Large Linear Arrays in Aperture Synthesis Microwave Radiometers


Abstract:

For one-dimensional aperture synthesis microwave radiometers, the optimal placement of antenna elements in a low-redundancy linear array (LRLA) is difficult when large nu...Show More

Abstract:

For one-dimensional aperture synthesis microwave radiometers, the optimal placement of antenna elements in a low-redundancy linear array (LRLA) is difficult when large numbers of elements are involved. In this paper, the general structure of large LRLAs is summarized first, and then a novel stochastic optimization technique, ant colony optimization (ACO), is applied to the search for low redundancy arrays. By combining the general structure with the ACO procedure, an efficient method is proposed for a rapid exploration for optimal array configurations. Numerical studies show that the method can generate various large LRLAs with lower redundancy than the previous algorithms did and the computational cost is greatly reduced. Based on the method, several analytical patterns for LRLAs are further derived, which can yield various array configurations with very low redundancy in nearly zero computation time. Both the method and the resulting configurations can be utilized to facilitate antenna array design in synthetic aperture radiometers with high spatial resolution.
Published in: IEEE Transactions on Antennas and Propagation ( Volume: 58, Issue: 6, June 2010)
Page(s): 1913 - 1921
Date of Publication: 29 March 2010

ISSN Information:


I. Introduction

Interferometric aperture synthesis technique is an attractive means for improving spatial resolution in passive microwave remote sensing of the Earth [1]–[3]. Different spatial frequencies are sampled by cross-correlating antenna pairs with different separations, and all sampled spatial frequencies can then be inverted to estimate the original brightness distribution of a scene.

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