Optical beamforming network for controlling an RF phased array
First Claim
1. An optical beamforming network for controlling a phased array antenna, comprising:
- means for providing a first beam of coherent light;
means for providing a reference beam of coherent light;
means for distributing said reference beam;
means for spatially modulating said first beam, said spatially modulated beam carrying a footprint of a desired antenna radiation pattern;
means for providing a Fourier transform of said spatially modulated beam;
means for generating a frequency shifted phase conjugate return of said modulated and transformed beam;
means for combining said frequency shifted phase conjugate return with said distributed reference beam to generate a distributed beat frequency; and
means for receiving and detecting said distributed beat frequency to control the phased array antenna.
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Abstract
An optical beamforming network is provided for controlling the RF radiation pattern of a phased array antenna. Light from a first laser is modulated by a spatial light modulator that is user-programmed with the desired far field radiation footprint. The modulated light beam is directed through a Fourier transform lens and onto a beam splitter where it is combined with light from a second laser that is frequency offset by the RF center frequency of the antenna. Light from the beam splitter is recovered by first and second fiber optic bundles. Each optical fiber leads to a corresponding photodetector that detects the beat frequency produced by the two frequency offset light beams. The outputs of corresponding photodetectors of the two fiber optic bundles are combined to control the radiation of a corresponding radiation element of the phased array. The use of two sets of optical fibers and photodetectors improves the signal-to-noise ratio of the system. An alternative embodiment of the invention uses photorefractive crystals to pass phase conjugate return beams back through the optical lenses to cancel lens-induced aberrations from the spatially modulated light beam. This embodiment reduces distortion of the far field radiation pattern without the use of high quality optical lenses.
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Citations
6 Claims
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1. An optical beamforming network for controlling a phased array antenna, comprising:
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means for providing a first beam of coherent light; means for providing a reference beam of coherent light; means for distributing said reference beam; means for spatially modulating said first beam, said spatially modulated beam carrying a footprint of a desired antenna radiation pattern; means for providing a Fourier transform of said spatially modulated beam; means for generating a frequency shifted phase conjugate return of said modulated and transformed beam; means for combining said frequency shifted phase conjugate return with said distributed reference beam to generate a distributed beat frequency; and means for receiving and detecting said distributed beat frequency to control the phased array antenna. - View Dependent Claims (2, 3, 4)
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5. An optical beamforming network for controlling a phased array antenna, comprising:
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a frequency stabilized laser for providing a beam of coherent light; a beam splitter for splitting said laser beam into a first beam and a reflected beam; an amplitude grating and a self pumped phase conjugator for receiving said reflected beam and generating a distributed reference beam; a spatial light modulator for modulating said first beam to include a footprint of a desired antenna radiation pattern; an optical lens for providing a Fourier transform of said modulated first beam; a mutually pumped phase conjugator for generating a frequency shifted phase conjugate return of said modulated and transformed first beam; means for combining said frequency shifted phase conjugate return with said distributed reference beam to generate a distributed beat frequency; and means for receiving and detecting said distributed beat frequency to control the phased array antenna. - View Dependent Claims (6)
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Specification