Scanned antenna system and method
First Claim
1. A scanned antenna for converting a radio frequency (rf) signal into a scanned antenna beam, comprising:
- a radiative member formed with an input port and an output aperture and configured to radiate rf energy that is received through said input port as an antenna beam from said output aperture, wherein said antenna beam has a phase distribution across said output aperture that is a function of the phase distribution of said rf energy across said input port;
a radiative line source having an entrance port and an exit aperture, said exit aperture spaced from said input port and configured to illuminate, in response to said rf signal at said entrance port, said input port with a sheet of rf energy which is directed along a signal plane that extends between said exit aperture and said input port;
a rotatable, transmission member having a cylindrical wall formed about a rotational axis, said transmission member positioned with said exit aperture received within said cylindrical wall; and
a plurality of different transmission structures, each positioned on said cylindrical wall to be across said signal plane as said transmission member is rotated about said axis to a different one of a plurality of rotational positions;
each of said different transmission structures configured to process said rf energy sheet with a different one of a plurality of transfer functions to direct a processed rf energy sheet into said input port with wavefronts which are each sloped at a different one of a plurality of wavefront angles with said input port, said different wavefront angles causing said processed rf energy sheet to have different phase distributions across said input port.
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Accused Products
Abstract
A compact scanned antenna which includes a radiator, a rotatable tube and a line source. The radiator is formed by plating a shaped dielectric core. It generates an antenna beam at an output aperture in response to a microwave signal at an input port. The line source generates a radiation sheet which is directed across a signal plane to the input pot. The tube has a cylindrical wall which is positioned across the signal plane. As the tube rotates, refractive or diffractive transmission structures pass through the signal plane. The refractive structures include linear segments which refract the wavefront of the radiation sheet. Because the wavefront slope at the radiator'"'"'s aperture is a function of the wavefront slope at its input port, the antenna beam is scanned. The linear contour segments have the same inclination but are not colinear. This arrangement reduces the thickness of the tube wall. Phase coherence is achieved by an appropriate radial spacing of adjacent ends of contour segments. The diffractive structures are arranged to vary the spacing of diffraction rings as they pass through the signal plane. This produces scanned, first-order antenna beams. The line source is adapted to direct a predetermined one of these beams into the radiator.
5 Citations
54 Claims
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1. A scanned antenna for converting a radio frequency (rf) signal into a scanned antenna beam, comprising:
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a radiative member formed with an input port and an output aperture and configured to radiate rf energy that is received through said input port as an antenna beam from said output aperture, wherein said antenna beam has a phase distribution across said output aperture that is a function of the phase distribution of said rf energy across said input port; a radiative line source having an entrance port and an exit aperture, said exit aperture spaced from said input port and configured to illuminate, in response to said rf signal at said entrance port, said input port with a sheet of rf energy which is directed along a signal plane that extends between said exit aperture and said input port; a rotatable, transmission member having a cylindrical wall formed about a rotational axis, said transmission member positioned with said exit aperture received within said cylindrical wall; and a plurality of different transmission structures, each positioned on said cylindrical wall to be across said signal plane as said transmission member is rotated about said axis to a different one of a plurality of rotational positions; each of said different transmission structures configured to process said rf energy sheet with a different one of a plurality of transfer functions to direct a processed rf energy sheet into said input port with wavefronts which are each sloped at a different one of a plurality of wavefront angles with said input port, said different wavefront angles causing said processed rf energy sheet to have different phase distributions across said input port. - View Dependent Claims (2, 3)
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4. A scanned antenna for converting a radio frequency (rf) signal with a wavelength λ
- into a scanned antenna beam, comprising;
a radiative member formed with an input port and an output aperture and configured to radiate rf energy that is received through said input port as an antenna beam from said output aperture, wherein said antenna beam has a phase distribution across said output aperture that is a function of the phase distribution of said rf energy across said input port; a radiative line source having an entrance port and an exit aperture, said exit aperture spaced from said input port and configured to illuminate, in response to said rf signal at said entrance port, said input port with a sheet of rf energy which is directed along a signal plane that extends between said exit aperture and said input port; a rotatable, refractive member having a cylindrical wall formed about a rotational axis, said cylindrical wall formed of a material with a refractive index n and having an inner and an outer surface, said refractive member positioned with said exit aperture received within said cylindrical wall; and a plurality of different contours formed by one of said inner and outer surfaces and each positioned on said cylindrical wall to be across said signal plane as said refractive member is rotated about said axis to a different one of a plurality of rotational positions; wherein; a first one of said contours includes a plurality of first linear segments which are not colinear and which have substantially the same first inclination from said axis; a second one of said contours includes a plurality of second linear segments which are not colinear and which have substantially the same second inclination from said axis; and said first inclination differs from said second inclination; said different contours causing said rf energy sheet to have different phase distributions across said input port. - View Dependent Claims (5, 6, 7, 8, 9, 10, 11, 12, 13, 14)
- into a scanned antenna beam, comprising;
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15. A scanned antenna for converting a radio frequency (rf) signal with a wavelength λ
- into a scanned antenna beam, comprising;
a radiative member formed with an input port and an output aperture and configured to radiate rf energy that is received through said input port as an antenna beam from said output aperture, wherein said antenna beam has a phase distribution across said output aperture that is a function of the phase distribution of said rf energy across said input port; a radiative line source having an entrance port and an exit aperture, said exit aperture spaced from said input port and configured to illuminate, in response to said rf signal at said entrance port, said input port with a sheet of rf energy which is directed along a signal plane that extends between said exit aperture and said input port; a rotatable, diffractive member having a cylindrical wall formed about a rotational axis, said cylindrical wall having an inner and an outer surface and said diffractive member positioned with said exit aperture received within said cylindrical wall; and a diffraction grating formed with a plurality of diffraction rings on one of said inner and outer surfaces; wherein; said diffraction grating is arranged to have, in said signal plane, different axial spacings between said diffraction rings as said diffractive member is rotated about said axis to different rotational positions, said diffraction grating processing said rf energy sheet into a zero-order, rf energy sheet and a pair of first-order, rf energy sheets; and said radiative line source adapted to direct a predetermined one of said first-order, rf energy sheets into said input port; said different, diffraction-grating spacings causing said predetermined, first-order, rf energy sheet to have different phase distributions across said input port. - View Dependent Claims (16, 17, 18, 19, 21, 22, 23, 24, 25, 26)
- into a scanned antenna beam, comprising;
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20. The scanned antenna of claim i5, wherein said radiative member incudes;
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a dielectric panel having a side and an edge, said edge defining said input port; and a plurality of dielectric ribs that are arranged to issue from said panel side to define said output aperture.
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27. A scanned antenna for converting a radio frequency (rf) signal into a scanned antenna beam, comprising:
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a radiative line source having an entrance port and an exit aperture, said exit aperture configured to radiate, in response to said rf signal at said entrance port, an antenna beam in the form of a sheet of rf energy; and a rotatable, transmission member having a cylindrical wall formed about a rotational axis, said transmission member positioned with said exit aperture received within said cylindrical wall; and a plurality of different transmission structures, each positioned on said cylindrical wall to be across said rf energy sheet as said transmission member is rotated about said axis to a different one of a plurality of rotational positions; each of said different transmission structures configured to process said rf energy sheet with a different one of a plurality of transfer functions to generate a processed rf energy sheet with wavefronts which are each sloped at a different one of a plurality of angles with said exit aperture, said different angles causing said processed rf energy sheet to be scanned. - View Dependent Claims (28, 29)
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30. A scanned antenna for converting a radio frequency (rf) signal with a wavelength λ
- into a scanned antenna beam, comprising;
a radiative line source having an entrance port and an exit aperture, said exit aperture configured to radiate, in response to said rf signal at said entrance port, an antenna beam in the form of a sheet of rf energy; a rotatable, refractive member having a cylindrical wall formed about a rotational axis, said cylindrical wall formed of a material with a refractive index n and having an inner and an outer surface, said refractive member positioned with said exit aperture received within said cylindrical wall; and a plurality of different contours formed by one of said inner and outer energy sheet as said retractive member is rotated about said axis to a different one of a plurality of rotational positions; wherein; a first one of said contours includes a plurality of first linear segments which are not colinear and which have substantially the same first inclination from said axis; a second one of said contours includes a plurality of second linear segments which are not colinear and which have substantially the same second inclination from said axis; and said first inclination differs from said second inclination; said different contours causing said rf energy sheet to have wavefronts which are each sloped at a different one of a plurality of angles with said exit aperture, said different wavefront angles causing said rf energy sheet to be scanned. - View Dependent Claims (31, 32, 33, 34, 35, 36, 37)
- into a scanned antenna beam, comprising;
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38. A scanned antenna for converting a radio frequency (rf) signal into at least one scanned antenna beam, comprising:
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a radiative line source having an entrance port and an exit aperture, said exit aperture configured to radiate, in response to said rf signal at said entrance port, an antenna beam in the form of a sheet of rf energy; a rotatable, diffractive member having a cylindrical wall formed about a rotational axis, said cylindrical wall having an inner and an outer surface and said diffractive member positioned with said exit aperture received within said cylindrical wall; and a diffraction grating formed with a plurality of diffraction rings on one of said inner and outer surfaces; wherein; said diffraction grating is arranged to have, across said rf energy sheet, different axial spacings between said diffraction rings as said diffractive member is rotated about said axis to different rotational positions; said diffraction grating processing said rf energy sheet into a zero-order, rf energy sheet and a pair of first-order, rf energy sheets; and said different, diffraction-grating spacings causing said first-order, rf energy sheets to each have wavefronts which are each sloped at a different one of a plurality of angles with said exit aperture, said different wavefront angles causing said first-order, rf energy sheets to be scanned. - View Dependent Claims (39, 40, 41, 42, 43, 44, 45, 46)
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47. An obstacle-avoidance system for generating a scanned antenna beam from a microwave signal, comprising:
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a motor vehicle; and a scanned antenna carried on said vehicle, wherein said antenna includes; a) a radiative member formed with an input port and an output aperture and configured to radiate rf energy that is received through said input port as an antenna beam from said output aperture, wherein said antenna beam has a phase distribution across said output aperture that is a function of the phase distribution of said rf energy across said input port; b) a radiative line source having an entrance port and an exit aperture, said exit aperture spaced from said input port and configured to illuminate, in response to said microwave signal at said entrance port, said input port with a sheet of rf energy which is directed along a signal plane that extends between said exit aperture and said input port; c) a rotatable, transmission member having a cylindrical wall formed about a rotational axis, said transmission member positioned with said exit aperture received within said cylindrical wall; and d) a plurality of different transmission structures, each positioned on said cylindrical wall to be across said signal plane as said transmission member is rotated about said axis to a different one of a plurality of rotational positions; each of said different transmission structures configured to process said rf energy sheet with a different one of a plurality of transfer functions to direct a processed rf energy sheet into said input port with wavefronts which are each sloped at a different one of a plurality of angles with said input port, said different angles causing said processed rf energy sheet to have different phase distributions across said input port. - View Dependent Claims (48, 49)
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50. A scanned antenna for converting a radio frequency (rf) signal with a wavelength λ
- into a scanned antenna beam, comprising;
a radiative line source having an entrance port and an exit aperture, said exit aperture configured to radiate, in response to said rf signal at said entrance port, an antenna beam in the form of a sheet of rf energy; a refractive belt having a wall with an ifiner and an outer surface and formed of a material with a refractive index n, said refractive belt positioned with said exit aperture directed at said wall; and a plurality of different contours formed by one of said inner and outer surfaces and each positioned on said wall to be across said rf energy sheet as said belt is moved past said exit aperture to a different one of a plurality of positions; wherein; a first one of said contdurs includes a plurality of first linear segments which are not colinear and which have substantially the same first inclination from said exit aperture; a second one of said contours includes a plurality of second linear segments which are not colinear and which have substantially the same second inclination from said exit aperture; and said first inclination differs from said second inclination; said different contours causing said rf energy sheet to have wavefronts which are each sloped at a different one of a plurality of angles with said exit aperture, said different wavefront angles causing said rf energy sheet to be scanned. - View Dependent Claims (51)
- into a scanned antenna beam, comprising;
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52. A scanned antenna for converting a radio frequency (rf) signal into at least one scanned antenna beam, comprising:
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a radiative line source having an entrance port and an exit aperture, said exit aperture configured to radiate, in response to said rf signal at said entrance port, an antenna beam in the form of a sheet of rf energy; a diffractive belt having a wall with an inner and an outer surface, said diffractive belt positioned with said exit aperture directed at said wall; and a diffraction grating formed with a plurality of diffraction lines on one of said inner and outer surfaces; wherein; said diffraction grating is arranged to have, across said rf energy sheet, different spacings between said diffraction lines as said belt is moved past said exit aperture to a different one of a plurality of positions; said diffraction grating processing said rf energy sheet into a zero-order, rf energy sheet and a pair of first-order, rf energy sheets; and said different, diffraction-grating spacings causing said first-order, rf energy sheets to each have wavefronts which are each sloped at a different one of a plurality of angles with said exit aperture, said different wavefront angles causing said first-order, rf energy sheets to be scanned. - View Dependent Claims (53, 54)
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Specification