Conical omni-directional coverage multibeam antenna
First Claim
1. An antenna system having a plurality of radiating structures spaced circumferentially around a center point, each radiating structure spaced equidistant from and parallel to a next adjacent radiating structure, said system comprising:
- a ground surface circumferentially located around said center point and between said center point and each of said radiating structures, wherein the radius of the ground surface and the radius of the circumferentially spaced radiating structures are selected to cooperatively control side lobe levels; and
means for phase shifting a transmission signal from certain activated ones of said activated radiating structures a selected delay amount, the phase shift amount being selected such that the transmission signal wave front leaving said certain activated radiating structures is in a relatively straight line substantially perpendicular to the direction of travel of said transmission signal, the direction of travel being normal to a point on the ground surface corresponding to one of said certain activated radiating structures.
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Abstract
An omni directional coverage multibeam antenna relief on a ground surface having simple conical shapes to provide beam steering. One advantage of such a system is that the projected area is always constant and broadside to the intended direction resulting in limited scan loss effects. In the case of a cylinder as the conical shape, z-axis symmetry provides a constant antenna aperture projection in any azimuthal direction. Using this geometry, high level, side lobes are reduced considerably because of the natural aperture tapering from dispersion effects. Coverage area and power can be controlled by changing the ground surface angle and by selectively activating different antenna beam positions around the circumference of the ground surface, and by selectively changing the phase relationship between a given set of antenna beams.
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Citations
56 Claims
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1. An antenna system having a plurality of radiating structures spaced circumferentially around a center point, each radiating structure spaced equidistant from and parallel to a next adjacent radiating structure, said system comprising:
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a ground surface circumferentially located around said center point and between said center point and each of said radiating structures, wherein the radius of the ground surface and the radius of the circumferentially spaced radiating structures are selected to cooperatively control side lobe levels; and
means for phase shifting a transmission signal from certain activated ones of said activated radiating structures a selected delay amount, the phase shift amount being selected such that the transmission signal wave front leaving said certain activated radiating structures is in a relatively straight line substantially perpendicular to the direction of travel of said transmission signal, the direction of travel being normal to a point on the ground surface corresponding to one of said certain activated radiating structures. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25)
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26. The method of operating an antenna system having a plurality of radiating structures spaced circumferentially around a center point, each radiating structure spaced equidistant from and parallel to a next adjacent radiating structure, wherein a ground surface is circumferentially located around the center point and between the center point and each of the radiating structures;
- the method comprising the steps of;
delaying a transmission signal from certain activated ones of the radiating structures a selected delay amount; and
selecting the delay amount such that the transmission signal wave front leaving the certain activated ones of the radiating structures is in a relatively straight line substantially perpendicular to the direction of desired travel of the transmission signal, the delay amount also being selected to produce a tapered aperture distribution when the certain activated ones of the radiating structures are driven substantially at unity. - View Dependent Claims (27, 28, 29, 30, 31)
selecting, during operation, a scan angle in the elevation plane.
- the method comprising the steps of;
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31. The method set forth in claim 30 wherein each radiating structure includes a plurality of individual sub-radiating structures, and wherein the step of selecting a scan angle in the elevation plane includes the step of:
adjusting the phase relationship of a signal radiating from the individual sub-radiating structures of each radiating structure.
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32. The method of operating an antenna system having a plurality of transmitting structures spaced circumferentially around a center point, each such structure spaced equidistant from and parallel to a next adjacent structure, wherein a ground surface is circumferentially located around the center point and between the center point and each of the structures;
- the method comprising the steps of;
delaying a reception signal from certain activated ones of the structures a selected delay amount; and
selecting the delay amount such that the reception signal wave front arriving at the certain activated ones of the structures is in a relatively straight line substantially perpendicular to the direction from which the transmission signal was originated, the delay amount also being selected to produce a tapered aperture distribution when the certain activated ones of the structures are driven substantially at unity. - View Dependent Claims (33, 34, 35, 36)
- the method comprising the steps of;
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37. The method of constructing an antenna system comprising the steps of:
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establishing a ground surface circumferentially located around a mast, said ground surface circumscribing a volume substantially perpendicular to a surface upon which signals transmitted from a radiating structure are to be received on; and
positioning a plurality of antenna structures at spaced intervals circumferentially around the ground surface, wherein a radius of the ground surface and a radius of the circumferentially spaced antenna structures are selected to provide a selected divergence factor; and
associating with each antenna structure a delay device for controlling the phase of a signal through the associated antenna with respect to other ones of the antenna structures. - View Dependent Claims (38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56)
curving either the top or bottom edge of the ground surface or both to form a torus.
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41. The method set forth in claim 40 further including the step of adding lossy material to the torus.
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42. The method set forth in claim 37 further including the step of constructing at least some of the antenna structures as signal receiving structures and some as signal transmission structures.
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43. The method set forth in claim 42 further including the step of forming two RF chambers within the volume of the ground surface, one chamber for containing the receiving structures and one chamber containing the transmission structures.
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44. The method set forth in claim 43 wherein both chambers are contained within a single radome, all supported by the mast extending through the longitudinal center of the antenna system.
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45. The method set forth in claim 37 wherein certain of the radiating structures have a first design and others of the radiating structures have a second design.
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46. The method set forth in claim 37 wherein each antenna structure is parallel to the longitudinal axis of the ground surface.
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47. The method set forth in claim 46 further including the step of constructing a plurality of individual antenna structures connected to a common signal transmission medium.
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48. The method set forth in claim 47 further including the step of adjusting the antenna structures which are connected to a common medium so as to be in phase with each other.
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49. The method set forth in claim 48 further including the step of adjusting the antenna structures, which are connected to a common medium so as to be out of phase with each other by a selected amount.
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50. The method set forth in claim 37 wherein said radiation structures create circular polarization of a transmission signal.
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51. The method set forth in claim 37 wherein the activation of any one structure involves the activation of only four adjacent structures.
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52. The method set forth in claim 51 wherein said four adjacent structures are controlled using Wilkinson and hybrid combiners in a non-interleaved mode with a loss of 3 db of power.
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53. The method set forth in claim 51 wherein said four adjacent structures are controlled using Wilkinson and hybrid combiners in an interleaved mode with no loss of power.
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54. The method set forth in claim 53 wherein said interleaved mode includes a dual antenna array for each of the structures.
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55. The method set forth in claim 54 wherein each of the dual antennas of each structure includes a plurality of individual radiator points, oriented to create an elliptical radiation pattern.
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56. The method set forth in claim 55 wherein the elliptical radiation pattern is circular.
Specification