Claims
- 1. A method of producing a dual reflector antenna system capable of passing radiation to or from a shaped coverage area by means of a single feed, a three dimensional main reflector surface and a three dimensional subreflector surface, which method comprises the steps of:
- defining at least one desired parameter from the group consisting of power levels of radiation or desired directivity characteristics of radiation to be incident on selected regions of said shaped coverage area, having a residual of the form ##EQU7## where: Pj=weighting factor for the j.sup.th point to produce stepped regions; Dj=directivity at j.sup.th point; Do=a constant reference directivity; Wj=weighting factor to emphasize or de-emphasize the residual at the j.sup.th point,
- tracing a regular grid of rays only in a forward direction through the antenna system from the feed to the sub-reflector surface and from the sub-reflector surface to the main reflector surface, where the rays become a set of irregularly distributed points of incident values of said radiation, in a ray generation coordinate system where
- .theta.=(.theta.x.sup.2 +.theta..sub.y.sup.2).sup.1/2,
- where (.theta..sub.x,.theta..sub.y) are the coordinates of a point on a square grid in the (.theta..sub.x,.theta..sub.y) plane,
- iteratively determining said residual by calculating from said .theta..sub.x,.theta..sub.y grid, obtaining a test value of the form
- iTEST=jmax[1.0-.delta.]=0,
- where .delta.=A.sub.i.sup.j /A.sub.o.sup.j *FRAC; .delta.<1.0 for some j, and .delta.>1.0 for all j indicative of deviation of said parameter from a desired characteristic,
- three dimensionally modifying both said reflector surfaces simultaneously by obtaining quantities A.sub.x, A.sub.y and A.sub.z for points on the square grid to obtain an improved test value, and
- repeating said tracing step, said iteratively determining step, said modifying step and said obtaining a test value step until providing an antenna which forms a beam in operation which is matched to said shaped coverage area.
- 2. A method according to claim 1, comprising the further step of, at each iteration, checking to ensure that each ray intersecting the main reflector surface is surrounded by same neighboring rays as when said each ray intersected the sub-reflector surface.
- 3. A method according to claim 2, in which the optimization includes partitioning the irregularly distributed points of known incident values of a field into triangles,
- interpolating the field values on a rectangular grid from the triangles, and
- wherein said checking step is done by ensuring that the modification effected to the sub reflector surface does not cause the triangles to move into an overlapping relationship.
- 4. A method according to claim 3, in which at each iteration the degree of deviation of the triangles from their original areas is assessed.
- 5. A method of producing a dual reflector antenna system capable of passing radiation to or from a shaped coverage area by means of a single feed, a three dimensional main reflector surface and a three dimensional sub-reflector surface, which method comprises the steps of:
- defining at least one desired parameter from the group consisting of power levels of radiation or desired directivity characteristics of radiation to be incident on selected regions of said shaped coverage area having a residual of the form ##EQU8## where: Pj=weighting factor for the j.sup.th point to produce stepped regions; Dj=directivity at j.sup.th point; Do=a constant reference directivity; Wj=weighting factor to emphasize or de-emphasize the residual at the j.sup.th point;
- tracing a regular grid of rays only in a forward direction through the antenna system from the feed to the sub-reflector surface and from the sub-reflector surface to the main reflector surface, where the rays become a set of irregularly distributed points of incident values of said radiation in a ray generation coordinate system where
- .theta.=(.theta.x.sup.2 +.theta..sub.y.sup.2).sup.1/2,
- where (.theta..sub.x,.theta..sub.y) are the coordinates of a point on a square grid in the (.theta..sub.x,.theta..sub.y) plane,
- iteratively determining said residual by describing each reflector surface by a set of coefficients in a Fourier expansion Z=F(x,y), and calculating a point of intersection with the surface;
- obtaining a test value of the form
- .sub.j TEST=jmax[1.0-.delta.]=0,
- where .delta.=A.sub.i.sup.j /A.sub.o.sup.j *FRAC; .delta.<1.0 for some j, and .delta.>1.0 for all j indicative of deviation of said parameter from a desired characteristic and optimizing the coefficients to meet requirements of said shaped coverage area;
- three dimensionally modifying both said reflector surfaces simultaneously by obtaining quantities A.sub.x, A.sub.y and A.sub.z for points on the square grid to obtain an improved test value; and
- repeating said tracing step, said iteratively determining step, and said modifying step until providing an antenna which provides a beam in operation which is matched to said shaped coverage area.
- 6. A method according to claim 5, comprising the further step of, at each iteration, checking to ensure that each ray intersecting the main reflector surface is surrounded by same neighboring rays as when said each ray intersected the sub-reflector surface.
- 7. A method according to claim 6, in which the optimization includes partitioning the irregularly distributed points of known incident values of a field into triangles,
- interpolating the field values on a rectangular grid from the triangles, and
- wherein said checking step is done by ensuring that the modification effected to the sub reflector surface does not cause the triangles to move into an overlapping relationship.
- 8. A method according to claim 7, wherein said test value test assesses a degree of deviation of the triangles from their original areas.
- 9. A method of producing a dual reflector antenna system capable of passing radiation to or from a shaped coverage area using a single feed, a three dimensional main reflector surface and a three dimensional sub-reflector surface, comprising the steps of:
- defining the shaped coverage area as a set of discrete directions j in the far field;
- associating a residual indicative of a desired parameter of radiation with each said direction, said residual of the form ##EQU9## where: Pj=weighting factor for the j.sup.th point to produce stepped regions; Dj=directivity at j.sup.th point; Do=a constant reference directivity; Wj=weighting factor to emphasize or de-emphasize the residual at the j.sup.th point;
- defining a basic reference surface S.sub.1 (x,y) for the main reflector and a basic reference surface S.sub.2 (x,y) for the subreflector;
- tracing a regular grid of rays only in a forward direction through a current antenna system comprising a current shape of said main reflector and a current shape of said sub-reflector to the shaped coverage area;
- determining data points in a plane of the main reflector based on said traced grid of rays;
- mapping said data points onto a rectangular grid and partitioning said data points into triangles;
- iteratively determining a test value of the form
- jTEST=jmax[1.0-.delta.]=0,
- where .delta.=A.sub.i.sup.j /A.sub.o.sup.j *FRAC; .delta.<1.0 for some j, and .delta.>1.0 for all j to assess the degree to which the triangles have deviated from original values;
- modifying surfaces of said main reflector and subreflector to produce a new current antenna system, in a way to improve said test value j TEST; and
- repeating said tracing, determining, mapping, iteratively determining, and modifying steps until said test value is below a predetermined value to obtain final surfaces of said reflectors.
Priority Claims (1)
Number |
Date |
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Kind |
8813655 |
Jun 1988 |
GBX |
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Parent Case Info
This is a continuation of application Ser. No. 07/363,262, filed on Jun. 8, 1989, which was abandoned upon the filing hereof.
US Referenced Citations (5)
Foreign Referenced Citations (2)
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Date |
Country |
0219321 |
Apr 1987 |
EPX |
2850492 |
May 1979 |
DEX |
Non-Patent Literature Citations (2)
Entry |
K. Madsen et al., "Efficient Minimax Design of Networks Without Using Derivatives", IEEE Transactions on Microwave Theory and Techniques vol. MTT-23, No. 10, Oct. 1975, pp. 803-809. |
E. E. Voglis et al., "Shaped Dual-Offset Antenna with Dielectric Cone Feed for DBS Reception", IEEE Proceedings Section, vol. 132, Pt. H. No. 2, Apr. 1985, pp. 110-114. |
Continuations (1)
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Parent |
363262 |
Jun 1989 |
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