System and method providing delays for CDMA nulling
First Claim
1. A system for avoiding nulls in a composite radiation pattern formed from a plurality of antenna beams each simulcasting a same signal, the system comprising:
- means for providing a delayed version and a non-delayed version of the signal;
means for selectively coupling the delayed version of the signal to ones of the plurality of antenna beams;
means for selectively coupling the non-delayed version of the signal to other ones of the plurality of antenna beams to thereby avoid destructive combining of radiated signals; and
means for selecting the ones of the plurality of antenna beams to couple the delayed version of the signal to and the other ones of the plurality of antenna beams to couple the non-delayed version of the signal to at least in part as a function of a determination of a minimum number of delay boundaries between the antenna beams capable of avoiding destructive combining of radiated signals.
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Accused Products
Abstract
A system and method are disclosed for avoiding nulls in a composite radiation pattern synthesized from a plurality of antenna beams. The disclosed invention teaches the use of delays in the signal paths associated with ones of the antenna beams utilized to synthesize the desired radiation pattern in order to avoid destructive combining of the signals. In a preferred embodiment delays are introduced in each antenna beam signal having a common attribute such as a common phase center. Accordingly, a minimum number of phase differential boundaries are introduced in order that certain communications, such as CDMA, are not adversely affected.
53 Citations
47 Claims
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1. A system for avoiding nulls in a composite radiation pattern formed from a plurality of antenna beams each simulcasting a same signal, the system comprising:
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means for providing a delayed version and a non-delayed version of the signal;
means for selectively coupling the delayed version of the signal to ones of the plurality of antenna beams;
means for selectively coupling the non-delayed version of the signal to other ones of the plurality of antenna beams to thereby avoid destructive combining of radiated signals; and
means for selecting the ones of the plurality of antenna beams to couple the delayed version of the signal to and the other ones of the plurality of antenna beams to couple the non-delayed version of the signal to at least in part as a function of a determination of a minimum number of delay boundaries between the antenna beams capable of avoiding destructive combining of radiated signals. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16)
means for selecting the ones of the plurality of antenna beams to couple the delayed version of the signal to and the other ones of the plurality of antenna beams to couple the non-delayed version of the signal to at least in part as a function of a desired synthesized sector azimuth pointing direction.
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6. The system of claim 5, wherein the synthesized sector azimuth pointing direction is selected to balance communication traffic loading across a plurality of sectors synthesized from said plurality of antenna beams.
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7. The system of claim 5, wherein the synthesized sector azimuth pointing direction is selected to balance communication traffic loading across a plurality of cells in a cellular communication system.
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8. The system of claim 1, wherein the ones of the plurality of antenna beams coupled by the means for selectively coupling the delayed version of the signal have a different phase center as compared to the other ones of the plurality of antenna beams coupled by the means for selectively coupling the non-delayed version of the signal.
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9. The system of claim 8, wherein the phase center difference is at least in part caused by the plurality of antenna beams coupled by the means for selectively coupling the delayed version of the signal being associated with a first antenna array and the other ones of the plurality of antenna beams coupled by the means for selectively coupling the non-delayed version of the signal being associated with a second antenna array.
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10. The system of claim 1, wherein the delayed signal version and non-delayed signal version means comprises a delay element disposed in the signal path to introduce a predetermined amount of delay.
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11. The system of claim 10, wherein the delay element is selected from the group consisting of:
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a predetermined length of cable, a surface acoustic wave device, and a digital signal processor.
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12. The system of claim 10, wherein the amount of delay introduced by the delay element is selected to be between 0.81 μ
- sec and 3 μ
sec.
- sec and 3 μ
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13. The system of claim 12, wherein the amount of delay introduced by the delay element is approximately 2 μ
- sec.
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14. The system of claim 12, wherein the amount of delay introduced by the delay element is approximately 2.5 μ
- sec.
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15. The system of claim 1, wherein both the selectively coupling means each comprise:
a switch matrix coupled to the delayed version of the signal and to the non-delayed version of the signal, wherein the means for selectively coupling the delayed version of the signal passes the delayed version of the signal to a particular antenna beam of the plurality of antenna beams and the means for selectively coupling the non-delayed version of the signal passes the non-delayed version of the signal to another antenna beam of the plurality of antenna beams.
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16. The system of claim 15, further comprising:
a processor based controller coupled to the switch matrix of both the selectively coupling means, wherein the controller provides automated selection of signals passed by the switch matrix.
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17. A system for avoiding nulls in a composite radiation pattern formed from a plurality of antenna beams each simulcasting a same signal, the system comprising:
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means for providing a delayed version and a non-delayed version of the signal;
means for selectively coupling the delayed version of the signal to at least one of the plurality of antenna beams; and
means for selectively coupling the non-delayed version of the signal to other ones of the plurality of antenna beams, wherein said ones of the plurality of antenna beams and said other ones of the plurality of antenna beams are alternate antenna beams and wherein at least one of the delayed version and the non-delayed version is selectively coupled to more than one of the plurality of antenna beams. - View Dependent Claims (18, 19, 20, 21, 22)
a predetermined length of cable, a surface acoustic wave device, and a digital signal processor.
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21. The system of claim 17, wherein both the selectively coupling means each comprise:
a switch matrix coupled to the delayed version of the signal and to the non-delayed version of the signal, wherein the means for selectively coupling the delayed version of the signal passes the delayed version of the signal to a particular antenna beam of the plurality of antenna beams and the means for selectively coupling the non-delayed version of the signal passes the non-delayed version of the signal to another antenna beam of the plurality of antenna beams.
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22. The system of claim 21, further comprising:
a processor based controller coupled to the switch matrix of both the selectively coupling means, wherein the controller provides automated selection of signals passed by the switch matrix.
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23. A method for avoiding destructive combining of signals, the method comprising the steps of:
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accepting an input signal;
splitting the input signal thereby providing a first rendition of the signal and a second rendition of the signal;
delaying the second rendition of the signal thereby providing a delayed second rendition of the signal;
providing the first rendition of the signal and the delayed second rendition of the signal to a coupling device having a plurality of inputs and a plurality of outputs, wherein said coupling device provides selectable signal path connections between ones of said plurality of inputs and ones of said plurality of outputs;
operating the coupling device to pass the first rendition of the signal to predetermined ones of the plurality of outputs and to pass the delayed second rendition of the signal to predetermined other ones of the plurality of outputs;
determining a minimum number of delay boundaries between the outputs capable of avoiding destructive combining of signals; and
selecting the ones of the plurality of outputs to pass the first rendition of the signal to and the other ones of the plurality of the outputs to pass the second delayed rendition of the signal to at least in part as a function of the determination made in the determining step. - View Dependent Claims (24, 25, 26, 27, 28, 29, 30)
identifying the antenna beams of the desired composite radiation pattern having a common attribute.
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26. The method of claim 25, wherein the first rendition of the signal are passed to ones of the antenna beams having a common attribute and the delayed second rendition of the signal are passed to other ones of the antenna beams having a common attribute at the operating step.
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27. The method of claim 25, wherein the common attribute is a same phase center.
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28. The method of claim 23, further comprising the steps of:
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determining if path length differences exist between a point of accepting the input signal and ones of the plurality of outputs;
selecting alternating ones of the plurality of outputs as the ones of the plurality of outputs to pass the first rendition of the signal to and the other ones of the plurality of the outputs to pass the delayed second rendition of the signal to.
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29. The method of claim 23, wherein the step of providing the first rendition of the signal and the delayed second rendition of the signal to a coupling device includes the steps of:
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splitting the first rendition of the signal thereby providing a plurality of renditions of the first rendition of the signal; and
splitting the delayed second rendition of the signal thereby providing a plurality of renditions of the delayed second rendition of the signal.
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30. The method of claim 29, wherein the coupling device includes a plurality of switch matrixes each having a plurality of inputs and an output associated with a particular antenna beam, and wherein a signal of the plurality of renditions of the first rendition of the signal is provided to an input of the plurality of inputs of ones of the switch matrixes, and wherein a signal of the plurality of renditions of the delayed second rendition of the signal is provided to another input of the plurality of inputs of the ones of the switch matrixes.
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31. An antenna feed system providing synthesis of a desired sector radiation pattern utilizing a plurality of narrow antenna beams simulcasting a sector signal, wherein the sector signal as simulcast by the narrow antenna beams is manipulated by the antenna feed system to prevent undesired nulling, the system comprising:
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circuitry providing both a delayed first sector signal and a non-delayed first sector signal for selective communication to each of the narrow antenna beams; and
a controller coupled to the circuitry operable to control the communication of the delayed first sector signal to first ones of the narrow antenna beams associated with a first sector to be synthesized and to control the communication of the non-delayed first sector signal to second ones of the narrow antenna beams associated with the first sector to be synthesized, wherein the first ones of the narrow antenna beams have a first phase center and the second ones of the narrow antenna beams have a second phase center. - View Dependent Claims (32, 33, 34, 35)
a delay element having a delay of between 0.81 μ
sec and 3 μ
sec associated therewith.
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34. The system of claim 33, wherein the delay is approximately 2 μ
- sec.
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35. The system of claim 31, wherein the circuitry also provides both a delayed second sector signal and a non-delayed second sector signal for selective communication to each of the narrow antenna beams, wherein the controller is also operable to control the communication of the delayed second sector signal to third ones of the narrow antenna beams associated with a second sector to be synthesized and to control the communication of the non-delayed second sector signal to fourth ones of the narrow antenna beams associated with the second sector to be synthesized.
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36. An antenna feed system providing synthesis of a desired sector radiation pattern utilizing a plurality of narrow antenna beams simulcasting a sector signal, wherein the sector signal as simulcast by the narrow antenna beams is manipulated by the antenna feed system to prevent undesired nulling, the system comprising:
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circuitry providing both a delayed first sector signal and a non-delayed first sector signal for selective communication to each of the narrow antenna beams;
a controller coupled to the circuitry operable to control the communication of the delayed first sector signal to first ones of the narrow antenna beams associated with a first sector to be synthesized and to control the communication of the non-delayed first sector signal to second ones of the narrow antenna beams associated with the first sector to be synthesized, wherein the first ones of the narrow antenna beams have a first phase center and the second ones of the narrow antenna beams have a second phase center, and wherein selection by the controller of the first ones of the narrow antenna beams to couple the delayed first sector signal to and the second ones of the narrow antenna beams to couple the non-delayed first sector signal to is at least in part a function of a desired synthesized sector azimuth angle. - View Dependent Claims (37, 38, 39)
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40. A system for avoiding destructive combining of signals simulcast over a plurality of antenna beams, the system comprising:
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a plurality of first splitters each associated with a particular signal input of a plurality of signal inputs;
a plurality of delay elements each of which is coupled to an output of a particular one of the plurality of first splitters;
a plurality of second splitters each of which is coupled to an output of a particular one of the plurality of first splitters;
a plurality of third splitters each of which is coupled to an output of a particular one of the plurality of delay elements; and
a plurality of switch matrixes each associated with a particular antenna beam output of a plurality of antenna beam outputs, wherein an output of each of the plurality of second splitters and an output of each of the plurality of third splitters are coupled to each of the plurality of switch matrixes. - View Dependent Claims (41, 42, 43, 44, 45, 46, 47)
a controller coupled to each of the plurality of switch matrixes, wherein the controller provides control signals to cause first ones of the plurality of switch matrixes to pass a non-delayed first signal associated with a first input of the plurality of signal inputs, and wherein the controller provides control signals to cause second ones of the plurality of switch matrixes to pass a delayed first signal associated with the first input of the plurality of signal inputs, wherein the delayed first signal is delayed with respect to the non-delayed first signal by the delay element of the plurality of delay elements associated with the first input of the plurality of signal inputs.
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46. The system of claim 45, wherein the controller provides control signals to cause third ones of the plurality of switch matrixes to pass a non-delayed second signal associated with a second input of the plurality of signal inputs, and wherein the controller provides control signals to cause fourth ones of the plurality of switch matrixes to pass a delayed second signal associated with the second input of the plurality of signal inputs, wherein the delayed second signal is delayed with respect to the non-delayed second signal by the delay element of the plurality of delay elements associated with the second input of the plurality of signal inputs.
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47. The system of claim 45, further comprising:
a plurality of signal amplitude adjuster elements each of which is coupled to an output of a particular one of the plurality of switch matrixes, wherein the controller is also coupled to each amplitude adjuster element, and wherein the controller provides control signals to cause ones of the amplitude adjuster elements to adjust an amplitude of a signal to provide a desired composite antenna beam size.
Specification