Antenna beam congruency system for spacecraft cellular communications system
First Claim
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1. A spacecraft cellular communication system, comprising:
- a spacecraft including a body;
a receiving and frequency conversion arrangement mounted on said body, for receiving signals from terrestrial stations, and for converting signals received from terrestrial stations at specific frequencies within a first frequency band to other frequencies in a second frequency band, which second frequency band does not include said first frequency band;
at least one antenna supported by said body, said antenna including an array of radiating elements and a first plurality of signal input ports coupled to said radiating elements of said array of radiating elements;
a beamforming network mounted on said body, said beamforming network including plural input ports coupled to said receiving and frequency conversion arrangement, and a plurality of output ports coupled to said signal input ports of said antenna array, for receiving signals at said other frequencies within said second frequency band at said plural input ports, and for combining said signals at said other frequencies in a manner which, in combination with said antenna, generates a plurality of spot radiation beams directed toward the Earth'"'"'s surface, said spot radiation beams defining overlapping footprints, for transmitting signals at said other frequencies from said spacecraft to terrestrial user terminals located within said footprints;
a fixed terrestrial terminal lying within the overlap region between at least first and second specific ones of said spot beams, for transmitting signals to said spacecraft at some of said specific frequencies within a first frequency range, for transmission of information signals to at least some of said terrestrial user terminals, whereby antenna positional errors may cause said spot beams to be misdirected; and
an antenna positioning arrangement, said antenna positioning arrangement comprising;
(a) beacon signal transmitting means located at said fixed terrestrial terminal, for transmitting beacon signals to said receiving and frequency conversion arrangement at a beacon frequency lying within said first frequency band, whereby said receiving and frequency conversion means converts said beacon signals lying within said first frequency band to beacon signals lying within said second frequency band;
(b) coupling means coupled to said receiving and frequency conversion means and to at least one of said input ports of said beamforming network, for coupling said beacon signals to said beamforming network in a manner which generates said first and second specific ones of said spot beams in a temporal sequence;
(c) beacon signal receiving means located at said fixed terrestrial terminal, for receiving said beacon signals at said second frequency band in said temporal sequence;
(d) error determining means coupled to said beacon signal receiving means, for comparing characteristics of said beacon signals in said temporal sequence, to determine pointing error of said antenna; and
(e) control means coupled to said error determining means, for generating control signals for tending to move said spot beams to a condition in which said beacon signals in said temporal sequence have a common value of at least one of said characteristics.
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Abstract
A spacecraft-based cellular communications system includes a spacecraft with transmit and receive antennas, each of which produces a plurality of spot beams which, together, provide coverage of the region served. In order to control the pointing of the spacecraft antennas, four mutually adjacent spot beams are centered over a particular "beacon" location, so that the beacon location lies between a pair of North and South spot beams, and between a pair of East and West spot beams. The transmit antenna is controlled by transmitting a beacon signal in time sequence over each of the four spot beams surrounding the beacon location, and decoding or desequencing the time-sequential signal received at the beacon location. The decoded signal is processed to provide a signal indicating the pointing error of the transmit antenna, and the error signal is used to control a gimbal which controls the pointing of the transmit antenna.
The receive antenna is independently controlled by a generally similar system, in which the beacon signal is transmitted from the beacon location to the receive antenna, and the beacon signal is selectively received from the four spot beams in a time-sequential manner. The received beacon signal is processed in much the same manner as in the transmit antenna controller, and controls a gimbal associated with the receive antenna, to cause the receive antenna to point at the beacon location. Since both transmit and receive antennas point at the beacon location, their beams can be congruent.
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Citations
15 Claims
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1. A spacecraft cellular communication system, comprising:
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a spacecraft including a body; a receiving and frequency conversion arrangement mounted on said body, for receiving signals from terrestrial stations, and for converting signals received from terrestrial stations at specific frequencies within a first frequency band to other frequencies in a second frequency band, which second frequency band does not include said first frequency band; at least one antenna supported by said body, said antenna including an array of radiating elements and a first plurality of signal input ports coupled to said radiating elements of said array of radiating elements; a beamforming network mounted on said body, said beamforming network including plural input ports coupled to said receiving and frequency conversion arrangement, and a plurality of output ports coupled to said signal input ports of said antenna array, for receiving signals at said other frequencies within said second frequency band at said plural input ports, and for combining said signals at said other frequencies in a manner which, in combination with said antenna, generates a plurality of spot radiation beams directed toward the Earth'"'"'s surface, said spot radiation beams defining overlapping footprints, for transmitting signals at said other frequencies from said spacecraft to terrestrial user terminals located within said footprints; a fixed terrestrial terminal lying within the overlap region between at least first and second specific ones of said spot beams, for transmitting signals to said spacecraft at some of said specific frequencies within a first frequency range, for transmission of information signals to at least some of said terrestrial user terminals, whereby antenna positional errors may cause said spot beams to be misdirected; and an antenna positioning arrangement, said antenna positioning arrangement comprising; (a) beacon signal transmitting means located at said fixed terrestrial terminal, for transmitting beacon signals to said receiving and frequency conversion arrangement at a beacon frequency lying within said first frequency band, whereby said receiving and frequency conversion means converts said beacon signals lying within said first frequency band to beacon signals lying within said second frequency band; (b) coupling means coupled to said receiving and frequency conversion means and to at least one of said input ports of said beamforming network, for coupling said beacon signals to said beamforming network in a manner which generates said first and second specific ones of said spot beams in a temporal sequence; (c) beacon signal receiving means located at said fixed terrestrial terminal, for receiving said beacon signals at said second frequency band in said temporal sequence; (d) error determining means coupled to said beacon signal receiving means, for comparing characteristics of said beacon signals in said temporal sequence, to determine pointing error of said antenna; and (e) control means coupled to said error determining means, for generating control signals for tending to move said spot beams to a condition in which said beacon signals in said temporal sequence have a common value of at least one of said characteristics. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11)
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12. A spacecraft communication system, said system including:
transmit antenna means mounted on said spacecraft, for generating a plurality of transmit spot beams directed toward the Earth, each of which transmit spot beams defines a footprint which is in a first predetermined spatial relationship with others of said footprints of said transmit spot beams, each of said spot beams being for transmitting communications to at least user terminals located within that one of said footprints associated with said transmit spot beam; receive antenna means mounted on said spacecraft, for generating a like plurality of receive spot beams directed toward the Earth, each of which receive spot beams defines a footprint, which is ideally in said first predetermined spatial relationship with others of said footprints of said receive spot beams, but which plurality of receive spot beams may not be congruent with said plurality of transmit spot beams of said transmitting antenna, each of said receive spot beams of said receive antenna being for receiving communications from at least user terminals located within said footprint associated with said receive spot beam; control means coupled to said transmit antenna, for causing the footprints of at least some of said transmit spot beams to assume a second predetermined spatial condition relative to a location on the Earth, whereby the footprints of said plurality of transmit spot beams assume said first predetermined condition relative to each other and second predetermined spatial condition relative to said location on the Earth; and control means coupled to said receive antenna, for causing the footprints of at least some of said receive spot beams to assume said second predetermined spatial condition relative to said location on the Earth, in such a manner that said footprints of said plurality of receive spot beams assume said first predetermined spatial condition relative to each other and said second predetermined spatial condition relative to said location on the Earth, whereby said footprints of said spot beams of said transmit and receive antennas are congruous. - View Dependent Claims (13, 14, 15)
Specification
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Current AssigneeLockheed Martin Corporation (Martin Marietta Corporation)
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Original AssigneeLockheed Martin Corporation (Martin Marietta Corporation)
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InventorsProfera, Charles Edward Jr., Hawkes, Thaddeus Arthur, Kent, Edward Jay
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Primary Examiner(s)Patel, Ajit
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Assistant Examiner(s)Phunkulh, Bob A
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Application NumberUS08/986,611Time in Patent Office764 DaysField of Search370/310, 370/315, 370/316, 370/319, 370/320, 370/321, 370/322, 370/323, 370/324, 370/325, 370/326, 370/328, 370/331, 370/336, 370/337, 370/345, 370/347, 370/348, 455/11.1, 455/12.1, 455/13.1, 455/422, 455/427, 455/428US Class Current370/316CPC Class CodesH04B 7/2041 Spot beam multiple access
