Method and system for transceiving signals using a constellation of satellites in close geosynchronous orbit
First Claim
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1. A system for transmitting a video signal to a terrestrial user via a main satellite within a constellation of satellites, which includes at least two pairs of satellites adjacent to the main satellite and spaced at regular angular intervals relative to the terrestrial user, comprising:
- a) an analog to digital converter converting the video signal to a digital signal;
b) a data compressor being coupled to the analog to digital converter and compressing the digital signal to form a compressed digital signal;
c) a shaped frequency shift keyed modulator being coupled to the data compressor and modulating the compressed digital signal into a wideband analog shaped frequency shift keyed signal that contains 3 to 8 dB of coding gain;
d) a satellite transmitter being coupled to the shaped frequency shift keyed modulator and outputting a wideband RF signal;
e) a satellite antenna radiating the wideband RF signal to the main satellite within the constellation of satellites, which wideband RF signal is retransmitted by the main satellite back to earth;
f) a terrestrial antenna receiving the wideband RF signal, outputting a received signal, and having a diameter such that a beamwidth of the terrestrial antenna encompasses the main satellite and the at least the two pairs of adjacent satellites in the constellation;
g) a shaped frequency shift keyed demodulator being coupled to the terrestrial antenna and demodulating the received signal into a received compressed digital signal;
h) a data decompressor being coupled to the shaped frequency shift keyed demodulator and converting the received compressed digital signal into a received digital signal; and
i) a digital to analog converter being coupled to the data decompressor and converting the received digital signal into a received video signal available to the user, wherein the terrestrial antenna further comprises;
(i) a central reflector;
(ii) a first side reflector;
(iii) a second side reflector;
(iv) a first gap between the central reflector and the first side reflector; and
(v) a second gap between the central reflector and the second side reflector, wherein said first and second gaps create at least two pairs of nulls in received energy, which two nulls inhibit signals being transmitted from said at least two pairs of adjacent satellites in the constellation.
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Abstract
A C-Band or Ku-Band satellite communication system uses a relatively small receiving antenna while operating within current FCC designated bandwidth and using existing satellite configurations. Aperture synthesis techniques create nulls in orbit locations from which potential interference is expected. Bandwidth inefficient modulation techniques reduce transmission power flux density. Video compression reduces the power necessary to transmit video information. These three features make possible a receiving antenna with a receiving area equivalent to that of a three foot diameter dish, at C-Band frequencies. Comparable reductions are possible for Ku-, Ka-, Sand L-Band systems. Compressing the data reduces the required transmitted power by a factor of ten. Spreading the bandwidth reduces the power density below the FCC limitation. However, reducing the antenna diameter increases the beam width of the antenna, hence, the smaller antenna can no longer discriminate between adjacent C-Band satellites in their current orbital configuration. By designing the receiving antenna with nulls in orbital locations where potentially interfering satellites would be located, the small antenna avoids this interference. The same general technique is possible for a Ku-Band Antenna system. The FCC power limits are higher at Ku-Band than C-Band, however, losses due to rain absorption and thermal noise are higher at Ku-Band frequencies. Nevertheless, equivalent size savings on Ku-Band antennas are possible with the combination of the above techniques, when tailored for the Ku-Band environment.
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Citations
10 Claims
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1. A system for transmitting a video signal to a terrestrial user via a main satellite within a constellation of satellites, which includes at least two pairs of satellites adjacent to the main satellite and spaced at regular angular intervals relative to the terrestrial user, comprising:
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a) an analog to digital converter converting the video signal to a digital signal; b) a data compressor being coupled to the analog to digital converter and compressing the digital signal to form a compressed digital signal; c) a shaped frequency shift keyed modulator being coupled to the data compressor and modulating the compressed digital signal into a wideband analog shaped frequency shift keyed signal that contains 3 to 8 dB of coding gain; d) a satellite transmitter being coupled to the shaped frequency shift keyed modulator and outputting a wideband RF signal; e) a satellite antenna radiating the wideband RF signal to the main satellite within the constellation of satellites, which wideband RF signal is retransmitted by the main satellite back to earth; f) a terrestrial antenna receiving the wideband RF signal, outputting a received signal, and having a diameter such that a beamwidth of the terrestrial antenna encompasses the main satellite and the at least the two pairs of adjacent satellites in the constellation; g) a shaped frequency shift keyed demodulator being coupled to the terrestrial antenna and demodulating the received signal into a received compressed digital signal; h) a data decompressor being coupled to the shaped frequency shift keyed demodulator and converting the received compressed digital signal into a received digital signal; and i) a digital to analog converter being coupled to the data decompressor and converting the received digital signal into a received video signal available to the user, wherein the terrestrial antenna further comprises; (i) a central reflector; (ii) a first side reflector; (iii) a second side reflector; (iv) a first gap between the central reflector and the first side reflector; and (v) a second gap between the central reflector and the second side reflector, wherein said first and second gaps create at least two pairs of nulls in received energy, which two nulls inhibit signals being transmitted from said at least two pairs of adjacent satellites in the constellation. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
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9. A system for transmitting a video signal to a terrestrial user via a main satellite within a constellation of satellites, which includes at least two pairs of satellites adjacent to the main satellite and spaced at regular angular intervals relative to the terrestrial user, comprising:
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a) an analog to digital converter converting the video signal to a digital signal; b) a data compressor being coupled to the analog to digital converter and compressing the digital signal to form a compressed digital signal; c) a shaped frequency shift keyed modulator being coupled to the data compressor and modulating the compressed digital signal into a wideband analog shaped frequency shift keyed signal that contains 3 to 8 dB of coding gain; d) a satellite transmitter being coupled to the shaped frequency shift keyed modulator and outputting a wideband RF signal; e) a satellite antenna radiating the wideband RF signal to the main satellite, which wideband RF signal is retransmitted by the main satellite back to earth; f) a terrestrial antenna receiving the wideband RF signal, outputting a received signal, having a diameter such that a beamwidth of the terrestrial antenna encompasses the main satellite and the at least two pairs of adjacent satellites in the constellation, and including an irregularly shaped contour that provides normal gain for a signal from the main satellite and low gain nulls for signals from the at least two pairs of adjacent satellites, wherein the low gain nulls prevent signals being transmitted from the at least two pairs of adjacent satellites from interfering with a signal being transmitted from the main satellite; g) a shaped frequency shift keyed demodulator being coupled to the terrestrial antenna and demodulating the received signal into a received compressed digital signal; h) a data decompressor being coupled to the shaped frequency shift keyed demodulator and converting the received compressed digital signal into a received digital signal; and i) a digital to analog converter being coupled to the data decompressor and converting the received digital signal into a received video signal available to the user, wherein the irregularly shaped contour of the terrestrial antenna has at least three primary areas separated by effective gaps, each gap having a width that is a function of the regular angular intervals of the constellation of satellites. - View Dependent Claims (10)
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Specification
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Current AssigneeDatasec Corporation
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Original AssigneeTerrastar, Inc.
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InventorsLusignan, Bruce B.
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Primary Examiner(s)Chin, Wellington
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Assistant Examiner(s)SOBUTKA, PHILIP
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Application NumberUS08/781,158Time in Patent Office929 DaysField of Search455/3.2, 455/12.1, 455/13.1, 455/13.2, 455/13.3, 455/25, 455/63, 455/66, 455/562, 455/269, 455/272, 455/276.1, 455/278.1, 455/279.1, 455/280, 455/286, 455/288 , 455/290, 375/272, 343/758, 343/840, 343/781 R, 343/912, 343/914US Class Current455/12.1CPC Class CodesH01Q 13/02 Waveguide hornsH01Q 19/12 wherein the surfaces are co...H01Q 19/13 the primary radiating sourc...H01Q 19/132 Horn reflector antennas; Of...H01Q 19/17 the primary radiating sourc...H01Q 21/24 Combinations of antenna uni...H01Q 21/28 Combinations of substantial...H01Q 25/00 Antennas or antenna systems...H01Q 3/26 varying the relative phase ...H04B 7/18517 Transmission equipment in e...H04B 7/1858 Arrangements for data trans...H04B 7/18597 Arrangements for system phy...H04H 40/90 specially adapted for satel...Y02D 30/70 in wireless communication n...
