Satellite system that produces optical inter-satellite link (ISL) beam based on optical feeder uplink beam
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
H04B-007/185
H04B-010/118
H04J-014/02
출원번호
US-0461369
(2017-03-16)
등록번호
US-9979465
(2018-05-22)
발명자
/ 주소
Hreha, William
Turgeon, Ghislain
Gallagher, Vijaya
출원인 / 주소
SPACE SYSTEMS/LORAL, LLC
대리인 / 주소
Vierra Magen Marcus LLP
인용정보
피인용 횟수 :
1인용 특허 :
6
초록▼
Described herein is a space based subsystem of a satellite, and methods for use therewith, for producing and transmitting an optical ISL beam to another satellite. The subsystem can include, inter alia, receiver optics, optical amplifiers, a WDM demultiplexer, beam splitters, a WDM multiplexer, and
Described herein is a space based subsystem of a satellite, and methods for use therewith, for producing and transmitting an optical ISL beam to another satellite. The subsystem can include, inter alia, receiver optics, optical amplifiers, a WDM demultiplexer, beam splitters, a WDM multiplexer, and transmitter optics. The transmitter optics may be configured to receive an amplified wavelength division multiplexed optical signal and, in dependence thereon, transmit an optical ISL beam to another satellite. In certain embodiments, because RF frequencies of a wavelength division multiplexed optical signal produced by the WDM multiplexer are within a same specified RF frequency range within which the other satellite is configured to transmit RF service downlink beams, there is an elimination of any need for the other satellite to perform any frequency conversions when producing the RF service downlink beams in dependence on the optical ISL beam.
대표청구항▼
1. A space based subsystem of a satellite, the space based subsystem comprising: receiver optics configured to receive an optical feeder uplink beam from a ground based subsystem and output an optical feeder uplink signal;a first optical amplifier optically coupled to the receiver optics and configu
1. A space based subsystem of a satellite, the space based subsystem comprising: receiver optics configured to receive an optical feeder uplink beam from a ground based subsystem and output an optical feeder uplink signal;a first optical amplifier optically coupled to the receiver optics and configured to amplify the optical feeder uplink signal that is output from the receiver optics;a wavelength-division multiplexing (WDM) demultiplexer optically coupled to the optical amplifier and configured to demultiplex and thereby separate the amplified optical feeder uplink signal, which is output from the first optical amplifier, into a plurality of separate optical signals that each have a different peak wavelength within a specified optical wavelength range;a plurality of beam splitters, each of which is configured to split a respective one of at least a subset of the separate optical signals that are output from the WDM demultiplexer into a respective pair of optical signals, the beam splitters thereby collectively configured to produce a plurality of separate pairs of optical signals that each have a different peak wavelength within the specified optical wavelength range, with the optical signals of a same pair having the same peak wavelength;a WDM multiplexer configured to receive one of the optical signals of each of the separate pairs of optical signals, and thereby receive a plurality of optical signals that each have a different peak wavelength within the specified optical wavelength range, and configured to multiplex and thereby combine the received optical signals onto a single optical fiber on which each of the optical signals are carried at a same time on its own separate optical wavelength within the specified optical wavelength range as a wavelength division multiplexed optical signal;a second optical amplifier optically coupled to the single optical fiber and configured to amplify the wavelength division multiplexed optical signal that is output by the WDM multiplexer; andtransmitter optics configured to receive the amplified wavelength division multiplexed optical signal and, in dependence therein, transmit an optical inter-satellite link (ISL) beam to another satellite. 2. The subsystem of claim 1, wherein because RF frequencies of the wavelength division multiplexed optical signal are within a same specified RF frequency range within which the other satellite is configured to transmit a plurality of RF service downlink beams, there is an elimination of any need for the other satellite to perform any frequency conversions when producing the plurality of RF service downlink beams in dependence on the optical ISL beam. 3. The subsystem of claim 1, further comprising filters within signal paths between the beam splitters and the WDM multiplexer. 4. The subsystem of claim 1, wherein the specified optical wavelength range is either a contiguous, or a non-contiguous, optical wavelength range within an infrared (IR) spectrum. 5. The subsystem of claim 1, further comprising: a plurality of photodetectors, each of which is configured to receive the other one of the optical signals of each of the separate pairs of optical signals produced by the beam splitters, and thereby collectively receive a plurality of optical signals that each have a different peak wavelength within the specified frequency range, and each of the photodetectors configured to convert a different one of the optical signals to a respective electrical data signal having an RF frequency within a same specified RF frequency range within which the space based subsystem is configured to transmit a plurality of RF service downlink beams; andone or more RF components and antennas configured to produce and transmit, in dependence on the electrical data signals generated by the plurality of PDs, the plurality of RF service downlink beams within the specified RF frequency range;wherein because the RF frequencies of the electrical data signals output by the photodetectors are within the same specified RF frequency range within which the space based subsystem is configured to transmit the plurality of RF service downlink beams, there is an elimination of any need for the space based subsystem to perform any frequency conversions when producing the plurality of RF service downlink beams in dependence on the optical feeder uplink beam. 6. The subsystem of claim 5, further comprising filters within signal paths between the beam splitters and the photodetectors. 7. The subsystem of claim 5, wherein the specified optical wavelength range is either a contiguous, or a non-contiguous, optical wavelength range within an infrared (IR) spectrum. 8. The subsystem of claim 5, wherein the specified RF frequency range within which the satellite is configured to produce and transmit a plurality of RF service downlink beams comprises a downlink portion of the Ka band. 9. The subsystem of claim 8, wherein the downlink portion of the Ka band is from 17.7 GHz to 20.2 GHz, and thus, has a bandwidth of 2.5 GHz. 10. The subsystem of claim 8, wherein the downlink portion of the Ka band is from 17.3 GHz to 20.2 GHz, and thus, has a bandwidth of 2.9 GHz. 11. A space based subsystem of a satellite, the space based subsystem comprising: receiver optics configured to receive an optical feeder uplink beam from a ground based subsystem and output an optical feeder uplink signal;a first optical amplifier optically coupled to the receiver optics and configured to amplify the optical feeder uplink signal that is output from the receiver optics;a wavelength-division multiplexing (WDM) demultiplexer optically coupled to the first optical amplifier and configured to demultiplex and thereby separate the amplified optical feeder uplink signal, which is output from the optical amplifier, into a plurality of separate optical signals that each have a different peak wavelength within a specified optical wavelength range;a WDM multiplexer configured to receive a subset of the optical signals that each have a different peak wavelength within the specified optical wavelength range, and configured to multiplex and thereby combine the received subset of the optical signals onto a single optical fiber on which each of the optical signals are carried at a same time on its own separate optical wavelength within the specified optical wavelength range as a wavelength division multiplexed optical signal;a second optical amplifier optically coupled to the single optical fiber and configured to amplify the wavelength divisional multiplexed optical signal that is output by the WDM multiplexer;transmitter optics configured to receive the amplified wavelength divisional multiplexed optical signal and, in dependence therein, transmit an optical inter-satellite link (ISL) beam to another satellite;a plurality of photodetectors (PDs), each PD of the plurality of PDs configured to receive one of a further subset of the optical signals that each have a different peak wavelength within the specified optical wavelength range, and each PD of the plurality of PDs configured to convert a different one of the further subset of optical signals to a respective electrical data signal; andone or more RF components and antennas configured to produce and transmit, in dependence on the electrical data signals generated by the plurality of PDs, a plurality of RF service downlink beams. 12. The subsystem of claim 11, wherein RF frequencies of the wavelength division multiplexed optical signal are within a same specified RF frequency range within which the other satellite is configured to transmit a plurality of RF service downlink beams, and thus, there is an elimination of any need for the other satellite to perform any frequency conversions when producing the plurality of RF service downlink beams in dependence on the optical ISL beam. 13. The subsystem of claim 11, further comprising filters within signal paths between the WDM demultiplexer and the WDM multiplexer. 14. The subsystem of claim 11, wherein the specified optical wavelength range is either a contiguous, or a non-contiguous, optical wavelength range within an infrared (IR) spectrum. 15. The subsystem of claim 11, wherein RF frequencies of the electrical data signals output by the plurality of PDs are within a same specified RF frequency range within which the space based subsystem is configured to transmit the plurality of RF service downlink beams, and thus, there is an elimination of any need for the space based subsystem to perform any frequency conversions when producing the plurality of RF service downlink beams in dependence on the optical feeder uplink beam. 16. The subsystem of claim 15, wherein the specified RF frequency range within which the satellite is configured to produce and transmit a plurality of RF service downlink beams comprises a downlink portion of the Ka band. 17. The subsystem of claim 16, wherein the downlink portion of the Ka band is from 17.7 GHz to 20.2 GHz, and thus, has a bandwidth of 2.5 GHz. 18. The subsystem of claim 16, wherein the downlink portion of the Ka band is from 17.3 GHz to 20.2 GHz, and thus, has a bandwidth of 2.9 GHz. 19. The subsystem of claim 11, further comprising filters within signal paths between the WDM demultiplexer and the photodetectors. 20. The subsystem of claim 11, wherein the specified optical wavelength range is either a contiguous, or a non-contiguous, optical wavelength range within an infrared (IR) spectrum. 21. A method for use by a space based subsystem of a satellite, the method comprising: receiving an optical feeder uplink beam from a ground based subsystem;producing, in dependence on the received optical feeder uplink beam, a plurality of separate optical signals that each have a different peak wavelength within a specified optical wavelength range;splitting each of at least a subset of the separate optical signals into a respective pair of optical signals, and thereby producing separate pairs of optical signals that each have a different peak wavelength within the specified optical wavelength range, with the optical signals of a same pair having the same peak wavelength;multiplexing optical signals that each have a different peak wavelength within the specified optical wavelength range, the optical signals being multiplexed including one of the optical signals of each of the separate pairs of optical signals, to thereby produce a wavelength division multiplexed optical signal that includes data that is to be forwarded to another satellite so that the other satellite can transmit, in dependence thereon, a plurality of RF service downlink beams;producing an optical inter-satellite link (ISL) beam in dependence on the wavelength division multiplexed optical signal; andtransmitting the optical ISL beam through free-space to the other satellite;wherein because RF frequencies of the wavelength division multiplexed optical signal are within the same specified RF frequency range within which the other satellite is configured to transmit the plurality of RF service downlink beams, there is an elimination of any need for the other satellite to perform any frequency conversions when producing the plurality of RF service downlink beams in dependence on the optical ISL beam. 22. The method of claim 21, further comprising: converting each of a plurality of optical signals, that each have a different peak wavelength within the specified optical wavelength range, into a respective electrical data signal having an RF frequency within the same specified RF frequency range within which the space based subsystem is configured to transmit a plurality of RF service downlink beams, the optical signals being converted including the other one of the optical signals of each of the separate pairs of optical signals;producing, in dependence on the electrical data signals, the plurality of RF service downlink beams within the specified RF frequency range; andtransmitting the plurality of RF service downlink beams within the specified RF frequency range;wherein because the RF frequencies of the electrical data signals resulting from the converting are within the same specified RF frequency range within which the space based subsystem is configured to transmit the plurality of RF service downlink beams, there is an elimination of any need for the space based subsystem to perform any frequency conversions when producing the plurality of RF service downlink beams in dependence on the optical feeder uplink beam. 23. The method of claim 22, wherein the specified RF frequency range within which the satellite and the other satellite are configured to produce and transmit a plurality of RF service downlink beams comprises a downlink portion of the Ka band. 24. The method of claim 23, wherein: the downlink portion of the Ka band is from 17.7 GHz to 20.2 GHz, and thus, has a bandwidth of 2.5 GHz; orthe downlink portion of the Ka band is from 17.3 GHz to 20.2 GHz, and thus, has a bandwidth of 2.9 GHz. 25. The method of claim 21, wherein the specified optical wavelength range is either a contiguous, or a non-contiguous, optical wavelength range within an infrared (IR) spectrum. 26. A method for use by a space based subsystem of a satellite, the method comprising: receiving an optical feeder uplink beam from a ground based subsystem;producing, in dependence on the received optical feeder uplink beam, a plurality of separate optical signals that each have a different peak wavelength;multiplexing a first subset of the optical signals that each have a different peak wavelength within the specified optical wavelength range to thereby produce a wavelength division multiplexed optical signal that includes data that is to be forwarded to another satellite so that the other satellite can transmit, in dependence thereon, a plurality of RF service downlink beams;producing an optical inter-satellite link (ISL) beam, in dependence on the wavelength division multiplexed optical signal;transmitting the optical ISL beam through free-space to the other satellite;converting each optical signal of a second subset of the optical signals, that each have a different peak wavelength within the specified optical wavelength range, into a respective electrical data signal;producing, in dependence on the electrical data signals, a plurality of RF service downlink beams; andtransmitting the plurality of RF service downlink beams. 27. The method of claim 26, wherein: RF frequencies of the wavelength division multiplexed optical signal are within a same specified RF frequency range within which the other satellite is configured to transmit the plurality of RF service downlink beams, and thus, there is an elimination of any need for the other satellite to perform any frequency conversions when producing the plurality of RF service downlink beams in dependence on the optical ISL beam; andRF frequencies of the electrical data signals resulting from the converting are within a same specified RF frequency range within which the space based subsystem is configured to transmit the plurality of RF service downlink beams, and thus, there is an elimination of any need for the space based subsystem to perform any frequency conversions when producing the plurality of RF service downlink beams in dependence on the optical feeder uplink beam. 28. The method of claim 27, wherein the specified RF frequency range within which the satellite and the other satellite are configured to produce and transmit a plurality of RF service downlink beams comprises a downlink portion of the Ka band. 29. The method of claim 28, wherein: the downlink portion of the Ka band is from 17.7 GHz to 20.2 GHz, and thus, has a bandwidth of 2.5 GHz; orthe downlink portion of the Ka band is from 17.3 GHz to 20.2 GHz, and thus, has a bandwidth of 2.9 GHz. 30. The method of claim 26, wherein the specified optical wavelength range is either a contiguous, or a non-contiguous, optical wavelength range within an infrared (IR) spectrum. 31. A space based subsystem of a satellite, the space based subsystem comprising: receiver optics configured to receive at least one of an optical feeder uplink beam from a ground based gateway or an inter-satellite link (ISL) beam from another satellite;a first optical amplifier optically coupled to the receiver optics and configured to amplify an optical signal that is output from the receiver optics;a wavelength-division multiplexing (WDM) demultiplexer optically coupled to the optical amplifier and configured to demultiplex and thereby separate the amplified optical signal, which is output from the first optical amplifier, into N separate optical signals that each have a different peak wavelength within a specified optical wavelength range, wherein N is an integer that is greater than one; andan optical cross-connect switch downstream of the WDM demultiplexer and configured to receive M of the N separate optical signals output by the WDM demultiplexer, and configured to control how the M of the N separate optical signals that are received by the optical cross-connect switch are provided to signal paths downstream of the optical cross-connect switch, wherein M is an integer that is no greater than N. 32. The space based subsystem of claim 31, further comprising: a WDM multiplexer downstream of the optical cross-connect switch and configured to receive at least some of the M optical signals from the optical cross-connect switch and configured to multiplex and thereby combine the at least some of the M optical signals, received from the optical cross-connect switch, onto an optical fiber on which the at least some of the M optical signals are carried at a same time;a second optical amplifier optically coupled to the optical fiber and configured to amplify a wavelength division multiplexed optical signal that is output by the WDM multiplexer; andtransmitter optics configured to receive the amplified wavelength division multiplexed optical signal and, in dependence therein, transmit an optical inter-satellite link (ISL) beam to a further satellite. 33. The space based subsystem of claim 31, further comprising: one or more photodetectors downstream of the optical cross-connect switch, each of the photodetector(s) configured to receive one of the optical signals from the optical cross-connect switch and configured to convert the received one of the optical signals to a respective electrical data signal. 34. The space based subsystem of claim 33, further comprising: one or more RF components and antennas configured to produce and transmit, in dependence on the electrical data signals generated by at least one of the one or more photodetectors, one or more RF service downlink beams. 35. The space based subsystem of claim 34, further comprising: command and data handling equipment configured to receive at least one of the electrical data signals produced by the one or more photodetectors and configured to use the electrical data signal(s) to control at least one aspect of a satellite carrying the space based subsystem or of a payload being carried by the satellite.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (6)
Ionov, Stanislav I.; Acampora, Anthony S., Global gateway architecture for interconnecting regional satellites into a communication network.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.