ESTABLISHMENT AND MAINTENANCE OF OPTICAL LINKS BETWEEN OPTICAL TRANSCEIVER NODES IN FREE-SPACE OPTICAL COMMUNICATIONS NETWORKS
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Accused Products
Abstract
A system and method for establishing and maintaining optical links between optical transceiver nodes in a free space optical communications network is disclosed. The system and method provide a protocol for acquisition of an optical link between transceivers in two adjacent nodes and for re-acquisition should a node be replaced or moved. The system and method also provide a protocol for tracking small movements of one or both nodes in a link. Also, the system and method provide a protocol for recovering a link that is temporarily lost.
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Citations
34 Claims
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1-18. -18. (canceled)
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19. A system for establishing and maintaining optical links between optical transceiver nodes in a free space optical communication network, the system comprising:
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a first fixed position node at a first location, the first fixed position node including a transmitter and a first receiver; and
a second fixed position node at a second location including a second receiver and a retro-reflector configured to receive an optical signal transmitted by the transmitter and to reflect the optical signal to the receiver;
wherein the first fixed position node is configured to;
transmit a plurality of optical signals from the transmitter towards the retro reflector, wherein transmitting includes a step-wise movement of the transmitter between transmissions of each of the plurality of optical signals;
receive, at the first receiver, a reflection for one or more of the optical signals transmitted toward the retro reflector;
measure received power for each of the received reflections; and
determine whether a communications link is established between the first and second fixed position nodes based on at least the received power measurements. - View Dependent Claims (20, 21)
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22. A node for use in a free space optical communication network, the node comprising:
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a pointing mechanism configured to adjust an azimuth angle and an elevation angle;
a first turret having an optical transmitter and an optical receiver and mounted on said pointing mechanism; and
a turret task module comprising;
an acquisition module configured to command said pointing mechanism to adjust said azimuth angle and said elevation angle until a response signal from a second remote turret is received, establishing an optical communication link between said first turret and said second remote turret, a retro reflector module configured to command said pointing mechanism to scan in a step-wise manner through an uncertainty region and transmit a plurality of optical signals toward a retro reflector on the second remote turret during said scanning, wherein the retro reflector module is further configured to command the node to measure received power for one or more reflections of the plurality of optical signals received by the optical receiver, and wherein the retro reflector module is configured to determine whether a communications link is established between the first turret and the second remote turret based on at least the received power measurements. - View Dependent Claims (23, 24, 25)
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26. A node for use in a free space optical communication network, the node comprising:
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a first node head having a first optical transmitter and a first optical receiver, a first pointing mechanism configured to adjust a first azimuth angle and a first elevation angle of said first node head;
a second node head having a second optical transmitter and a second optical receiver, a second pointing mechanism configured to adjust a second azimuth angle and a second elevation angle of said second node head;
wherein each of the first node and the second node is configured to;
transmit a plurality of optical signals from its respective transmitter towards a retro reflector on a corresponding remote node, wherein transmitting includes a step-wise movement of the respective transmitter between transmissions of each of the plurality of optical signals;
receive, at its respective receiver, a reflection for one or more of the optical signals transmitted toward the retro reflector of its corresponding remote node;
measure received power for each of the received reflections; and
determine whether a communications link is established with the corresponding remote node based on at least the received power measurements. - View Dependent Claims (27, 28)
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29. A node for use in a free space optical communication network, the node comprising;
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a first turret having an optical transmitter and an optical receiver and mounted on a pointing mechanism; and
a retro reflector module configured to, when the node is operating in a retro reflector mode, command said pointing mechanism to scan in a step-wise manner through an uncertainty region and transmit a plurality of optical signals toward a retro reflector on the second remote turret during said scanning, wherein the retro reflector module is further configured to command the node to measure received power for one or more reflections of the plurality of optical signals received by the optical receiver, and wherein the retro reflector module is configured to determine whether a communications link is established between the first turret and the second remote turret based on at least the received power measurements. - View Dependent Claims (30)
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31. A system for establishing and maintaining optical links between optical transceiver nodes in a free space optical communication network, the system comprising:
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a first node including a first transmitter, and a first receiver; and
a second node including a second transmitter, a second receiver, and a retro reflector;
wherein the first node is configured to;
transmit a plurality of optical signals from the first transmitter towards the retro reflector, wherein transmitting includes a step-wise movement of the first transmitter between transmissions of each of the plurality of optical signals;
receive, at the first receiver, a reflection of one or more of the optical signals transmitted toward the retro reflector;
measure received power for each of the received reflections; and
determine whether a communications link is established between the first and second fixed position nodes based on at least the received power measurements. - View Dependent Claims (32, 33)
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34. A method comprising:
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transmitting a plurality of optical signals from a transmitter on first node to a retro reflector on a second node, wherein said transmitting includes a step-wise movement of the transmitter through a first uncertainty region between transmissions of each of the plurality of optical signals;
receiving reflections from one or more of the plurality of optical signals at a first receiver located on the first node;
measuring power of each of the received reflections;
terminating transmission of the plurality of optical signals;
generating a transmit beam from the first node;
directing the transmit beam to a second receiver of the second node;
scanning the second receiver, wherein said scanning includes step-wise movement of the receiver through a second uncertainty region;
performing a power measurement for each step of said scanning, wherein the power measurement is indicative of the power of the transmit beam as received by the second receiver; and
terminating said scanning responsive to the second node receiving an indication that a communication link between the first node and the second node has been established.
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Specification
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Current AssigneeKiribati Wireless Ventures LLC (Intellectual Ventures LLC)
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Original AssigneeKiribati Wireless Ventures LLC (Intellectual Ventures LLC)
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InventorsPavelchek, Andrew
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Application NumberUS11/764,576Publication NumberTime in Patent OfficeDaysField of SearchUS Class Current398/158CPC Class CodesH04B 10/1123 Bidirectional transmission
