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Simultaneous bidirectional wireless link

專利號(hào)
US10791581B2
公開日期
2020-09-29
申請(qǐng)人
Facebook, Inc.(US CA Menlo Park)
發(fā)明人
Djordje Tujkovic; Krishna Gomadam; Sanjai Kohli
IPC分類
H04W76/10; H04B7/06
技術(shù)領(lǐng)域
node,sector,second,beam,link,first,signal,wireless,antennas,settings
地域: CA CA Menlo Park

摘要

Apparatuses, methods, and systems of a node that supports a simultaneous bidirectional wireless link with a second node are disclosed. One embodiment of the node includes a first transceiver operative to form a beam directed to a first sector of a second node, and a second transceiver operative to form a beam directed to a second sector of the second node, wherein for at least some time slots a simultaneous bidirectional wireless link is formed between the node and the second node by the one of the first transceiver or the second transceiver transmitting a first communication signal to the second node while the other of the first transceiver or the second transceiver is receiving a second communication signal from the second node, and selecting between forming the simultaneous bidirectional wireless link or a non-simultaneous bidirectional wireless link based on a throughput or a link quality.

說(shuō)明書

RELATED APPLICATIONS

This patent application is a continuation of U.S. patent application Ser. No. 15/196,340, filed Jun. 29, 2016, which is herein incorporated by reference.

FIELD OF THE DESCRIBED EMBODIMENTS

The described embodiments relate generally to wireless communications. More particularly, the described embodiments relate to systems, methods and apparatuses of a simultaneous bidirectional wireless link.

BACKGROUND

Transmission and reception of communication between a node and another node on a common channel of a wireless network are typically time division duplexed to reduce interference between transmitted are receive communication signals.

It is desirable to have methods apparatuses, and systems for a simultaneous bidirectional (transmission and reception) wireless link.

SUMMARY

權(quán)利要求

1
What is claimed:1. A node, comprising:a first sector comprising a first transceiver operative to form a beam directed to a first sector of a second node;a second sector comprising a second transceiver operative to form a beam directed to a second sector of the second node;wherein for at least some time slots a simultaneous bidirectional wireless link is formed between the node and the second node by the one of the first transceiver or the second transceiver transmitting a first communication signal to the second node while the other of the first transceiver or the second transceiver is receiving a second communication signal from the second node;wherein a controller is operative to:determine a throughput load of the first node or the second node, or a link quality between the first node and the second node; andselect between forming the simultaneous bidirectional wireless link or a non-simultaneous bidirectional wireless link based on the throughput or the link quality.2. The node of claim 1, wherein for at least one time slot of the plurality of time slots, the first transceiver transmits a communication signal to the second node while the second transceiver receives a communication signal from the second node, and for at least one other time slot of the plurality of time slots the first transceiver receives a communication signal from the second node while the second transceiver transmits a communication signal to the second node.3. The node of claim 1, wherein time slots of transmission of the first communication signal are synchronized with time slots of reception of the second communication signal.4. The node of claim 1, wherein the node is further operative to select between the simultaneous bidirectional wireless link formed between the node and the second node or communication between the node and a third node, comprising:the node operative to form the simultaneous bidirectional wireless link between the node and the second node for a first period of time; andthe node operative to establish a second link between the node and the third node for a second period of time.5. The node of claim 4, wherein establishing the second link between the node and the third node comprises:for at least one time slot of a plurality of time slots of the second period of time, one of the first transceiver or the second transceiver transmitting a third communication signal to the third node while the other of the first transceiver or the second transceiver is receiving a fourth communication signal from the third node.6. The node of claim 4, wherein the node is further operative to select between the simultaneous bidirectional wireless link between the node and the second node or the non-simultaneous bidirectional wireless link between the node and the second node, comprising:the node operative to form the simultaneous bidirectional wireless link between the node and the second node for a first period of time; andthe node operative to form the non-simultaneous bidirectional wireless link between the node and the second node for a second period of time.7. The node of claim 1, wherein node forms a plurality of directional beams directed to a plurality of transceivers of the second node.8. The node of claim 1, wherein node forms a single directional beam directed to a plurality of transceivers of the second node.9. The node of claim 1, wherein the node is further operative to:self-characterize itself comprising the node operative to:transmit a signal through a predetermined transmission channel at each of a first plurality of transmit beam forming settings of the first plurality of antennas;receive the signal through the predetermined channel at a second plurality of receive beam forming settings of the second plurality of antennas, for each of more than one of the first plurality of transmit beam forming settings of the first plurality of antennas;measure a received signal quality of the received signal at each of the second plurality of receive beam forming settings of the second plurality of antennas, for each of the more than one of the first plurality of transmit beam forming settings of the first plurality of antennas; whereinthe node is further operative to:generate an interference cancellation signal for at least one of pairs of transmit beam forming settings and receive beam forming settings based at least in part on characterized received signal qualities of the self-characterization of the node; andsum the interference cancellation signal with a signal received while the simultaneous bidirectional wireless link is formed between the node and the second node.10. The node of claim 1, wherein the node is further operative to:self-characterize itself comprising the node operative to:transmit a signal through a predetermined transmission channel at each of a first plurality of transmit beam forming settings of the first plurality of antennas;receive the signal through the predetermined channel at a second plurality of receive beam forming settings of the second plurality of antennas, for each of more than one of the first plurality of transmit beam forming settings of the first plurality of antennas;measure a received signal quality of the received signal at each of the second plurality of receive beam forming settings of the second plurality of antennas, for each of the more than one of the first plurality of transmit beam forming settings of the first plurality of antennas; whereinthe node is further operative to:select a transmit beam forming setting and a receive beam forming setting between the node and the second node, wherein the selection is based on the measure received signal quality measurements that correspond with each of the transmit beam forming settings and the receive beam forming setting between the node and the second node.11. A method, comprising:forming a first beam directed to a first sector of a second node by a first plurality of antennas of a first sector of a first transceiver of a node;forming a second beam directed to a second sector of the second node by a second plurality of antennas of a second sector of a second transceiver of the node;forming for at least some time slots a simultaneous bidirectional wireless link between the node and the second node by the one of the first transceiver or the second transceiver transmitting a first communication signal to the second node while the other of the first transceiver or the second transceiver is receiving a second communication signal from the second node;determining a throughput load of the first node or the second node, or a link quality between the first node and the second node; andselecting between forming the simultaneous bidirectional wireless link or a non-simultaneous bidirectional wireless link based on the throughput or the link quality.12. The method of claim 11, wherein for at least one time slot of the plurality of time slots, the first transceiver transmits a communication signal to the second node while the second transceiver receives a communication signal from the second node, and for at least one other time slot of the plurality of time slots the first transceiver receives a communication signal from the second node while the second transceiver transmits a communication signal to the second node.13. The method of claim 11, wherein time slots of transmission of the first communication signal are synchronized with time slots of reception of the second communication signal.14. The method of claim 11, further comprising:selecting, by the node, between the simultaneous bidirectional wireless link formed between the node and the second node or communication between the node and a third node, comprising:forming, by the node, the simultaneous bidirectional wireless link between the node and the second node for a first period of time; andestablishing, by the node, a second link between the node and the third node for a second period of time.15. The method of claim 14, wherein establishing the second link between the node and the third node comprises:for at least one time slot of a plurality of time slots of the second period of time, one of the first transceiver or the second transceiver transmitting a third communication signal to the third node while the other of the first transceiver or the second transceiver is receiving a fourth communication signal from the third node.16. The method of claim 14, wherein the node is further operative to select between the simultaneous bidirectional wireless link between the node and the second node or the non-simultaneous bidirectional wireless link between the node and the second node, comprising:the node operative to form the simultaneous bidirectional wireless link between the node and the second node for a first period of time; andthe node operative to form the non-simultaneous bidirectional wireless link between the node and the second node for a second period of time.17. The method of claim 14, wherein wherein node forms a plurality of directional beams directed to a plurality of transceivers of the second node.18. The method of claim 14, wherein wherein node forms a single directional beam directed to a plurality of transceivers of the second node.19. The method of claim 14, further comprising:self-characterizing, by the node, comprising;transmitting, by the node, a signal through a predetermined transmission channel at each of a first plurality of transmit beam forming settings of the first plurality of antennas;receiving, by the node, the signal through the predetermined channel at a second plurality of receive beam forming settings of the second plurality of antennas, for each of more than one of the first plurality of transmit beam forming settings of the first plurality of antennas;measuring, by the node, a received signal quality of the received signal at each of the second plurality of receive beam forming settings of the second plurality of antennas, for each of the more than one of the first plurality of transmit beam forming settings of the first plurality of antennas;generating, by the node, an interference cancellation signal for at least one of pairs of transmit beam forming settings and receive beam forming settings based at least in part on characterized received signal qualities of the self-characterization of the node; andsumming, by the node, the interference cancellation signal with a signal received while the simultaneous bidirectional wireless link is formed between the node and the second node.20. The method of claim 14, further comprising:self-characterizing, by the node, comprising:transmitting, by the node, a signal through a predetermined transmission channel at each of a first plurality of transmit beam forming settings of the first plurality of antennas;receiving, by the node, the signal through the predetermined channel at a second plurality of receive beam forming settings of the second plurality of antennas, for each of more than one of the first plurality of transmit beam forming settings of the first plurality of antennas;measuring, by the node, a received signal quality of the received signal at each of the second plurality of receive beam forming settings of the second plurality of antennas, for each of the more than one of the first plurality of transmit beam forming settings of the first plurality of antennas; whereinselecting, by the node, a transmit beam forming setting and a receive beam forming setting between the node and the second node, wherein the selection is based on the measure received signal quality measurements that correspond with each of the transmit beam forming settings and the receive beam forming setting between the node and the second node.
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