Proactive MIMO relaying in wireless communications
First Claim
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1. A wireless network apparatus configured for simultaneously relaying communications between multiple wireless radio nodes, comprising:
- a central coordinator radio node which is configured for multiple-input-multiple-output (MIMO) communications over a wireless network communicating with the multiple wireless radio nodes which include at least one access point (AP);
wherein said wireless radio nodes comprise a combination of first category radio nodes and second category radio nodes, in which the first category nodes support multiple-input-multiple-output (MIMO) communications, and in which the second category radio nodes do not support MIMO;
wherein said central coordinator radio node performs selection of one of said radio nodes within said multiple wireless radio nodes as a relay node between at least one said AP and any one of said radio nodes within said multiple wireless radio nodes based on communication characteristics, including category of radio node, signal strength and estimated air time;
wherein said AP utilizes a relaying service period (SP) within a superframe structure which contains multiple training and data transmission frames;
wherein said AP initiates a simultaneous relay link setup (RLS) process with two or more of said plurality of radio nodes within said multiple wireless radio nodes toward decreasing RLS messaging overhead;
wherein data communications is performed between the AP and a destination radio node through the selected relay node in response to making a MIMO hop from said AP to the selected relay node, followed by a multi-user (MU) MIMO hop from the selected relay node and the destination radio node; and
wherein fields in said relaying service period (SP) comprise;
(a) beamforming (BF) refinement between AP and the relay node;
(b) a channel state information metric is fed back by the relay node for MIMO operation;
(c) BF training is performed between the relay node and a first station (STA 1) including transmitter (Tx) and receiver (Rx) sector training;
(d) BF training is performed between the relay node and a second station (STA 2) including Tx and Rx sector training;
(e) a probing sequence is performed from the relay node to STA 1;
(f) a channel state information metric is fed back by STA 1;
(g) a probing sequence is performed from the relay node to STA 2;
(h) a channel state information metric is fed back by STA 2;
(i) simultaneous pilot transmissions are performed by STA 1 and STA 2 for inter-user interference estimation by the relay;
(j) data is transmitted between the AP and the relay node using MIMO; and
(k) data is transmitted from the relay node to STA 1 and STA 2 using multiple-user (MU) MIMO.
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Abstract
A wireless communication system with directional transmission for simultaneously relaying communications between an access point (AP) and multiple radio nodes in the network which are in a first category that supports multiple-input-multiple-output (MIMO) capability, or a second category having different signal processing capabilities. Utilizing a superframe, which is a modification of an existing protocol, a relaying service period (SP) controls multiple simultaneous training and data transmission frames. The AP selects a relay device from the radio nodes based on metrics selected from signal strength, estimation of air time, category of radio node, AoA/AoD, power connectivity. This allows data to be communicated in a MIMO hop from said AP to the selected relay device, with a multi-user (MU) MIMO hop from the selected relay device and a destination radio node (client).
16 Citations
20 Claims
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1. A wireless network apparatus configured for simultaneously relaying communications between multiple wireless radio nodes, comprising:
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a central coordinator radio node which is configured for multiple-input-multiple-output (MIMO) communications over a wireless network communicating with the multiple wireless radio nodes which include at least one access point (AP); wherein said wireless radio nodes comprise a combination of first category radio nodes and second category radio nodes, in which the first category nodes support multiple-input-multiple-output (MIMO) communications, and in which the second category radio nodes do not support MIMO; wherein said central coordinator radio node performs selection of one of said radio nodes within said multiple wireless radio nodes as a relay node between at least one said AP and any one of said radio nodes within said multiple wireless radio nodes based on communication characteristics, including category of radio node, signal strength and estimated air time; wherein said AP utilizes a relaying service period (SP) within a superframe structure which contains multiple training and data transmission frames; wherein said AP initiates a simultaneous relay link setup (RLS) process with two or more of said plurality of radio nodes within said multiple wireless radio nodes toward decreasing RLS messaging overhead; wherein data communications is performed between the AP and a destination radio node through the selected relay node in response to making a MIMO hop from said AP to the selected relay node, followed by a multi-user (MU) MIMO hop from the selected relay node and the destination radio node; and wherein fields in said relaying service period (SP) comprise;
(a) beamforming (BF) refinement between AP and the relay node;
(b) a channel state information metric is fed back by the relay node for MIMO operation;
(c) BF training is performed between the relay node and a first station (STA 1) including transmitter (Tx) and receiver (Rx) sector training;
(d) BF training is performed between the relay node and a second station (STA 2) including Tx and Rx sector training;
(e) a probing sequence is performed from the relay node to STA 1;
(f) a channel state information metric is fed back by STA 1;
(g) a probing sequence is performed from the relay node to STA 2;
(h) a channel state information metric is fed back by STA 2;
(i) simultaneous pilot transmissions are performed by STA 1 and STA 2 for inter-user interference estimation by the relay;
(j) data is transmitted between the AP and the relay node using MIMO; and
(k) data is transmitted from the relay node to STA 1 and STA 2 using multiple-user (MU) MIMO. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8)
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9. A method for implementing a wireless network apparatus configured for simultaneously relaying communications between multiple wireless radio nodes on the network, comprising the steps of:
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configuring the multiple wireless radio nodes as a combination of a first category of radio nodes which supports multiple-input-multiple-output (MIMO) communications, and a second category of radio nodes which does not support MIMO communications; wherein at least one of said radio nodes is an Access Point (AP) configured as a first category of radio nodes for MIMO communication; selecting a radio node as a relay node between said AP and any one of said radio nodes, within the multiple wireless radio nodes, based on communication characteristics, which include signal strength and air time considerations, whereby said first category radio nodes have an increased probability of selection since they consume less air time because of their multiplexed communications than said second category of radio nodes; relaying is performed in response to a MIMO hop from the AP to the selected relay node, followed by a multi-user (MU) MIMO hop from the relay node to said radio node which is a destination radio node (client); and modifying relaying service period (SP) within a superframe structure utilized in said method to contain multiple training and data transmission frames; wherein MIMO capability of radio nodes is exploited to provide spectrally-efficient relaying between radio nodes and the AP; and wherein fields in said relaying service period (SP) comprise;
(a) beamforming (BF) refinement between AP and the relay node;
(b) a channel state information metric is fed back by the relay node for MIMO operation;
(c) BF training is performed between the relay node and a first station (STA 1) including transmitter (Tx) and receiver (Rx) sector training;
(d) BF training is performed between the relay node and a second station (STA 2) including Tx and Rx sector training;
(e) a probing sequence is performed from the relay node to STA 1;
(f) a channel state information metric is fed back by STA 1;
(q) a probing sequence is performed from the relay node to STA 2;
(h) a channel state information metric is fed back by STA 2;
(i) simultaneous pilot transmissions are performed by STA 1 and STA 2 for inter-user interference estimation by the relay node;
(j) data is transmitted between the AP and the relay node using MIMO; and
(k) data is transmitted from the relay node to STA 1 and STA 2 using multiple-user (MU) MIMO. - View Dependent Claims (10, 11, 12, 13, 14)
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15. A wireless Access Point (AP) apparatus for a wireless network configured for simultaneously relaying communications between multiple wireless radio nodes on the network, comprising:
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(a) an access point (AP) configured for performing simultaneous communications using multiple-input-multiple-output (MIMO) capability to communicate in the network of the multiple wireless radio nodes with a first category of radio nodes which support MIMO, or a second category of radio nodes which does not support MIMO; (b) a computer processor in said AP; (c) a non-transitory computer-readable memory storing instructions executable by said computer processor in said AP; (d) wherein said instructions, when executed by the computer processor, perform steps comprising; (i) selecting a relay device from the multiple wireless radio nodes based on at least signal strength metrics and an estimation of air time requirements; (ii) utilizing a relaying service period (SP) within a superframe structure which contain multiple training and data transmission frames; (iii) performing relay link setup (RLS) to two or more radio nodes within the multiple wireless radio nodes simultaneously which decreases RLS messaging overhead; (e) relaying data communications in response to a MIMO hop from said AP to the selected relay device, followed by a multi-user (MU) MIMO hop from the selected relay device and a destination radio node (client); and (f) wherein fields in said relaying service period (SP) comprise;
(a) beamforming (BF) refinement between AP and the relay node;
(b) a channel state information metric is fed back by the relay node for MIMO operation;
(c) BF training is performed between the relay node and a first station (STA 1) including transmitter (Tx) and receiver (Rx) sector training;
(d) BF training is performed between the relay node and a second station (STA 2) including Tx and Rx sector training;
(e) a probing sequence is performed from the relay node to STA 1;
(f) a channel state information metric is fed back by STA 1;
(q) a probing sequence is performed from the relay node to STA 2;
(h) a channel state information metric is fed back by STA 2;
(i) simultaneous pilot transmissions are performed by STA 1 and STA 2 for inter-user interference estimation by the relay node;
(j) data is transmitted between the AP and the relay node using MIMO; and
(k) data is transmitted from the relay node to STA 1 and STA 2 using multiple-user (MU) MIMO. - View Dependent Claims (16, 17, 18, 19, 20)
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Specification
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Current AssigneeSony Corporation (Sony Group Corp.)
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Original AssigneeSony Corporation (Sony Group Corp.)
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InventorsAbdallah, Ramy Medhat
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Primary Examiner(s)Fotakis, Aristocratis
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Application NumberUS15/142,822Publication NumberTime in Patent Office718 DaysField of SearchUS Class CurrentCPC Class CodesH04B 17/318 Received signal strengthH04B 17/336 Signal-to-interference rati...H04B 7/026 Co-operative diversity, e.g...H04B 7/0452 Multi-user MIMO systemsH04B 7/0617 for beam formingH04B 7/0626 Channel coefficients, e.g. ...H04B 7/0695 using beam selectionH04B 7/155 Ground-based stations H04B7...H04B 7/1555 Selecting relay station ant...H04W 84/12 WLAN [Wireless Local Area N...
