MULTIPLE ACCESS BY SPACE DIVISION (SDMA) THROUGH MULTIPLE OPERATORS

专利摘要:
Wireless communications systems and methods related to SDM operations across multiple network operating entities are provided. a first wireless communication device transmits a communication indicating a reservation for one or more spatial layers in a transmission opportunity (txop) of a shared spectrum. the shared spectrum is shared by a first network operational entity and a second network operational entity. the first wireless communication device is associated with the first operational entity on the network. the first wireless communication device communicates, with a second wireless communication device, data over one or more spatial layers during txop. the second wireless communication device is associated with the first operational entity on the network.
公开号:BR112019021076A2
申请号:R112019021076-8
申请日:2018-03-13
公开日:2020-05-12
发明作者:Zhang Xiaoxia；Yoo Taesang；Mallik Siddhartha；Kadous Tamer；Jain Vikas；Sadek Ahmed
申请人:Qualcomm Incorporated；
IPC主号:

专利说明:

MULTIPLE ACCESS BY SPACE DIVISION (SDMA) THROUGH MULTIPLE OPERATORS
Xiaoxia Zhang, Taesang Yoo, Siddhartha Mallik, Tamer Kadous, Vikas Jain, Ahmed Sadek
CROSS REFERENCE TO RELATED REQUESTS
[0001] This application claims priority and benefit from US Non-Provisional Application No. 15 / 787,141, filed on October 18, 2017, and US Provisional Patent Application No. 62 / 484,730, filed on April 12, 2017, which are incorporated into this document by reference in their entirety, as if it were fully defined below and for all applicable purposes.
TECHNICAL FIELD
[0002] This request refers to wireless communication systems and, more specifically, to the improvement of spectrum sharing between various network operational entities, employing multiple access by spatial division (SDMA).
INTRODUCTION
[0003] Wireless communication systems are widely implemented to provide various types of communication content, such as voice, video, data packets, messages, transmission and so on. These systems may be able to support communication with various uses by sharing the available resources of the system (for example, time, frequency and energy). Examples of such multiple access systems include access code division multiple systems (CDMA), time division multiple access systems (TDMA), frequency division multiple access systems
Petition 870190100411, of 10/07/2019, p. 8/110
2/71 (FDMA) and orthogonal frequency division multiple access systems (OFDMA), (for example, a Long Term Evolution System (LTE)). A wireless multiple access communication system can include a number of base stations (BSs), each simultaneously supporting communication for various communication devices, which may also be known as user equipment (UE).
[0004] A wireless communication system can operate on a shared spectrum, which means that the wireless communication system includes one or more frequency bands that can be shared by several operational network entities. The shared spectrum may include unlicensed and / or licensed spectrum. In some cases, several network operating entities may share their licensed spectrum with one another to better use the spectrum. In some other cases, several network operating entities may obtain a licensed spectrum together.
[0005] One approach to sharing a medium or spectrum is to employ a coordinated access scheme based on priority. In the priority-based coordinated access scheme, a shared spectrum is partitioned over several time periods. Each time period is assigned to a specific type of access. For example, a period of time can be allocated to a specific network operator for exclusive access to the shared spectrum, where no reservation from the specific network operator is required. Like
Petition 870190100411, of 10/07/2019, p. 9/110
3/71 Alternatively, a period of time can be shared between several network operators, with priority, with reservations. For example, a high priority network operator may have priority or guaranteed access to the shared spectrum over a period of time, but requires prior reservation for the period. When the high priority network operator does not reserve the period, a low priority network operator can opportunistically access the shared spectrum in the period. Although the priority-based coordinated access scheme can be relatively efficient, the priority-based coordinated access scheme considers only the sharing of the medium over time and / or frequency.
BRIEF SUMMARY OF SOME EXAMPLES
[0006] Below, we summarize some aspects of this disclosure to provide a basic understanding of the technology discussed. This summary is not a comprehensive overview of all resources covered in the disclosure and is not intended to identify key or critical elements of all aspects of the disclosure, nor to outline the scope of one or all aspects of the disclosure. Its sole purpose is to present some concepts of one or more aspects of dissemination in summary form as a prelude
for description more detailed that it will be presented posteriorly. [0007] Per example, in one aspect of dissemination, a method of communication without wire includes
transmit, by a first wireless communication device associated with a first network operational entity, a communication indicating a reservation for one or
Petition 870190100411, of 10/07/2019, p. 10/110
4/71 more spatial layers in a transmission opportunity (TXOP) of a shared spectrum, where the shared spectrum is shared by the first operational entity of the network and a second operational entity of the network; and communicating, over the first wireless communication device with a second wireless communication device associated with the first operational entity on the network, data over one or more spatial layers during TXOP.
[0008] In an additional aspect of the disclosure, a device includes means to transmit a communication indicating a reservation for one or more space layers in a transmission opportunity (TXOP) of a shared spectrum, where the shared spectrum is shared by a first network operational entity and a second network operational entity, and in which the device is associated with the first network operational entity; and means for communicating, with a second wireless communication device associated with the first network operational entity, data over one or more spatial layers during TXOP.
[0009] In an additional aspect of the disclosure, a computer-readable medium having program code registered in it, the program code includes code to cause a first wireless communication device associated with a first network operational entity to transmit a communication indicating a reservation for one or more space layers in a transmission opportunity (TXOP) of a shared spectrum, where the shared spectrum is shared by the first entity
Petition 870190100411, of 10/07/2019, p. 11/110
5/71 network operational and a second network operational entity; and code to cause the first wireless communication device to communicate, with a second wireless communication device associated with the first network operational entity, data on one or more spatial layers during TXOP.
[0010] Other aspects, characteristics and modalities of the present invention will become evident to those skilled in the art, after reviewing the description below of specific exemplary modalities of the present invention together with the attached figures. Although the features of the present invention can be discussed in relation to certain embodiments and figures below, all of the embodiments of the present invention can include one or more of the advantageous features discussed here. In other words, while one or more modalities can be discussed as having certain advantageous characteristics, one or more of these characteristics can also be used according to the various modalities of the invention discussed here. Similarly, although exemplary modalities can be discussed below as device, system or method modalities, it should be understood that such exemplary modalities can be implemented in various devices, systems and methods.
BRIEF DESCRIPTION OF THE DRAWINGS
[0011] A Figure 1 illustrates a network in wireless communication according with modalities gives present disclosure. [0012] A Figure 2 illustrates a scheme in
Petition 870190100411, of 10/07/2019, p. 12/110
6/71 media sharing based on coordinated priority
with management interference in a deal with at modalities of this disclosure. [0013] A Figure 3 illustrates a network in wireless communication that implements multiple access per
spatial division (SDMA) for media sharing according to the modalities of this disclosure.
[0014] Figure 4 is a block diagram of an exemplary user equipment (UE) according to the modalities of the present disclosure.
[0015] Figure 5 is a block diagram of an exemplary base station (BS) according to the modalities of the present disclosure.
[0016] Figure 6 illustrates an SDMA-based media sharing scheme in accordance with the modalities of this disclosure.
[0017] Figure 7 is a signaling diagram of a media sharing method based on SDMA according to the modalities of this disclosure.
[0018] Figure 8 illustrates a media sharing scheme based on SDMA according to the modalities of this disclosure.
[0019] Figure 9 illustrates an SDMA-based media sharing scheme in accordance with the modalities of this disclosure.
[0020] Figure 10 illustrates an SDMA-based media sharing scheme in accordance with the modalities of this disclosure.
[0021] Figure 11 is a flow diagram of a SDMA-based media sharing method of
Petition 870190100411, of 10/07/2019, p. 1/13
7/71 in accordance with the terms of this disclosure.
DETAILED DESCRIPTION
[0022] The detailed description set out below, in connection with the attached drawings, is intended to be a description of various configurations and does not represent the only configurations in which the concepts described here can be practiced. The detailed description includes specific details in order to provide a complete understanding of the various concepts. However, it will be evident to people skilled in the art that these concepts can be practiced without these specific details. In some cases, known structures and components are shown in the form of a block diagram to avoid obscuring such concepts.
[0023] The techniques described in this document can be used for various wireless communication networks, such as code division multiple access (CDMA), time division multiple access (TDMA), customer division multiple access (FDMA), orthogonal multiple access by frequency division (OFDMA), single operator FDMA (SC-FDMA) and other networks. The terms network and system are often used interchangeably. A CDMA network can implement radio technology such as Universal terrestrial radio access (UTRA), cdma2000, etc. UTRA includes broadband CDMA (WCDMA) and other variants of CDMA. Cdma2000 covers the IS-2000, IS-95 and IS-856 standards. A TDMA network can implement radio technology such as the Global Mobile Communications System (GSM). An OFDMA network can implement radio technology
Petition 870190100411, of 10/07/2019, p. 14/110
8/71 such as evolved UTRA (E-UTRA), ultra mobile broadband (UMB), IEEE 802.11 (Wi-Fi), IEEE 802.16 (WiMAX), IEEE 802.20, Flash-OFDMA, etc. UTRA and E-UTRA are part of the Universal Mobile Telecommunications System (UMTS). The Long Term Evolution of 3GPP (LTE) and Advanced LTE (LTEA) are new releases of UMTS that use E-UTRA. UTRA, E-UTRA, UMTS, LTE, LTE-A and GSM are described in documents from an organization named Partnership Project 3 Generation (3GPP). CDMA2000 and UMB are described in documents from an organization named Partnership Project 3 Generation 2 (3GPP2). The techniques described herein may be used for the wireless networks and radio technologies mentioned above as well as other wireless networks and radio technologies, such as a next-generation network (eg, the fifth generation (5G) operating in bands Millimeter Waves).
[0024] This disclosure describes mechanisms for sharing spatial transmission layers between various network operational entities, in addition to time and frequency. In a priority-based spectrum sharing scheme, a spectrum is partitioned over time in transmission opportunities (TXOPs). Each TXOP is designated for priority use by a priority or high priority network operating entity and opportunistic use by low priority network operating entities based on reservations. In the disclosed modalities, the network operational entities that share a medium or a spectrum can exchange information from the space layer, for example, through a central authority.
Petition 870190100411, of 10/07/2019, p. 1/15
9/71
The spatial layer information can indicate a total number of spatial layers supported by an operational entity of the network. In the disclosed modalities, a high priority network operating entity may reserve one or more of the supportable space layers for communications on a TXOP. A low priority network operating entity may use the remaining unreserved space layers for TXOP communications in due course. The sharing of spatial layers between various network operational entities is known as SDMA. The disclosed modalities include framework structures, signaling mechanisms for low priority network operational entities to detect space layer reserves of high priority network operational entities. The disclosed modalities include channel sounding mechanisms for all network operational entities that share spatial layers in a TXOP to determine space channel information for SDMA pre-coding.
[0025] In one modality, the medium reserves can be signaled through reserve response signal transmissions (RRS) by programmed UEs and the space channel sounding can be obtained from sound reference signal transmissions (SRS) by Scheduled UEs. For example, each programmed UE transmits an RRS signal to indicate each programmed spatial layer and transmits an SRS according to each programmed spatial layer to facilitate spatial channel estimation at base stations (BSs) of all network operating entities that
Petition 870190100411, of 10/07/2019, p. 1/16
10/71 share the TXOP.
[0026] In one modality, the space and sound reserves of the space channel can be obtained from SRS transmissions by programmed UEs. For example, each programmed UE transmits an SRS according to each programmed spatial layer to indicate each programmed spatial layer and to facilitate spatial channel estimation in the BSs of all network operating entities that share the TXOP.
[0027] In one modality, the media reserves can be signaled through indications of explicit space layer programming information and other network operational entities that share the spectrum can decode the explicit programming information. For example, explicit programming information can be signaled through RRQ signal transmissions by BS concession or transmitted simultaneously by all BS concessions in a single customer network (SEN) manner. Alternatively, the explicit programming information can be signaled through simultaneous RRS signal transmissions by all BS concessions and all UEs programmed in TXOP in a SEN manner. In addition, explicit programming information may include space layer reservation information at a finer granular age, for example, at a subperiod level within a TXOP.
[0028] Aspects of this disclosure can provide several benefits. For example, sharing a medium in a spatial dimension beyond
Petition 870190100411, of 10/07/2019, p. 17/110
11/71 time and frequency dimensions allow ο sharing at a finer granularity, and thus can improve the efficiency of media sharing. Synchronous sharing operations based on structured TXOPs, as described in more detail here, allow synchronous SDMA without massive antennas in BSs and / or UEs, and thus can provision for SDMA at a low cost.
[0029] Figure 1 illustrates a wireless communication network 100 according to the modalities of the present disclosure. Network 100 includes BSs 105, UEs 115, and a main network 130. In some embodiments, network 100 operates over a shared spectrum. The shared spectrum may be unlicensed or partially licensed to one or more network operators. Access to the spectrum can be limited and can be controlled by a separate coordinating body. In some embodiments, network 100 may be an LTE or LTE-A network. In still other modalities, the network 100 can be a millimeter wave network (mmW), a new radio network (NR), a 5G network or any other successor network to LTE. Network 100 can be operated by more than one network operator. Wireless resources can be partitioned and arbitrated between different network operators for coordinated communication between network operators over network 100.
[0030] BSs 105 can communicate wirelessly with UEs 115 through one or more BS antennas. Each BS 105 can provide communication coverage for a respective geographic coverage area 110. In 3GPP, the term cell can refer to that coverage area
Petition 870190100411, of 10/07/2019, p. 1/18
12/71 specific geography of a BS and / or BS subsystem that serves the coverage area, depending on the context in which the term is used. In this regard, a BS 105 can provide communication coverage for a macro cell, a peak cell, a femto cell and / or other cell types. A macro cell generally covers a relatively large geographical area (for example, several kilometers in radius) and can allow unrestricted access by UEs with service subscriptions with the network provider. A peak cell can generally cover a relatively smaller geographic area and can allow unrestricted access by UEs with service subscriptions with the network provider. A femto cell can also generally cover a relatively small geographical area (for example, a house) and, in addition to unrestricted access, it can also provide restricted access for UEs that have an association with the femto cell (for example, UEs in a closed group) subscribers (CSG), UEs for use at home and the like). A BS for a macro cell can be called a BS macro. A BS for a peak cell can be referred to as a peak BS. A BS for a femto cell can be referred to as a femto BS or a domestic BS. In the example shown in Figure 1, BSs 105a, 105b and 105c are examples of macro BSs for coverage areas 110a, 110b and 110c, respectively. BS 105d is an example of a BS peak or BS femto for the HOd coverage area. As will be recognized, a BS 105 can support one or multiple cells (for example, two, three, four and the like).
[0031] Communication links 125 shown
Petition 870190100411, of 10/07/2019, p. 1/1910
13/71 on network 100 may include uplink (UL) transmissions from a UE 115 to a BS 105 or downlink (DL) transmissions from a BS 105 to a UE 115. UEs 115 may be dispersed across network 100, and each UE 115 can be stationary or mobile. A UE 115 can also be referred to as a mobile station, a subscriber station, a mobile unit, a subscriber unit, a wireless unit, a remote unit, a mobile device, a wireless device, a wireless communication device , a remote device, a mobile subscriber station, an access terminal, a mobile terminal, a wireless terminal, a remote terminal, a telephone, a user agent, a mobile client, a customer or some other suitable terminology. An UE 115 can also be a cell phone, a personal digital assistant (PDA), a wireless modem, a wireless communication device, a portable device, a tablet computer, a laptop, a cordless phone, an electronic device a personal device, a portable device, a personal computer, a wireless local loop station (WLL), an Internet of Things (loT) device, an Internet of Everything (loE) device, a machine-type communication device (MTC) ), a device, a car, or the like.
[0032] BSs 105 can communicate with main network 130 and with each other. Core network 130 can provide user authentication, access authorization, tracking, Internet Protocol (IP) Connectivity and other access, routing or mobility functions. At least some of the BSs 105 (for example, which can be an example of an evolved NodeB (eNB), an
Petition 870190100411, of 10/07/2019, p. 1/20
14/71
Next generation NodeB (gNB) or an access node controller (ANC)) can interact with the main network 130 through backhaul links 132 (eg SI, S2, etc.) and can perform radio configuration and programming for communication with UEs 115. In several instances, BSs 105 can communicate, directly or indirectly (for example, through main network 130), with each of the other backhaul links 134 (for example, XI, X2, etc. .), which can be wired or wireless communication links.
[0033] Each BS 105 can also communicate with several UEs 115 through several other BSs 105, where BS 105 can be an example of an intelligent radio head. In alternative configurations, several functions of each BS 105 can be distributed among several BSs 105 (for example, radio heads and access network controllers) or consolidated into a single BS 105.
[0034] In some implementations, network 100 uses multiplexing by orthogonal frequency division (OFDM) in the downlink and multiplexing by single carrier frequency division (SC-FDM) in UL. OFDM and SC-FDM partition the system's bandwidth into several orthogonal (K) subcarriers, which are also commonly referred to as tones, compartments or the like. Each subcarrier can be modulated with data. In general, modulation symbols are sent in the frequency domain with OFDM and in the time domain with SC-FDM. The spacing between adjacent subcarriers can be fixed and the total number of subcarriers (K) can be dependent on the system bandwidth. The system's bandwidth can also be partitioned into sub-bands.
Petition 870190100411, of 10/07/2019, p. 1/21
15/71
[0035] In one embodiment, BSs 105 can allocate or schedule transmission resources (for example, in the form of time frequency resource blocks) for DL and UL transmissions on network 100. DL refers to the direction of transmission from a BS 105 to a UE 115, while UL refers to the direction of transmission from a UE 115 to a BS 105. Communication can be in the form of radio frames. A radio frame can be divided into a plurality of subframes, for example, around 10. Each subframe can be divided into partitions, for example, about 2. In a frequency division duplex (FDD) mode, transmissions can occur of simultaneous UL and DL in different frequency ranges. For example, each subframe includes a subframe of UL in a frequency band of UL and a subframe of DL in a frequency band of DL. In time division duplex (TDD) mode, UL and DL transmissions occur at different times using the same frequency band. For example, a subset of the subframes (for example, DL subframes) in a radio frame can be used for DL transmissions and another subset of the subframes (for example, UL subframes) in the radio frame can be used for radio transmissions. UL.
[0036] The DL and UL subframes can be divided into several regions. For example, each DL or UL subframe can have predefined regions for transmitting reference signals, control information and data. Reference signals are predetermined signals that facilitate communications between BSs 105 and UEs 115. For example, a reference signal
Petition 870190100411, of 10/07/2019, p. 22/110
16/71 can have a specific panel or pilot structure, where the pilot tones can span a bandwidth or operating frequency range, each positioned at a predefined time and a predefined frequency. For example, a BS 105 can transmit cell-specific reference signals (CRSs) and / or channel status reference signal information (CSI-RSs) to allow a UE 115 to estimate a DL channel. Likewise, an UE 115 can transmit audible reference signals (SRSs) to allow a BS 105 to estimate an UL channel. Control information can include resource assignments and protocol controls. The data may include protocol data and / or operational data. In some embodiments, BSs 105 and UEs 115 can communicate using independent subframes. An independent subframe can include a portion for DL communication and a portion for UL communication. An independent subframe can be centralized in DL or UL. A DL centralized subframe can include a longer duration for DL communication than UL communication. A UL-centered subframe may include a longer duration for UL communication than UL communication.
[0037] In one embodiment, a UE 115 attempting to access network 100 can perform an initial cell search by detecting a primary sync signal (BSS) from a BS 105. The BSS can activate period time synchronization and can indicate an identity value of the physical layer. The UE 115 can then receive a secondary synchronization signal (SSS). SSS can activate the
Petition 870190100411, of 10/07/2019, p. 1/23
17/71 radio frame synchronization and provide a cell identity value, which can be combined with the physical layer identity value to identify the cell. The SSS can also allow detection of a duplex mode and a cyclic prefix length. Some systems, such as TDD systems, can transmit an SSS, but not a PSS. Both the PSS and the SSS can be located in a central portion of a carrier, respectively. After receiving the PSS and SSS, the UE 115 can receive a master information block (MIB), which can be transmitted on the physical transmission channel (PBCH). The MIB can contain system bandwidth information, a system frame number (SFN), and a Hybrid-ARQ physical indicator channel configuration (PHICH). After decoding the MIB, the UE 115 can receive one or more blocks of system information (SIBs). For example, SIB1 can contaminate cell access parameters and programming information for other SIBs. Decoding SIB1 may allow UE 115 to receive SIB2. 0 SIB2 can contaminate radio resource configuration (RRC) configuration information related to random access channel (RACH) procedures, paging, physical uplink control channel (PUCCH), shared physical uplink channel (PUSCH), control power, SRS and cell restriction. After obtaining the MIB and / or the SIBs, the UE 115 can perform random access procedures to establish a connection with BS 105. After establishing the connection, the UE 115 and BS 105 can enter a normal operating stage, where operational data can be exchanged.
Petition 870190100411, of 10/07/2019, p. 24/110
18/71
[0038] In some modalities, UEs 115 and BSs 105 can be operated by several network operators or network operational entities and can operate on a shared radio frequency spectrum, which may include licensed or unlicensed frequency bands. The shared spectrum can be partitioned in time for sharing between the various network operational entities to facilitate coordinated communication. For example, in network 100, BS 105a and UE 115a can be associated with one operational entity in the network, while BS 105b and UE 115b can be associated with another operational entity in the network. When dividing the time, the spectrum shared according to the operational network entities, the communications between the BS 105a and the UE 115a and the communications between the BS 105b and the UE 115b can occur during the respective periods of time and can be a totality of designated shared spectrum.
[0039] To support coordinated access of the shared spectrum, a BS 105 or an entity of the main network 130 can act as a central arbiter to manage access and coordinate the partition of resources between different network operational entities operating within the network 100 In some modalities, the central arbiter may include a spectrum access system (SAS). In addition, transmissions from the various network operating entities can be synchronized over time to facilitate coordination.
[0040] Figure 2 illustrates a coordinated spectrum sharing scheme based on
Petition 870190100411, of 10/07/2019, p. 25/110
19/71 priority 200 with interference management in accordance with the terms of this disclosure. The x-axes represent time in some constant units. The y-axes represent frequency in some constant units. Scheme 200 can be employed by BSs 105 and UEs 115 to access a shared spectrum 201. While scheme 200 illustrates coordinated spectrum access for two network operational entities
different (for example, Operator A and Operator B), The 200 scheme can be applied to any suitable number in network operating entities, including three four or more operational entities. [0041] In the scheme 200, the spectrum 201 is
partitioned over time into a plurality of transmission opportunities (TXOPs) 202, as shown in structure structure 205. TXOPs 202 can have a fixed duration and can be defined in units of OFDM symbols, subframes, partitions and / or any format appropriate time. Each TXOP 202 includes a plurality of channel detection periods or clear channel evaluation (CCA) 204 followed by a transmission period 206. CCA periods 204 are separated by a 234 interval period. The TXOP frame structure 205 202 is predetermined and known by all network operating entities that share the 201 spectrum. The network operational entities can be synchronized with time when operating on the shared spectrum 201.
[0042] Each CCA 204 period is assigned to a specific network operational entity (for example, Operator A or Operator B). The network operating entity
Petition 870190100411, of 10/07/2019, p. 26/110
Assigned 20/71 can transmit a reservation in the CCA 204 period to reserve the following 206 transmission period. Each CCA 204 period includes portions 207, 208 and 209. Portions 207 and 208 are separated by a 232 difference period. Portions 207 are used to transmit RRQ 220 signals. Each RRQ 220 signal may include a predetermined preamble sequence, a request-to-send (RTS) signal and / or transmission triggers (e.g., programming information). Portions 208 are used to transmit RRS 222 signals for sharing at the operator level (for example, between operators). Portions 209 are used to transmit RRS 224 signals for sharing at the link level (for example, between UL and DL) within an operator. Each of the RRS signals 222 and 224 can include a predetermined preamble sequence or a send-out (CTS) signal. CCA 204 periods can be organized in decreasing order of priority. Thus, a low priority operator node can monitor the channel (for example, the shared spectrum 201) at the high priority CCA 204 periods. After detecting a reservation from a high priority operator node, the low priority operator node may refrain from transmitting in the transmission period 206. The 234 interval period
allows what the knots the operator low priority sue The reservation of an operator high pri ority. 0 period in interval 232 allows switch in between The
UL and DL processing.
Transmission period 206 includes a plurality of sub-periods 210 shown as 210 _s to 210 _sN .
Petition 870190100411, of 10/07/2019, p. 27/110
21/71 first subperiod 210 _s i includes portions 214 and 216. The remaining subperiods 210 in transmission period 206 include portions 212, 214 and 216. Portions 212 are used to transmit DL 230 controls (for example, UL or DL) for the corresponding portions 214. Portions 214 are used to transmit UL or DL 226 data based on the corresponding triggers. Portions 216 are used to transmit UL 228 controls, such as schedule request information (SR) and hybrid automatic repeat request (HARQ). In one embodiment, TXOP 202 is divided into a number of partitions 218. The first partition 218 includes the periods of COA 204 and the subperiod 210 _s i. The remaining partitions 218 correspond to the remaining subperiods 210. In some embodiments, a partition 218 can span approximately 500 microseconds.
[0044] For example, Operator A has priority over Operator B in the specific TXOP 202. As such, the high priority COA period 204a is assigned to Operator A and the low priority COA period 2046 is assigned to Operator B. Thus, the nodes of operator A prioritized access during transmission period 206, while the nodes operator B can access transmission period 206 when transmission period 206 is not reserved by operator A nodes. In addition, the default link direction is DL within Operator A and within Operator B during TXOP 202. Therefore, transmission priorities in order are DL from Operator A, UL from Operator A, DL from Operator B and UL from Operator B. The pattern filled boxes shown in
Petition 870190100411, of 10/07/2019, p. 1/28
22/71 in relation to Operators A and B in Figure 2 represent signal transmissions. The dashed line boxes at the top of Figure 2 are included as references to the structure of TXOP 205 without signal transmission.
[0045] For priority access, a BS to DL grant from Operator A can transmit an RRQ signal 220a in portion 207 of the COA period 204a to reserve the following transmission period 206. The RRQ signal 220a can include a trigger of DL. For dynamic TDD within Operator A, a BS grant to UL from Operator A can transmit an RRQ signal 220a including a UL trigger on the same portion 207 of the COA period 204a based on reuse. Nodes driven by operator A can transmit an RRS signal 222a in portion 208 of COA period 204a to silence the nodes of operator B (e.g., the low priority operator). The nodes of operator B can monitor the COA period 204a for an RRQ signal 220a and / or an RRS signal 222a of operator A. After the detection of the RRQ signal 220a and / or the RRS signal 222a, the nodes of the operator B can provide access to the spectrum to operator A.
[0046] A DL powered UE (eg, the target receiver) can transmit an RRS 224a signal in the 209 portion of the CCA 204a period to silence Operator A nodes with a lower link priority (eg, UL ). Subsequently, the BS to DL grant can transmit data 226a to the DL-driven UE in portion 214 of sub-period 210 _s i. The DL-triggered UE can transmit UL 228a control in portion 216 of sub-period 210 _s i. In subsequent sub-periods 210, the
Petition 870190100411, of 10/07/2019, p. 1/29
23/71 BS to DL granting can trigger one or more other UEs for DL communications. In some embodiments, the transmission period 206 may begin after the CCA period 204a (for example, occupying the low priority CCA period 2046).
[0047] The UL triggered UE can monitor an RRS 224a signal in the 209 portion of the CCA 204a period. When no RRS 224a signal is detected, the UL triggered UE can dynamically switch the link priority to UL and transmit data 226a and a UL 228a control for granting BS to UL during portions 214 and 216, respectively, of the subperiod 210 _s i. When lower priority operator nodes exist, the BS grant to UL (for example, the target receiver) can transmit an RRS signal 222a during portion 209 of the CCA period 204a to silence low priority nodes near the grant of BS to UL. In subsequent sub-periods 210, the BS grant to UL can trigger one or more other UEs for UL communications. While dynamic TDD mechanisms are described in the context of switching a link priority from DL to UL, similar mechanisms can be applied to a link priority from UL to DL.
[0048] When shared spectrum 201 is not reserved by Operator A, Operator B may opportunistically access TXOP 202 using mechanisms similar to Operator A. For example, a BS to UL grant and / or a BS to DL grant from Operator B can transmit RRQ signals 220b in the 207 portion of the assigned CCA period 204b to trigger communications
Petition 870190100411, of 10/07/2019, p. 1/30
24/71 of DL and / or UL 226b data. Nodes driven by operator B can transmit an RRS signal 222b in portion 208 of the COA period 204b when there is a lower priority operator. A DL2 driven UE can transmit an RRS signal 224b in the 209 portion of the CCA 204b period. Subsequently, the BS DL grant can transmit data 226b to the DL-driven UE in portion 214 of sub-period 210 _s i. The DL-triggered UE can transmit UL 228b control in portion 216 of sub-period 210 _s i. To switch the link priority from the standard link priority, the UL triggered UE can monitor an RRS 224b signal in portion 209. When no RRS 224b signal is detected, the UL triggered UE can transmit 226b data and a control of UL 228b to BS from BS to UL during parts 214 and 216, respectively, of sub-period 210 _s i.
[0049] Figure 3 illustrates a wireless communication network 300 that implements SDMA for media sharing, according to the modalities of this disclosure. Network 300 corresponds to a portion of network 100. Figure 3 illustrates two BSs 305 and three UEs 315 for the sake of simplicity of discussion, although it is recognized that the modalities of the present disclosure can scale to many more UEs 315 and / or BSs 305 BSs 305 and UEs 315 can be similar to BS 105 and UE 115, respectively. The network 300 can be operated by several operators sharing a frequency spectrum. For example, operator A can operate BSs 305a and UEs 315a, and operator B can operate BSs 305b and UEs 315b. In addition, Figure 3 illustrates each BS 305, including
Petition 870190100411, of 10/07/2019, p. 1/31
25/71 four transmission antennas 320 and each EU 315, including two receiving antennas 322 for the sake of simplicity of discussion, although it is recognized that the modalities of this disclosure may scale to any suitable number of transmission antennas and / or receiving antennas in BSs 305 and / or UEs 315.
[0050] BS 305a with four transmission antennas 320 can support a transmission classification of four or four spatial layers. BS 305a can employ multiple single input (SIMO) outputs, multiple input and multiple output (MISO) pre-coding techniques, or multiple input and multiple output (MIMO) to communicate with 315 UEs through multiple layers space. For example, BS 305a can communicate with UE 315ai using a subset or all transmission antennas 320 over two spatial layers, as shown by link 330. In addition, BS 305a can communicate with UE 315a ₂ using a subset or all transmission antennas 320 over two other spatial layers, as shown by link 332. Communications with UE 315ai and UE 315a ₂ can occur simultaneously through pre-coding. Similar to BS 305a, BS 305b can support a transmission classification of four or four spatial layers and can employ SIMO, MISO or MIMO techniques to communicate with the UE 315b.
[0051] Operator A's BS 305a and Operator B's BS 305b can share a spectrum (for example, spectrum 201) for communication with corresponding UEs 315 using a media sharing scheme
Petition 870190100411, of 10/07/2019, p. 32/110
26/71 similar to scheme 200. However, in addition to sharing over time and frequency, Operator A and Operator B can share over a spatial dimension (for example, the spatial layers). For example, when BS 305a uses two of the four space layers to communicate with UE 315ai on a TXOP (for example, TXOP 202), BS 305b can use the remaining two space layers to communicate with UE 315b during same TXOP as shown by link 334.
[0052] In one embodiment, Operator A can include the NI number of BSs in a coordinated multipoint cluster (CoMP) and each of Operator A's BSs can include the Ml number of transmission antennas. Thus, operator A can support NI by the number Ml of spatial layers in the CoMP cluster. Operator B can include the N2 number of BSs in a CoMP cluster and each of the BSs of operator B can include the number M2 of transmission antennas, supporting N2 by M2 space layers. To facilitate SDMA on a shared spectrum, operators can share information associated with the number of supportable spatial layers with each other, for example, through SAS or backhaul coordination. The mechanisms for employing SDMA-based media sharing are described in more detail here.
[0053] Figure 4 is a block diagram of an exemplary UE 400 in accordance with the modalities of the present disclosure. UE 400 can be UE 115 or 315 as discussed above. As shown, the UE 400 can include a processor 402, a memory 404, a media sharing module 408, a transceiver 410 including
Petition 870190100411, of 10/07/2019, p. 33/110
27/71 a modem subsystem 412 and a radio frequency (RF) unit 414, and one or more antennas 416. These elements can be in direct or indirect communication with each other, for example through one or more buses.
[0054] Processor 402 may include a central processing unit (CPU), a digital signal processor (DSP), an application-specific integrated circuit (ASIC), a controller, a field programmable port array device (FPGA) ), another hardware device, a firmware device, or any combination thereof configured to perform the operations described in this document. Processor 402 can also be implemented as a combination of computing devices, for example, a combination of a DSP and a microprocessor, a plurality of microprocessors, one or more microprocessors in conjunction with a DSP core or any other configuration.
[0055] The 404 memory can include a cache memory (for example, a 402 processor cache memory), random access memory (RAM), magnetoresistive RAM (MRAM), read-only memory (ROM), programmable read-only memory (PROM ), erasable programmable read-only memory (EPROM), programmable read-only programmable memory (EEPROM), flash memory, solid state memory device, hard disk drives, other forms of volatile and non-volatile memory or a combination of different types of memory. In one embodiment, memory 404 includes a non-transitory computer-readable medium. 404 memory can store
Petition 870190100411, of 10/07/2019, p. 34/110
28/71 instructions 406. Instructions 406 may include instructions that, when executed by processor 402, cause processor 402 to perform the operations described therein with reference to UEs 215 in connection with the modalities of the present disclosure. Instructions 406 can also be called code. The terms instructions and code must be interpreted widely to include any type of computer-readable statement. For example, the terms instructions and code can refer to one or more programs, routines, subroutines, functions, procedures, etc. Instructions and code can include a single computer-readable statement or many computer-readable statements.
[0056] The media sharing module
408 can be implemented through hardware, software, or combinations thereof. For example, the media sharing module 408 can be implemented as a processor, circuit, and / or 406 instructions stored in memory 404 and executed by processor 402. The media sharing module 408 can be used for various aspects of the present disclosure . For example, the media sharing module 408 is configured to identify TXOPs in a shared spectrum, perform network listening, transmit RRs and / or SRSs to indicate programmed spatial layers, transmit SRSs to facilitate spatial channel estimation and / or perform pre-coding based on the spatial channel estimate, as described in more detail here.
[0057] As shown, transceiver 410 may include modem subsystem 412 and RF unit 414.
Petition 870190100411, of 10/07/2019, p. 35/110
29/71 transceiver 410 can be configured to communicate bidirectionally with other devices, such as BSs 105 and 305. Modem subsystem 412 can be configured to modulate and / or encode data from memory 404 and / or the sharing module SDMA 408-based media according to a modulation and encoding scheme (MCS), for example, a low density parity check (LDPC) encoding scheme, a turbo encoding scheme, a convolutional encoding scheme, a digital beam shaping scheme, etc. The RF unit 414 can be configured to process (for example, perform analog to digital or digital to analog conversion, etc.) modulated / encoded data from modem subsystem 412 (in outgoing transmissions) or from transmissions originating from another source , such as an UE 315 or a BS 305. The RF unit 414 can be further configured to perform analog beam shaping in conjunction with digital beam shaping. Although shown as integrated together in transceiver 410, modem subsystem 412 and RF unit 414 can be separate devices that are coupled to UE 215 to allow UE 215 to communicate with other devices.
[0058] The RF unit 414 can supply the modulated and / or processed data, for example, data packets (or, more generally, data messages that can contaminate one or more data packets and other information), to the antennas 416 for transmission to one or more other devices. 416 antennas may be similar to antennas 320 and 322. This may include, for example,
Petition 870190100411, of 10/07/2019, p. 36/110
30/71 example, transmission of RRS signals and / or SRSs according to the modalities of the present disclosure. The 416 antennas can also receive data messages transmitted from other devices. This may include, for example, receiving request to send (RTS) and / or CTS signals in accordance with the modalities of this disclosure. The antennas 416 can provide the data messages received for processing and / or demodulation on the transceiver 410. The antennas 416 can include multiple antennas of similar or different designs, in order to support multiple transmission links. The RF unit 414 can configure the 416 antennas.
[0059] Figure 5 is a block diagram of an exemplary BS 500 according to the modalities of the present disclosure. The BS 500 can be a BS 105 or 305 as discussed above. As shown, the BS 500 can include a processor 502, a memory 504, a media sharing module 508, a transceiver 510 including a modem subsystem 512 and an RF unit 514, and one or more antennas 516. These elements can be in direct or indirect communication with each other, for example through one or more buses.
[0060] The 502 processor can have several features like a specific type processor. For example, these can include a CPU, a DSP, an ASIC, a controller, an FPGA device, another hardware device, a firmware device or any combination thereof configured to perform the operations described here. The 502 processor can also be implemented as a combination of computing devices, for example,
Petition 870190100411, of 10/07/2019, p. 37/110
31/71 a combination of a DSP and a microprocessor, a
plurality of microprocessors, one or more microprocessors together with a core in DSP or any other configuration. [0061] Memory 504 can include an memory
cache (for example, a 502 processor cache memory), RAM, MRAM, ROM, PROM, EPROM, EEPROM, flash memory, a solid state memory device, one or more hard drives, arrays based on other forms of volatile and non-volatile memory or a combination of different types of memory. In some embodiments, memory 504 may include a non-transitory, computer-readable medium. Memory 504 can store instructions 506. Instructions 506 can include instructions that, when executed by processor 502, cause processor 502 to perform operations described here. Instructions 506 can also be referred to as code, which can be interpreted widely to include any type of computer-readable statement (s), as discussed above in relation to Figure 5.
[0062] The 508 media sharing module can be implemented through hardware, software or combinations thereof. For example, the media sharing module 508 can be implemented as a processor, circuit and / or instructions 506 stored in memory 404 and executed by the processor 502. The media sharing module 508 can be used for various aspects of the present disclosure. For example, the 508 media sharing module is configured to identify TXOPs in a spectrum
Petition 870190100411, of 10/07/2019, p. 38/110
32/71 shared, perform network listening, program UEs in space layers, trigger programmed UEs for RRS and / or SRS transmissions, receive SRSs from programmed UEs, detect SRSs from other operators, estimate space channel information based on received SRSs and detected and / or perform pre-coding based on the spatial channel estimation information for SDMA, as described in more detail here.
[0063] As shown, transceiver 510 can include modem subsystem 512 and RE unit 514. Transceiver 510 can be configured to communicate bidirectionally with other devices, such as UEs 115 and 215 and / or another element of the main network. Modem subsystem 512 can be configured to modulate and / or encode data according to an MCS, for example, an LDPC encoding scheme, a turbo encoding scheme, a convolutional encoding scheme, a digital beam shaping scheme , etc. The RE 514 unit can be configured to process (for example, perform analog to digital or digital to analog conversion, etc.) modulated / encoded data from modem subsystem 512 (in outgoing transmissions) or from transmissions originating from another source as a UE 215. The RE 514 unit can further be configured to perform analog beam shaping in conjunction with the digital beam shaping. Although shown as integrated together in transceiver 510, modem subsystem 512 and RE unit 514 can be separate devices that are coupled to BS 305 to allow BS 305 to communicate with others
Petition 870190100411, of 10/07/2019, p. 39/110
33/71 devices.
[0064] The RF 514 unit can supply the modulated and / or processed data, for example, data packets (or, more generally, data messages that can contaminate one or more data packets and other information), to the antennas 516 for transmission to one or more other devices. Antennas 516 may be similar to antennas 320 and 322. This may include, for example, the transmission of information to complete connection to a network and communication with a UE 215 camped in accordance with the modalities of this disclosure. The 516 antennas can also receive data messages transmitted from other devices and provide the received data messages for processing and / or demodulation on the 510 transceiver. The 516 antennas can include several antennas of similar or different designs, in order to support multiple data links. streaming.
[0065] Figure 6 is a media sharing scheme based on SDMA 600, according to the modalities of this disclosure. The x-axes represent time in some constant units. The y axes represent the frequency in some constant units. Scheme 600 can be used by BSs 105, 305 and 500 and UEs 115, 315 and 400. Scheme 600 allows the sharing of spatial layers between various operators, in addition to time and frequency. For example, a high priority operator can reserve one or more spatial layers for communication on a specific TXOP (for example, TXOP 202) and allow
Petition 870190100411, of 10/07/2019, p. 40/110
34/71 lower priority operators share the remaining unreserved space layers on the TXOP. The programmed UEs of all operators that share space layers during a TXOP can transmit SRSs to facilitate SDMA pre-coding, as described in more detail here.
[0066] Scheme 600 divides time on a spectrum 201 in TXOPs 202 and employs priority-based sharing mechanisms similar to scheme 200. However, scheme 600 includes additional signaling to facilitate SDMA. As shown in structure structure 605, each TXOP 202 includes an SRS period 604 before transmission period 206, in addition to CCA periods 204. SRS period 604 is designated for SRS transmissions by UEs programmed in transmission period 206 In addition, all sub-periods 210 within transmission period 206 have a similar structure instead of having a different sub-period 210 at the beginning of transmission period 206 as in scheme 200. Sub-periods 210 can be referred to as transmission time intervals (TTIs) or partitions. In one embodiment, each subperiod 210 may span about 500 microseconds.
[0067] As an example, Operator A has priority over Operator B in the specific TXOP 202. To facilitate sharing of spatial layers,
Operators A and B can exchange information from the space layer. For example, the BSs of Operator A can obtain information from the spatial layer of Operator B and the BSs of Operator A
Operator B can obtain information from the space layer of the
Petition 870190100411, of 10/07/2019, p. 41/110
35/71
Operator A. The spatial layer information can include a total number of spatial layers supported by a corresponding operator.
[0068] An Operator A BS A (for example, the high priority operator) can program an Operator A UE A over one or more spatial layers in TXOP 202. BS A transmits an RRQ 620a signal in portion 207 of the CCA period 204a to indicate a schedule, an RRS trigger and an SRS trigger for the UE A. The RRS trigger may include RR transmission resources in the 208 portion assigned to the UE A. The SRS trigger may include SRS transmission in the 604 period of the SRS assigned to the UE A. The RRS transmission resources and the SRS transmission resources may be specific to the UE, specific to the space layer. The RRQ signal 620a can also include a preamble and / or other information similar to the RRQ signal 220a.
[0069] Upon receiving the RRQ signal 620a, UE A transmits an RRS signal 622a in portion 208 of the CCA period 204a to each space layer programmed according to the RRS trigger. For example, the RRS trigger can indicate an orthogonal feature in the portion 208 corresponding to each programmed spatial layer. The orthogonal feature can be orthogonalized through frequency division multiplexing (FDM), time division multiplexing (TDM) and / or code division multiplexing (CDM). Thus, UE A can transmit an RRS signal 622a to each programmed space layer in a corresponding resource.
[0070] Subsequently, UE A transmits a
Petition 870190100411, of 10/07/2019, p. 42/110
36/71
SRS 624a according to each spatial layer programmed during the SRS 604 period according to the SRS trigger. For example, the SRS trigger can indicate an orthogonal feature in the SRS 604 period for each programmed spatial layer. Thus, UE A can transmit an SRS 624a according to each spatial layer programmed in a corresponding resource.
[0071] A BS B of Operator B (for example, the low priority operator) monitors the COA period 204a of Operator A of high priority. After detecting the RRS signal 622a from Operator A, BS B can determine several spatial layers and / or several UEs programmed by Operator A at TXOP 202 based on various received RRS signals 622a.
[0072] When the number of reserved space layers is less than the total number of supportable space layers of Operator A, BS B can program the UE B over one or more of the remaining unreserved space layers in TXOP 202. BS B transmits an RRQ 620b signal similar to the RRQ 620a signal. In some embodiments, the RRQ 620b signal may not include an RRS trigger when Operator B has the lowest priority at TXOP 202.
[0073] After receiving the RRQ signal 620b, the UE B transmits an SRS 624b according to each spatial layer programmed during the SRS 604 period according to the SRS trigger. In one embodiment, the orthogonal features in the SRS 604 period for operators (for example, Operator A and Operator B) can be pre-configured according to a predetermined rule. For example,
Petition 870190100411, of 10/07/2019, p. 43/110
37/71 orthogonal features are ordered based on spatial layers and operators to allow operators to decode SRSs from each other more efficiently.
[0074] BS A can receive SRSs 624a from UE A based on SRS resources assigned by BS A. BS A can apply blind decoding to detect SRSs 624b from Operator B. The blind decoding refers to detection of all permitted SRS signatures (eg waveforms) on each SRS resource.
[0075] BS B can receive SRSs 624b from UE B based on SRS resources assigned by BS B. BS B can apply the space channel reservation information obtained from RRS 622a signal signals to detect SRSs 624a from Operator A. For example, BS B can receive two RRS signal signals 622a from Operator A and determine that Operator A has reserved two spatial layers or spatial layers for two UEs. BS B can monitor SRS resources in the 604 period corresponding to the two reserved space layers or according to the reserve information obtained from RRS signal signals 622a instead of applying blind decoding to all SRS resources.
[0076] Subsequently, BS A and BS B separately estimate space channel information based on received SRSs corresponding to 624a and 624b and determine pre-coding parameters based on the estimated space channel information.
Petition 870190100411, of 10/07/2019, p. 44/110
38/71
[0077] When the communication is to DL, the BS A pre-encodes data according to the pre-determined parameters determined and transmits the data 226a to a UE A programmed during a subperiod 210. Alternatively, when the communication is to UL, the BS A can provide pre-coding parameters for a UE A programmed based on receipt of UL SRS and UE A can pre-encode data according to the supplied pre-coding parameters and transmit data 226a to BS A during a subperiod 210. In some embodiments, the DL 230 controls and UL 228 controls can also be pre-coded based on the pre-coding parameters.
[0078] In one mode, an RRQ 620 signal and / or an RRS 622 signal can indicate a direction of the transmission link (for example, DL or UL) for a corresponding reservation. For example, when a high priority operator indicates a space layer reserved for DL transmission, a low priority operator can share the remaining unreserved space layers for communication in the same direction as DL. This can reduce interference or facilitate interference management between operators.
[0079] In one embodiment, an RRQ 620 signal and / or an RRS 622 signal can indicate whether the sharing of remaining unreserved spatial layers by lower priority operators is allowed on a TXOP 202. For example, when an operator high priority indicates that sharing of remaining unreserved spatial layers is allowed in
Petition 870190100411, of 10/07/2019, p. 45/110
39/71 a TXOP 202, a low priority operator can program a UE in the remaining unreserved space layers. On the other hand, when a high priority operator indicates that sharing of remaining unreserved spatial layers is not allowed on a TXOP 202, a low priority operator may abstain from accessing the medium (for example, spectrum 201 ) even when unreserved space layers are available.
[0080] In one embodiment, to reduce the overhead of RRS resources, a programmed UE can transmit a single RRS 622 signal, regardless of the number of spatial layers programmed and a low priority operator can take a reservation for a classification transmission complete after detection of the RRS 622 signal. For example, BS B can obtain information from the space layer indicating that the UE A can support 4 space layers. After detecting an RRS 622a signal from UE A, BS B can assume that all 4 spatial layers are reserved while BS A can program UE A for only 2 spatial layers.
[0081] In another embodiment, to reduce the overhead of RRS resources, an operator's programmed UEs can transmit RRS 662 signals on a common operator-specific resource instead of specific UE-specific space layer resources. For example, BS A can program two UEs for TXOP 202 and both UEs can transmit RRS 622a signals on the same common resource. In such a modality, BS B can determine a subscription or interference pattern of the common resource and
Petition 870190100411, of 10/07/2019, p. 46/110
40/71 determine a number of scheduled or reserved space layers and / or a number of UEs programmed based on the given signature or interference pattern.
[0082] As shown above, to facilitate SDMA through operators, in some cases, a BS or a UE may receive a signal that is intended for the BS or the UE, while in some other cases, a BS or a UE may detect a signal that is not specifically intended for BS or the UE, such as a signal intended for another BS or UE. While scheme 600 is described in the context of one BS per operator, scheme 600 can be used by any suitable number of BSs to communicate with any suitable number of UEs. In addition, since the sharing of spatial layers between operators is synchronized to the TXOP 605 frame structure, the sharing is referred to as synchronous SDMA.
[0083] Figure 7 is a signaling diagram of a media sharing method based on SDMA 700 according to the modalities of the present disclosure. Method 700 is implemented between a BS A, a UE A, a BS B, and a UE B. BSs A and B are similar to BSs 105, 305, and 500. UEs A and B are similar to UEs 115, 315, and 400. Method 700 steps can be performed by computing devices (for example, a process, processing circuit and / or other suitable component) from BSs A and B and UEs A and B. Method 700 can employ mechanisms similar to those of schemes 200 and 600 described in relation to Figures 2 and 6, respectively. As illustrated, method 700 includes a series of steps
Petition 870190100411, of 10/07/2019, p. 47/110
41/71 enumerated, but modalities of method 700 may include additional steps before, after and between the enumerated steps. In some embodiments, one or more of the steps listed may be omitted or performed in a different order. As an example, BS A and UE A are operated by Operator A, while BS B and UE B are operated by Operator B, where Operator A has priority over Operator B on a specific TXOP (for example, TXOP 202) over a shared spectrum (for example, spectrum 201).
[0084] In step 705, BS A obtains spatial layer information associated with Operator B. In step 710, BS B obtains spatial layer information associated with Operator A. For example, each of BSs A and B can support layers focal spatial (for example, layers 1, 2, 3, and 4).
[0085] In step 715, BS A communicates channel reservation information with UE A. Channel reservation information indicates a schedule for UE A at TXOP over space layers 1 and 2. For example, BS A
and the UE The exchange RRQ signals and RRs like described in 600 scheme.[0086] At step 720, The BS B communicates booking information channel with the UE B. The information
channel reservation indicates a schedule for UE B at TXOP over the other space layers 3 and 4. For example, BS B determines that space layers 1 and 2 are reserved by Operator A and space layers 3 and 4 are available and exchange RRQ and RRS signals with UE B as described in scheme 600.
Petition 870190100411, of 10/07/2019, p. 48/110
42/71
[0087] In step 725, UE A transmits an SRS A (for example, SRSs 624a) in each of the programmed space layers 1 and 2, for example, according to an SRS trigger received from an BS RRQ
THE.
[0088] In step 730, UE B transmits an SRS B (for example, SRSs 624b) in each of the programmed space layers 3 and 4, for example, according to an SRS trigger received from an BS RRQ
B.
[0089] In step 735, BS A monitors for SRSs A and B. Since BS A programmed space layers 1 and 2 and allocated SRS resources, BS A can receive SRSs A according to SRS resources allocated. However, BS A may not have prior knowledge about the spatial layers programmed by BS B and / or the SRS resources allocated by BS B. Therefore, BS A can apply blind decoding to detect SRSs B. In step 740, BS A can determine pre-coding parameters based on the SRSs A and B received. For example, pre-coding parameters can be in the form of a pre-coding matrix for spatial layers 1, 2, 3 and 4.
[0090] In step 745, BS B monitors for SRSs A and B. Since BS B programmed spatial layers 1 and 2 and allocated SRS resources, BS B can receive SRSs according to the resources of allocated SRS. As described above, BS B may have prior knowledge of the number of spatial layers and / or the number of UEs programmed by Operator A based on the detection of the RR signal. Thus, the
Petition 870190100411, of 10/07/2019, p. 49/110
43/71
BS B can leverage the reserve information (for example, programmed space layers 1 and 2) obtained from detecting the RRS signal to detect SRSs A. For example, BS B can monitor SRSs A in SRS resources corresponding to space layers 1 and 2. In step 750, BS B can determine pre-coding parameters for space layers 1, 2, 3 and 4 based on the received SRSs A and B.
[0091] In step 760, BS A communicates data (for example, data 226a) with UE A over spatial layers 1 and 2. The data is pre-coded based on the pre-coding parameters determined in step 740 .
[0092] In step 7 65, BS B communicates data (for example, data 22 6b) with UE B over spatial layers 3 and 4. The data is pre-coded based on the pre-coding parameters determined in step 750.
B6çBn; iB®: s [[[[: give [[[[: s [ináÍ; íBBdBO [[[[ábB [[[[BoBpBbUd: lháBênU: õ [[[[: give [[[[Bé: iõ: bãbd: ãdÕ7 :: éB7B; Í®7 ^ ÍÚé7: pÕ: déBiBd: B7: éOÃllBBdõ; d7 [foot; Magnet: S7 :: BS: S711: 0: 5: / s: s3: 0Í; is [[[[50 [i [[[and [[[ [éBpB [[[O [s [[[[lii [i [[[[3 [i5 [[[[is [[[[4Í | [ l [[[ÃÍ [[dé [S: çr [Í [t: ã | [[[[: nõ [[[[[çbhtõBB [õ [[[[[õB [[[[[Íúõ [[[[ [[õ [[[[[Qpé [radõ [f [[[[à [[[[[téB [[[[[b [i [õrÍdádê: ê: s: qúêBB [[[6; OR [[[ and [[[ãõ [[; Béb; õdõ [[[7 [OÉ [5 [[; ÉBs [[[In: gurã: s [[[8 [[[ã [[[lÉ7 [[[BB [[[ b: ixdl [[[k BépÍd; bélt: ãB7ibi7B; bBlbi7BB7iBiBei: si7: úlÍdÍd®; b7iBõhbU: ãhtdBsssbsssõb ^ is [ixõ [s [[[[[[[[y [ éhtBB [[[[[[[õ [[[[[[[[ÍBéqúeh: çiB [[[[[[[éB [[[[[[[[[[[[[[[[®ilÍÉsi; çõÃdtlhUéi.
[0094] Figure 8 illustrates a media sharing scheme based on SDMA 800 according to the modalities of this disclosure. Scheme 800 is similar to scheme 600, but uses SRS waveforms
Petition 870190100411, of 10/07/2019, p. 50/110
44/71 for channel sound and media reservations. As shown in frame structure 805, each period of CCA 204 includes a portion 207 and a period of SRS 804. The period of SRSs 804 may be substantially similar to the period of SRSs 604, but are operator specific.
[0095] In scheme 800, an Operator A BS A (for example, the high priority operator) transmits an RRQ signal 820a in portion 207 of the CCA 204a period to program an Operator A UE A over one or more layers in the 206 transmission period. The RRQ signal 820a can be substantially similar to the RRQ signal 620a. For example, the RRQ signal 820a may include an SRS schedule and trigger for UE A. The SRS trigger may indicate SRS resources in the SRS 804 period of the CCA 204a period. UE A responds by transmitting an SRS 624a according to each spatial layer programmed according to the SRS trigger.
[0096] An Operator B BS B (eg, low priority operator) can apply blind decoding to detect SRSs 624a from the SRS 804 period of the CCA 204a period. BS B can determine the spatial layers reserved by Operator A based on detected SRSs 624a. BS B can program an Operator B UE B over one or more unreserved spatial layers remaining in the 206 transmission period. BS B transmits an RRQ 820b signal in the 207 portion of the CCA 204b period indicating a programming and trigger trigger. SRS for UE B. The SRS trigger can indicate SRS resources in the SRS 804 period of the CCA 204b period. UE B responds by transmitting an SRS 624b according to each
Petition 870190100411, of 10/07/2019, p. 51/110
45/71 space layer programmed according to the SRS trigger. BS B receives SRSs 624b based on the SRS resources allocated by BS B.
[0097] BS A receives SRSs 624a based on the SRS resources assigned by BS A. BS A can apply blind decoding to detect SRSs 624b from the SRS 804 period of the CCA 204b period. Subsequently, BS A and BS B perform SDMA pre-coding based on the corresponding SRSs 624a and 624b received and / or detected using mechanisms similar to those described in scheme 600.
[0098] As can be seen, the 800 scheme can reduce resource overload using SRS waveforms for channel sound and media reservations. However, in some embodiments, the 800 scheme may not provide the same channel sound and / or media sharing performance as the 600 scheme and may increase the complexity of processing in low priority operators due to blind decoding. While scheme 800 is described in the context of one BS per operator, scheme 800 can be employed by any suitable number of BSs to communicate with any suitable number of UEs.
[0099] Figure 9 illustrates a media sharing scheme based on SDMA 900 according to the modalities of this disclosure. The 900 scheme is similar to the 600 and 800 scheme, but allows sharing of the spatial layer at a finer granularity such as in a subperiod or TTI granularity. For example, a BS concession can schedule
Petition 870190100411, of 10/07/2019, p. 52/110
46/71 different UEs in different TTIs or programming subperiods 210 within a TXOP 2 02. As shown in frame structure 905, each CCA 204 period includes a 907 portion. Each 907 portion can include FDM and / or TDM resources for RRQ signal transmissions (for example, a preamble) and information transmission programming.
[0100] In Scheme 900, a BS A from Operator A (for example, the high priority operator) transmits a
signal from RRQ 920a in portion 907 of period from CCA 204a for program one set of UEs THE for the subperiods 210. 0 signal in RRQ 92 0a may indicate programming
space layer and SRS resource information for each UE A programmed in each subperiod 210. The RRQ 920a signal can include a preamble similar to the RRQ 220 signals. The RRQ 920a signal can indicate a link direction for each 210 sub-period and / or if a low priority operator can share the remaining unreserved space layers.
[0101] To allow other operators to decode the space layer programming and SRS resource information, the RRQ 920a signal can be transmitted using mechanisms similar to the LTE physical downlink control channel (PDCCH). For example, the resources in portion 907 to carry explicit programming information can be divided into a plurality of predetermined search spaces. A search space can carry the space layer programming and SRS resource information to a UE programmed in a subperiod 210 of TXOP 202.
[0102] A BS B from Operator B (for example, the
Petition 870190100411, of 10/07/2019, p. 53/110
47/71 low priority operator) monitors an RRQ 920a signal from Operator A. Upon detecting the RRQ 920a signal, BS B can apply blind decoding to each search space to determine the space layer schedule and resource information of SRS of operator A for each subperiod 210. BS B can program one or more UEs B in subperiods 210 using the remaining available space layers based on the programming information for the space layer. BS B can program a UEs B in a subperiod 210 in the same direction as the transmission link, as indicated by BS A. BS B can skip programming in a specific subperiod 210 when BS A indicates that sharing the space layer does not is allowed in specific sub-period 210. BS B transmits an RRQ 920b signal to indicate space layer programming information and SRS resources for each UE B programmed in sub-periods 210 using mechanisms similar to BS A.
[0103] Subsequently, each of the programmed UEs A and B transmit an SRS 624 to each corresponding programmed spatial layer in the SRS 604 period, according to the SRS resource information. BS A receives SRSs 624a from UEs A based on the SRS resources assigned by BS A and detects SRSs 624b based on SRS resource information detected from the RRQ signal 920b. Likewise, BS B receives SRSs 624b from UEs B based on the SRS resources assigned by BS B and detects SRSs 624a based on SRS resource information detected from the RRQ signal 920a. BS A and BS B separately determine the pre-coding parameters for each subperiod 210 based on the SRSs
Petition 870190100411, of 10/07/2019, p. 54/110
48/71 received corresponding to 624a and 624b.
[0104] Figure 10 illustrates a media sharing scheme based on SDMA 1000 according to the modalities of the present disclosure. Scheme 1000 is similar to scheme 900, but all BS concessions and all programmed UEs of a specific operator transmit by TTI space layer programming and SRS resource information simultaneously, for example, in a single frequency network way (SEN). Scheme 1000 uses the same frame structure 605 as scheme 600. However, portions 208 can carry the concurrent transmissions of the programmed BSs and UEs.
[0105] In Scheme 1000, a BS A from Operator A (for example, the high priority operator) transmits an RRQ signal 1020a in portion 207 of CCA period 204a to program a set of UEs A for sub-periods 210. O RRQ signal 1020a may be similar to RRQ signal 620a, but may include space layer scheduling and SRS resource information for each UE A programmed in each subperiod 210.
[0106] All programmed A UEs and the BS A concession can simultaneously transmit an RRS 1022a signal in portion 208 of the CCA 204a period. The RRS 1022a signals can include a preamble or a predetermined sequence and the programming of the space layer and SRS resource information. Simultaneous transmissions can increase reception quality and detection performance on other operators.
[0107] Operator B's BS B (for example, the
Petition 870190100411, of 10/07/2019, p. 55/110
49/71 low priority operator) can determine Operator A's SRS resource layer programming and SRS resource information for each subperiod 210 by monitoring RRS signals 1022a. For example, BS B can decode the space layer programming and SRS resource information using the preamble or the predetermined sequence in the RRS signal as a reference signal for demodulation. BS B can schedule one or more UEs B in sub-periods 210 using the remaining available space layers based on the programming information for the space layer. BS B transmits an RRQ signal 1020b to indicate space layer programming and SRS resource information for each UE B programmed in each subperiod 210 using mechanisms similar to BS A. All programmed B UEs and the BS B grant can transmit simultaneously an RRS signal 1022b in portion 208 of the CCA 204b period echoing the space layer programming and SRS resource information.
[0108] Subsequently, each of the programmed UEs A and B transmit an SRS 624 in each corresponding programmed spatial layer in the SRS 604 period, according to the spatial layer programming and SRS resource information. BS A receives SRSs 624a from UEs A based on the SRS resources assigned by BS A and detects SRSs 624b based on SRS resource information detected from RRS signals 1022b. Likewise, BS B receives SRSs 624b from UEs B based on the SRS resources assigned by BS B and detects SRSs 624a based on SRS resource information detected by RRS signals 1022a. BS A and BS
Petition 870190100411, of 10/07/2019, p. 56/110
50/71
B separately determine the pre-coding parameters for each sub-period 210 based on the corresponding received SRSs 624a and 624b. In some embodiments, RRQ 1020 signals and / or RRS 1022 signals may indicate additional reservation information, such as a direction of the transmission link in a specific sub-period 210 and / or whether sharing of the remaining unreserved space layers is allowed .
[0109] The 900 and 1000 schemes can provide several benefits. For example, sharing the spatial layer at the finest granularity allows operators to better adapt to traffic and / or channel conditions. In addition, the 900 and 1000 scheme allows the unscheduled UEs to turn off certain components in the transceiver chains during the 206 transmission period and thus provide energy savings in the unscheduled UEs.
[0110] Figure 11 is a flow diagram of a media sharing method based on SDMA 1100 according to the modalities of this disclosure. The steps of method 1100 can be performed by a computing device (for example, processes, processing circuit and / or other suitable component) of a wireless communication device, such as BSs 105, 305 and 500 and UEs 115, 315 and 400. Method 1100 may employ mechanisms similar to those in schemes 200, 600, 800, 900, 1000 and method 700 described in relation to Figures 2, 6, 8, 9, 10 and 7, respectively. As illustrated, method 1100 includes a series of steps listed, but modalities of method 1100 may include
Petition 870190100411, of 10/07/2019, p. 57/110
51/71 additional steps before, after and between the steps listed. In some embodiments, one or more of the steps listed may be omitted or performed in a different order.
[0111] In step 1110, method 1100 includes transmitting a communication indicating a reservation for one or more spatial layers in a TXOP (for example, TXOP 102) of a shared spectrum (for example, the shared spectrum 101). The shared spectrum is shared by the plurality of network operational entities (for example, Operator A and Operator B) based on priorities. For example, the wireless communication device is associated with a first network operating entity (for example, Operator A) of the plurality of network operating entities. In one embodiment, the communication includes RRS signal signals such as RRS signal signals 622 or 1022 as described with respect to schemes 600 or 1000, respectively. In one embodiment, the communication includes SRSs such as the SRSs 624 described in relation to scheme 800. In one embodiment, the communication includes RRQ signals such as the RRQ signals 920 described in relation to scheme 900.
[0112] In step 1120, method 1100 includes communication data (for example, data 226) over one or more spatial layers during TXOP. The data is pre-encoded based on spatial channel information determined as described above.
[0113] Information and signals can be represented using any of a variety of different technologies and techniques. For example, data,
Petition 870190100411, of 10/07/2019, p. 58/110
52/71 instructions, commands, information, signals, bits, symbols and chips that can be referenced throughout the description above can be represented by voltages, currents, electromagnetic waves, magnetic fields or particles, optical fields or particles or any combination thereof .
[0114] The various blocks and illustrative modules described in connection with the disclosure contained herein may be implemented or executed with a general purpose processor, DSP, ASIC, FPGA or other programmable logic device, discrete gate logic or transistor, discrete hardware components or any combination thereof designed to perform the functions described here. A general purpose processor can be a microprocessor, but, alternatively, the processor can be any processor, controller, microcontroller or conventional state machine. A processor can also be implemented as a combination of computing devices (for example, a combination of a DSP and a microprocessor, several microprocessors, one or more microprocessors in conjunction with a DSP core or any other configuration).
[0115] The functions described in it can be implemented in hardware, software executed by a processor, firmware or any combination thereof. If implemented in software run by a processor, functions can be stored or transmitted as one or more instructions or code in a computer-readable medium. Other examples and implementations are within the scope of the disclosure and attached claims. For example, due to the nature of the software, the functions
Petition 870190100411, of 10/07/2019, p. 59/110
53/71 described above can be implemented using software run by a processor, hardware, firmware, wiring or combinations of any of them. Features that implement functions can also be physically located in various positions, including distribution, so that parts of the functions are implemented in different physical locations. In addition, as used here, including in the claims or, as used in a list of items (for example, a list of items preceded by a phrase such as at least one of or one or more of) indicates an inclusive list that, for example , a list of [at least one of A, B or C] means A or B or C or AB or AC or BC or ABC (that is, A and B and C).
[0116] The modalities of this disclosure include a wireless communication method that includes transmitting, through a first wireless communication device associated with a first network operational entity, a communication indicating a reservation for one or more space layers at an opportunity transmission (TXOP) of a shared spectrum, where the shared spectrum is shared by the first network operational entity and a second network operational entity; and communicating, over the first wireless communication device with a second wireless communication device associated with the first operational entity on the network, data over one or more spatial layers during TXOP.
[0117] The method also includes that the transmission includes transmitting one or more reserve response signals (RRS) using one or more resources assigned to the first
Petition 870190100411, of 10/07/2019, p. 60/110
54/71 wireless communication device, and each of the one or more resources corresponds to one of the one or more spatial layers. The method further includes that the transmission includes transmitting one or more reserve response signals (RRS) to indicate to one or more space layers reserved at the TXOP using the same resource as an RRS signal transmission from another wireless communication device. associated with the first operational entity of the network. The method further includes that the transmission includes transmitting one or more sound reference signals (SRSs) using one or more resources assigned to the first wireless communication device, where each of the one or more resources corresponds to one of the one or more spatial layers, and where each of the one or more SRSs provide spatial channel information for a corresponding spatial layer of one or more spatial layers. The method further includes receiving, by the first wireless communication device from the second wireless communication device, a reservation request signal (RRQ) indicating a first TXOP schedule for the first wireless communication device, and in which transmission is in response to the RRQ signal. The method further includes that the RRQ signal still indicates a second TXOP schedule for another wireless communication device associated with the first network operational entity, and wherein the transmission includes transmitting a reserve response signal (RRS) including the first schedule and second schedule. The method further includes that the transmission includes transmitting a reservation request signal (RRQ) indicating a first
Petition 870190100411, of 10/07/2019, p. 61/110
55/71 programming for communication with the second wireless communication device over one or more spatial layers during TXOP. The method also includes generating, by the first wireless communication device, the RRQ signal for encoding the first programming based on a first research space; and code a second TXOP schedule based on a different second search space from the first search space. The method further includes that the reservation still indicates a direction of the transmission link, and in which the communication of the data includes communicating the data in the direction of the transmission link. The method further includes in which the first operational entity of the network includes several supportable spatial layers including one or more spatial layers, and in which the reservation still indicates whether the sharing of remaining unreserved supportable spatial layers is allowed. The method further includes receiving, by the first wireless communication device from the second wireless communication device, a first set of sound reference signals (SRSs) corresponding to one or more spatial layers, in which the data is pre-coded based on at least the first set of SRSs. The method further includes detecting, by the first wireless communication device, a second set of SRSs from the second network operational entity corresponding to one or more other spatial layers, in which the data is still pre-coded based on the second set of SRSs. The method further includes obtaining, by the first wireless communication device, spatial layer information indicating supportable spatial layers
Petition 870190100411, of 10/07/2019, p. 62/110
56/71 of the second operational entity of the network, wherein the supportable space layers include one or more space layers and one or more other space layers; detect, by the first wireless communication device, another reservation for the TXOP from the second operational entity of the network which reserves one or more other space layers; and determining, by the first wireless communication device, to one or more space layers for communication with the second wireless communication device on the TXOP based on at least one other reservation and the space layer information. The method further includes that the detection of another reserve includes receiving one or more reserve response signals (RRS) indicating one or more other spatial layers. The method further includes that the detection of another reserve includes receiving the second set of SRSs. The method further includes that the detection of another reservation includes receiving a reservation request signal (RRQ); and determine by applying blind decoding to the
RRQ on one or more research spaces, which one or more other spatial layers are reserved for at least one of a first programming period within the
TXOP or a direction of the transmission link. The method further includes that the detection of another reserve includes receiving a reserve response signal (RRS); and determining, by demodulating the RRS signal, that one or more other spatial layers are reserved for at least one of a first programming period within the TXOP or a direction of the transmission link. The method further includes comprising determining, by the first
Petition 870190100411, of 10/07/2019, p. 63/110
57/71 wireless communication, that sharing of unreserved supportable spatial layers is allowed based on another reservation. The method further includes determining, by the first wireless communication device, that one or more other spatial layers are reserved for a first programming period within the TXOP based on another reservation, in which data communication includes communicating the data in the first programming period. The method further includes determining, by the first wireless communication device, that one or more other spatial layers are reserved for one direction of the transmission link based on another reservation, where communication still includes communicating data in the direction of the transmission link.
[0118] The modalities of the present disclosure also include a device comprising a transceiver configured to transmit a communication indicating a reservation for one or more space layers in a transmission opportunity (TXOP) of a shared spectrum, in which the shared spectrum is shared by a first network operational entity and a second network operational entity, and where the device is associated with the first network operational entity; and communicate, with a second wireless communication device associated with the first entity
network, data on a network or more layers space during the TXOP. [0119] 0 device still includes that the transceiver is still configured for transmit the
communication by transmitting one or more response signals
Petition 870190100411, of 10/07/2019, p. 64/110
58/71 reserve (RRS) using one or more resources assigned to the device, and each of the one or more resources corresponds to one of the one or more spatial layers. The apparatus further includes that the transceiver is further configured to transmit the communication by transmitting one or more reserve response signals (RRS) to indicate to one or more spatial layers reserved at the TXOP using the same resource as an RRS signal transmission. another wireless communication device associated with the first operational entity on the network. The apparatus further includes that the transceiver is further configured to transmit the communication by transmitting one or more audible reference signals (SRSs) using one or more resources assigned to the apparatus, where each one or more resources correspond to one of the one or more spatial layers, and each of the one or more SRSs provide spatial channel information for a corresponding spatial layer of one or more spatial layers. The apparatus further includes that the transceiver is further configured to receive, from the second wireless communication device, a reservation request signal (RRQ) indicating a first TXOP programming for the apparatus, and in which the communication is transmitted in response to the RRQ signal. The apparatus further includes that the
RRQ also indicates a second TXOP schedule for another wireless communication device associated with the first network operational entity, and the transceiver is further configured to transmit the communication by transmitting a reserve response signal (RRS) including the first schedule and the second
Petition 870190100411, of 10/07/2019, p. 65/110
59/71 programming. The apparatus further includes that the transceiver is further configured to transmit communication by transmitting a reservation request signal (RRQ) indicating a first schedule for communication with the second wireless communication device over one or more spatial layers during TXOP . The apparatus also includes a processor configured to generate the RRQ signal by encoding the first programming based on a first search space; and code a second TXOP schedule based on a different second search space from the first search space. The apparatus further includes that the reservation still indicates a direction of the transmission link, and in which the transceiver is further configured to communicate the data by communicating the data in the direction of the transmission link. The apparatus further includes in which the first operational entity of the network includes several supportable spatial layers including one or more spatial layers, and in which the reservation still indicates whether the sharing of remaining unreserved supportable spatial layers is allowed. The apparatus further includes that the transceiver is further configured to receive, from the second wireless communication device, a first set of sound reference signals (SRSs) corresponding to one or more spatial layers, and in which the data is pre-coded with based on at least the first set of SRSs. The apparatus also includes a processor configured to detect a second set of SRSs from the second network operational entity corresponding to one or more other spatial layers, in which the data is
Petition 870190100411, of 10/07/2019, p. 66/110
60/71 still pre-coded based on the second set of SRSs. The device also includes a processor configured to obtain spatial layer information indicating supportable spatial layers of the second operational entity of the network, in which the supportable spatial layers include one or more spatial layers and one or more other spatial layers; detect another reserve for TXOP from the second operational entity of the network that reserves one or more other space layers; and determining one or more space layers for communication with the second wireless communication device on the TXOP based on at least one other reservation and the space layer information. The apparatus also includes that the processor is further configured to detect another reserve by receiving one or more reserve response signals (RRS) indicating one or more other spatial layers. The device also includes that the processor is still configured to detect another reserve receiving the second set of SRSs. The device also includes that the processor is still configured to detect another reservation by receiving a reservation request signal (RRQ); and determine, by applying blind decoding to the RRQ signal over one or more search spaces, that one or more other spatial layers are reserved for at least one of the first programming period within the TXOP or a direction of the transmission link . The device also includes that the processor is further configured to detect another reserve by receiving a reserve response signal (RRS); and determine,
Petition 870190100411, of 10/07/2019, p. 67/110
61/71 by demodulating the RRS signal, which one or more other spatial layers are reserved for at least one of a first programming period within the TXOP or a direction of the transmission link. The apparatus further includes that the processor is further configured to determine that sharing of unreserved supportable spatial layers is permitted based on another reservation. The apparatus further includes that the processor is further configured to determine that one or more other spatial layers are reserved for a first programming period within the TXOP based on another reservation, and in which data communication includes communicating the data in the first programming period. The apparatus further includes that the processor is further configured to determine that one or more other spatial layers are reserved for one direction of the transmission link based on another reservation, and that communication still includes communicating data in the direction of the link. transmission.
[0120] The modalities of the present disclosure include a computer-readable medium having program code registered on it, the program code comprising code to cause a first wireless communication device associated with a first network operational entity to transmit a communication indicating a reservation for one or more spatial layers in a transmission opportunity (TXOP) of a shared spectrum, where the shared spectrum is shared by the first network operational entity and a second network operational entity; and code for
Petition 870190100411, of 10/07/2019, p. 68/110
62/71 cause the first wireless communication device to communicate, with a second wireless communication device associated with the first network operational entity, data over one or more spatial layers during TXOP.
[0121] The computer-readable medium further includes that the code causes the first wireless communication device to transmit the communication and is further configured to transmit one or more reserve response signals (RRS) using one or more resources designated for the first wireless communication device, and where each of the one or more resources corresponds to one of the one or more spatial layers. The computer-readable medium further includes that the code causes the first wireless communication device to transmit the communication and is further configured to transmit one or more reserve response signals (RRS) to indicate to one or more space layers reserved in the TXOP using the same resource as an RRS signal transmission from another wireless communication device associated with the first operational entity on the network. The computer-readable medium further includes that the code causes the first wireless communication device to transmit the communication and is further configured to transmit one or more audible reference signals (SRSs) using one or more resources assigned to the first communication device. wireless, where each of the one or more resources corresponds to one of the one or more spatial layers, and where each of the one or more SRSs provides spatial channel information for a corresponding spatial layer of the one or more spatial layers. The middle
Petition 870190100411, of 10/07/2019, p. 69/110
63/71 computer-readable also includes code to make the first wireless communication device receive, from the second wireless communication device, a reservation request signal (RRQ) indicating a first TXOP programming for the first wireless communication device, where the code causes the first wireless communication device to transmit the communication is further configured to transmit the communication in response to the RRQ signal. The computer-readable medium further includes that the RRQ signal still indicates a second programming on the TXOP for another wireless communication device associated with the first operational entity on the network, and where the code causes the first communication device without wire transmit communication is further configured to transmit a reserve response signal (RRS) including the first schedule and the second schedule. The computer-readable medium further includes that the code causes the first wireless communication device to transmit the communication and is further configured to transmit a reserve request signal (RRQ) indicating a first schedule for communicating with the second communication device without wire over to one or more spatial layers during TXOP. The computer-readable medium also includes code that causes the first wireless communication device to generate the RRQ signal by encoding the first programming based on a first search space; and code a second TXOP schedule based on a different second search space from the first search space. 0 means readable by
Petition 870190100411, of 10/07/2019, p. 70/110
64/71 computer still includes that the reservation still indicates a direction of the transmission link, and in which the code to cause the first wireless communication device to communicate data is still configured to communicate data in the direction of the streaming. The computer-readable medium further includes in which the first operational entity of the network includes several supportable spatial layers including one or more spatial layers, and in which the reservation still indicates whether the sharing of remaining unreserved supportable spatial layers is allowed. The computer-readable medium further includes code to cause the first wireless communication device to receive, from the second wireless communication device, a first set of sound reference signals (SRSs) corresponding to one or more spatial layers, where the data is pre-encoded based on at least the first set of SRSs. The computer-readable medium also includes code to cause the first wireless communication device to detect a second set of SRSs from the second network operational entity corresponding to one or more other spatial layers, where the data is still pre-defined. coded based on the second set of SRSs. The computer-readable medium further includes code to cause the first wireless communication device to obtain spatial layer information indicating supportable spatial layers from the second operational entity of the network, where the supported spatial layers include the one or more spatial layers and the one or more other layers
Petition 870190100411, of 10/07/2019, p. 71/110
65/71 space; code to cause the first wireless communication device to detect another reservation for TXOP from the second operational entity of the network which reserves one or more other space layers; and code to cause the first wireless communication device to determine one or more space layers for communication with the second wireless communication device on the TXOP based on at least one other buffer and the space layer information. The computer-readable medium further includes that the code to cause the first wireless communication device to detect another reserve is further configured to receive one or more reserve response signals (RRS) indicating one or more other spatial layers. . The computer-readable medium further includes that the code for causing the first wireless communication device to detect another buffer is further configured to receive the second set of SRSs. The computer-readable medium further includes that the code for causing the first wireless communication device to detect another reservation is further configured to receive a reservation request signal (RRQ); and determine, by applying blind decoding to the RRQ signal over one or more search spaces, that one or more other spatial layers are reserved for at least one of a first programming period within the TXOP or a direction of the broadcast link . The computer-readable medium further includes that the code to cause the first wireless communication device to detect another buffer is further configured to
Petition 870190100411, of 10/07/2019, p. 72/110
66/71 receive a reserve response signal (RRS); and determining, by demodulating the RRS signal, that one or more other spatial layers are reserved for at least one of a first programming period within the TXOP or a direction of the transmission link. The computer-readable medium further includes code to make the first wireless communication device determine that sharing of unreserved supportable space layers is permitted based on another reservation. The computer-readable medium further includes code to make the first wireless communication device determine that one or more other spatial layers are reserved for a first programming period within the TXOP based on another reservation, in which the code to make the first wireless communication device communicate data it is further configured to communicate data in the first programming period. The computer-readable medium further includes code to make the first wireless communication device determine that one or more other spatial layers are reserved for one direction of the transmission link based on another reservation, where the communication still includes communicate the data in the direction of the transmission link.
[0122] The modalities of the present disclosure also include a device comprising means to transmit a communication indicating a reservation for one or more spatial layers in a transmission opportunity (TXOP) of a shared spectrum, in which the shared spectrum is shared by a first
Petition 870190100411, of 10/07/2019, p. 73/110
67/71 network operational entity and a second network operational entity, and in which the device is associated with the first network operational entity; and means to communicate, with a second communication device without
wire associated with first entity operational gives network, Dice about a or more layers space during TXOP. [0123] 0 device still includes that the means
to transmit the communication they are further configured to transmit one or more reserve response signals (RRS) using one or more resources assigned to the device, and each of the one or more resources corresponds to one of the one or more spatial layers. The apparatus further includes that the means for transmitting the communication are further configured to transmit one or more reserve response signals (RRS) to indicate to one or more spatial layers reserved at the TXOP using the same resource as a transmission RRS signal. another wireless communication device associated with the first operational entity on the network. The apparatus further includes that the means for transmitting the communication are further configured to transmit one or more sound reference signals (SRSs) using one or more resources assigned to the apparatus, wherein each of the one or more resources corresponds to one of the one or more spatial layers, and each of the one or more SRSs provide spatial channel information for a corresponding spatial layer of one or more spatial layers. The apparatus further includes means for receiving, from the second wireless communication device, a reservation request signal (RRQ) indicating a
Petition 870190100411, of 10/07/2019, p. 74/110
68/71 first TXOP programming for the device, in which communication is transmitted in response to the RRQ signal. The apparatus further includes that the RRQ signal still indicates a second TXOP programming for another wireless communication device associated with the first network operational entity, and in which the means for transmitting the communication are further configured to transmit a signal. reserve response (RRS) including the first schedule and the second schedule. The apparatus further includes that the means for transmitting the communication are further configured to transmit a reserve request signal (RRQ) indicating a first schedule for communicating with the second wireless communication device over one or more spatial layers during the TXOP. The apparatus further includes means for generating the RRQ signal by encoding the first programming based on a first search space; and code a second TXOP schedule based on a different second search space from the first search space. The apparatus further includes that the reservation still indicates a direction of the transmission link, and in which the means for communicating the data are further configured to communicate the data in the direction of the transmission link. The apparatus further includes in which the first operational entity of the network includes several supportable spatial layers including one or more spatial layers, and in which the reservation still indicates whether the sharing of remaining unreserved supportable spatial layers is allowed. The apparatus further includes means for receiving, from the second wireless communication device, a
Petition 870190100411, of 10/07/2019, p. 75/110
69/71 first set of sound reference signals (SRSs) corresponding to one or more spatial layers, in which data is pre-coded based on at least the first set of SRSs. The apparatus further includes means for detecting a second set of SRSs from the second operational entity of the network corresponding to one or more other spatial layers, where the data is still pre-coded based on the second set of SRSs. The apparatus further includes means for obtaining spatial layer information indicating supportable spatial layers from the second operational entity of the network, wherein the supportable spatial layers include one or more spatial layers and one or more other spatial layers; means for detecting another reservation for TXOP from the second operational entity of the network which reserves one or more other space layers; and means for determining one or more space layers to communicate with the second wireless communication device on the TXOP based on at least one other reservation and the space layer information. The apparatus further includes that the means for detecting another reserve is further configured to receive one or more reserve response signals (RRS) indicating one or more other spatial layers. The apparatus further includes that the means for detecting another reserve is further configured to receive the second set of SRSs. The apparatus further includes that the means for detecting another reservation is further configured to receive a reservation request signal (RRQ); and determine, applying blind decoding to the RRQ signal over one or more
Petition 870190100411, of 10/07/2019, p. 76/110
70/71 research spaces, which one or more other spatial layers are reserved for at least one of a first programming period within the TXOP or a direction of the transmission link. The apparatus further includes that the means for detecting another reserve is further configured to receive a reserve response signal (RRS); and determining, by demodulating the RRS signal, that one or more other spatial layers are reserved for at least one of a first programming period within the TXOP or a direction of the transmission link. The device also includes means to determine that sharing of unreserved supportable space layers is allowed based on another reservation. The apparatus further includes that the means for determining that one or more other spatial layers are reserved for a first programming period within the TXOP based on another reservation, and in which the means for communicating the data are further configured to communicate the data. data in the first programming period. The apparatus further includes means for determining that one or more other spatial layers are reserved for one direction of the transmission link based on another reservation, in which the means for communicating the data are further configured to communicate the data in the direction of the link. transmission.
[0124] As people versed in this technique will already appreciate and, depending on the specific application in question, many modifications, substitutions and variations can be made in the materials, devices, configurations and methods of use of the devices of the present disclosure
Petition 870190100411, of 10/07/2019, p. 77/110
71/71 without departing from the spirit and scope. In light of this, the scope of this disclosure should not be limited to that of the particular modalities illustrated and described in this document, since they are merely by means of some examples of them, but must be fully proportional to that of the appended claims below and their equivalents functional.

权利要求:
Claims (17)
[1]
1. Wireless communication method, comprising:
transmit, by a first wireless communication device associated with a first network operational entity, a communication indicating a reservation for one or more spatial layers in a transmission opportunity (TXOP) of a shared spectrum, where the shared spectrum is shared the first network operational entity and a second network operational entity; and communicating, over the first wireless communication device with a second wireless communication device associated with the first operational entity on the network, data over one or more spatial layers during TXOP.
[2]
A method according to claim 1, wherein the transmission includes transmitting one or more reserve response signals (RRS) using one or more resources designated for the first wireless communication device, and in which each of the one or more resources correspond to one of the one or more spatial layers.
[3]
A method according to claim 1, wherein the transmission includes transmitting one or more reserve response signals (RRS) to indicate one or more spatial layers reserved at the TXOP using the same resource as a transmission of the RRS signal another wireless communication device associated with the first operational entity on the network.
[4]
A method according to claim 1, wherein the transmission includes transmitting one or more
Petition 870190100411, of 10/07/2019, p. 79/110
2/17 sound reference (SRSs) using one or more features assigned to the first wireless communication device, where each of the one or more features corresponds to one of the one or more spatial layers, and where each of the one or more most SRSs provide space channel information for a corresponding space layer of one or more space layers.
[5]
5. Method according to claim 1, further comprising receiving, by the first wireless communication device from the second wireless communication device, a reservation request signal (RRQ) indicating a first TXOP programming for the first wireless communication device, and where transmission is in response to the RRQ signal.
[6]
6. Method according to claim 5, wherein the RRQ signal still indicates a second TXOP programming for another wireless communication device associated with the first network operational entity, and wherein the transmission includes transmitting a signal reserve response (RRS) including the first schedule and the second schedule.
[7]
7. Method according to claim 1, wherein the transmission includes transmitting a reserve request signal (RRQ) indicating a first schedule for communicating with the second wireless communication device over one or more spatial layers during TXOP .
[8]
8. Method according to claim 7, further comprising generating, by the first wireless communication device, the RRQ signal by:
encode the first schedule based on a
Petition 870190100411, of 10/07/2019, p. 80/110
3/17 first research space; and code a second TXOP schedule based on a different second search space from the first search space.
[9]
9. Method according to claim 1, in which the reservation still indicates a direction of the transmission link, and in which the communication of the data includes communicating the data in the direction of the transmission link.
[10]
10. Method according to claim 1, wherein the first operational entity of the network includes several supportable spatial layers including one or more spatial layers, and the reservation further indicates whether the sharing of remaining unreserved supportable spatial layers is allowed.
11 Method, in wake up with claim 1, comprises still receive , by the first device in Communication wireless from the second device in Communication wireless, one first set of signs in reference sound (SRSs) corresponding to one or more spatial layers, in what the data are pre-coded with
based on at least the first set of SRSs.
12. The method of claim 11, further comprising detecting, by the first wireless communication device, a second set of SRSs from the second network operational entity corresponding to one or more other spatial layers, in which the data is still pre-coded based on the second set of SRSs.
13. The method of claim 12, further comprising:
obtain, by the first communication device
Petition 870190100411, of 10/07/2019, p. 81/110
4/17 wireless, spatial layer information indicating supportable spatial layers of the second operational entity of the network, where the supportable spatial layers include one or more spatial layers and one or more other spatial layers;
detect, by the first wireless communication device, another reservation for the TXOP from the second operational entity of the network which reserves one or more other space layers; and determining, by the first wireless communication device, to one or more space layers for communication with the second wireless communication device on the TXOP based on at least one other reservation and the space layer information.
14. The method of claim 13, wherein detecting another reserve includes receiving one or more reserve response signals (RRS) indicating one or more other spatial layers.
15. The method of claim 13, wherein detecting another reserve includes receiving the second set of SRSs.
16. The method of claim 13, wherein detecting another reserve includes:
receive a reservation request signal (RRQ); and determine, by applying blind decoding to the RRQ signal over one or more search spaces, that one or more other spatial layers are reserved for at least one of a first programming period within the TXOP or a direction of the broadcast link .
Petition 870190100411, of 10/07/2019, p. 82/110
5/17
17. The method of claim 13, wherein detecting another reserve includes:
receiving a reserve response signal (RRS); and determining, by demodulating the RRS signal, that one or more other spatial layers are reserved for at least one of a first programming period within the TXOP or a direction of the transmission link.
18. The method of claim 13, further comprising determining, by the first wireless communication device, that the sharing of unreserved supportable space layers is permitted based on another reservation.
19. The method according to claim 13, further comprising determining, by the first wireless communication device, that one or more other spatial layers are reserved for a first programming period within the TXOP based on another reservation, in that data communication includes communicating data in the first programming period.
20. Method according to claim 13, further comprising determining, by the first wireless communication device, that one or more other spatial layers are reserved for a direction of the transmission link based on another reservation, in which the communication further includes communicating the data in the direction of the transmission link.
21. Apparatus comprising:
means for transmitting a communication indicating a reservation for one or more spatial layers in a spectrum transmission opportunity (TXOP)
Petition 870190100411, of 10/07/2019, p. 83/110
6/17 shared, in which the shared spectrum is shared by a first network operational entity and a second network operational entity, and in which the device is associated with the first network operational entity; and means for communicating, with a second wireless communication device associated with the first network operational entity, data over one or more spatial layers during TXOP.
22. Apparatus according to claim 21, wherein the means for transmitting the communication are further configured to transmit one or more reserve response signals (RRS) using one or more resources assigned to the apparatus, and in which each one or more resources correspond to one of the one or more spatial layers.
23. Apparatus according to claim 21, wherein the means for transmitting the communication are further configured to transmit one or more reserve response signals (RRS) to indicate to one or more spatial layers reserved on the TXOP using the same resource as an RRS signal transmission from another wireless communication device associated with the first operational entity on the network.
24. Apparatus, according to claim 21, wherein the means for transmitting communication are further configured to transmit one or more sound reference signals (SRSs) using one or more resources designated for the apparatus, in which each one or more resources correspond to one of the one or more spatial layers, and each of the one or more SRSs provide
Petition 870190100411, of 10/07/2019, p. 84/110
7/17 space channel information for a corresponding space layer of one or more space layers.
25. Apparatus according to claim 21, further comprising:
means for receiving, from the second wireless communication device, a reservation request signal (RRQ) indicating a first TXOP programming for the device, in which the means for transmitting the communication are further configured to transmit the communication in response to the RRQ signal.
26. Apparatus according to claim 25, wherein the RRQ signal still indicates a second programming on the TXOP for another wireless communication device associated with the first network operational entity, and in which the means for transmitting the communication they are also configured to transmit a reserve response signal (RRS) including the first schedule and the second schedule.
27. Apparatus according to claim 21, wherein the means for transmitting communication are further configured to transmit a reservation request signal (RRQ) indicating a first schedule for communication with the second wireless communication device over a or more spatial layers during TXOP.
28. Apparatus according to claim 27, further comprising means for generating the RRQ signal by:
codify the first programming based on a first research space; and code a second TXOP programming with
Petition 870190100411, of 10/07/2019, p. 85/110
8/17 base in a second different research space from the first research space.
29. Apparatus according to claim 21, in which the reservation still indicates a direction of the transmission link, and in which the means for communicating the data are further configured to communicate the data in the direction of the transmission link.
30. Apparatus according to claim 21, in which the first operational entity of the network includes several supportable spatial layers including one or more spatial layers, and in which the reservation still indicates whether the sharing of remaining unreserved supportable spatial layers is allowed.
31. The apparatus of claim 21, further comprising:
means for receiving, from the second wireless communication device, a first set of sound reference signals (SRSs) corresponding to one or more spatial layers, in which the data is pre-coded based on at least the first set of SRSs.
32. Apparatus according to claim 31, further comprising:
means for detecting a second set of SRSs from the second operational entity of the network corresponding to one or more other spatial layers, where the data is still pre-coded based on the second set of SRSs.
33. The apparatus of claim 32, further comprising:
Petition 870190100411, of 10/07/2019, p. 86/110
9/17 means for obtaining spatial layer information indicating supportable spatial layers of the second operational entity of the network, wherein the supportable spatial layers include one or more spatial layers and one or more other spatial layers;
means for detecting another reservation for TXOP from the second operational entity of the network which reserves one or more other space layers; and means for determining one or more space layers to communicate with the second wireless communication device on the TXOP based on at least one other reservation and the space layer information.
34. The apparatus of claim 33, wherein the means for detecting another reserve is further configured to receive one or more reserve response signals (RRS) indicating one or more other spatial layers.
35. Apparatus according to claim 33, wherein the means for detecting another reserve is further configured to detect another reserve receiving the second set of SRSs.
36. Apparatus according to claim 33, wherein the means for detecting another reserve is further configured to detect another reserve by:
receive a reservation request signal (RRQ); and determine, by applying blind decoding to the RRQ signal over one or more research spaces, that one or more other spatial layers are reserved for at least one of a first programming period within
Petition 870190100411, of 10/07/2019, p. 87/110
10/17 of the TXOP or a direction of the transmission link.
37. Apparatus according to claim 33, wherein the means for detecting another reserve is further configured to:
receiving a reserve response signal (RRS); and determining, by demodulating the RRS signal, that one or more other spatial layers are reserved for at least one of a first programming period within the TXOP or a direction of the transmission link.
38. Apparatus according to claim 33, further comprising:
means of determining that sharing of unreserved supportable space layers is permitted based on another reservation.
39. Apparatus according to claim 33, further comprising:
means for determining that one or more other spatial layers are reserved for a first programming period within the TXOP based on another reservation, wherein the means for communicating the data are further configured to communicate the data in the first programming period.
40. Apparatus according to claim 33, further comprising:
means for determining that one or more other spatial layers are reserved for one direction of the transmission link based on another reservation, wherein the means for communicating data are further configured to communicate data in the direction of the transmission link
Petition 870190100411, of 10/07/2019, p. 88/110
[11]
11/17 transmission.
41. Computer readable medium having program code registered on it, the program code comprising:
code to cause a first wireless communication device associated with a first network operational entity to transmit a communication indicating a reservation for one or more space layers in a shared spectrum (TXOP) transmission opportunity, where the shared spectrum it is shared by the first network operational entity and a second network operational entity; and code to cause the first wireless communication device to communicate, with a second wireless communication device associated with the first network operational entity, data on one or more spatial layers during TXOP.
42. A computer-readable medium according to claim 41, wherein the code causes the first wireless communication device to transmit the communication is further configured to transmit one or more reserve response signals (RRS) using one or more more resources assigned to the first wireless communication device, and each of the one or more resources corresponds to one of the one or more spatial layers.
43. A computer-readable medium according to claim 41, wherein the code causes the first wireless communication device to transmit the communication is further configured to transmit one or more
Petition 870190100411, of 10/07/2019, p. 89/110
[12]
12/17 reservation response (RRS) to indicate one or more spatial layers reserved at TXOP using the same resource as an RRS signal transmission from another wireless communication device associated with the first operational entity on the network.
44. Computer-readable medium according to claim 41, wherein the code causes the first wireless communication device to transmit the communication and is further configured to transmit one or more audible reference signals (SRSs) using one or more resources assigned to the first wireless communication device, where each of the one or more resources corresponds to one of the one or more spatial layers, and where each of the one or more SRSs provides spatial channel information for a corresponding spatial layer one or more spatial layers.
45. Computer-readable medium according to claim 41, further comprising:
code to cause the first wireless communication device to receive a reserve request signal (RRQ) from the second wireless communication device indicating a first TXOP programming for the first wireless communication device, where the code causes the first wireless communication device to transmit the communication and is further configured to transmit the communication in response to the RRQ signal.
46. Computer-readable medium, according to claim 45, in which the RRQ signal still indicates a second TXOP programming for another
Petition 870190100411, of 10/07/2019, p. 90/110
[13]
13/17 wireless communication associated with the first network operational entity, and where the code causes the first wireless communication device to transmit the communication is further configured to transmit a reserve response signal (RRS) including the first programming and the second schedule.
47. Computer-readable medium, according to claim 41, in which the code causes the first wireless communication device to transmit the communication is further configured to transmit a reservation request signal (RRQ) indicating a first programming for communication with the second wireless communication device over one or more spatial layers during TXOP.
48. A computer-readable medium according to claim 47, still comprising code, causes the first wireless communication device to generate the RRQ signal by:
codify the first programming based on a first research space; and code a second TXOP schedule based on a different second search space from the first search space.
49. Computer readable medium, according to claim 41, in which the reservation still indicates a direction of the transmission link, and in which the code to make the first wireless communication device communicate data is still configured to communicate the data in the direction of the transmission link.
50. Computer readable medium, according to
Petition 870190100411, of 10/07/2019, p. 91/110
[14]
14/17 claim 41, wherein the first operational entity of the network includes several supportable spatial layers including one or more spatial layers, and where the reservation further indicates whether the sharing of remaining unreserved supportable spatial layers is allowed.
51. Computer-readable medium, according to claim 41, further comprises:
code to make the first wireless communication device receive, from the second wireless communication device, a first set of sound reference signals (SRSs) corresponding to one or more spatial layers, in which the data is pre- coded based on at least the first set of SRSs.
52. Computer-readable medium according to claim 51, further comprising:
code to cause the first wireless communication device to detect a second set of SRSs from the second network operational entity corresponding to one or more other spatial layers, where the data is still pre-encrypted based on the second set of SRSs.
53. Computer-readable medium according to claim 52, further comprising:
code to make the first wireless communication device obtain spatial layer information indicating supportable spatial layers from the second operational entity of the network, where the supportable spatial layers include one or more spatial layers and one or more other spatial layers;
Petition 870190100411, of 10/07/2019, p. 92/110
[15]
15/17 code to cause the first wireless communication device to detect another reservation for TXOP from the second operational entity of the network that reserves one or more other space layers; and code to cause the first wireless communication device to determine one or more space layers for communication with the second wireless communication device on the TXOP based on at least one other buffer and the space layer information.
54. Computer-readable medium according to claim 53, in which the code to cause the first wireless communication device to detect another reservation is further configured to receive one or more reservation response signals (RRS) indicating one or more other spatial layers.
55. Computer-readable medium according to claim 53, wherein the code for causing the first wireless communication device to detect another buffer is further configured to receive the second set of SRSs.
56. A computer-readable medium according to claim 53, in which the code to cause the first wireless communication device to detect another reservation is further configured to:
receive a reservation request signal (RRQ); and determine, by applying blind decoding to the RRQ signal over one or more research spaces, that one or more other spatial layers are reserved for at least one of a first programming period within
Petition 870190100411, of 10/07/2019, p. 93/110
[16]
16/17 of the TXOP or a direction of the transmission link.
57. A computer-readable medium according to claim 53, in which the code to cause the first wireless communication device to detect another reservation is further configured to:
receiving a reserve response signal (RRS); and determining, by demodulating the RRS signal, that one or more other spatial layers are reserved for at least one of a first programming period within the TXOP or a direction of the transmission link.
58. A computer-readable medium according to claim 53, further comprising:
code to make the first wireless communication device determine that sharing of unreserved supportable space layers is allowed based on another reservation.
59. Computer-readable medium according to claim 53, further comprising:
code to make the first wireless communication device determine that one or more other space layers are reserved for a first programming period within the TXOP based on another reservation, in which the code for making the first device Wireless communication to communicate data is further configured to communicate data in the first programming period.
60. Computer-readable medium according to claim 53, further comprising:
code to make the first device
Petition 870190100411, of 10/07/2019, p. 94/110
[17]
17/17 wireless communication determines that one or more other spatial layers are reserved for one direction of the transmission link based on another reservation, where communication still includes communicating data in the direction of the transmission link.

类似技术:

---

公开号 | 公开日 | 专利标题

---

BR112019021076A2|2020-05-12|MULTIPLE ACCESS BY SPACE DIVISION | THROUGH MULTIPLE OPERATORS

---

US10841870B2|2020-11-17|Discovery for spectrum renting

---

US10575185B2|2020-02-25|Spectrum renting negotiation

---

US10231131B2|2019-03-12|Autonomous uplink | transmission in new radio-spectrum sharing |

---

US10123358B2|2018-11-06|Priority management for new radio-spectrum sharing |

---

US10715301B2|2020-07-14|Radio-spectrum sharing | in frequency-division duplexing | spectrum

---

US10616771B2|2020-04-07|Opportunistic reclaiming of resources in new radio-spectrum sharing |

---

TWI735715B|2021-08-11|Dynamic medium sharing

---

US20180324856A1|2018-11-08|Control information update for dynamic time-division duplexing |

---

EP3571858B1|2021-04-14|Dynamic time-division duplexing | in new radio-spectrum sharing | and self-contained subframe structure

---

BR112020006877A2|2020-10-06|random withdrawal process to hear before speaking | space

---

CN110226348B|2022-02-18|Interference management for new radio-spectrum sharing |

---

US20210185719A1|2021-06-17|Channel access contention management for ultra-reliable low-latency communication |

---

TWI746689B|2021-11-21|Priority management for new radio-spectrum sharing |

同族专利:

---

公开号 | 公开日

---

TW201842792A|2018-12-01|

---

CN110603832A|2019-12-20|

---

JP6982095B2|2021-12-17|

---

KR20190139861A|2019-12-18|

---

WO2018190979A1|2018-10-18|

---

US20180302796A1|2018-10-18|

---

SG11201907928UA|2019-10-30|

---

EP3610668A1|2020-02-19|

---

JP2020517160A|2020-06-11|

---

US10433179B2|2019-10-01|

引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

---

US8670390B2|2000-11-22|2014-03-11|Genghiscomm Holdings, LLC|Cooperative beam-forming in wireless networks|

---

JP3816334B2|2000-12-22|2006-08-30|株式会社エヌ・ティ・ティ・ドコモ|Radio resource allocation method and base station|

---

EP1389884A1|2002-08-13|2004-02-18|Siemens Aktiengesellschaft|Method to operate a radio system using directional antennas and sending station and radio system|

---

CN100551119C|2005-11-11|2009-10-14|上海贝尔阿尔卡特股份有限公司|The method and the base station that are used for allocated bandwidth in the wireless single-hop self-return network|

---

JP2011512705A|2008-01-08|2011-04-21|ノキアシーメンスネットワークスオサケユキチュア|Sounding reference signal configuration|

---

WO2011139189A1|2010-05-04|2011-11-10|Telefonaktiebolaget L M Ericsson |Method and arrangement in a wireless communication system|

---

US20160212625A1|2015-01-19|2016-07-21|Qualcomm Incorporated|Medium access for shared or unlicensed spectrum|US10499409B2|2012-02-02|2019-12-03|Genghiscomm Holdings, LLC|Cooperative and parasitic radio access networks|

---

CN109923828B|2017-05-01|2022-02-01|Lg 电子株式会社|Method for detecting terminal in wireless communication system and apparatus for the same|

---

US10756860B2|2018-11-05|2020-08-25|XCOM Labs, Inc.|Distributed multiple-input multiple-output downlink configuration|

---

US10812216B2|2018-11-05|2020-10-20|XCOM Labs, Inc.|Cooperative multiple-input multiple-output downlink scheduling|

---

US10659112B1|2018-11-05|2020-05-19|XCOM Labs, Inc.|User equipment assisted multiple-input multiple-output downlink configuration|

---

US10432272B1|2018-11-05|2019-10-01|XCOM Labs, Inc.|Variable multiple-input multiple-output downlink user equipment|

---

US11063645B2|2018-12-18|2021-07-13|XCOM Labs, Inc.|Methods of wirelessly communicating with a group of devices|

---

US10756795B2|2018-12-18|2020-08-25|XCOM Labs, Inc.|User equipment with cellular link and peer-to-peer link|

---

US10756767B1|2019-02-05|2020-08-25|XCOM Labs, Inc.|User equipment for wirelessly communicating cellular signal with another user equipment|

---

US10756782B1|2019-04-26|2020-08-25|XCOM Labs, Inc.|Uplink active set management for multiple-input multiple-output communications|

---

US11032841B2|2019-04-26|2021-06-08|XCOM Labs, Inc.|Downlink active set management for multiple-input multiple-output communications|

---

US10735057B1|2019-04-29|2020-08-04|XCOM Labs, Inc.|Uplink user equipment selection|

---

US10686502B1|2019-04-29|2020-06-16|XCOM Labs, Inc.|Downlink user equipment selection|

法律状态:
2021-10-19| B350| Update of information on the portal [chapter 15.35 patent gazette]|

优先权:

---

申请号 | 申请日 | 专利标题

---

US201762484730P| true| 2017-04-12|2017-04-12|

---

US62/484,730|2017-04-12|

---

US15/787,141|2017-10-18|

---

US15/787,141|US10433179B2|2017-04-12|2017-10-18|Spatial-division multiple accessacross multiple operators|

---

PCT/US2018/022153|WO2018190979A1|2017-04-12|2018-03-13|Spatial-division multiple accessacross multiple operators|

---