WO2021062892A1 - Method and device for dynamic indication of resources - Google Patents
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- WO2021062892A1 WO2021062892A1 PCT/CN2019/112787 CN2019112787W WO2021062892A1 WO 2021062892 A1 WO2021062892 A1 WO 2021062892A1 CN 2019112787 W CN2019112787 W CN 2019112787W WO 2021062892 A1 WO2021062892 A1 WO 2021062892A1
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- H—ELECTRICITY
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- H04L5/00—Arrangements affording multiple use of the transmission path
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
Definitions
- This application relates to the field of communication technology, and in particular to a method and device for dynamically indicating resources.
- a wireless relay node establishes a connection with the core network through a wireless backhaul link, which can save part of the fiber deployment cost.
- the relay node RN establishes a wireless backhaul link with one or more upper-level nodes, and accesses the core network through the upper-level nodes.
- the upper node can control the relay node through a variety of signaling (for example, data scheduling, timing modulation, power control, etc.).
- the relay node can also provide services for multiple subordinate nodes.
- the upper-level node of the relay node may be a base station or another relay node; the lower-level node of the relay node may be another relay node or a terminal equipment (UE).
- UE terminal equipment
- the upper-level node may also be called the upstream node, and the lower-level node may also be called the downstream node.
- In-band relay is a relay solution in which the backhaul link and the access link share the same frequency band. Since no additional spectrum resources are used, the in-band relay has the advantages of high spectrum efficiency and low deployment cost. In-band relay generally has a half-duplex constraint. Specifically, a relay node cannot send a downlink signal to its lower-level node when receiving a downlink signal sent by its upper-level node, while a relay node is receiving an uplink signal sent by its lower-level node. It cannot send an uplink signal to its superior node.
- the in-band relay scheme of the new generation wireless communication system (new radio, NR) is called integrated access and backhaul (IAB), and the relay node is usually called an IAB node (IAB node).
- the IAB node includes a terminal (mobile termination, MT) function and a distributed unit (distributed unit, DU) function.
- the terminal function is hereinafter referred to as a terminal unit, and specifically refers to a certain function/module that resides on an IAB node to distinguish it from the terminal equipment UE that can be used as a lower-level node in this application.
- the MT is used for the communication between the IAB node and the upper-level node
- the DU is used for the communication between the IAB node and the lower-level node.
- the lower-level node can be the terminal equipment UE or other IAB nodes.
- the link between the MT and the upper-level node is called the parent BH link
- the link between the DU and the lower-level IAB node is called the child BH link
- the DU and the lower-level UE The link through which nodes communicate is called an access link.
- the DU of the IAB node may have multiple cells (cells), and different DU cells may be sectors with different orientations, or may be carriers of different frequency bands.
- the MT of the IAB node may also have multiple carriers in different frequency bands.
- This application provides a method for dynamically indicating resources, which can realize dynamic resource sharing of backhaul resources and access resources.
- This application provides a dynamic resource indication method, which solves the problem of dynamic resource indication when the MT of the IAB node has multiple carriers and DUs have multiple cells.
- this application provides a method for dynamically indicating resources.
- the method includes: a first node receives first indication information sent by a second node or a host node, and the first indication information is used to indicate D in the first node.
- the first node receives the second indication information sent by the second node, and the second indication information is used to indicate the availability of the first resources corresponding to the D carriers in the first node
- the second indication information sent by the second node may indicate the available status of the available resources of the first resources corresponding to the D carriers and the available status of the dynamic resources of the second resources corresponding to the F cells, and the first node may Determine the cell and carrier to which the second indication information is applied, so that in the case of MT multi-carrier DU multi-cell, the available status of the first resource corresponding to D carriers and the second resource corresponding to F cells can be realized The available status of the dynamic resources can be accurately indicated.
- the first node receives the second indication information sent by the second node, and the second indication information is only used to indicate the first node corresponding to the D carriers in the first node.
- the available state of the available resource of the resource the first node determines the available state of the available resource of the first resource corresponding to the D carriers according to the second indication information; the first node determines the available state of the available resource of the first resource corresponding to the D carriers according to the second indication information ,
- the resource reuse relationship between the first resources corresponding to the D carriers and the second resources corresponding to the F cells determines the available status of the dynamic resources of the second resources corresponding to the F cells.
- the MT resource of the IAB node can be displayed and indicated by the superior node of the IAB node, and the availability of the DUsoft resource can be derived based on the resource reuse or association relationship between each carrier of the MT and each cell of the DU.
- the first node receives the second indication information sent by the second node, and the second indication information is only used to indicate the second indication information corresponding to the F cells in the first node.
- the available state of the dynamic resource of the resource; the first node determines the available state of the dynamic resource of the second resource corresponding to the F cells according to the second indication information; the available state of the dynamic resource of the second resource corresponding to the F cells of the first node,
- the resource reuse relationship between the first resources corresponding to the D carriers and the second resources corresponding to the F cells determines the available state of the available resources of the first resources corresponding to the D carriers.
- the DU soft resources of the IAB node can be displayed by the upper node of the IAB node, and the availability of the MT resource can be derived based on the resource reuse or association relationship between each carrier of the MT and each cell of the DU.
- the second node is an upper-level node of the first node; the first resource is a transmission resource for communication between the first node and the second node, and the second resource is the first node The transmission resource for communicating with the third node, and the third node is a subordinate node of the first node.
- the available resource of the first resource is an available resource determined after the first resource is configured through a semi-static resource.
- the dynamic resource of the second resource is a dynamic resource determined after the second resource is configured through a semi-static resource.
- the resource reuse relationship between the first resources corresponding to D carriers and the second resources corresponding to F cells includes at least one of the following: time division multiplexing, Half-duplex frequency division multiplexing, half-duplex space division multiplexing, full duplex, dynamic adaptive frequency division multiplexing, dynamic adaptive space division multiplexing, dynamic adaptive full duplex.
- the IAB node and the upper-level node can derive the available/unavailable resources of the IAB MT according to the above-mentioned resource reuse relationship.
- the IAB node and the upper-level node may derive the available status of the DUsoft resources of the IAB node according to the above-mentioned resource reuse relationship.
- the IAB node and the upper-level node can derive the available status of the MT available resources of the IAB node according to the above-mentioned resource reuse relationship.
- the indication range of the second indication information includes at least one of the following: the available resources of the first resource determined by the semi-static resource configuration; A first set of resources to be indicated that has a resource reuse relationship with G cells determined by a cell; a second set of resources to be indicated consisting of part of the first resources indicated by a second node or a donor node; a second node or host A third resource set to be indicated consisting of all resources in the first resource indicated by the node.
- the second indication information includes the identities of D carriers and/or the identities of F cells.
- the second indication information is downlink control information DCI.
- the downlink control information DCI further includes at least one of the following information: control resource set information, search space set information, indication delay information, and indication range information.
- this application provides a relay device that has the function of implementing the method in the first aspect and any possible implementation manners thereof.
- the function can be realized by hardware, or by hardware executing corresponding software.
- the hardware or software includes one or more units corresponding to the above-mentioned functions.
- the present application provides a computer-readable storage medium in which computer instructions are stored.
- the computer instructions When the computer instructions are executed on the computer, the computer executes the first aspect or any possible implementation of the first aspect The method in the way.
- the present application provides a chip including a processor.
- the processor is used to read and execute the computer program stored in the memory to execute the method in the first aspect or any possible implementation manner of the first aspect.
- the chip further includes a memory, and the memory and the processor are connected to the memory through a circuit or a wire, and the memory is used to store a computer program.
- the chip further includes a communication interface.
- the present application also provides a computer program product.
- the computer program product includes computer program code.
- the computer program code runs on a computer, the computer executes the first aspect and any one of the possibilities thereof. The method in the implementation mode.
- the resource dynamic indication method provided in this application can explicitly or implicitly indicate the available resource status of the MT of the IAB node through the indication of dynamic resource signaling, and explicitly or implicitly indicate the DU soft of the IAB node.
- the availability status of the resource In the scenario where the MT has multiple carriers and the DU has multiple cells, the dynamic sharing of the MT resource and the DU resource of the IAB node can be realized.
- Fig. 1 is an architecture diagram of an IAB system applicable to an embodiment of the present application
- Figure 2 is a simple example of an IAB system provided by an embodiment of the application.
- FIG. 3 is a schematic diagram of an access link and a backhaul link provided by an embodiment of this application;
- FIG. 4 is a schematic structural diagram of an IAB node provided by an embodiment of this application.
- FIG. 5 is a logical schematic diagram of an MT and DU provided by an embodiment of this application.
- FIG. 6 is a schematic diagram of another access link and backhaul link provided by an embodiment of the application.
- Fig. 7 is a method for configuring backhaul resources in the LTE relay system
- Figure 8 is a schematic diagram of an example of resource configuration in NR's IAB system
- FIG. 9 is a schematic diagram of the relationship between DU resources and MT resources of a multi-cell according to an embodiment of this application.
- FIG. 10 is a flowchart of a method for dynamically indicating resources according to an embodiment of the application.
- FIG. 11 is an example of a case where the MT includes two carriers and the DU includes 4 cells according to an embodiment of the application;
- FIG. 12 is a schematic diagram of the multiplexing or association relationship between a MT carrier and a DU cell provided by an embodiment of the application;
- FIG. 13 is an example of a method for deriving available/unavailable resources of each carrier of an MT in a semi-static resource configuration provided by an embodiment of this application;
- FIG. 14 is an example of a dynamic resource indication method for DU soft resources of an IAB node provided by an embodiment of this application;
- FIG. 15 is an example of an indication DCI including indication delay information provided by an embodiment of this application.
- FIG. 16 is an example of a dynamic resource indication method for MT resources of an IAB node provided by an embodiment of this application;
- FIG. 17 is a schematic diagram of a relay device 1700 according to an embodiment of the application.
- the communication systems involved in this application include but are not limited to: narrowband-internet of things (NB-IoT) systems, wireless local access network (WLAN) systems, and long-term evolution (LTE) systems , Fifth generation mobile networks (5th generation mobile networks or 5G) systems or communication systems after 5G, such as new radio (NR) systems, device to device (device to device, D2D) communication systems Wait.
- NB-IoT narrowband-internet of things
- WLAN wireless local access network
- LTE long-term evolution
- 5G Fifth generation mobile networks
- 5G Fifth generation mobile networks
- 5G communication systems after 5G, such as new radio (NR) systems
- NR new radio
- D2D device to device
- the relay equipment includes ordinary fixed relay nodes, such as IAB nodes, and also includes mobile relay nodes, such as mobile IAB nodes, terminal equipment UE relays, and so on.
- IAB nodes ordinary fixed relay nodes
- mobile relay nodes such as mobile IAB nodes, terminal equipment UE relays, and so on.
- this application uses the relay device as an IAB node as an example to describe the technical solution provided.
- an IAB node can generally refer to any node or device with a relay function, and does not mean The solution in this application is only applicable to NR scenarios.
- the use of IAB nodes and relay nodes or relay devices should be understood to have the same meaning.
- an IAB system includes at least one base station 100, one or more terminal devices (terminals) 101 served by the base station 100, one or more relay nodes (taking IAB nodes as an example) 110, and IAB One or more terminal devices 111 served by the node 110.
- the base station 100 may be called a donor next generation node B (DgNB), and the IAB node 110 is connected to the base station 100 through a wireless backhaul link 113.
- the donor base station is also referred to as a donor node, a donor node, or a donor base station in this application.
- the base station 100 includes but is not limited to: evolved node B (evolved node base, eNB), baseband unit (BBU), evolved base station (evolved LTE, eLTE), NR base station (next generation node B, gNB), and 5G Base stations behind the communication system, etc.
- evolved node B evolved node base, eNB
- BBU baseband unit
- evolved base station evolved LTE, eLTE
- NR base station next generation node B, gNB
- 5G Base stations behind the communication system etc.
- Terminal equipment includes but is not limited to: terminal equipment (user equipment, UE), mobile station, access terminal, user unit, user station, mobile station, remote station, remote terminal, mobile equipment, terminal, wireless communication equipment, user agent, Station (ST), cellular phone, cordless phone, session initiation protocol (SIP) phone, wireless local loop (wireless local loop, WLL) station in wireless local area network (wireless local access network, WLAN), cell phone, cordless phone, Personal digital assistant (PDA), handheld devices with wireless communication functions, computing devices, other processing devices connected to wireless modems, in-vehicle devices, wearable devices, mobile stations in 5G networks, and public land in the future Any one of terminal devices in a public land mobile network (PLMN) network.
- PLMN public land mobile network
- the IAB node is the specific name of the relay node in the 5G NR system, and does not limit the solution of this application. It may be one of the aforementioned base stations or terminal devices with a forwarding function, or it may be an independent device form.
- the IAB node in this application may also be called a relay node (RN), a transmission and reception point (TRP), a relay transmission and reception point (TRP), and so on.
- the IAB system shown in FIG. 1 may also include multiple other IAB nodes, for example, the IAB node 120 and the IAB node 130.
- the IAB node 120 is connected to the IAB node 110 through a wireless backhaul link 123 to access the network.
- the IAB node 130 is connected to the IAB node 110 through a wireless backhaul link 133 to access the network.
- the IAB node 120 serves one or more terminal devices 121, and the IAB node 130 serves one or more terminal devices 131.
- both the IAB node 110 and the IAB node 120 are connected to the network through a wireless backhaul link. In this application, the wireless backhaul links are all viewed from the perspective of the relay node.
- the wireless backhaul link 113 is the backhaul link of the IAB node 110
- the wireless backhaul link 123 is the IAB node 120.
- Backhaul link As shown in FIG. 1, an IAB node, such as an IAB node 120, can be connected to another IAB node 110 through a wireless backhaul link, such as 123, so as to be connected to the network.
- the relay node can be connected to the network via a multi-level wireless relay node.
- IAB nodes can generally refer to any node or device with a relay function.
- the use of an IAB node and a relay node or a relay device should be understood to have the same meaning.
- an IAB node is connected to an upper-level node.
- an IAB node such as 120
- the IAB node 130 in Figure 1 also It may be connected to the IAB node 120 through the backhaul link 134, that is, both the IAB node 110 and the IAB node 120 are regarded as the upper node of the IAB node 130.
- the names of the IAB nodes 110, 120, and 130 do not limit the scenarios or networks where they are deployed, and may be any other names such as relay and RN.
- the use of an IAB node in this application is only needed for convenience of description. In this application, an IAB node can generally refer to any node or device with a relay function.
- the wireless links 102, 112, 122, 132, 113, 123, 133, 134 may be bidirectional links, including uplink and downlink transmission links, in particular, wireless backhaul links 113, 123, 133, 134 can be used by the upper-level node to provide services for the lower-level nodes, for example, the upper-level node 100 provides wireless backhaul services for the lower-level node 110. It should be understood that the uplink and downlink of the backhaul link may be separated, that is, the uplink and the downlink are not transmitted through the same node.
- the downlink transmission refers to an upper node, such as node 100, and a lower node, such as node 110, transmitting information or data
- the uplink transmission refers to a lower node, such as node 110, and an upper node, such as node 100, transmitting information or data.
- the node is not limited to whether it is a network node or a terminal device.
- the terminal device can act as a relay node to serve other terminal devices.
- the wireless backhaul link can be an access link in some scenarios.
- the backhaul link 123 can also be regarded as an access link for the node 110, and the backhaul link 113 is also the access link of the node 100. link.
- the foregoing upper-level node may be a base station or a relay node
- the lower-level node may be a relay node or a terminal device with a relay function.
- the lower-level node may be a terminal device.
- Figure 2 is a simple example of an IAB system.
- IAB system shown in FIG. 2 it includes a donor base station, IAB node 1, IAB node 2, terminal equipment UE1 and terminal equipment UE2.
- the link between the donor base station and the IAB node 1 and the link between the IAB node 1 and the IAB node 2 are backhaul links.
- the link between the terminal equipment UE1 and the donor base station and the link between the terminal equipment UE2 and the IAB node 1 are access links.
- Access link the link between the terminal equipment UE and the IAB node (IAB node) or IAB donor node (IAB donor). Or, the access link includes a wireless link used when a node communicates with its subordinate nodes.
- the access link includes an uplink access link and a downlink access link.
- the uplink access link is also referred to as the uplink transmission of the access link, and the downlink access link is also referred to as the downlink transmission of the access link.
- Backhaul link A link between an IAB node (IAB node) and an IAB child node (IAB child node) or IAB parent node (IAB parent node).
- the backhaul link includes the downlink transmission link with the IAB child node or the IAB parent node, and the uplink transmission link with the IAB child node or the IAB parent node.
- the data transmission from the IAB node to the IAB parent node or the uplink transmission from the IAB child node is called the uplink transmission of the backhaul link.
- the IAB node receives the data transmission of the IAB parent node, or the data transmission to the IAB child node is called the downlink transmission of the backhaul link.
- the backhaul link between the IAB node and the IAB parent node is also called the parent BH, and the backhaul between the IAB node and the IAB child node
- the link is called the lower-level backhaul link (child BH).
- the lower-level backhaul link and the access link of the IAB node are collectively referred to as the access link, that is, the lower-level node is regarded as a terminal device of the upper-level node.
- Figure 3 is a schematic diagram of an access link and a backhaul link.
- Fig. 4 is a schematic structural diagram of an IAB node.
- the terminal (mobile-termination, MT) function is defined as a component similar to the UE.
- MT is called a function (or module) that resides on the IAB node. Since the MT is similar to the function of an ordinary UE, it can be considered that the IAB node accesses the upper-level node or network through the MT.
- a distributed unit (DU) function is defined as a component similar to a base station. In the IAB system, the DU is called a function (or module) that resides on the IAB node.
- the IAB node can allow the access of lower-level nodes and terminal equipment through the DU.
- the terminal function is referred to as the terminal unit for short, and the use of it and the terminal function should be understood to have the same meaning.
- the terminal unit specifically refers to a certain function and/or module residing on the IAB node to be used with the original
- the terminal equipment UE that can be used as a lower-level node in the application can be distinguished.
- Both the MT and DU modules of the IAB node have a complete transceiver unit, and there is an interface between the two.
- MT and DU are logical modules. In practice, they can share some sub-modules, for example, they can share transceiver antennas, baseband processing units, etc., as shown in Figure 5.
- the MT of the D IAB node may have multiple subunits, which may be multiple carriers, multiple panels, multiple cells, etc.; the DU of the IAB node may also have multiple subunits, and multiple subunits may be multiple Carrier, multiple panels, multiple cells, etc.
- the DU may have multiple cells, the MT may have multiple carriers, and so on. And there is a certain association or multiplexing relationship between the subunits of the MT and the subunits of the DU.
- the IAB node communicates with the upper node through the MT, and the function of the MT is similar to that of a normal UE. Therefore, the MT of the IAB node (hereinafter referred to as IAB MT) may use carrier aggregation (CA) to communicate with the upper node.
- the MT may have multiple carriers (component carriers, CC).
- the DU of the IAB node (hereinafter referred to as IAB DU) may also have multiple sub-modules.
- the DU may have multiple cells. Take two possible cases for example: (1) DU has multiple facing panels or sectors, and different panels are different cells; (2) DU adopts carrier aggregation, and different carriers are different cells.
- the link between the MT and the upper-level node is called the parent BH link
- the link between the DU and the lower-level IAB node is called the child BH link
- the link through which the DU communicates with the lower-level UE is called an access link.
- the upper-level backhaul link includes the upper-level backhaul uplink (uplink, UL) and the upper-level backhaul downlink (downlink, DL)
- the lower-level backhaul link includes the lower-level backhaul uplink (UL) and the lower-level backhaul.
- access link includes access uplink (UL) and access downlink (DL), as shown in Figure 6.
- the lower-level backhaul link is also called an access link.
- the donor node In the LTE relay system, the donor node (or host node) semi-statically configures the backhaul resources for the relay node RN.
- Fig. 7 shows a specific example of downlink backhaul resource configuration in the LTE relay system.
- the donor node allocates backhaul link resources to the relay node in units of subframes (1ms), and the allocation period is one radio frame (10ms).
- the donor base station designates some subframes as backhaul link subframes through radio resource control (RRC) signaling.
- RRC radio resource control
- a relay node in LTE when a subframe is configured as a backhaul link subframe, the relay node needs to monitor the relay physical downlink control channel in this subframe. , R-PDCCH) and/or receiving physical downlink share channel (PDSCH), so it cannot be sent on the access link.
- R-PDCCH relay physical downlink control channel
- PDSCH physical downlink share channel
- FIG. 7 subframes 2, 4, and 6 are configured as backhaul link subframes, and subframes 2, 4, and 6 on the access link at the corresponding positions are unavailable. Therefore, the method for configuring backhaul resources in LTE is semi-static time division multiplexing (TDM) resource allocation.
- TDM time division multiplexing
- FIG. 8 is a schematic diagram of an example of resource configuration in the NR IAB system (hereinafter referred to as NR IAB).
- the MT resource of the IAB node can be configured into three types: uplink (U), downlink (D), and flexible (F). These three types are also supported by terminal equipment in the prior art, so MT resources can be indicated by using existing signaling. Different from the terminal equipment, the IAB node MT can support more D/U/F sequences. For example: the terminal equipment only supports the sequence of D--F--U; the MT can support the sequence of U--F--D or U--D, etc.
- the DU resource of the IAB node can be configured into three types: uplink (U), downlink (D), and flexible (F). Further, the DU's uplink, downlink and flexible three types of resources can also be divided into hard (hard, H) resources and soft (softS) resources. Among them, the hard resource of the DU indicates the resource that is always available to the DU; the soft resource of the DU indicates that whether the DU is available or not depends on the indication of the upper-level node (such as the donor node). In addition, DU may also include unavailable (Null, N) resources.
- the availability of some resources (that is, soft resources) on the IAB node DU in the NR depends on the instructions of the superior node, and the DU resource needs to be instructed by means of semi-static configuration plus dynamic indication.
- the availability of the MT's available resources obtained according to the semi-static resource configuration is modified to be unavailable also needs to depend on the instructions of the superior node.
- This resource allocation method is very different from the resource allocation method in the LTE system.
- the MT of the IAB node is connected to the DU of the upper node, and the DU of the IAB node is connected to the MT of the lower node, or the DU of the IAB node is connected to the UE.
- the IAB node can obtain the resource configuration of its MT resource and DU resource respectively.
- it may include the transmission direction of MT resources and DU resources (U/D/F), the location of MT's available/unavailable resources, the attributes of DU resources (soft/hard), and the time of DU's unavailable resources (Null). Domain location, etc. It should be understood that the above-mentioned related configuration can be obtained through explicit signaling or implicitly.
- the MT of the IAB node has three types of resources, and the DU of the IAB node has a total of 7 types of resources.
- Table 1 shows the resource configuration under various possible resource type combinations of MT and DU in a time division multiplexing (TDM) scenario.
- Table 2 shows the resource configuration under various possible resource type combinations of MT and DU in a spatial division multiplexing (SDM) scenario.
- MT:Tx MT should transmit after being scheduled
- MT has the ability to receive (if there is a signal that needs to be received);
- DU can schedule the uplink transmission of lower nodes
- MT:Tx/Rx MT should transmit or receive after being scheduled, but transmission and reception do not occur at the same time
- DU can transmit or receive transmission from lower-level nodes, but transmission and reception do not occur at the same time;
- IA DU resource is indicated as available explicitly or implicitly;
- INA DU resources are explicitly or implicitly indicated as unavailable
- MT:NULL MT does not send and does not have to have receiving capability
- DU:NULL DU does not send and does not receive transmissions from lower-level nodes.
- the IAB node and its superior node should determine or derive the availability of MT resources according to the resource configuration of the DU.
- the principle of derivation is that the transmission of MT does not affect the use of hard resources by DU.
- the hard resources of its DU for example, the DU resources corresponding to the first, sixth, seventh, and eighth time slots
- MT resources for example, MT resources corresponding to time slots 1, 6, 7, and 8 are unavailable.
- different cells of the DU may have different resource attributes (hard/soft). For example, suppose there are two cells in the DU, cell0 and cell1, where cell0 shares an antenna panel with the MT, or is oriented in the same direction as the MT antenna panel.
- time slots time slots
- time slot 0 is the downlink resource of the MT
- time slot 1 and time slot 2 are for the downlink hard resources of the two cells
- time slot 3 is the uplink and downlink flexible hard resources of the two cells
- time slot 4 is the uplink resource of the MT, the soft resource of cell0, and the hard resource of cell1, as shown in Figure 9.
- the letter “U” represents the uplink resource type
- the letter “D” represents the downlink resource type
- the letter “F” represents the flexible resource type
- the letter “S” represents the soft resource attribute
- the letter “H” represents hard Resource attributes.
- the two cells of DU can have different H/S types in time slot 4 because the transmission direction of cell 1 in this time slot is opposite to the transmission direction of MT.
- the transmission (transmission) will not violate the half-duplex constraint (ie, MT).
- DU cannot receive and send), and the MT and cell#1 panels are reversed, and the two have little influence on each other.
- the two-level resource indication refers to that the upper-level node configures resources for the DU of the IAB node in an explicit or implicit manner
- the resource attributes include at least two types, soft and hard.
- the hard resource represents the resource that is always available to the DU of the IAB node
- the available state of the soft resource depends on the instruction of the upper-level node.
- the upper-level node also configures resources for the MT of the IAB node in an explicit or implicit manner. Whether the available state of the MT's available resources is modified also depends on the instruction of the upper-level node.
- the IAB node can obtain the resource configuration of its MT resource and DU resource respectively. For example, it may include the transmission direction of MT resources and DU resources (U/D/F), the location of MT's available/unavailable resources, the attributes of DU resources (soft/hard), and the time of DU's unavailable resources (Null). Domain location, etc.
- the resource configuration of MT is transmitted through air interface signaling such as RRC
- the resource configuration of DU is transmitted through interface messages such as F1-AP.
- the upper-level node can indicate the availability of its soft resources for the IAB node through dynamic signaling, such as downlink control information (DCI).
- DCI downlink control information
- this DCI is referred to as indicative DCI.
- the indicated DCI can be based on a dedicated DCI format, or it can be an enhancement to or reuse of existing DCI.
- Dynamic instructions can be divided into two types: explicit instructions and implicit instructions:
- Implicit indication The upper-level node indicates whether the MT resource of the IAB node is released (that is, unavailable), and the IAB node derives the availability of its own soft resource according to the indication of the MT resource from the upper-level node.
- the superior node directly indicates the availability of the soft resource of the IAB node DU.
- indicating DCI can also indicate other content at the same time, such as indicating the transmission direction of DU flexible resources.
- the embodiments of the present application provide a method and device for dynamically indicating resources, which are used to dynamically indicate resource allocation schemes of MT multi-carrier and DU multi-cell.
- the method and the device are based on the same technical idea. Since the principles of the method and the device to solve the problem are similar, the implementation of the device and the method can be referred to each other, and the repetition will not be repeated.
- FIG. 1 is only an exemplary illustration, and does not describe the terminal equipment, network equipment, and medium included in the communication system. The number and type of subsequent nodes are specifically limited.
- At least one in the embodiments of the present application refers to one or more, and “multiple” refers to two or more.
- “And/or” describes the association relationship of the associated object, indicating that there can be three relationships, for example, A and/or B, which can mean: A alone exists, A and B exist at the same time, and B exists alone, where A, B can be singular or plural.
- the character “/” generally indicates that the associated objects before and after are in an “or” relationship.
- “The following at least one (item)” or similar expressions refers to any combination of these items, including any combination of single item (item) or plural items (item).
- At least one of a, b, or c can mean: a, b, c, a and b, a and c, b and c, or a, b, c, where a, b, c It can be single or multiple.
- the first node involved in the following embodiments is the IAB node
- the second node is the upper node of the IAB node
- the third node is the lower node of the IAB node
- the first resource is the MT resource of the IAB node
- the second node is the MT resource of the IAB node
- the resource is the DU resource of the IAB node.
- FIG. 10 is a flowchart of a method for dynamically indicating resources according to an embodiment of the application, and the method includes:
- the second node or the donor node sends first indication information to the first node, where the first indication information is used to indicate the semi-static status of the first resource corresponding to the D carriers and the second resource corresponding to the F cells in the first node Resource allocation.
- the first node may be an IAB node
- the second node is an upper-level node of the IAB node.
- the embodiment of the present application may further include a third node, and the third node is a lower-level node of the IAB node.
- the first node may be a relay device, including a common fixed relay node, such as an IAB node, and also a mobile relay node, such as a mobile IAB node, UE relay, and so on.
- the second node may be a common network device, such as a base station, etc., or a relay device.
- the third node can be a relay device or a terminal device.
- the first resource is the transmission resource for the communication between the first node and the second node, that is, the MT resource of the IAB node;
- the second resource is the transmission resource for the communication between the first node and the third node, that is, the DU resource of the IAB node .
- the MT of an IAB node can have multiple subunits, which can be multiple carriers, multiple panels, multiple cells, etc.; the DU of an IAB node can also have multiple subunits, and multiple subunits can also be multiple Carrier, multiple panels, multiple cells, etc.
- the MT of the IAB node has (or is configured) multiple carriers (CC), and the DU has (or is configured) multiple cells (cells) as an example.
- the instruction method is explained. Among them, it is assumed that the MT of the IAB node has D carriers, where D ⁇ 1; the DU of the IAB node has F cells, where F ⁇ 1.
- the embodiments of the present application only take the carrier or the cell as an example for description, and are not limited to taking the carrier or the cell as the unit.
- other sub-modules or sub-units may also be used as the unit, for example, Sectors, antenna panels, etc.
- the DU of the IAB node may have K sectors, where K ⁇ 2.
- communication protocols such as LTE and NR generally use serving cells to identify or describe component carriers, and different serving cells have different serving cell IDs.
- the component carrier is directly used to describe the serving cell of the MT, that is, the carrier of the MT in this application corresponds to the serving cell of the MT in the protocol.
- the IAB node in the example has two (two groups) antenna panels panel 1 and panel 2 with different orientations.
- the DU of the IAB node can communicate with the lower-level nodes through two cells using different carriers (denoted as CC3 and CC4) on each (group) antenna panel. That is, the DU of the IAB node is in each antenna panel. Two cells are run on one antenna panel, for example, cells cell1 and cell2 are run on antenna panel 1, and cells cell3 and cell4 are run on antenna panel 2. Therefore, the DU in FIG. 11 has four cells cell1, cell2, cell3, and cell4.
- the MT of the IAB node uses one (group) antenna panel 1 to communicate with the upper node through two carriers (carrier aggregation) CC1 and CC2.
- the two carriers CC1 and CC2 of the MT are the same as the two carriers CC3 and CC4 of the DU, or the two carriers CC1 and CC2 of the MT coincide with the two carriers CC3 and CC4 of the DU respectively.
- the carrier CC1 used by the MT coincides with the frequency bands of the cell cell 1 running on panel 1 and the cell 3 running on panel 2, while the carrier CC2 used by MT overlaps with the cell 2 and cell 2 running on panel 1 of the MT.
- the cell 4 frequency bands of the cell operating on panel 2 overlap. It should be understood that the overlap of frequency bands may refer to the complete overlap of the entire frequency bands, or may refer to the overlap of some frequency bands.
- multiple (e.g., D) carriers of the MT and multiple (e.g., F) cells of the DU may have different resource reuse or association relationships during transmission.
- the possible resource reuse or association relationship between each carrier of the MT and each cell of the DU is shown in Figure 12. Shown, including but not limited to:
- Time division multiplexing The carrier of the MT and the cell of the DU cannot be transmitted at the same time.
- the carrier CC1 of the MT and the cell cell1 of the DU use the same carrier frequency and are located in the same antenna panel. Therefore, the resource reuse or association relationship between the two is TDM, that is, when the carrier CC1 is transmitting, the cell cell1 cannot perform any form. Transmission and vice versa.
- the multiplexing relationship between the carrier CC2 and the cell cell2 is also TDM.
- the carrier of the MT and the cell of the DU can be received or sent at the same time, but they cannot be received and sent at the same time.
- the carrier CC1 and the cell cell2 use the same antenna panel but have different carrier frequency bands, they can receive or transmit simultaneously, that is, perform (half-duplex) FDM.
- the carrier CC1 and the cell cell3 have the same carrier frequency band but use different antenna panels, they can receive or transmit simultaneously, that is, perform (half-duplex) SDM.
- Full duplex The carrier of the MT and the cell of the DU do not affect each other.
- the carrier CC1 and the cell cell4 use different frequency band carriers and use different antenna panels, so the two have sufficient isolation and can transmit and receive at the same time without affecting each other.
- the carrier of the MT and the cell of the DU have a full-duplex resource reuse or association relationship, or it can be defined that the carrier of the MT and the cell of the DU do not have a resource reuse or association relationship.
- Full duplex can be same frequency full duplex or different frequency full duplex.
- the inter-frequency full-duplex may also be called full-duplex FDM.
- the DU cell determines the configuration or scheme for simultaneous half-duplex transmission/reception according to the transmission situation of the MT. For example, when the MT is performing downlink transmission, the DU of the IAB node can only select some terminal devices for uplink transmission; and when the MT is not performing transmission, the DU of the IAB node can select more terminal devices for uplink transmission. Taking simultaneous reception of MT and DU as an example, different terminal equipment may cause different levels of interference to MT reception. When MT is transmitting, DU should select terminal equipment that has no influence on MT transmission or influences controllable terminal equipment for uplink transmission.
- the DU cell determines the configuration or scheme for full-duplex transmission or reception according to the transmission situation of the MT. For example, when the MT is performing downlink transmission, the DU of the IAB node can only select some terminal devices for downlink transmission; and when the MT is not performing transmission, the DU can select more terminal devices for downlink transmission.
- each carrier of the MT and each cell of the DU may have a default resource reuse or association relationship.
- the default resource reuse or association relationship between each carrier of the MT and each cell of the DU is time division multiplexing TDM.
- the IAB node can modify all or part of the default resource reuse or association relationship between the MT carrier and the DU cell by reporting information to the superior node/host node. For example, the IAB node reports that the resource reuse or association relationship between some MT carriers and DU cells is full duplex, and the resource reuse or association relationship between other MT carriers and DU cells is still the default time division multiplexing TDM.
- the resource configuration mode of NR is semi-static resource configuration plus dynamic resource indication.
- the second node Before performing dynamic resource indication, the second node sends first indication information to the first node, which is used to indicate the MT resource and DU resource of the first node.
- Semi-static resource configuration Before performing dynamic resource indication, the second node sends first indication information to the first node, which is used to indicate the MT resource and DU resource of the first node.
- the first node determines, according to the first indication information, the semi-static resource configuration of the first resource corresponding to the D carriers and the second resource corresponding to the F cells.
- the first node receives the first indication information, and determines the semi-static resource configuration of the MT resource and the DU resource according to the first indication information, including:
- the semi-static configuration of MT resources is similar to that of terminal equipment.
- the host node and/or the superior node of the IAB node can use broadcast signaling and unicast RRC signaling to configure the three D/U/F resources of MT resources on a carrier-by-carrier basis. Types of. It should be understood that the upper-level node of the IAB node may also modify the resource type of the MT of the IAB node through downlink control information (DCI).
- DCI downlink control information
- DU can first be configured with D/U/F resource types by the host node or the superior node of the IAB node. Then, the host node or the superior node of the IAB node can further indicate the hard/soft attributes (attribute) of the DU resource and the time domain location of the unavailable resource (NA). The host node or the superior node of the IAB node generally configures the resources of the DU through interface messages.
- the host node or the superior node of the IAB node simultaneously indicates the hard/soft attributes of the DU resource and the time domain position of the unavailable resource (NA) through interface signaling such as F1-AP, that is, the unavailability of the DU.
- the use of resources is regarded as an attribute of DU resources.
- the host node or the superior node of the IAB node respectively indicate the hard/soft attributes of the resources and the time domain location of the unavailable resources (NA) through independent signaling.
- the IAB node obtains the D/U/F three resource types of the MT resource, as well as the hard/soft attributes of the DU resource and the time domain location of the unavailable resource (NA).
- the IAB node and the upper node of the IAB node need to pass between each carrier of the MT and each cell of the DU. Derives the available/unavailable resources of the MT based on the resource reuse or association relationship.
- the method for deriving the available/unavailable resources of each carrier of the MT of the IAB node is as follows:
- the resource reuse relationship between the MT carrier and the DU cell is time division multiplexing TDM
- the MT resources that overlap with the DU hard resource in the time domain are all unavailable resources;
- the multiplexing relationship between the MT carrier and the DU cell is half-duplex frequency division multiplexing (FDM) or half-duplex space division multiplexing (SDM), which coincides with the DU hard resource time domain and the transmission direction
- FDM frequency division multiplexing
- SDM half-duplex space division multiplexing
- the MT contains a carrier CC1
- the DU contains a cell cell0
- the resource reuse relationship between the MT carrier and the DU cell is time division multiplexing TDM, then the MT resources that overlap with the DU hard resources in the time domain are all Is an unavailable resource.
- the available resources of MT are resources that do not affect the transmission of DU hard resources. Due to the timing deviation between MT and DU and the switching interval between MT and DU resources, some MT resources that do not overlap with DU hard resources may also affect DU hard resources. The transmission of resources should therefore also be regarded as unavailable resources of the MT.
- the derivation of the available/unavailable resources of the MT carrier needs to depend on the resource configuration of the multiple DU cells associated with it, for example, through the resources of multiple cells of the DU Type and resource attributes, jointly derive the available/unavailable resources of the MT carrier.
- the principle of derivation is that the transmission between the MT carrier of the IAB node and the superior node of the IAB node does not affect the use of hard resources in the DU cell of any IAB node.
- the available resources of the MT carrier are the intersection of the available resources of the MT carrier derived from each associated DU cell.
- the unavailable resources of the MT carrier are the union of the unavailable resources of the MT carrier derived from each associated DU cell.
- the available/unavailable resources of each carrier of the MT can be derived carrier by carrier according to the above method.
- the MT includes two carriers CC1 and CC2, and the DU includes four cells cell1, cell2, cell3, and cell4.
- the MT carrier CC1 is associated with the DU cells cell1 and cell2.
- the available resources of the MT carrier CC1 can be derived as time slots 1, 2, and 3.
- the available resources of the MT carrier CC1 are time slots 0, 1, and 2. Taking the intersection of the two available resource sets, it can be seen that the available resources of the MT carrier CC1 are time slots 1 and 2. In other words, the unavailable resources of the MT carrier are time slots 0, 3, and 4.
- the available resources of the MT obtained according to the semi-static resource configuration refer to the resources that may be used for the backhaul link transmission. In the actual process, whether the available resources are used for the backhaul link transmission depends on the upper-level node. Instructions.
- the second node sends second indication information to the first node, where the second indication information is used to indicate the available status of the available resources of the first resource corresponding to the D carriers in the first node and/or the first resource corresponding to the F cells. 2. The available status of the dynamic resource of the resource.
- NR IAB's resource configuration method is semi-static resource configuration plus dynamic resource indication.
- the upper-level node of the IAB node can display it through dynamic signaling. Or implicitly indicate the availability of the DU soft resources of the IAB node, or explicitly or implicitly indicate whether the available resources of the MT of the IAB node will be released.
- the release of the available resources of the MT by the superior node of the IAB node means that the superior node indicates that the available resources will not be used by the backhaul link.
- the available resources of the MT obtained according to the semi-static resource configuration may be used as the resources of the backhaul link, whether the actual available resources will be used for the backhaul link transmission, that is, the available state of the MT's available resources Whether it will be modified (or rewritten, or re-instructed, or overwritten) depends on the instructions of the superior node.
- the availability status of the available resources of the first resource may refer to the superior node of the IAB node explicitly or implicitly indicating whether the available resources of the MT of the IAB node will be released, that is, the available resources of the MT obtained by the semi-static resource configuration Whether the available status of may be modified (or rewritten, or re-indicated, or overwritten) by the superior node.
- the superior node of the IAB node modifies the availability of the available resources of the first resource corresponding to the D carriers. Generally speaking, only the original available resources can be modified to be unavailable, and the original unavailable resources cannot be modified to be available. .
- the availability status of the dynamic resource of the second resource may refer to the availability of the soft resource of the DU of the IAB node, that is, the superior node of the IAB node explicitly or implicitly indicates the availability of the soft resource of the IAB node.
- the IAB node does not use the corresponding resource to communicate with the lower-level IAB node or UE.
- the upper-level node of the IAB node indicating the DU soft resource of the IAB node as an example to illustrate the above dynamic resource indication method.
- the second indication information indicates the first cell of a certain cell among the F cells of the IAB node DU If the dynamic resource of the second resource is available (solid line in the figure), the first node can use the corresponding resource to communicate with the third node. If the second indication information indicates that the dynamic resource of the second resource of a certain cell among the F cells of the DU is unavailable (the dotted line in the figure), the first node cannot use the corresponding resource to communicate with the third node.
- the second indication information may be sent through dynamic signaling, such as downlink control information (DCI).
- DCI downlink control information
- the second indication information used for dynamic resource indication sent by the second node is referred to as indication DCI below.
- the indication DCI can adopt a dedicated DCI format, or can be obtained by adding or modifying fields in the existing DCI format.
- the donor node or superior node of the IAB node can configure the IAB node with related information indicating DCI through radio resource control RRC signaling, and the related information indicating DCI may include at least one of the following:
- Control resource set (CORESET) information the same or similar to the existing control resource set CORESET configuration
- Search space collection information contains configuration information indicating the DCI search space, which is the same or similar to the usual search space collection configuration, including the CORESET associated with the search space, and the time domain information of the search space (period, offset, duration) , The start symbol of the search space in the time slot, etc.), physical downlink control channel (physical downlink control channel, PDCCH) candidate set (candidate) information, DCI format information, aggregation level, etc.
- configuration information indicating the DCI search space which is the same or similar to the usual search space collection configuration, including the CORESET associated with the search space, and the time domain information of the search space (period, offset, duration) , The start symbol of the search space in the time slot, etc.), physical downlink control channel (physical downlink control channel, PDCCH) candidate set (candidate) information, DCI format information, aggregation level, etc.
- PDCCH physical downlink control channel
- the indication delay is the time difference between the time when the MT of the IAB node receives the physical downlink control channel PDCCH and the start position of the corresponding DCI indication.
- the delay may also be indicated by DCI.
- Indication range information Indicate the time domain range of DCI application.
- the indication delay can be the time from the start symbol of the DCI (corresponding physical downlink control channel PDCCH or CORESET) to the start position of the indication range, or the end symbol of the DCI (corresponding PDCCH or CORESET) to the indication range The time of the starting position.
- the first node determines, according to the second indication information, the available state of the available resources of the first resource corresponding to the D carriers and/or the available state of the dynamic resources of the second resource corresponding to the F cells.
- the first node receives the second indication information, and determines the dynamic resource configuration of the MT resource and the DU resource according to the second indication information, including:
- the foregoing embodiment provides a detailed design in which the upper-level node of the IAB node explicitly indicates the available state of the MT's available resources of the IAB node and the available state of the DU's soft resources in the case of MT multi-carrier and DU multi-cell.
- the following describes the details of the solution when the upper-level node of the IAB node only displays the available status of the available resources of the MT of the IAB node, and the IAB node can implicitly determine the available status of its soft resources according to the indication.
- the superior node of the IAB node only explicitly indicates the available state of the soft resources of the DU, and the IAB node can implicitly determine the detailed design of the available state of its MT available resources according to the indication.
- the superior node of the IAB node may only explicitly indicate the available status of the MT available resources of the IAB node, and the IAB node may Indicates to implicitly determine the available status of its DU soft resources. That is, the superior node of the IAB node indicates whether the availability of the available resources determined by the MT of the IAB node after semi-static configuration is modified, and the IAB node according to its superior node's indication of the available state of the MT's available resources (hereinafter referred to as the MT indication), Derive the availability of the soft resources of its own DU.
- the MT indication the superior node's indication of the available state of the MT's available resources
- the available status of its soft resources should be determined according to the dynamic resource indication results of multiple MT carriers associated with it, that is, whether the IAB node uses the soft resources obtained by the DU through semi-static resource configuration and the subordinate IAB node or UE To communicate.
- the resource reuse or association relationship between each carrier of the MT and each cell of the DU needs to be considered.
- the MT indication can be performed on a carrier-by-carrier basis.
- the upper-level node of the IAB node can indicate the availability of the time domain resources of the different carriers of the MT through different DCI fields (whether the availability status of the available resource is modified to unavailable), or the upper-level node of the IAB node can indicate that the MT is different.
- the availability of the time domain resources of the carrier (whether the availability status of the available resources is modified to unavailable).
- the MT of the IAB node can determine the time domain and frequency domain resources (carrier level) with which the upper-level node communicates.
- the upper-level node can indicate whether the available state of the available time slot of the MT has been modified carrier by carrier.
- the physical downlink channel PDCCH carrying the indication DCI is located on a carrier of the MT.
- the MT may also receive the indication DCI through different carriers.
- the upper-level node does not give an instruction, or the upper-level node indicates it as release, or the IAB node ignores the instruction of the upper-level node.
- the upper-level node may also sub-carrier groups to indicate the available status of the available resources of the MT. Specifically, the upper-level node simultaneously indicates the availability of the available resources of the MT's carrier group (multiple carriers). When the upper-level node indicates that a certain time domain resource of the MT is available/unavailable, the time domain resources corresponding to multiple carriers in the carrier group are all indicated as available/unavailable. Still taking Fig.
- the upper-level node jointly indicates whether the available status of the available resources of the carrier CC1 and the carrier CC2 will be modified, that is, the resources of the carriers CC1 and CC2 are only Can be indicated at the same time whether the available status of its available resources will be modified.
- carrier CC1 is semi-statically configured as an unavailable resource, so the instructions of the upper node only apply to carrier CC2.
- the instructions of the superior node only apply to carrier CC1. That is to say, for the unavailable resources derived from the semi-static resource configuration in the MT, the IAB node can ignore the instructions of its superior node.
- the indication based on the carrier group can save the overhead of indicating the DCI, but the flexibility of resource reuse between the MT resource and the DU resource of the IAB node is insufficient.
- the indicated DCI may have an indication range, and the resource indicated by the superior node of the IAB node should be within the indication range. Further, the IAB node needs to determine the specific resource set indicated by the indication DCI within the indication range.
- the indication resource of the upper node (or the resource to be indicated of the IAB node MT) is the available resource of all MTs within the indication range, and the available resource of the MT is obtained through semi-static resource configuration.
- the specific method for obtaining the available resources of the MT is the same as the method given in step S1001 in the embodiment described in FIG. 10.
- the indication resource of the superior node may be determined by a specific DU cell set.
- the MT to-be-indicated resource includes the MT resource corresponding to the soft resource of the specific DU cell, or includes the specific MT resources corresponding to soft resources and unavailable (NA) resources of the DU cell.
- the indicated resource of the upper node may include the intersection or union of the to-be-indicated resources of the MT determined by the multiple specific DU cells.
- the to-be-indicated resource set of the MT is determined by the DU resources corresponding to the F cells associated with it.
- the DU resources corresponding to the specific G cells in the F cells can be used to determine the to-be-indicated resource set of the MT associated with it. Indicates the resource set, where G ⁇ K.
- the instruction resource of the superior node (or the resource to be instructed of the IAB node MT) is directly indicated by the superior node or the donor node, and this implementation manner is usually applied in a multi-connection scenario;
- the indicated resource of the superior node (or the to-be-indicated resource of the IAB node MT) is all the resources of the IAB node MT within the indication range.
- the MT resource indicated by the DCI sent by the superior node is an unavailable resource (determined by semi-static configuration) of the MT of the IAB node.
- the MT may ignore the corresponding field indicating the DCI, or MT expects the indication DCI to always indicate that the unavailable resource is unavailable.
- the upper-level node indicates the available status of a time slot of the MT, and the MT time slot may contain several unusable symbols. At this time, even if the upper-level node indicates the time slot as available, the original time slot is not available. The symbol is still unavailable.
- the indication resource granularity of the indication DCI may be at the slot level, symbol level, or resource type level. among them,
- (1) Slot-level indication The upper node of the IAB node indicates whether the MT resource is available (or whether the available state of its MT available resource is modified) time slot by time slot. In the simplest case, only one bit is required for each MT slot to indicate. It should be understood that the MT time slot here refers to an MT time slot in the available resources of the MT.
- the upper node of the IAB node can modify part of the symbols in a time slot to be unavailable. For example, through the start and length indicator value (SLIV), the upper-level node of the IAB node can indicate that a segment of consecutive symbols in the time slot is available/unavailable.
- SIV start and length indicator value
- Resource type level indicator can be regarded as a special symbol level indicator, that is, the indicator signaling can separately indicate the availability of symbols of each or multiple resource types (D/U/F) in the time slot .
- resource type level indication can be divided into two sub-methods: (a) indication based on MT resource type, that is, symbols with different resource types in an MT slot can be independently indicated unavailability; (b) based on DU resource Type indication, that is, MT symbols corresponding to symbols with different resource types in a DU slot can be independently indicated unavailability.
- time domain resources for example, different time slots
- binding the upper-level node of the IAB node can indicate the same resource availability status for multiple bound time domain resources.
- the release of an MT resource by the IAB node indicates that the corresponding DU resource is available, and the corresponding DU resource indicates a DU resource with the same identifier (for example, the same index) as the MT resource.
- some carriers of the MT of the IAB node (that is, certain serving cells in the protocol) will be in an inactive state.
- the IAB node and its superior node treat all the resources of the corresponding carrier of the MT as inactive.
- the indication DCI may not indicate the corresponding carrier, or indicate that the DCI always releases the corresponding resource, or the IAB node ignores the corresponding indication DCI indication field.
- the foregoing embodiment details the solution when the superior node of the IAB node only displays the available state of the available resources of the MT of the IAB node, and implicitly indicates the available state of the soft resources of the DU.
- the detailed design of the scheme in which the upper-level node only explicitly indicates the available state of the soft resource of the DU, and the available state of the available resource of the MT of the IAB node is described in detail below.
- the superior node of the IAB node can directly indicate the available status of the soft resource of the IAB node's DU, and the IAB node can be based on this Indicate to determine the available status of its MT available resources. That is, the upper-level node of the IAB node indicates whether the IAB node can use the soft resource determined by the DU after semi-static resource configuration to communicate with the lower-level IAB node or UE, and the IAB node according to its upper-level node's indication of the available state of the DU's soft resource ( Hereinafter referred to as DU indication), the available state of the available resources of the own MT is derived.
- the resource reuse or association relationship between each carrier of the MT and each cell of the DU needs to be considered.
- the indication DCI can selectively indicate the availability of soft resources of all DU cells or some DU cells.
- the IAB node may ignore the indication of the DCI for some of the time slots or symbols.
- the part of the symbols or time slots for which the indication can be ignored includes: DU hard time slots or symbols configured by semi-static signaling, DU unavailable time slots or symbols configured by semi-static signaling, and cell-level signals or channels (including SS/PBCH) are configured. block, PRACH resource) time slot or symbol, designated configuration resource, etc.
- the designated configuration resource refers to the resource additionally determined by the IAB node through configuration signaling, and the IAB node ignores the dynamic indication of the resource by the DCI.
- the designated configuration resource is the DU slot corresponding to the MT slot indicating the DCI received by the IAB node and a section of resources thereafter.
- the designated configuration resource may be a segment of resources from DU slot 0 to DU slot 3 corresponding to MT slot 0 of the DCI received by the IAB node.
- the IAB node After receiving the instruction information for the DU sent by the superior node, the IAB node should determine the resource availability of each MT carrier at different moments through the resource multiplexing or association relationship between each carrier of the MT and each cell of the DU. For an MT carrier, the available time domain resources of the MT should not affect the transmission of the hard resources of all cells of the DU and the soft resources indicated as available by the upper node.
- the method for determining the MT resource is similar to step S1002 of the foregoing embodiment. The difference is that this embodiment needs to consider both the hard resources of the DU and the soft resources indicated as available to the DU by the upper-level node.
- the available/unavailable time domain resources of each carrier of the MT may need to be determined according to the instructions of multiple DU cells associated with it. That is, for an MT carrier, the available state of its available resources should be determined according to the dynamic indication results of multiple DU cells associated with it, that is, whether the available state of the available resources obtained by the MT through semi-static resource configuration will be modified to unavailable.
- the resource reuse or association relationship between each carrier of the MT and each cell of the DU needs to be considered.
- the MT carrier can be taken into consideration when the DCI indicates the available status of the soft resources of the DU cell.
- the DCI indicates the soft data of one or more DU cells associated with one or more MT carriers. The available status of the resource.
- the MT carrier associated with the DCI can be configured at the same time.
- the IAB node can also determine the DU cell corresponding to the indicated DCI, where the DU cell can be a donor node or an upper node
- the configuration may also be derived by the IAB node based on the associated MT carrier.
- the indication DCI indicates a DU cell that has a TDM relationship with the associated MT carrier.
- the DCI is instructed to indicate a DU cell with FDM/SDM with the associated MT carrier.
- the configuration information indicating the DCI may include:
- the associated MT carrier identifier may refer to the identifier of the MT carrier that has resource reuse or association relationship with the DU cell that is dynamically resource indicated by the upper node, for example, CC1.
- the indicated DU cell identifier may refer to the identifier of the DU cell indicated by the upper node in the dynamic resource, for example, cell 1.
- the associated MT carrier identifier is configured by an upper-level node, and the indicated DU cell identifier may be configured by an upper-level node, or may be obtained from the associated MT carrier identifier, and the resource reuse or association relationship between the MT carrier and the indicated DU cell.
- the configuration of the associated MT carrier identifier while indicating the available status of the soft resources of the DU cell enables the IAB node to quickly obtain the available status of the available resources of each MT carrier.
- the indication DCI indicates the available state of the soft resources of the DU cell and the available state of the available resources of the MT carrier at the same time.
- the configuration information indicating the DCI may further include:
- indicating the MT carrier identifier may refer to the identifier of the MT carrier indicated by the upper node in the dynamic resource, for example, CC2.
- the indicator DU cell identity may refer to the identity of the DU cell indicated by the higher-level node in the dynamic resource, for example, cell 2.
- Both the indicated MT carrier identifier and the indicated DU cell identifier can be configured by an upper-level node, and the upper-level node can indicate the available status of one or more MT carriers and one or more DU cells at the same time by instructing DCI. In this possible implementation manner, it is assumed that the indicated DCI indicates the resource availability of an MT carrier and a DU cell.
- the indicated DCI can indicate two states, such as 0/1. Among them, (1) 0: DU resource is not available + MT resource is available; (2) 1: DU resource is available + MT resource is not available.
- the IAB node after receiving the dynamic resource indication from the upper-level node, if the indication is an MT indication, that is, the upper-level node indicates the availability of the MT available resources of the IAB node, the IAB node should follow the MT indication and each carrier of the MT The resource reuse or association relationship with each cell of the DU determines the availability of the soft resources of each cell of the DU, where the use of the DU resources by the IAB node should not affect the use of the MT available resources that are indicated as available.
- the indication is a DU indication, that is, the superior node directly indicates the availability of the DU soft resource of the IAB node
- the IAB node should determine the resource reuse or association relationship between the DU indication and each carrier of the MT and each cell of the DU. The availability of the available resources of each carrier of the MT, where the use of the MT resources by the IAB node should not affect the use of DU hard and indicated as available soft resources.
- the IAB node can determine the availability of each resource of each MT carrier.
- the behavior of the MT is similar to that of ordinary terminal equipment, while for the unavailable resources of the MT, the behavior of the MT needs to be defined. specifically:
- the MT of the IAB node does not expect the upper node to instruct the DCI to instruct it to perform PDSCH reception, PUSCH transmission, and HARQ-ACK feedback on unavailable resources.
- the above restrictions may only apply to part of the transmission process, for example, only partial RNTI (such as C-RNTI, MCS-C-RNTI) scrambling CRC for the DCI scheduled PDSCH, PUSCH, or the indicated HARQ-ACK Feedback etc.
- RNTI for example, SI-RNTI
- the constraints do not need to be met.
- the above limitation only applies to the unicast PDSCH and PUSCH of the IAB node, but not to the broadcast PDSCH scheduling of the upper-level node.
- the MT of the IAB node may not perform high-level configuration signal transmission and reception on unavailable resources, and may include one or more of the following: PDCCH monitoring, CSI-RS reception, SRS transmission, semi-static PDSCH, configuration-based PUSCH, etc.
- PDCCH monitoring the MT may only perform partial PDCCH monitoring on unavailable resources, such as a UE-specific search space set, or the DCI corresponding to a unicast PDSCH/PUSCH that is dynamically scheduled.
- the MT can monitor the PDCCH corresponding to the broadcast channel on unavailable resources.
- the MT does not monitor the specific RNTI to scramble the DCI of the CRC. In the same way, the MT may only receive UE-specific CSI-RS on unavailable resources.
- the above-mentioned MT behavior may only be limited to a specific MT state, for example, the MT meets the above-mentioned behavior only when the MT is in the RRC connected state. When the MT is in the idle or inactive state, it may not be limited to the above behavior.
- the IAB node MT may miss the PDCCH corresponding to the DCI. At this time, the IAB node MT should assume that the availability of all semi-statically determined available resources remains unchanged, and perform the corresponding backhaul chain Receiving or sending of roads. However, the IAB node MT may have the following exceptions: the IAB node may not perform SRS transmission or PUSCH transmission based on the configuration on the available resources determined semi-statically.
- This application provides a dynamic resource indication method for the MT resource and DU resource of the IAB node.
- the superior node of the IAB node can explicitly or implicitly indicate the available status of the MT's available resources of the IAB node, and explicitly or implicitly indicate the DU soft of the IAB node.
- the availability status of the resource may also only explicitly indicate the available state of the available resources of the MT of the IAB node, and the IAB node may implicitly determine the available state of its soft resources according to the indication.
- the upper-level node of the IAB node may also only explicitly indicate the available state of the DU soft resource of the IAB node, and the IAB node may implicitly determine the available state of the available resource of its MT according to the indication.
- the technical solution provided in this application can realize the dynamic resource sharing of the MT resource and the DU resource of the IAB node.
- FIG. 17 is a schematic structural block diagram of a relay device 1700 provided in the present application.
- the relay device 1700 includes a processing unit 1710 and a transceiving unit 1720.
- the processing unit 1710 is configured to determine, according to the first indication information, the semi-static resource configuration of the first resource corresponding to the D carriers and the second resource corresponding to the F cells, where D ⁇ 1 and F ⁇ 1;
- the second indication information determines the available state of the available resource of the first resource corresponding to the D carriers and the available state of the dynamic resource of the second resource corresponding to the F cells.
- the transceiver unit 1720 is configured to receive first indication information sent by the second node or the donor node, where the first indication information is used to indicate the first resource corresponding to the D carriers and the second resource corresponding to the F cells in the first node Semi-static resource configuration, where D ⁇ 1, F ⁇ 1; receiving second indication information sent by the second node, the second indication information is used to indicate the available resources of the first resource corresponding to the D carriers in the first node The available state and the available state of the dynamic resource of the second resource corresponding to the F cells.
- the device 1700 may be a chip or an integrated circuit.
- the chip described in the embodiment of the application may be a field-programmable gate array (FPGA), an application specific integrated circuit (ASIC), a system on chip (SoC), a central Processor (central processor unit, CPU), network processor (Network Processor, NP), digital signal processing circuit (digital signal processor, DSP), can also be a microcontroller (microcontroller unit, MCU, programmable controller ( programmable logic device (PLD) or other integrated chips.
- FPGA field-programmable gate array
- ASIC application specific integrated circuit
- SoC system on chip
- CPU central processor unit, CPU
- Network Processor Network Processor
- NP network Processor
- digital signal processing circuit digital signal processor, DSP
- MCU microcontroller unit
- PLD programmable logic device
- the processing unit 1710 may be a processor.
- the transceiver unit 1710 may be composed of a receiving unit and a sending unit.
- the transceiver unit 1720 may be a transceiver, and the transceiver may include a transmitter and a receiver, and has the functions of receiving and transmitting at the same time.
- the transceiver unit 1710 may also be an input/output interface or an input/output circuit.
- the transceiver unit 1720 may be a communication interface.
- input and output interface input interface circuit and output interface circuit, etc.
- the apparatus 1700 may correspond to the first node or the IAB node in the method 1000 for indicating dynamic resources provided in the embodiment of FIG. 10 provided by the present application and other embodiments.
- the units included in the apparatus 1700 are respectively used to implement corresponding operations and/or processes performed by the first node or the IAB node in the method 1000 and other embodiments.
- the processing unit 1710 is further configured to implicitly determine the available state of its DU soft resources according to the available state of the available resources of the MT. Or, it is also used to implicitly determine the available state of the MT's available resources according to the available state of the DU soft resources.
- the present application provides a computer-readable storage medium.
- the computer-readable storage medium stores computer instructions.
- the computer instructions run on the computer, the computer executes any of the foregoing method embodiments by the first node or the IAB node. The corresponding operations and/or processes performed.
- the computer program product includes computer program code.
- the computer program code runs on a computer, the computer executes the corresponding method executed by the first node or the IAB node in any of the above-mentioned method embodiments of this application. Operations and/or processes.
- the application also provides a chip including a processor.
- the processor is used to call and run the computer program stored in the memory to execute the corresponding operation and/or process executed by the first node in any of the foregoing method embodiments of the present application.
- the chip further includes a memory, and the memory is connected to the processor.
- the processor is used to read and execute the computer program in the memory.
- the chip further includes a communication interface, and the processor is connected to the communication interface.
- the communication interface is used to receive signals and/or data to be processed, and the processor obtains the signals and/or data from the communication interface and processes them.
- the communication interface may be an input/output interface, which may specifically include an input interface and an output interface.
- the communication interface may be an input/output circuit, which may specifically include an input circuit and an output circuit.
- the memory and the memory involved in the foregoing embodiments may be physically independent units, or the memory may also be integrated with the processor.
- the processor may be a central processing unit (CPU), a microprocessor, an application-specific integrated circuit (ASIC), or one or more of the technologies used to control the application. Integrated circuits for the execution of program programs, etc.
- the processor may be a digital signal processor device, a microprocessor device, an analog-to-digital converter, a digital-to-analog converter, and so on.
- the processor can distribute the control and signal processing functions of the terminal device or the network device among these devices according to their respective functions.
- the processor may have a function of operating one or more software programs, and the software programs may be stored in the memory.
- the functions of the processor can be implemented by hardware, or can be implemented by hardware executing corresponding software.
- the hardware or software includes one or more modules corresponding to the above-mentioned functions.
- the memory can be read-only memory (ROM), other types of static storage devices that can store static information and instructions, random access memory (RAM), or other types that can store information and instructions
- Dynamic storage devices can also be electrically erasable programmable read-only memory (EEPROM), compact disc read-only memory (CD-ROM), or other optical disk storage, optical disc storage ( Including compact discs, laser discs, optical discs, digital universal discs, Blu-ray discs, etc.), magnetic disk storage media or other magnetic storage devices, or can be used to carry or store desired program codes in the form of instructions or data structures Any other medium accessed by the computer, etc.
- EEPROM electrically erasable programmable read-only memory
- CD-ROM compact disc read-only memory
- optical disc storage Including compact discs, laser discs, optical discs, digital universal discs, Blu-ray discs, etc.
- magnetic disk storage media or other magnetic storage devices or can be used to carry or store desired program codes in the form of instructions or data structures Any other medium accessed by the computer
- the units can be implemented by electronic hardware or a combination of computer software and electronic hardware. Whether these functions are performed by hardware or software depends on the specific application and design constraint conditions of the technical solution. Professional technicians can use different methods for each specific application to achieve the described functions.
- the disclosed system, device, and method may be implemented in other ways.
- the device embodiments described above are only illustrative.
- the division of the units is only a logical function division, and there may be other divisions in actual implementation, for example, multiple units or components may be combined or may be Integrate into another system, or some features can be ignored or not implemented.
- the displayed or discussed mutual coupling or direct coupling or communication connection may be indirect coupling or communication connection through some interfaces, devices or units, and may be in electrical, mechanical or other forms.
- the units described as separate components may or may not be physically separated, and the components displayed as units may or may not be physical units, that is, they may be located in one place, or they may be distributed on multiple network units. Some or all of the units may be selected according to actual needs to achieve the objectives of the solutions of the embodiments.
- the functional units in the various embodiments of the present application may be integrated into one processing unit, or each unit may exist alone physically, or two or more units may be integrated into one unit.
- the function is implemented in the form of a software functional unit and sold or used as an independent product, it can be stored in a computer readable storage medium.
- the technical solution of the present application essentially or the part that contributes to the existing technology or the part of the technical solution can be embodied in the form of a software product, and the computer software product is stored in a storage medium, including Several instructions are used to make a computer device (which may be a personal computer, a server, or a network device, etc.) execute all or part of the steps of the methods described in the various embodiments of the present application.
- the aforementioned storage media include: U disk, mobile hard disk, read-only memory (read-only memory, ROM), random access memory (random access memory, RAM), magnetic disks or optical disks and other media that can store program codes. .
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Abstract
A method and device for dynamic indication of resources, for use in implementing dynamic resource indication in a case of MT multi-load DU multi-cell. The method comprises: a first node determines, on the basis of first indication information transmitted by a second node or a host node, a semi-static resource configuration of a first resource corresponding to D carriers and a second resource corresponding to F cells; the first node determines, on the basis of second indication information transmitted by the second node or the host node, an available state of an available resource of the first resource corresponding to the D carrier and an available state of a dynamic resource of the second resource corresponding to the F cells.
Description
本申请涉及通信技术领域,尤其涉及一种资源的动态指示方法及装置。This application relates to the field of communication technology, and in particular to a method and device for dynamically indicating resources.
随着移动通信技术的不断发展,频谱资源日趋紧张。为了提高频谱利用率,未来的基站部署将会更加密集。此外,密集部署还可避免覆盖空洞的出现。在传统蜂窝网络架构下,基站通过光纤与核心网建立连接。然而在很多应用场景下,光纤的部署成本非常高昂。无线中继节点(relay node,RN)通过无线回传链路与核心网建立连接,可节省部分光纤部署成本。With the continuous development of mobile communication technology, spectrum resources are becoming increasingly scarce. In order to improve spectrum utilization, future base station deployment will be more intensive. In addition, dense deployment can also avoid the appearance of coverage holes. Under the traditional cellular network architecture, the base station establishes a connection with the core network through optical fiber. However, in many application scenarios, the deployment cost of optical fiber is very high. A wireless relay node (RN) establishes a connection with the core network through a wireless backhaul link, which can save part of the fiber deployment cost.
一般情况下,中继节点RN与一个或多个上级节点建立无线回传链路,并通过上级节点接入核心网。上级节点可通过多种信令对中继节点进行控制(例如,数据调度、定时调制、功率控制等)。另外,中继节点还可为多个下级节点提供服务。中继节点的上级节点可以是基站,也可以是另一个中继节点;中继节点的下级节点可以是另一个中继节点,也可以是终端设备(user equipment,UE)。在某些情形下,上级节点也可以称为上游节点,下级节点也可以称为下游节点。Generally, the relay node RN establishes a wireless backhaul link with one or more upper-level nodes, and accesses the core network through the upper-level nodes. The upper node can control the relay node through a variety of signaling (for example, data scheduling, timing modulation, power control, etc.). In addition, the relay node can also provide services for multiple subordinate nodes. The upper-level node of the relay node may be a base station or another relay node; the lower-level node of the relay node may be another relay node or a terminal equipment (UE). In some cases, the upper-level node may also be called the upstream node, and the lower-level node may also be called the downstream node.
带内中继是回传链路与接入链路共享相同频段的中继方案,由于没有使用额外的频谱资源,带内中继具有频谱效率高及部署成本低等优点。带内中继一般具有半双工的约束,具体地,中继节点在接收其上级节点发送的下行信号时不能向其下级节点发送下行信号,而中继节点在接收其下级节点发送的上行信号时不能向其上级节点发送上行信号。新一代无线通信系统(new radio,NR)的带内中继方案被称为一体化接入回传(integrated access and backhaul,IAB),而中继节点通常被称为IAB节点(IAB node)。In-band relay is a relay solution in which the backhaul link and the access link share the same frequency band. Since no additional spectrum resources are used, the in-band relay has the advantages of high spectrum efficiency and low deployment cost. In-band relay generally has a half-duplex constraint. Specifically, a relay node cannot send a downlink signal to its lower-level node when receiving a downlink signal sent by its upper-level node, while a relay node is receiving an uplink signal sent by its lower-level node. It cannot send an uplink signal to its superior node. The in-band relay scheme of the new generation wireless communication system (new radio, NR) is called integrated access and backhaul (IAB), and the relay node is usually called an IAB node (IAB node).
IAB节点包括终端(mobile termination,MT)功能与分布式单元(distributed unit,DU)功能。终端功能以下简称终端单元,特指驻留在IAB节点上的某一功能/模块,用以与本申请中可作为下级节点的终端设备UE进行区分。其中,MT用于IAB节点与上级节点通信,DU用于IAB节点与下级节点通信。下级节点可以是终端设备UE,也可以是其他IAB节点。MT与上级节点通信的链路被称为上级回传链路(parent BH link),DU与下级IAB节点通信的链路被称为下级回传链路(child BH link),而DU与下级UE节点通信的链路被称为接入链路(access link)。The IAB node includes a terminal (mobile termination, MT) function and a distributed unit (distributed unit, DU) function. The terminal function is hereinafter referred to as a terminal unit, and specifically refers to a certain function/module that resides on an IAB node to distinguish it from the terminal equipment UE that can be used as a lower-level node in this application. Among them, the MT is used for the communication between the IAB node and the upper-level node, and the DU is used for the communication between the IAB node and the lower-level node. The lower-level node can be the terminal equipment UE or other IAB nodes. The link between the MT and the upper-level node is called the parent BH link, the link between the DU and the lower-level IAB node is called the child BH link, and the DU and the lower-level UE The link through which nodes communicate is called an access link.
在一些部署场景中,IAB节点的DU可能具有多个小区(cell),不同的DU cell可能是不同朝向的扇区,也可能是不同频段的载波。类似的,IAB节点的MT也可能具有多个不同频段的载波。现有技术目前不存在当IAB节点的MT具有多个载波且DU具有多个小区时的动态资源指示方法。本申请提供一种资源的动态指示方法,可以实现回传资源和接入资源的动态资源共享。In some deployment scenarios, the DU of the IAB node may have multiple cells (cells), and different DU cells may be sectors with different orientations, or may be carriers of different frequency bands. Similarly, the MT of the IAB node may also have multiple carriers in different frequency bands. In the prior art, there is currently no dynamic resource indication method when the MT of the IAB node has multiple carriers and the DU has multiple cells. This application provides a method for dynamically indicating resources, which can realize dynamic resource sharing of backhaul resources and access resources.
发明内容Summary of the invention
本申请提供一种资源的动态指示方法,解决了当IAB节点的MT具有多载波DU具有多小区时的动态资源指示问题。This application provides a dynamic resource indication method, which solves the problem of dynamic resource indication when the MT of the IAB node has multiple carriers and DUs have multiple cells.
第一方面,本申请提供了一种资源的动态指示方法,该方法包括:第一节点接收第二节点或宿主节点发送的第一指示信息,该第一指示信息用于指示第一节点中D个载波对应的第一资源和F个小区对应的第二资源的半静态资源配置,其中,D≥1,F≥1;第一节点根据第一指示信息确定D个载波对应的第一资源和F个小区对应的第二资源的半静态资源配置;第一节点接收第二节点发送的第二指示信息,该第二指示信息用于指示第一节点中D个载波对应的第一资源的可用资源的可用状态和F个小区对应的第二资源的动态资源的可用状态;第一节点根据第二指示信息确定D个载波对应的第一资源的可用资源的可用状态和F个小区对应的第二资源的动态资源的可用状态。In the first aspect, this application provides a method for dynamically indicating resources. The method includes: a first node receives first indication information sent by a second node or a host node, and the first indication information is used to indicate D in the first node. The semi-static resource configuration of the first resource corresponding to the two carriers and the second resource corresponding to the F cells, where D≥1 and F≥1; the first node determines the first resource and the first resource corresponding to the D carriers according to the first indication information The semi-static resource configuration of the second resources corresponding to the F cells; the first node receives the second indication information sent by the second node, and the second indication information is used to indicate the availability of the first resources corresponding to the D carriers in the first node The available state of the resource and the available state of the dynamic resource of the second resource corresponding to the F cells; the first node determines, according to the second indication information, the available state of the available resource of the first resource corresponding to the D carriers and the available state of the first resource corresponding to the F cells. 2. The available status of the dynamic resource of the resource.
上述技术方案,第二节点发送的第二指示信息可以指示D个载波对应的第一资源的可用资源的可用状态和F个小区对应的第二资源的动态资源的可用状态,而第一节点可以确定该第二指示信息所应用的小区和载波,从而可以实现在MT多载波DU多小区的情况下,D个载波对应的第一资源的可用资源的可用状态和F个小区对应的第二资源的动态资源的可用状态可以得到准确的指示。In the above technical solution, the second indication information sent by the second node may indicate the available status of the available resources of the first resources corresponding to the D carriers and the available status of the dynamic resources of the second resources corresponding to the F cells, and the first node may Determine the cell and carrier to which the second indication information is applied, so that in the case of MT multi-carrier DU multi-cell, the available status of the first resource corresponding to D carriers and the second resource corresponding to F cells can be realized The available status of the dynamic resources can be accurately indicated.
结合第一方面,在第一方面的某些实现方式中,第一节点接收第二节点发送的第二指示信息,该第二指示信息仅用于指示第一节点中D个载波对应的第一资源的可用资源的可用状态;第一节点根据第二指示信息确定D个载波对应的第一资源的可用资源的可用状态;第一节点根据D个载波对应的第一资源的可用资源的可用状态,和D个载波对应的第一资源与F个小区对应的第二资源之间的资源复用关系,确定F个小区对应的第二资源的动态资源的可用状态。With reference to the first aspect, in some implementations of the first aspect, the first node receives the second indication information sent by the second node, and the second indication information is only used to indicate the first node corresponding to the D carriers in the first node. The available state of the available resource of the resource; the first node determines the available state of the available resource of the first resource corresponding to the D carriers according to the second indication information; the first node determines the available state of the available resource of the first resource corresponding to the D carriers according to the second indication information , The resource reuse relationship between the first resources corresponding to the D carriers and the second resources corresponding to the F cells determines the available status of the dynamic resources of the second resources corresponding to the F cells.
上述技术方案中,可以通过IAB节点的上级节点对IAB节点MT资源的显示指示,并根据MT的各个载波与DU的各个小区之间的资源复用或关联关系,推导出DU soft资源的可用性。In the above technical solution, the MT resource of the IAB node can be displayed and indicated by the superior node of the IAB node, and the availability of the DUsoft resource can be derived based on the resource reuse or association relationship between each carrier of the MT and each cell of the DU.
结合第一方面,在第一方面的某些实现方式中,第一节点接收第二节点发送的第二指示信息,该第二指示信息仅用于指示第一节点中F个小区对应的第二资源的动态资源的可用状态;第一节点根据第二指示信息确定F个小区对应的第二资源的动态资源的可用状态;第一节点F个小区对应的第二资源的动态资源的可用状态,和D个载波对应的第一资源与F个小区对应的第二资源之间的资源复用关系,确定D个载波对应的第一资源的可用资源的可用状态。With reference to the first aspect, in some implementations of the first aspect, the first node receives the second indication information sent by the second node, and the second indication information is only used to indicate the second indication information corresponding to the F cells in the first node. The available state of the dynamic resource of the resource; the first node determines the available state of the dynamic resource of the second resource corresponding to the F cells according to the second indication information; the available state of the dynamic resource of the second resource corresponding to the F cells of the first node, The resource reuse relationship between the first resources corresponding to the D carriers and the second resources corresponding to the F cells determines the available state of the available resources of the first resources corresponding to the D carriers.
上述技术方案中,可以通过IAB节点的上级节点对IAB节点DU soft资源的显示指示,并根据MT的各个载波与DU的各个小区之间的资源复用或关联关系,推导出MT资源的可用性。In the above technical solution, the DU soft resources of the IAB node can be displayed by the upper node of the IAB node, and the availability of the MT resource can be derived based on the resource reuse or association relationship between each carrier of the MT and each cell of the DU.
结合第一方面,在第一方面的某些实现方式中,第二节点为第一节点的上级节点;第一资源为第一节点与第二节点通信的传输资源,第二资源为第一节点与第三节点通信的传输资源,第三节点为第一节点的下级节点。With reference to the first aspect, in some implementations of the first aspect, the second node is an upper-level node of the first node; the first resource is a transmission resource for communication between the first node and the second node, and the second resource is the first node The transmission resource for communicating with the third node, and the third node is a subordinate node of the first node.
结合第一方面,在第一方面的某些实现方式中,第一资源的可用资源为第一资源经过半静态资源配置后确定的可用资源。With reference to the first aspect, in some implementation manners of the first aspect, the available resource of the first resource is an available resource determined after the first resource is configured through a semi-static resource.
上述技术方案中,通过半静态资源配置,可以获得MT资源的D/U/F三种资源类型。In the above technical solution, through semi-static resource configuration, three resource types of D/U/F of MT resources can be obtained.
结合第一方面,在第一方面的某些实现方式中,第二资源的动态资源为第二资源经过半静态资源配置后确定的动态资源。With reference to the first aspect, in some implementation manners of the first aspect, the dynamic resource of the second resource is a dynamic resource determined after the second resource is configured through a semi-static resource.
上述技术方案中,通过半静态资源配置,可以获得DU资源的D/U/F三种资源类型,DU 资源的hard/soft属性(attribute),以及不可用资源(NA)的时域位置。In the above technical solution, through the semi-static resource configuration, three resource types of D/U/F of the DU resource, the hard/soft attribute of the DU resource, and the time domain location of the unavailable resource (NA) can be obtained.
结合第一方面,在第一方面的某些实现方式中,D个载波对应的第一资源与F个小区对应的第二资源之间的资源复用关系至少包括以下一种:时分复用、半双工频分复用、半双工空分复用、全双工、动态自适应频分复用、动态自适应空分复用、动态自适应全双工。With reference to the first aspect, in some implementations of the first aspect, the resource reuse relationship between the first resources corresponding to D carriers and the second resources corresponding to F cells includes at least one of the following: time division multiplexing, Half-duplex frequency division multiplexing, half-duplex space division multiplexing, full duplex, dynamic adaptive frequency division multiplexing, dynamic adaptive space division multiplexing, dynamic adaptive full duplex.
上述技术方案中,在获取到DU的资源配置后,IAB节点和上级节点可以根据上述资源复用关系推导IAB MT的可用/不可用资源。或者,在获取到MT的可用资源的可用状态后,IAB节点和上级节点可以根据上述资源复用关系推导IAB节点的DUsoft资源的可用状态。或者,在获取到DUsoft资源的可用状态后,IAB节点和上级节点可以根据上述资源复用关系推导IAB节点的MT可用资源的可用状态。In the above technical solution, after obtaining the resource configuration of the DU, the IAB node and the upper-level node can derive the available/unavailable resources of the IAB MT according to the above-mentioned resource reuse relationship. Or, after obtaining the available status of the available resources of the MT, the IAB node and the upper-level node may derive the available status of the DUsoft resources of the IAB node according to the above-mentioned resource reuse relationship. Alternatively, after obtaining the available status of the DUsoft resources, the IAB node and the upper-level node can derive the available status of the MT available resources of the IAB node according to the above-mentioned resource reuse relationship.
结合第一方面,在第一方面的某些实现方式中,第二指示信息的指示范围包括以下至少一种:半静态资源配置确定的第一资源的可用资源;F个小区中由指定的G个小区确定的与G个小区具有资源复用关系的第一待指示资源集合;第二节点或宿主节点指示的第一资源中的部分资源组成的第二待指示资源集合;第二节点或宿主节点指示的第一资源中的全部资源组成的第三待指示资源集合。With reference to the first aspect, in some implementations of the first aspect, the indication range of the second indication information includes at least one of the following: the available resources of the first resource determined by the semi-static resource configuration; A first set of resources to be indicated that has a resource reuse relationship with G cells determined by a cell; a second set of resources to be indicated consisting of part of the first resources indicated by a second node or a donor node; a second node or host A third resource set to be indicated consisting of all resources in the first resource indicated by the node.
结合第一方面,在第一方面的某些实现方式中,第二指示信息包含D个载波的标识和/或F个小区的标识。With reference to the first aspect, in some implementations of the first aspect, the second indication information includes the identities of D carriers and/or the identities of F cells.
结合第一方面,在第一方面的某些实现方式中,第二指示信息为下行控制信息DCI。With reference to the first aspect, in some implementation manners of the first aspect, the second indication information is downlink control information DCI.
结合第一方面,在第一方面的某些实现方式中,下行控制信息DCI还包括以下至少一种信息:控制资源集信息、搜索空间集合信息、指示时延信息、指示范围信息。With reference to the first aspect, in some implementations of the first aspect, the downlink control information DCI further includes at least one of the following information: control resource set information, search space set information, indication delay information, and indication range information.
第二方面,本申请提供了一种中继装置,该中继装置具有实现第一方面及其任意可能的实现方式中的方法的功能。所述功能可以通过硬件实现,也可以通过硬件执行相应的软件实现。所述硬件或软件包括一个或多个与上述功能相对应的单元。In the second aspect, this application provides a relay device that has the function of implementing the method in the first aspect and any possible implementation manners thereof. The function can be realized by hardware, or by hardware executing corresponding software. The hardware or software includes one or more units corresponding to the above-mentioned functions.
第三方面,本申请提供一种计算机可读存储介质,计算机可读存储介质中存储有计算机指令,当计算机指令在计算机上运行时,使得计算机执行第一方面或第一方面的任意可能的实现方式中的方法。In a third aspect, the present application provides a computer-readable storage medium in which computer instructions are stored. When the computer instructions are executed on the computer, the computer executes the first aspect or any possible implementation of the first aspect The method in the way.
第四方面,本申请提供一种芯片,包括处理器。处理器用于读取并执行存储器中存储的计算机程序,以执行第一方面或第一方面任意可能的实现方式中的方法。In a fourth aspect, the present application provides a chip including a processor. The processor is used to read and execute the computer program stored in the memory to execute the method in the first aspect or any possible implementation manner of the first aspect.
可选地,所述芯片还包括存储器,存储器与处理器通过电路或电线与存储器连接,存储器用于存储计算机程序。Optionally, the chip further includes a memory, and the memory and the processor are connected to the memory through a circuit or a wire, and the memory is used to store a computer program.
进一步可选地,所述芯片还包括通信接口。Further optionally, the chip further includes a communication interface.
第五方面,本申请还提供一种计算机程序产品,所述计算机程序产品包括计算机程序代码,当所述计算机程序代码在计算机上运行时,使得计算机执行上述第一方面及其任意一种可能的实现方式中的方法。In a fifth aspect, the present application also provides a computer program product. The computer program product includes computer program code. When the computer program code runs on a computer, the computer executes the first aspect and any one of the possibilities thereof. The method in the implementation mode.
本申请提供的资源的动态指示方法,通过动态资源信令的指示,可以显式或隐式地指示IAB节点的MT的可用资源的可用状态,以及显式或隐式地指示IAB节点的DU soft资源的可用状态。在MT具有多载波以及DU具有多小区的场景下,可以实现IAB节点的MT资源与DU资源的动态共享。The resource dynamic indication method provided in this application can explicitly or implicitly indicate the available resource status of the MT of the IAB node through the indication of dynamic resource signaling, and explicitly or implicitly indicate the DU soft of the IAB node. The availability status of the resource. In the scenario where the MT has multiple carriers and the DU has multiple cells, the dynamic sharing of the MT resource and the DU resource of the IAB node can be realized.
图1为适用于本申请实施例的一种IAB系统的架构图;Fig. 1 is an architecture diagram of an IAB system applicable to an embodiment of the present application;
图2为本申请实施例提供的一种IAB系统的简单示例;Figure 2 is a simple example of an IAB system provided by an embodiment of the application;
图3为本申请实施例提供的一种接入链路与回传链路的示意图;FIG. 3 is a schematic diagram of an access link and a backhaul link provided by an embodiment of this application;
图4为本申请实施例提供的一种IAB节点的结构示意图;FIG. 4 is a schematic structural diagram of an IAB node provided by an embodiment of this application;
图5为本申请实施例提供的一种MT和DU的逻辑示意图;FIG. 5 is a logical schematic diagram of an MT and DU provided by an embodiment of this application;
图6为本申请实施例提供的另一种接入链路和回传链路的示意图;FIG. 6 is a schematic diagram of another access link and backhaul link provided by an embodiment of the application;
图7为LTE的中继系统中配置回传资源的方法;Fig. 7 is a method for configuring backhaul resources in the LTE relay system;
图8为NR的IAB系统中资源配置的一例示意图;Figure 8 is a schematic diagram of an example of resource configuration in NR's IAB system;
图9为本申请实施例提供的一种多小区的DU资源与MT资源的关系示意图;FIG. 9 is a schematic diagram of the relationship between DU resources and MT resources of a multi-cell according to an embodiment of this application;
图10为本申请实施例提供的一种资源的动态指示方法的流程图;FIG. 10 is a flowchart of a method for dynamically indicating resources according to an embodiment of the application;
图11为本申请实施例提供的一种MT包含两个载波DU包含4个小区的情况示例;FIG. 11 is an example of a case where the MT includes two carriers and the DU includes 4 cells according to an embodiment of the application;
图12为本申请实施例提供的MT的载波与DU小区具有的复用或关联关系的示意图;FIG. 12 is a schematic diagram of the multiplexing or association relationship between a MT carrier and a DU cell provided by an embodiment of the application;
图13为本申请实施例提供的一种半静态资源配置中MT各个载波的可用/不可用资源的推导方法示例;FIG. 13 is an example of a method for deriving available/unavailable resources of each carrier of an MT in a semi-static resource configuration provided by an embodiment of this application;
图14为本申请实施例提供的一种IAB节点的DU soft资源的动态资源指示方法示例;FIG. 14 is an example of a dynamic resource indication method for DU soft resources of an IAB node provided by an embodiment of this application;
图15为本申请实施例提供的一种包含指示时延信息的指示DCI的示例;FIG. 15 is an example of an indication DCI including indication delay information provided by an embodiment of this application;
图16为本申请实施例提供的一种IAB节点的MT资源的动态资源指示方法示例;FIG. 16 is an example of a dynamic resource indication method for MT resources of an IAB node provided by an embodiment of this application;
图17为本申请实施例提供的一种中继装置1700的示意图;FIG. 17 is a schematic diagram of a relay device 1700 according to an embodiment of the application;
下面将结合附图,对本申请中的技术方案进行描述。The technical solution in this application will be described below in conjunction with the accompanying drawings.
本申请中所有节点、消息的名称仅仅是为了描述方便而设定的名称,在实际网络中的名称可能不同,不应该理解本申请限定各种节点、消息的名称。相反,任何具有和本申请中使用的节点或消息具有相同或类似功能的名称都视作本申请的方法或等效替换,都在本申请的保护范围之内,以下不再赘述。The names of all nodes and messages in this application are only names set for the convenience of description. The names in the actual network may be different, and it should not be understood that this application limits the names of various nodes and messages. On the contrary, any name that has the same or similar function as the node or message used in this application is regarded as a method or equivalent replacement of this application, and is within the protection scope of this application, and will not be repeated hereafter.
本申请涉及的通信系统包括但不限于:窄带物联网(narrow band-internet of things,NB-IoT)系统、无线局域网(wireless local access network,WLAN)系统、长期演进(long term evolution,LTE)系统、第五代移动通信(5th generation mobile networks or 5th generation wireless systems,5G)系统或者5G之后的通信系统,例如新空口(new radio,NR)系统、设备到设备(device to device,D2D)通信系统等。The communication systems involved in this application include but are not limited to: narrowband-internet of things (NB-IoT) systems, wireless local access network (WLAN) systems, and long-term evolution (LTE) systems , Fifth generation mobile networks (5th generation mobile networks or 5G) systems or communication systems after 5G, such as new radio (NR) systems, device to device (device to device, D2D) communication systems Wait.
为了更好地理解本申请提供的技术方案,下面先对本申请适用的网络架构进行描述。本申请适用于具有中继设备的无线通信系统。中继设备包括普通的固定中继节点,例如IAB节点,也包括移动的中继节点,如移动IAB节点,终端设备UE中继等。为了描述方便,本申请以中继设备是IAB节点为例,对提供的技术方案进行描述,应理解,在本申请中,IAB节点可以泛指任何具有中继功能的节点或设备,并不表示本申请的方案仅适用于NR的场景,本申请中,IAB节点和中继节点、或中继设备的使用应理解具有相同的含义。In order to better understand the technical solutions provided by this application, the following first describes the network architecture applicable to this application. This application is suitable for wireless communication systems with relay equipment. The relay equipment includes ordinary fixed relay nodes, such as IAB nodes, and also includes mobile relay nodes, such as mobile IAB nodes, terminal equipment UE relays, and so on. For the convenience of description, this application uses the relay device as an IAB node as an example to describe the technical solution provided. It should be understood that in this application, an IAB node can generally refer to any node or device with a relay function, and does not mean The solution in this application is only applicable to NR scenarios. In this application, the use of IAB nodes and relay nodes or relay devices should be understood to have the same meaning.
参见图1,图1为适用于本申请实施例的一种IAB系统的架构图。如图1所示,一个IAB系统至少包括一个基站100,以及基站100所服务的一个或多个终端设备(terminal)101,一个或多个中继节点(以IAB节点为例)110,以及IAB节点110所服务的一个或多个终端设备111。通常,基站100可被称为宿主基站(donor next generation node B,DgNB),IAB节 点110通过无线回传链路113连接到基站100。宿主基站在本申请中也称为宿主节点,donor节点,或donor基站。Refer to FIG. 1, which is an architecture diagram of an IAB system suitable for an embodiment of the present application. As shown in Figure 1, an IAB system includes at least one base station 100, one or more terminal devices (terminals) 101 served by the base station 100, one or more relay nodes (taking IAB nodes as an example) 110, and IAB One or more terminal devices 111 served by the node 110. Generally, the base station 100 may be called a donor next generation node B (DgNB), and the IAB node 110 is connected to the base station 100 through a wireless backhaul link 113. The donor base station is also referred to as a donor node, a donor node, or a donor base station in this application.
基站100包括但不限于:演进型节点B(evolved node base,eNB)、基带单元(baseband Unit,BBU)、演进的基站(evolved LTE,eLTE)、NR基站(next generation node B,gNB)以及5G通信系统之后的基站等。The base station 100 includes but is not limited to: evolved node B (evolved node base, eNB), baseband unit (BBU), evolved base station (evolved LTE, eLTE), NR base station (next generation node B, gNB), and 5G Base stations behind the communication system, etc.
终端设备包括但不限于:终端设备(user equipment,UE)、移动台、接入终端、用户单元、用户站、移动站、远方站、远程终端、移动设备、终端、无线通信设备、用户代理、无线局域网(wireless local access network,WLAN)中的站点(station,ST)、蜂窝电话、无绳电话、会话启动协议(session initiation protocol,SIP)电话、无线本地环路(wireless local loop,WLL)站、个人数字处理(personal digital assistant,PDA)、具有无线通信功能的手持设备、计算设备、连接到无线调制解调器的其它处理设备、车载设备、可穿戴设备、5G网络中的移动台以及未来演进的公共陆地移动网络(public land mobile network,PLMN)网络中的终端设备等中的任意一种。Terminal equipment includes but is not limited to: terminal equipment (user equipment, UE), mobile station, access terminal, user unit, user station, mobile station, remote station, remote terminal, mobile equipment, terminal, wireless communication equipment, user agent, Station (ST), cellular phone, cordless phone, session initiation protocol (SIP) phone, wireless local loop (wireless local loop, WLL) station in wireless local area network (wireless local access network, WLAN), cell phone, cordless phone, Personal digital assistant (PDA), handheld devices with wireless communication functions, computing devices, other processing devices connected to wireless modems, in-vehicle devices, wearable devices, mobile stations in 5G networks, and public land in the future Any one of terminal devices in a public land mobile network (PLMN) network.
IAB节点是5G NR系统中中继节点的特定名称,不对本申请的方案构成限定。其可以是一种具有转发功能的上述基站或者终端设备中的一种,也可以是一种独立的设备形态。例如,本申请中的IAB节点也可以被称为中继节点(relay node,RN)、传输接收点(transmission and reception point,TRP)、中继发送接收点(relaying TRP)等。The IAB node is the specific name of the relay node in the 5G NR system, and does not limit the solution of this application. It may be one of the aforementioned base stations or terminal devices with a forwarding function, or it may be an independent device form. For example, the IAB node in this application may also be called a relay node (RN), a transmission and reception point (TRP), a relay transmission and reception point (TRP), and so on.
图1所示的IAB系统还可以包括多个其它IAB节点,例如,IAB节点120和IAB节点130。IAB节点120通过无线回传链路123连接到IAB节点110以接入到网络。IAB节点130通过无线回传链路133连接到IAB节点110以接入到网络。IAB节点120为一个或多个终端设备121服务,IAB节点130为一个或多个终端设备131服务。图1中,IAB节点110和IAB节点120都通过无线回传链路连接到网络。在本申请中,所述无线回传链路都是从中继节点的角度来看的,例如无线回传链路113是IAB节点110的回传链路,无线回传链路123是IAB节点120的回传链路。如图1所示,一个IAB节点,如IAB节点120,可以通过无线回传链路,如123,连接另一个IAB节点110,从而连接到网络。而且,中继节点可以经过多级无线中继节点连接到网络。应理解,本申请中使用IAB节点仅仅出于描述的需要,并不表示本申请的方案仅适用于NR的场景,在本申请中,IAB节点可以泛指任何具有中继功能的节点或设备,本申请中,IAB节点和中继节点或中继设备的使用应理解具有相同的含义。The IAB system shown in FIG. 1 may also include multiple other IAB nodes, for example, the IAB node 120 and the IAB node 130. The IAB node 120 is connected to the IAB node 110 through a wireless backhaul link 123 to access the network. The IAB node 130 is connected to the IAB node 110 through a wireless backhaul link 133 to access the network. The IAB node 120 serves one or more terminal devices 121, and the IAB node 130 serves one or more terminal devices 131. In FIG. 1, both the IAB node 110 and the IAB node 120 are connected to the network through a wireless backhaul link. In this application, the wireless backhaul links are all viewed from the perspective of the relay node. For example, the wireless backhaul link 113 is the backhaul link of the IAB node 110, and the wireless backhaul link 123 is the IAB node 120. Backhaul link. As shown in FIG. 1, an IAB node, such as an IAB node 120, can be connected to another IAB node 110 through a wireless backhaul link, such as 123, so as to be connected to the network. Moreover, the relay node can be connected to the network via a multi-level wireless relay node. It should be understood that the use of IAB nodes in this application is only for the purpose of description, and does not mean that the solution of this application is only applicable to NR scenarios. In this application, IAB nodes can generally refer to any node or device with a relay function. In this application, the use of an IAB node and a relay node or a relay device should be understood to have the same meaning.
应理解,图1所示的IAB系统中,一个IAB节点连接一个上级节点。但是在未来的中继系统中,为了提高无线回传链路的可靠性,一个IAB节点,如120,可以有多个上级节点同时为一个IAB节点提供服务,如图1中的IAB节点130还可以通过回传链路134连接到IAB节点120,即,IAB节点110和IAB节点120都视为IAB节点130的上级节点。IAB节点110,120,130的名称并不限制其所部署的场景或网络,可以是比如relay,RN等任何其他名称。本申请使用IAB节点仅是方便描述的需要,在本申请中,IAB节点可以泛指任何具有中继功能的节点或设备。It should be understood that in the IAB system shown in FIG. 1, an IAB node is connected to an upper-level node. However, in the future relay system, in order to improve the reliability of the wireless backhaul link, an IAB node, such as 120, can have multiple upper-level nodes providing services to an IAB node at the same time. The IAB node 130 in Figure 1 also It may be connected to the IAB node 120 through the backhaul link 134, that is, both the IAB node 110 and the IAB node 120 are regarded as the upper node of the IAB node 130. The names of the IAB nodes 110, 120, and 130 do not limit the scenarios or networks where they are deployed, and may be any other names such as relay and RN. The use of an IAB node in this application is only needed for convenience of description. In this application, an IAB node can generally refer to any node or device with a relay function.
在图1所示的IAB系统中,无线链路102,112,122,132,113,123,133,134可以是双向链路,包括上行和下行传输链路,特别地,无线回传链路113,123,133,134可以用于上级节点为下级节点提供服务,如上级节点100为下级节点110提供无线回传服务。应理解,回传链路的上行和下行可以是分离的,即,上行链路和下行链路不是通过同一个节点进行传输的。所述下行传输是指上级节点,例如节点100,向下级节点,例如节点110,传输信 息或数据,上行传输是指下级节点,例如节点110,向上级节点,例如节点100,传输信息或数据。所述节点不限于是网络节点还是终端设备,例如,在D2D场景下,终端设备可以充当中继节点为其他终端设备服务。无线回传链路在某些场景下又可以是接入链路,如回传链路123对节点110来说也可以被视作接入链路,回传链路113也是节点100的接入链路。应理解,上述上级节点可以是基站,也可以是中继节点,下级节点可以是中继节点,也可以是具有中继功能的终端设备,例如D2D场景下,下级节点可以是终端设备。In the IAB system shown in Figure 1, the wireless links 102, 112, 122, 132, 113, 123, 133, 134 may be bidirectional links, including uplink and downlink transmission links, in particular, wireless backhaul links 113, 123, 133, 134 can be used by the upper-level node to provide services for the lower-level nodes, for example, the upper-level node 100 provides wireless backhaul services for the lower-level node 110. It should be understood that the uplink and downlink of the backhaul link may be separated, that is, the uplink and the downlink are not transmitted through the same node. The downlink transmission refers to an upper node, such as node 100, and a lower node, such as node 110, transmitting information or data, and the uplink transmission refers to a lower node, such as node 110, and an upper node, such as node 100, transmitting information or data. The node is not limited to whether it is a network node or a terminal device. For example, in a D2D scenario, the terminal device can act as a relay node to serve other terminal devices. The wireless backhaul link can be an access link in some scenarios. For example, the backhaul link 123 can also be regarded as an access link for the node 110, and the backhaul link 113 is also the access link of the node 100. link. It should be understood that the foregoing upper-level node may be a base station or a relay node, and the lower-level node may be a relay node or a terminal device with a relay function. For example, in a D2D scenario, the lower-level node may be a terminal device.
参见图2,图2是IAB系统的一个简单示例。在图2所示的IAB系统中,包括宿主基站,IAB节点1,IAB节点2,终端设备UE1和终端设备UE2。其中,宿主基站和IAB节点1之间的链路,以及IAB节点1和IAB节点2之间的链路为回传链路。终端设备UE1和宿主基站之间的链路以及终端设备UE2和IAB节点1之间的链路为接入链路。See Figure 2. Figure 2 is a simple example of an IAB system. In the IAB system shown in FIG. 2, it includes a donor base station, IAB node 1, IAB node 2, terminal equipment UE1 and terminal equipment UE2. Among them, the link between the donor base station and the IAB node 1 and the link between the IAB node 1 and the IAB node 2 are backhaul links. The link between the terminal equipment UE1 and the donor base station and the link between the terminal equipment UE2 and the IAB node 1 are access links.
另外,本申请中还涉及到如下基本术语或概念的具体含义。In addition, this application also involves the specific meanings of the following basic terms or concepts.
接入链路(access link):终端设备UE和IAB节点(IAB node)或IAB宿主节点(IAB donor)之间的链路。或者,接入链路包括某个节点和它的下级节点进行通信时所使用的无线链路。接入链路包括上行接入链路和下行接入链路。上行接入链路也被称为接入链路的上行传输,下行接入链路也被称为接入链路的下行传输。Access link: the link between the terminal equipment UE and the IAB node (IAB node) or IAB donor node (IAB donor). Or, the access link includes a wireless link used when a node communicates with its subordinate nodes. The access link includes an uplink access link and a downlink access link. The uplink access link is also referred to as the uplink transmission of the access link, and the downlink access link is also referred to as the downlink transmission of the access link.
回传链路(backhaul link):IAB节点(IAB node)和IAB子节点(IAB child node)或者IAB父节点(IAB parent node)之间的链路。回传链路包括和IAB子节点或者IAB父节点的下行传输的链路,以及和IAB子节点或者IAB父节点的上行传输的链路。IAB节点向IAB父节点进行的数据传输,或者接收IAB子节点的上行传输被称为回传链路的上行传输。IAB节点接收IAB父节点的数据传输,或者向IAB子节点进行的数据传输被称为回传链路的下行传输。为了对终端设备UE和IAB节点进行区分,IAB节点与IAB父节点之间的回传链路又被称为上级回传链路(parent BH),而IAB节点与IAB子节点之间的回传链路被称为下级回传链路(child BH)。在一些情况下,IAB节点的下级回传链路和接入链路被统称为接入链路,即下级节点被视作是上级节点的一个终端设备。参见图3,图3是一种接入链路与回传链路的示意图。Backhaul link: A link between an IAB node (IAB node) and an IAB child node (IAB child node) or IAB parent node (IAB parent node). The backhaul link includes the downlink transmission link with the IAB child node or the IAB parent node, and the uplink transmission link with the IAB child node or the IAB parent node. The data transmission from the IAB node to the IAB parent node or the uplink transmission from the IAB child node is called the uplink transmission of the backhaul link. The IAB node receives the data transmission of the IAB parent node, or the data transmission to the IAB child node is called the downlink transmission of the backhaul link. In order to distinguish the terminal equipment UE from the IAB node, the backhaul link between the IAB node and the IAB parent node is also called the parent BH, and the backhaul between the IAB node and the IAB child node The link is called the lower-level backhaul link (child BH). In some cases, the lower-level backhaul link and the access link of the IAB node are collectively referred to as the access link, that is, the lower-level node is regarded as a terminal device of the upper-level node. Refer to Figure 3, which is a schematic diagram of an access link and a backhaul link.
进一步的,参见图4,图4是IAB节点的结构示意图。如图4所示,终端(mobile-termination,MT)功能被定义为类似UE的一个组件。在IAB中,MT被称为驻留在IAB节点上的功能(或模块)。由于MT类似一个普通UE的功能,因此可以认为IAB节点通过MT接入到上级节点或网络。分布式单元(distributed unit,DU)功能被定义为类似基站的一个组件。在IAB系统中,DU被称为驻留在IAB节点上的功能(或模块)。由于DU类似一个普通基站的功能或者部分功能,因此,可以认为IAB节点可以通过DU允许下级节点、终端设备的接入。需要说明的是,在下文中终端功能简称为终端单元,其和终端功能的使用应理解具有相同的含义,终端单元特指驻留在IAB节点上的某一功能和/或模块,用以与本申请中可作为下级节点的终端设备UE进行区分。Further, referring to Fig. 4, Fig. 4 is a schematic structural diagram of an IAB node. As shown in Figure 4, the terminal (mobile-termination, MT) function is defined as a component similar to the UE. In IAB, MT is called a function (or module) that resides on the IAB node. Since the MT is similar to the function of an ordinary UE, it can be considered that the IAB node accesses the upper-level node or network through the MT. A distributed unit (DU) function is defined as a component similar to a base station. In the IAB system, the DU is called a function (or module) that resides on the IAB node. Since the DU is similar to the function or part of the function of an ordinary base station, it can be considered that the IAB node can allow the access of lower-level nodes and terminal equipment through the DU. It should be noted that in the following, the terminal function is referred to as the terminal unit for short, and the use of it and the terminal function should be understood to have the same meaning. The terminal unit specifically refers to a certain function and/or module residing on the IAB node to be used with the original The terminal equipment UE that can be used as a lower-level node in the application can be distinguished.
IAB节点的MT与DU模块均具有完整的收发单元,且两者之间具有接口。但应注意,MT与DU为逻辑模块,在实际中,两者可以共享部分子模块,例如可共用收发天线,基带处理单元等,如图5所示。进一步的,D IAB节点的MT可具有多个子单元,多个子单元可以是多个载波,多个面板,多个小区等;IAB节点的DU也可能具有多个子单元,多个子单元可以是多个载波,多个面板,多个小区等。例如,DU可具有多个小区(cell),MT可具有多个载波等。而MT的子单元与DU的子单元之间具有一定的关联或复用关系。Both the MT and DU modules of the IAB node have a complete transceiver unit, and there is an interface between the two. However, it should be noted that MT and DU are logical modules. In practice, they can share some sub-modules, for example, they can share transceiver antennas, baseband processing units, etc., as shown in Figure 5. Further, the MT of the D IAB node may have multiple subunits, which may be multiple carriers, multiple panels, multiple cells, etc.; the DU of the IAB node may also have multiple subunits, and multiple subunits may be multiple Carrier, multiple panels, multiple cells, etc. For example, the DU may have multiple cells, the MT may have multiple carriers, and so on. And there is a certain association or multiplexing relationship between the subunits of the MT and the subunits of the DU.
进一步的,IAB节点通过MT与上级节点通信,MT的功能与普通UE相似。因此,IAB节点的MT(以下可简称为IAB MT)可能采用载波聚合(carrier aggregation,CA)与上级节点通信,例如,MT可具有多个载波(component carrier,CC)。此外,IAB节点的DU(以下可简称为IAB DU)也可具有多个子模块,例如,DU可具有多个小区(cell)。以两种可能的情况举例:(1)DU具有多个朝向的面板(panel)或扇区,不同的面板是不同的小区;(2)DU采用载波聚合,不同的载波是不同的小区。Further, the IAB node communicates with the upper node through the MT, and the function of the MT is similar to that of a normal UE. Therefore, the MT of the IAB node (hereinafter referred to as IAB MT) may use carrier aggregation (CA) to communicate with the upper node. For example, the MT may have multiple carriers (component carriers, CC). In addition, the DU of the IAB node (hereinafter referred to as IAB DU) may also have multiple sub-modules. For example, the DU may have multiple cells. Take two possible cases for example: (1) DU has multiple facing panels or sectors, and different panels are different cells; (2) DU adopts carrier aggregation, and different carriers are different cells.
结合图3,MT与上级节点通信的链路被称为上级回传链路(parent BH link),DU与下级IAB节点通信的链路被称为下级回传链路(child BH link),而DU与下级UE通信的链路被称为接入链路(access link)。其中,上级回传链路包括上级回传上行链路(uplink,UL)以及上级回传下行链路(downlink,DL),下级回传链路包括下级回传上行链路(UL)和下级回传下行链路(DL),接入链路包括接入上行链路(UL)和接入下行链路(DL),如图6所示。在一些情况下,下级回传链路也被称为接入链路。With reference to Figure 3, the link between the MT and the upper-level node is called the parent BH link, and the link between the DU and the lower-level IAB node is called the child BH link, and The link through which the DU communicates with the lower-level UE is called an access link. Among them, the upper-level backhaul link includes the upper-level backhaul uplink (uplink, UL) and the upper-level backhaul downlink (downlink, DL), and the lower-level backhaul link includes the lower-level backhaul uplink (UL) and the lower-level backhaul. Transmission downlink (DL), access link includes access uplink (UL) and access downlink (DL), as shown in Figure 6. In some cases, the lower-level backhaul link is also called an access link.
下面结合图7介绍LTE的中继系统中配置回传资源的方法。The method for configuring backhaul resources in the LTE relay system will be introduced below in conjunction with FIG. 7.
在LTE的中继系统中,donor节点(或宿主节点)为中继节点RN半静态的配置回传资源。图7示出了LTE的中继系统中下行回传资源配置的一个具体示例。在LTE中,donor节点以子帧(1ms)为单位为中继节点分配回传链路资源,分配周期为一个无线帧(10ms)。具体地,宿主基站通过无线资源控制(radio resource control,RRC)信令将部分子帧指定为回传链路子帧。回传链路子帧的数量和位置可被重配,然而RRC信令重配所需时间较长。In the LTE relay system, the donor node (or host node) semi-statically configures the backhaul resources for the relay node RN. Fig. 7 shows a specific example of downlink backhaul resource configuration in the LTE relay system. In LTE, the donor node allocates backhaul link resources to the relay node in units of subframes (1ms), and the allocation period is one radio frame (10ms). Specifically, the donor base station designates some subframes as backhaul link subframes through radio resource control (RRC) signaling. The number and position of the backhaul link subframes can be reconfigured, but the RRC signaling reconfiguration takes a longer time.
以下行传输为例,对于LTE中的中继节点,当某个子帧被配置为回传链路子帧时,中继节点需要在此子帧监测中继物理下行控制信道(relay physical downlink control channel,R-PDCCH)和/或接收物理下行共享信道(physical downlink share channel,PDSCH),因此无法在接入链路进行发送。如图7所示,子帧2、4、6被配置为回传链路子帧,则对应位置的接入链路上子帧2、4、6不可用。因此,LTE中配置回传资源的方法为半静态的时分复用(time division multiplexing,TDM)资源分配。Take the following transmission as an example. For a relay node in LTE, when a subframe is configured as a backhaul link subframe, the relay node needs to monitor the relay physical downlink control channel in this subframe. , R-PDCCH) and/or receiving physical downlink share channel (PDSCH), so it cannot be sent on the access link. As shown in FIG. 7, subframes 2, 4, and 6 are configured as backhaul link subframes, and subframes 2, 4, and 6 on the access link at the corresponding positions are unavailable. Therefore, the method for configuring backhaul resources in LTE is semi-static time division multiplexing (TDM) resource allocation.
下面结合图8介绍NR的IAB系统中的资源配置方法。The resource allocation method in the IAB system of NR is introduced below in conjunction with FIG. 8.
参见图8,图8是NR的IAB系统(以下可简称NR IAB)中资源配置的一例示意图。其中,IAB节点的MT资源可以被配置为上行(uplink,U)、下行(downlink,D)、灵活(Flexible,F)三种类型。这三种类型也是现有技术中的终端设备所支持的,因此MT资源可以使用现有信令指示。与终端设备不同的是,IAB节点MT可以支持更多的D/U/F顺序。例如:终端设备仅支持D--F--U的顺序;MT可支持U--F--D或U--D的顺序等。Referring to FIG. 8, FIG. 8 is a schematic diagram of an example of resource configuration in the NR IAB system (hereinafter referred to as NR IAB). Among them, the MT resource of the IAB node can be configured into three types: uplink (U), downlink (D), and flexible (F). These three types are also supported by terminal equipment in the prior art, so MT resources can be indicated by using existing signaling. Different from the terminal equipment, the IAB node MT can support more D/U/F sequences. For example: the terminal equipment only supports the sequence of D--F--U; the MT can support the sequence of U--F--D or U--D, etc.
IAB节点的DU资源可以被配置为上行(U),下行(D),灵活(F)三种类型。进一步地,DU的上行,下行,灵活三种类型的资源还可以被分为硬(hard,H)资源和软(softS)资源。其中,DU的hard资源,表示DU始终可用的资源;DU的soft资源,表示DU是否可用需要依赖于上级节点(例如donor节点)的指示。此外,DU还可能包括不可用(Null,N)资源。The DU resource of the IAB node can be configured into three types: uplink (U), downlink (D), and flexible (F). Further, the DU's uplink, downlink and flexible three types of resources can also be divided into hard (hard, H) resources and soft (softS) resources. Among them, the hard resource of the DU indicates the resource that is always available to the DU; the soft resource of the DU indicates that whether the DU is available or not depends on the indication of the upper-level node (such as the donor node). In addition, DU may also include unavailable (Null, N) resources.
由上可见,NR中IAB节点DU上部分资源(即软资源)的可用性依赖于上级节点的指示,需要通过半静态配置加动态指示的方式来进行DU资源的指示。此外,根据半静态资源配置得到的MT可用资源的可用性是否被修改为不可用,也需要依赖于上级节点的指示。这种资源分配方式和LTE系统中的资源分配方法有很大的不同。It can be seen from the above that the availability of some resources (that is, soft resources) on the IAB node DU in the NR depends on the instructions of the superior node, and the DU resource needs to be instructed by means of semi-static configuration plus dynamic indication. In addition, whether the availability of the MT's available resources obtained according to the semi-static resource configuration is modified to be unavailable also needs to depend on the instructions of the superior node. This resource allocation method is very different from the resource allocation method in the LTE system.
结合图3和图8,IAB节点的MT与上级节点的DU相连接,而IAB节点的DU与下级 节点的MT相连接,或者IAB节点的DU与UE相连接,在经过半静态(例如,通过RRC信令和/或F1-AP接口信令)的资源配置以后,IAB节点可以分别得到其MT资源和DU资源的资源配置。例如,可以包括MT资源和DU资源的传输方向(U/D/F),MT的可用/不可用资源的位置,DU资源的属性(soft/hard),DU的不可用资源(Null)的时域位置等。应理解,上述相关配置可以通过显式信令获得,也可以通过隐式的方式获得。With reference to Figures 3 and 8, the MT of the IAB node is connected to the DU of the upper node, and the DU of the IAB node is connected to the MT of the lower node, or the DU of the IAB node is connected to the UE. After the resource configuration of RRC signaling and/or F1-AP interface signaling), the IAB node can obtain the resource configuration of its MT resource and DU resource respectively. For example, it may include the transmission direction of MT resources and DU resources (U/D/F), the location of MT's available/unavailable resources, the attributes of DU resources (soft/hard), and the time of DU's unavailable resources (Null). Domain location, etc. It should be understood that the above-mentioned related configuration can be obtained through explicit signaling or implicitly.
具体的,IAB节点的MT共有三种类型的资源,而IAB节点的DU共有7种类型的资源,两两组合后,IAB节点的MT以及其对应的DU可能的行为如下面的两张表所示,其中表1为时分复用(time division multiplexing,TDM)场景下的MT以及DU的各种可能的资源类型组合下的资源配置情况。表2为空分复用(spatial division multiplexing,SDM)场景下的MT以及DU的各种可能的资源类型组合下的资源配置情况。Specifically, the MT of the IAB node has three types of resources, and the DU of the IAB node has a total of 7 types of resources. After pairwise combination, the possible behaviors of the MT of the IAB node and its corresponding DU are shown in the following two tables. As shown, Table 1 shows the resource configuration under various possible resource type combinations of MT and DU in a time division multiplexing (TDM) scenario. Table 2 shows the resource configuration under various possible resource type combinations of MT and DU in a spatial division multiplexing (SDM) scenario.
表1Table 1
表2Table 2
在上述表1和表2中,各标识的含义如下:In the above Table 1 and Table 2, the meaning of each symbol is as follows:
“MT:Tx”:MT在被调度后应进行传输;"MT:Tx": MT should transmit after being scheduled;
“DU:Tx”:DU可以进行传输;"DU:Tx": DU can be transmitted;
“MT:Rx”:MT有能力进行接收(如果有信号需要接收);"MT:Rx": MT has the ability to receive (if there is a signal that needs to be received);
“DU:Rx”:DU可以调度下级节点的上行传输;"DU:Rx": DU can schedule the uplink transmission of lower nodes;
“MT:Tx/Rx”:MT在被调度后应传输或接收,但传输和接收不同时发生;"MT:Tx/Rx": MT should transmit or receive after being scheduled, but transmission and reception do not occur at the same time;
“DU:Tx/Rx”:DU可以进行传输或接收下级节点的传输,但传输和接收不同时发生;"DU:Tx/Rx": DU can transmit or receive transmission from lower-level nodes, but transmission and reception do not occur at the same time;
“IA”:DU资源被显式或隐式的指示为可用;"IA": DU resource is indicated as available explicitly or implicitly;
“INA”:DU资源被显式或隐式的指示为不可用;"INA": DU resources are explicitly or implicitly indicated as unavailable;
“MT:NULL”:MT不进行发送且不必具有接收能力;"MT:NULL": MT does not send and does not have to have receiving capability;
“DU:NULL”:DU不进行发送且不接收下级节点的传输。"DU:NULL": DU does not send and does not receive transmissions from lower-level nodes.
IAB节点和其上级节点应该根据DU的资源配置确定或推导MT资源的可用性。推导的原则是MT的传输不影响DU对其hard资源的使用。作为示例,结合图8以及上面的表1可以看出,在TDM情况下,对于IAB节点,其DU的hard资源(例如,第1、6、7、8时隙对应的DU资源)所对应的MT资源(例如,第1、6、7、8时隙对应的MT资源)为不可用。The IAB node and its superior node should determine or derive the availability of MT resources according to the resource configuration of the DU. The principle of derivation is that the transmission of MT does not affect the use of hard resources by DU. As an example, in conjunction with Figure 8 and Table 1 above, it can be seen that in the case of TDM, for an IAB node, the hard resources of its DU (for example, the DU resources corresponding to the first, sixth, seventh, and eighth time slots) correspond to MT resources (for example, MT resources corresponding to time slots 1, 6, 7, and 8) are unavailable.
在DU具有多小区的情况下,DU的不同小区可能具有不同资源属性(hard/soft)的情况。例如,假设DU存在两个小区,分别为cell0和cell1,其中,cell0与MT共用天线面板,或与MT的天线面板同朝向。考虑五个时域资源(时隙),其中,时隙0是MT的下行资源,两个cell的下行soft资源,时隙1~3对于MT而言不可用,时隙1和时隙2是两个cell的下行hard资源,时隙3是两个cell的上下行灵活的hard资源,时隙4是MT的上行资源,cell0的soft资源,cell1的hard资源,如图9所示。需要说明的是,图9中字母“U”代表上行资源类型,字母“D”代表下行资源类型,字母“F”代表灵活资源类型,字母“S”代表soft资源属性,字母“H”代表hard资源属性。其中,DU两个cell在时隙4可以有不同的H/S类型的原因是cell1在此时隙的传输方向和MT传输方向相反,同时传输(发送)不会违背半双工约束(即MT与DU不能一收一发),且MT与cell#1面板反向,两者相互影响较小。When the DU has multiple cells, different cells of the DU may have different resource attributes (hard/soft). For example, suppose there are two cells in the DU, cell0 and cell1, where cell0 shares an antenna panel with the MT, or is oriented in the same direction as the MT antenna panel. Consider five time domain resources (time slots), among them, time slot 0 is the downlink resource of the MT, and the downlink soft resource of the two cells. Time slots 1 to 3 are not available to the MT, and time slot 1 and time slot 2 are For the downlink hard resources of the two cells, time slot 3 is the uplink and downlink flexible hard resources of the two cells, time slot 4 is the uplink resource of the MT, the soft resource of cell0, and the hard resource of cell1, as shown in Figure 9. It should be noted that in Figure 9 the letter "U" represents the uplink resource type, the letter "D" represents the downlink resource type, the letter "F" represents the flexible resource type, the letter "S" represents the soft resource attribute, and the letter "H" represents hard Resource attributes. Among them, the two cells of DU can have different H/S types in time slot 4 because the transmission direction of cell 1 in this time slot is opposite to the transmission direction of MT. At the same time, the transmission (transmission) will not violate the half-duplex constraint (ie, MT). And DU cannot receive and send), and the MT and cell# 1 panels are reversed, and the two have little influence on each other.
为了在接入链路和回传链路之间动态协调资源,NR IAB将使用两级资源指示。具体地,两级资源指示是指,上级节点通过显式或隐式的方式为IAB节点的DU配置资源,资源属性至少包括soft和hard两种。其中,hard资源表示IAB节点的DU始终可用的资源,而soft资源的可用状态依赖于上级节点的指示。此外,上级节点还通过显式或隐式的方式为IAB节点的MT配置资源,MT可用资源的可用状态是否修改,也依赖于上级节点的指示。In order to dynamically coordinate resources between the access link and the backhaul link, NR IAB will use two levels of resource indication. Specifically, the two-level resource indication refers to that the upper-level node configures resources for the DU of the IAB node in an explicit or implicit manner, and the resource attributes include at least two types, soft and hard. Among them, the hard resource represents the resource that is always available to the DU of the IAB node, and the available state of the soft resource depends on the instruction of the upper-level node. In addition, the upper-level node also configures resources for the MT of the IAB node in an explicit or implicit manner. Whether the available state of the MT's available resources is modified also depends on the instruction of the upper-level node.
在经过半静态资源配置以后,IAB节点可以分别得到其MT资源和DU资源的资源配置。例如,可以包括MT资源和DU资源的传输方向(U/D/F),MT的可用/不可用资源的位置,DU资源的属性(soft/hard),DU的不可用资源(Null)的时域位置等。一般情况下,MT的资源配置通过RRC等空口信令传输,而DU的资源配置通过F1-AP等接口消息传输。在半静态配置完成后,上级节点可以通过动态信令,例如下行控制信息(downlink control information,DCI),为IAB节点指示其soft资源的可用性。在本申请中,将此DCI称为指示DCI。指示DCI可以基于专用的DCI格式,也可以是对现有DCI的增强或对现有DCI的重用。After the semi-static resource configuration, the IAB node can obtain the resource configuration of its MT resource and DU resource respectively. For example, it may include the transmission direction of MT resources and DU resources (U/D/F), the location of MT's available/unavailable resources, the attributes of DU resources (soft/hard), and the time of DU's unavailable resources (Null). Domain location, etc. Generally, the resource configuration of MT is transmitted through air interface signaling such as RRC, and the resource configuration of DU is transmitted through interface messages such as F1-AP. After the semi-static configuration is completed, the upper-level node can indicate the availability of its soft resources for the IAB node through dynamic signaling, such as downlink control information (DCI). In this application, this DCI is referred to as indicative DCI. The indicated DCI can be based on a dedicated DCI format, or it can be an enhancement to or reuse of existing DCI.
动态指示可分为显式指示与隐式指示两类:Dynamic instructions can be divided into two types: explicit instructions and implicit instructions:
隐式指示:上级节点指示IAB节点MT资源是否被释放(即不可用),IAB节点根据上级节点对MT资源的指示,推导出自身DU soft资源的可用性。Implicit indication: The upper-level node indicates whether the MT resource of the IAB node is released (that is, unavailable), and the IAB node derives the availability of its own soft resource according to the indication of the MT resource from the upper-level node.
显示指示:上级节点直接指示IAB节点DU的soft资源的可用性。Display indication: The superior node directly indicates the availability of the soft resource of the IAB node DU.
其中,指示DCI除了显示或隐式的指示soft资源的可用性以外,还可以同时指示其余内容,例如指示DU flexible资源的传输方向等。Wherein, in addition to indicating the availability of soft resources, indicating DCI can also indicate other content at the same time, such as indicating the transmission direction of DU flexible resources.
针对IAB系统中MT具有多载波且DU具有多小区的情况,本申请实施例提供一种资源的动态指示方法及装置,用于动态指示MT多载波和DU多小区的资源配置方案。其中,方法和装置是基于同一技术构思的,由于方法及装置解决问题的原理相似,因此装置与方法的实施可以相互参见,重复之处不再赘述。In view of the situation that the MT has multiple carriers and the DU has multiple cells in the IAB system, the embodiments of the present application provide a method and device for dynamically indicating resources, which are used to dynamically indicate resource allocation schemes of MT multi-carrier and DU multi-cell. Among them, the method and the device are based on the same technical idea. Since the principles of the method and the device to solve the problem are similar, the implementation of the device and the method can be referred to each other, and the repetition will not be repeated.
本申请实施例提供的资源的动态指示方法可以应用于图1所示的通信系统中,应理解,图1仅是一种示例性说明,并不对通信系统中包括的终端设备、网络设备、中继节点的数量和类型进行具体限定。The method for dynamically indicating resources provided by the embodiments of the present application can be applied to the communication system shown in FIG. 1. It should be understood that FIG. 1 is only an exemplary illustration, and does not describe the terminal equipment, network equipment, and medium included in the communication system. The number and type of subsequent nodes are specifically limited.
应理解,本申请实施例中的“至少一个”是指一个或者多个,“多个”是指两个或两个以上。“和/或”,描述关联对象的关联关系,表示可以存在三种关系,例如,A和/或B,可以表示:单独存在A,同时存在A和B,单独存在B的情况,其中A、B可以是单数或者复数。字符“/”一般表示前后关联对象是一种“或”的关系。“以下至少一(项)个”或其类似表达,是指的这些项中的任意组合,包括单项(个)或复数项(个)的任意组合。例如,a、b或c中的至少一项(个),可以表示:a,b,c,a和b,a和c,b和c,或a、b、c,其中a、b、c可以是单个,也可以是多个。It should be understood that "at least one" in the embodiments of the present application refers to one or more, and "multiple" refers to two or more. "And/or" describes the association relationship of the associated object, indicating that there can be three relationships, for example, A and/or B, which can mean: A alone exists, A and B exist at the same time, and B exists alone, where A, B can be singular or plural. The character "/" generally indicates that the associated objects before and after are in an "or" relationship. "The following at least one (item)" or similar expressions refers to any combination of these items, including any combination of single item (item) or plural items (item). For example, at least one of a, b, or c can mean: a, b, c, a and b, a and c, b and c, or a, b, c, where a, b, c It can be single or multiple.
另外,需要理解的是,在本申请的描述中,“第一”、“第二”、“第三”等词汇,仅用于区分描述的目的,而不能理解为指示或暗示相对重要性,也不能理解为指示或暗示顺序。In addition, it should be understood that in the description of this application, words such as "first", "second", and "third" are only used for the purpose of distinguishing description, and cannot be understood as indicating or implying relative importance. Nor can it be understood as indicating or implying order.
下面结合附图对本申请实施例提供的IAB节点的MT资源和DU资源的动态指示方法进行具体说明。The method for dynamically indicating the MT resource and DU resource of the IAB node provided by the embodiments of the present application will be described in detail below with reference to the accompanying drawings.
为了方便描述,下述实施例中涉及的第一节点为IAB节点,第二节点为IAB节点的上级节点,第三节点为IAB节点的下级节点;第一资源为IAB节点的MT资源,第二资源为IAB节点的DU资源。应理解,本申请中使用IAB节点仅是出于描述的需要,并不代表本申请提供的资源的动态指示方法仅适用于NR场景,在本申请中,IAB节点可以泛指任何具有中继功能的节点或设备,IAB节点和中继节点或中继设备在本申请中的使用应理解为具有相同的含义。For the convenience of description, the first node involved in the following embodiments is the IAB node, the second node is the upper node of the IAB node, and the third node is the lower node of the IAB node; the first resource is the MT resource of the IAB node, and the second node is the MT resource of the IAB node. The resource is the DU resource of the IAB node. It should be understood that the use of IAB nodes in this application is only for the purpose of description, and does not mean that the dynamic indication method of resources provided by this application is only applicable to NR scenarios. In this application, IAB nodes can generally refer to any relay function. The use of nodes or devices, IAB nodes and relay nodes or relay devices in this application should be understood to have the same meaning.
参见图10,图10为本申请实施例提供的一种资源的动态指示方法的流程图,该方法包括:Referring to FIG. 10, FIG. 10 is a flowchart of a method for dynamically indicating resources according to an embodiment of the application, and the method includes:
S1001、第二节点或宿主节点向第一节点发送第一指示信息,该第一指示信息用于指示第一节点中D个载波对应的第一资源和F个小区对应的第二资源的半静态资源配置。S1001. The second node or the donor node sends first indication information to the first node, where the first indication information is used to indicate the semi-static status of the first resource corresponding to the D carriers and the second resource corresponding to the F cells in the first node Resource allocation.
具体的,第一节点可以为IAB节点,第二节点为IAB节点的上级节点。除第一节点和第二节点外,本申请实施例可能还包括第三节点,该第三节点为IAB节点的下级节点。其中,第一节点可以是中继设备,包括普通的固定中继节点,例如IAB节点,也包括移动的中继节点,例如移动IAB节点,UE中继等。第二节点可以是普通网络设备,如基站等,也可以是中继设备。第三节点可以是中继设备,还可以是终端设备。Specifically, the first node may be an IAB node, and the second node is an upper-level node of the IAB node. In addition to the first node and the second node, the embodiment of the present application may further include a third node, and the third node is a lower-level node of the IAB node. The first node may be a relay device, including a common fixed relay node, such as an IAB node, and also a mobile relay node, such as a mobile IAB node, UE relay, and so on. The second node may be a common network device, such as a base station, etc., or a relay device. The third node can be a relay device or a terminal device.
进一步地,第一资源为第一节点与第二节点进行通信的传输资源,即IAB节点的MT资源;第二资源为第一节点与第三节点进行通信的传输资源,即IAB节点的DU资源。Further, the first resource is the transmission resource for the communication between the first node and the second node, that is, the MT resource of the IAB node; the second resource is the transmission resource for the communication between the first node and the third node, that is, the DU resource of the IAB node .
一般的,IAB节点的MT可具有多个子单元,多个子单元可以是多个载波,多个面板,多个小区等;IAB节点的DU也可以具有多个子单元,多个子单元也可以是多个载波,多个面板,多个小区等。在本申请实施例中,以IAB节点的MT具有(或者被配置)多个载波(CC),DU具有(或者被配置)多个小区(cell)为例,对本申请提出的一种资源的动态指示方法进 行说明。其中,假定IAB节点的MT具有D个载波,其中,D≥1;IAB节点的DU具有F个小区,其中,F≥1。应理解,本申请实施例中仅是以载波或小区为例进行说明,并不限定于以载波或小区为单位,在具体实施方式中,也可以以其他子模块或者子单元为单位,例如,扇区、天线面板等。示例性的,以扇区为单位时,IAB节点的DU可以具有K个扇区,其中,K≥2。Generally, the MT of an IAB node can have multiple subunits, which can be multiple carriers, multiple panels, multiple cells, etc.; the DU of an IAB node can also have multiple subunits, and multiple subunits can also be multiple Carrier, multiple panels, multiple cells, etc. In the embodiment of this application, the MT of the IAB node has (or is configured) multiple carriers (CC), and the DU has (or is configured) multiple cells (cells) as an example. The instruction method is explained. Among them, it is assumed that the MT of the IAB node has D carriers, where D≥1; the DU of the IAB node has F cells, where F≥1. It should be understood that the embodiments of the present application only take the carrier or the cell as an example for description, and are not limited to taking the carrier or the cell as the unit. In specific implementations, other sub-modules or sub-units may also be used as the unit, for example, Sectors, antenna panels, etc. Exemplarily, when a sector is used as a unit, the DU of the IAB node may have K sectors, where K≥2.
应理解,当UE或MT采用载波聚合时,LTE和NR等通信协议一般采用服务小区(serving cell)来标识或者描述分量载波,而不同的服务小区具有不同的服务小区ID。在本申请中,为了与DU小区区别,直接采用分量载波描述MT的服务小区,即本申请中MT的载波对应于协议中MT的服务小区。It should be understood that when UE or MT adopts carrier aggregation, communication protocols such as LTE and NR generally use serving cells to identify or describe component carriers, and different serving cells have different serving cell IDs. In this application, in order to be distinguished from the DU cell, the component carrier is directly used to describe the serving cell of the MT, that is, the carrier of the MT in this application corresponds to the serving cell of the MT in the protocol.
图11给出了一种IAB节点的MT具有两个载波CC1、CC2,DU具有四个小区cell1、cell2、cell3、cell4的情况示例,即D=2,F=4。其中,示例中的IAB节点具有两个(两组)不同朝向的天线面板panel 1、panel 2。Figure 11 shows an example of a situation where the MT of an IAB node has two carriers CC1 and CC2, and the DU has four cells cell1, cell2, cell3, and cell4, that is, D=2, F=4. Among them, the IAB node in the example has two (two groups) antenna panels panel 1 and panel 2 with different orientations.
如图11所示,IAB节点的DU在每个(组)天线面板(panel)上可以通过两个采用不同载波(记为CC3和CC4)的小区与下级节点通信,即IAB节点的DU在每个天线面板上运行两个小区,例如,在天线面板panel 1上运行小区cell1、cell2,在天线面板panel 2上运行小区cell3、cell4。因此,图11中的DU具有四个小区cell1、cell2、cell3、cell4。另一方面,IAB节点的MT使用一个(组)天线面板panel 1通过两个载波(载波聚合)CC1、CC2与上级节点通信。MT的两个载波CC1、CC2与DU的两个载波CC3、CC4相同,或者说MT的两个载波CC1、CC2与DU的两个载波CC3、CC4分别重合。具体地,MT使用的载波CC1与DU在panel 1上运行的小区cell 1和在panel 2上运行的小区cell 3频段重合,而MT使用的载波CC 2与DU在panel 1运行的小区cell 2和panel 2上运行的小区cell 4频段重合。应理解,频段重合可能是指整个频段完全重合,也可能指部分频段重合。As shown in Figure 11, the DU of the IAB node can communicate with the lower-level nodes through two cells using different carriers (denoted as CC3 and CC4) on each (group) antenna panel. That is, the DU of the IAB node is in each antenna panel. Two cells are run on one antenna panel, for example, cells cell1 and cell2 are run on antenna panel 1, and cells cell3 and cell4 are run on antenna panel 2. Therefore, the DU in FIG. 11 has four cells cell1, cell2, cell3, and cell4. On the other hand, the MT of the IAB node uses one (group) antenna panel 1 to communicate with the upper node through two carriers (carrier aggregation) CC1 and CC2. The two carriers CC1 and CC2 of the MT are the same as the two carriers CC3 and CC4 of the DU, or the two carriers CC1 and CC2 of the MT coincide with the two carriers CC3 and CC4 of the DU respectively. Specifically, the carrier CC1 used by the MT coincides with the frequency bands of the cell cell 1 running on panel 1 and the cell 3 running on panel 2, while the carrier CC2 used by MT overlaps with the cell 2 and cell 2 running on panel 1 of the MT. The cell 4 frequency bands of the cell operating on panel 2 overlap. It should be understood that the overlap of frequency bands may refer to the complete overlap of the entire frequency bands, or may refer to the overlap of some frequency bands.
进一步地,MT的多个(例如,D个)载波和DU的多个小区(例如,F个)在传输中可能具有不同的资源复用或关联关系。仍以图11中MT具有两个载波CC1、CC2,DU具有四个小区cell1、cell2、cell3、cell4为例,MT的各个载波与DU的各个小区可能具有的资源复用或关联关系如图12所示,包括但不限于:Further, multiple (e.g., D) carriers of the MT and multiple (e.g., F) cells of the DU may have different resource reuse or association relationships during transmission. Still taking the MT in Figure 11 with two carriers CC1 and CC2 and the DU with four cells cell1, cell2, cell3, and cell4 as an example, the possible resource reuse or association relationship between each carrier of the MT and each cell of the DU is shown in Figure 12. Shown, including but not limited to:
时分复用(TDM):MT的载波和DU的小区不能进行同时传输。例如,MT的载波CC1与DU的小区cell1使用重合的载波频率并位于同一个天线面板,因此两者的资源复用或关联关系为TDM,即当载波CC1在传输时,小区cell1不能进行任何形式的传输,反之亦然。类似地,载波CC2与小区cell2之间的复用关系也为TDM。Time division multiplexing (TDM): The carrier of the MT and the cell of the DU cannot be transmitted at the same time. For example, the carrier CC1 of the MT and the cell cell1 of the DU use the same carrier frequency and are located in the same antenna panel. Therefore, the resource reuse or association relationship between the two is TDM, that is, when the carrier CC1 is transmitting, the cell cell1 cannot perform any form. Transmission and vice versa. Similarly, the multiplexing relationship between the carrier CC2 and the cell cell2 is also TDM.
(半双工)频分复用(FDM):MT的载波和DU的小区可以进行同时接收或同时发送,但不能一收一发。例如,载波CC1与小区cell2虽然使用相同的天线面板但具有不同的载波频段,因此两者可以进行同时接收或者同时发送,即进行(半双工)FDM。(Half-duplex) Frequency Division Multiplexing (FDM): The carrier of the MT and the cell of the DU can be received or sent at the same time, but they cannot be received and sent at the same time. For example, although the carrier CC1 and the cell cell2 use the same antenna panel but have different carrier frequency bands, they can receive or transmit simultaneously, that is, perform (half-duplex) FDM.
(半双工)空分复用(space division multiplexing,SDM):MT的载波和DU的小区可以进行同时接收或同时发送,但不能一收一发。例如,载波CC1与小区cell3虽然具有相同的载波频段但使用不同的天线面板,因此两者可以进行同时接收或者同时发送,即进行(半双工)SDM。(Half-duplex) Space division multiplexing (SDM): The carrier of the MT and the cell of the DU can be received or sent at the same time, but they cannot be received and sent at the same time. For example, although the carrier CC1 and the cell cell3 have the same carrier frequency band but use different antenna panels, they can receive or transmit simultaneously, that is, perform (half-duplex) SDM.
全双工(full duplex,FD):MT的载波和DU的小区收发互不影响。例如,载波CC1与小区cell4采用不同频段的载波且使用不同的天线面板,因此两者具有足够的隔离度,可以同时收发而相互不影响。MT的载波和DU的小区具有全双工资源复用或关联关系也可以定 义为MT的载波和DU的小区不具有资源复用或关联关系。全双工可以为同频全双工,也可以为异频全双工。而异频全双工也可能被称为全双工FDM。Full duplex (FD): The carrier of the MT and the cell of the DU do not affect each other. For example, the carrier CC1 and the cell cell4 use different frequency band carriers and use different antenna panels, so the two have sufficient isolation and can transmit and receive at the same time without affecting each other. The carrier of the MT and the cell of the DU have a full-duplex resource reuse or association relationship, or it can be defined that the carrier of the MT and the cell of the DU do not have a resource reuse or association relationship. Full duplex can be same frequency full duplex or different frequency full duplex. The inter-frequency full-duplex may also be called full-duplex FDM.
此外,MT的各个载波和DU的各个小区之间可能还存在以下的资源复用或关联关系:In addition, the following resource reuse or association relationships may also exist between each carrier of the MT and each cell of the DU:
动态(自适应)SDM/FDM:DU的小区根据MT的传输情况,确定进行半双工同时发送/同时接收的配置或方案。例如,当MT在进行下行传输时,IAB节点的DU仅能选取部分终端设备进行上行发送;而当MT不进行传输时,IAB节点的DU可选取更多的终端设备进行上行发送。以MT和DU同时接收为例,不同的终端设备对MT的接收可能造成不同的干扰水平,当MT进行传输时,DU应选择对MT的传输无影响或影响可控的终端设备进行上行传输。Dynamic (adaptive) SDM/FDM: The DU cell determines the configuration or scheme for simultaneous half-duplex transmission/reception according to the transmission situation of the MT. For example, when the MT is performing downlink transmission, the DU of the IAB node can only select some terminal devices for uplink transmission; and when the MT is not performing transmission, the DU of the IAB node can select more terminal devices for uplink transmission. Taking simultaneous reception of MT and DU as an example, different terminal equipment may cause different levels of interference to MT reception. When MT is transmitting, DU should select terminal equipment that has no influence on MT transmission or influences controllable terminal equipment for uplink transmission.
动态(自适应)全双工:DU的小区根据MT的传输情况,确定进行全双工发送或接收的配置或方案。例如,当MT在进行下行传输时,IAB节点的DU仅能选取部分终端设备进行下行传输;而当MT不进行传输时,DU可选取更多的终端设备进行下行传输。Dynamic (adaptive) full-duplex: The DU cell determines the configuration or scheme for full-duplex transmission or reception according to the transmission situation of the MT. For example, when the MT is performing downlink transmission, the DU of the IAB node can only select some terminal devices for downlink transmission; and when the MT is not performing transmission, the DU can select more terminal devices for downlink transmission.
在一种可能的实现方式中,MT的各个载波和DU的各个小区之间可以具有默认的资源复用或关联关系。例如,MT的各个载波和DU的各个小区之间默认的资源复用或关联关系为时分复用TDM。在另一种可能的实现方式中,IAB节点可通过向上级节点/宿主节点上报信息,修改全部或部分MT载波和DU小区默认的资源复用或关联关系。例如,IAB节点上报部分MT载波和DU小区之间的资源复用或关联关系为全双工,其他MT载波和DU小区之间的资源复用或关联关系仍为默认的时分复用TDM。In a possible implementation manner, each carrier of the MT and each cell of the DU may have a default resource reuse or association relationship. For example, the default resource reuse or association relationship between each carrier of the MT and each cell of the DU is time division multiplexing TDM. In another possible implementation manner, the IAB node can modify all or part of the default resource reuse or association relationship between the MT carrier and the DU cell by reporting information to the superior node/host node. For example, the IAB node reports that the resource reuse or association relationship between some MT carriers and DU cells is full duplex, and the resource reuse or association relationship between other MT carriers and DU cells is still the default time division multiplexing TDM.
目前,NR的资源配置方式为半静态资源配置加动态资源指示,在进行动态资源指示前,第二节点向第一节点发送第一指示信息,用于指示第一节点的MT资源和DU资源的半静态资源配置。Currently, the resource configuration mode of NR is semi-static resource configuration plus dynamic resource indication. Before performing dynamic resource indication, the second node sends first indication information to the first node, which is used to indicate the MT resource and DU resource of the first node. Semi-static resource configuration.
S1002、第一节点根据第一指示信息确定D个载波对应的第一资源和F个小区对应的第二资源的半静态资源配置。S1002. The first node determines, according to the first indication information, the semi-static resource configuration of the first resource corresponding to the D carriers and the second resource corresponding to the F cells.
具体的,第一节点接收第一指示信息,并根据第一指示信息确定MT资源和DU资源的半静态资源配置,包括:Specifically, the first node receives the first indication information, and determines the semi-static resource configuration of the MT resource and the DU resource according to the first indication information, including:
MT资源配置:MT资源的半静态配置与终端设备类似,宿主节点和/或IAB节点的上级节点可采用广播信令和单播RRC信令逐载波配置MT资源的D/U/F三种资源类型。应理解,IAB节点的上级节点还可通过下行控制信息(DCI)修改IAB节点的MT的资源类型。MT resource configuration: The semi-static configuration of MT resources is similar to that of terminal equipment. The host node and/or the superior node of the IAB node can use broadcast signaling and unicast RRC signaling to configure the three D/U/F resources of MT resources on a carrier-by-carrier basis. Types of. It should be understood that the upper-level node of the IAB node may also modify the resource type of the MT of the IAB node through downlink control information (DCI).
DU资源配置:DU首先可以被宿主节点或IAB节点的上级节点配置D/U/F资源类型。然后,宿主节点或IAB节点的上级节点可进一步的指示DU资源的hard/soft属性(attribute),以及不可用资源(NA)的时域位置。宿主节点或IAB节点的上级节点一般通过接口消息对DU进行资源配置。DU resource configuration: DU can first be configured with D/U/F resource types by the host node or the superior node of the IAB node. Then, the host node or the superior node of the IAB node can further indicate the hard/soft attributes (attribute) of the DU resource and the time domain location of the unavailable resource (NA). The host node or the superior node of the IAB node generally configures the resources of the DU through interface messages.
在一种可能的实现方式中,宿主节点或IAB节点的上级节点通过F1-AP等接口信令同时指示DU资源的hard/soft属性和不可用资源(NA)的时域位置,即将DU的不可用资源视为DU资源的一种属性。在另一种可能的实现方式中,宿主节点或IAB节点的上级节点通过独立的信令分别指示资源的hard/soft属性和不可用资源(NA)的时域位置。In a possible implementation, the host node or the superior node of the IAB node simultaneously indicates the hard/soft attributes of the DU resource and the time domain position of the unavailable resource (NA) through interface signaling such as F1-AP, that is, the unavailability of the DU. The use of resources is regarded as an attribute of DU resources. In another possible implementation manner, the host node or the superior node of the IAB node respectively indicate the hard/soft attributes of the resources and the time domain location of the unavailable resources (NA) through independent signaling.
通过半静态资源配置,IAB节点获取了MT资源的D/U/F三种资源类型,以及DU资源的hard/soft属性和不可用资源(NA)的时域位置。为了使IAB节点的上级节点与IAB节点的MT之间的传输不影响IAB节点的DU对其hard资源的使用,IAB节点和IAB节点的上级节点需要通过MT的各个载波与DU的各个小区之间的资源复用或关联关系推导MT的可 用/不可用资源。Through the semi-static resource configuration, the IAB node obtains the D/U/F three resource types of the MT resource, as well as the hard/soft attributes of the DU resource and the time domain location of the unavailable resource (NA). In order to ensure that the transmission between the upper node of the IAB node and the MT of the IAB node does not affect the use of the hard resources of the IAB node's DU, the IAB node and the upper node of the IAB node need to pass between each carrier of the MT and each cell of the DU. Derives the available/unavailable resources of the MT based on the resource reuse or association relationship.
具体的,IAB节点的MT各个载波的可用/不可用资源的推导方法如下:Specifically, the method for deriving the available/unavailable resources of each carrier of the MT of the IAB node is as follows:
当MT的一个载波与DU的一个小区关联时,若该MT载波与DU小区的资源复用关系为时分复用TDM,则与DU hard资源时域重合的MT资源均为不可用资源;若该MT载波与DU小区的复用关系为半双工频分复用(frequency division multiplexing,FDM)或半双工空分复用(space division multiplexing,SDM),则与DU hard资源时域重合且传输方向相同的MT资源为不可用资源。示例性的,如图9所示,MT包含一个载波CC1,DU包含一个小区cell0,MT载波与DU小区的资源复用关系为时分复用TDM,则与DU hard资源时域重合的MT资源均为不可用资源。When a carrier of the MT is associated with a cell of the DU, if the resource reuse relationship between the MT carrier and the DU cell is time division multiplexing TDM, the MT resources that overlap with the DU hard resource in the time domain are all unavailable resources; The multiplexing relationship between the MT carrier and the DU cell is half-duplex frequency division multiplexing (FDM) or half-duplex space division multiplexing (SDM), which coincides with the DU hard resource time domain and the transmission direction The same MT resource is an unavailable resource. Exemplarily, as shown in Figure 9, the MT contains a carrier CC1, the DU contains a cell cell0, and the resource reuse relationship between the MT carrier and the DU cell is time division multiplexing TDM, then the MT resources that overlap with the DU hard resources in the time domain are all Is an unavailable resource.
需要说明的是,MT的可用资源是不影响DU hard资源传输的资源,由于MT与DU的定时偏差以及MT与DU资源的切换间隔,部分不与DU hard资源重合的MT资源也可能影响DU hard资源的传输,因此也应视作MT的不可用资源。It should be noted that the available resources of MT are resources that do not affect the transmission of DU hard resources. Due to the timing deviation between MT and DU and the switching interval between MT and DU resources, some MT resources that do not overlap with DU hard resources may also affect DU hard resources. The transmission of resources should therefore also be regarded as unavailable resources of the MT.
当MT的一个载波与DU的多个小区关联时,该MT载波的可用/不可用资源的推导需要依赖于与之关联的多个DU小区的资源配置,例如,通过DU的多个小区的资源类型和资源属性,联合推导MT载波的可用/不可用资源。推导的原则是,该IAB节点的MT载波与IAB节点的上级节点的传输不影响任意一个IAB节点的DU小区中hard资源的使用。具体地,MT载波的可用资源是每个与之关联的DU小区推导得到的MT载波的可用资源的交集。或者说,MT载波的不可用资源是每个与之关联的DU小区推导得到的MT载波不可用资源的并集。When a carrier of an MT is associated with multiple cells of a DU, the derivation of the available/unavailable resources of the MT carrier needs to depend on the resource configuration of the multiple DU cells associated with it, for example, through the resources of multiple cells of the DU Type and resource attributes, jointly derive the available/unavailable resources of the MT carrier. The principle of derivation is that the transmission between the MT carrier of the IAB node and the superior node of the IAB node does not affect the use of hard resources in the DU cell of any IAB node. Specifically, the available resources of the MT carrier are the intersection of the available resources of the MT carrier derived from each associated DU cell. In other words, the unavailable resources of the MT carrier are the union of the unavailable resources of the MT carrier derived from each associated DU cell.
需要说明的是,在MT具有多个载波和DU具有多个小区的应用场景下,半静态资源配置中,MT各个载波的可用/不可用资源均可根据上述方法逐载波推导。示例性的,如图13所示,MT包含两个载波CC1、CC2,DU包含四个小区cell1、cell2、cell3、cell4。其中,MT的载波CC1和DU的小区cell1和cell2关联,根据DU小区cell1的资源配置,可推导得到MT载波CC1的可用资源为时隙1,2,3;根据DU小区cell2的资源配置,可推导得到MT载波CC1的可用资源为时隙0,1,2。将两个可用资源集合取交集可知,该MT载波CC1的可用资源为时隙1,2。或者说,该MT载波的不可用资源为时隙0,3和4。It should be noted that in the application scenario where the MT has multiple carriers and the DU has multiple cells, in the semi-static resource configuration, the available/unavailable resources of each carrier of the MT can be derived carrier by carrier according to the above method. Exemplarily, as shown in FIG. 13, the MT includes two carriers CC1 and CC2, and the DU includes four cells cell1, cell2, cell3, and cell4. Among them, the MT carrier CC1 is associated with the DU cells cell1 and cell2. According to the resource configuration of the DU cell cell1, the available resources of the MT carrier CC1 can be derived as time slots 1, 2, and 3. According to the resource configuration of the DU cell cell2, It is deduced that the available resources of the MT carrier CC1 are time slots 0, 1, and 2. Taking the intersection of the two available resource sets, it can be seen that the available resources of the MT carrier CC1 are time slots 1 and 2. In other words, the unavailable resources of the MT carrier are time slots 0, 3, and 4.
应理解,上述推导过程可能有协议明确定义的流程,也可以留作IAB节点和其上级节点的实现。It should be understood that the above-mentioned derivation process may have a process clearly defined by the protocol, or it may be reserved for the realization of the IAB node and its superior node.
需要说明的是,根据半静态资源配置得到的MT的可用资源是指可能被用作回传链路传输的资源,实际过程中,可用资源是否被用作回传链路传输需要依赖于上级节点的指示。It should be noted that the available resources of the MT obtained according to the semi-static resource configuration refer to the resources that may be used for the backhaul link transmission. In the actual process, whether the available resources are used for the backhaul link transmission depends on the upper-level node. Instructions.
S1003、第二节点向第一节点发送第二指示信息,该第二指示信息用于指示第一节点中D个载波对应的第一资源的可用资源的可用状态和/或F个小区对应的第二资源的动态资源的可用状态。S1003. The second node sends second indication information to the first node, where the second indication information is used to indicate the available status of the available resources of the first resource corresponding to the D carriers in the first node and/or the first resource corresponding to the F cells. 2. The available status of the dynamic resource of the resource.
NR IAB的资源配置方式为半静态资源配置加动态资源指示,在根据半静态资源配置获取到IAB节点的MT资源和DU资源的半静态配置后,IAB节点的上级节点可通过动态信令显式或隐式的指示IAB节点的DU soft资源的可用性,或者显式或隐式的指示IAB节点的MT的可用资源是否会释放。在本申请中,IAB节点的上级节点释放MT的可用资源是指上级节点指示该可用资源不会被回传链路使用。需要说明的是,根据半静态资源配置得到的MT的可用资源是可能被用作回传链路的资源,实际可用资源是否会被用作回传链路传输,即MT的可用资源的可用状态是否会被修改(或重写、或重新指示、或覆盖),需要依赖于上级节点的指示。NR IAB's resource configuration method is semi-static resource configuration plus dynamic resource indication. After obtaining the semi-static configuration of the MT resource and DU resource of the IAB node according to the semi-static resource configuration, the upper-level node of the IAB node can display it through dynamic signaling. Or implicitly indicate the availability of the DU soft resources of the IAB node, or explicitly or implicitly indicate whether the available resources of the MT of the IAB node will be released. In this application, the release of the available resources of the MT by the superior node of the IAB node means that the superior node indicates that the available resources will not be used by the backhaul link. It should be noted that the available resources of the MT obtained according to the semi-static resource configuration may be used as the resources of the backhaul link, whether the actual available resources will be used for the backhaul link transmission, that is, the available state of the MT's available resources Whether it will be modified (or rewritten, or re-instructed, or overwritten) depends on the instructions of the superior node.
具体的,第一资源的可用资源的可用状态可以指IAB节点的上级节点显式或隐式的指示IAB节点的MT的可用资源是否会被释放,即由半静态资源配置得到的MT的可用资源的可用状态是否可能会被上级节点修改(或重写、或重新指示、或覆盖)。IAB节点的上级节点对D个载波对应的第一资源的可用资源进行可用性修改,一般来说,仅可以将原有的可用资源修改为不可用,而不能将原有的不可用资源修改为可用。MT的可用资源的可用状态是否会被上级节点修改需要依赖于上级节点的第二指示信息指示。第二资源的动态资源的可用状态可以指IAB节点的DU的soft资源的可用性,即IAB节点的上级节点显式或隐式的指示IAB节点的DU soft资源的可用性。当上级节点将DU soft资源指示为不可用时,IAB节点不采用对应资源与下级IAB节点或UE进行通信。Specifically, the availability status of the available resources of the first resource may refer to the superior node of the IAB node explicitly or implicitly indicating whether the available resources of the MT of the IAB node will be released, that is, the available resources of the MT obtained by the semi-static resource configuration Whether the available status of may be modified (or rewritten, or re-indicated, or overwritten) by the superior node. The superior node of the IAB node modifies the availability of the available resources of the first resource corresponding to the D carriers. Generally speaking, only the original available resources can be modified to be unavailable, and the original unavailable resources cannot be modified to be available. . Whether the available state of the available resources of the MT will be modified by the upper-level node depends on the second indication information of the upper-level node. The availability status of the dynamic resource of the second resource may refer to the availability of the soft resource of the DU of the IAB node, that is, the superior node of the IAB node explicitly or implicitly indicates the availability of the soft resource of the IAB node. When the upper-level node indicates that the DU soft resource is unavailable, the IAB node does not use the corresponding resource to communicate with the lower-level IAB node or UE.
进一步地,以IAB节点的上级节点指示IAB节点的DU soft资源为例说明上述动态资源指示方法,如图14所示,若第二指示信息指示IAB节点DU的F个小区中某个小区的第二资源的动态资源为可用(图中实线),则第一节点可使用该对应的资源与第三节点进行通信。若第二指示信息指示DU的F个小区中某个小区的第二资源的动态资源为不可用(图中虚线),则第一节点不能使用对应的资源与第三节点进行通信。Further, take the upper-level node of the IAB node indicating the DU soft resource of the IAB node as an example to illustrate the above dynamic resource indication method. As shown in FIG. 14, if the second indication information indicates the first cell of a certain cell among the F cells of the IAB node DU If the dynamic resource of the second resource is available (solid line in the figure), the first node can use the corresponding resource to communicate with the third node. If the second indication information indicates that the dynamic resource of the second resource of a certain cell among the F cells of the DU is unavailable (the dotted line in the figure), the first node cannot use the corresponding resource to communicate with the third node.
在本申请实施例中,第二指示信息可以通过动态信令,如下行控制信息(downlink control information,DCI)发送。In the embodiment of the present application, the second indication information may be sent through dynamic signaling, such as downlink control information (DCI).
为了方便描述,下面将第二节点发送的用于动态资源指示的第二指示信息称为指示DCI。该指示DCI可以采用专用的DCI格式,也可以在现有的DCI格式中增加或修改字段得到。For the convenience of description, the second indication information used for dynamic resource indication sent by the second node is referred to as indication DCI below. The indication DCI can adopt a dedicated DCI format, or can be obtained by adding or modifying fields in the existing DCI format.
IAB节点的donor节点或上级节点可通过无线资源控制RRC信令为IAB节点配置指示DCI的相关信息,该指示DCI的相关信息可以包括以下至少一种:The donor node or superior node of the IAB node can configure the IAB node with related information indicating DCI through radio resource control RRC signaling, and the related information indicating DCI may include at least one of the following:
(1)控制资源集(control resource set,CORESET)信息:与现有的控制资源集CORESET配置相同或类似;(1) Control resource set (CORESET) information: the same or similar to the existing control resource set CORESET configuration;
(2)搜索空间集合信息:包含指示DCI的搜索空间的配置信息,与通常的搜索空间集合配置相同或类似,包括搜索空间关联的CORESET,搜索空间的时域信息(周期,偏移,持续时间,搜索空间在时隙内的起始符号等),物理下行控制信道(physical downlink control channel,PDCCH)候选集(candidate)信息,DCI格式信息,聚合级别等。(2) Search space collection information: contains configuration information indicating the DCI search space, which is the same or similar to the usual search space collection configuration, including the CORESET associated with the search space, and the time domain information of the search space (period, offset, duration) , The start symbol of the search space in the time slot, etc.), physical downlink control channel (physical downlink control channel, PDCCH) candidate set (candidate) information, DCI format information, aggregation level, etc.
(3)指示时延信息:指示时延是IAB节点的MT接收物理下行控制信道PDCCH的时间与对应DCI指示起始位置的时间差。此时延也可能由DCI指示。(3) Indication delay information: The indication delay is the time difference between the time when the MT of the IAB node receives the physical downlink control channel PDCCH and the start position of the corresponding DCI indication. The delay may also be indicated by DCI.
(4)指示范围信息:指示DCI应用的时域范围。(4) Indication range information: Indicate the time domain range of DCI application.
示例性的,如图15所示,是一种包含指示时延信息的一种指示DCI的示例。该指示时延可以是指示DCI(对应的物理下行控制信道PDCCH或CORESET)的起始符号至指示范围起始位置的时间,也可以是指示DCI(对应的PDCCH或CORESET)的结束符号至指示范围的起始位置的时间。Exemplarily, as shown in FIG. 15, it is an example of an indication DCI containing indication delay information. The indication delay can be the time from the start symbol of the DCI (corresponding physical downlink control channel PDCCH or CORESET) to the start position of the indication range, or the end symbol of the DCI (corresponding PDCCH or CORESET) to the indication range The time of the starting position.
S1004、第一节点根据第二指示信息确定D个载波对应的第一资源的可用资源的可用状态和/或F个小区对应的第二资源的动态资源的可用状态。S1004. The first node determines, according to the second indication information, the available state of the available resources of the first resource corresponding to the D carriers and/or the available state of the dynamic resources of the second resource corresponding to the F cells.
具体的,第一节点接收第二指示信息,并根据第二指示信息确定MT资源和DU资源的动态资源配置,包括:Specifically, the first node receives the second indication information, and determines the dynamic resource configuration of the MT resource and the DU resource according to the second indication information, including:
(1)确定IAB节点的MT的D个载波中各个载波的可用资源的可用状态是否被IAB节点的上级节点修改;(1) Determine whether the available state of the available resources of each of the D carriers of the MT of the IAB node is modified by the superior node of the IAB node;
(2)确定IAB节点的DU的F个小区中各个小区的soft资源的可用状态,即DU的soft 资源是否会被回传链路或接入链路使用。(2) Determine the available status of the soft resource of each cell in the F cells of the DU of the IAB node, that is, whether the soft resource of the DU will be used by the backhaul link or the access link.
上述实施例提供了在MT多载波和DU多小区的情况下,IAB节点的上级节点对IAB节点的MT的可用资源的可用状态和DU的soft资源的可用状态进行显式指示的细节设计。下面详述当IAB节点的上级节点仅对IAB节点的MT的可用资源的可用状态进行显示指示,而IAB节点可根据该指示隐式确定其DU soft资源的可用状态的方案细节。以及IAB节点的上级节点仅对DU的soft资源的可用状态进行显式指示,而IAB节点可根据该指示隐式确定其MT可用资源的可用状态的方案细节设计。The foregoing embodiment provides a detailed design in which the upper-level node of the IAB node explicitly indicates the available state of the MT's available resources of the IAB node and the available state of the DU's soft resources in the case of MT multi-carrier and DU multi-cell. The following describes the details of the solution when the upper-level node of the IAB node only displays the available status of the available resources of the MT of the IAB node, and the IAB node can implicitly determine the available status of its soft resources according to the indication. And the superior node of the IAB node only explicitly indicates the available state of the soft resources of the DU, and the IAB node can implicitly determine the detailed design of the available state of its MT available resources according to the indication.
在一种可能的实现方式中,在MT多载波和DU多小区的情况下,IAB节点的上级节点可以仅对IAB节点的MT的可用资源的可用状态进行显式指示,而IAB节点可根据该指示隐式确定其DU soft资源的可用状态。即IAB节点的上级节点指示IAB节点的MT在经过半静态配置后确定的可用资源的可用性是否被修改,IAB节点根据其上级节点对MT的可用资源的可用状态的指示(以下简称MT指示),推导出自身DU的soft资源的可用性。即对于一个DU小区,应根据与其关联的多个MT载波的动态资源指示结果确定其soft资源的可用状态,即确定IAB节点是否采用DU通过半静态资源配置得到的soft资源与下级IAB节点或UE进行通信。在确定DU的soft资源的可用状态时,需要考虑MT的各个载波与DU的各个小区之间的资源复用或关联关系。In a possible implementation manner, in the case of MT multi-carrier and DU multi-cell, the superior node of the IAB node may only explicitly indicate the available status of the MT available resources of the IAB node, and the IAB node may Indicates to implicitly determine the available status of its DU soft resources. That is, the superior node of the IAB node indicates whether the availability of the available resources determined by the MT of the IAB node after semi-static configuration is modified, and the IAB node according to its superior node's indication of the available state of the MT's available resources (hereinafter referred to as the MT indication), Derive the availability of the soft resources of its own DU. That is, for a DU cell, the available status of its soft resources should be determined according to the dynamic resource indication results of multiple MT carriers associated with it, that is, whether the IAB node uses the soft resources obtained by the DU through semi-static resource configuration and the subordinate IAB node or UE To communicate. When determining the available status of the soft resources of the DU, the resource reuse or association relationship between each carrier of the MT and each cell of the DU needs to be considered.
需要说明的是,MT指示可逐载波进行。具体地,IAB节点的上级节点可通过不同的DCI字段指示MT不同载波的各时域资源的可用性(可用资源的可用状态是否被修改为不可用),或者IAB节点的上级节点可分别指示MT不同载波的各时域资源的可用性(可用资源的可用状态是否被修改为不可用)。在接收到MT指示后,IAB节点的MT可确定上级节点与之通信的时域和频域资源(载波级)。It should be noted that the MT indication can be performed on a carrier-by-carrier basis. Specifically, the upper-level node of the IAB node can indicate the availability of the time domain resources of the different carriers of the MT through different DCI fields (whether the availability status of the available resource is modified to unavailable), or the upper-level node of the IAB node can indicate that the MT is different. The availability of the time domain resources of the carrier (whether the availability status of the available resources is modified to unavailable). After receiving the MT indication, the MT of the IAB node can determine the time domain and frequency domain resources (carrier level) with which the upper-level node communicates.
参见图16,以MT具有两个载波CC1、CC2为例,考虑指示范围内的10个MT资源(假设为时隙0至时隙9)。根据半静态资源配置,可得到MT在载波CC1的可用资源为时隙{0,1,2,7,8,9},而载波CC2的可用资源为时隙{0,1,2,3,8,9}。因此,上级节点可逐个载波指示MT的可用时隙的可用状态是否被修改。Referring to FIG. 16, taking the MT having two carriers CC1 and CC2 as an example, consider 10 MT resources within the indication range (assuming time slot 0 to time slot 9). According to the semi-static resource configuration, it can be obtained that the available resources of the MT on the carrier CC1 are time slots {0, 1, 2, 7, 8, 9}, and the available resources of the carrier CC2 are time slots {0, 1, 2, 3, 8, 9}. Therefore, the upper-level node can indicate whether the available state of the available time slot of the MT has been modified carrier by carrier.
在一种可能的实现方式中,承载指示DCI的物理下行信道PDCCH位于MT的一个载波,在一种可能的实现方式中,MT也可以通过不同的载波接收指示DCI。In a possible implementation manner, the physical downlink channel PDCCH carrying the indication DCI is located on a carrier of the MT. In a possible implementation manner, the MT may also receive the indication DCI through different carriers.
对于MT的通过半静态资源配置推导得到的不可用资源,上级节点不进行指示,或上级节点将其指示为释放,或IAB节点忽略上级节点的指示。For the unavailable resources derived from the semi-static resource configuration of the MT, the upper-level node does not give an instruction, or the upper-level node indicates it as release, or the IAB node ignores the instruction of the upper-level node.
在一种可能的实现方式中,上级节点也可以分载波组为指示MT的可用资源的可用状态。具体地,上级节点同时指示MT的载波组(多个载波)的可用资源的可用性。当上级节点指示MT的某个时域资源为可用/不可用时,载波组内多个载波对应的时域资源均被指示为可用/不可用。仍以图16为例,对于时隙{0,1,2,8,9},上级节点联合指示载波CC1和载波CC2的可用资源的可用状态是否会被修改,即载波CC1和CC2的资源只能同时被指示为其可用资源的可用状态是否会被修改。对于时隙3,载波CC1被半静态配置为不可用资源,因此上级节点的指示只适用于载波CC2。类似的,对于时隙7,上级节点的指示只适用于载波CC1。也就是说,对于MT中通过半静态资源配置推导得到的不可用资源,IAB节点可以忽略其上级节点的指示。基于载波组的指示可以节省指示DCI的开销,但IAB节点的MT资源与DU资源的资源复用灵活性不足。In a possible implementation manner, the upper-level node may also sub-carrier groups to indicate the available status of the available resources of the MT. Specifically, the upper-level node simultaneously indicates the availability of the available resources of the MT's carrier group (multiple carriers). When the upper-level node indicates that a certain time domain resource of the MT is available/unavailable, the time domain resources corresponding to multiple carriers in the carrier group are all indicated as available/unavailable. Still taking Fig. 16 as an example, for time slots {0, 1, 2, 8, 9}, the upper-level node jointly indicates whether the available status of the available resources of the carrier CC1 and the carrier CC2 will be modified, that is, the resources of the carriers CC1 and CC2 are only Can be indicated at the same time whether the available status of its available resources will be modified. For time slot 3, carrier CC1 is semi-statically configured as an unavailable resource, so the instructions of the upper node only apply to carrier CC2. Similarly, for time slot 7, the instructions of the superior node only apply to carrier CC1. That is to say, for the unavailable resources derived from the semi-static resource configuration in the MT, the IAB node can ignore the instructions of its superior node. The indication based on the carrier group can save the overhead of indicating the DCI, but the flexibility of resource reuse between the MT resource and the DU resource of the IAB node is insufficient.
需要说明的是,指示DCI可以存在一个指示范围,IAB节点的上级节点指示的资源应位 于该指示范围内。进一步地,IAB节点需要确定指示DCI在指示范围内所指示的具体资源集合。It should be noted that the indicated DCI may have an indication range, and the resource indicated by the superior node of the IAB node should be within the indication range. Further, the IAB node needs to determine the specific resource set indicated by the indication DCI within the indication range.
在一种可能的实现方式中,上级节点的指示资源(或IAB节点MT的待指示资源)是指示范围内所有MT的可用资源,其中MT的可用资源通过半静态资源配置获得。MT的可用资源的具体获取方式与图10所述实施例中步骤S1001所给出的方法相同。In a possible implementation manner, the indication resource of the upper node (or the resource to be indicated of the IAB node MT) is the available resource of all MTs within the indication range, and the available resource of the MT is obtained through semi-static resource configuration. The specific method for obtaining the available resources of the MT is the same as the method given in step S1001 in the embodiment described in FIG. 10.
在一种可能的实现方式中,上级节点的指示资源(或IAB节点MT的待指示资源)可以由特定的DU小区集合确定。例如,假设特定的DU小区集合中某个特定的DU小区与MT的载波具有TDM资源复用关系,则MT的待指示资源包括特定的DU小区的soft资源所对应的MT资源,或者包括特定的DU小区的soft资源和不可用(NA)资源所对应的MT资源。当特定的DU小区集合包含多个特定的DU小区时,则上级节点的指示资源可包含通过多个特定的DU小区确定的MT的待指示资源的交集或者并集。与图10所述的实施例不同的是,若IAB节点中MT具有D个载波,DU具有F个小区,并且D个载波与F个小区均具有资源复用或关联关系,则D个载波对应的MT的待指示资源集合由与之关联的F个小区对应的DU资源确定,而本实现方式中,可以由F个小区中特定的G个小区对应的DU资源确定与之关联的MT的待指示资源集合,其中,G<K。In a possible implementation manner, the indication resource of the superior node (or the resource to be indicated of the IAB node MT) may be determined by a specific DU cell set. For example, assuming that a specific DU cell in a specific DU cell set has a TDM resource reuse relationship with the MT carrier, the MT to-be-indicated resource includes the MT resource corresponding to the soft resource of the specific DU cell, or includes the specific MT resources corresponding to soft resources and unavailable (NA) resources of the DU cell. When a specific DU cell set includes multiple specific DU cells, the indicated resource of the upper node may include the intersection or union of the to-be-indicated resources of the MT determined by the multiple specific DU cells. The difference from the embodiment described in FIG. 10 is that if the MT in the IAB node has D carriers, the DU has F cells, and both D carriers and F cells have a resource reuse or association relationship, then D carriers correspond to The to-be-indicated resource set of the MT is determined by the DU resources corresponding to the F cells associated with it. In this implementation, the DU resources corresponding to the specific G cells in the F cells can be used to determine the to-be-indicated resource set of the MT associated with it. Indicates the resource set, where G<K.
在一种可能的实现方式中,上级节点的指示资源(或IAB节点MT的待指示资源)由上级节点或donor节点直接指示,该实现方式通常应用于多连接场景;In a possible implementation manner, the instruction resource of the superior node (or the resource to be instructed of the IAB node MT) is directly indicated by the superior node or the donor node, and this implementation manner is usually applied in a multi-connection scenario;
在一种可能的实现方式中,上级节点的指示资源(或IAB节点MT的待指示资源)为指示范围内IAB节点MT的所有资源。In a possible implementation manner, the indicated resource of the superior node (or the to-be-indicated resource of the IAB node MT) is all the resources of the IAB node MT within the indication range.
进一步地,在一些情况下,上级节点发送的指示DCI所指示的MT资源为IAB节点的MT的(通过半静态配置所确定)不可用资源,此时,MT可忽略指示DCI的对应字段,或者,MT期望该指示DCI始终指示该不可用资源为不可用。示例性的,上级节点指示MT的一个时隙的可用状态,而该MT时隙内可能包含若干不可用符号,此时,即使上级节点将此时隙指示为可用,原有的时隙内不可用符号依然为不可用。Further, in some cases, the MT resource indicated by the DCI sent by the superior node is an unavailable resource (determined by semi-static configuration) of the MT of the IAB node. In this case, the MT may ignore the corresponding field indicating the DCI, or MT expects the indication DCI to always indicate that the unavailable resource is unavailable. Exemplarily, the upper-level node indicates the available status of a time slot of the MT, and the MT time slot may contain several unusable symbols. At this time, even if the upper-level node indicates the time slot as available, the original time slot is not available. The symbol is still unavailable.
此外,本申请还详细阐述了指示DCI的指示粒度。具体的,指示DCI的指示资源粒度可以为时隙级,符号级,或者资源类型级。其中,In addition, this application also elaborates on the indication granularity of the indication DCI. Specifically, the indication resource granularity of the indication DCI may be at the slot level, symbol level, or resource type level. among them,
(1)时隙级指示:IAB节点的上级节点逐个时隙指示MT资源是否可用(或者其MT可用资源的可用状态是否被修改)。最简单的情况下,每个MT时隙仅需要一个比特来指示。应理解,这里的MT时隙是指MT可用资源中的MT时隙。(1) Slot-level indication: The upper node of the IAB node indicates whether the MT resource is available (or whether the available state of its MT available resource is modified) time slot by time slot. In the simplest case, only one bit is required for each MT slot to indicate. It should be understood that the MT time slot here refers to an MT time slot in the available resources of the MT.
(2)符号级指示:IAB节点的上级节点可将一个时隙内的部分符号修改为不可用。例如,通过起始和长度指示值(start and length indicator value,SLIV),IAB节点的上级节点可将时隙内一段连续的符号指示为可用/不可用。(2) Symbol level indication: The upper node of the IAB node can modify part of the symbols in a time slot to be unavailable. For example, through the start and length indicator value (SLIV), the upper-level node of the IAB node can indicate that a segment of consecutive symbols in the time slot is available/unavailable.
(3)资源类型级指示:资源类型级指示可视作一种特殊的符号级指示,即指示信令可单独指示时隙内每种或多种资源类型(D/U/F)符号的可用性。对于MT指示,资源类型级指示可分为两种子方法:(a)基于MT资源类型的指示,即一个MT时隙内具有不同资源类型的符号可被独立指示不可用性;(b)基于DU资源类型的指示,即一个DU时隙内具有不同资源类型的符号所对应的MT符号可被可被独立指示不可用性。(3) Resource type level indicator: The resource type level indicator can be regarded as a special symbol level indicator, that is, the indicator signaling can separately indicate the availability of symbols of each or multiple resource types (D/U/F) in the time slot . For MT indication, resource type level indication can be divided into two sub-methods: (a) indication based on MT resource type, that is, symbols with different resource types in an MT slot can be independently indicated unavailability; (b) based on DU resource Type indication, that is, MT symbols corresponding to symbols with different resource types in a DU slot can be independently indicated unavailability.
还需要说明的是,不同的时域资源(例如不同的时隙)可以被绑定指示,也就是说IAB节点的上级节点可以为绑定的多个时域资源指示相同的资源可用状态。It should also be noted that different time domain resources (for example, different time slots) can be indicated by binding, that is, the upper-level node of the IAB node can indicate the same resource availability status for multiple bound time domain resources.
另外,在一种可能的实现中,IAB节点释放一个MT资源表示对应的DU资源为可用, 对应的DU资源表示与该MT资源具有相同标识(例如相同索引)的DU资源。In addition, in a possible implementation, the release of an MT resource by the IAB node indicates that the corresponding DU resource is available, and the corresponding DU resource indicates a DU resource with the same identifier (for example, the same index) as the MT resource.
在一种可能的实现中,IAB节点的MT的某些载波(即协议中的某些服务小区)会处于非激活状态,此时IAB节点和其上级节点将MT对应载波的所有资源视为不可用,并且,指示DCI可以不指示该对应载波,或指示DCI始终释放对应资源,或IAB节点忽略对应的指示DCI指示字段。In a possible implementation, some carriers of the MT of the IAB node (that is, certain serving cells in the protocol) will be in an inactive state. At this time, the IAB node and its superior node treat all the resources of the corresponding carrier of the MT as inactive. In addition, the indication DCI may not indicate the corresponding carrier, or indicate that the DCI always releases the corresponding resource, or the IAB node ignores the corresponding indication DCI indication field.
上述实施例详述了当IAB节点的上级节点仅对IAB节点的MT的可用资源的可用状态进行显示指示,对DU的soft资源的可用状态进行隐式指示的方案。下面详述上级节点仅对DU的soft资源的可用状态进行显式指示,对IAB节点的MT的可用资源的可用状态进行隐示指示的方案细节设计。The foregoing embodiment details the solution when the superior node of the IAB node only displays the available state of the available resources of the MT of the IAB node, and implicitly indicates the available state of the soft resources of the DU. The detailed design of the scheme in which the upper-level node only explicitly indicates the available state of the soft resource of the DU, and the available state of the available resource of the MT of the IAB node is described in detail below.
在一种可能的实现方式中,在MT多载波和DU多小区的情况下,IAB节点的上级节点可以直接对IAB节点的DU的soft资源的可用状态进行显式指示,而IAB节点可根据该指示确定其MT可用资源的可用状态。即IAB节点的上级节点指示IAB节点是否可以采用DU在经过半静态资源配置后确定的soft资源与下级IAB节点或UE进行通信,IAB节点根据其上级节点对DU的soft资源的可用状态的指示(以下简称DU指示),推导出自身MT的可用资源的可用状态。在确定MT的可用资源的可用状态时,需要考虑MT的各个载波与DU的各个小区之间的资源复用或关联关系。In a possible implementation manner, in the case of MT multi-carrier and DU multi-cell, the superior node of the IAB node can directly indicate the available status of the soft resource of the IAB node's DU, and the IAB node can be based on this Indicate to determine the available status of its MT available resources. That is, the upper-level node of the IAB node indicates whether the IAB node can use the soft resource determined by the DU after semi-static resource configuration to communicate with the lower-level IAB node or UE, and the IAB node according to its upper-level node's indication of the available state of the DU's soft resource ( Hereinafter referred to as DU indication), the available state of the available resources of the own MT is derived. When determining the available status of the available resources of the MT, the resource reuse or association relationship between each carrier of the MT and each cell of the DU needs to be considered.
具体的,在IAB节点的DU具有多个小区的情况下,指示DCI可选择性的指示所有DU小区或部分DU小区的soft资源的可用性。Specifically, in the case where the DU of the IAB node has multiple cells, the indication DCI can selectively indicate the availability of soft resources of all DU cells or some DU cells.
在一种可能的实现方式中,指示DCI需要指示一个或多个DU小区若干时隙或符号的资源的可用性。可选地,IAB节点可忽略指示DCI对其中部分时隙或符号的指示。该可忽略指示的部分符号或时隙包括:半静态信令配置的DU hard时隙或符号,半静态信令配置的DU不可用时隙或符号,配置了小区级信号或信道(包括SS/PBCH block,PRACH资源)的时隙或符号,指定配置资源等。在这里,指定配置资源是指IAB节点通过配置信令额外确定的资源,IAB节点忽略指示DCI对该资源的动态指示。在一种可能的实现方式中,指定配置资源为IAB节点接收到指示DCI的MT时隙所对应的DU时隙及其之后的一段资源。如图8所示,指定配置资源可以为IAB节点接收到指示DCI的MT时隙0所对应的DU时隙0至DU时隙3的一段资源。通过配置指定配置资源,可实现动态指示的延时指示,提升动态指示的灵活性。In a possible implementation manner, indicating that the DCI needs to indicate the availability of resources of several time slots or symbols in one or more DU cells. Optionally, the IAB node may ignore the indication of the DCI for some of the time slots or symbols. The part of the symbols or time slots for which the indication can be ignored includes: DU hard time slots or symbols configured by semi-static signaling, DU unavailable time slots or symbols configured by semi-static signaling, and cell-level signals or channels (including SS/PBCH) are configured. block, PRACH resource) time slot or symbol, designated configuration resource, etc. Here, the designated configuration resource refers to the resource additionally determined by the IAB node through configuration signaling, and the IAB node ignores the dynamic indication of the resource by the DCI. In a possible implementation manner, the designated configuration resource is the DU slot corresponding to the MT slot indicating the DCI received by the IAB node and a section of resources thereafter. As shown in FIG. 8, the designated configuration resource may be a segment of resources from DU slot 0 to DU slot 3 corresponding to MT slot 0 of the DCI received by the IAB node. By configuring the specified configuration resources, the delay indication of the dynamic indication can be realized, and the flexibility of the dynamic indication can be improved.
在收到上级节点发送的对DU的指示信息后,IAB节点应通过MT的各个载波和DU的各个小区的资源复用或关联关系确定各个MT载波在不同时刻的资源的可用性。对于一个MT载波,MT的可用时域资源应不影响DU所有小区的hard资源和被上级节点指示为可用的soft资源的传输。在这里,MT资源的确定方法与上述实施例步骤S1002相似,不同的是,本实施例需要同时考虑DU的hard资源与被上级节点指示为DU可用的soft资源。After receiving the instruction information for the DU sent by the superior node, the IAB node should determine the resource availability of each MT carrier at different moments through the resource multiplexing or association relationship between each carrier of the MT and each cell of the DU. For an MT carrier, the available time domain resources of the MT should not affect the transmission of the hard resources of all cells of the DU and the soft resources indicated as available by the upper node. Here, the method for determining the MT resource is similar to step S1002 of the foregoing embodiment. The difference is that this embodiment needs to consider both the hard resources of the DU and the soft resources indicated as available to the DU by the upper-level node.
同半静态资源配置类似,MT各载波的可用/不可用时域资源可能需要根据与之关联的多个DU小区的指示确定。即对于一个MT载波,应根据与其关联的多个DU小区的动态指示结果确定其可用资源的可用状态,即确定MT通过半静态资源配置得到的可用资源的可用状态是否会被修改为不可用。在确定MT的可用资源的可用状态时,需要考虑MT的各个载波与DU的各个小区之间的资源复用或关联关系。Similar to the semi-static resource configuration, the available/unavailable time domain resources of each carrier of the MT may need to be determined according to the instructions of multiple DU cells associated with it. That is, for an MT carrier, the available state of its available resources should be determined according to the dynamic indication results of multiple DU cells associated with it, that is, whether the available state of the available resources obtained by the MT through semi-static resource configuration will be modified to unavailable. When determining the available status of the available resources of the MT, the resource reuse or association relationship between each carrier of the MT and each cell of the DU needs to be considered.
在一种可能的实现中,指示DCI在指示DU小区的soft资源的可用状态时可将MT载波纳入考虑,例如令指示DCI指示一个或多个MT载波所关联的一个或多个DU小区的soft资 源的可用状态。In a possible implementation, the MT carrier can be taken into consideration when the DCI indicates the available status of the soft resources of the DU cell. For example, the DCI indicates the soft data of one or more DU cells associated with one or more MT carriers. The available status of the resource.
具体地,上级节点或donor节点在配置指示DCI信息时,可同时配置DCI所关联的MT载波,此外IAB节点还可以确定该指示DCI对应的DU小区,这里的DU小区可以是donor节点或上级节点配置的,也可以是IAB节点根据关联MT载波推导而出的。例如,指示DCI指示与关联MT载波具有TDM关系的DU小区。可选的,当MT载波不存在TDM关系的DU小区时,指示DCI指示与关联MT载波具有FDM/SDM的DU小区。Specifically, when the upper node or donor node configures the indicated DCI information, the MT carrier associated with the DCI can be configured at the same time. In addition, the IAB node can also determine the DU cell corresponding to the indicated DCI, where the DU cell can be a donor node or an upper node The configuration may also be derived by the IAB node based on the associated MT carrier. For example, the indication DCI indicates a DU cell that has a TDM relationship with the associated MT carrier. Optionally, when the MT carrier does not have a DU cell with a TDM relationship, the DCI is instructed to indicate a DU cell with FDM/SDM with the associated MT carrier.
示例性的,指示DCI的配置信息可以包括:Exemplarily, the configuration information indicating the DCI may include:
{{
关联载波标识;Associated carrier identification;
被指示DU小区标识;The identity of the indicated DU cell;
}}
其中,关联MT载波标识可以指与被上级节点进行动态资源指示的DU小区具有资源复用或关联关系的MT载波的标识,例如,CC1。被指示DU小区标识可以指被上级节点进动态资源指示的DU小区的标识,例如cell 1。该关联MT载波标识由上级节点配置得到,被指示DU小区标识可以由上级节点配置得到,也可以由关联MT载波标识,和MT载波与被指示DU小区的资源复用或关联关系得到。在指示DU小区的soft资源的可用状态的同时配置关联MT载波标识可使得IAB节点快速获取各个MT载波的可用资源的可用状态。Wherein, the associated MT carrier identifier may refer to the identifier of the MT carrier that has resource reuse or association relationship with the DU cell that is dynamically resource indicated by the upper node, for example, CC1. The indicated DU cell identifier may refer to the identifier of the DU cell indicated by the upper node in the dynamic resource, for example, cell 1. The associated MT carrier identifier is configured by an upper-level node, and the indicated DU cell identifier may be configured by an upper-level node, or may be obtained from the associated MT carrier identifier, and the resource reuse or association relationship between the MT carrier and the indicated DU cell. The configuration of the associated MT carrier identifier while indicating the available status of the soft resources of the DU cell enables the IAB node to quickly obtain the available status of the available resources of each MT carrier.
在一种可能的实现方式中,指示DCI同时指示DU小区的soft资源的可用状态与MT载波的可用资源的可用状态。In a possible implementation manner, the indication DCI indicates the available state of the soft resources of the DU cell and the available state of the available resources of the MT carrier at the same time.
示例性的,指示DCI的配置信息还可以包括:Exemplarily, the configuration information indicating the DCI may further include:
指示DCI的配置信息:Indicate DCI configuration information:
{{
指示MT载波标识;Indicate the MT carrier identification;
指示DU小区标识;Indicate the DU cell identity;
}}
其中,指示MT载波标识可以指被上级节点进动态资源指示的MT载波的标识,例如,CC2。指示DU小区标识可以指被上级节点进动态资源指示的DU小区的标识,例如cell 2。该指示MT载波标识与指示DU小区标识均可由上级节点配置得到,上级节点可通过指示DCI同时指示一个或多个MT载波与一个或多个DU小区的资源的可用状态。在该可能的实现方式中,假设指示DCI指示一个MT载波与DU小区的资源可用性,当所被指示的MT载波与DU小区具TDM关联关系时,指示DCI可以指示两种状态,例如0/1。其中,(1)0:DU资源不可用+MT资源可用;(2)1:DU资源可用+MT资源不可用。Wherein, indicating the MT carrier identifier may refer to the identifier of the MT carrier indicated by the upper node in the dynamic resource, for example, CC2. The indicator DU cell identity may refer to the identity of the DU cell indicated by the higher-level node in the dynamic resource, for example, cell 2. Both the indicated MT carrier identifier and the indicated DU cell identifier can be configured by an upper-level node, and the upper-level node can indicate the available status of one or more MT carriers and one or more DU cells at the same time by instructing DCI. In this possible implementation manner, it is assumed that the indicated DCI indicates the resource availability of an MT carrier and a DU cell. When the indicated MT carrier has a TDM association relationship with the DU cell, the indicated DCI can indicate two states, such as 0/1. Among them, (1) 0: DU resource is not available + MT resource is available; (2) 1: DU resource is available + MT resource is not available.
综上所述,在接收到上级节点的动态资源指示后,若该指示为MT指示,即上级节点指示了IAB节点的MT可用资源的可用性,则IAB节点应根据该MT指示以及MT的各个载波与DU的各个小区之间的资源复用或关联关系确定DU的各个小区的soft资源的可用性,其中,IAB节点对DU资源的使用不应影响被指示为可用的MT可用资源的使用。In summary, after receiving the dynamic resource indication from the upper-level node, if the indication is an MT indication, that is, the upper-level node indicates the availability of the MT available resources of the IAB node, the IAB node should follow the MT indication and each carrier of the MT The resource reuse or association relationship with each cell of the DU determines the availability of the soft resources of each cell of the DU, where the use of the DU resources by the IAB node should not affect the use of the MT available resources that are indicated as available.
若该指示为DU指示,即上级节点直接指示了IAB节点的DU soft资源的可用性,则IAB节点应根据该DU指示以及MT的各个载波与DU的各个小区之间的资源复用或关联关系确定MT的各个载波的可用资源的可用性,其中,IAB节点对MT资源的使用不应影响DU hard和被指示为可用soft资源的使用。If the indication is a DU indication, that is, the superior node directly indicates the availability of the DU soft resource of the IAB node, the IAB node should determine the resource reuse or association relationship between the DU indication and each carrier of the MT and each cell of the DU. The availability of the available resources of each carrier of the MT, where the use of the MT resources by the IAB node should not affect the use of DU hard and indicated as available soft resources.
无论接收到的上级节点的动态资源指示为MT指示或DU指示,IAB节点均可确定出每个MT载波的各个资源的可用性。对于MT的可用资源,MT的行为与普通终端设备类似,而对于MT的不可用资源,则需要定义MT的行为。具体地:Regardless of whether the received dynamic resource indication of the upper node is an MT indication or a DU indication, the IAB node can determine the availability of each resource of each MT carrier. For the available resources of the MT, the behavior of the MT is similar to that of ordinary terminal equipment, while for the unavailable resources of the MT, the behavior of the MT needs to be defined. specifically:
IAB节点的MT不期望上级节点通过指示DCI指示其在不可用资源进行PDSCH接收,PUSCH发送,HARQ-ACK反馈。但应注意,上述限制可能仅适用于部分传输过程,例如仅限于部分RNTI(例如C-RNTI,MCS-C-RNTI)加扰CRC的DCI所调度的PDSCH,PUSCH,或者所指示的HARQ-ACK反馈等。而对于另一些RNTI(例如SI-RNTI)加扰CRC的DCI所调度的PDSCH和PUSCH所指示的传输,则不需要满足其约束。在一种可能的实现方式中,上述限制仅适用于IAB节点的单播PDSCH和PUSCH,而不适用于上级节点的广播PDSCH调度。The MT of the IAB node does not expect the upper node to instruct the DCI to instruct it to perform PDSCH reception, PUSCH transmission, and HARQ-ACK feedback on unavailable resources. However, it should be noted that the above restrictions may only apply to part of the transmission process, for example, only partial RNTI (such as C-RNTI, MCS-C-RNTI) scrambling CRC for the DCI scheduled PDSCH, PUSCH, or the indicated HARQ-ACK Feedback etc. For other RNTI (for example, SI-RNTI) scrambling the transmission indicated by the PDSCH and PUSCH scheduled by the DCI of the CRC, the constraints do not need to be met. In a possible implementation manner, the above limitation only applies to the unicast PDSCH and PUSCH of the IAB node, but not to the broadcast PDSCH scheduling of the upper-level node.
进一步地,IAB节点的MT可以不在不可用资源进行高层配置信号的收发,可以包括下述的一个或多个:PDCCH监测,CSI-RS接收,SRS发送,半静态PDSCH,基于配置的PUSCH等。对于PDCCH监测,MT可能只在不可用资源不进行部分PDCCH的监测,例如,UE-specific搜索空间集合,或动态调度的单播PDSCH/PUSCH所对应的DCI。或者说,MT可以在不可用资源监测广播信道所对应的PDCCH。MT不监测特定RNTI加扰CRC的DCI。同理,MT可能仅在不可用资源不接收UE-specific的CSI-RS。Further, the MT of the IAB node may not perform high-level configuration signal transmission and reception on unavailable resources, and may include one or more of the following: PDCCH monitoring, CSI-RS reception, SRS transmission, semi-static PDSCH, configuration-based PUSCH, etc. For PDCCH monitoring, the MT may only perform partial PDCCH monitoring on unavailable resources, such as a UE-specific search space set, or the DCI corresponding to a unicast PDSCH/PUSCH that is dynamically scheduled. In other words, the MT can monitor the PDCCH corresponding to the broadcast channel on unavailable resources. The MT does not monitor the specific RNTI to scramble the DCI of the CRC. In the same way, the MT may only receive UE-specific CSI-RS on unavailable resources.
还需要说明的是,当MT具有多个载波时,对于同一个时域资源,不同载波可能具有不同的可用状态。It should also be noted that when the MT has multiple carriers, for the same time domain resource, different carriers may have different available states.
应理解,上述MT行为可能仅局限于特定的MT状态,例如,仅当MT处于RRC连接状态时,MT满足上述行为。而当MT处于idle或inactive状态时,可以不局限于上述行为。It should be understood that the above-mentioned MT behavior may only be limited to a specific MT state, for example, the MT meets the above-mentioned behavior only when the MT is in the RRC connected state. When the MT is in the idle or inactive state, it may not be limited to the above behavior.
还应理解,在一些情况下,IAB节点MT可能会漏检指示DCI所对应的PDCCH,此时,IAB节点MT应假设所有半静态确定的可用资源的可用性不变,并进行对应的回传链路的接收或发送。但IAB节点MT可以有以下例外行为:IAB节点可以不在半静态确定的可用资源上进行SRS发送或基于配置的PUSCH发送。It should also be understood that in some cases, the IAB node MT may miss the PDCCH corresponding to the DCI. At this time, the IAB node MT should assume that the availability of all semi-statically determined available resources remains unchanged, and perform the corresponding backhaul chain Receiving or sending of roads. However, the IAB node MT may have the following exceptions: the IAB node may not perform SRS transmission or PUSCH transmission based on the configuration on the available resources determined semi-statically.
本申请提供了IAB节点的MT资源与DU资源的动态资源指示方法。在MT多载波和DU多小区的应用场景下,IAB节点的上级节点可以显式或隐式地指示IAB节点的MT的可用资源的可用状态,以及显式或隐式地指示IAB节点的DU soft资源的可用状态。其中,IAB节点的上级节点还可以仅对IAB节点的MT的可用资源的可用状态进行显式指示,而IAB节点可根据该指示隐式确定其DU soft资源的可用状态。IAB节点的上级节点还可以仅对IAB节点的DU soft资源的可用状态进行显式指示,而IAB节点可根据该指示隐式确定其MT的可用资源的可用状态。本申请提供的技术方案可以实现IAB节点的MT资源与DU资源的动态资源共享。This application provides a dynamic resource indication method for the MT resource and DU resource of the IAB node. In the application scenarios of MT multi-carrier and DU multi-cell, the superior node of the IAB node can explicitly or implicitly indicate the available status of the MT's available resources of the IAB node, and explicitly or implicitly indicate the DU soft of the IAB node. The availability status of the resource. Wherein, the upper-level node of the IAB node may also only explicitly indicate the available state of the available resources of the MT of the IAB node, and the IAB node may implicitly determine the available state of its soft resources according to the indication. The upper-level node of the IAB node may also only explicitly indicate the available state of the DU soft resource of the IAB node, and the IAB node may implicitly determine the available state of the available resource of its MT according to the indication. The technical solution provided in this application can realize the dynamic resource sharing of the MT resource and the DU resource of the IAB node.
以上对本申请提供的资源的动态指示的方法进行了详细说明,下面介绍本申请提供的与第一节点对应的中继装置。The method for dynamically indicating resources provided by the present application has been described in detail above, and the relay device corresponding to the first node provided by the present application will be introduced below.
参见图17,图17是本申请提供的中继装置1700的示意性结构框图。如图17所示,中继装置1700包括处理单元1710和收发单元1720。Referring to FIG. 17, FIG. 17 is a schematic structural block diagram of a relay device 1700 provided in the present application. As shown in FIG. 17, the relay device 1700 includes a processing unit 1710 and a transceiving unit 1720.
处理单元1710,用于根据第一指示信息确定D个载波对应的第一资源和F个小区对应的第二资源的半静态资源配置,其中,D≥1,F≥1;还用于根据第二指示信息确定D个载波对应的第一资源的可用资源的可用状态和F个小区对应的第二资源的动态资源的可用状态。The processing unit 1710 is configured to determine, according to the first indication information, the semi-static resource configuration of the first resource corresponding to the D carriers and the second resource corresponding to the F cells, where D≥1 and F≥1; The second indication information determines the available state of the available resource of the first resource corresponding to the D carriers and the available state of the dynamic resource of the second resource corresponding to the F cells.
收发单元1720,用于接收第二节点或宿主节点发送的第一指示信息,该第一指示信息用 于指示第一节点中D个载波对应的第一资源和F个小区对应的第二资源的半静态资源配置,其中,D≥1,F≥1;接收第二节点发送的第二指示信息,该第二指示信息用于指示第一节点中D个载波对应的第一资源的可用资源的可用状态和F个小区对应的第二资源的动态资源的可用状态。The transceiver unit 1720 is configured to receive first indication information sent by the second node or the donor node, where the first indication information is used to indicate the first resource corresponding to the D carriers and the second resource corresponding to the F cells in the first node Semi-static resource configuration, where D≥1, F≥1; receiving second indication information sent by the second node, the second indication information is used to indicate the available resources of the first resource corresponding to the D carriers in the first node The available state and the available state of the dynamic resource of the second resource corresponding to the F cells.
可选地,装置1700可以为芯片或集成电路。Optionally, the device 1700 may be a chip or an integrated circuit.
本申请实施例中所述的芯片,可以是现场可编程门阵列(field-programmable gate array,FPGA)、专用集成芯片(application specific integrated circuit,ASIC)、系统芯片(system on chip,SoC)、中央处理器(central processor unit,CPU)、网络处理器(Network Processor,NP)、数字信号处理电路(digital signal processor,DSP),还可以是微控制器(micro controller unit,MCU、可编程控制器(programmable logic device,PLD)或其它集成芯片。The chip described in the embodiment of the application may be a field-programmable gate array (FPGA), an application specific integrated circuit (ASIC), a system on chip (SoC), a central Processor (central processor unit, CPU), network processor (Network Processor, NP), digital signal processing circuit (digital signal processor, DSP), can also be a microcontroller (microcontroller unit, MCU, programmable controller ( programmable logic device (PLD) or other integrated chips.
可选地,处理单元1710可以为处理器。收发单元1710可以由接收单元和发送单元组成。收发单元1720可以为收发器,收发器可以包括发射机和接收机,同时具备接收和发送的功能。可选地,收发单元1710还可以为输入输出接口,或者输入输出电路。Optionally, the processing unit 1710 may be a processor. The transceiver unit 1710 may be composed of a receiving unit and a sending unit. The transceiver unit 1720 may be a transceiver, and the transceiver may include a transmitter and a receiver, and has the functions of receiving and transmitting at the same time. Optionally, the transceiver unit 1710 may also be an input/output interface or an input/output circuit.
在另一种可能的方式中,收发单元1720可以为通信接口。例如,输入输出接口,输入接口电路和输出接口电路等。In another possible manner, the transceiver unit 1720 may be a communication interface. For example, input and output interface, input interface circuit and output interface circuit, etc.
应理解,装置1700可以对应本申请提供的图10实施例提供的动态资源的指示方法1000及其它实施例中的第一节点或IAB节点。装置1700包括的各单元分别用于实现方法1000及其它实施例中由第一节点或IAB节点执行的相应操作和/或流程。It should be understood that the apparatus 1700 may correspond to the first node or the IAB node in the method 1000 for indicating dynamic resources provided in the embodiment of FIG. 10 provided by the present application and other embodiments. The units included in the apparatus 1700 are respectively used to implement corresponding operations and/or processes performed by the first node or the IAB node in the method 1000 and other embodiments.
例如,处理单元1710还用于根据MT的可用资源的可用状态隐式确定其DU soft资源的可用状态。或者,还用于根据DU soft资源的可用状态隐式确定其MT的可用资源的可用状态。For example, the processing unit 1710 is further configured to implicitly determine the available state of its DU soft resources according to the available state of the available resources of the MT. Or, it is also used to implicitly determine the available state of the MT's available resources according to the available state of the DU soft resources.
此外,本申请提供一种计算机可读存储介质,计算机可读存储介质中存储有计算机指令,当计算机指令在计算机上运行时,使得计算机执行上述任一方法实施例中由第一节点或IAB节点执行的相应操作和/或流程。In addition, the present application provides a computer-readable storage medium. The computer-readable storage medium stores computer instructions. When the computer instructions run on the computer, the computer executes any of the foregoing method embodiments by the first node or the IAB node. The corresponding operations and/or processes performed.
本申请还提供一种计算机程序产品,计算机程序产品包括计算机程序代码,当计算机程序代码在计算机上运行时,使得计算机执行本申请上述任一方法实施例中由第一节点或IAB节点执行的相应操作和/或流程。This application also provides a computer program product. The computer program product includes computer program code. When the computer program code runs on a computer, the computer executes the corresponding method executed by the first node or the IAB node in any of the above-mentioned method embodiments of this application. Operations and/or processes.
本申请还提供一种芯片,包括处理器。处理器用于调用并运行存储器中存储的计算机程序,以执行本申请上述任一方法实施例中由第一节点执行的相应操作和/或流程。The application also provides a chip including a processor. The processor is used to call and run the computer program stored in the memory to execute the corresponding operation and/or process executed by the first node in any of the foregoing method embodiments of the present application.
可选地,芯片还包括存储器,存储器与处理器连接。处理器用于读取并执行存储器中的计算机程序。Optionally, the chip further includes a memory, and the memory is connected to the processor. The processor is used to read and execute the computer program in the memory.
进一步可选地,芯片还包括通信接口,处理器与通信接口连接。通信接口用于接收需要处理的信号和/或数据,处理器从通信接口获取该信号和/或数据,并对其进行处理。Further optionally, the chip further includes a communication interface, and the processor is connected to the communication interface. The communication interface is used to receive signals and/or data to be processed, and the processor obtains the signals and/or data from the communication interface and processes them.
可选地,通信接口可以是输入输出接口,具体可以包括输入接口和输出接口。或者,通信接口可以是输入输出电路,具体可以包括输入电路和输出电路。Optionally, the communication interface may be an input/output interface, which may specifically include an input interface and an output interface. Alternatively, the communication interface may be an input/output circuit, which may specifically include an input circuit and an output circuit.
上述实施例中涉及的存储器与存储器可以是物理上相互独立的单元,或者,存储器也可以和处理器集成在一起。The memory and the memory involved in the foregoing embodiments may be physically independent units, or the memory may also be integrated with the processor.
以上各实施例中,处理器可以为中央处理器(central processing unit,CPU)、微处理器、特定应用集成电路(application-specific integrated circuit,ASIC),或一个或多个用于控制本申请技术方案程序执行的集成电路等。例如,处理器可以是数字信号处理器设备、微处理器设 备、模数转换器、数模转换器等。处理器可以根据这些设备各自的功能而在这些设备之间分配终端设备或网络设备的控制和信号处理的功能。此外,处理器可以具有操作一个或多个软件程序的功能,软件程序可以存储在存储器中。处理器的所述功能可以通过硬件实现,也可以通过硬件执行相应的软件实现。所述硬件或软件包括一个或多个与上述功能相对应的模块。In the above embodiments, the processor may be a central processing unit (CPU), a microprocessor, an application-specific integrated circuit (ASIC), or one or more of the technologies used to control the application. Integrated circuits for the execution of program programs, etc. For example, the processor may be a digital signal processor device, a microprocessor device, an analog-to-digital converter, a digital-to-analog converter, and so on. The processor can distribute the control and signal processing functions of the terminal device or the network device among these devices according to their respective functions. In addition, the processor may have a function of operating one or more software programs, and the software programs may be stored in the memory. The functions of the processor can be implemented by hardware, or can be implemented by hardware executing corresponding software. The hardware or software includes one or more modules corresponding to the above-mentioned functions.
存储器可以是只读存储器(read-only memory,ROM)、可存储静态信息和指令的其它类型的静态存储设备、随机存取存储器(random access memory,RAM)或可存储信息和指令的其它类型的动态存储设备,也可以是电可擦可编程只读存储器(electrically erasable programmable read-only memory,EEPROM)、只读光盘(compact disc read-only memory,CD-ROM)或其他光盘存储、光碟存储(包括压缩光碟、激光碟、光碟、数字通用光碟、蓝光光碟等)、磁盘存储介质或者其它磁存储设备,或者还可以是能够用于携带或存储具有指令或数据结构形式的期望的程序代码并能够由计算机存取的任何其它介质等。The memory can be read-only memory (ROM), other types of static storage devices that can store static information and instructions, random access memory (RAM), or other types that can store information and instructions Dynamic storage devices can also be electrically erasable programmable read-only memory (EEPROM), compact disc read-only memory (CD-ROM), or other optical disk storage, optical disc storage ( Including compact discs, laser discs, optical discs, digital universal discs, Blu-ray discs, etc.), magnetic disk storage media or other magnetic storage devices, or can be used to carry or store desired program codes in the form of instructions or data structures Any other medium accessed by the computer, etc.
本申请实施例中,“和/或”,描述关联对象的关联关系,表示可以存在三种关系,例如,A和/或B,可以表示单独存在A、同时存在A和B、单独存在B的情况。其中A,B可以是单数或者复数。In the embodiments of the present application, "and/or" describes the association relationship of the associated objects, which means that there can be three relationships, for example, A and/or B, which can mean that A alone exists, A and B exist simultaneously, and B exists alone Happening. Among them, A and B can be singular or plural.
本领域普通技术人员可以意识到,结合本文中所公开的实施例描述的各示例的单元,能够以电子硬件、或者计算机软件和电子硬件的结合来实现。这些功能究竟以硬件还是软件方式来执行,取决于技术方案的特定应用和设计约束条件。专业技术人员可以对每个特定的应用来使用不同方法来实现所描述的功能。A person of ordinary skill in the art may be aware that, in combination with the examples described in the embodiments disclosed herein, the units can be implemented by electronic hardware or a combination of computer software and electronic hardware. Whether these functions are performed by hardware or software depends on the specific application and design constraint conditions of the technical solution. Professional technicians can use different methods for each specific application to achieve the described functions.
在本申请所提供的几个实施例中,应该理解到,所揭露的系统、装置和方法,可以通过其它的方式实现。例如,以上所描述的装置实施例只是示意性的,例如,所述单元的划分,仅仅为一种逻辑功能划分,实际实现时可以有另外的划分方式,例如多个单元或组件可以结合或者可以集成到另一个系统,或一些特征可以忽略,或不执行。另一点,所显示或讨论的相互之间的耦合或直接耦合或通信连接可以是通过一些接口,装置或单元的间接耦合或通信连接,可以是电性,机械或其它的形式。In the several embodiments provided in this application, it should be understood that the disclosed system, device, and method may be implemented in other ways. For example, the device embodiments described above are only illustrative. For example, the division of the units is only a logical function division, and there may be other divisions in actual implementation, for example, multiple units or components may be combined or may be Integrate into another system, or some features can be ignored or not implemented. In addition, the displayed or discussed mutual coupling or direct coupling or communication connection may be indirect coupling or communication connection through some interfaces, devices or units, and may be in electrical, mechanical or other forms.
所述作为分离部件说明的单元可以是或者也可以不是物理上分开的,作为单元显示的部件可以是或者也可以不是物理单元,即可以位于一个地方,或者也可以分布到多个网络单元上。可以根据实际的需要选择其中的部分或者全部单元来实现本实施例方案的目的。The units described as separate components may or may not be physically separated, and the components displayed as units may or may not be physical units, that is, they may be located in one place, or they may be distributed on multiple network units. Some or all of the units may be selected according to actual needs to achieve the objectives of the solutions of the embodiments.
另外,在本申请各个实施例中的各功能单元可以集成在一个处理单元中,也可以是各个单元单独物理存在,也可以两个或两个以上单元集成在一个单元中。In addition, the functional units in the various embodiments of the present application may be integrated into one processing unit, or each unit may exist alone physically, or two or more units may be integrated into one unit.
所述功能如果以软件功能单元的形式实现并作为独立的产品销售或使用时,可以存储在一个计算机可读取存储介质中。基于这样的理解,本申请的技术方案本质上或者说对现有技术做出贡献的部分或者该技术方案的部分可以以软件产品的形式体现出来,该计算机软件产品存储在一个存储介质中,包括若干指令用以使得一台计算机设备(可以是个人计算机,服务器,或者网络设备等)执行本申请各个实施例所述方法的全部或部分步骤。而前述的存储介质包括:U盘、移动硬盘、只读存储器(read-only memory,ROM)、随机存取存储器(random access memory,RAM)、磁碟或者光盘等各种可以存储程序代码的介质。If the function is implemented in the form of a software functional unit and sold or used as an independent product, it can be stored in a computer readable storage medium. Based on this understanding, the technical solution of the present application essentially or the part that contributes to the existing technology or the part of the technical solution can be embodied in the form of a software product, and the computer software product is stored in a storage medium, including Several instructions are used to make a computer device (which may be a personal computer, a server, or a network device, etc.) execute all or part of the steps of the methods described in the various embodiments of the present application. The aforementioned storage media include: U disk, mobile hard disk, read-only memory (read-only memory, ROM), random access memory (random access memory, RAM), magnetic disks or optical disks and other media that can store program codes. .
以上所述,仅为本申请的具体实施方式,但本申请的保护范围并不局限于此,任何熟悉本技术领域的技术人员在本申请揭露的技术范围内,可轻易想到变化或替换,都应涵盖在本申请的保护范围之内。因此,本申请的保护范围应以所述权利要求的保护范围为准。The above are only specific implementations of this application, but the protection scope of this application is not limited to this. Any person skilled in the art can easily think of changes or substitutions within the technical scope disclosed in this application. Should be covered within the scope of protection of this application. Therefore, the protection scope of this application should be subject to the protection scope of the claims.
Claims (20)
- 一种资源的动态指示方法,其特征在于,所述方法包括:A method for dynamically indicating resources, characterized in that the method includes:第一节点接收第二节点或宿主节点发送的第一指示信息,所述第一指示信息用于指示所述第一节点中D个载波对应的第一资源和F个小区对应的第二资源的半静态资源配置,其中,D≥1,F≥1;The first node receives the first indication information sent by the second node or the donor node, where the first indication information is used to indicate the first resource corresponding to the D carriers and the second resource corresponding to the F cells in the first node Semi-static resource configuration, where D≥1, F≥1;所述第一节点根据所述第一指示信息确定所述D个载波对应的第一资源和所述F个小区对应的第二资源的半静态资源配置;Determining, by the first node, the semi-static resource configuration of the first resources corresponding to the D carriers and the second resources corresponding to the F cells according to the first indication information;所述第一节点接收所述第二节点发送的第二指示信息,所述第二指示信息用于指示所述第一节点中所述D个载波对应的所述第一资源的可用资源的可用状态和所述F个小区对应的所述第二资源的动态资源的可用状态;The first node receives second indication information sent by the second node, where the second indication information is used to indicate the availability of available resources of the first resource corresponding to the D carriers in the first node Status and available status of the dynamic resource of the second resource corresponding to the F cells;所述第一节点根据所述第二指示信息确定所述D个载波对应的所述第一资源的可用资源的可用状态和所述F个小区对应的所述第二资源的动态资源的可用状态。The first node determines, according to the second indication information, the available state of the available resource of the first resource corresponding to the D carriers and the available state of the dynamic resource of the second resource corresponding to the F cells .
- 如权利要求1所述的方法,其特征在于,所述方法还包括:The method of claim 1, wherein the method further comprises:所述第一节点接收所述第二节点发送的所述第二指示信息,所述第二指示信息用于指示所述第一节点中所述D个载波对应的所述第一资源的可用资源的可用状态;The first node receives the second indication information sent by the second node, where the second indication information is used to indicate the available resources of the first resource corresponding to the D carriers in the first node Available status;所述第一节点根据所述第二指示信息确定所述D个载波对应的所述第一资源的可用资源的可用状态;Determining, by the first node, the available state of the available resource of the first resource corresponding to the D carriers according to the second indication information;所述第一节点根据所述D个载波对应的所述第一资源的可用资源的可用状态,和所述D个载波对应的所述第一资源与所述F个小区对应的所述第二资源之间的资源复用关系,确定所述F个小区对应的所述第二资源的动态资源的可用状态。According to the available state of the available resources of the first resource corresponding to the D carriers, the first node corresponds to the first resource corresponding to the D carriers and the second resource corresponding to the F cells. The resource reuse relationship between resources determines the available status of the dynamic resources of the second resources corresponding to the F cells.
- 如权利要求1或2所述的方法,其特征在于,所述方法还包括:The method according to claim 1 or 2, wherein the method further comprises:所述第一节点接收所述第二节点发送的所述第二指示信息,所述第二指示信息用于指示所述第一节点中所述F个小区对应的所述第二资源的动态资源的可用状态;The first node receives the second indication information sent by the second node, where the second indication information is used to indicate the dynamic resources of the second resources corresponding to the F cells in the first node Available status;所述第一节点根据所述第二指示信息确定所述F个小区对应的所述第二资源的动态资源的可用状态;Determining, by the first node, the available status of the dynamic resource of the second resource corresponding to the F cells according to the second indication information;所述第一节点根据所述F个小区对应的所述第二资源的动态资源的可用状态,和所述D个载波对应的所述第一资源与所述F个小区对应的所述第二资源之间的所述资源复用关系,确定所述D个载波对应的所述第一资源的可用资源的可用状态。According to the availability status of the dynamic resources of the second resources corresponding to the F cells, the first node and the first resources corresponding to the D carriers and the second resources corresponding to the F cells The resource reuse relationship between resources determines the available state of the available resources of the first resource corresponding to the D carriers.
- 如权利要求1-3中任一项所述的方法,其特征在于,所述第二节点为所述第一节点的上级节点;所述第一资源为所述第一节点与所述第二节点通信的传输资源,所述第二资源为所述第一节点与第三节点通信的传输资源,所述第三节点为所述第一节点的下级节点。The method according to any one of claims 1-3, wherein the second node is an upper-level node of the first node; and the first resource is the first node and the second node A transmission resource for node communication, the second resource is a transmission resource for communication between the first node and a third node, and the third node is a subordinate node of the first node.
- 如权利要求1-4中任一项所述的方法,其特征在于,所述第一资源的可用资源为所述第一资源经过所述半静态资源配置后确定的可用资源。The method according to any one of claims 1 to 4, wherein the available resource of the first resource is an available resource determined by the first resource after the semi-static resource configuration.
- 如权利要求1-5中任一项所述的方法,其特征在于,所述第二资源的动态资源为所述第二资源经过所述半静态资源配置后确定的动态资源。The method according to any one of claims 1 to 5, wherein the dynamic resource of the second resource is a dynamic resource determined after the second resource is configured through the semi-static resource.
- 如权利要求1-6中任一项所述的方法,其特征在于,所述D个载波对应的所述第一资源与所述F个小区对应的所述第二资源之间的所述资源复用关系至少包括以下一种:The method according to any one of claims 1-6, wherein the resources between the first resources corresponding to the D carriers and the second resources corresponding to the F cells The reuse relationship includes at least one of the following:时分复用、半双工频分复用、半双工空分复用、全双工、动态自适应频分复用、动态自适应空分复用、动态自适应全双工。Time division multiplexing, half duplex frequency division multiplexing, half duplex space division multiplexing, full duplex, dynamic adaptive frequency division multiplexing, dynamic adaptive space division multiplexing, dynamic adaptive full duplex.
- 如权利要求2所述的方法,其特征在于,所述第二指示信息的指示范围包括以下至少 一种:The method according to claim 2, wherein the indication range of the second indication information includes at least one of the following:所述半静态资源配置确定的所述第一资源的可用资源;Available resources of the first resource determined by the semi-static resource configuration;所述F个小区中由指定的G个小区确定的与所述G个小区具有所述资源复用关系的第一待指示资源集合;A first set of to-be-indicated resources that are determined by the designated G cells and have the resource reuse relationship with the G cells among the F cells;所述第二节点或所述宿主节点指示的第一资源中的部分资源组成的第二待指示资源集合;A second resource set to be indicated consisting of part of the first resources indicated by the second node or the host node;所述第二节点或所述宿主节点指示的第一资源中的全部资源组成的第三待指示资源集合。A third resource set to be indicated consisting of all resources in the first resource indicated by the second node or the host node.
- 如权利要求1-8中任一项所述的方法,其特征在于,所述第二指示信息包含所述D个载波的标识和/或所述F个小区的标识。The method according to any one of claims 1-8, wherein the second indication information includes the identities of the D carriers and/or the identities of the F cells.
- 如权利要求1-9中任一项所述的方法,其特征在于,所述第二指示信息为下行控制信息DCI。The method according to any one of claims 1-9, wherein the second indication information is downlink control information DCI.
- 如前述权利要求1-10所述的方法,其特征在于,所述下行控制信息DCI还包括以下至少一种信息:控制资源集信息、搜索空间集合信息、指示时延信息、指示范围信息。The method according to claim 1-10, wherein the downlink control information DCI further includes at least one of the following information: control resource set information, search space set information, indication delay information, indication range information.
- 一种中继装置,其特征在于,包括:A relay device, characterized in that it comprises:收发单元,用于接收第二节点或宿主节点发送的第一指示信息,所述第一指示信息用于指示所述第一节点中D个载波对应的第一资源和F个小区对应的第二资源的半静态资源配置,其中,D≥1,F≥1;The transceiver unit is configured to receive first indication information sent by a second node or a donor node, where the first indication information is used to indicate first resources corresponding to D carriers and second resources corresponding to F cells in the first node Semi-static resource allocation of resources, where D≥1, F≥1;所述收发单元还用于,接收所述第二节点发送的第二指示信息,所述第二指示信息用于指示所述第一节点中所述D个载波对应的所述第一资源的可用资源的可用状态和所述F个小区对应的所述第二资源的动态资源的可用状态;The transceiver unit is further configured to receive second indication information sent by the second node, where the second indication information is used to indicate the availability of the first resource corresponding to the D carriers in the first node The available state of the resource and the available state of the dynamic resource of the second resource corresponding to the F cells;处理单元,用于根据所述第一指示信息确定所述D个载波对应的第一资源和所述F个小区对应的第二资源的半静态资源配置;A processing unit, configured to determine a semi-static resource configuration of the first resource corresponding to the D carriers and the second resource corresponding to the F cells according to the first indication information;所述处理单元还用于,根据所述第二指示信息确定所述D个载波对应的所述第一资源的可用资源的可用状态和所述F个小区对应的所述第二资源的动态资源的可用状态。The processing unit is further configured to determine, according to the second indication information, the available status of the available resources of the first resources corresponding to the D carriers and the dynamic resources of the second resources corresponding to the F cells Available status.
- 如权利要求12所述的方法,其特征在于,The method of claim 12, wherein:所述收发单元还用于,接收所述第二节点发送的第二指示信息,所述第二指示信息用于指示所述第一节点中所述D个载波对应的所述第一资源的可用资源的可用状态;The transceiver unit is further configured to receive second indication information sent by the second node, where the second indication information is used to indicate the availability of the first resource corresponding to the D carriers in the first node The available status of the resource;所述处理单元还用于,根据所述第二指示信息确定所述D个载波对应的所述第一资源的可用资源的可用状态;The processing unit is further configured to determine, according to the second indication information, the available state of the available resource of the first resource corresponding to the D carriers;所述处理单元还用于,根据所述D个载波对应的所述第一资源的可用资源的可用状态,和所述D个载波对应的所述第一资源与所述F个小区对应的所述第二资源之间的资源复用关系,确定所述F个小区对应的所述第二资源的动态资源的可用状态。The processing unit is further configured to, according to the available state of the available resources of the first resources corresponding to the D carriers, and all the first resources corresponding to the D carriers and the F cells corresponding to the available states The resource reuse relationship between the second resources determines the available status of the dynamic resources of the second resources corresponding to the F cells.
- 如权利要求12或13所述的方法,其特征在于,The method of claim 12 or 13, wherein:所述收发单元还用于,接收所述第二节点发送的所述第二指示信息,所述第二指示信息用于指示所述第一节点中所述F个小区对应的所述第二资源的动态资源的可用状态;The transceiver unit is further configured to receive the second indication information sent by the second node, where the second indication information is used to indicate the second resource corresponding to the F cells in the first node The available status of the dynamic resources;所述处理单元还用于,根据所述第二指示信息确定所述F个小区对应的所述第二资源的动态资源的可用状态;The processing unit is further configured to determine the available state of the dynamic resource of the second resource corresponding to the F cells according to the second indication information;所述处理单元还用于,根据所述F个小区对应的所述第二资源的动态资源的可用状态,和所述D个载波对应的所述第一资源与所述F个小区对应的所述第二资源之间的所述资源复用关系,确定所述D个载波对应的所述第一资源的可用资源的可用状态。The processing unit is further configured to, according to the available status of the dynamic resources of the second resources corresponding to the F cells, and all the first resources corresponding to the D carriers and all the F cells corresponding to the F cells. The resource reuse relationship between the second resources determines the available state of the available resources of the first resource corresponding to the D carriers.
- 如权利要求12-14中任一项所述的方法,其特征在于,所述第二节点为所述中继装 置的上级节点;所述第一资源为所述中继装置与所述第二节点通信的传输资源,所述第二资源为所述中继装置与第三节点通信的传输资源,所述第三节点为所述中继装置的下级节点。The method according to any one of claims 12-14, wherein the second node is an upper-level node of the relay device; and the first resource is the relay device and the second A transmission resource for node communication, the second resource is a transmission resource for the relay device to communicate with a third node, and the third node is a subordinate node of the relay device.
- 如权利要求12-15中任一项所述的方法,其特征在于,所述第一资源的可用资源为所述第一资源经过所述半静态资源配置后确定的可用资源。The method according to any one of claims 12-15, wherein the available resource of the first resource is an available resource determined by the first resource after the semi-static resource configuration.
- 如权利要求12-16中任一项所述的方法,其特征在于,所述第二资源的动态资源为所述第二资源经过所述半静态资源配置后确定的动态资源。The method according to any one of claims 12-16, wherein the dynamic resource of the second resource is a dynamic resource determined after the second resource is configured through the semi-static resource.
- 如权利要求12-17中任一项所述的方法,其特征在于,所述D个载波对应的所述第一资源与所述F个小区对应的所述第二资源之间的所述资源复用关系至少包括以下一种:The method according to any one of claims 12-17, wherein the resources between the first resources corresponding to the D carriers and the second resources corresponding to the F cells The reuse relationship includes at least one of the following:时分复用、半双工频分复用、半双工空分复用、全双工、动态自适应频分复用、动态自适应空分复用、动态自适应全双工。Time division multiplexing, half duplex frequency division multiplexing, half duplex space division multiplexing, full duplex, dynamic adaptive frequency division multiplexing, dynamic adaptive space division multiplexing, dynamic adaptive full duplex.
- 一种计算机可读存储介质,其特征在于,所述计算机可读存储介质存储有计算机指令,当所述计算机指令在计算机上运行时,使得所述计算机执行如权利要求1-11中任一项所述的方法。A computer-readable storage medium, wherein the computer-readable storage medium stores computer instructions, and when the computer instructions run on a computer, the computer executes any one of claims 1-11. The method described.
- 一种芯片,其特征在于,包括存储器和处理器,所述存储器用于存储计算机程序,所述处理器用于从读取并执行所述存储器中存储的计算机程序,以执行如权利要求1-11中任一项所述的方法。A chip, characterized by comprising a memory and a processor, the memory is used to store a computer program, and the processor is used to read and execute the computer program stored in the memory to execute as claimed in claims 1-11 The method of any one of.
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Publication number | Priority date | Publication date | Assignee | Title |
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Non-Patent Citations (5)
Title |
---|
ERICSSON: "IAB resource configuration and multiplexing", 3GPP DRAFT; R1-1909026, 3RD GENERATION PARTNERSHIP PROJECT (3GPP), MOBILE COMPETENCE CENTRE ; 650, ROUTE DES LUCIOLES ; F-06921 SOPHIA-ANTIPOLIS CEDEX ; FRANCE, vol. RAN WG1, no. Prague, CZ; 20190826 - 20190830, 16 August 2019 (2019-08-16), Mobile Competence Centre ; 650, route des Lucioles ; F-06921 Sophia-Antipolis Cedex ; France, XP051765630 * |
HUAWEI, HISILICON: "Resource multiplexing between backhaul and access in IAB", 3GPP DRAFT; R1-1908036, 3RD GENERATION PARTNERSHIP PROJECT (3GPP), MOBILE COMPETENCE CENTRE ; 650, ROUTE DES LUCIOLES ; F-06921 SOPHIA-ANTIPOLIS CEDEX ; FRANCE, vol. RAN WG1, no. Prague, Czech Republic; 20190826 - 20190830, 17 August 2019 (2019-08-17), Mobile Competence Centre ; 650, route des Lucioles ; F-06921 Sophia-Antipolis Cedex ; France, XP051764659 * |
HUAWEI, HISILICON: "Resource multiplexing between backhaul and access in IAB", 3GPP DRAFT; R1-1910051, 3RD GENERATION PARTNERSHIP PROJECT (3GPP), MOBILE COMPETENCE CENTRE ; 650, ROUTE DES LUCIOLES ; F-06921 SOPHIA-ANTIPOLIS CEDEX ; FRANCE, vol. RAN WG1, no. Chongqing, China; 20191014 - 20191020, 5 October 2019 (2019-10-05), Mobile Competence Centre ; 650, route des Lucioles ; F-06921 Sophia-Antipolis Cedex ; France, XP051788858 * |
LG ELECTRONICS: "Discussions on resource multiplexing among backhaul and access links", 3GPP DRAFT; R1-1908694 DISCUSSIONS ON RESOURCE MULTIPLEXING AMONG BACKHAUL AND ACCESS LINKS_V3, 3RD GENERATION PARTNERSHIP PROJECT (3GPP), MOBILE COMPETENCE CENTRE ; 650, ROUTE DES LUCIOLES ; F-06921 SOPHIA-ANTIPOLIS CEDEX ; FRANCE, vol. RAN WG1, no. Prague, CZ; 20190826 - 20190830, 17 August 2019 (2019-08-17), Mobile Competence Centre ; 650, route des Lucioles ; F-06921 Sophia-Antipolis Cedex ; France, XP051765302 * |
NOKIA, NOKIA SHANGHAI BELL: "Mechanisms for resource multiplexing among backhaul and access links", 3GPP DRAFT; R1-1907116_IAB RESOURCE ALLOCATION, 3RD GENERATION PARTNERSHIP PROJECT (3GPP), MOBILE COMPETENCE CENTRE ; 650, ROUTE DES LUCIOLES ; F-06921 SOPHIA-ANTIPOLIS CEDEX ; FRANCE, vol. RAN WG1, no. Reno, NV, USA; 20190513 - 20190517, 3 May 2019 (2019-05-03), Mobile Competence Centre ; 650, route des Lucioles ; F-06921 Sophia-Antipolis Cedex ; France, XP051709145 * |
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