WO2019095227A1 - 数据复制传输的控制方法、用户设备、主节点及辅助节点 - Google Patents

数据复制传输的控制方法、用户设备、主节点及辅助节点 Download PDF

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Publication number
WO2019095227A1
WO2019095227A1 PCT/CN2017/111418 CN2017111418W WO2019095227A1 WO 2019095227 A1 WO2019095227 A1 WO 2019095227A1 CN 2017111418 W CN2017111418 W CN 2017111418W WO 2019095227 A1 WO2019095227 A1 WO 2019095227A1
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WIPO (PCT)
Prior art keywords
drb
control information
node
data
bearer
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PCT/CN2017/111418
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English (en)
French (fr)
Inventor
唐海
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Oppo广东移动通信有限公司
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Publication date
Application filed by Oppo广东移动通信有限公司 filed Critical Oppo广东移动通信有限公司
Priority to PCT/CN2018/071819 priority Critical patent/WO2019095538A1/zh
Priority to CN202010256281.2A priority patent/CN111585714B/zh
Priority to JP2020526949A priority patent/JP2021503244A/ja
Priority to KR1020207016015A priority patent/KR20200086306A/ko
Priority to RU2020119163A priority patent/RU2760908C1/ru
Priority to EP18877482.2A priority patent/EP3700288B1/en
Priority to BR112020009657-1A priority patent/BR112020009657A2/pt
Priority to CN201880055812.2A priority patent/CN111052853B/zh
Priority to AU2018367159A priority patent/AU2018367159A1/en
Priority to CA3082722A priority patent/CA3082722A1/en
Priority to PCT/CN2018/084509 priority patent/WO2019095635A1/zh
Publication of WO2019095227A1 publication Critical patent/WO2019095227A1/zh
Priority to US15/930,695 priority patent/US11470504B2/en

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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W28/00Network traffic management; Network resource management
    • H04W28/02Traffic management, e.g. flow control or congestion control
    • H04W28/06Optimizing the usage of the radio link, e.g. header compression, information sizing, discarding information
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L1/00Arrangements for detecting or preventing errors in the information received
    • H04L1/08Arrangements for detecting or preventing errors in the information received by repeating transmission, e.g. Verdan system
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L1/00Arrangements for detecting or preventing errors in the information received
    • H04L1/12Arrangements for detecting or preventing errors in the information received by using return channel
    • H04L1/16Arrangements for detecting or preventing errors in the information received by using return channel in which the return channel carries supervisory signals, e.g. repetition request signals
    • H04L1/18Automatic repetition systems, e.g. Van Duuren systems
    • H04L1/1809Selective-repeat protocols
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L1/00Arrangements for detecting or preventing errors in the information received
    • H04L1/12Arrangements for detecting or preventing errors in the information received by using return channel
    • H04L1/16Arrangements for detecting or preventing errors in the information received by using return channel in which the return channel carries supervisory signals, e.g. repetition request signals
    • H04L1/1607Details of the supervisory signal
    • H04L1/1614Details of the supervisory signal using bitmaps
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L1/00Arrangements for detecting or preventing errors in the information received
    • H04L1/12Arrangements for detecting or preventing errors in the information received by using return channel
    • H04L1/16Arrangements for detecting or preventing errors in the information received by using return channel in which the return channel carries supervisory signals, e.g. repetition request signals
    • H04L1/18Automatic repetition systems, e.g. Van Duuren systems
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W28/00Network traffic management; Network resource management
    • H04W28/02Traffic management, e.g. flow control or congestion control
    • H04W28/0252Traffic management, e.g. flow control or congestion control per individual bearer or channel
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W28/00Network traffic management; Network resource management
    • H04W28/02Traffic management, e.g. flow control or congestion control
    • H04W28/0252Traffic management, e.g. flow control or congestion control per individual bearer or channel
    • H04W28/0257Traffic management, e.g. flow control or congestion control per individual bearer or channel the individual bearer or channel having a maximum bit rate or a bit rate guarantee
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W28/00Network traffic management; Network resource management
    • H04W28/02Traffic management, e.g. flow control or congestion control
    • H04W28/04Error control
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W76/00Connection management
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W76/00Connection management
    • H04W76/10Connection setup
    • H04W76/11Allocation or use of connection identifiers
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W76/00Connection management
    • H04W76/10Connection setup
    • H04W76/15Setup of multiple wireless link connections
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W80/00Wireless network protocols or protocol adaptations to wireless operation
    • H04W80/08Upper layer protocols
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W80/00Wireless network protocols or protocol adaptations to wireless operation
    • H04W80/02Data link layer protocols
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W84/00Network topologies
    • H04W84/18Self-organising networks, e.g. ad-hoc networks or sensor networks
    • H04W84/20Master-slave selection or change arrangements

Definitions

  • the present invention relates to the field of communication processing technologies, and in particular, to a data copy transmission control method, a user equipment (UE), a master node, a secondary node, and a computer storage medium.
  • UE user equipment
  • the data replication transmission function of one of the bearers can be activated or deactivated dynamically by the MAC CE.
  • the MCG and the SCG may respectively send a MAC CE to activate or deactivate the copy data function of one of the split bearers of the UE.
  • the primary node of the MCG and the secondary node of the SCG can separately send control information, which requires the UE side to identify which specific control information is used to control which DRBs to ensure the processing efficiency of the UE.
  • an embodiment of the present invention provides a data copy transmission control method, a user equipment (UE), a master node, a secondary node, and a computer storage medium.
  • UE user equipment
  • the method for controlling data replication transmission provided by the embodiment of the present invention is applied to user equipment, including:
  • the embodiment of the invention provides a data copy transmission control method, which is applied to a master node, and includes:
  • the primary node controls the target UE to enable or disable a data replication function of a first partial data radio bearer in the at least one data radio bearer
  • the auxiliary node controls the target UE to be turned on or Close the data copy function of the second part of the data radio bearer in the at least one data radio bearer; wherein the first part of the data radio bearer is at least partially different from the second part of the data radio bearer;
  • An embodiment of the present invention provides a data copy transmission control method, which is applied to a secondary node, and includes:
  • the primary node controls the target UE to enable or disable a data replication function of a first partial data radio bearer DRB in the at least one data radio bearer, and the auxiliary node controls the target UE to be enabled. a data copy function of the second part of the at least one DRB radio bearer; wherein the first part DRB is at least partially different from the second part DRB;
  • An embodiment of the present invention provides a UE, including:
  • the first communication unit receives the first control information sent by the primary node, and/or receives the second control information sent by the secondary node;
  • the first processing unit determines to enable or disable at least based on the indication of the first partial data radio bearer DRB corresponding to the first control information, and/or based on the indication of the second portion DRB corresponding to the second control information A data replication transmission function of a DRB.
  • An embodiment of the present invention provides a master node, including:
  • the second communication unit in consultation with the auxiliary node, determines a data replication transmission function of turning on or off at least one data radio bearer of the target UE; and transmitting the first control information to the target UE;
  • a second processing unit determining, according to the negotiation result, that the primary node controls the target UE to enable or disable data replication function of the first partial data radio bearer in the at least one data radio bearer, and the assistant node control Determining, by the target UE, a data replication function of the second part of the data radio bearer in the at least one data radio bearer; wherein the first part of the data radio bearer is at least partially different from the second part of the data radio bearer; The data copy function of the first part of the data radio bearer DRB that is turned on or off generates the first control information.
  • An embodiment of the present invention provides a secondary node, including:
  • the third communication unit in consultation with the master node, determines whether to enable or disable the data copy transmission function of the at least one data radio bearer of the target UE; and send the second control information to the target UE;
  • a third processing unit determining, according to the negotiation result, that the primary node controls the target UE to enable or disable data replication function of the first partial data radio bearer DRB in the at least one data radio bearer, and the assistant node control Transmitting, by the target UE, a data replication function of a second partial data radio bearer in the at least one DRB; wherein the first partial DRB is at least partially different from the second partial DRB;
  • the data replication function of the two-part DRB generates second control information.
  • An embodiment of the present invention provides a UE, including: a processor and a storage device capable of being stored on the processor The memory of the running computer program,
  • processor is configured to perform the steps of the foregoing method when the computer program is run.
  • An embodiment of the present invention provides a master node, including: a processor and a memory for storing a computer program capable of running on the processor,
  • processor is configured to perform the steps of the foregoing method when the computer program is run.
  • An embodiment of the present invention provides a secondary node, including: a processor and a memory for storing a computer program capable of running on the processor,
  • processor is configured to perform the steps of the foregoing method when the computer program is run.
  • a computer storage medium is provided by the embodiment of the present invention.
  • the computer storage medium stores computer executable instructions, and the foregoing method steps are implemented when the computer executable instructions are executed.
  • the technical solution of the embodiment of the present invention enables the UE side to determine whether to enable or disable the data transmission replication of at least one DRB of the DRB according to the first control information and/or the second control information sent by the primary node and/or the secondary node.
  • the UE can determine, after receiving the control information sent by the two nodes, determine which DRB data transmission replication functions are specifically enabled, and ensure the processing efficiency of the UE.
  • FIG. 1 is a schematic flowchart 1 of a method for controlling data copy transmission according to an embodiment of the present invention
  • FIG. 2 is a schematic flowchart 2 of a method for controlling data copy transmission according to an embodiment of the present invention
  • FIG. 3 is a schematic flowchart 3 of a method for controlling data copy transmission according to an embodiment of the present invention
  • FIG. 4 is a schematic structural diagram of a user equipment according to an embodiment of the present invention.
  • FIG. 5 is a schematic structural diagram of a protocol layer according to an embodiment of the present invention.
  • FIG. 6 is a schematic structural diagram of a main node according to an embodiment of the present invention.
  • FIG. 7 is a schematic structural diagram of a secondary node according to an embodiment of the present invention.
  • FIG. 8 is a schematic diagram of a hardware architecture according to an embodiment of the present invention.
  • An embodiment of the present invention provides a data copy transmission control method, which is applied to a user equipment UE, as shown in FIG. 1 , and includes:
  • Step 101 Receive first control information sent by the primary node, and/or receive second control information sent by the secondary node.
  • Step 102 Determine to enable or disable at least one DRB based on the indication of the first partial data radio bearer DRB corresponding to the first control information, and/or based on the indication of the second partial DRB corresponding to the second control information.
  • Data replication transfer function Determine to enable or disable at least one DRB based on the indication of the first partial data radio bearer DRB corresponding to the first control information, and/or based on the indication of the second partial DRB corresponding to the second control information.
  • the primary node may be a node in a primary cell group (MCG)
  • the secondary node may be a node in a secondary cell group (SCG).
  • the receiving the first control information sent by the primary node, and/or receiving the second control information sent by the secondary node includes:
  • the control information of the receiving the primary node or the secondary node may be received separately or separately.
  • the sequence of receiving the first control information and the second control information is not limited herein.
  • the primary node of the MCG on the network side and the secondary node of the SCG cooperate through the Xn interface to determine a network node that controls whether a certain DRB replication data function of the UE is enabled or disabled.
  • the first control information based on the bitmap format and the identification letter of the DRB Corresponding relationship between the information, determining the first part DRB indicated by the first control information. And/or determining a second part DRB indicated by the second control information based on a correspondence between the second control information of the bitmap format and the identification information of the DRB.
  • each bit can correspond to one DRB identification information; it is assumed that bit 1-3 can correspond to DRB1, 4, and 7, respectively, and then the remaining bite 4-8 are invalid bits. Then, through the bimap, it can be determined that the first control information indicates which DRB is turned on or off. Further, the bit transfer bit in the bitmap can be set to 0 to disable the data transfer copy function of the DRB. When the bit is 1, the data transfer copy function of the DRB can be turned on. Of course, it can be reversed, but it is not exhaustive in this embodiment.
  • bits 1-3 of the bitmap of the second control information may respectively correspond to the identifiers 1, 3, and 7 of the DRB, and the remaining bits may be invalid bits.
  • the meanings of the bit bits are the same as those of the foregoing, and will not be described again.
  • the DRB includes three types: MCG bearer, SCG bearer and Split bearer; the MAC CE sent by the MN is responsible for controlling the opening or closing of the data copy function of the MCG bearer and the split bearer; the MAC CE sent by the SN is responsible for controlling the SCG bearer and the split bearer.
  • the data copy function is turned on or off.
  • step 102 determining, according to the indication of the first partial data radio bearer DRB corresponding to the first control information, and/or determining, according to the indication of the second partial DRB corresponding to the second control information, that at least one is turned on or off.
  • DRB data replication transmission function When operating, there are three factors that can be considered to control:
  • the first DRB corresponding to the first control information includes the first DRB that is the primary cell bearer, determining to enable or disable the data replication transmission function of the first DRB based on the indication of the first control information . And/or, when the second DRB that is the secondary cell bearer is included in the second part DRB corresponding to the second control information, determining that the second control is based
  • the indication of the information turns on or off the data replication transmission function of the second DRB.
  • first DRB is not included in the second part DRB.
  • second DRB is not included in the first part DRB.
  • the non-forked bearer (for example, the MCG bearer (first DRB) and the SCG bearer (second DRB)) is not controlled by the peer end, for example, the MCG bearer controls the MCG bearer, and the SCG MAC CE controls. SCG bearer.
  • first DRB and the second DRB is not limited in this embodiment. In practice, one or more first DRBs and second DRBs may exist, and the number of the two may be different.
  • the first part of the DRB corresponding to the first control information includes the third DRB as the bifurcation bearer, and/or the second part of the DRB corresponding to the second control information includes the bifurcation When carrying the third DRB,
  • the data copy transmission function of the third DRB is determined to be turned on or off based on a preset condition.
  • the bifurcation bearer that is, the third DRB may be a split bearer, and the third DRB may be controlled by the MCG or the SCG.
  • the specific preset conditions may include at least one of the following:
  • Condition 1 based on the group of PDCPs of the third DRB, determining control information sent by the node corresponding to the group to control whether to enable or disable the data replication transmission function of the third DRB.
  • the method for determining the group of the PDCPs in the third DRB may be determined according to the key value of the third DRB, that is, the key value corresponding to the third DRB is obtained, based on the third DRB corresponding to the third DRB.
  • the key value determines the group in which the PDCP of the third SRB is located.
  • the MCG MAC CE controls the split bearer.
  • the UE can distinguish the split bearer by the difference of the key value (Key) of the split bearer.
  • the PDCP is in the MCG or SCG.
  • the different groups may have different key values, and the setting may be determined by the network side and the UE side in advance.
  • the key value may be KeNB.
  • S-KgNB by identifying the two key values, the UE can distinguish the PDCP in the MCG or the SCG; specifically, the KeNB can be the Key of the corresponding MCG, and the S-KgNB can be the Key of the corresponding SCG.
  • Condition 2 based on the default transmission path corresponding to the third DRB, determining control information corresponding to the control node other than the default transmission path to control whether to enable or disable the data replication transmission function of the third DRB.
  • the default transmission path is a path adopted when the duplicate data transmission function is in a deactivated state.
  • the non default leg of a split bearer refers to the path of the default transmission after duplication deactivated. It can be a node corresponding to non default leg to control duplication.
  • Condition 3 Determine, according to the PDCP version of the third DRB, control information sent by a node corresponding to the PDCP version to control whether to enable or disable the data replication transmission function of the third DRB.
  • the PDCP version of the third DRB is one of the following: a version of the LTE PDCP, and an NR PDCP version.
  • the version of the PDCP of the split bearer is determined.
  • the MAC on the LTE side can only control the split bearer of the LTE PDCP
  • the MAC on the NR side can only control the split bearer whose PDCP is the NR PDCP.
  • the correspondence between the DRB and the MAC CE bitmap corresponds to the ascending or descending order of the DRB ID
  • the DRB IDs 1, 3, 4, and 7 of the UE respectively have a PDCP copy data transmission function; wherein the DRB ID 1 is an MCG bearer, the DRB ID 3 is an SCG bearer, and the DRB IDs 4 and 7 are split bearers;
  • the network side MCG and the SCG cooperate to determine that the DRB IDs 1, 4, and 7 respectively correspond to 1, 2, and 3 bits in the MAC CE bitmap sent by the MN, and the remaining 4, 5, 6, 7, and 8 bits are invalid bits;
  • DRB IDs 3, 4, and 7 respectively correspond to 1, 2, and 3 bits in the MAC CE bitmap sent by the SN, and the remaining 4, 5, 6, 7, and 8 bits are invalid bits.
  • the first control information and/or the second control information sent by the MAC layer of the UE, the receiving network (which may be the primary node in the MCG or the secondary node in the SCG), enables or disables the replication data transmission of the at least one DRB.
  • the MAC layer of the UE indicates the corresponding bit of the received copy data control MAC address to the PDCP layer of the corresponding DRB;
  • the MAC layer of the UE finds the corresponding bit of the DRB ID in the bitmap according to the mapping between the bitmap and the DRB ID.
  • the DRB ID of the UE is 1, 4, and 7 respectively correspond to 1, 2, and 3 bits in the bitmap of the MN MAC CE.
  • the MAC CE After receiving the MAC CE bitmap, the MAC CE indicates the first bit value to the PDCP with the DRB ID being 1, the second bit value to the PDCP with the DRB ID being 3, and so on.
  • the foregoing processing manner in this embodiment is to determine, according to the relationship between the DRB and the control information, which control information the DRB corresponds to after receiving the control information, for example, and when a DRB receives the first control information and the first When controlling information, how to decide which control information to use for subsequent processing.
  • this embodiment may also provide another processing manner, that is, determine which DRB to obtain which control information according to the preset rule in advance; that is, in this processing mode, the network side may send only one control for one DRB.
  • Information the specific treatment is as follows:
  • each of the at least one DRB of the UE corresponds to the first control information or the second control information according to the preset rule.
  • the identification information of different DRBs corresponds to which bit of the first control information or the second control information.
  • the preset rule includes at least one of the following:
  • the DRB is included in the first part of the DRB corresponding to the first control information
  • the DRB is included in the second part DRB corresponding to the second control information.
  • the identifier information of the DRB corresponds to the first bit in the first control information; and when a DRB is carried by the secondary cell, the identifier of the DRB
  • the information corresponds to the second bit in the second control information.
  • the first bit and the second bit do not represent the specific bit in the control information, and the first bit is located in the second bit.
  • the first bit can be the first control information.
  • the bit 3 and the second bit may be bit 1 in the second control information.
  • the DRB when the DRB is a primary cell bearer, it does not correspond to the second control information, and is not included in the second partial DRB.
  • the DRB When the DRB is the secondary cell bearer, it does not correspond to the first control information. Not included in the first part of the DRB.
  • the preset rule further includes at least one of the following:
  • the DRB is a bifurcated bearer, based on the group of the PDCP in which the DRB is located, determining the DRB of the control information sent by the node corresponding to the group in which the PDCP is located is controlled; it is understood that the node here may be the master node.
  • the control node may be the first control information or the second control information.
  • the DRB When the DRB is a forked bearer, it is determined based on a default transmission path corresponding to the DRB.
  • the control information sent by the node other than the default transmission path controls the DRB; it is understood that the node may be a secondary node, and the control information may be the first control information or the first One of the two control information;
  • the DRB is a forked bearer, determining, according to the PDCP version of the DRB, control information sent by a node corresponding to the PDCP version to control the DRB; it is understood that the node may be a master node.
  • the control information may be one of the first control information and the second control information.
  • the DRB is a forked bearer, based on the group of the PDCP in which the DRB is located, it is determined that the control information sent by the node corresponding to the group not in the DRB cannot control the DRB.
  • the DRB is a forked bearer, based on the default transmission path corresponding to the DRB, it is determined that the control information sent by the node of the default transmission path cannot control the DRB.
  • the DRB is a forked bearer
  • the control information sent by the node that does not correspond to the PDCP version cannot control the DRB.
  • the UE side can determine whether to enable or disable the data transmission replication function of at least one DRB of the DRB according to the first control information and/or the second control information sent by the primary node and/or the secondary node. .
  • the UE can determine, after receiving the control information sent by the two nodes, determine which DRB data transmission replication functions are specifically enabled, and ensure the processing efficiency of the UE.
  • the embodiment of the present invention provides a data copy transmission control method, which is applied to a master node, as shown in FIG. 2, and includes:
  • Step 201 Negotiate with the auxiliary node to determine whether to enable or disable the data replication transmission function of the at least one data radio bearer of the target UE.
  • Step 202 Determine, according to the negotiation result, that the primary node controls the target UE to enable or disable data replication of the first partial data radio bearer in the at least one data radio bearer. a function, and the secondary node controls the target UE to enable or disable a data replication function of a second partial data radio bearer in the at least one data radio bearer; wherein the first portion of data is wirelessly carried in the second portion
  • the data radio bearer is at least partially different;
  • Step 203 Generate first control information, and send the first control information to the target UE, based on determining a data replication function of the first part of the data radio bearer DRB that is enabled or disabled.
  • the primary node may be a node in a primary cell group (MCG)
  • the secondary node may be a node in a secondary cell group (SCG).
  • the primary node of the MCG on the network side and the secondary node of the SCG may negotiate through the Xn interface to determine whether one or more DRB replication data functions for controlling the UE are turned on or off.
  • the generating, by the data replication function of the first part of the DRB that is determined to be turned on or off, generating the first control information includes:
  • the first control information is generated by setting a data bit corresponding to the identification information of the first part DRB in the bitmap.
  • each bit can correspond to one DRB identification information; it is assumed that bit 1-3 can correspond to DRB1, 4, and 7, respectively, and then the remaining bite 4-8 are invalid bits. Then, through the bimap, it can be determined that the first control information indicates which DRB is turned on or off. Further, the bit transfer bit in the bitmap can be set to 0 to disable the data transfer copy function of the DRB. When the bit is 1, the data transfer copy function of the DRB can be turned on. Of course, it can be reversed, but it is not exhaustive in this embodiment.
  • bits 1-3 of the bitmap of the second control information may respectively correspond to the identifier of the DRB. 3, 7, the remaining bits can be invalid.
  • the meanings of the bit bits are the same as those of the foregoing, and will not be described again.
  • the DRB includes three types: MCG bearer, SCG bearer and Split bearer; the MAC CE sent by the MN is responsible for controlling the opening or closing of the data copy function of the MCG bearer and the split bearer; the MAC CE sent by the SN is responsible for controlling the SCG bearer and the split bearer.
  • the data copy function is turned on or off.
  • the negotiation between the primary node and the secondary node may include:
  • the target DRB is the primary cell bearer, it is determined that the primary node controls it by using the first control information; the target DRB may be understood as any one of the multiple DRBs of the UE;
  • the target DRB is the secondary cell bearer, it is determined that the secondary node controls it by using the second control information; the target DRB may be understood as any one of the multiple DRBs of the UE;
  • the node is determined to be a master node or a secondary node, and it is determined that the master node or the secondary node generates control information to control the opening of the data replication function of the target DRB. Or close. That is to say, according to the group of the PDCP in which the DRB is located, it is determined whether the control information corresponding to the DRB is the first control information sent by the primary node or the second control information sent by the secondary node.
  • the target DRB When the target DRB is used as a forked bearer, determining, based on the default transmission path corresponding to the target DRB, generating control information by the primary node or the secondary node other than the default transmission path to control whether to open or close the third DRB. Data copy transfer function. That is to say, according to the default transmission path corresponding to the DRB, it is determined whether the control information corresponding to the DRB is the first control information sent by the primary node or the second control information sent by the secondary node.
  • Data replication transfer function That is, according to the PDCP version of the DRB, determining that the control information corresponding to the DRB is sent by the primary node A control message or a second control message sent by the secondary node.
  • the correspondence between the DRB and the MAC CE bitmap corresponds to the ascending or descending order of the DRB ID
  • the DRB IDs 1, 3, 4, and 7 of the UE respectively have a PDCP copy data transmission function; wherein the DRB ID 1 is an MCG bearer, the DRB ID 3 is an SCG bearer, and the DRB IDs 4 and 7 are split bearers;
  • the network side MCG and the SCG cooperate to determine that the DRB IDs 1, 4, and 7 respectively correspond to 1, 2, and 3 bits in the MAC CE bitmap sent by the MN, and the remaining 4, 5, 6, 7, and 8 bits are invalid bits;
  • DRB IDs 3, 4, and 7 respectively correspond to 1, 2, and 3 bits in the MAC CE bitmap sent by the SN, and the remaining 4, 5, 6, 7, and 8 bits are invalid bits.
  • the UE side can determine whether to enable or disable the data transmission replication function of at least one DRB of the DRB according to the first control information and/or the second control information sent by the primary node and/or the secondary node. .
  • the UE can determine, after receiving the control information sent by the two nodes, determine which DRB data transmission replication functions are specifically enabled, and ensure the processing efficiency of the UE.
  • An embodiment of the present invention provides a data copy transmission control method, which is applied to a secondary node, as shown in FIG. 3, and includes:
  • Step 301 Negotiate with the primary node to determine whether to enable or disable the data replication transmission function of the at least one data radio bearer of the target UE.
  • Step 302 Determine, according to the negotiation result, that the primary node controls the target UE to enable or disable data replication function of the first partial data radio bearer DRB in the at least one data radio bearer, and the assistant node controls the The target UE enables or disables a data replication function of the second partial data radio bearer in the at least one DRB; wherein the first partial DRB is at least partially different from the second partial DRB;
  • Step 303 Generate second control information, and send the second control information to the target UE, based on determining a data replication function of the second part of the DRB that is turned on or off.
  • the primary node may be a node in a primary cell group (MCG)
  • the secondary node may be a node in a secondary cell group (SCG).
  • the primary node of the MCG on the network side and the secondary node of the SCG may negotiate through the Xn interface to determine whether one or more DRB replication data functions for controlling the UE are turned on or off.
  • the generating the second control information includes:
  • the second control information is generated by setting data bits corresponding to the identification information of the second portion DRB in the bitmap.
  • each bit can correspond to one DRB identification information; it is assumed that bit 1-3 can correspond to DRB1, 4, and 7, respectively, and then the remaining bite 4-8 are invalid bits. Then, through the bimap, it can be determined that the first control information indicates which DRB is turned on or off. Further, the bit transfer bit in the bitmap can be set to 0 to disable the data transfer copy function of the DRB. When the bit is 1, the data transfer copy function of the DRB can be turned on. Of course, it can be reversed, but it is not exhaustive in this embodiment.
  • bits 1-3 of the bitmap of the second control information may respectively correspond to the identifiers 1, 3, and 7 of the DRB, and the remaining bits may be invalid bits.
  • the meanings of the bit bits are the same as those of the foregoing, and will not be described again.
  • the DRB includes three types: MCG bearer, SCG bearer and Split bearer; the MAC CE sent by the MN is responsible for controlling the opening or closing of the data copy function of the MCG bearer and the split bearer; the MAC CE sent by the SN is responsible for controlling the SCG bearer and the split bearer.
  • the data copy function is turned on or off.
  • the negotiation between the primary node and the secondary node may include:
  • the target DRB is the primary cell bearer, it is determined that the primary node passes the first control information pair. It performs control; the target DRB can be understood as any one of multiple DRBs of the UE;
  • the target DRB is the secondary cell bearer, it is determined that the secondary node controls it by using the second control information; the target DRB may be understood as any one of the multiple DRBs of the UE;
  • the node is determined to be a master node or a secondary node, and it is determined that the master node or the secondary node generates control information to control the opening of the data replication function of the target DRB. Or close. That is to say, according to the group of the PDCP in which the DRB is located, it is determined whether the control information corresponding to the DRB is the first control information sent by the primary node or the second control information sent by the secondary node.
  • the target DRB When the target DRB is used as a forked bearer, determining, based on the default transmission path corresponding to the target DRB, generating control information by the primary node or the secondary node other than the default transmission path to control whether to open or close the third DRB. Data copy transfer function. That is to say, according to the default transmission path corresponding to the DRB, it is determined whether the control information corresponding to the DRB is the first control information sent by the primary node or the second control information sent by the secondary node.
  • Data replication transfer function That is to say, according to the PDCP version of the DRB, it is determined whether the control information corresponding to the DRB is the first control information sent by the primary node or the second control information sent by the secondary node.
  • the correspondence between the DRB and the MAC CE bitmap corresponds to the ascending or descending order of the DRB ID
  • the DRB IDs 1, 3, 4, and 7 of the UE respectively have a PDCP copy data transmission function; wherein the DRB ID 1 is an MCG bearer, the DRB ID 3 is an SCG bearer, and the DRB IDs 4 and 7 are split bearers;
  • the network side MCG and the SCG cooperate to determine that the DRB IDs 1, 4, and 7 respectively correspond to 1, 2, and 3 bits in the MAC CE bitmap sent by the MN, and the remaining 4, 5, 6, 7, and 8 bits are invalid bits;
  • DRB IDs 3, 4, and 7 respectively correspond to 1, 2, and 3 bits in the MAC CE bitmap sent by the SN, and the remaining 4, 5, 6, 7, and 8 bits are invalid bits.
  • the UE side can determine whether to enable or disable the data transmission replication function of at least one DRB of the DRB according to the first control information and/or the second control information sent by the primary node and/or the secondary node. .
  • the UE can determine, after receiving the control information sent by the two nodes, determine which DRB data transmission replication functions are specifically enabled, and ensure the processing efficiency of the UE.
  • An embodiment of the present invention provides a UE, as shown in FIG. 4, including:
  • the first communication unit 41 receives the first control information sent by the master node, and/or receives the second control information sent by the assistant node;
  • the first processing unit 42 determines, according to the indication of the first partial data radio bearer DRB corresponding to the first control information, and/or based on the indication of the second part DRB corresponding to the second control information, determining to enable or disable At least one DRB data copy transmission function.
  • the primary node may be a node in a primary cell group (MCG)
  • the secondary node may be a node in a secondary cell group (SCG).
  • the first communication unit 41 receives first control information in a bitmap format sent by the master node; and/or receives second control information in a bitmap format sent by the auxiliary node.
  • the control information of the receiving the primary node or the secondary node may be received separately or separately.
  • the sequence of receiving the first control information and the second control information is not limited herein.
  • the primary node of the MCG on the network side and the secondary node of the SCG cooperate through the Xn interface to determine a network node that controls whether a certain DRB replication data function of the UE is enabled or disabled.
  • the first part DRB indicated by the first control information is determined based on a correspondence between the first control information of the bitmap format and the identification information of the DRB. with/ Or determining a second part DRB indicated by the second control information based on a correspondence between the second control information of the bitmap format and the identification information of the DRB.
  • each bit can correspond to one DRB identification information; it is assumed that bit 1-3 can correspond to DRB1, 4, and 7, respectively, and then the remaining bite 4-8 are invalid bits. Then, through the bimap, it can be determined that the first control information indicates which DRB is turned on or off. Further, the bit transfer bit in the bitmap can be set to 0 to disable the data transfer copy function of the DRB. When the bit is 1, the data transfer copy function of the DRB can be turned on. Of course, it can be reversed, but it is not exhaustive in this embodiment.
  • bits 1-3 of the bitmap of the second control information may respectively correspond to the identifiers 1, 3, and 7 of the DRB, and the remaining bits may be invalid bits.
  • the meanings of the bit bits are the same as those of the foregoing, and will not be described again.
  • the DRB includes three types: MCG bearer, SCG bearer and Split bearer; the MAC CE sent by the MN is responsible for controlling the opening or closing of the data copy function of the MCG bearer and the split bearer; the MAC CE sent by the SN is responsible for controlling the SCG bearer and the split bearer.
  • the data copy function is turned on or off.
  • the first processing unit 42 is configured to: when the first DRB corresponding to the first control information includes the first DRB that is the primary cell bearer, determine, according to the indication of the first control information, enable or disable the first DRB data replication transmission function. And/or, when the second part of the DRB corresponding to the second control information includes the second DRB that is the secondary cell bearer, determining to enable or disable the second DRB based on the indication of the second control information Data replication transmission Features. It should be noted that the first DRB is not included in the second part DRB. And the second DRB is not included in the first part DRB.
  • the non-forked bearer (for example, the MCG bearer (first DRB) and the SCG bearer (second DRB)) is not controlled by the peer end, for example, the MCG bearer controls the MCG bearer, and the SCG MAC CE controls. SCG bearer.
  • first DRB and the second DRB is not limited in this embodiment. In practice, one or more first DRBs and second DRBs may exist, and the number of the two may be different.
  • the first processing unit 42 when the first part DRB corresponding to the first control information includes a third DRB as a bifurcation bearer, and/or, when the second control information corresponds to the second part DRB , when there is a third DRB as a forked bearer,
  • the data copy transmission function of the third DRB is determined to be turned on or off based on a preset condition.
  • the bifurcation bearer that is, the third DRB may be a split bearer, and the third DRB may be controlled by the MCG or the SCG.
  • the specific preset conditions may include at least one of the following:
  • Condition 1 based on the group of PDCPs of the third DRB, determining control information sent by the node corresponding to the group to control whether to enable or disable the data replication transmission function of the third DRB.
  • the method for determining the group of the PDCPs in the third DRB may be determined according to the key value of the third DRB, that is, the first processing unit 42 acquires the key value corresponding to the third DRB, based on the The key value corresponding to the third DRB determines the group of the PDCP of the third SRB.
  • the MCG MAC CE controls the split bearer.
  • the UE can distinguish the split bearer by the difference of the key value (Key) of the split bearer.
  • the PDCP is in the MCG or SCG.
  • Different groups may have different key values, and the setting manner may be that the network side and the UE side pre-negotiate and determine that in a dual connectivity (DC), for a split bearer, the key value may be KeNB or S.
  • the UE can be distinguished to distinguish the PDCP in the MCG or the SCG; specifically, the KeNB can be the Key of the corresponding MCG, and the S-KgNB can be the Key of the corresponding SCG.
  • Condition 2 based on the default transmission path corresponding to the third DRB, determining control information corresponding to the control node other than the default transmission path to control whether to enable or disable the data replication transmission function of the third DRB.
  • the default transmission path is a path adopted when the duplicate data transmission function is in a deactivated state.
  • the non default leg of a split bearer refers to the path of the default transmission after duplication deactivated. It can be a node corresponding to non default leg to control duplication.
  • Condition 3 Determine, according to the PDCP version of the third DRB, control information sent by a node corresponding to the PDCP version to control whether to enable or disable the data replication transmission function of the third DRB.
  • the PDCP version of the third DRB is one of the following: a version of the LTE PDCP, and an NR PDCP version.
  • the version of the PDCP of the split bearer is determined.
  • the MAC on the LTE side can only control the split bearer of the LTE PDCP
  • the MAC on the NR side can only control the split bearer whose PDCP is the NR PDCP.
  • the copy data transmission mode adopts a split bearer.
  • the protocol architecture for the uplink and downlink, the PDCP is located in a certain CG (MCG or SCG), and the CG is the anchor CG.
  • the PDCP copies the PDCP PDUs into the same two copies. For example, one is a PDCP PDU, and the other is a Duplicated PDCP PDU.
  • the two PDCPs pass through different RCGs and MACs of the CG, and reach the UE (downlink) or the base station (uplink) corresponding MAC through the air interface.
  • the RLC layer is finally aggregated to PDCP.
  • the PDCP layer detects that the two PDCPs are the same duplicate version, that is, discard one of them and submit the other to the upper layer.
  • the one that connects the two RLCs and the MACs respectively under the PDCP is called a split bearer. If the PDCP is located at the MCG, it is the MCG Split Bearer. If the PDCP is located at the SCG, it is the SCG Split Bearer. Specifically, the solution provided by this embodiment:
  • the correspondence between the DRB and the MAC CE bitmap corresponds to the ascending or descending order of the DRB ID
  • the DRB IDs 1, 3, 4, and 7 of the UE respectively have a PDCP copy data transmission function; wherein the DRB ID 1 is an MCG bearer, the DRB ID 3 is an SCG bearer, and the DRB IDs 4 and 7 are split bearers;
  • the network side MCG and the SCG cooperate to determine that the DRB IDs 1, 4, and 7 respectively correspond to 1, 2, and 3 bits in the MAC CE bitmap sent by the MN, and the remaining 4, 5, 6, 7, and 8 bits are invalid bits;
  • DRB IDs 3, 4, and 7 respectively correspond to 1, 2, and 3 bits in the MAC CE bitmap sent by the SN, and the remaining 4, 5, 6, 7, and 8 bits are invalid bits.
  • the first control information and/or the second control information sent by the MAC layer of the UE, the receiving network (which may be the primary node in the MCG or the secondary node in the SCG), enables or disables the replication data transmission of the at least one DRB.
  • the MAC layer of the UE indicates the corresponding bit of the received copy data control MAC address to the PDCP layer of the corresponding DRB;
  • the MAC layer of the UE finds the corresponding bit of the DRB ID in the bitmap according to the mapping between the bitmap and the DRB ID.
  • the DRB ID of the UE is 1, 4, and 7 respectively correspond to 1, 2, and 3 bits in the bitmap of the MN MAC CE.
  • the MAC CE After the MAC CE receives the MAC CE bitmap, it puts the first The value of the bit indicates to the PDCP with the DRB ID of 1, the value of the second bit to the PDCP with the DRB ID of 3, and so on.
  • the foregoing processing manner in this embodiment is to determine, according to the relationship between the DRB and the control information, which control information the DRB corresponds to after receiving the control information, for example, and when a DRB receives the first control information and the first When controlling information, how to decide which control information to use for subsequent processing.
  • this embodiment may also provide another processing manner, that is, determine which DRB to obtain which control information according to the preset rule in advance; that is, in this processing mode, the network side may send only one control for one DRB.
  • Information the specific treatment is as follows:
  • each of the at least one DRB corresponds to the first control information or the second control information according to the preset rule.
  • the foregoing preset rule may be a preset rule that is provided by the UE side and the node (the primary node and the secondary node) side, that is, the UE side determines, based on the preset rule, which DRB corresponds to which bit in the control information.
  • the node may also determine which DRB control information is placed in which bit according to a preset rule.
  • the identification information of different DRBs corresponds to which bit of the first control information or the second control information.
  • the preset rule includes at least one of the following:
  • the DRB is included in the first part of the DRB corresponding to the first control information
  • the DRB is included in the second part DRB corresponding to the second control information.
  • the identifier information of the DRB corresponds to the first bit in the first control information; and when a DRB is carried by the secondary cell, the identifier of the DRB
  • the information corresponds to the second bit in the second control information. among them, The first bit and the second bit do not represent the specific bit in the control information, and the first bit is located in the second bit.
  • the first bit can be the bit 3 in the first control information.
  • the second bit can be bit 1 in the second control information.
  • the DRB when the DRB is a primary cell bearer, it does not correspond to the second control information, and is not included in the second partial DRB.
  • the DRB When the DRB is the secondary cell bearer, it does not correspond to the first control information. Not included in the first part of the DRB.
  • the preset rule further includes at least one of the following:
  • the DRB is a bifurcated bearer, based on the group of the PDCP in which the DRB is located, determining the DRB of the control information sent by the node corresponding to the group in which the PDCP is located is controlled; it is understood that the node here may be the master node.
  • the control node may be the first control information or the second control information.
  • the DRB is a forked bearer, based on the default transmission path corresponding to the DRB, determining control information sent by a node other than the default transmission path controls the DRB; it is understood that the node here may
  • the primary node may be a secondary node, and the control information may be one of the first control information and the second control information;
  • the DRB is a forked bearer, determining, according to the PDCP version of the DRB, control information sent by a node corresponding to the PDCP version to control the DRB; it is understood that the node may be a master node.
  • the control information may be one of the first control information and the second control information.
  • the DRB is a forked bearer, based on the group of the PDCP in which the DRB is located, it is determined that the control information sent by the node corresponding to the group not in the DRB cannot control the DRB.
  • the DRB is a forked bearer, based on the default transmission path corresponding to the DRB, it is determined that the control information sent by the node of the default transmission path cannot control the DRB.
  • the DRB is a forked bearer
  • the control information sent by the node that does not correspond to the PDCP version cannot control the DRB.
  • the UE side can determine whether to enable or disable the data transmission replication function of at least one DRB of the DRB according to the first control information and/or the second control information sent by the primary node and/or the secondary node. .
  • the UE can determine, after receiving the control information sent by the two nodes, determine which DRB data transmission replication functions are specifically enabled, and ensure the processing efficiency of the UE.
  • An embodiment of the present invention provides a master node, as shown in FIG. 6, including:
  • the second communication unit 61 in consultation with the auxiliary node, determines a data replication transmission function of turning on or off at least one data radio bearer of the target UE; and transmitting the first control information to the target UE;
  • the second processing unit 62 determines, according to the negotiation result, that the primary node controls the target UE to enable or disable data replication function of the first partial data radio bearer in the at least one data radio bearer, and the assistant node controls
  • the target UE enables or disables a data replication function of the second part of the data radio bearer in the at least one data radio bearer; wherein the first part of the data radio bearer is at least partially different from the second part of the data radio bearer; Determining a data copy function of the first part of the data radio bearer DRB that is turned on or off, and generating first control information.
  • the primary node may be a node in a primary cell group (MCG)
  • the secondary node may be a node in a secondary cell group (SCG).
  • the primary node of the MCG on the network side and the secondary node of the SCG may negotiate through the Xn interface to determine whether one or more DRB replication data functions for controlling the UE are turned on or off.
  • the second processing unit 62 acquires the correspondence between the identification information of the DRB and the data bits of the bitmap
  • the first control information is generated by setting a data bit corresponding to the identification information of the first part DRB in the bitmap.
  • each bit can correspond to one DRB identification information; it is assumed that bit 1-3 can correspond to DRB1, 4, and 7, respectively, and then the remaining bite 4-8 are invalid bits. Then, through the bimap, it can be determined that the first control information indicates which DRB is turned on or off. Further, the bit transfer bit in the bitmap can be set to 0 to disable the data transfer copy function of the DRB. When the bit is 1, the data transfer copy function of the DRB can be turned on. Of course, it can be reversed, but it is not exhaustive in this embodiment.
  • bits 1-3 of the bitmap of the second control information may respectively correspond to the identifiers 1, 3, and 7 of the DRB, and the remaining bits may be invalid bits.
  • the meanings of the bit bits are the same as those of the foregoing, and will not be described again.
  • the DRB includes three types: MCG bearer, SCG bearer and Split bearer; the MAC CE sent by the MN is responsible for controlling the opening or closing of the data copy function of the MCG bearer and the split bearer; the MAC CE sent by the SN is responsible for controlling the SCG bearer and the split bearer.
  • the data copy function is turned on or off.
  • the negotiation between the primary node and the secondary node may include:
  • the second processing unit 62 determines that the primary DR is controlled by the primary node by using the first control information when the target DRB is the primary cell bearer; the target DRB can be understood as any one of the multiple DRBs of the UE;
  • the second processing unit 62 determines that the secondary node is controlled by the secondary node when the target DRB is the secondary cell bearer; the target DRB can be understood as any one of the multiple DRBs of the UE;
  • the second processing unit 62 when the target DRB is used as a forked bearer, based on the PDCP of the DRB
  • the node corresponding to the group is the primary node or the secondary node, and it is determined that the primary node or the secondary node generates control information to control the opening or closing of the data replication function of the target DRB. That is to say, according to the group of the PDCP in which the DRB is located, it is determined whether the control information corresponding to the DRB is the first control information sent by the primary node or the second control information sent by the secondary node.
  • a second processing unit 62 when the target DRB is used as a forked bearer, determining, according to the default transmission path corresponding to the target DRB, generating control information by the primary node or the secondary node other than the default transmission path to control on or off The data replication transmission function of the third DRB. That is to say, according to the default transmission path corresponding to the DRB, it is determined whether the control information corresponding to the DRB is the first control information sent by the primary node or the second control information sent by the secondary node.
  • a second processing unit 62 when the target DRB is used as a forked bearer, determining, according to the PDCP version of the target DRB, a master node or a secondary node corresponding to the PDCP version to generate control information to control the opening or The data replication transmission function of the third DRB is closed. That is to say, according to the PDCP version of the DRB, it is determined whether the control information corresponding to the DRB is the first control information sent by the primary node or the second control information sent by the secondary node.
  • the correspondence between the DRB and the MAC CE bitmap corresponds to the ascending or descending order of the DRB ID
  • the DRB IDs 1, 3, 4, and 7 of the UE respectively have a PDCP copy data transmission function; wherein the DRB ID 1 is an MCG bearer, the DRB ID 3 is an SCG bearer, and the DRB IDs 4 and 7 are split bearers;
  • the network side MCG and the SCG cooperate to determine that the DRB IDs 1, 4, and 7 respectively correspond to 1, 2, and 3 bits in the MAC CE bitmap sent by the MN, and the remaining 4, 5, 6, 7, and 8 bits are invalid bits;
  • DRB IDs 3, 4, and 7 respectively correspond to 1, 2, and 3 bits in the MAC CE bitmap sent by the SN, and the remaining 4, 5, 6, 7, and 8 bits are invalid bits.
  • the UE side can determine whether to enable or disable the first control information and/or the second control information sent by the primary node and/or the secondary node.
  • One less DRB data transfer replication function the UE can determine, after receiving the control information sent by the two nodes, determine which DRB data transmission replication functions are specifically enabled, and ensure the processing efficiency of the UE.
  • An embodiment of the present invention provides a secondary node, as shown in FIG. 7, including:
  • the third communication unit 71 in consultation with the master node, determines whether to enable or disable the data replication transmission function of the at least one data radio bearer of the target UE; and sends the second control information to the target UE;
  • the third processing unit 72 determines, according to the negotiation result, that the primary node controls the target UE to enable or disable the data replication function of the first partial data radio bearer DRB in the at least one data radio bearer, and the auxiliary node Controlling, by the target UE, a data replication function of a second partial data radio bearer in the at least one DRB; wherein the first partial DRB is at least partially different from the second partial DRB; based on determining to enable or disable The data replication function of the second part of the DRB generates second control information.
  • the primary node may be a node in a primary cell group (MCG)
  • the secondary node may be a node in a secondary cell group (SCG).
  • the primary node of the MCG on the network side and the secondary node of the SCG may negotiate through the Xn interface to determine whether one or more DRB replication data functions for controlling the UE are turned on or off.
  • the third processing unit 72 acquires the correspondence between the identifier information of the DRB and the data bits of the bitmap;
  • the second control information is generated by setting data bits corresponding to the identification information of the second portion DRB in the bitmap.
  • each bit can correspond to one DRB identification information; it is assumed that bit 1-3 can correspond to DRB1, 4, and 7, respectively, and then the remaining bite 4-8 are invalid bits. Then, through the bimap, it can be determined which of the first control information is indicated.
  • the DRB is turned on or off.
  • the bit transfer bit in the bitmap can be set to 0 to disable the data transfer copy function of the DRB. When the bit is 1, the data transfer copy function of the DRB can be turned on. Of course, it can be reversed, but it is not exhaustive in this embodiment.
  • bits 1-3 of the bitmap of the second control information may respectively correspond to the identifiers 1, 3, and 7 of the DRB, and the remaining bits may be invalid bits.
  • the meanings of the bit bits are the same as those of the foregoing, and will not be described again.
  • the DRB includes three types: MCG bearer, SCG bearer and Split bearer; the MAC CE sent by the MN is responsible for controlling the opening or closing of the data copy function of the MCG bearer and the split bearer; the MAC CE sent by the SN is responsible for controlling the SCG bearer and the split bearer.
  • the data copy function is turned on or off.
  • the negotiation between the primary node and the secondary node may include:
  • the third processing unit 72 determines that the primary DR is controlled by the primary node by using the first control information when the target DRB is the primary cell bearer; the target DRB can be understood as any one of the multiple DRBs of the UE;
  • the third processing unit 72 determines that the secondary node is controlled by the secondary node when the target DRB is the secondary cell bearer; the target DRB can be understood as any one of the multiple DRBs of the UE;
  • the third processing unit 72 determines, when the target DRB is a forked bearer, that the node corresponding to the group of the PDCPs of the DRB is a master node or a secondary node, and determines that the master node or the assistant node generates control information to control the target DRB.
  • the data copy function is turned on or off. That is to say, according to the group of the PDCP in which the DRB is located, it is determined whether the control information corresponding to the DRB is the first control information sent by the primary node or the second control information sent by the secondary node.
  • the third processing unit 72 determines, when the target DRB is used as a forked bearer, based on the default transmission path corresponding to the target DRB, determining that the control information is generated by the primary node or the secondary node other than the default transmission path to control the opening or closing.
  • the data replication transmission function of the third DRB and also That is to say, according to the default transmission path corresponding to the DRB, it is determined whether the control information corresponding to the DRB is the first control information sent by the primary node or the second control information sent by the secondary node.
  • a third processing unit 72 when the target DRB is used as a forked bearer, determining, according to the PDCP version of the target DRB, that the primary node or the secondary node corresponding to the PDCP version generates control information to control the opening or The data replication transmission function of the third DRB is closed. That is to say, according to the PDCP version of the DRB, it is determined whether the control information corresponding to the DRB is the first control information sent by the primary node or the second control information sent by the secondary node.
  • the correspondence between the DRB and the MAC CE bitmap corresponds to the ascending or descending order of the DRB ID
  • the DRB IDs 1, 3, 4, and 7 of the UE respectively have a PDCP copy data transmission function; wherein the DRB ID 1 is an MCG bearer, the DRB ID 3 is an SCG bearer, and the DRB IDs 4 and 7 are split bearers;
  • the network side MCG and the SCG cooperate to determine that the DRB IDs 1, 4, and 7 respectively correspond to 1, 2, and 3 bits in the MAC CE bitmap sent by the MN, and the remaining 4, 5, 6, 7, and 8 bits are invalid bits;
  • DRB IDs 3, 4, and 7 respectively correspond to 1, 2, and 3 bits in the MAC CE bitmap sent by the SN, and the remaining 4, 5, 6, 7, and 8 bits are invalid bits.
  • the UE side can determine whether to enable or disable the data transmission replication function of at least one DRB of the DRB according to the first control information and/or the second control information sent by the primary node and/or the secondary node. .
  • the UE can determine, after receiving the control information sent by the two nodes, determine which DRB data transmission replication functions are specifically enabled, and ensure the processing efficiency of the UE.
  • the embodiment of the present invention further provides a hardware composition structure of a user equipment UE or a node.
  • the method includes at least one processor 81, a memory 82, and at least one network interface 83.
  • the various components are coupled together by a bus system 84.
  • bus system 84 is used to implement connection communication between these components.
  • the bus system 84 also includes a total power supply. Line, control bus and status signal bus.
  • various buses are labeled as bus system 84 in FIG.
  • the memory 82 in the embodiments of the present invention may be a volatile memory or a non-volatile memory, or may include both volatile and non-volatile memory.
  • memory 82 stores elements, executable modules or data structures, or a subset thereof, or their extension set:
  • the processor 81 is configured to be able to process the method steps of any one of the foregoing Embodiments 1 to 3, and details are not described herein.
  • the embodiment of the present invention provides a computer storage medium, where the computer storage medium stores computer executable instructions, and when the computer executable instructions are executed, the method steps of any one of the foregoing Embodiments 1 to 3 are implemented.
  • Embodiments of the Invention may be stored in a computer readable storage medium if it is implemented in the form of a software function module and sold or used as a standalone product. Based on such understanding, the technical solution of the embodiments of the present invention may be embodied in the form of a software product in essence or in the form of a software product stored in a storage medium, including a plurality of instructions.
  • a computer device (which may be a personal computer, a server, or a master node, a secondary node, etc.) is caused to perform all or part of the methods described in various embodiments of the present invention.
  • the foregoing storage medium includes various media that can store program codes, such as a USB flash drive, a mobile hard disk, a read only memory (ROM), a magnetic disk, or an optical disk.
  • program codes such as a USB flash drive, a mobile hard disk, a read only memory (ROM), a magnetic disk, or an optical disk.
  • an embodiment of the present invention further provides a computer storage medium, wherein a computer program is configured, and the computer program is configured to execute a data scheduling method according to an embodiment of the present invention.

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Abstract

本发明公开了一种数据复制传输的控制方法、用户设备(UE)、主节点、辅助节点及计算机存储介质,其中,方法包括:接收主节点发来的第一控制信息,和/或,接收辅助节点发来的第二控制信息;基于所述第一控制信息所对应的第一部分数据无线承载DRB的指示、和/或、基于所述第二控制信息所对应的第二部分DRB的指示,确定开启或关闭至少一个DRB的数据复制传输功能。

Description

数据复制传输的控制方法、用户设备、主节点及辅助节点 技术领域
本发明涉及通信处理技术领域,尤其涉及一种数据复制传输的控制方法、用户设备(UE)、主节点、辅助节点及计算机存储介质。
背景技术
在NR现有的讨论中,对于配置了复制数据传输功能的无线承载,可以通过MAC CE动态的激活(activate)或者去激活(de-activate)某一个承载的数据复制传输功能。对于双连接(DC)的情况,MCG和SCG可以分别发送MAC CE来激活或者去激活UE某一个split bearer的复制数据功能。
但是在DC场景下,由于MCG的主节点和SCG的辅助节点可以分别发送控制信息,这就需要UE侧需要识别出具体哪些控制信息用于控制哪些DRB,以保证UE的处理效率。
发明内容
为解决上述技术问题,本发明实施例提供了一种数据复制传输的控制方法、用户设备(UE)、主节点、辅助节点及计算机存储介质。
本发明实施例提供的一种数据复制传输的控制方法,应用于用户设备,包括:
接收主节点发来的第一控制信息,和/或,接收辅助节点发来的第二控制信息;
基于所述第一控制信息所对应的第一部分数据无线承载DRB的指示、和/或、基于所述第二控制信息所对应的第二部分DRB的指示,确定开启或关闭至少一个DRB的数据复制传输功能。
本发明实施例提供一种数据复制传输的控制方法,应用于主节点,包括:
与辅助节点协商,确定开启或关闭目标UE的至少一个数据无线承载的数据复制传输功能;
基于所述协商结果,确定所述主节点控制所述目标UE开启或关闭所述至少一个数据无线承载中的第一部分数据无线承载的数据复制功能,以及所述辅助节点控制所述目标UE开启或关闭所述至少一个数据无线承载中的第二部分数据无线承载的数据复制功能;其中,所述第一部分数据无线承载于所述第二部分数据无线承载至少部分不同;
基于确定开启或关闭的所述第一部分数据无线承载DRB的数据复制功能,生成第一控制信息,发送所述第一控制信息至所述目标UE。
本发明实施例提供一种数据复制传输的控制方法,应用于辅助节点,包括:
与主节点协商,确定是否开启或关闭目标UE的至少一个数据无线承载的数据复制传输功能;
基于所述协商结果,确定所述主节点控制所述目标UE开启或关闭所述至少一个数据无线承载中的第一部分数据无线承载DRB的数据复制功能,以及所述辅助节点控制所述目标UE开启所述至少一个DRB中的第二部分数据无线承载的数据复制功能;其中,所述第一部分DRB与所述第二部分DRB至少部分不同;
基于确定开启或关闭的所述第二部分DRB的数据复制功能,生成第二控制信息,发送所述第二控制信息至所述目标UE。
本发明实施例提供一种UE,包括:
第一通信单元,接收主节点发来的第一控制信息,和/或,接收辅助节点发来的第二控制信息;
第一处理单元,基于所述第一控制信息所对应的第一部分数据无线承载DRB的指示、和/或、基于所述第二控制信息所对应的第二部分DRB的指示,确定开启或关闭至少一个DRB的数据复制传输功能。
本发明实施例提供一种主节点,包括:
第二通信单元,与辅助节点协商,确定开启或关闭目标UE的至少一个数据无线承载的数据复制传输功能;以及发送所述第一控制信息至所述目标UE;
第二处理单元,基于所述协商结果,确定所述主节点控制所述目标UE开启或关闭所述至少一个数据无线承载中的第一部分数据无线承载的数据复制功能,以及所述辅助节点控制所述目标UE开启或关闭所述至少一个数据无线承载中的第二部分数据无线承载的数据复制功能;其中,所述第一部分数据无线承载于所述第二部分数据无线承载至少部分不同;基于确定开启或关闭的所述第一部分数据无线承载DRB的数据复制功能,生成第一控制信息。
本发明实施例提供一种辅助节点,包括:
第三通信单元,与主节点协商,确定是否开启或关闭目标UE的至少一个数据无线承载的数据复制传输功能;以及发送第二控制信息至所述目标UE;
第三处理单元,基于所述协商结果,确定所述主节点控制所述目标UE开启或关闭所述至少一个数据无线承载中的第一部分数据无线承载DRB的数据复制功能,以及所述辅助节点控制所述目标UE开启所述至少一个DRB中的第二部分数据无线承载的数据复制功能;其中,所述第一部分DRB与所述第二部分DRB至少部分不同;基于确定开启或关闭的所述第二部分DRB的数据复制功能,生成第二控制信息。
本发明实施例提供一种UE,包括:处理器和用于存储能够在处理器上 运行的计算机程序的存储器,
其中,所述处理器用于运行所述计算机程序时,执行前述方法的步骤。
本发明实施例提供一种主节点,包括:处理器和用于存储能够在处理器上运行的计算机程序的存储器,
其中,所述处理器用于运行所述计算机程序时,执行前述方法的步骤。
本发明实施例提供一种辅助节点,包括:处理器和用于存储能够在处理器上运行的计算机程序的存储器,
其中,所述处理器用于运行所述计算机程序时,执行前述方法的步骤。
本发明实施例提供的一种计算机存储介质,所述计算机存储介质存储有计算机可执行指令,所述计算机可执行指令被执行时实现前述方法步骤。
本发明实施例的技术方案,就能够使得UE侧根据主节点和/或辅助节点发来的第一控制信息和/或第二控制信息,确定是否开启或关闭自身的至少一个DRB的数据传输复制功能。如此,就在双连接的场景下,使得UE能够确定收到两个节点发来的控制信息之后,判断具体开启哪些DRB的数据传输复制功能,保证UE的处理效率。
附图说明
图1为本发明实施例提供的一种数据复制传输的控制方法流程示意图1;
图2为本发明实施例提供的一种数据复制传输的控制方法流程示意图2;
图3为本发明实施例提供的一种数据复制传输的控制方法流程示意图3;
图4为本发明实施例用户设备组成结构示意图;
图5为本发明实施例协议层架构示意图;
图6为本发明实施例主节点组成结构示意图;
图7为本发明实施例辅助节点组成结构示意图;
图8为本发明实施例的一种硬件架构示意图。
具体实施方式
为了能够更加详尽地了解本发明实施例的特点与技术内容,下面结合附图对本发明实施例的实现进行详细阐述,所附附图仅供参考说明之用,并非用来限定本发明实施例。
实施例一、
本发明实施例提供了一种数据复制传输的控制方法,应用于用户设备UE,如图1所示,包括:
步骤101:接收主节点发来的第一控制信息,和/或,接收辅助节点发来的第二控制信息;
步骤102:基于所述第一控制信息所对应的第一部分数据无线承载DRB的指示、和/或、基于所述第二控制信息所对应的第二部分DRB的指示,确定开启或关闭至少一个DRB的数据复制传输功能。
这里,所述主节点可以为主小区群组(MCG)中的节点,辅助节点可以为辅助小区群组(SCG)中的节点。
前述步骤101中,所述接收主节点发来的第一控制信息,和/或,接收辅助节点发来的第二控制信息,包括:
接收所述主节点发来的比特图(bitmap)格式的第一控制信息;和/或,接收所述辅助节点发来的比特图格式的第二控制信息。
接收主节点或辅助节点的控制信息,可以同时也可以分别接收,这里不对接收第一控制信息以及第二控制信息的先后顺序进行限定。
网络侧的MCG的主节点和SCG的辅助节点通过Xn接口协作,确定控制UE某个DRB复制数据功能开启或关闭的网络节点。
进一步地,基于所述比特图格式的第一控制信息、以及DRB的标识信 息之间的对应关系,确定所述第一控制信息所指示的第一部分DRB。和/或,基于所述比特图格式的第二控制信息、以及DRB的标识信息之间的对应关系,确定所述第二控制信息所指示的第二部分DRB。
比如,bitmap格式的第一控制信息中包括8bit,那么可以每一个bit对应一个DRB的标识信息;假设可以bit1-3分别对应DRB1、4、7,然后剩余的bite4-8为无效bit。那么通过bimap就可以确定第一控制信息指示了哪个DRB的开启或关闭。再进一步地,可以设置bitmap中的某一个bit位为0表示关闭DRB的数据传输复制功能,bit位为1的时候可以表示开启DRB的数据传输复制功能。当然还可以反之设置,只是本实施例中不进行穷举。
另外,第二控制信息的bitmap中bit1-3可以分别对应DRB的标识1、3、7,剩余bit位可以为无效位。关于bit位的含义与前述的设置方式相同,不再进行赘述。
所述DRB包含三种类型:MCG bearer,SCG bearer和Split bearer;MN发送的MAC CE负责控制MCG bearer和Split bearer的数据复制功能的开启或关闭;SN发送的MAC CE负责控制SCG bearer和split bearer的数据复制功能开启或关闭。
前述步骤102,基于所述第一控制信息所对应的第一部分数据无线承载DRB的指示、和/或、基于所述第二控制信息所对应的第二部分DRB的指示,确定开启或关闭至少一个DRB的数据复制传输功能。操作的时候,可以有三个因素可以考虑如何控制:
第一种因素、
当所述第一控制信息对应的第一部分DRB中,包含有作为主小区承载的第一DRB时,确定基于所述第一控制信息的指示,开启或关闭所述第一DRB的数据复制传输功能。和/或,当所述第二控制信息对应的第二部分DRB中,包含有作为辅助小区承载的第二DRB时,确定基于所述第二控制 信息的指示,开启或关闭所述第二DRB的数据复制传输功能。
需要指出的是,所述第一DRB不包含在第二部分DRB中。以及所述第二DRB不包含在第一部分DRB中。
也就是说,Non split bearers即非分叉承载(比如,可以为MCG bearer(第一DRB)and SCG bearer(第二DRB))不由对端控制,比如MCG MAC CE控制MCG bearer,SCG MAC CE控制SCG bearer。
需要理解的是,本实施例中未针对第一DRB以及第二DRB的数量进行限定,实际中均可以存在一个或多个第一DRB以及第二DRB,并且两者数量可以不同。
第二种因素、
当所述第一控制信息对应的第一部分DRB中,包含有作为分叉承载的第三DRB时,和/或,当所述第二控制信息对应的第二部分DRB中,包含有作为分叉承载的第三DRB时,
基于预设条件,确定开启或关闭所述第三DRB的数据复制传输功能。
其中分叉承载即第三DRB可以为Split bearer,该第三DRB可以由MCG或者SCG控制。
具体的针对预设条件可以包括以下至少之一:
条件1、基于所述第三DRB的PDCP所在群组,确定由所述群组所对应的节点发来的控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。
其中,关于如何确定第三DRB在哪种PDCP的群组,可以根据第三DRB的密钥值来确定,也就是说,获取第三DRB对应的密钥值,基于所述第三DRB对应的密钥值确定所述第三SRB的PDCP所在群组。
比如一个split bearer的PDCP在MCG,则MCG MAC CE控制该split bearer。UE可以通过split bearer的密钥值(Key)的不同来区分该split bearer 的PDCP在MCG还是SCG。其中,不同的群组可以对应有不同的密钥值,其设置方式可以为网络侧与UE侧预先协商确定,比如,在双连接(DC)中,对于一个split bearer,其key值可以是KeNB或S-KgNB,通过识别这两个key值就可以让UE区分就能够区分出来PDCP在MCG或者SCG;具体的,KeNB可以为对应MCG的Key,S-KgNB可以为对应SCG的Key。
条件2、基于所述第三DRB所对应的默认传输路径,确定由所述默认传输路径之外的控制节点所对应的控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。
其中,所述默认传输路径为当复制数据传输功能处于去激活状态时所采用的路径。
比如,一个split bearer(即第三DRB)的non default leg,default leg指的是duplication deactivated以后,默认传输的path。可以是non default leg对应的节点来控制duplication。
条件3、基于所述第三DRB的PDCP版本,来确定与所述PDCP版本相对应的节点发来的控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。
其中,所述第三DRB的PDCP版本为以下之一:LTE PDCP的版本、NR PDCP版本。
Split bearer的PDCP的version(版本)来决定,比如,LTE侧的MAC只能控制PDCP为LTE PDCP的split bearer,NR侧的MAC只能控制PDCP为NR PDCP的split bearer。
需要理解的是,上述第一种因素、第二种因素,以及第二种因素中的3个条件,可以进行组合来进行判断。本实施例中不对组合进行穷举,各种组合均在本实施例的保护范围内。
下面举例说明本实施例提供的方案:
DRB与MAC CE bitmap的对应按照DRB ID的升序或者降序对应;
比如,UE的DRB ID 1,3,4,7分别具有PDCP复制数据传输功能;其中DRB ID 1为MCG bearer,DRB ID 3为SCG bearer,DRB ID 4和7为split bearer;
网络侧MCG和SCG通过协作,可以确定DRB ID 1,4,7分别对应MN发送的MAC CE的bitmap中的1,2,3位,其余4,5,6,7,8位为无效位;
确定DRB ID 3,4,7分别对应SN发送的MAC CE的bitmap中的1,2,3位,其余4,5,6,7,8位为无效位。
相应的,UE的MAC层,接收网络(可以是MCG中的主节点或者是SCG中的辅助节点)发送的第一控制信息和/或第二控制信息进行开启或关闭至少一个DRB的复制数据传输功能。
UE的MAC层把收到的复制数据控制MAC CE中的bitmap的相应bit位指示(indicate to)给对应的DRB的PDCP层;
UE的MAC层根据bitmap与DRB ID的对应关系,找到DRB ID在bitmap中的对应bit位,比如UE的DRB ID为1,4,7分别对应MN MAC CE的bitmap中的1,2,3位。则MAC CE收到MAC CE的bitmap之后,把第一位的值指示给DRB ID为1的PDCP,把第二位的值指示给DRB ID为3的PDCP,以此类推。
本实施例前述的处理方式,针对当接收到控制信息之后,如何根据DRB与控制信息之间的关系,确定DRB与哪个控制信息相对应,比如,以及当一个DRB收到第一控制信息以及第二控制信息的时候,如何决策使用哪个控制信息进行后续处理。
另外,本实施例还可以提供另外一种处理方式,也就是预先根据预设规则,确定哪个DRB去获取哪一个控制信息;即这种处理方式下,网络侧可以针对一个DRB仅发来一个控制信息,具体的处理方式如下:
针对UE的至少一个DRB分别与哪个控制信息相对应进行描述,可以为根据预设规则,确定所述至少一个DRB中的每一个DRB对应于第一控制信息或第二控制信息。
具体来说,可以理解为不同的DRB的标识信息,与第一控制信息、或者第二控制信息中的哪个比特位相对应。
其中,所述预设规则,包括以下至少之一:
当DRB为主小区承载时,所述DRB包含在所述第一控制信息对应的第一部分DRB中;
当DRB为辅助小区承载时,所述DRB包含在所述第二控制信息对应的第二部分DRB中。
也就是说,当某一个DRB为主小区承载的时候,该DRB的标识信息与第一控制信息中的第一bit位对应;另外,当某一个DRB为辅助小区承载的时候,该DRB的标识信息与第二控制信息中的第二bit位对应。其中,第一bit以及第二bit位并不真实表示控制信息中的具体bit位,而表征第一bit位于第二bit位不相同而已,实际上第一bit位可以为第一控制信息中的bit3、第二bit位可以为第二控制信息中的bit1。
并且,上述当所述DRB为主小区承载时,不与第二控制信息相对应、不包含在第二部分DRB中;当所述DRB为辅助小区承载时,不与第一控制信息相对应、不包含在第一部分DRB中。
所述预设规则还包括以下至少之一:
当DRB为分叉承载时,基于所述DRB的PDCP所在群组,确定由PDCP所在群组所对应的节点发来的控制信息所述DRB进行控制;需要理解的是,这里节点可以为主节点可以为辅助节点,控制信息可以为第一控制信息也可以为第二控制信息中的一个;
当DRB为分叉承载时,基于所述DRB所对应的默认传输路径,确定 由所述默认传输路径之外的节点发来的控制信息对所述DRB进行控制;需要理解的是,这里节点可以为主节点可以为辅助节点,控制信息可以为第一控制信息也可以为第二控制信息中的一个;
当DRB为分叉承载时,基于所述DRB的PDCP版本,确定与所述PDCP版本相对应的节点发来的控制信息对所述DRB进行控制;需要理解的是,这里节点可以为主节点可以为辅助节点,控制信息可以为第一控制信息也可以为第二控制信息中的一个。
当DRB为分叉承载时,基于所述DRB的PDCP所在群组,确定DRB所不在群组对应的节点发出的控制信息不能够对所述DRB进行控制。
当DRB为分叉承载时,基于所述DRB所对应的默认传输路径,确定由所述默认传输路径的节点发来的控制信息不能够对所述DRB进行控制。
当DRB为分叉承载时,基于所述DRB的PDCP版本,确定与所述PDCP版本不对应的节点发来的控制信息不能够对所述DRB进行控制。
可见,通过采用上述方案,就能够使得UE侧根据主节点和/或辅助节点发来的第一控制信息和/或第二控制信息,确定是否开启或关闭自身的至少一个DRB的数据传输复制功能。如此,就在双连接的场景下,使得UE能够确定收到两个节点发来的控制信息之后,判断具体开启哪些DRB的数据传输复制功能,保证UE的处理效率。
实施例二、
本发明实施例提供了一种数据复制传输的控制方法,应用于主节点,如图2所示,包括:
步骤201:与辅助节点协商,确定开启或关闭目标UE的至少一个数据无线承载的数据复制传输功能;
步骤202:基于所述协商结果,确定所述主节点控制所述目标UE开启或关闭所述至少一个数据无线承载中的第一部分数据无线承载的数据复制 功能,以及所述辅助节点控制所述目标UE开启或关闭所述至少一个数据无线承载中的第二部分数据无线承载的数据复制功能;其中,所述第一部分数据无线承载于所述第二部分数据无线承载至少部分不同;
步骤203:基于确定开启或关闭的所述第一部分数据无线承载DRB的数据复制功能,生成第一控制信息,发送所述第一控制信息至所述目标UE。
这里,所述主节点可以为主小区群组(MCG)中的节点,辅助节点可以为辅助小区群组(SCG)中的节点。
网络侧的MCG的主节点和SCG的辅助节点可以通过Xn接口进行协商,以确定控制UE的一个或多个DRB复制数据功能开启或关闭。
进一步地,所述基于确定开启或关闭的所述第一部分DRB的数据复制功能,生成第一控制信息,包括:
获取DRB的标识信息、与比特图的数据位之间的对应关系;
通过对比特图中与所述第一部分DRB的标识信息所对应的数据位进行设置,生成所述第一控制信息。
基于所述比特图格式的第一控制信息、以及DRB的标识信息之间的对应关系,确定所述第一控制信息所指示的第一部分DRB。和/或,基于所述比特图格式的第二控制信息、以及DRB的标识信息之间的对应关系,确定所述第二控制信息所指示的第二部分DRB。
比如,bitmap格式的第一控制信息中包括8bit,那么可以每一个bit对应一个DRB的标识信息;假设可以bit1-3分别对应DRB1、4、7,然后剩余的bite4-8为无效bit。那么通过bimap就可以确定第一控制信息指示了哪个DRB的开启或关闭。再进一步地,可以设置bitmap中的某一个bit位为0表示关闭DRB的数据传输复制功能,bit位为1的时候可以表示开启DRB的数据传输复制功能。当然还可以反之设置,只是本实施例中不进行穷举。
另外,第二控制信息的bitmap中bit1-3可以分别对应DRB的标识1、 3、7,剩余bit位可以为无效位。关于bit位的含义与前述的设置方式相同,不再进行赘述。
所述DRB包含三种类型:MCG bearer,SCG bearer和Split bearer;MN发送的MAC CE负责控制MCG bearer和Split bearer的数据复制功能的开启或关闭;SN发送的MAC CE负责控制SCG bearer和split bearer的数据复制功能开启或关闭。
主节点和辅助节点进行协商,可以包括:
当针对目标DRB为主小区承载时,确定由主节点通过第一控制信息对其进行控制;目标DRB可以理解为UE的多个DRB中的任意一个;
当针对目标DRB为辅助小区承载时,确定由辅助节点通过第二控制信息对其进行控制;目标DRB可以理解为UE的多个DRB中的任意一个;
当目标DRB作为分叉承载时,基于所述DRB的PDCP所在群组对应的节点为主节点或辅助节点,确定由主节点或辅助节点生成控制信息以控制所述目标DRB的数据复制功能的开启或关闭。也就是说,根据DRB所的PDCP所在群组,确定该DRB对应的控制信息为主节点发出的第一控制信息,还是辅助节点发出的第二控制信息。
当目标DRB作为分叉承载时,基于所述目标DRB所对应的默认传输路径,确定由所述默认传输路径之外的主节点或辅助节点生成控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。也就是说,根据DRB所对应的默认传输路径,确定该DRB对应的控制信息为主节点发出的第一控制信息,还是辅助节点发出的第二控制信息。
当目标DRB作为分叉承载时,基于所述目标DRB的PDCP版本,确定与所述PDCP版本相对应的主节点或辅助节点生成控制信息,以通过控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。也就是说,根据DRB的PDCP版本,确定该DRB对应的控制信息为主节点发出的第 一控制信息,还是辅助节点发出的第二控制信息。
下面举例说明本实施例提供的方案:
DRB与MAC CE bitmap的对应按照DRB ID的升序或者降序对应;
比如,UE的DRB ID 1,3,4,7分别具有PDCP复制数据传输功能;其中DRB ID 1为MCG bearer,DRB ID 3为SCG bearer,DRB ID 4和7为split bearer;
网络侧MCG和SCG通过协作,可以确定DRB ID 1,4,7分别对应MN发送的MAC CE的bitmap中的1,2,3位,其余4,5,6,7,8位为无效位;
确定DRB ID 3,4,7分别对应SN发送的MAC CE的bitmap中的1,2,3位,其余4,5,6,7,8位为无效位。
可见,通过采用上述方案,就能够使得UE侧根据主节点和/或辅助节点发来的第一控制信息和/或第二控制信息,确定是否开启或关闭自身的至少一个DRB的数据传输复制功能。如此,就在双连接的场景下,使得UE能够确定收到两个节点发来的控制信息之后,判断具体开启哪些DRB的数据传输复制功能,保证UE的处理效率。
实施例三、
本发明实施例提供了一种数据复制传输的控制方法,应用于辅助节点,如图3所示,包括:
步骤301:与主节点协商,确定是否开启或关闭目标UE的至少一个数据无线承载的数据复制传输功能;
步骤302:基于所述协商结果,确定所述主节点控制所述目标UE开启或关闭所述至少一个数据无线承载中的第一部分数据无线承载DRB的数据复制功能,以及所述辅助节点控制所述目标UE开启或关闭所述至少一个DRB中的第二部分数据无线承载的数据复制功能;其中,所述第一部分DRB与所述第二部分DRB至少部分不同;
步骤303:基于确定开启或关闭的所述第二部分DRB的数据复制功能,生成第二控制信息,发送所述第二控制信息至所述目标UE。
这里,所述主节点可以为主小区群组(MCG)中的节点,辅助节点可以为辅助小区群组(SCG)中的节点。
网络侧的MCG的主节点和SCG的辅助节点可以通过Xn接口进行协商,以确定控制UE的一个或多个DRB复制数据功能开启或关闭。
进一步地,所述生成第二控制信息,包括:
获取DRB的标识信息、与比特图的数据位之间的对应关系;
通过对比特图中与所述第二部分DRB的标识信息所对应的数据位进行设置,生成所述第二控制信息。
比如,bitmap格式的第一控制信息中包括8bit,那么可以每一个bit对应一个DRB的标识信息;假设可以bit1-3分别对应DRB1、4、7,然后剩余的bite4-8为无效bit。那么通过bimap就可以确定第一控制信息指示了哪个DRB的开启或关闭。再进一步地,可以设置bitmap中的某一个bit位为0表示关闭DRB的数据传输复制功能,bit位为1的时候可以表示开启DRB的数据传输复制功能。当然还可以反之设置,只是本实施例中不进行穷举。
另外,第二控制信息的bitmap中bit1-3可以分别对应DRB的标识1、3、7,剩余bit位可以为无效位。关于bit位的含义与前述的设置方式相同,不再进行赘述。
所述DRB包含三种类型:MCG bearer,SCG bearer和Split bearer;MN发送的MAC CE负责控制MCG bearer和Split bearer的数据复制功能的开启或关闭;SN发送的MAC CE负责控制SCG bearer和split bearer的数据复制功能开启或关闭。
主节点和辅助节点进行协商,可以包括:
当针对目标DRB为主小区承载时,确定由主节点通过第一控制信息对 其进行控制;目标DRB可以理解为UE的多个DRB中的任意一个;
当针对目标DRB为辅助小区承载时,确定由辅助节点通过第二控制信息对其进行控制;目标DRB可以理解为UE的多个DRB中的任意一个;
当目标DRB作为分叉承载时,基于所述DRB的PDCP所在群组对应的节点为主节点或辅助节点,确定由主节点或辅助节点生成控制信息以控制所述目标DRB的数据复制功能的开启或关闭。也就是说,根据DRB所的PDCP所在群组,确定该DRB对应的控制信息为主节点发出的第一控制信息,还是辅助节点发出的第二控制信息。
当目标DRB作为分叉承载时,基于所述目标DRB所对应的默认传输路径,确定由所述默认传输路径之外的主节点或辅助节点生成控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。也就是说,根据DRB所对应的默认传输路径,确定该DRB对应的控制信息为主节点发出的第一控制信息,还是辅助节点发出的第二控制信息。
当目标DRB作为分叉承载时,基于所述目标DRB的PDCP版本,确定与所述PDCP版本相对应的主节点或辅助节点生成控制信息,以通过控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。也就是说,根据DRB的PDCP版本,确定该DRB对应的控制信息为主节点发出的第一控制信息,还是辅助节点发出的第二控制信息。
下面举例说明本实施例提供的方案:
DRB与MAC CE bitmap的对应按照DRB ID的升序或者降序对应;
比如,UE的DRB ID 1,3,4,7分别具有PDCP复制数据传输功能;其中DRB ID 1为MCG bearer,DRB ID 3为SCG bearer,DRB ID 4和7为split bearer;
网络侧MCG和SCG通过协作,可以确定DRB ID 1,4,7分别对应MN发送的MAC CE的bitmap中的1,2,3位,其余4,5,6,7,8位为无效位;
确定DRB ID 3,4,7分别对应SN发送的MAC CE的bitmap中的1,2,3位,其余4,5,6,7,8位为无效位。
可见,通过采用上述方案,就能够使得UE侧根据主节点和/或辅助节点发来的第一控制信息和/或第二控制信息,确定是否开启或关闭自身的至少一个DRB的数据传输复制功能。如此,就在双连接的场景下,使得UE能够确定收到两个节点发来的控制信息之后,判断具体开启哪些DRB的数据传输复制功能,保证UE的处理效率。
实施例三、
本发明实施例提供了一种UE,如图4所示,包括:
第一通信单元41,接收主节点发来的第一控制信息,和/或,接收辅助节点发来的第二控制信息;
第一处理单元42,基于所述第一控制信息所对应的第一部分数据无线承载DRB的指示、和/或、基于所述第二控制信息所对应的第二部分DRB的指示,确定开启或关闭至少一个DRB的数据复制传输功能。
这里,所述主节点可以为主小区群组(MCG)中的节点,辅助节点可以为辅助小区群组(SCG)中的节点。
前述第一通信单元41,接收所述主节点发来的比特图(bitmap)格式的第一控制信息;和/或,接收所述辅助节点发来的比特图格式的第二控制信息。
接收主节点或辅助节点的控制信息,可以同时也可以分别接收,这里不对接收第一控制信息以及第二控制信息的先后顺序进行限定。
网络侧的MCG的主节点和SCG的辅助节点通过Xn接口协作,确定控制UE某个DRB复制数据功能开启或关闭的网络节点。
进一步地,基于所述比特图格式的第一控制信息、以及DRB的标识信息之间的对应关系,确定所述第一控制信息所指示的第一部分DRB。和/ 或,基于所述比特图格式的第二控制信息、以及DRB的标识信息之间的对应关系,确定所述第二控制信息所指示的第二部分DRB。
比如,bitmap格式的第一控制信息中包括8bit,那么可以每一个bit对应一个DRB的标识信息;假设可以bit1-3分别对应DRB1、4、7,然后剩余的bite4-8为无效bit。那么通过bimap就可以确定第一控制信息指示了哪个DRB的开启或关闭。再进一步地,可以设置bitmap中的某一个bit位为0表示关闭DRB的数据传输复制功能,bit位为1的时候可以表示开启DRB的数据传输复制功能。当然还可以反之设置,只是本实施例中不进行穷举。
另外,第二控制信息的bitmap中bit1-3可以分别对应DRB的标识1、3、7,剩余bit位可以为无效位。关于bit位的含义与前述的设置方式相同,不再进行赘述。
所述DRB包含三种类型:MCG bearer,SCG bearer和Split bearer;MN发送的MAC CE负责控制MCG bearer和Split bearer的数据复制功能的开启或关闭;SN发送的MAC CE负责控制SCG bearer和split bearer的数据复制功能开启或关闭。
基于所述第一控制信息所对应的第一部分数据无线承载DRB的指示、和/或、基于所述第二控制信息所对应的第二部分DRB的指示,确定开启或关闭至少一个DRB的数据复制传输功能。操作的时候,可以有三个因素可以考虑如何控制:
第一种因素、
第一处理单元42,当所述第一控制信息对应的第一部分DRB中,包含有作为主小区承载的第一DRB时,确定基于所述第一控制信息的指示,开启或关闭所述第一DRB的数据复制传输功能。和/或,当所述第二控制信息对应的第二部分DRB中,包含有作为辅助小区承载的第二DRB时,确定基于所述第二控制信息的指示,开启或关闭所述第二DRB的数据复制传输 功能。需要指出的是,所述第一DRB不包含在第二部分DRB中。以及所述第二DRB不包含在第一部分DRB中。
也就是说,Non split bearers即非分叉承载(比如,可以为MCG bearer(第一DRB)and SCG bearer(第二DRB))不由对端控制,比如MCG MAC CE控制MCG bearer,SCG MAC CE控制SCG bearer。
需要理解的是,本实施例中未针对第一DRB以及第二DRB的数量进行限定,实际中均可以存在一个或多个第一DRB以及第二DRB,并且两者数量可以不同。
第二种因素、
第一处理单元42,当所述第一控制信息对应的第一部分DRB中,包含有作为分叉承载的第三DRB时,和/或,当所述第二控制信息对应的第二部分DRB中,包含有作为分叉承载的第三DRB时,
基于预设条件,确定开启或关闭所述第三DRB的数据复制传输功能。
其中分叉承载即第三DRB可以为Split bearer,该第三DRB可以由MCG或者SCG控制。
具体的针对预设条件可以包括以下至少之一:
条件1、基于所述第三DRB的PDCP所在群组,确定由所述群组所对应的节点发来的控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。
其中,关于如何确定第三DRB在哪种PDCP的群组,可以根据第三DRB的密钥值来确定,也就是说,第一处理单元42,获取第三DRB对应的密钥值,基于所述第三DRB对应的密钥值确定所述第三SRB的PDCP所在群组。
比如一个split bearer的PDCP在MCG,则MCG MAC CE控制该split bearer。UE可以通过split bearer的密钥值(Key)的不同来区分该split bearer 的PDCP在MCG还是SCG。其中,不同的群组可以对应有不同的密钥值,其设置方式可以为网络侧与UE侧预先协商确定,在双连接(DC)中,对于一个split bearer,其key值可以是KeNB或S-KgNB,通过识别这两个key值就可以让UE区分就能够区分出来PDCP在MCG或者SCG;具体的,KeNB可以为对应MCG的Key,S-KgNB可以为对应SCG的Key。
条件2、基于所述第三DRB所对应的默认传输路径,确定由所述默认传输路径之外的控制节点所对应的控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。
其中,所述默认传输路径为当复制数据传输功能处于去激活状态时所采用的路径。
比如,一个split bearer(即第三DRB)的non default leg,default leg指的是duplication deactivated以后,默认传输的path。可以是non default leg对应的节点来控制duplication。
条件3、基于所述第三DRB的PDCP版本,来确定与所述PDCP版本相对应的节点发来的控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。
其中,所述第三DRB的PDCP版本为以下之一:LTE PDCP的版本、NR PDCP版本。
Split bearer的PDCP的version(版本)来决定,比如,LTE侧的MAC只能控制PDCP为LTE PDCP的split bearer,NR侧的MAC只能控制PDCP为NR PDCP的split bearer。
需要理解的是,上述第一种因素、第二种因素,以及第二种因素中的3个条件,可以进行组合来进行判断。本实施例中不对组合进行穷举,各种组合均在本实施例的保护范围内。
下面结合图5,可以看出,复制数据传输方式采用采用的是split bearer 的协议架构;对于上下行来说,PDCP位于某一个CG(MCG或者SCG),该CG即为anchor CG。PDCP将PDCP PDU复制为相同的两份,比如一个是PDCP PDU,一个是Duplicated PDCP PDU,两个PDCP经过不同CG的RLC,MAC,在经过空口到达UE(下行)或者基站(上行)相应的MAC,RLC层,最后再汇聚到PDCP,PDCP层监测到两个PDCP为相同的复制版本,即丢弃其中一个,将另外一个递交到高层。将PDCP下面分别连接两个RLC和MAC的这一个承载称为split bearer,如果PDCP位于MCG,则为MCG Split Bearer,如果PDCP位于SCG,则为SCG Split Bearer。具体来说,本实施例提供的方案:
DRB与MAC CE bitmap的对应按照DRB ID的升序或者降序对应;
比如,UE的DRB ID 1,3,4,7分别具有PDCP复制数据传输功能;其中DRB ID 1为MCG bearer,DRB ID 3为SCG bearer,DRB ID 4和7为split bearer;
网络侧MCG和SCG通过协作,可以确定DRB ID 1,4,7分别对应MN发送的MAC CE的bitmap中的1,2,3位,其余4,5,6,7,8位为无效位;
确定DRB ID 3,4,7分别对应SN发送的MAC CE的bitmap中的1,2,3位,其余4,5,6,7,8位为无效位。
相应的,UE的MAC层,接收网络(可以是MCG中的主节点或者是SCG中的辅助节点)发送的第一控制信息和/或第二控制信息进行开启或关闭至少一个DRB的复制数据传输功能。
UE的MAC层把收到的复制数据控制MAC CE中的bitmap的相应bit位指示(indicate to)给对应的DRB的PDCP层;
UE的MAC层根据bitmap与DRB ID的对应关系,找到DRB ID在bitmap中的对应bit位,比如UE的DRB ID为1,4,7分别对应MN MAC CE的bitmap中的1,2,3位。则MAC CE收到MAC CE的bitmap之后,把第一 位的值指示给DRB ID为1的PDCP,把第二位的值指示给DRB ID为3的PDCP,以此类推。
本实施例前述的处理方式,针对当接收到控制信息之后,如何根据DRB与控制信息之间的关系,确定DRB与哪个控制信息相对应,比如,以及当一个DRB收到第一控制信息以及第二控制信息的时候,如何决策使用哪个控制信息进行后续处理。
另外,本实施例还可以提供另外一种处理方式,也就是预先根据预设规则,确定哪个DRB去获取哪一个控制信息;即这种处理方式下,网络侧可以针对一个DRB仅发来一个控制信息,具体的处理方式如下:
针对UE的至少一个DRB分别与哪个控制信息相对应进行描述,可以为根据预设规则,确定所述至少一个DRB中的每一个DRB对应于第一控制信息或第二控制信息。需要理解的是,前述预设规则,可以为UE侧与节点(主节点以及辅助节点)侧均具备的预设规则,即UE侧基于预设规则判断哪个DRB对应了哪个控制信息中的bit位,相应的,节点也可以根据预设规则、确定在哪个bit为中放置针对哪个DRB的控制信息。
具体来说,可以理解为不同的DRB的标识信息,与第一控制信息、或者第二控制信息中的哪个比特位相对应。
其中,所述预设规则,包括以下至少之一:
当DRB为主小区承载时,所述DRB包含在所述第一控制信息对应的第一部分DRB中;
当DRB为辅助小区承载时,所述DRB包含在所述第二控制信息对应的第二部分DRB中。
也就是说,当某一个DRB为主小区承载的时候,该DRB的标识信息与第一控制信息中的第一bit位对应;另外,当某一个DRB为辅助小区承载的时候,该DRB的标识信息与第二控制信息中的第二bit位对应。其中, 第一bit以及第二bit位并不真实表示控制信息中的具体bit位,而表征第一bit位于第二bit位不相同而已,实际上第一bit位可以为第一控制信息中的bit3、第二bit位可以为第二控制信息中的bit1。
并且,上述当所述DRB为主小区承载时,不与第二控制信息相对应、不包含在第二部分DRB中;当所述DRB为辅助小区承载时,不与第一控制信息相对应、不包含在第一部分DRB中。
所述预设规则还包括以下至少之一:
当DRB为分叉承载时,基于所述DRB的PDCP所在群组,确定由PDCP所在群组所对应的节点发来的控制信息所述DRB进行控制;需要理解的是,这里节点可以为主节点可以为辅助节点,控制信息可以为第一控制信息也可以为第二控制信息中的一个;
当DRB为分叉承载时,基于所述DRB所对应的默认传输路径,确定由所述默认传输路径之外的节点发来的控制信息对所述DRB进行控制;需要理解的是,这里节点可以为主节点可以为辅助节点,控制信息可以为第一控制信息也可以为第二控制信息中的一个;
当DRB为分叉承载时,基于所述DRB的PDCP版本,确定与所述PDCP版本相对应的节点发来的控制信息对所述DRB进行控制;需要理解的是,这里节点可以为主节点可以为辅助节点,控制信息可以为第一控制信息也可以为第二控制信息中的一个。
当DRB为分叉承载时,基于所述DRB的PDCP所在群组,确定DRB所不在群组对应的节点发出的控制信息不能够对所述DRB进行控制。
当DRB为分叉承载时,基于所述DRB所对应的默认传输路径,确定由所述默认传输路径的节点发来的控制信息不能够对所述DRB进行控制。
当DRB为分叉承载时,基于所述DRB的PDCP版本,确定与所述PDCP版本不对应的节点发来的控制信息不能够对所述DRB进行控制。
可见,通过采用上述方案,就能够使得UE侧根据主节点和/或辅助节点发来的第一控制信息和/或第二控制信息,确定是否开启或关闭自身的至少一个DRB的数据传输复制功能。如此,就在双连接的场景下,使得UE能够确定收到两个节点发来的控制信息之后,判断具体开启哪些DRB的数据传输复制功能,保证UE的处理效率。
实施例五、
本发明实施例提供了一种主节点,如图6所示,包括:
第二通信单元61,与辅助节点协商,确定开启或关闭目标UE的至少一个数据无线承载的数据复制传输功能;以及发送所述第一控制信息至所述目标UE;
第二处理单元62,基于所述协商结果,确定所述主节点控制所述目标UE开启或关闭所述至少一个数据无线承载中的第一部分数据无线承载的数据复制功能,以及所述辅助节点控制所述目标UE开启或关闭所述至少一个数据无线承载中的第二部分数据无线承载的数据复制功能;其中,所述第一部分数据无线承载于所述第二部分数据无线承载至少部分不同;基于确定开启或关闭的所述第一部分数据无线承载DRB的数据复制功能,生成第一控制信息。
这里,所述主节点可以为主小区群组(MCG)中的节点,辅助节点可以为辅助小区群组(SCG)中的节点。
网络侧的MCG的主节点和SCG的辅助节点可以通过Xn接口进行协商,以确定控制UE的一个或多个DRB复制数据功能开启或关闭。
进一步地,所述第二处理单元62,获取DRB的标识信息、与比特图的数据位之间的对应关系;
通过对比特图中与所述第一部分DRB的标识信息所对应的数据位进行设置,生成所述第一控制信息。
基于所述比特图格式的第一控制信息、以及DRB的标识信息之间的对应关系,确定所述第一控制信息所指示的第一部分DRB。和/或,基于所述比特图格式的第二控制信息、以及DRB的标识信息之间的对应关系,确定所述第二控制信息所指示的第二部分DRB。
比如,bitmap格式的第一控制信息中包括8bit,那么可以每一个bit对应一个DRB的标识信息;假设可以bit1-3分别对应DRB1、4、7,然后剩余的bite4-8为无效bit。那么通过bimap就可以确定第一控制信息指示了哪个DRB的开启或关闭。再进一步地,可以设置bitmap中的某一个bit位为0表示关闭DRB的数据传输复制功能,bit位为1的时候可以表示开启DRB的数据传输复制功能。当然还可以反之设置,只是本实施例中不进行穷举。
另外,第二控制信息的bitmap中bit1-3可以分别对应DRB的标识1、3、7,剩余bit位可以为无效位。关于bit位的含义与前述的设置方式相同,不再进行赘述。
所述DRB包含三种类型:MCG bearer,SCG bearer和Split bearer;MN发送的MAC CE负责控制MCG bearer和Split bearer的数据复制功能的开启或关闭;SN发送的MAC CE负责控制SCG bearer和split bearer的数据复制功能开启或关闭。
主节点和辅助节点进行协商,可以包括:
第二处理单元62,当针对目标DRB为主小区承载时,确定由主节点通过第一控制信息对其进行控制;目标DRB可以理解为UE的多个DRB中的任意一个;
第二处理单元62,当针对目标DRB为辅助小区承载时,确定由辅助节点通过第二控制信息对其进行控制;目标DRB可以理解为UE的多个DRB中的任意一个;
第二处理单元62,当目标DRB作为分叉承载时,基于所述DRB的PDCP 所在群组对应的节点为主节点或辅助节点,确定由主节点或辅助节点生成控制信息以控制所述目标DRB的数据复制功能的开启或关闭。也就是说,根据DRB所的PDCP所在群组,确定该DRB对应的控制信息为主节点发出的第一控制信息,还是辅助节点发出的第二控制信息。
第二处理单元62,当目标DRB作为分叉承载时,基于所述目标DRB所对应的默认传输路径,确定由所述默认传输路径之外的主节点或辅助节点生成控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。也就是说,根据DRB所对应的默认传输路径,确定该DRB对应的控制信息为主节点发出的第一控制信息,还是辅助节点发出的第二控制信息。
第二处理单元62,当目标DRB作为分叉承载时,基于所述目标DRB的PDCP版本,确定与所述PDCP版本相对应的主节点或辅助节点生成控制信息,以通过控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。也就是说,根据DRB的PDCP版本,确定该DRB对应的控制信息为主节点发出的第一控制信息,还是辅助节点发出的第二控制信息。
下面举例说明本实施例提供的方案:
DRB与MAC CE bitmap的对应按照DRB ID的升序或者降序对应;
比如,UE的DRB ID 1,3,4,7分别具有PDCP复制数据传输功能;其中DRB ID 1为MCG bearer,DRB ID 3为SCG bearer,DRB ID 4和7为split bearer;
网络侧MCG和SCG通过协作,可以确定DRB ID 1,4,7分别对应MN发送的MAC CE的bitmap中的1,2,3位,其余4,5,6,7,8位为无效位;
确定DRB ID 3,4,7分别对应SN发送的MAC CE的bitmap中的1,2,3位,其余4,5,6,7,8位为无效位。
可见,通过采用上述方案,就能够使得UE侧根据主节点和/或辅助节点发来的第一控制信息和/或第二控制信息,确定是否开启或关闭自身的至 少一个DRB的数据传输复制功能。如此,就在双连接的场景下,使得UE能够确定收到两个节点发来的控制信息之后,判断具体开启哪些DRB的数据传输复制功能,保证UE的处理效率。
实施例六、
本发明实施例提供了一种辅助节点,如图7所示,包括:
第三通信单元71,与主节点协商,确定是否开启或关闭目标UE的至少一个数据无线承载的数据复制传输功能;以及发送第二控制信息至所述目标UE;
第三处理单元72,基于所述协商结果,确定所述主节点控制所述目标UE开启或关闭所述至少一个数据无线承载中的第一部分数据无线承载DRB的数据复制功能,以及所述辅助节点控制所述目标UE开启所述至少一个DRB中的第二部分数据无线承载的数据复制功能;其中,所述第一部分DRB与所述第二部分DRB至少部分不同;基于确定开启或关闭的所述第二部分DRB的数据复制功能,生成第二控制信息。
这里,所述主节点可以为主小区群组(MCG)中的节点,辅助节点可以为辅助小区群组(SCG)中的节点。
网络侧的MCG的主节点和SCG的辅助节点可以通过Xn接口进行协商,以确定控制UE的一个或多个DRB复制数据功能开启或关闭。
进一步地,所述第三处理单元72,获取DRB的标识信息、与比特图的数据位之间的对应关系;
通过对比特图中与所述第二部分DRB的标识信息所对应的数据位进行设置,生成所述第二控制信息。
比如,bitmap格式的第一控制信息中包括8bit,那么可以每一个bit对应一个DRB的标识信息;假设可以bit1-3分别对应DRB1、4、7,然后剩余的bite4-8为无效bit。那么通过bimap就可以确定第一控制信息指示了哪 个DRB的开启或关闭。再进一步地,可以设置bitmap中的某一个bit位为0表示关闭DRB的数据传输复制功能,bit位为1的时候可以表示开启DRB的数据传输复制功能。当然还可以反之设置,只是本实施例中不进行穷举。
另外,第二控制信息的bitmap中bit1-3可以分别对应DRB的标识1、3、7,剩余bit位可以为无效位。关于bit位的含义与前述的设置方式相同,不再进行赘述。
所述DRB包含三种类型:MCG bearer,SCG bearer和Split bearer;MN发送的MAC CE负责控制MCG bearer和Split bearer的数据复制功能的开启或关闭;SN发送的MAC CE负责控制SCG bearer和split bearer的数据复制功能开启或关闭。
主节点和辅助节点进行协商,可以包括:
第三处理单元72,当针对目标DRB为主小区承载时,确定由主节点通过第一控制信息对其进行控制;目标DRB可以理解为UE的多个DRB中的任意一个;
第三处理单元72,当针对目标DRB为辅助小区承载时,确定由辅助节点通过第二控制信息对其进行控制;目标DRB可以理解为UE的多个DRB中的任意一个;
第三处理单元72,当目标DRB作为分叉承载时,基于所述DRB的PDCP所在群组对应的节点为主节点或辅助节点,确定由主节点或辅助节点生成控制信息以控制所述目标DRB的数据复制功能的开启或关闭。也就是说,根据DRB所的PDCP所在群组,确定该DRB对应的控制信息为主节点发出的第一控制信息,还是辅助节点发出的第二控制信息。
第三处理单元72,当目标DRB作为分叉承载时,基于所述目标DRB所对应的默认传输路径,确定由所述默认传输路径之外的主节点或辅助节点生成控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。也 就是说,根据DRB所对应的默认传输路径,确定该DRB对应的控制信息为主节点发出的第一控制信息,还是辅助节点发出的第二控制信息。
第三处理单元72,当目标DRB作为分叉承载时,基于所述目标DRB的PDCP版本,确定与所述PDCP版本相对应的主节点或辅助节点生成控制信息,以通过控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。也就是说,根据DRB的PDCP版本,确定该DRB对应的控制信息为主节点发出的第一控制信息,还是辅助节点发出的第二控制信息。
下面举例说明本实施例提供的方案:
DRB与MAC CE bitmap的对应按照DRB ID的升序或者降序对应;
比如,UE的DRB ID 1,3,4,7分别具有PDCP复制数据传输功能;其中DRB ID 1为MCG bearer,DRB ID 3为SCG bearer,DRB ID 4和7为split bearer;
网络侧MCG和SCG通过协作,可以确定DRB ID 1,4,7分别对应MN发送的MAC CE的bitmap中的1,2,3位,其余4,5,6,7,8位为无效位;
确定DRB ID 3,4,7分别对应SN发送的MAC CE的bitmap中的1,2,3位,其余4,5,6,7,8位为无效位。
可见,通过采用上述方案,就能够使得UE侧根据主节点和/或辅助节点发来的第一控制信息和/或第二控制信息,确定是否开启或关闭自身的至少一个DRB的数据传输复制功能。如此,就在双连接的场景下,使得UE能够确定收到两个节点发来的控制信息之后,判断具体开启哪些DRB的数据传输复制功能,保证UE的处理效率。
本发明实施例还提供了一种用户设备UE、或节点的硬件组成架构,如图8所示,包括:至少一个处理器81、存储器82、至少一个网络接口83。各个组件通过总线系统84耦合在一起。可理解,总线系统84用于实现这些组件之间的连接通信。总线系统84除包括数据总线之外,还包括电源总 线、控制总线和状态信号总线。但是为了清楚说明起见,在图8中将各种总线都标为总线系统84。
可以理解,本发明实施例中的存储器82可以是易失性存储器或非易失性存储器,或可包括易失性和非易失性存储器两者。
在一些实施方式中,存储器82存储了如下的元素,可执行模块或者数据结构,或者他们的子集,或者他们的扩展集:
操作系统821和应用程序822。
其中,所述处理器81配置为:能够处理前述实施例一至实施例三任一个实施例的方法步骤,这里不再进行赘述。
本发明实施例提供的一种计算机存储介质,所述计算机存储介质存储有计算机可执行指令,所述计算机可执行指令被执行时实施前述实施例一至实施例三任一个实施例的方法步骤。
本发明实施例上述装置如果以软件功能模块的形式实现并作为独立的产品销售或使用时,也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,本发明实施例的技术方案本质上或者说对现有技术做出贡献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、或者主节点、辅助节点等)执行本发明各个实施例所述方法的全部或部分。而前述的存储介质包括:U盘、移动硬盘、只读存储器(ROM,Read Only Memory)、磁碟或者光盘等各种可以存储程序代码的介质。这样,本发明实施例不限制于任何特定的硬件和软件结合。
相应地,本发明实施例还提供一种计算机存储介质,其中存储有计算机程序,该计算机程序配置为执行本发明实施例的数据调度方法。
尽管为示例目的,已经公开了本发明的优选实施例,本领域的技术人员将意识到各种改进、增加和取代也是可能的,因此,本发明的范围应当 不限于上述实施例。

Claims (71)

  1. 一种数据复制传输的控制方法,应用于用户设备UE,包括:
    接收主节点发来的第一控制信息,和/或,接收辅助节点发来的第二控制信息;
    基于所述第一控制信息所对应的第一部分数据无线承载DRB的指示、和/或、基于所述第二控制信息所对应的第二部分DRB的指示,确定开启或关闭至少一个DRB的数据复制传输功能。
  2. 根据权利要求1所述的方法,其中,所述接收主节点发来的第一控制信息,和/或,接收辅助节点发来的第二控制信息,包括:
    接收所述主节点发来的比特图格式的第一控制信息;和/或,接收所述辅助节点发来的比特图格式的第二控制信息。
  3. 根据权利要求2所述的方法,其中,所述方法还包括:
    基于所述比特图格式的第一控制信息、以及DRB的标识信息之间的对应关系,确定所述第一控制信息所指示的第一部分DRB。
  4. 根据权利要求2所述的方法,其中,所述方法还包括:
    基于所述比特图格式的第二控制信息、以及DRB的标识信息之间的对应关系,确定所述第二控制信息所指示的第二部分DRB。
  5. 根据权利要求1-4任一项所述的方法,其中,所述基于所述第一控制信息所对应的第一部分数据无线承载DRB的指示、和/或、基于所述第二控制信息所对应的第二部分DRB的指示,确定开启或关闭至少一个DRB的数据复制传输功能,包括:
    当所述第一控制信息对应的第一部分DRB中,包含有作为主小区承载的第一DRB时,确定基于所述第一控制信息的指示,开启或关闭所述第一DRB的数据复制传输功能。
  6. 根据权利要求5所述的方法,其中,所述第一DRB不包含在第二 部分DRB中。
  7. 根据权利要求1-4任一项所述的方法,其中,所述基于所述第一控制信息所对应的第一部分数据无线承载DRB的指示、和/或、基于所述第二控制信息所对应的第二部分DRB的指示,确定开启或关闭至少一个DRB的数据复制传输功能,包括:
    当所述第二控制信息对应的第二部分DRB中,包含有作为辅助小区承载的第二DRB时,确定基于所述第二控制信息的指示,开启或关闭所述第二DRB的数据复制传输功能。
  8. 根据权利要求7所述的方法,其中,所述第二DRB不包含在第一部分DRB中。
  9. 根据权利要求1-4任一项所述的方法,其中,所述基于所述第一控制信息所对应的第一部分数据无线承载DRB的指示、和/或、基于所述第二控制信息所对应的第二部分DRB的指示,确定开启或关闭至少一个DRB的数据复制传输功能,包括:
    当所述第一控制信息对应的第一部分DRB中,包含有作为分叉承载的第三DRB时,和/或,当所述第二控制信息对应的第二部分DRB中,包含有作为分叉承载的第三DRB时,
    基于预设条件,确定开启或关闭所述第三DRB的数据复制传输功能。
  10. 根据权利要求9所述的方法,其中,所述预设条件包含以下至少之一:
    基于所述第三DRB的PDCP所在群组,确定由所述群组所对应的节点发来的控制信息来控制开启或关闭所述第三DRB的数据复制传输功能;
    基于所述第三DRB所对应的默认传输路径,确定由所述默认传输路径之外的控制节点所对应的控制信息来控制开启或关闭所述第三DRB的数据复制传输功能;
    基于所述第三DRB的PDCP版本,来确定与所述PDCP版本相对应的节点发来的控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。
  11. 根据权利要求10所述的方法,其中,所述方法还包括:
    获取第三DRB对应的密钥值,基于所述第三DRB对应的密钥值确定所述第三SRB的PDCP所在群组。
  12. 根据权利要求10所述的方法,其中,所述第三DRB的PDCP版本为以下之一:
    LTE PDCP的版本、NR PDCP版本。
  13. 根据权利要求10所述的方法,其中,所述默认传输路径为当复制数据传输功能处于去激活状态时所采用的路径。
  14. 根据权利要求1所述的方法,其中,所述方法还包括:
    根据预设规则,确定所述至少一个DRB中的每一个DRB对应于第一控制信息或第二控制信息。
  15. 根据权利要求14所述的方法,其中,所述预设规则包括以下至少之一:
    当DRB为主小区承载时,所述DRB包含在所述第一控制信息对应的第一部分DRB中;
    当DRB为辅助小区承载时,所述DRB包含在所述第二控制信息对应的第二部分DRB中。
  16. 根据权利要求15所述的方法,其中,当所述DRB为主小区承载时,不包含在第二部分DRB中。
  17. 根据权利要求15所述的方法,其中,当所述DRB为辅助小区承载时,不包含在第一部分DRB中。
  18. 根据权利要求14所述的方法,其中,所述预设规则还包括以下至 少之一:
    当DRB为分叉承载时,基于所述DRB的PDCP所在群组,确定由PDCP所在群组所对应的节点发来的控制信息所述DRB进行控制;
    当DRB为分叉承载时,基于所述DRB所对应的默认传输路径,确定由所述默认传输路径之外的节点发来的控制信息对所述DRB进行控制;
    当DRB为分叉承载时,基于所述DRB的PDCP版本,确定与所述PDCP版本相对应的节点发来的控制信息对所述DRB进行控制。
  19. 根据权利要求18所述的方法,其中,所述方法还包括:
    当DRB为分叉承载时,基于所述DRB的PDCP所在群组,确定DRB所不在群组对应的节点发出的控制信息不能够对所述DRB进行控制。
  20. 根据权利要求18所述的方法,其中,所述方法还包括:
    当DRB为分叉承载时,基于所述DRB所对应的默认传输路径,确定由所述默认传输路径的节点发来的控制信息不能够对所述DRB进行控制。
  21. 根据权利要求18所述的方法,其中,所述方法还包括:
    当DRB为分叉承载时,基于所述DRB的PDCP版本,确定与所述PDCP版本不对应的节点发来的控制信息不能够对所述DRB进行控制。
  22. 根据权利要求18所述的方法,其中,所述方法还包括:
    获取第三DRB对应的密钥值,基于所述第三DRB对应的密钥值确定所述第三SRB的PDCP所在群组。
  23. 根据权利要求18所述的方法,其中,所述第三DRB的PDCP版本为以下之一:
    LTE PDCP的版本、NR PDCP版本。
  24. 根据权利要求18所述的方法,其中,所述默认传输路径为当复制数据传输功能处于去激活状态时所采用的路径。
  25. 一种数据复制传输的控制方法,应用于主节点,包括:
    与辅助节点协商,确定开启或关闭目标UE的至少一个数据无线承载的数据复制传输功能;
    基于所述协商结果,确定所述主节点控制所述目标UE开启或关闭所述至少一个数据无线承载中的第一部分数据无线承载的数据复制功能,以及所述辅助节点控制所述目标UE开启或关闭所述至少一个数据无线承载中的第二部分数据无线承载的数据复制功能;其中,所述第一部分数据无线承载于所述第二部分数据无线承载至少部分不同;
    基于确定开启或关闭的所述第一部分数据无线承载DRB的数据复制功能,生成第一控制信息,发送所述第一控制信息至所述目标UE。
  26. 根据权利要求25所述的方法,其中,所述基于确定开启或关闭的所述第一部分DRB的数据复制功能,生成第一控制信息,包括:
    获取DRB的标识信息、与比特图的数据位之间的对应关系;
    通过对比特图中与所述第一部分DRB的标识信息所对应的数据位进行设置,生成所述第一控制信息。
  27. 根据权利要求25所述的方法,其中,所述方法还包括:
    当目标DRB作为分叉承载时,基于所述DRB的PDCP所在群组对应的节点为主节点或辅助节点,确定由主节点或辅助节点生成控制信息以控制所述目标DRB的数据复制功能的开启或关闭。
  28. 根据权利要求25所述的方法,其中,所述方法还包括:
    当目标DRB作为分叉承载时,基于所述目标DRB所对应的默认传输路径,确定由所述默认传输路径之外的主节点或辅助节点生成控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。
  29. 根据权利要求25所述的方法,其中,所述方法还包括:
    当目标DRB作为分叉承载时,基于所述目标DRB的PDCP版本,确定与所述PDCP版本相对应的主节点或辅助节点生成控制信息,以通过控 制信息来控制开启或关闭所述第三DRB的数据复制传输功能。
  30. 一种数据复制传输功能的控制方法,应用于辅助节点,包括:
    与主节点协商,确定是否开启或关闭目标UE的至少一个数据无线承载的数据复制传输功能;
    基于所述协商结果,确定所述主节点控制所述目标UE开启或关闭所述至少一个数据无线承载中的第一部分数据无线承载DRB的数据复制功能,以及所述辅助节点控制所述目标UE开启所述至少一个DRB中的第二部分数据无线承载的数据复制功能;其中,所述第一部分DRB与所述第二部分DRB至少部分不同;
    基于确定开启或关闭的所述第二部分DRB的数据复制功能,生成第二控制信息,发送所述第二控制信息至所述目标UE。
  31. 根据权利要求30所述的方法,其中,所述生成第二控制信息,包括:
    获取DRB的标识信息、与比特图的数据位之间的对应关系;
    通过对比特图中与所述第二部分DRB的标识信息所对应的数据位进行设置,生成所述第二控制信息。
  32. 根据权利要求30所述的方法,其中,所述方法还包括:
    当目标DRB作为分叉承载时,基于所述DRB的PDCP所在群组对应的节点为主节点或辅助节点,确定由主节点或辅助节点生成控制信息以控制所述目标DRB的数据复制功能的开启或关闭。
  33. 根据权利要求30所述的方法,其中,所述方法还包括:
    当目标DRB作为分叉承载时,基于所述目标DRB所对应的默认传输路径,确定由所述默认传输路径之外的主节点或辅助节点生成控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。
  34. 根据权利要求30所述的方法,其中,所述方法还包括:
    当目标DRB作为分叉承载时,基于所述目标DRB的PDCP版本,确定与所述PDCP版本相对应的主节点或辅助节点生成控制信息,以通过控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。
  35. 一种UE,包括:
    第一通信单元,接收主节点发来的第一控制信息,和/或,接收辅助节点发来的第二控制信息;
    第一处理单元,基于所述第一控制信息所对应的第一部分数据无线承载DRB的指示、和/或、基于所述第二控制信息所对应的第二部分DRB的指示,确定开启或关闭至少一个DRB的数据复制传输功能。
  36. 根据权利要求35所述的UE,其中,所述第一通信单元,接收所述主节点发来的比特图格式的第一控制信息;和/或,接收所述辅助节点发来的比特图格式的第二控制信息。
  37. 根据权利要求36所述的UE,其中,所述第一处理单元,
    基于所述比特图格式的第一控制信息、以及DRB的标识信息之间的对应关系,确定所述第一控制信息所指示的第一部分DRB。
  38. 根据权利要求36所述的UE,其中,所述第一处理单元,
    基于所述比特图格式的第二控制信息、以及DRB的标识信息之间的对应关系,确定所述第二控制信息所指示的第二部分DRB。
  39. 根据权利要求35-38任一项所述的UE,其中,所述第一处理单元,
    当所述第一控制信息对应的第一部分DRB中,包含有作为主小区承载的第一DRB时,确定基于所述第一控制信息的指示,开启或关闭所述第一DRB的数据复制传输功能。
  40. 根据权利要求39所述的UE,其中,所述第一DRB不包含在第二部分DRB中。
  41. 根据权利要求35-38任一项所述的UE,其中,所述第一处理单元, 当所述第二控制信息对应的第二部分DRB中,包含有作为辅助小区承载的第二DRB时,确定基于所述第二控制信息的指示,开启或关闭所述第二DRB的数据复制传输功能。
  42. 根据权利要求41所述的UE,其中,所述第二DRB不包含在第一部分DRB中。
  43. 根据权利要求35-38任一项所述的UE,其中,所述第一处理单元,当所述第一控制信息对应的第一部分DRB中,包含有作为分叉承载的第三DRB时,和/或,当所述第二控制信息对应的第二部分DRB中,包含有作为分叉承载的第三DRB时,
    基于预设条件,确定开启或关闭所述第三DRB的数据复制传输功能。
  44. 根据权利要求43所述的UE,其中,所述预设条件包含以下至少之一:
    基于所述第三DRB的PDCP所在群组,确定由所述群组所对应的节点发来的控制信息来控制开启或关闭所述第三DRB的数据复制传输功能;
    基于所述第三DRB所对应的默认传输路径,确定由所述默认传输路径之外的控制节点所对应的控制信息来控制开启或关闭所述第三DRB的数据复制传输功能;
    基于所述第三DRB的PDCP版本,来确定与所述PDCP版本相对应的节点发来的控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。
  45. 根据权利要求44所述的UE,其中,所述第一处理单元,获取第三DRB对应的密钥值,基于所述第三DRB对应的密钥值确定所述第三SRB的PDCP所在群组。
  46. 根据权利要求44所述的UE,其中,所述第三DRB的PDCP版本为以下之一:
    LTE PDCP的版本、NR PDCP版本。
  47. 根据权利要求44所述的UE,其中,所述默认传输路径为当复制数据传输功能处于去激活状态时所采用的路径。
  48. 根据权利要求35所述的UE,其中,所述第一处理单元,根据预设规则,确定所述至少一个DRB中的每一个DRB对应于第一控制信息或第二控制信息。
  49. 根据权利要求48所述的UE,其中,所述预设规则包括以下至少之一:
    当DRB为主小区承载时,所述DRB包含在所述第一控制信息对应的第一部分DRB中;
    当DRB为辅助小区承载时,所述DRB包含在所述第二控制信息对应的第二部分DRB中。
  50. 根据权利要求49所述的UE,其中,当所述DRB为主小区承载时,不包含在第二部分DRB中。
  51. 根据权利要求49所述的UE,其中,当所述DRB为辅助小区承载时,不包含在第一部分DRB中。
  52. 根据权利要求48所述的UE,其中,所述预设规则还包括以下至少之一:
    当DRB为分叉承载时,基于所述DRB的PDCP所在群组,确定由PDCP所在群组所对应的节点发来的控制信息所述DRB进行控制;
    当DRB为分叉承载时,基于所述DRB所对应的默认传输路径,确定由所述默认传输路径之外的节点发来的控制信息对所述DRB进行控制;
    当DRB为分叉承载时,基于所述DRB的PDCP版本,确定与所述PDCP版本相对应的节点发来的控制信息对所述DRB进行控制。
  53. 根据权利要求52所述的UE,其中,所述第一处理单元,当DRB 为分叉承载时,基于所述DRB的PDCP所在群组,确定DRB所不在群组对应的节点发出的控制信息不能够对所述DRB进行控制。
  54. 根据权利要求52所述的UE,其中,所述第一处理单元,当DRB为分叉承载时,基于所述DRB所对应的默认传输路径,确定由所述默认传输路径的节点发来的控制信息不能够对所述DRB进行控制。
  55. 根据权利要求52所述的UE,其中,所述第一处理单元,当DRB为分叉承载时,基于所述DRB的PDCP版本,确定与所述PDCP版本不对应的节点发来的控制信息不能够对所述DRB进行控制。
  56. 根据权利要求55所述的UE,其中,所述第一处理单元,获取第三DRB对应的密钥值,基于所述第三DRB对应的密钥值确定所述第三SRB的PDCP所在群组。
  57. 根据权利要求55所述的UE,其中,所述第三DRB的PDCP版本为以下之一:
    LTE PDCP的版本、NR PDCP版本。
  58. 根据权利要求55所述的UE,其中,所述默认传输路径为当复制数据传输功能处于去激活状态时所采用的路径。
  59. 一种主节点,包括:
    第二通信单元,与辅助节点协商,确定开启或关闭目标UE的至少一个数据无线承载的数据复制传输功能;以及发送所述第一控制信息至所述目标UE;
    第二处理单元,基于所述协商结果,确定所述主节点控制所述目标UE开启或关闭所述至少一个数据无线承载中的第一部分数据无线承载的数据复制功能,以及所述辅助节点控制所述目标UE开启或关闭所述至少一个数据无线承载中的第二部分数据无线承载的数据复制功能;其中,所述第一部分数据无线承载于所述第二部分数据无线承载至少部分不同;基于确定 开启或关闭的所述第一部分数据无线承载DRB的数据复制功能,生成第一控制信息。
  60. 根据权利要求59所述的主节点,其中,所述第二处理单元,获取DRB的标识信息、与比特图的数据位之间的对应关系;
    通过对比特图中与所述第一部分DRB的标识信息所对应的数据位进行设置,生成所述第一控制信息。
  61. 根据权利要求59所述的主节点,其中,所述第二处理单元,当目标DRB作为分叉承载时,基于所述DRB的PDCP所在群组对应的节点为主节点或辅助节点,确定由主节点或辅助节点生成控制信息以控制所述目标DRB的数据复制功能的开启或关闭。
  62. 根据权利要求59所述的主节点,其中,所述第二处理单元,当目标DRB作为分叉承载时,基于所述目标DRB所对应的默认传输路径,确定由所述默认传输路径之外的主节点或辅助节点生成控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。
  63. 根据权利要求59所述的主节点,其中,所述第二处理单元,当目标DRB作为分叉承载时,基于所述目标DRB的PDCP版本,确定与所述PDCP版本相对应的主节点或辅助节点生成控制信息,以通过控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。
  64. 一种辅助节点,包括:
    第三通信单元,与主节点协商,确定是否开启或关闭目标UE的至少一个数据无线承载的数据复制传输功能;以及发送第二控制信息至所述目标UE;
    第三处理单元,基于所述协商结果,确定所述主节点控制所述目标UE开启或关闭所述至少一个数据无线承载中的第一部分数据无线承载DRB的数据复制功能,以及所述辅助节点控制所述目标UE开启或关闭所述至少一 个DRB中的第二部分数据无线承载的数据复制功能;其中,所述第一部分DRB与所述第二部分DRB至少部分不同;基于确定开启或关闭的所述第二部分DRB的数据复制功能,生成第二控制信息。
  65. 根据权利要求64所述的辅助节点,其中,所述第三处理单元,获取DRB的标识信息、与比特图的数据位之间的对应关系;
    通过对比特图中与所述第二部分DRB的标识信息所对应的数据位进行设置,生成所述第二控制信息。
  66. 根据权利要求64所述的辅助节点,其中,所述第三处理单元,当目标DRB作为分叉承载时,基于所述DRB的PDCP所在群组对应的节点为主节点或辅助节点,确定由主节点或辅助节点生成控制信息以控制所述目标DRB的数据复制功能的开启或关闭。
  67. 根据权利要求64所述的辅助节点,其中,所述第三处理单元,当目标DRB作为分叉承载时,基于所述目标DRB所对应的默认传输路径,确定由所述默认传输路径之外的主节点或辅助节点生成控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。
  68. 根据权利要求64所述的辅助节点,其中,所述第三处理单元,当目标DRB作为分叉承载时,基于所述目标DRB的PDCP版本,确定与所述PDCP版本相对应的主节点或辅助节点生成控制信息,以通过控制信息来控制开启或关闭所述第三DRB的数据复制传输功能。
  69. 一种UE,包括:处理器和用于存储能够在处理器上运行的计算机程序的存储器,
    其中,所述处理器用于运行所述计算机程序时,执行权利要求1-24任一项所述方法的步骤。
  70. 一种节点,包括:处理器和用于存储能够在处理器上运行的计算机程序的存储器,
    其中,所述处理器用于运行所述计算机程序时,执行权利要求25-34任一项所述方法的步骤。
  71. 一种计算机存储介质,所述计算机存储介质存储有计算机可执行指令,所述计算机可执行指令被执行时实现权利要求1-15任一项所述的方法步骤。
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