WO2018202075A1 - 一种测量间隔的配置方法、节点及终端 - Google Patents

一种测量间隔的配置方法、节点及终端 Download PDF

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Publication number
WO2018202075A1
WO2018202075A1 PCT/CN2018/085448 CN2018085448W WO2018202075A1 WO 2018202075 A1 WO2018202075 A1 WO 2018202075A1 CN 2018085448 W CN2018085448 W CN 2018085448W WO 2018202075 A1 WO2018202075 A1 WO 2018202075A1
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WIPO (PCT)
Prior art keywords
measurement interval
node
terminal
configuration
measurement
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PCT/CN2018/085448
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English (en)
French (fr)
Inventor
陈力
杨晓东
Original Assignee
维沃移动通信有限公司
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
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Publication date
Application filed by 维沃移动通信有限公司 filed Critical 维沃移动通信有限公司
Priority to EP18794465.7A priority Critical patent/EP3637835B1/en
Priority to ES18794465T priority patent/ES2901884T3/es
Priority to US16/610,792 priority patent/US11523294B2/en
Publication of WO2018202075A1 publication Critical patent/WO2018202075A1/zh
Priority to US17/523,255 priority patent/US11917443B2/en
Priority to US18/414,215 priority patent/US20240155396A1/en

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    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W24/00Supervisory, monitoring or testing arrangements
    • H04W24/10Scheduling measurement reports ; Arrangements for measurement reports
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W24/00Supervisory, monitoring or testing arrangements
    • H04W24/08Testing, supervising or monitoring using real traffic
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L41/00Arrangements for maintenance, administration or management of data switching networks, e.g. of packet switching networks
    • H04L41/08Configuration management of networks or network elements
    • H04L41/0803Configuration setting
    • H04L41/0806Configuration setting for initial configuration or provisioning, e.g. plug-and-play
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04WWIRELESS COMMUNICATION NETWORKS
    • H04W48/00Access restriction; Network selection; Access point selection
    • H04W48/16Discovering, processing access restriction or access information

Definitions

  • the present disclosure relates to the field of communications technologies, and in particular, to a method, a node, and a terminal for configuring a measurement interval.
  • the measurements are divided into intra-frequency measurements and inter-frequency measurements.
  • the so-called intra-frequency measurement refers to the cell where the terminal (UE) is currently located and the target cell to be measured are at the same carrier frequency (central frequency point).
  • the inter-frequency measurement means that the cell where the UE is currently located and the target cell are not at a carrier frequency.
  • 3GPP proposes a measurement interval (Measurement Gap, MG), in which a part of time (ie, measurement interval time) is reserved during normal data transmission and reception, during which the UE does not send and receive any data. And the receiver is tuned to the target cell frequency point, and the inter-frequency (or heterogeneous) measurement is performed.
  • the measurement gap time ends, the data is transferred to the current serving cell, and data transmission and reception is continued.
  • the carrier frequency of the current cell and the target cell are different, the target cell bandwidth is smaller than the current cell bandwidth, and the target cell bandwidth is within the current cell bandwidth: this scenario belongs to the inter-frequency measurement, and the GAP needs to be measured.
  • the carrier frequency of the current cell and the target cell are different, the target cell bandwidth is greater than the current cell bandwidth, and the current cell bandwidth is within the target cell bandwidth: the scenario belongs to the inter-frequency measurement, and the GAP needs to be measured.
  • the carrier frequency of the current cell and the target cell are different, and the target cell bandwidth does not overlap with the current cell bandwidth: this scenario belongs to the inter-frequency measurement, and the GAP needs to be measured.
  • the UE and the network In order to enable the UE to determine when to perform inter-frequency measurement or to perform data transmission and reception, the UE and the network must have consistent understanding of the configuration of the Measurement Gap (eg, gap start position, gap length, number of gaps, etc.), and these parameters are controlled by radio resources (RRC).
  • RRC radio resources
  • the above measurement gaps are all configured for the terminal (per-UE), that is, each UE has its own separate measurement gap.
  • a measurement gap for a component carrier (per-CC) corresponding to a terminal is proposed, that is, each measurement carrier is configured with a measurement gap.
  • each measurement carrier is configured with a measurement gap.
  • dual connectivity Dual Connectivity, DualCo, DC
  • MCG primary cell group
  • SCG secondary cell group
  • MgNB primary base station
  • SeNB or SgNB secondary base station
  • Each cell (cell) corresponds to a component carrier
  • the Per-CC measurement gap is a separate measurement gap for each component carrier.
  • a measurement gap for each cell group (per-CG) corresponding to the terminal is also proposed. That is, the MCG and the SCG can each configure a measurement gap for the same UE, that is, all the cells (or component carriers) under the MCG (or SCG) use the measurement gap.
  • per-UE per-UE
  • per-CG per-CG
  • per-CC measurement gap correspond to coarse to fine, respectively.
  • the DC architecture After the introduction of the 5G system, the DC architecture will be adopted to improve the transmission reliability.
  • a dual-connected architecture is used with LTE to meet interworking requirements.
  • the measurement gap is configured by the per-UE, that is, each UE is configured with a measurement gap, and all are configured through the MeNB.
  • the first phase mainly uses the LTE base station as the MeNB, that is, the MN, and the NR base station gNB as the SeNB. It is SN.
  • the scheme for coordinating the measurement interval between the secondary base station and the secondary base station and the primary base station is not implemented, and the integrity of the 5G NR communication cannot be guaranteed, and the reliability of the network communication cannot be guaranteed.
  • the embodiments of the present disclosure provide a method, a node, and a terminal for configuring a measurement interval, which are used to solve the problem that the NR does not implement the measurement interval of the secondary base station and the secondary base station and the primary base station, and the network communication process is incomplete, and the network cannot be guaranteed.
  • the issue of reliability and effectiveness of communications is not due to the NR to the measurement interval of the secondary base station and the secondary base station and the primary base station.
  • an embodiment of the present disclosure provides a method for configuring a measurement interval, which is applied to a first node, and includes:
  • the measurement interval includes at least one of a measurement interval for the terminal per-UE, a measurement interval for each cell group per-CG corresponding to the terminal, and a measurement interval for the component carrier per-CC corresponding to the terminal.
  • An embodiment of the present disclosure provides a method for configuring a measurement interval, which is applied to a second node, and includes:
  • the measurement interval includes at least one of a measurement interval for the terminal per-UE, a measurement interval for each cell group per-CG corresponding to the terminal, and a measurement interval for the component carrier per-CC corresponding to the terminal.
  • An embodiment of the present disclosure provides a method for configuring a measurement interval, which is applied to a terminal, and includes:
  • the measurement interval includes at least one of a measurement interval for the terminal per-UE, a measurement interval for each cell group per-CG corresponding to the terminal, and a measurement interval for the component carrier per-CC corresponding to the terminal.
  • An embodiment of the present disclosure provides a first node, including:
  • a first configuration module configured to perform measurement interval configuration for the terminal
  • the measurement interval includes at least one of a measurement interval for the terminal per-UE, a measurement interval for each cell group per-CG corresponding to the terminal, and a measurement interval for the component carrier per-CC corresponding to the terminal.
  • An embodiment of the present disclosure provides a second node, including:
  • a second receiving module configured to receive configuration content of a measurement interval sent by the first node, where the measurement interval is configured by the first node as a terminal;
  • the measurement interval includes at least one of a measurement interval for the terminal per-UE, a measurement interval for each cell group per-CG corresponding to the terminal, and a measurement interval for the component carrier per-CC corresponding to the terminal.
  • An embodiment of the present disclosure provides a terminal, including:
  • a third receiving module configured to receive a measurement interval configured by the first node and/or the second node
  • the measurement interval includes at least one of a measurement interval for the terminal per-UE, a measurement interval for each cell group per-CG corresponding to the terminal, and a measurement interval for the component carrier per-CC corresponding to the terminal.
  • An embodiment of the present disclosure provides a first node, including a processor, a memory, and a network access program stored on the memory and operable on the processor, where the network access program is executed by the processor.
  • An embodiment of the present disclosure provides a second node, including a processor, a memory, and a network access program stored on the memory and operable on the processor, where the network access program is executed by the processor.
  • An embodiment of the present disclosure provides a terminal, including a processor, a memory, and a network access program stored on the memory and operable on the processor, where the network access program is implemented by the processor The steps of the configuration method of the measurement interval described above.
  • An embodiment of the present disclosure provides a computer readable storage medium, wherein the computer readable storage medium stores a network access program, and when the network access program is executed by the processor, the configuration of the measurement interval is implemented. The steps of the method.
  • the above solution implements a scheme in which the secondary node and the primary node and the secondary node coordinately configure the measurement interval, thereby ensuring the integrity of the NR network communication process and ensuring the reliability and effectiveness of the network communication.
  • Figure 1 is a schematic diagram of a network architecture in a scenario of 5G NR and LTE non-standalone deployment;
  • FIG. 2 is a flow chart showing a method of configuring a measurement interval according to some embodiments of the present disclosure
  • FIG. 3 is a flow chart showing a method of configuring a measurement interval according to some embodiments of the present disclosure
  • FIG. 4 is a flow chart showing a method of configuring a measurement interval according to some embodiments of the present disclosure
  • FIG. 5 is a schematic structural diagram of a first node of some embodiments of the present disclosure.
  • FIG. 6 is a schematic structural diagram of a second node of some embodiments of the present disclosure.
  • FIG. 7 is a block diagram showing the structure of a terminal according to some embodiments of the present disclosure.
  • the present disclosure is directed to a scheme in which the secondary base station is not implemented in the NR, and the secondary base station and the primary base station are coordinated to configure the measurement interval, which causes the network communication process to be incomplete, and there is a problem that the reliability and validity of the network communication cannot be guaranteed, and a measurement interval configuration is provided.
  • Method, node and terminal are not implemented in the NR, and the secondary base station and the primary base station are coordinated to configure the measurement interval, which causes the network communication process to be incomplete, and there is a problem that the reliability and validity of the network communication cannot be guaranteed.
  • some embodiments of the present disclosure provide a method for configuring a measurement interval, which is applied to a first node, and includes:
  • Step 201 Perform a measurement interval configuration for the terminal.
  • the measurement interval includes at least one of a measurement interval for the terminal per-UE, a measurement interval for each cell group per-CG corresponding to the terminal, and a measurement interval for the component carrier per-CC corresponding to the terminal.
  • the configuration method of the measurement interval is mainly applied between a master node (MN) and a secondary node (SN), where the node refers to a network element on the access network side, for example, It may be an access network node (ie, a base station) under LTE, or may be an access network node in the NR.
  • the first node may represent a primary node or a secondary node, that is, the primary node may be a node under LTE.
  • the eNB may be a node under NR, and may also be a node under LTE or a node under NR.
  • the combination of the primary node and the secondary node may include: MeNB and SeNB, MeNB and SgNB, MgNB and SeNB, MgNB and SgNB.
  • Case 1 The configuration of the measurement interval is directly performed by the first node, and after the configuration of the first node is completed, the configuration content of the measurement interval is sent to the second node.
  • the optional implementation is:
  • the configuration content of the measurement interval is sent to the terminal, so that the terminal reports the configuration content of the measurement interval to the second node.
  • the first node may only configure the measurement interval associated with the first node, or may also configure the measurement interval associated with the second node; therefore, the configuration content of the measurement interval And including: at least one of a configuration content of a measurement interval of the terminal per-UE, a configuration content of a measurement interval corresponding to the first node, and a configuration content of a measurement interval corresponding to the second node;
  • the configuration content of the measurement interval corresponding to the first node includes: a configuration content of a measurement interval of each cell group per-CG corresponding to the terminal corresponding to the first node, and a measurement of a component carrier per-CC corresponding to the terminal At least one of the configuration contents of the interval;
  • the configuration content of the measurement interval corresponding to the second node includes: a configuration content of a measurement interval of each cell group per-CG corresponding to the terminal corresponding to the second node, and a measurement of a component carrier per-CC corresponding to the terminal At least one of the configured contents of the interval.
  • the configuration method of the measurement interval should also include:
  • the first node and the second node independently perform the configuration of the measurement interval, and after the configuration is completed, the configuration content is interworked between the two.
  • the optional implementation manner is:
  • the configuration method of the measurement interval further includes:
  • the request information includes at least one of a configuration request and a configuration policy.
  • the configuration request refers to a request for performing measurement interval configuration, that is, after receiving the configuration request, the first node knows that the measurement interval needs to be configured for the terminal;
  • the configuration policy refers to the second node.
  • the configuration content to be configured that is, the configuration of the measurement interval is performed in advance by the second node, and the measurement interval to be configured is sent to the first node, and the first node determines whether the configuration can be performed in this way.
  • the request information of the measurement interval is sent by the second node to the first node.
  • the second node does not perform the measurement interval configuration at the beginning, and the second node acquires
  • the request may be a request for the terminal to perform a measurement interval to the second node
  • the second node needs to send a request to the first node to request configuration of the measurement interval.
  • the manner of obtaining the request information of the measurement interval sent by the second node is:
  • the following processing may be performed:
  • the measurement interval includes: at least one of a measurement interval for the terminal per-UE, a measurement interval corresponding to the first node, and a measurement interval corresponding to the second node.
  • the second node may not send the measurement interval directly to the terminal.
  • the configured measurement interval may be sent to the terminal, and the configuration content of the configured measurement interval is also sent to the second node.
  • the first node when the first node sends the configuration content of the measurement interval to the second node, the first node may use the X1 interface or the S1 interface of the OAM architecture to transmit, or the terminal may forward the configuration content of the measurement interval to the second node.
  • the first node is directly configured with a per-UE measurement gap; if it is a per-CG measurement gap, the first node is configured with the first node and the per-CG under the second node.
  • the first node first determines how the second node needs to perform the measurement interval configuration, and then informs the second node of the configuration content of the measurement interval, and the second node configures the measurement interval for the terminal, and at the same time, the first The node also configures the measurement interval to which the terminal belongs.
  • the first node is configured with a Per-CG measurement gap under the first node
  • the second node is configured with a Per-CG measurement gap under the second node
  • the first node is configured with a measurement gap of all CCs under the first node
  • the second node is configured with a measurement gap of all CCs under the second node.
  • the first node first determines how the first node and the second node need to perform the measurement interval configuration, and then informs the second node of the configuration content of the measurement interval, and the second node configures the measurement interval for the terminal.
  • the second node when the second node is configured, if it is a per-UE measurement gap, the second node is directly configured with a per-UE measurement gap; if it is a Per-CG measurement gap, the second node is configured with the first node and the first node.
  • the Per-CG measurement gap under the two nodes; if it is a per-CC measurement gap, it is the measurement gap of the second node with all the CCs under the first node and the second node.
  • the first decision needs to be made.
  • the first measurement interval may be selected based on the lowest terminal capability; or further, if it is per-CG, The per-CG measurement gap of the first node is configured according to the first node, and the per-CG measurement gap of the second node is configured according to the second node; or if it is per-CC, all of the first node is The measurement gap of the CC is configured according to the first node, and the measurement gap of all the CCs under the second node is configured according to the second node.
  • the first node directly configures the terminal, and the second node does not need to participate in the configuration.
  • the second node may not send a measurement interval directly to the terminal.
  • the configured measurement interval may be sent to the terminal, and the configuration content of the configured measurement interval is also sent to the second node.
  • the first node when the first node sends the configuration content of the measurement interval to the second node, the first node may use the X1 interface or the S1 interface of the OAM architecture to transmit, or the terminal may forward the configuration content of the measurement interval to the second node.
  • the first node is directly configured with a per-UE measurement gap; if it is a per-CG measurement gap, the first node is configured with the first node and the per-CG under the second node.
  • the first node sends all configuration content to the second node, and the second node configures the terminal.
  • the second node when the second node is configured, if it is a per-UE measurement gap, the second node is directly configured with a per-UE measurement gap; if it is a Per-CG measurement gap, the second node is configured with the first node and the first node.
  • the Per-CG measurement gap under the two nodes; if it is a per-CC measurement gap, it is the measurement gap of the second node with all the CCs under the first node and the second node.
  • the first node sends the configuration content corresponding to the second node to the second node, where the first node and the second node respectively configure the terminal.
  • the first node if it is a Per-CG measurement gap, the first node is configured with a Per-CG measurement gap under the first node, and the second node is configured with a Per-CG measurement gap under the second node; if it is per -CC measurement gap, the first node is configured with the measurement gap of all CCs under the first node, and the second node is configured with the measurement gap of all CCs under the second node.
  • the specific implementation manner is: the first node sends the configuration policy of the measurement interval to the central control node, so that the central control node determines the configuration content of the measurement interval according to the configuration policy, and receives the configuration content fed back by the central control node.
  • the central control node is a network element in the core network or the access network.
  • the central control node may be a network element on the core network side.
  • the central control node When the central control node makes a decision, it can select the measurement interval to be used based on the lowest terminal capability, or the per-CG measurement gap of the first node if the central control node makes a decision, according to the first a node is configured, the per-CG measurement gap of the second node is configured according to the second node; or if it is per-CC, the measurement gap of all CCs under the first node is configured according to the first node, The measurement gap of all CCs under the second node is configured according to the second node.
  • the central control node can adopt the following processing methods:
  • the central control node sends the configuration content of the measurement interval determined according to the configuration policy to the first node, and the first node configures the measurement interval for the terminal;
  • the first node is directly configured with a per-UE measurement gap; if it is a per-CG measurement gap, the first node is configured with the first node and the second node is followed by per- CG measurement gap; if it is a per-CC measurement gap, it is a measurement gap of all CCs under the first node and the second node.
  • the central control node sends the configuration content of the measurement interval determined according to the configuration policy to the second node, and the second node configures the measurement interval for the terminal.
  • a per-UE measurement gap is directly configured by the second node; if it is a per-CG measurement gap, the second node is configured with the first node and the per-second node.
  • the central control node sends the configuration content of the measurement interval determined according to the configuration policy to the first node and the second node, and the first node and the second node respectively configure the measurement interval for the terminal;
  • the first node is configured with a Per-CG measurement gap under the first node
  • the second node is configured with a Per-CG measurement gap under the second node
  • the first node is configured with the measurement gap of all CCs under the first node
  • the second node is configured with the measurement gap of all CCs under the second node.
  • the measurement interval configuration related information includes: a measurement interval required by the terminal and/or a measurement interval supported by the terminal capability.
  • the terminal reports the measurement interval configuration information to the first node.
  • a per-UE measurement gap a per-UE measurement gap is directly reported; if it is a Per-CG measurement gap, the Per-CG measurement gap corresponding to the first node and the second node is directly reported; The per-CC measurement gap directly reports the per-CC measurement gap corresponding to the first node and the second node respectively.
  • the terminal reports the measurement interval configuration information to the second node.
  • a per-UE measurement gap a per-UE measurement gap is directly reported; if it is a Per-CG measurement gap, the Per-CG measurement gap corresponding to the first node and the second node is directly reported; The per-CC measurement gap directly reports the per-CC measurement gap corresponding to the first node and the second node respectively.
  • the terminal reports the measurement interval configuration information to the second node and the second node respectively.
  • the same per-UE measurement gap is directly reported; if it is a Per-CG measurement gap, the Per-CG measurement gap corresponding to the first node is reported to the first node, and the second The node reports the Per-CG measurement gap corresponding to the second node; if it is a per-CC measurement gap, reports the per-CC measurement gap corresponding to the first node to the first node, and reports the per- corresponding to the second node to the second node.
  • CC measurement gap if it is a per-UE measurement gap, the same per-UE measurement gap is directly reported; if it is a Per-CG measurement gap, the Per-CG measurement gap corresponding to the first node is reported to the first node, and the second The node reports the Per-CG measurement gap corresponding to the second node; if it is a per-CC measurement gap, reports the per-CC measurement gap corresponding to the first node to the first node, and reports the per- corresponding to the second node to the second node.
  • CC measurement gap
  • the terminal may report the target preset message or the auxiliary message, and correspondingly, the first node acquires the measurement interval configuration reported by the terminal in the target preset message or the auxiliary message sent by the terminal.
  • Information wherein the target preset message is a radio resource control RRC message or a capability report message.
  • the terminal may also enable the measurement interval configuration related information reporting timer; wherein, when the related measurement information reporting timer is configured, the information about the measurement interval configuration is stopped.
  • first node and the second node may also enable the reporting of the measurement interval configuration related information.
  • the specific implementation manner is: sending indication information of the measurement interval configuration related information to the terminal, where the indication information is used to indicate Whether the measurement of the interval configuration information is allowed to be reported.
  • the subsequent processing flow may also adopt the configuration policy in the second case to coordinate, and the specific implementation process is not described herein.
  • the first node is configured with a Per-CG measurement gap under the first node
  • the second node is configured with a Per-CG measurement gap under the second node
  • the measurement gap is configured by the first node with the measurement gap of all the CCs of the first node
  • the second node is configured with the measurement gap of all the CCs of the second node.
  • the method may further include the implementation process of the four terminal requests, that is, the terminal reports the required measurement gap to the first node, and the first node needs to report the second reported by the terminal.
  • the per-CG measurement gap or all the per-CC measurement gaps are sent to the second node (similar to the above-mentioned X2 interface or the S1 interface notification), and the terminal reports the required measurement gap to the second node, and the second node needs to report the terminal.
  • the first node under the per-CG measurement gap or all Per-CC measurement gaps notifies the first node (similar to the X2 interface or the S1 interface notification described above); or the terminal transmits the required measurement gap to the first node and the second node, respectively.
  • the terminal selects the measurement interval in the following manner: when the measurement interval is the measurement interval for the terminal per-UE, the measurement interval sent by the first node or the second node is selected; where the measurement interval is corresponding to the terminal Selecting a measurement interval corresponding to the first node sent by the first node, and selecting a measurement interval sent by the second node, when the measurement interval of each cell group per-CG and/or the measurement interval of the component carrier per-CC corresponding to the terminal The measurement interval corresponding to the second node.
  • first node side can be implemented on the second node side.
  • functions implemented on the second node side can be implemented on the first node side.
  • Some embodiments of the present disclosure implement a scheme in which a secondary node and a primary node and a secondary node coordinate configuration measurement intervals, which ensures the integrity of the NR network communication process and ensures the reliability and effectiveness of the network communication.
  • some embodiments of the present disclosure provide a method for configuring a measurement interval, which is applied to a second node, and includes:
  • Step 301 Receive configuration content of a measurement interval sent by the first node, where the measurement interval is configured by the first node as a terminal;
  • the measurement interval includes at least one of a measurement interval for the terminal per-UE, a measurement interval for each cell group per-CG corresponding to the terminal, and a measurement interval for the component carrier per-CC corresponding to the terminal.
  • the method further includes:
  • the configuration of the measurement interval is performed for the terminal according to the configuration content of the measurement interval.
  • the method for configuring the measurement interval further includes:
  • the configuration content of the measurement interval is sent to the first node.
  • step of sending the configuration content of the measurement interval to the first node includes:
  • the configuration content of the measurement interval is sent to the terminal, so that the terminal reports the configuration content of the measurement interval to the first node.
  • the step of receiving the configuration content of the measurement interval sent by the first node includes:
  • the configuration content of the measurement interval sent by the first node forwarded by the terminal is received.
  • the configuration content of the measurement interval includes: a configuration content of a measurement interval of the terminal per-UE, a configuration content of a measurement interval corresponding to the first node, and a configuration content of a measurement interval corresponding to the second node. At least one item;
  • the configuration content of the measurement interval corresponding to the first node includes: a configuration content of a measurement interval of each cell group per-CG corresponding to the terminal corresponding to the first node, and a measurement of a component carrier per-CC corresponding to the terminal At least one of the configuration contents of the interval;
  • the configuration content of the measurement interval corresponding to the second node includes: a configuration content of a measurement interval of each cell group per-CG corresponding to the terminal corresponding to the second node, and a measurement of a component carrier per-CC corresponding to the terminal At least one of the configured contents of the interval.
  • the step of receiving the configuration content of the measurement interval sent by the first node includes:
  • the request information includes at least one of a configuration request and a configuration policy.
  • step of sending the request information of the measurement interval of the second node to the first node includes:
  • the request information of the measurement interval of the second node is sent to the terminal, so that the terminal reports the request information of the measurement interval of the second node to the first node.
  • the method further includes:
  • the method for configuring the measurement interval further includes:
  • the measurement interval includes: a measurement interval corresponding to the first node and/or a measurement interval corresponding to the second node.
  • the method further includes:
  • the measurement interval includes: at least one of a measurement interval for the terminal per-UE, a measurement interval corresponding to the first node, and a measurement interval corresponding to the second node.
  • the method for configuring the measurement interval further includes:
  • the measurement interval configuration related information includes: a measurement interval required by the terminal and/or a measurement interval supported by the terminal capability.
  • the method further includes:
  • the step of receiving the configuration content of the measurement interval sent by the first node includes:
  • the method further includes:
  • the configuration of the measurement interval is performed for the terminal.
  • the method further includes:
  • the related information is configured according to the measurement interval, and the measurement interval is configured for the terminal.
  • the step of acquiring the measurement interval configuration related information reported by the terminal includes:
  • the target preset message is a radio resource control RRC message or a capability report message.
  • the method further includes:
  • the indication information of the measurement interval configuration related information is sent to the terminal, where the indication information is used to indicate whether the measurement of the measurement interval configuration related information is allowed.
  • the method further includes:
  • the configuration content of the measurement interval includes: a configuration content of a measurement interval corresponding to the second node.
  • the step of notifying the configuration content of the measurement interval to the first node includes:
  • the configuration content of the measurement interval is sent to the terminal, so that the terminal reports the configuration content of the measurement interval to the first node.
  • the method further includes:
  • the measurement interval includes at least one of a measurement interval for the terminal per-UE, a measurement interval corresponding to the first node, and a measurement interval corresponding to the second node.
  • some embodiments of the present disclosure further provide a method for configuring a measurement interval, which is applied to a terminal, including:
  • Step 401 Receive a measurement interval configured by the first node and/or the second node.
  • the measurement interval includes at least one of a measurement interval for the terminal per-UE, a measurement interval for each cell group per-CG corresponding to the terminal, and a measurement interval for the component carrier per-CC corresponding to the terminal.
  • the method when receiving the measurement interval sent by the first node, the method further includes:
  • the configuration content of the measurement interval includes: a configuration content of a measurement interval corresponding to the first node or a configuration content of a measurement interval corresponding to the first node and the second node respectively.
  • the method for configuring the measurement interval further includes:
  • the request information includes at least one of a configuration request and a configuration policy.
  • the method for configuring the measurement interval further includes:
  • the measurement interval configuration related information includes: a measurement interval required by the terminal and/or a measurement interval supported by the terminal capability.
  • the step of transmitting the measurement interval configuration related information to at least one of the first node and the second node includes:
  • the target preset message is a radio resource control RRC message or a capability report message.
  • the step of transmitting the measurement interval configuration related information to at least one of the first node and the second node includes:
  • the method for configuring the measurement interval further includes:
  • the information about the measurement interval configuration is stopped during the timing when the related information reporting timer is configured.
  • the step of transmitting the measurement interval configuration related information to at least one of the first node and the second node includes:
  • the measurement interval configuration related information is sent to at least one of the first node and the second node.
  • the method further includes:
  • the measurement interval is a measurement interval for each cell group per-CG corresponding to the terminal and/or a measurement interval for the component carrier per-CC corresponding to the terminal
  • the measurement corresponding to the first node sent by the first node is selected.
  • the interval between the second node and the second node is selected by the second node.
  • Some embodiments of the present disclosure also provide a first node, including:
  • a first configuration module configured to perform measurement interval configuration for the terminal
  • the measurement interval includes at least one of a measurement interval for the terminal per-UE, a measurement interval for each cell group per-CG corresponding to the terminal, and a measurement interval for the component carrier per-CC corresponding to the terminal.
  • the first node further includes:
  • the first sending module is configured to send the configuration content of the measurement interval to the second node.
  • the first sending module is configured to:
  • the configuration content of the measurement interval is sent to the terminal, so that the terminal reports the configuration content of the measurement interval to the second node.
  • the first node further includes:
  • the first receiving module is configured to receive configuration content of the measurement interval sent by the second node.
  • the first receiving module is configured to:
  • the configuration content of the measurement interval includes: a configuration content of a measurement interval of the terminal per-UE, a configuration content of a measurement interval corresponding to the first node, and a configuration content of a measurement interval corresponding to the second node. At least one item;
  • the configuration content of the measurement interval corresponding to the first node includes: a configuration content of a measurement interval of each cell group per-CG corresponding to the terminal corresponding to the first node, and a measurement of a component carrier per-CC corresponding to the terminal At least one of the configuration contents of the interval;
  • the configuration content of the measurement interval corresponding to the second node includes: a configuration content of a measurement interval of each cell group per-CG corresponding to the terminal corresponding to the second node, and a measurement of a component carrier per-CC corresponding to the terminal At least one of the configured contents of the interval.
  • the first node further includes:
  • a first acquiring module configured to acquire request information of a measurement interval sent by the second node
  • the request information includes at least one of a configuration request and a configuration policy.
  • the first obtaining module is configured to:
  • the first configuration module is configured to:
  • the measurement interval includes: at least one of a measurement interval for the terminal per-UE, a measurement interval corresponding to the first node, and a measurement interval corresponding to the second node.
  • the first node further includes:
  • a second sending module configured to send, to the second node, configuration content of the measurement interval corresponding to the second node.
  • the first node further includes:
  • the first determining module is configured to determine, according to the request information, a configuration content of a measurement interval corresponding to the second node.
  • the first node further includes:
  • a third sending module configured to send configuration content of the measurement interval corresponding to the second node to the second node.
  • the measurement interval configured by the first node for the terminal is a measurement interval corresponding to the first node.
  • the first node further includes:
  • a second determining module configured to determine, according to the request information, configuration content of a measurement interval corresponding to the first node and the second node.
  • the first node further includes:
  • a fourth sending module configured to send configuration content of the measurement interval corresponding to the first node and the second node to the second node.
  • the first node further includes:
  • a fifth sending module configured to send the configuration policy of the measurement interval to the central control node, so that the central control node determines the configuration content of the measurement interval according to the configuration policy, and receives the configuration content that is fed back by the central control node.
  • the first configuration module is configured to:
  • the measurement interval configured by the first node for the terminal is a measurement interval corresponding to the first node or the measurement interval configured by the first node for the terminal is a measurement interval corresponding to the first node and the second node respectively.
  • the measurement interval configuration related information includes: a measurement interval required by the terminal and/or a measurement interval supported by the terminal capability.
  • the first node further includes:
  • the sixth sending module is configured to send the measurement interval configuration related information corresponding to the first node in the measurement interval configuration related information and/or the measurement interval configuration related information corresponding to the second node to the second node.
  • the first node further includes:
  • a seventh sending module configured to send, to the second node, the configuration content of the measurement interval corresponding to the second node in the configured measurement interval and/or the configuration content of the measurement interval corresponding to the first node and the second node respectively.
  • the method for acquiring the relevant information of the measurement interval reported by the terminal is:
  • the target preset message is a radio resource control RRC message or a capability report message.
  • the first node further includes:
  • the eighth sending module is configured to send the indication information of the measurement interval configuration related information to the terminal, where the indication information is used to indicate whether to allow the reporting of the measurement interval configuration related information.
  • the first node further includes:
  • a ninth sending module configured to send the configured measurement interval to the terminal
  • the measurement interval includes at least one of a measurement interval for the terminal per-UE, a measurement interval corresponding to the first node, and a measurement interval corresponding to the second node.
  • FIG. 5 is a structural diagram of a first node of some embodiments of the present disclosure, which can implement the details of the above-described configuration method applied to the measurement interval of the first node side, and achieve the same effect.
  • the base station 500 includes a processor 501, a transceiver 502, a memory 503, and a bus interface, where:
  • the processor 501 is configured to read a program in the memory 503 and perform the following process:
  • the measurement interval includes at least one of a measurement interval for the terminal per-UE, a measurement interval for each cell group per-CG corresponding to the terminal, and a measurement interval for the component carrier per-CC corresponding to the terminal.
  • the bus architecture may include any number of interconnected buses and bridges, specifically linked by one or more processors represented by processor 501 and various circuits of memory represented by memory 503.
  • the bus architecture can also link various other circuits such as peripherals, voltage regulators, and power management circuits, which are well known in the art and, therefore, will not be further described herein.
  • the bus interface provides an interface.
  • Transceiver 502 can be a plurality of components, including a transmitter and a receiver, providing means for communicating with various other devices on a transmission medium.
  • the processor 501 is responsible for managing the bus architecture and general processing, and the memory 503 can store data used by the processor 501 in performing operations.
  • the processor 501 is further configured to: send the configuration content of the measurement interval to the second node by using the transceiver 502.
  • the processor 501 is further configured to: send, by using an X2 interface or an S1 interface that manages and manages the OAM architecture, the configuration content of the measurement interval to the second node; or
  • the configuration content of the measurement interval is sent to the terminal, so that the terminal reports the configuration content of the measurement interval to the second node.
  • the processor 501 is further configured to: receive, by the transceiver 502, configuration content of a measurement interval sent by the second node.
  • the processor 501 is further configured to: receive, by using an X2 interface or an S1 interface of the OAM architecture, configuration content of a measurement interval sent by the second node; or
  • the configuration content of the measurement interval includes: a configuration content of a measurement interval of a terminal per-UE, a configuration content of a measurement interval corresponding to the first node, and a configuration content of a measurement interval corresponding to the second node. At least one item;
  • the configuration content of the measurement interval corresponding to the first node includes: a configuration content of a measurement interval of each cell group per-CG corresponding to the terminal corresponding to the first node, and a measurement of a component carrier per-CC corresponding to the terminal At least one of the configuration contents of the interval;
  • the configuration content of the measurement interval corresponding to the second node includes: a configuration content of a measurement interval of each cell group per-CG corresponding to the terminal corresponding to the second node, and a measurement of a component carrier per-CC corresponding to the terminal At least one of the configured contents of the interval.
  • the processor 501 is further configured to: obtain, by using the transceiver 502, request information of a measurement interval sent by the second node;
  • the request information includes at least one of a configuration request and a configuration policy.
  • the processor 501 is further configured to: receive, by using an X1 interface or an S1 interface of the OAM architecture, request information of a measurement interval sent by the second node; or
  • the processor 501 is further configured to: perform, according to the request information, a configuration of a measurement interval for the terminal;
  • the measurement interval includes: at least one of a measurement interval for the terminal per-UE, a measurement interval corresponding to the first node, and a measurement interval corresponding to the second node.
  • the processor 501 is further configured to: send, by the transceiver 502, the configuration content of the measurement interval corresponding to the second node to the second node.
  • the processor 501 is further configured to: determine, according to the request information, configuration content of a measurement interval corresponding to the second node.
  • the processor 501 is further configured to: send, by the transceiver 502, configuration content of the measurement interval corresponding to the second node to the second node.
  • the measurement interval configured by the first node for the terminal is a measurement interval corresponding to the first node.
  • the processor 501 is further configured to: determine, according to the request information, configuration content of a measurement interval corresponding to the first node and the second node.
  • the processor 501 is further configured to: send, by the transceiver 502, configuration content of the measurement interval corresponding to the first node and the second node to the second node.
  • the processor 501 is further configured to: send, by the transceiver 502, a configuration policy of the measurement interval to the central control node, so that the central control node determines, according to the configuration policy, configuration content of the measurement interval, and receives the The configuration content fed back by the central control node.
  • the processor 501 is further configured to: perform, according to the configuration content, a configuration of a measurement interval for the terminal;
  • the measurement interval configured by the first node for the terminal is a measurement interval corresponding to the first node or the measurement interval configured by the first node for the terminal is a measurement interval corresponding to the first node and the second node respectively.
  • the processor 501 is further configured to: acquire measurement interval configuration related information that is sent by the terminal or sent by the second node;
  • the measurement interval configuration related information includes: a measurement interval required by the terminal and/or a measurement interval supported by the terminal capability.
  • the processor 501 is further configured to: perform, by using the transceiver 502, measurement interval configuration related information corresponding to the first node in the measurement interval configuration related information and/or a measurement corresponding to the second node. Interval configuration related information is sent to the second node.
  • the processor 501 is further configured to: perform, by the transceiver 502, configuration content of the measurement interval corresponding to the second node in the configured measurement interval, and/or measurement corresponding to the first node and the second node respectively.
  • the configured content of the interval is sent to the second node.
  • the processor 501 is further configured to: obtain, in the target preset message or the auxiliary message sent by the terminal, the measurement interval configuration related information reported by the terminal;
  • the target preset message is a radio resource control RRC message or a capability report message.
  • the processor 501 is further configured to: send, by the transceiver 502, indication information of the measurement interval configuration related information to the terminal, where the indication information is used to indicate whether to allow reporting of the measurement interval configuration related information.
  • the processor 501 is further configured to: send, by using the transceiver 502, the configured measurement interval to the terminal;
  • the measurement interval includes: at least one of a measurement interval for the terminal per-UE, a measurement interval corresponding to the first node, and a measurement interval corresponding to the second node.
  • the first node of some embodiments of the present disclosure can implement various processes implemented by the first node in the foregoing embodiment. To avoid repetition, details are not described herein again.
  • the first node of some embodiments of the present disclosure ensures the integrity of the NR network communication process and ensures the reliability and effectiveness of the network communication.
  • Some embodiments of the present disclosure also provide a second node, including:
  • a second receiving module configured to receive configuration content of a measurement interval sent by the first node, where the measurement interval is configured by the first node as a terminal;
  • the measurement interval includes at least one of a measurement interval for the terminal per-UE, a measurement interval for each cell group per-CG corresponding to the terminal, and a measurement interval for the component carrier per-CC corresponding to the terminal.
  • the second node further includes:
  • the second configuration module is configured to perform measurement interval configuration for the terminal according to the configuration content of the measurement interval.
  • the second node further includes:
  • a ninth sending module configured to send, to the first node, configuration content of the measurement interval.
  • the ninth sending module is configured to:
  • the configuration content of the measurement interval is sent to the terminal, so that the terminal reports the configuration content of the measurement interval to the first node.
  • the second receiving module is configured to:
  • the configuration content of the measurement interval sent by the first node forwarded by the terminal is received.
  • the configuration content of the measurement interval includes: a configuration content of a measurement interval of the terminal per-UE, a configuration content of a measurement interval corresponding to the first node, and a configuration content of a measurement interval corresponding to the second node. At least one item;
  • the configuration content of the measurement interval corresponding to the first node includes: a configuration content of a measurement interval of each cell group per-CG corresponding to the terminal corresponding to the first node, and a measurement of a component carrier per-CC corresponding to the terminal At least one of the configuration contents of the interval;
  • the configuration content of the measurement interval corresponding to the second node includes: a configuration content of a measurement interval of each cell group per-CG corresponding to the terminal corresponding to the second node, and a measurement of a component carrier per-CC corresponding to the terminal At least one of the configured contents of the interval.
  • the second receiving module includes:
  • a first sending unit configured to send request information of a measurement interval of the second node to the first node
  • An acquiring unit configured to acquire a configuration content of a measurement interval that is fed back by the first node according to the request information
  • the request information includes at least one of a configuration request and a configuration policy.
  • the sending unit is configured to:
  • the request information of the measurement interval of the second node is sent to the terminal, so that the terminal reports the request information of the measurement interval of the second node to the first node.
  • the second node further includes:
  • the tenth sending module is configured to send a configuration policy of the measurement interval to the central control node, so that the central control node determines the configuration content of the measurement interval according to the configuration policy, and receives the configuration content that is fed back by the central control node.
  • the second node further includes:
  • a third configuration module configured to perform a measurement interval configuration for the terminal according to the configuration content of the measurement interval
  • the measurement interval includes: a measurement interval corresponding to the first node and/or a measurement interval corresponding to the second node.
  • the second node further includes:
  • An eleventh sending module configured to send the configured measurement interval to the terminal
  • the measurement interval includes: at least one of a measurement interval for the terminal per-UE, a measurement interval corresponding to the first node, and a measurement interval corresponding to the second node.
  • the second node further includes:
  • An acquiring module configured to acquire information about a measurement interval configuration reported by the terminal
  • the measurement interval configuration related information includes: a measurement interval required by the terminal and/or a measurement interval supported by the terminal capability.
  • the second node further includes:
  • the twelfth sending module is configured to send the measurement interval configuration related information to the first node.
  • the second receiving module is configured to:
  • the second node further includes:
  • the fourth configuration module is configured to perform measurement interval configuration for the terminal according to the configuration content.
  • the second node further includes:
  • the fifth configuration module is configured to configure related information according to the measurement interval, and perform configuration of the measurement interval for the terminal.
  • the obtaining module is configured to:
  • the target preset message is a radio resource control RRC message or a capability report message.
  • the second node further includes:
  • the thirteenth sending module is configured to send the indication information of the measurement interval configuration related information to the terminal, where the indication information is used to indicate whether the measurement of the measurement interval configuration related information is allowed.
  • the second node further includes:
  • a notification module configured to notify the first node of the configuration content of the measurement interval
  • the configuration content of the measurement interval includes: a configuration content of a measurement interval corresponding to the second node.
  • the notification module is configured to:
  • the configuration content of the measurement interval is sent to the terminal, so that the terminal reports the configuration content of the measurement interval to the first node.
  • the second node further includes:
  • a fourteenth sending module configured to send the configured measurement interval to the terminal
  • the measurement interval includes at least one of a measurement interval for the terminal per-UE, a measurement interval corresponding to the first node, and a measurement interval corresponding to the second node.
  • the base station 600 includes a processor 601, a transceiver 602, a memory 603, and a bus interface, where:
  • the processor 601 is configured to read a program in the memory 603 and perform the following process:
  • the measurement interval includes at least one of a measurement interval for the terminal per-UE, a measurement interval for each cell group per-CG corresponding to the terminal, and a measurement interval for the component carrier per-CC corresponding to the terminal.
  • the bus architecture may include any number of interconnected buses and bridges, specifically linked by one or more processors represented by processor 601 and various circuits of memory represented by memory 603.
  • the bus architecture can also link various other circuits such as peripherals, voltage regulators, and power management circuits, which are well known in the art and, therefore, will not be further described herein.
  • the bus interface provides an interface.
  • Transceiver 602 can be a plurality of components, including a transmitter and a receiver, providing means for communicating with various other devices on a transmission medium.
  • the processor 601 is responsible for managing the bus architecture and general processing, and the memory 603 can store data used by the processor 601 in performing operations.
  • the processor 601 is further configured to: perform configuration of a measurement interval for the terminal according to the configuration content of the measurement interval.
  • the processor 601 is further configured to: send, by the transceiver 602, configuration content of the measurement interval to the first node.
  • the processor 601 is further configured to: send the configuration content of the measurement interval to the first node by using an X2 interface or an S1 interface of an operation maintenance management OAM architecture; or
  • the configuration content of the measurement interval is sent to the terminal, so that the terminal reports the configuration content of the measurement interval to the first node.
  • the processor 601 is further configured to: receive, by using an X2 interface or an S1 interface of an operation maintenance management OAM architecture, configuration content of a measurement interval sent by the first node; or
  • the configuration content of the measurement interval sent by the first node forwarded by the terminal is received.
  • the configuration content of the measurement interval includes: a configuration content of a measurement interval of a terminal per-UE, a configuration content of a measurement interval corresponding to the first node, and a configuration content of a measurement interval corresponding to the second node. At least one item;
  • the configuration content of the measurement interval corresponding to the first node includes: a configuration content of a measurement interval of each cell group per-CG corresponding to the terminal corresponding to the first node, and a measurement of a component carrier per-CC corresponding to the terminal At least one of the configuration contents of the interval;
  • the configuration content of the measurement interval corresponding to the second node includes: a configuration content of a measurement interval of each cell group per-CG corresponding to the terminal corresponding to the second node, and a measurement of a component carrier per-CC corresponding to the terminal At least one of the configured contents of the interval.
  • the processor 601 is further configured to: send, by the transceiver 602, request information of a measurement interval of the second node to the first node;
  • the request information includes at least one of a configuration request and a configuration policy.
  • the processor 601 is further configured to: send, by using an X2 interface or an S1 interface of the OAM architecture, request information of a measurement interval of the second node to the first node; or
  • the request information of the measurement interval of the second node is sent to the terminal, so that the terminal reports the request information of the measurement interval of the second node to the first node.
  • the processor 601 is further configured to: send, by the transceiver 602, a configuration policy of the measurement interval to the central control node, so that the central control node determines the configuration content of the measurement interval according to the configuration policy, and receives the center.
  • the configuration content fed back by the control node is further configured to: send, by the transceiver 602, a configuration policy of the measurement interval to the central control node, so that the central control node determines the configuration content of the measurement interval according to the configuration policy, and receives the center.
  • the configuration content fed back by the control node.
  • the processor 601 is further configured to: perform a configuration of the measurement interval for the terminal according to the configuration content of the measurement interval;
  • the measurement interval includes: a measurement interval corresponding to the first node and/or a measurement interval corresponding to the second node.
  • the processor 601 is further configured to: send, by using the transceiver 602, the configured measurement interval to the terminal;
  • the measurement interval includes: at least one of a measurement interval for the terminal per-UE, a measurement interval corresponding to the first node, and a measurement interval corresponding to the second node.
  • the processor 601 is further configured to: obtain measurement interval configuration related information reported by the terminal;
  • the measurement interval configuration related information includes: a measurement interval required by the terminal and/or a measurement interval supported by the terminal capability.
  • the processor 601 is further configured to: send, by the transceiver 602, the measurement interval configuration related information to the first node.
  • the processor 601 is further configured to: receive, by the transceiver 602, configuration content of the measurement interval that is fed back by the first node according to the measurement interval configuration related information.
  • the processor 601 is further configured to perform, according to the configuration content, a configuration of a measurement interval for the terminal.
  • the processor 601 is further configured to: configure related information according to the measurement interval, and perform configuration of a measurement interval for the terminal.
  • the processor 601 is further configured to: obtain, in the target preset message or the auxiliary message sent by the terminal, the measurement interval configuration related information reported by the terminal;
  • the target preset message is a radio resource control RRC message or a capability report message.
  • the processor 601 is further configured to: send, by the transceiver 602, indication information of the measurement interval configuration related information to the terminal, where the indication information is used to indicate whether to allow reporting of the measurement interval configuration related information.
  • the processor 601 is further configured to: notify, by the transceiver 602, the configuration content of the measurement interval to the first node;
  • the configuration content of the measurement interval includes: a configuration content of a measurement interval corresponding to the second node.
  • the processor 601 is further configured to: notify, by using an X2 interface or an S1 interface of an operation maintenance management OAM architecture, the configuration content of the measurement interval to the first node; or
  • the configuration content of the measurement interval is sent to the terminal, so that the terminal reports the configuration content of the measurement interval to the first node.
  • the processor 601 is further configured to: send, by using the transceiver 602, the configured measurement interval to the terminal;
  • the measurement interval includes at least one of a measurement interval for the terminal per-UE, a measurement interval corresponding to the first node, and a measurement interval corresponding to the second node.
  • the second node of some embodiments of the present disclosure can implement various processes implemented by the second node in the foregoing embodiment. To avoid repetition, details are not described herein again.
  • the second node of some embodiments of the present disclosure ensures the integrity of the NR network communication process and ensures the reliability and effectiveness of the network communication.
  • Some embodiments of the present disclosure also provide a terminal, including:
  • a third receiving module configured to receive a measurement interval configured by the first node and/or the second node
  • the measurement interval includes at least one of a measurement interval for the terminal per-UE, a measurement interval for each cell group per-CG corresponding to the terminal, and a measurement interval for the component carrier per-CC corresponding to the terminal.
  • the terminal is characterized in that it further includes:
  • a fifteenth sending module configured to send the configuration content of the measurement interval to the second node
  • the configuration content of the measurement interval includes: a configuration content of a measurement interval corresponding to the first node or a configuration content of a measurement interval corresponding to the first node and the second node respectively.
  • the terminal is characterized in that it further includes:
  • a fourth receiving module configured to receive request information of a measurement interval sent by the second node, and send the request information to the first node;
  • the request information includes at least one of a configuration request and a configuration policy.
  • the terminal is characterized in that it further includes:
  • a sixteenth sending module configured to send the measurement interval configuration related information to at least one of the first node and the second node;
  • the measurement interval configuration related information includes: a measurement interval required by the terminal and/or a measurement interval supported by the terminal capability.
  • sixteenth sending module includes:
  • a first generating unit configured to add measurement interval configuration related information to the preset message, and generate a target preset message
  • a second sending unit configured to send, by using the target preset message, the measurement interval configuration related information to at least one of the first node and the second node;
  • the target preset message is a radio resource control RRC message or a capability report message.
  • sixteenth sending module includes:
  • a second generating unit configured to generate an auxiliary message, where the auxiliary message includes the measurement interval configuration related information
  • a third sending unit configured to send, by using the auxiliary message, the measurement interval configuration related information to at least one of the first node and the second node.
  • the terminal is characterized in that it further includes:
  • the module is enabled to enable the reporting of the information related to the measurement interval.
  • the information about the measurement interval configuration is stopped during the timing when the related information reporting timer is configured.
  • sixteenth sending module includes:
  • the indication information receiving module is configured to receive the indication information of the measurement interval configuration related information sent by the at least one of the first node and the second node, where the indication information is used to indicate whether the measurement of the measurement interval configuration related information is allowed;
  • a fourth sending unit configured to: when the indication information is used to indicate that the measurement interval configuration related information is allowed to be reported, send the measurement interval configuration related information to at least one of the first node and the second node.
  • the method further includes:
  • a first selection module configured to select a measurement interval sent by the first node or the second node when the measurement interval is a measurement interval for the terminal per-UE;
  • a second selection module configured to select, when the measurement interval is a measurement interval for each cell group per-CG corresponding to the terminal, and/or a measurement interval for the component carrier per-CC corresponding to the terminal, The measurement interval corresponding to the first node is selected, and the measurement interval corresponding to the second node sent by the second node is selected.
  • FIG. 7 is a schematic structural diagram of a terminal according to some embodiments of the present disclosure.
  • the terminal in FIG. 7 may be a mobile phone, a tablet computer, a personal digital assistant (PDA), or a car computer.
  • PDA personal digital assistant
  • the terminal in FIG. 7 includes a radio frequency (RF) circuit 710, a memory 720, an input unit 730, a display unit 740, a processor 750, an audio circuit 760, a WiFi (Wireless Fidelity) module 770, and a power source 780.
  • RF radio frequency
  • the input unit 730 can be configured to receive numeric or character information input by the user, and generate signal input related to user settings and function control of the mobile terminal.
  • the input unit 730 may include a touch panel 731.
  • the touch panel 731 also referred to as a touch screen, can collect touch operations on or near the user (such as the operation of the user using any suitable object or accessory such as a finger or a stylus on the touch panel 731), and according to the preset
  • the programmed program drives the corresponding connection device.
  • the touch panel 731 can include two parts: a touch detection device and a touch controller.
  • the touch detection device detects the touch orientation of the user, and detects a signal brought by the touch operation, and transmits the signal to the touch controller; the touch controller receives the touch information from the touch detection device, converts the touch information into contact coordinates, and sends the touch information.
  • the processor 750 is provided and can receive commands from the processor 750 and execute them.
  • the touch panel 731 can be implemented in various types such as resistive, capacitive, infrared, and surface acoustic waves.
  • the input unit 730 may further include other input devices 732, which may include, but are not limited to, physical keyboards, function keys (such as volume control buttons, switch buttons, etc.), trackballs, mice, joysticks, and the like. One or more of them.
  • the display unit 740 can be used to display information input by the user or information provided to the user and various menu interfaces of the mobile terminal.
  • the display unit 740 can include a display panel 741.
  • the display panel 741 can be configured in the form of an LCD or an Organic Light-Emitting Diode (OLED).
  • the touch panel 731 can cover the display panel 741 to form a touch display screen, and when the touch display screen detects a touch operation on or near it, it is transmitted to the processor 750 to determine the type of the touch event, and then the processor The 750 provides a corresponding visual output on the touch display depending on the type of touch event.
  • the touch display includes an application interface display area and a common control display area.
  • the arrangement manner of the application interface display area and the display area of the common control is not limited, and the arrangement of the two display areas can be distinguished by being arranged up and down, left and right, and the like.
  • the application interface display area can be used to display the interface of the application. Each interface can contain interface elements such as at least one application's icon and/or widget desktop control.
  • the application interface display area can also be an empty interface that does not contain any content.
  • the common control display area is used to display controls with high usage, such as setting buttons, interface numbers, scroll bars, phone book icons, and the like.
  • the processor 750 is a control center of the mobile terminal, and connects various parts of the entire mobile phone by using various interfaces and lines, by running or executing software programs and/or modules stored in the first memory 721, and calling the second memory.
  • the data in 722 performs various functions and processing data of the mobile terminal, thereby performing overall monitoring on the mobile terminal.
  • processor 750 can include one or more processing units.
  • the processor 750 is configured to receive the first node and/or the second by calling a software program and/or module stored in the first memory 721 and/or data in the second memory 722.
  • the measurement interval of the node configuration is configured to receive the first node and/or the second by calling a software program and/or module stored in the first memory 721 and/or data in the second memory 722.
  • the measurement interval includes at least one of a measurement interval for the terminal per-UE, a measurement interval for each cell group per-CG corresponding to the terminal, and a measurement interval for the component carrier per-CC corresponding to the terminal.
  • the processor 750 is further configured to: send configuration content of the measurement interval to the second node;
  • the configuration content of the measurement interval includes: a configuration content of a measurement interval corresponding to the first node or a configuration content of a measurement interval corresponding to the first node and the second node respectively.
  • the processor 750 is further configured to: receive request information of the measurement interval sent by the second node, and send the request information to the first node;
  • the request information includes at least one of a configuration request and a configuration policy.
  • the processor 750 is further configured to: send the measurement interval configuration related information to at least one of the first node and the second node;
  • the measurement interval configuration related information includes: a measurement interval required by the terminal and/or a measurement interval supported by the terminal capability.
  • the processor 750 is further configured to: add measurement interval configuration related information to the preset message, and generate a target preset message;
  • the target preset message is a radio resource control RRC message or a capability report message.
  • the processor 750 is further configured to: generate an auxiliary message, where the auxiliary message includes the measurement interval configuration related information; The measurement interval configuration related information is sent to at least one of the first node and the second node.
  • the processor 750 is further configured to: enable a measurement interval interval related information reporting timer;
  • the information about the measurement interval configuration is stopped during the timing when the related information reporting timer is configured.
  • the processor 750 is further configured to: receive indication information about measurement interval configuration related information sent by at least one of the first node and the second node, where the indication information is used to indicate whether to allow measurement interval configuration related information When the indication information is used to indicate that the measurement interval configuration related information is allowed to be reported, the measurement interval configuration related information is sent to at least one of the first node and the second node.
  • the processor The 750 is further configured to: when the measurement interval is a measurement interval for the terminal per-UE, select a measurement interval sent by the first node or the second node; where the measurement interval is per cell group corresponding to the terminal per- When the measurement interval of the CG and/or the measurement interval of the component carrier per-CC corresponding to the terminal, the measurement interval corresponding to the first node sent by the first node is selected, and the measurement interval corresponding to the second node sent by the second node is selected.
  • the terminal of some embodiments of the present disclosure can implement various processes implemented by the terminal in the foregoing embodiment. To avoid repetition, details are not described herein again.
  • the terminal of some embodiments of the present disclosure receives the measurement interval of the first node and/or the second node configuration by the processor 750; thereby ensuring the integrity of the NR network communication process and ensuring the reliability and effectiveness of the network communication.
  • embodiments of some embodiments of the present disclosure may be provided as a method, apparatus, or computer program product. Accordingly, some embodiments of the present disclosure may take the form of an entirely hardware embodiment, an entirely software embodiment, or a combination of software and hardware aspects. Moreover, some embodiments of the present disclosure may take the form of a computer program product embodied on one or more computer usable storage media (including but not limited to disk storage, CD-ROM, optical storage, etc.) in which computer usable program code is embodied. .
  • the computer program instructions can also be stored in a computer readable memory that can direct a computer or other programmable data processing terminal device to operate in a particular manner, such that the instructions stored in the computer readable memory produce an article of manufacture comprising the instruction device.
  • the instruction device implements the functions specified in one or more blocks of the flowchart or in a flow or block of the flowchart.

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Abstract

本公开提供了一种测量间隔的配置方法、节点及终端,涉及通信技术领域。该测量间隔的配置方法,应用于第一节点,包括:为终端进行测量间隔的配置;其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。

Description

一种测量间隔的配置方法、节点及终端
相关申请的交叉引用
本申请主张在2017年5月5日在中国提交的中国专利申请号No.201710313283.9的优先权,其全部内容通过引用包含于此。
技术领域
本公开涉及通信技术领域,特别涉及一种测量间隔的配置方法、节点及终端。
背景技术
在协议TS 36.300中,测量分为同频测量(Intra-frequency measurement)和异频测量(inter-frequency measurement)。所谓同频测量,是指终端(UE)当前所在的小区和待测量的目标小区在同一个载波频点(中心频点)上。而异频测量,是指UE当前所在的小区和目标小区不在一个载波频点上。
如果UE需要进行异频测量(包括异制式Inter-RAT测量),一种简单的方式是在UE设备中安装2种射频接收机,分别测量本小区的频点和目标小区的频点,但这样会带来成本提升和不同频点之间相互间干扰的问题。因此,3GPP提出了测量间隔(Measurement Gap,MG)这种方式,即在正常收发数据过程中,预留一部分时间(即测量间隔时间),在这段时间内,UE不会发送和接收任何数据,而将接收机调向目标小区频点,进行异频(或异制式)的测量,measurement gap时间结束时再转到当前服务小区,继续进行数据收发。
当前所在小区和目标小区的载波频点不同,目标小区带宽小于当前小区带宽且目标小区带宽在当前小区带宽内:这种场景属于异频测量,需要测量GAP。
当前所在小区和目标小区的载波频点不同,目标小区带宽大于当前小区带宽且当前小区带宽在目标小区带宽内:这种场景属于异频测量,需要测量GAP。
当前所在小区和目标小区的载波频点不同,目标小区带宽和当前小区带宽不重叠:这种场景属于异频测量,需要测量GAP。
为了使UE能确定何时进行异频测量或进行数据收发,UE和网络必须对Measurement Gap的配置理解一致(比如,gap开始位置,gap长度,gap数量等),这些参数通过无线资源控制(RRC)配置消息或重配置(Re-configuration)消息的MeasGapConfig信息元素定义。
上述的measurement gap都是针对终端(per-UE)配的,即每个UE有自己单独的measurement gap。在长期演进(LTE)后续演进中,提出了针对终端对应的成分载波(per-CC)的measurement gap,即每个成分载波(component carrier)配置一个measurement gap。在双连接(Dual Connectivity,DualCo,DC)架构下,对于主基站(MeNB或MgNB)(和辅基站(SeNB或SgNB))下的主小区组(MCG)(和辅小区组(SCG))中的每一个小区(cell),都对应一个component carrier,Per-CC measurement gap就是每个component carrier都单独配置measurement gap。
在5G新空口(NR)中,还提出了针对终端对应的每个小区组(per-CG)的measurement gap。即MCG和SCG可以为同一个UE分别配置一个measurement gap,即MCG(或SCG)下的所有cell(或Component Carrier)都使用此measurement gap。
从颗粒度的角度看,per-UE,per-CG,per-CC measurement gap分别对应从粗到细。
5G系统在引入后,将采用DC架构来提升传输可靠性。在第一阶段的部署中,会与LTE之间使用双连接的架构来满足互操作(interworking)需求。在LTE的DC架构中,measurement gap都是per-UE配置的,即每个UE配置一个measurement gap,而且都是通过MeNB配置。
在5G NR与LTE interworking的非独立部署(non-standalone)场景的讨论中,如图1所示,第一阶段主要是将LTE的基站作为MeNB,即为MN,而NR的基站gNB作为SeNB,即为SN。
目前的5G NR中没有实现辅基站以及辅基站与主基站协调配置测量间隔的方案,无法保证5G NR通信完整性,无法保证网络通信的可靠性。
发明内容
本公开实施例提供一种测量间隔的配置方法、节点及终端,用以解决NR中没有实现辅基站以及辅基站与主基站协调配置测量间隔的方案,造成网络通信流程不完整,存在无法保证网络通信的可靠性和有效性的问题。
为了解决上述技术问题,本公开实施例提供一种测量间隔的配置方法,应用于第一节点,包括:
为终端进行测量间隔的配置;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。
本公开实施例提供一种测量间隔的配置方法,应用于第二节点,包括:
接收第一节点发送的测量间隔的配置内容,所述测量间隔为所述第一节点为终端配置的;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。
本公开实施例提供一种测量间隔的配置方法,应用于终端,包括:
接收第一节点和/或第二节点配置的测量间隔;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。
本公开实施例提供一种第一节点,包括:
第一配置模块,用于为终端进行测量间隔的配置;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。
本公开实施例提供一种第二节点,包括:
第二接收模块,用于接收第一节点发送的测量间隔的配置内容,所述测 量间隔为所述第一节点为终端配置的;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。
本公开实施例提供一种终端,包括:
第三接收模块,用于接收第一节点和/或第二节点配置的测量间隔;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。
本公开实施例提供一种第一节点,包括处理器、存储器及存储在所述存储器上并可在所述处理器上运行的网络接入程序,所述网络接入程序被所述处理器执行时实现如上述测量间隔的配置方法的步骤。
本公开实施例提供一种第二节点,包括处理器、存储器及存储在所述存储器上并可在所述处理器上运行的网络接入程序,所述网络接入程序被所述处理器执行时实现如上述测量间隔的配置方法的步骤。
本公开实施例提供一种终端,包括处理器、存储器及存储在所述存储器上并可在所述处理器上运行的网络接入程序,所述网络接入程序被所述处理器执行时实现如上述测量间隔的配置方法的步骤。
本公开实施例提供一种计算机可读取存储介质,其中,所述计算机可读取存储介质上存储有网络接入程序,所述网络接入程序被处理器执行时实现如上述测量间隔的配置方法的步骤。
本公开的有益效果是:
上述方案,实现了辅节点以及主节点和辅节点协调配置测量间隔的方案,保证了NR网络通信流程的完整,保证了网络通信的可靠性和有效性。
附图说明
图1表示5G NR与LTE non-standalone部署场景下的网络架构示意图;
图2表示本公开一些实施例的测量间隔的配置方法的流程示意图;
图3表示本公开一些实施例的测量间隔的配置方法的流程示意图;
图4表示本公开一些实施例的测量间隔的配置方法的流程示意图;
图5表示本公开一些实施例的第一节点的结构示意图;
图6表示本公开一些实施例的第二节点的结构示意图;
图7表示本公开一些实施例的终端的结构示意图。
具体实施方式
为使本公开的目的、技术方案和优点更加清楚,下面将结合附图及具体实施例对本公开进行详细描述。
本公开针对NR中没有实现辅基站以及辅基站与主基站协调配置测量间隔的方案,造成网络通信流程不完整,存在无法保证网络通信的可靠性和有效性的问题,提供一种测量间隔的配置方法、节点及终端。
如图2所示,本公开一些实施例提供一种测量间隔的配置方法,应用于第一节点,包括:
步骤201,为终端进行测量间隔的配置;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。
需要说明的是,该测量间隔的配置方法主要应用于主节点(Master Node,MN)和辅节点(Secondary Node,SN)之间,这里的节点指的是接入网侧的网元,例如,可以是LTE下的接入网节点(即基站),也可以是NR中的接入网节点,该第一节点可以表示主节点,也可以表示辅节点,即该主节点可以是LTE下的节点,也可以是NR下的节点,该辅节点同样可以是LTE下的节点,也可以是NR下的节点,可选地,主节点和辅节点的组合可以包括:MeNB与SeNB、MeNB与SgNB、MgNB与SeNB、MgNB与SgNB。
下面在具体的应用中,对该测量间隔的配置方法进行详细说明如下。
情况一、由第一节点直接进行测量间隔的配置,在第一节点配置完成后,向第二节点发送所述测量间隔的配置内容。
在向第二节点发送时,可选的实现方式为:
通过X2接口或者操作维护管理OAM架构的S1接口,向第二节点发送所 述测量间隔的配置内容;或者
将所述测量间隔的配置内容发送给终端,使得终端将所述测量间隔的配置内容上报给第二节点。
此种情况下,因测量间隔完全由第一节点进行配置,第一节点可以只配置与第一节点相关的测量间隔,也可以配置与第二节点相关的测量间隔;因此该测量间隔的配置内容包括:针对终端per-UE的测量间隔的配置内容、第一节点对应的测量间隔的配置内容和第二节点对应的测量间隔的配置内容中的至少一项;
其中,所述第一节点对应的测量间隔的配置内容包括:第一节点对应的针对终端对应的每个小区组per-CG的测量间隔的配置内容和针对终端对应的成分载波per-CC的测量间隔的配置内容中的至少一项;
其中,所述第二节点对应的测量间隔的配置内容包括:第二节点对应的针对终端对应的每个小区组per-CG的测量间隔的配置内容和针对终端对应的成分载波per-CC的测量间隔的配置内容中的至少一项。
需要说明的是,当第一节点只配置与自身相关的测量间隔时,为了获取与第二节点相关的测量间隔,该测量间隔的配置方法,还应包括:
接收第二节点发送的测量间隔的配置内容。
即第一节点和第二节点独立进行测量间隔的配置,在配置完成后,二者之间进行配置内容的互通。
在接收第二节点发送的配置内容时,可选的实现方式为:
通过X2接口或者OAM架构的S1接口,接收第二节点发送的测量间隔的配置内容;或者
接收终端转发的第二节点发送的测量间隔的配置内容。
情况二、第一节点和第二节点协调实现
在步骤201之前,该测量间隔的配置方法,还包括:
获取第二节点发送的测量间隔的请求信息;
其中,所述请求信息包括:配置请求和配置策略中的至少一项。
需要说明的是,该配置请求指的是要进行测量间隔配置的请求,即第一节点接到该配置请求后,就知道需要给终端进行测量间隔的配置;该配置策 略指的是第二节点将要配置的配置内容,即第二节点预先进行测量间隔的配置,并将该将要配置测量间隔发送给第一节点,由第一节点决定是否可以这样进行配置。
需要说明的是,该测量间隔的请求信息是由第二节点发送给第一节点的,此种情况的一种应用场景为:第二节点一开始没有进行测量间隔的配置,当第二节点获取到有配置测量间隔的需求时(该需求可以是终端向第二节点进行测量间隔的请求),此时,第二节点需要向第一节点发送请求,以请求进行测量间隔的配置。
具体地,获取第二节点发送的测量间隔的请求信息的方式为:
通过X2接口或者OAM架构的S1接口,接收第二节点发送的测量间隔的请求信息;或者
接收终端转发的第二节点发送的测量间隔的请求信息。
当第一节点接收的请求信息为配置请求时,可以进行以下几种处理:
1、根据所述请求信息,为终端进行测量间隔的配置;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、所述第一节点对应的测量间隔和所述第二节点对应的测量间隔中的至少一项。
第一节点在配置完成后,可以进行以下处理:
第一节点配置完成后可以不给第二节点发送直接将配置的测量间隔发送给终端。
第一节点配置完成后,也可以将配置的测量间隔发送给终端,同时也将配置的测量间隔的配置内容发送给第二节点。
需要说明的是,第一节点在向第二节点发送测量间隔的配置内容时,可以采用X2接口或者OAM架构的S1接口进行发送,也可以通过终端转发该测量间隔的配置内容给第二节点。
其中,如果是per-UE measurement gap,则直接是第一节点配一个per-UE measurement gap;如果是per-CG measurement gap,则是第一节点配第一节点和第二节点下的per-CG measurement gap;如果是per-CC measurement gap,则是第一节点配第一节点和第二节点下的所有CC的measurement gap。
2、根据所述请求信息,确定所述第二节点对应的测量间隔的配置内容。
此种处理方式下,第一节点先确定第二节点需要如何进行测量间隔配置,然后将该测量间隔的配置内容告知第二节点,由第二节点为终端进行测量间隔的配置,同时,第一节点也为终端配置自身所属的测量间隔。
即如果是Per-CG measurement gap,则由第一节点配第一节点下的Per-CG measurement gap,由第二节点配第二节点下的Per-CG measurement gap;如果是per-CC measurement gap,则由第一节点配第一节点下所有CC的measurement gap,由第二节点配第二节点下所有CC的measurement gap。
3、根据所述请求信息,确定所述第一节点和所述第二节点对应的测量间隔的配置内容。
此种处理方式下,第一节点先确定第一节点和第二节点需要如何进行测量间隔配置,然后将该测量间隔的配置内容告知第二节点,由第二节点为终端进行测量间隔的配置。
其中,第二节点在配置时,如果是per-UE measurement gap,则直接是第二节点配一个per-UE measurement gap;如果是Per-CG measurement gap,则是第二节点配第一节点和第二节点下的Per-CG measurement gap;如果是per-CC measurement gap,则是第二节点配第一节点和第二节点下的所有CC的measurement gap。
当第一节点接收的请求信息为配置策略时,首先需要进行决策,第一节点在做决策时,可以基于最低的终端能力来选择要使用的测量间隔;或者进一步地,如果是per-CG,则第一节点的per-CG measurement gap,根据第一节点进行配置,第二节点的per-CG measurement gap,根据第二节点进行配置;或如果是per-CC,则第一节点下的所有的CC的measurement gap,根据第一节点进行配置,则第二节点下的所有的CC的measurement gap,根据第二节点进行配置。
在第一节点做完决策后,可以进行以下几种处理:
1、为终端进行测量间隔的配置
此种处理方式是第一节点直接为终端进行配置,第二节点无需参与配置。
第一节点在配置完成后,可以进行以下处理:
第一节点配置完成后可以不给第二节点发送直接将配置的测量间隔发送 给终端。
第一节点配置完成后,也可以将配置的测量间隔发送给终端,同时也将配置的测量间隔的配置内容发送给第二节点。
需要说明的是,第一节点在向第二节点发送测量间隔的配置内容时,可以采用X2接口或者OAM架构的S1接口进行发送,也可以通过终端转发该测量间隔的配置内容给第二节点。
其中,如果是per-UE measurement gap,则直接是第一节点配一个per-UE measurement gap;如果是per-CG measurement gap,则是第一节点配第一节点和第二节点下的per-CG measurement gap;如果是per-CC measurement gap,则是第一节点配第一节点和第二节点下的所有CC的measurement gap。
2、第一节点将所有的配置内容发送给第二节点,由第二节点为终端进行配置。
其中,第二节点在配置时,如果是per-UE measurement gap,则直接是第二节点配一个per-UE measurement gap;如果是Per-CG measurement gap,则是第二节点配第一节点和第二节点下的Per-CG measurement gap;如果是per-CC measurement gap,则是第二节点配第一节点和第二节点下的所有CC的measurement gap。
3、第一节点将与第二节点对应的配置内容发送给第二节点,由第一节点和第二节点分别为终端进行配置。
其中,在配置时,如果是Per-CG measurement gap,则由第一节点配第一节点下的Per-CG measurement gap,由第二节点配第二节点下的Per-CG measurement gap;如果是per-CC measurement gap,则由第一节点配第一节点下所有CC的measurement gap,由第二节点配第二节点下所有CC的measurement gap。
情况三、由中心控制节点进行配置内容的决策
具体实现方式为:第一节点将测量间隔的配置策略发送给中心控制节点,使得中心控制节点根据所述配置策略确定测量间隔的配置内容,并接收所述中心控制节点反馈的所述配置内容。
需要说明的是,该中心控制节点为核心网或接入网中的网元,优选地, 该中心控制节点可以为核心网侧的网元。
中心控制节点在做决策时,可以基于最低的终端能力来选择要使用的测量间隔,或中心控制节点在做决策时,如果是per-CG,则第一节点的per-CG measurement gap,根据第一节点进行配置,第二节点的per-CG measurement gap,根据第二节点进行配置;或如果是per-CC,则第一节点下的所有的CC的measurement gap,根据第一节点进行配置,则第二节点下的所有的CC的measurement gap,根据第二节点进行配置。
中心控制节点在决策完成后,可采用如下处理方式:
1、中心控制节点将根据配置策略确定的测量间隔的配置内容发送给第一节点,由第一节点为终端配置测量间隔;
具体地,如果是per-UE measurement gap,则直接是第一节点配一个per-UE measurement gap;如果是per-CG measurement gap,则是第一节点配第一节点和第二节点下的per-CG measurement gap;如果是per-CC measurement gap,则是第一节点配第一节点和第二节点下的所有CC的measurement gap。
2、中心控制节点将根据配置策略确定的测量间隔的配置内容发送给第二节点,由第二节点为终端配置测量间隔;
具体地,如果是per-UE measurement gap,则直接由第二节点配一个per-UE measurement gap;如果是per-CG measurement gap,则由第二节点配第一节点和第二节点下的per-CG measurement gap;如果是per-CC measurement gap,则由第二节点配第一节点和第二节点下的所有CC的measurement gap。
3、中心控制节点将根据配置策略确定的测量间隔的配置内容发送给第一节点和第二节点,由第一节点和第二节点分别为终端配置测量间隔;
具体地,如果是Per-CG measurement gap,则由第一节点配第一节点下的Per-CG measurement gap,由第二节点配第二节点下的Per-CG measurement gap;如果是per-CC measurement gap,则由第一节点配第一节点下所有CC的measurement gap,由第二节点配第二节点下所有CC的measurement gap。
情况四、基于终端的请求的测量间隔的配置
获取终端上报的或第二节点发送的测量间隔配置相关信息;
根据所述测量间隔配置相关信息,为终端进行测量间隔的配置;
其中,所述测量间隔配置相关信息包括:终端需求的测量间隔和/或终端能力支持的测量间隔。
需要说明的是,终端在进行上报时,可以分为如下情况:
1、终端向第一节点上报测量间隔配置相关信息
具体地,如果是per-UE measurement gap,则直接上报一个per-UE measurement gap;如果是Per-CG measurement gap,则直接上报第一节点和第二节点分别对应的Per-CG measurement gap;如果是per-CC measurement gap,则直接上报第一节点和第二节点分别对应的per-CC measurement gap。
2、终端向第二节点上报测量间隔配置相关信息
具体地,如果是per-UE measurement gap,则直接上报一个per-UE measurement gap;如果是Per-CG measurement gap,则直接上报第一节点和第二节点分别对应的Per-CG measurement gap;如果是per-CC measurement gap,则直接上报第一节点和第二节点分别对应的per-CC measurement gap。
3、终端分别向第二节点和第二节点上报测量间隔配置相关信息
具体地,如果是per-UE measurement gap,则直接上报同一个per-UE measurement gap;如果是Per-CG measurement gap,则向第一节点上报第一节点对应的Per-CG measurement gap,向第二节点上报第二节点对应地Per-CG measurement gap;如果是per-CC measurement gap,则向第一节点上报第一节点对应的per-CC measurement gap,向第二节点上报第二节点对应的per-CC measurement gap。
需要说明的是,终端在进行上报时,可以采用目标预设消息或辅助消息进行上报,对应地,第一节点在终端发送的目标预设消息或辅助消息中,获取终端上报的测量间隔配置相关信息;其中,所述目标预设消息为无线资源控制RRC消息或能力上报消息。
终端在进行测量间隔配置相关信息时,还可以开启禁止测量间隔配置相关信息上报定时器;其中,在所述禁止测量间隔配置相关信息上报定时器的定时时间内,停止上报测量间隔配置相关信息。
还需要说明的是,第一节点和第二节点还可以使能该测量间隔配置相关信息的上报,具体实现方式为:发送测量间隔配置相关信息的指示信息给终端,所述指示信息用于指示是否允许测量间隔配置相关信息的上报。
需要说明的是,在此种情况下,后续的处理流程也可以采用情况二中的配置策略进行协调的方式,具体的实现过程,在此不再赘述。
情况五、第一节点和第二节点独立进行配置
在配置时,如果是Per-CG measurement gap,则由第一节点配第一节点下的Per-CG measurement gap,由第二节点配第二节点下的Per-CG measurement gap;如果是per-CC measurement gap,则由第一节点配第一节点下所有CC的measurement gap,由第二节点配第二节点下所有CC的measurement gap。
进一步地,第一节点和第二节点独立进行配置前,还可以包括情况四种终端请求的实现过程,即终端向第一节点上报需求的measurement gap,则第一节点需要将终端上报的第二节点下per-CG measurement gap或所有Per-CC measurement gap通知第二节点(类似上述的X2接口或S1接口通知),终端向第二节点上报需求的measurement gap,则第二节点需要将终端上报的第一节点下per-CG measurement gap或所有Per-CC measurement gap通知第一节点(类似上述的X2接口或S1接口通知);或者终端向第一节点和第二节点分别发送需求的measurement gap。
还需要说明的是,当终端同时接收到第一节点和第二节点发送的测量间隔、且第一节点和第二节点配置的第一节点对应的测量间隔与第二节点对应的测量间隔不一致时,终端采用如下的方式进行测量间隔的选择:在所述测量间隔为针对终端per-UE的测量间隔时,选择第一节点或第二节点发送的测量间隔;在所述测量间隔为针对终端对应的每个小区组per-CG的测量间隔和/或针对终端对应的成分载波per-CC的测量间隔时,选择第一节点发送的属于第一节点对应的测量间隔,选择第二节点发送的属于第二节点对应的测量间隔。
需要说明的是,以上所有在第一节点侧实现的功能均可以在第二节点侧实现,同样,在第二节点侧实现的功能可以在第一节点侧实现。
本公开一些实施例,实现了辅节点以及主节点和辅节点协调配置测量间隔的方案,保证了NR网络通信流程的完整,保证了网络通信的可靠性和有效性。
如图3所示,本公开一些实施例提供一种测量间隔的配置方法,应用于第二节点,包括:
步骤301,接收第一节点发送的测量间隔的配置内容,所述测量间隔为所述第一节点为终端配置的;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。
进一步地,在所述接收第一节点发送的测量间隔的配置内容的步骤之后,还包括:
根据所述测量间隔的配置内容,为终端进行测量间隔的配置。
进一步地,所述测量间隔的配置方法,还包括:
向第一节点发送所述测量间隔的配置内容。
进一步地,所述向第一节点发送所述测量间隔的配置内容的步骤包括:
通过X2接口或者操作维护管理OAM架构的S1接口,向第一节点发送所述测量间隔的配置内容;或者
将所述测量间隔的配置内容发送给终端,使得终端将所述测量间隔的配置内容上报给第一节点。
进一步地,所述接收第一节点发送的测量间隔的配置内容的步骤包括:
通过X2接口或者操作维护管理OAM架构的S1接口,接收所述第一节点发送的测量间隔的配置内容;或者
接收终端转发的第一节点发送的测量间隔的配置内容。
进一步地,所述测量间隔的配置内容包括:针对终端per-UE的测量间隔的配置内容、所述第一节点对应的测量间隔的配置内容和所述第二节点对应的测量间隔的配置内容中的至少一项;
其中,所述第一节点对应的测量间隔的配置内容包括:第一节点对应的针对终端对应的每个小区组per-CG的测量间隔的配置内容和针对终端对应 的成分载波per-CC的测量间隔的配置内容中的至少一项;
其中,所述第二节点对应的测量间隔的配置内容包括:第二节点对应的针对终端对应的每个小区组per-CG的测量间隔的配置内容和针对终端对应的成分载波per-CC的测量间隔的配置内容中的至少一项。
进一步地,所述接收第一节点发送的测量间隔的配置内容的步骤,包括:
发送第二节点的测量间隔的请求信息给所述第一节点;
获取所述第一节点根据所述请求信息,反馈的测量间隔的配置内容;
其中,所述请求信息包括:配置请求和配置策略中的至少一项。
进一步地,所述发送第二节点的测量间隔的请求信息给所述第一节点的步骤,包括:
通过X2接口或者OAM架构的S1接口,发送第二节点的测量间隔的请求信息给所述第一节点;或者
将第二节点的测量间隔的请求信息发送给终端,使得终端将所述第二节点的测量间隔的请求信息上报给第一节点。
进一步地,在接收所述第一节点发送的测量间隔的步骤之前,还包括:
发送测量间隔的配置策略给中心控制节点,使得中心控制节点根据所述配置策略确定测量间隔的配置内容,并接收所述中心控制节点反馈的所述配置内容。
进一步地,所述测量间隔的配置方法,还包括:
根据测量间隔的配置内容,为终端进行测量间隔的配置;
其中,所述测量间隔包括:所述第一节点对应的测量间隔和/或所述第二节点对应的测量间隔。
进一步地,在为终端进行测量间隔的配置的步骤之后,还包括:
将配置的测量间隔发送给终端;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、所述第一节点对应的测量间隔和所述第二节点对应的测量间隔中的至少一项。
进一步地,所述测量间隔的配置方法,还包括:
获取终端上报的测量间隔配置相关信息;
其中,所述测量间隔配置相关信息包括:终端需求的测量间隔和/或终端 能力支持的测量间隔。
进一步地,在所述获取终端上报的测量间隔配置相关信息的步骤之后,还包括:
将所述测量间隔配置相关信息发送给第一节点。
进一步地,所述接收第一节点发送的测量间隔的配置内容的步骤,包括:
接收第一节点根据所述测量间隔配置相关信息,反馈的测量间隔的配置内容。
进一步地,在所述接收第一节点根据所述测量间隔配置相关信息,反馈的测量间隔的配置内容的步骤之后,还包括:
根据所述配置内容,为终端进行测量间隔的配置。
进一步地,在所述获取终端上报的测量间隔配置相关信息的步骤之后,还包括:
根据所述测量间隔配置相关信息,为终端进行测量间隔的配置。
进一步地,所述获取终端上报的测量间隔配置相关信息的步骤,包括:
在终端发送的目标预设消息或辅助消息中,获取终端上报的测量间隔配置相关信息;
其中,所述目标预设消息为无线资源控制RRC消息或能力上报消息。
进一步地,在获取终端上报的测量间隔配置相关信息的步骤之前,还包括:
发送测量间隔配置相关信息的指示信息给终端,所述指示信息用于指示是否允许测量间隔配置相关信息的上报。
进一步地,在所述为终端进行测量间隔的配置的步骤之后,还包括:
将所述测量间隔的配置内容通知给所述第一节点;
其中所述测量间隔的配置内容包括:第二节点对应的测量间隔的配置内容。
进一步地,所述将所述测量间隔的配置内容通知给所述第一节点的步骤,包括:
通过X2接口或者操作维护管理OAM架构的S1接口,将所述测量间隔的配置内容通知给所述第一节点;或者
将所述测量间隔的配置内容发送给终端,使得终端将所述测量间隔的配置内容上报给所述第一节点。
进一步地,在为终端进行测量间隔的配置的步骤之后,还包括:
将配置的测量间隔发送给终端;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、所述第一节点对应的测量间隔和第二节点对应的测量间隔中的至少一项。
需要说明的是,在第一节点实施例中,所有关于第二节点侧的描述,均适用应用于第二节点侧的测量间隔的配置方法的实施例中,也能达到相同的技术效果。
如图4所示,本公开一些实施例还提供一种测量间隔的配置方法,应用于终端,包括:
步骤401,接收第一节点和/或第二节点配置的测量间隔;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。
进一步地,当接收到第一节点发送的测量间隔时,还包括:
将所述测量间隔的配置内容发送给第二节点;
其中,所述测量间隔的配置内容包括:第一节点对应的测量间隔的配置内容或者第一节点和第二节点分别对应的测量间隔的配置内容。
进一步地,所述测量间隔的配置方法,还包括:
接收第二节点发送的测量间隔的请求信息,并将所述请求信息发送给第一节点;
其中,所述请求信息包括:配置请求和配置策略中的至少一项。
进一步地,所述测量间隔的配置方法,还包括:
将测量间隔配置相关信息发送给第一节点和第二节点中的至少一者;
其中,所述测量间隔配置相关信息包括:终端需求的测量间隔和/或终端能力支持的测量间隔。
进一步地,所述将测量间隔配置相关信息发送给第一节点和第二节点中的至少一者的步骤包括:
在预设消息中添加测量间隔配置相关信息,生成目标预设消息;
通过所述目标预设消息,将所述测量间隔配置相关信息发送给第一节点和第二节点中的至少一者;
其中,所述目标预设消息为无线资源控制RRC消息或能力上报消息。
进一步地,所述将测量间隔配置相关信息发送给第一节点和第二节点中的至少一者的步骤包括:
生成一辅助消息,所述辅助消息中包含所述测量间隔配置相关信息;
通过所述辅助消息,将所述测量间隔配置相关信息发送给第一节点和第二节点中的至少一者。
进一步地,所述测量间隔的配置方法,还包括:
开启禁止测量间隔配置相关信息上报定时器;
其中,在所述禁止测量间隔配置相关信息上报定时器的定时时间内,停止上报测量间隔配置相关信息。
进一步地,所述将测量间隔配置相关信息发送给第一节点和第二节点中的至少一者的步骤包括:
接收第一节点和第二节点中的至少一者发送的测量间隔配置相关信息的指示信息,所述指示信息用于指示是否允许测量间隔配置相关信息的上报;
在所述指示信息用于指示允许测量间隔配置相关信息的上报时,将测量间隔配置相关信息发送给第一节点和第二节点中的至少一者。
进一步地,当同时接收到第一节点和第二节点发送的测量间隔、且第一节点和第二节点配置的第一节点对应的测量间隔与第二节点对应的测量间隔不一致时,还包括:
在所述测量间隔为针对终端per-UE的测量间隔时,选择第一节点或第二节点发送的测量间隔;
在所述测量间隔为针对终端对应的每个小区组per-CG的测量间隔和/或针对终端对应的成分载波per-CC的测量间隔时,选择第一节点发送的属于第一节点对应的测量间隔,选择第二节点发送的属于第二节点对应的测量间隔。
需要说明的是,在第一节点实施例中,所有关于终端侧的描述,均适用应用于终端侧的测量间隔的配置方法的实施例中,也能达到相同的技术效果。
本公开一些实施例还提供一种第一节点,包括:
第一配置模块,用于为终端进行测量间隔的配置;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。
进一步地,所述第一节点,还包括:
第一发送模块,用于向第二节点发送所述测量间隔的配置内容。
进一步地,所述第一发送模块用于:
通过X2接口或者操作维护管理OAM架构的S1接口,向第二节点发送所述测量间隔的配置内容;或者
将所述测量间隔的配置内容发送给终端,使得终端将所述测量间隔的配置内容上报给第二节点。
进一步地,所述第一节点,还包括:
第一接收模块,用于接收第二节点发送的测量间隔的配置内容。
进一步地,所述第一接收模块用于:
通过X2接口或者OAM架构的S1接口,接收第二节点发送的测量间隔的配置内容;或者
接收终端转发的第二节点发送的测量间隔的配置内容。
进一步地,所述测量间隔的配置内容包括:针对终端per-UE的测量间隔的配置内容、所述第一节点对应的测量间隔的配置内容和所述第二节点对应的测量间隔的配置内容中的至少一项;
其中,所述第一节点对应的测量间隔的配置内容包括:第一节点对应的针对终端对应的每个小区组per-CG的测量间隔的配置内容和针对终端对应的成分载波per-CC的测量间隔的配置内容中的至少一项;
其中,所述第二节点对应的测量间隔的配置内容包括:第二节点对应的针对终端对应的每个小区组per-CG的测量间隔的配置内容和针对终端对应的成分载波per-CC的测量间隔的配置内容中的至少一项。
进一步地,所述第一节点,还包括:
第一获取模块,用于获取第二节点发送的测量间隔的请求信息;
其中,所述请求信息包括:配置请求和配置策略中的至少一项。
进一步地,所述第一获取模块用于:
通过X2接口或者OAM架构的S1接口,接收第二节点发送的测量间隔的请求信息;或者
接收终端转发的第二节点发送的测量间隔的请求信息。
进一步地,所述第一配置模块用于:
根据所述请求信息,为终端进行测量间隔的配置;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、所述第一节点对应的测量间隔和所述第二节点对应的测量间隔中的至少一项。
进一步地,所述第一节点,还包括:
第二发送模块,用于向第二节点发送所述第二节点对应的测量间隔的配置内容。
进一步地,所述第一节点,还包括:
第一确定模块,用于根据所述请求信息,确定所述第二节点对应的测量间隔的配置内容。
进一步地,所述第一节点,还包括:
第三发送模块,用于将所述第二节点对应的测量间隔的配置内容发送给第二节点。
进一步地,所述第一节点为终端配置的测量间隔为第一节点对应的测量间隔。
进一步地,所述第一节点,还包括:
第二确定模块,用于根据所述请求信息,确定所述第一节点和所述第二节点对应的测量间隔的配置内容。
进一步地,所述第一节点,还包括:
第四发送模块,用于将所述第一节点和所述第二节点对应的测量间隔的配置内容发送给第二节点。
进一步地,所述第一节点,还包括:
第五发送模块,用于将测量间隔的配置策略发送给中心控制节点,使得中心控制节点根据所述配置策略确定测量间隔的配置内容,并接收所述中心 控制节点反馈的所述配置内容。
进一步地,所述第一配置模块用于:
根据所述配置内容,为终端进行测量间隔的配置;
其中,所述第一节点为终端配置的测量间隔为第一节点对应的测量间隔或者所述第一节点为终端配置的测量间隔为第一节点和第二节点分别对应的测量间隔。
进一步地,所述为终端进行测量间隔的配置的方式为:
获取终端上报的或第二节点发送的测量间隔配置相关信息;
根据所述测量间隔配置相关信息,为终端进行测量间隔的配置;
其中,所述测量间隔配置相关信息包括:终端需求的测量间隔和/或终端能力支持的测量间隔。
进一步地,所述第一节点,还包括:
第六发送模块,用于将所述测量间隔配置相关信息中所述第一节点对应的测量间隔配置相关信息和/或所述第二节点对应的测量间隔配置相关信息,发送给第二节点。
进一步地,所述第一节点,还包括:
第七发送模块,用于将配置的所述测量间隔中第二节点对应的测量间隔的配置内容和/或第一节点与第二节点分别对应的测量间隔的配置内容发送给第二节点。
进一步地,当所述测量间隔配置相关信息由终端上报时,所述获取终端上报的测量间隔配置相关信息的方式为:
在终端发送的目标预设消息或辅助消息中,获取终端上报的测量间隔配置相关信息;
其中,所述目标预设消息为无线资源控制RRC消息或能力上报消息。
进一步地,所述第一节点,还包括:
第八发送模块,用于发送测量间隔配置相关信息的指示信息给终端,所述指示信息用于指示是否允许测量间隔配置相关信息的上报。
进一步地,所述第一节点,还包括:
第九发送模块,用于将配置的测量间隔发送给终端;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、所述第一节点对应的测量间隔和第二节点对应的测量间隔中的至少一项。
图5是本公开一些实施例的第一节点的结构图,能够实现上述应用于第一节点侧的测量间隔的配置方法的细节,并达到相同的效果。如图5所示,基站500包括:处理器501、收发机502、存储器503和总线接口,其中:
处理器501,用于读取存储器503中的程序,执行下列过程:
为终端进行测量间隔的配置;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。
在图5中,总线架构可以包括任意数量的互联的总线和桥,具体由处理器501代表的一个或多个处理器和存储器503代表的存储器的各种电路链接在一起。总线架构还可以将诸如外围设备、稳压器和功率管理电路等之类的各种其他电路链接在一起,这些都是本领域所公知的,因此,本文不再对其进行进一步描述。总线接口提供接口。收发机502可以是多个元件,即包括发送机和接收机,提供用于在传输介质上与各种其他装置通信的单元。
处理器501负责管理总线架构和通常的处理,存储器503可以存储处理器501在执行操作时所使用的数据。
可选地,所述处理器501还用于执行:通过收发机502向第二节点发送所述测量间隔的配置内容。
可选地,所述处理器501还用于执行:通过X2接口或者操作维护管理OAM架构的S1接口,向第二节点发送所述测量间隔的配置内容;或者
将所述测量间隔的配置内容发送给终端,使得终端将所述测量间隔的配置内容上报给第二节点。
可选地,所述处理器501还用于执行:通过收发机502接收第二节点发送的测量间隔的配置内容。
可选地,所述处理器501还用于执行:通过X2接口或者OAM架构的S1接口,接收第二节点发送的测量间隔的配置内容;或者
接收终端转发的第二节点发送的测量间隔的配置内容。
其中,所述测量间隔的配置内容包括:针对终端per-UE的测量间隔的配置内容、所述第一节点对应的测量间隔的配置内容和所述第二节点对应的测量间隔的配置内容中的至少一项;
其中,所述第一节点对应的测量间隔的配置内容包括:第一节点对应的针对终端对应的每个小区组per-CG的测量间隔的配置内容和针对终端对应的成分载波per-CC的测量间隔的配置内容中的至少一项;
其中,所述第二节点对应的测量间隔的配置内容包括:第二节点对应的针对终端对应的每个小区组per-CG的测量间隔的配置内容和针对终端对应的成分载波per-CC的测量间隔的配置内容中的至少一项。
可选地,所述处理器501还用于执行:通过收发机502获取第二节点发送的测量间隔的请求信息;
其中,所述请求信息包括:配置请求和配置策略中的至少一项。
可选地,所述处理器501还用于执行:通过X2接口或者OAM架构的S1接口,接收第二节点发送的测量间隔的请求信息;或者
接收终端转发的第二节点发送的测量间隔的请求信息。
可选地,所述处理器501还用于执行:根据所述请求信息,为终端进行测量间隔的配置;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、所述第一节点对应的测量间隔和所述第二节点对应的测量间隔中的至少一项。
可选地,所述处理器501还用于执行:通过收发机502向第二节点发送所述第二节点对应的测量间隔的配置内容。
可选地,所述处理器501还用于执行:根据所述请求信息,确定所述第二节点对应的测量间隔的配置内容。
可选地,所述处理器501还用于执行:通过收发机502将所述第二节点对应的测量间隔的配置内容发送给第二节点。
其中,所述第一节点为终端配置的测量间隔为第一节点对应的测量间隔。
可选地,所述处理器501还用于执行:根据所述请求信息,确定所述第一节点和所述第二节点对应的测量间隔的配置内容。
可选地,所述处理器501还用于执行:通过收发机502将所述第一节点 和所述第二节点对应的测量间隔的配置内容发送给第二节点。
可选地,所述处理器501还用于执行:通过收发机502将测量间隔的配置策略发送给中心控制节点,使得中心控制节点根据所述配置策略确定测量间隔的配置内容,并接收所述中心控制节点反馈的所述配置内容。
可选地,所述处理器501还用于执行:根据所述配置内容,为终端进行测量间隔的配置;
其中,所述第一节点为终端配置的测量间隔为第一节点对应的测量间隔或者所述第一节点为终端配置的测量间隔为第一节点和第二节点分别对应的测量间隔。
可选地,所述处理器501还用于执行:获取终端上报的或第二节点发送的测量间隔配置相关信息;
根据所述测量间隔配置相关信息,为终端进行测量间隔的配置;
其中,所述测量间隔配置相关信息包括:终端需求的测量间隔和/或终端能力支持的测量间隔。
可选地,所述处理器501还用于执行:通过收发机502将所述测量间隔配置相关信息中所述第一节点对应的测量间隔配置相关信息和/或所述第二节点对应的测量间隔配置相关信息,发送给第二节点。
可选地,所述处理器501还用于执行:通过收发机502将配置的所述测量间隔中第二节点对应的测量间隔的配置内容和/或第一节点与第二节点分别对应的测量间隔的配置内容发送给第二节点。
可选地,所述处理器501还用于执行:在终端发送的目标预设消息或辅助消息中,获取终端上报的测量间隔配置相关信息;
其中,所述目标预设消息为无线资源控制RRC消息或能力上报消息。
可选地,所述处理器501还用于执行:通过收发机502发送测量间隔配置相关信息的指示信息给终端,所述指示信息用于指示是否允许测量间隔配置相关信息的上报。
可选地,所述处理器501还用于执行:通过收发机502将配置的测量间隔发送给终端;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、所述第一节点 对应的测量间隔和第二节点对应的测量间隔中的至少一项。
本公开一些实施例的第一节点能够实现前述实施例中第一节点实现的各个过程,为避免重复,这里不再赘述。
本公开一些实施例的第一节点,保证了NR网络通信流程的完整,保证了网络通信的可靠性和有效性。
本公开一些实施例还提供一种第二节点,包括:
第二接收模块,用于接收第一节点发送的测量间隔的配置内容,所述测量间隔为所述第一节点为终端配置的;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。
进一步地,所述第二节点,还包括:
第二配置模块,用于根据所述测量间隔的配置内容,为终端进行测量间隔的配置。
进一步地,所述第二节点,还包括:
第九发送模块,用于向第一节点发送所述测量间隔的配置内容。
进一步地,所述第九发送模块用于:
通过X2接口或者操作维护管理OAM架构的S1接口,向第一节点发送所述测量间隔的配置内容;或者
将所述测量间隔的配置内容发送给终端,使得终端将所述测量间隔的配置内容上报给第一节点。
进一步地,所述第二接收模块用于:
通过X2接口或者操作维护管理OAM架构的S1接口,接收所述第一节点发送的测量间隔的配置内容;或者
接收终端转发的第一节点发送的测量间隔的配置内容。
进一步地,所述测量间隔的配置内容包括:针对终端per-UE的测量间隔的配置内容、所述第一节点对应的测量间隔的配置内容和所述第二节点对应的测量间隔的配置内容中的至少一项;
其中,所述第一节点对应的测量间隔的配置内容包括:第一节点对应的 针对终端对应的每个小区组per-CG的测量间隔的配置内容和针对终端对应的成分载波per-CC的测量间隔的配置内容中的至少一项;
其中,所述第二节点对应的测量间隔的配置内容包括:第二节点对应的针对终端对应的每个小区组per-CG的测量间隔的配置内容和针对终端对应的成分载波per-CC的测量间隔的配置内容中的至少一项。
进一步地,所述第二接收模块包括:
第一发送单元,用于发送第二节点的测量间隔的请求信息给所述第一节点;
获取单元,用于获取所述第一节点根据所述请求信息,反馈的测量间隔的配置内容;
其中,所述请求信息包括:配置请求和配置策略中的至少一项。
进一步地,所述发送单元用于:
通过X2接口或者OAM架构的S1接口,发送第二节点的测量间隔的请求信息给所述第一节点;或者
将第二节点的测量间隔的请求信息发送给终端,使得终端将所述第二节点的测量间隔的请求信息上报给第一节点。
进一步地,所述第二节点,还包括:
第十发送模块,用于发送测量间隔的配置策略给中心控制节点,使得中心控制节点根据所述配置策略确定测量间隔的配置内容,并接收所述中心控制节点反馈的所述配置内容。
进一步地,所述第二节点,还包括:
第三配置模块,用于根据测量间隔的配置内容,为终端进行测量间隔的配置;
其中,所述测量间隔包括:所述第一节点对应的测量间隔和/或所述第二节点对应的测量间隔。
进一步地,所述第二节点,还包括:
第十一发送模块,用于将配置的测量间隔发送给终端;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、所述第一节点对应的测量间隔和所述第二节点对应的测量间隔中的至少一项。
进一步地,所述第二节点,还包括:
获取模块,用于获取终端上报的测量间隔配置相关信息;
其中,所述测量间隔配置相关信息包括:终端需求的测量间隔和/或终端能力支持的测量间隔。
进一步地,所述第二节点,还包括:
第十二发送模块,用于将所述测量间隔配置相关信息发送给第一节点。
进一步地,所述第二接收模块用于:
接收第一节点根据所述测量间隔配置相关信息,反馈的测量间隔的配置内容。
进一步地,所述第二节点,还包括:
第四配置模块,用于根据所述配置内容,为终端进行测量间隔的配置。
进一步地,所述第二节点,还包括:
第五配置模块,用于根据所述测量间隔配置相关信息,为终端进行测量间隔的配置。
进一步地,所述获取模块用于:
在终端发送的目标预设消息或辅助消息中,获取终端上报的测量间隔配置相关信息;
其中,所述目标预设消息为无线资源控制RRC消息或能力上报消息。
进一步地,所述第二节点,还包括:
第十三发送模块,用于发送测量间隔配置相关信息的指示信息给终端,所述指示信息用于指示是否允许测量间隔配置相关信息的上报。
进一步地,所述第二节点,还包括:
通知模块,用于将所述测量间隔的配置内容通知给所述第一节点;
其中所述测量间隔的配置内容包括:第二节点对应的测量间隔的配置内容。
进一步地,所述通知模块用于:
通过X2接口或者操作维护管理OAM架构的S1接口,将所述测量间隔的配置内容通知给所述第一节点;或者
将所述测量间隔的配置内容发送给终端,使得终端将所述测量间隔的配 置内容上报给所述第一节点。
进一步地,所述第二节点,还包括:
第十四发送模块,用于将配置的测量间隔发送给终端;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、所述第一节点对应的测量间隔和第二节点对应的测量间隔中的至少一项。
图6是本公开一些实施例的第二节点的结构图,能够实现上述应用于第二节点侧的测量间隔的配置方法的细节,并达到相同的效果。如图6所示,基站600包括:处理器601、收发机602、存储器603和总线接口,其中:
处理器601,用于读取存储器603中的程序,执行下列过程:
通过收发机602接收第一节点发送的测量间隔的配置内容,所述测量间隔为所述第一节点为终端配置的;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。
在图6中,总线架构可以包括任意数量的互联的总线和桥,具体由处理器601代表的一个或多个处理器和存储器603代表的存储器的各种电路链接在一起。总线架构还可以将诸如外围设备、稳压器和功率管理电路等之类的各种其他电路链接在一起,这些都是本领域所公知的,因此,本文不再对其进行进一步描述。总线接口提供接口。收发机602可以是多个元件,即包括发送机和接收机,提供用于在传输介质上与各种其他装置通信的单元。
处理器601负责管理总线架构和通常的处理,存储器603可以存储处理器601在执行操作时所使用的数据。
可选地,所述处理器601还用于执行:根据所述测量间隔的配置内容,为终端进行测量间隔的配置。
可选地,所述处理器601还用于执行:通过收发机602向第一节点发送所述测量间隔的配置内容。
可选地,所述处理器601还用于执行:通过X2接口或者操作维护管理OAM架构的S1接口,向第一节点发送所述测量间隔的配置内容;或者
将所述测量间隔的配置内容发送给终端,使得终端将所述测量间隔的配 置内容上报给第一节点。
可选地,所述处理器601还用于执行:通过X2接口或者操作维护管理OAM架构的S1接口,接收所述第一节点发送的测量间隔的配置内容;或者
接收终端转发的第一节点发送的测量间隔的配置内容。
其中,所述测量间隔的配置内容包括:针对终端per-UE的测量间隔的配置内容、所述第一节点对应的测量间隔的配置内容和所述第二节点对应的测量间隔的配置内容中的至少一项;
其中,所述第一节点对应的测量间隔的配置内容包括:第一节点对应的针对终端对应的每个小区组per-CG的测量间隔的配置内容和针对终端对应的成分载波per-CC的测量间隔的配置内容中的至少一项;
其中,所述第二节点对应的测量间隔的配置内容包括:第二节点对应的针对终端对应的每个小区组per-CG的测量间隔的配置内容和针对终端对应的成分载波per-CC的测量间隔的配置内容中的至少一项。
可选地,所述处理器601还用于执行:通过收发机602发送第二节点的测量间隔的请求信息给所述第一节点;
获取所述第一节点根据所述请求信息,反馈的测量间隔的配置内容;
其中,所述请求信息包括:配置请求和配置策略中的至少一项。
可选地,所述处理器601还用于执行:通过X2接口或者OAM架构的S1接口,发送第二节点的测量间隔的请求信息给所述第一节点;或者
将第二节点的测量间隔的请求信息发送给终端,使得终端将所述第二节点的测量间隔的请求信息上报给第一节点。
可选地,所述处理器601还用于执行:通过收发机602发送测量间隔的配置策略给中心控制节点,使得中心控制节点根据所述配置策略确定测量间隔的配置内容,并接收所述中心控制节点反馈的所述配置内容。
可选地,所述处理器601还用于执行:根据测量间隔的配置内容,为终端进行测量间隔的配置;
其中,所述测量间隔包括:所述第一节点对应的测量间隔和/或所述第二节点对应的测量间隔。
可选地,所述处理器601还用于执行:通过收发机602将配置的测量间 隔发送给终端;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、所述第一节点对应的测量间隔和所述第二节点对应的测量间隔中的至少一项。
可选地,所述处理器601还用于执行:获取终端上报的测量间隔配置相关信息;
其中,所述测量间隔配置相关信息包括:终端需求的测量间隔和/或终端能力支持的测量间隔。
可选地,所述处理器601还用于执行:通过收发机602将所述测量间隔配置相关信息发送给第一节点。
可选地,所述处理器601还用于执行:通过收发机602接收第一节点根据所述测量间隔配置相关信息,反馈的测量间隔的配置内容。
可选地,所述处理器601还用于执行:根据所述配置内容,为终端进行测量间隔的配置。
可选地,所述处理器601还用于执行:根据所述测量间隔配置相关信息,为终端进行测量间隔的配置。
可选地,所述处理器601还用于执行:在终端发送的目标预设消息或辅助消息中,获取终端上报的测量间隔配置相关信息;
其中,所述目标预设消息为无线资源控制RRC消息或能力上报消息。
可选地,所述处理器601还用于执行:通过收发机602发送测量间隔配置相关信息的指示信息给终端,所述指示信息用于指示是否允许测量间隔配置相关信息的上报。
可选地,所述处理器601还用于执行:通过收发机602将所述测量间隔的配置内容通知给所述第一节点;
其中所述测量间隔的配置内容包括:第二节点对应的测量间隔的配置内容。
可选地,所述处理器601还用于执行:通过X2接口或者操作维护管理OAM架构的S1接口,将所述测量间隔的配置内容通知给所述第一节点;或者
将所述测量间隔的配置内容发送给终端,使得终端将所述测量间隔的配置内容上报给所述第一节点。
可选地,所述处理器601还用于执行:通过收发机602将配置的测量间隔发送给终端;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、所述第一节点对应的测量间隔和第二节点对应的测量间隔中的至少一项。
本公开一些实施例的第二节点能够实现前述实施例中第二节点实现的各个过程,为避免重复,这里不再赘述。
本公开一些实施例的第二节点,保证了NR网络通信流程的完整,保证了网络通信的可靠性和有效性。
本公开一些实施例还提供一种终端,包括:
第三接收模块,用于接收第一节点和/或第二节点配置的测量间隔;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。
进一步地,所述的终端,其特征在于,还包括:
第十五发送模块,用于将所述测量间隔的配置内容发送给第二节点;
其中,所述测量间隔的配置内容包括:第一节点对应的测量间隔的配置内容或者第一节点和第二节点分别对应的测量间隔的配置内容。
进一步地,所述的终端,其特征在于,还包括:
第四接收模块,用于接收第二节点发送的测量间隔的请求信息,并将所述请求信息发送给第一节点;
其中,所述请求信息包括:配置请求和配置策略中的至少一项。
进一步地,所述的终端,其特征在于,还包括:
第十六发送模块,用于将测量间隔配置相关信息发送给第一节点和第二节点中的至少一者;
其中,所述测量间隔配置相关信息包括:终端需求的测量间隔和/或终端能力支持的测量间隔。
进一步地,所述第十六发送模块包括:
第一生成单元,用于在预设消息中添加测量间隔配置相关信息,生成目标预设消息;
第二发送单元,用于通过所述目标预设消息,将所述测量间隔配置相关信息发送给第一节点和第二节点中的至少一者;
其中,所述目标预设消息为无线资源控制RRC消息或能力上报消息。
进一步地,所述第十六发送模块包括:
第二生成单元,用于生成一辅助消息,所述辅助消息中包含所述测量间隔配置相关信息;
第三发送单元,用于通过所述辅助消息,将所述测量间隔配置相关信息发送给第一节点和第二节点中的至少一者。
进一步地,所述的终端,其特征在于,还包括:
开启模块,用于开启禁止测量间隔配置相关信息上报定时器;
其中,在所述禁止测量间隔配置相关信息上报定时器的定时时间内,停止上报测量间隔配置相关信息。
进一步地,所述第十六发送模块包括:
指示信息接收模块,用于接收第一节点和第二节点中的至少一者发送的测量间隔配置相关信息的指示信息,所述指示信息用于指示是否允许测量间隔配置相关信息的上报;
第四发送单元,用于在所述指示信息用于指示允许测量间隔配置相关信息的上报时,将测量间隔配置相关信息发送给第一节点和第二节点中的至少一者。
进一步地,当同时接收到第一节点和第二节点发送的测量间隔、且第一节点和第二节点配置的第一节点对应的测量间隔与第二节点对应的测量间隔不一致时,还包括:
第一选择模块,用于在所述测量间隔为针对终端per-UE的测量间隔时,选择第一节点或第二节点发送的测量间隔;
第二选择模块,用于在所述测量间隔为针对终端对应的每个小区组per-CG的测量间隔和/或针对终端对应的成分载波per-CC的测量间隔时,选择第一节点发送的属于第一节点对应的测量间隔,选择第二节点发送的属于第二节点对应的测量间隔。
图7是本公开一些实施例的终端的结构示意图。具体地,图7中的终端 可以为手机、平板电脑、个人数字助理(Personal Digital Assistant,PDA)、或车载电脑等。
图7中的终端包括射频(Radio Frequency,RF)电路710、存储器720、输入单元730、显示单元740、处理器750、音频电路760、WiFi(Wireless Fidelity)模块770和电源780。
其中,输入单元730可用于接收用户输入的数字或字符信息,以及产生与移动终端的用户设置以及功能控制有关的信号输入。具体地,本公开一些实施例中,该输入单元730可以包括触控面板731。触控面板731,也称为触摸屏,可收集用户在其上或附近的触摸操作(比如用户使用手指、触笔等任何适合的物体或附件在触控面板731上的操作),并根据预先设定的程式驱动相应的连接装置。可选的,触控面板731可包括触摸检测装置和触摸控制器两个部分。其中,触摸检测装置检测用户的触摸方位,并检测触摸操作带来的信号,将信号传送给触摸控制器;触摸控制器从触摸检测装置上接收触摸信息,并将它转换成触点坐标,再送给该处理器750,并能接收处理器750发来的命令并加以执行。此外,可以采用电阻式、电容式、红外线以及表面声波等多种类型实现触控面板731。除了触控面板731,输入单元730还可以包括其他输入设备732,其他输入设备732可以包括但不限于物理键盘、功能键(比如音量控制按键、开关按键等)、轨迹球、鼠标、操作杆等中的一种或多种。
其中,显示单元740可用于显示由用户输入的信息或提供给用户的信息以及移动终端的各种菜单界面。显示单元740可包括显示面板741,可选的,可以采用LCD或有机发光二极管(Organic Light-Emitting Diode,OLED)等形式来配置显示面板741。
应注意,触控面板731可以覆盖显示面板741,形成触摸显示屏,当该触摸显示屏检测到在其上或附近的触摸操作后,传送给处理器750以确定触摸事件的类型,随后处理器750根据触摸事件的类型在触摸显示屏上提供相应的视觉输出。
触摸显示屏包括应用程序界面显示区及常用控件显示区。该应用程序界面显示区及该常用控件显示区的排列方式并不限定,可以为上下排列、左右 排列等可以区分两个显示区的排列方式。该应用程序界面显示区可以用于显示应用程序的界面。每一个界面可以包含至少一个应用程序的图标和/或widget桌面控件等界面元素。该应用程序界面显示区也可以为不包含任何内容的空界面。该常用控件显示区用于显示使用率较高的控件,例如,设置按钮、界面编号、滚动条、电话本图标等应用程序图标等。
其中处理器750是移动终端的控制中心,利用各种接口和线路连接整个手机的各个部分,通过运行或执行存储在第一存储器721内的软件程序和/或模块,以及调用存储在第二存储器722内的数据,执行移动终端的各种功能和处理数据,从而对移动终端进行整体监控。可选的,处理器750可包括一个或多个处理单元。
在本公开一些实施例中,通过调用存储该第一存储器721内的软件程序和/或模块和/或该第二存储器722内的数据,处理器750用于接收第一节点和/或第二节点配置的测量间隔;
其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。
可选地,处理器750还用于:将所述测量间隔的配置内容发送给第二节点;
其中,所述测量间隔的配置内容包括:第一节点对应的测量间隔的配置内容或者第一节点和第二节点分别对应的测量间隔的配置内容。
可选地,处理器750还用于:接收第二节点发送的测量间隔的请求信息,并将所述请求信息发送给第一节点;
其中,所述请求信息包括:配置请求和配置策略中的至少一项。
可选地,处理器750还用于:将测量间隔配置相关信息发送给第一节点和第二节点中的至少一者;
其中,所述测量间隔配置相关信息包括:终端需求的测量间隔和/或终端能力支持的测量间隔。
可选地,当所述判断结果为没有新数据需要发送时,处理器750还用于:在预设消息中添加测量间隔配置相关信息,生成目标预设消息;
通过所述目标预设消息,将所述测量间隔配置相关信息发送给第一节点和第二节点中的至少一者;
其中,所述目标预设消息为无线资源控制RRC消息或能力上报消息。
可选地,当所述判断结果为没有新数据需要发送时,处理器750还用于:生成一辅助消息,所述辅助消息中包含所述测量间隔配置相关信息;通过所述辅助消息,将所述测量间隔配置相关信息发送给第一节点和第二节点中的至少一者。
可选地,处理器750还用于:开启禁止测量间隔配置相关信息上报定时器;
其中,在所述禁止测量间隔配置相关信息上报定时器的定时时间内,停止上报测量间隔配置相关信息。
可选地,处理器750还用于:接收第一节点和第二节点中的至少一者发送的测量间隔配置相关信息的指示信息,所述指示信息用于指示是否允许测量间隔配置相关信息的上报;在所述指示信息用于指示允许测量间隔配置相关信息的上报时,将测量间隔配置相关信息发送给第一节点和第二节点中的至少一者。
可选地,当同时接收到第一节点和第二节点发送的测量间隔、且第一节点和第二节点配置的第一节点对应的测量间隔与第二节点对应的测量间隔不一致时,处理器750还用于:在所述测量间隔为针对终端per-UE的测量间隔时,选择第一节点或第二节点发送的测量间隔;在所述测量间隔为针对终端对应的每个小区组per-CG的测量间隔和/或针对终端对应的成分载波per-CC的测量间隔时,选择第一节点发送的属于第一节点对应的测量间隔,选择第二节点发送的属于第二节点对应的测量间隔。
本公开一些实施例的终端能够实现前述实施例中终端实现的各个过程,为避免重复,这里不再赘述。
本公开一些实施例的终端,通过处理器750接收第一节点和/或第二节点配置的测量间隔;以此保证了NR网络通信流程的完整,保证了网络通信的可靠性和有效性。
本说明书中的各个实施例均采用递进的方式描述,每个实施例重点说明 的都是与其他实施例的不同之处,各个实施例之间相同相似的部分互相参见即可。
本领域内的技术人员应明白,本公开一些实施例的实施例可提供为方法、装置、或计算机程序产品。因此,本公开一些实施例可采用完全硬件实施例、完全软件实施例、或结合软件和硬件方面的实施例的形式。而且,本公开一些实施例可采用在一个或多个其中包含有计算机可用程序代码的计算机可用存储介质(包括但不限于磁盘存储器、CD-ROM、光学存储器等)上实施的计算机程序产品的形式。
本公开一些实施例是参照根据本公开一些实施例的方法、终端设备(系统)、和计算机程序产品的流程图和/或方框图来描述的。应理解可由计算机程序指令实现流程图和/或方框图中的每一流程和/或方框、以及流程图和/或方框图中的流程和/或方框的结合。可提供这些计算机程序指令到通用计算机、专用计算机、嵌入式处理机或其他可编程数据处理终端设备的处理器以产生一个机器,使得通过计算机或其他可编程数据处理终端设备的处理器执行的指令产生用于实现在流程图一个流程或多个流程和/或方框图一个方框或多个方框中指定的功能的装置。
这些计算机程序指令也可存储在能引导计算机或其他可编程数据处理终端设备以特定方式工作的计算机可读存储器中,使得存储在该计算机可读存储器中的指令产生包括指令装置的制造品,该指令装置实现在流程图一个流程或多个流程和/或方框图一个方框或多个方框中指定的功能。
这些计算机程序指令也可装载到计算机或其他可编程数据处理终端设备上,使得在计算机或其他可编程终端设备上执行一系列操作步骤以产生计算机实现的处理,从而在计算机或其他可编程终端设备上执行的指令提供用于实现在流程图一个流程或多个流程和/或方框图一个方框或多个方框中指定的功能的步骤。
尽管已描述了本公开一些实施例的优选实施例,但本领域内的技术人员一旦得知了基本创造性概念,则可对这些实施例做出另外的变更和修改。所以,所附权利要求意欲解释为包括优选实施例以及落入本公开一些实施例范围的所有变更和修改。
还需要说明的是,在本文中,诸如第一和第二等之类的关系术语仅仅用来将一个实体或者操作与另一个实体或操作区分开来,而不一定要求或者暗示这些实体或操作之间存在任何这种实际的关系或者顺序。而且,术语“包括”、“包含”或者其任何其他变体意在涵盖非排他性的包含,从而使得包括一系列要素的过程、方法、物品或者终端设备不仅包括那些要素,而且还包括没有明确列出的其他要素,或者是还包括为这种过程、方法、物品或者终端设备所固有的要素。在没有更多限制的情况下,由语句“包括一个……”限定的要素,并不排除在包括所述要素的过程、方法、物品或者终端设备中还存在另外的相同要素。
以上所述的是本公开的一些实施方式,应当指出对于本技术领域的普通人员来说,在不脱离本公开所述的原理前提下还可以作出若干改进和润饰,这些改进和润饰也在本公开的保护范围内。

Claims (112)

  1. 一种测量间隔的配置方法,应用于第一节点,包括:
    为终端进行测量间隔的配置;
    其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。
  2. 根据权利要求1所述的测量间隔的配置方法,还包括:
    向第二节点发送所述测量间隔的配置内容。
  3. 根据权利要求2所述的测量间隔的配置方法,其中,所述向第二节点发送所述测量间隔的配置内容的步骤,包括:
    通过X2接口或者操作维护管理OAM架构的S1接口,向第二节点发送所述测量间隔的配置内容;或者
    将所述测量间隔的配置内容发送给终端,使得终端将所述测量间隔的配置内容上报给第二节点。
  4. 根据权利要求1所述的测量间隔的配置方法,还包括:
    接收第二节点发送的测量间隔的配置内容。
  5. 根据权利要求4所述的测量间隔的配置方法,其中,所述接收第二节点发送的测量间隔的配置内容的步骤,包括:
    通过X2接口或者OAM架构的S1接口,接收第二节点发送的测量间隔的配置内容;或者
    接收终端转发的第二节点发送的测量间隔的配置内容。
  6. 根据权利要求2或4所述的测量间隔的配置方法,其中,所述测量间隔的配置内容包括:针对终端per-UE的测量间隔的配置内容、所述第一节点对应的测量间隔的配置内容和所述第二节点对应的测量间隔的配置内容中的至少一项;
    其中,所述第一节点对应的测量间隔的配置内容包括:第一节点对应的针对终端对应的每个小区组per-CG的测量间隔的配置内容和针对终端对应的成分载波per-CC的测量间隔的配置内容中的至少一项;
    其中,所述第二节点对应的测量间隔的配置内容包括:第二节点对应的针对终端对应的每个小区组per-CG的测量间隔的配置内容和针对终端对应的成分载波per-CC的测量间隔的配置内容中的至少一项。
  7. 根据权利要求1所述的测量间隔的配置方法,其中,在所述为终端进行测量间隔的配置的步骤之前,还包括:
    获取第二节点发送的测量间隔的请求信息;
    其中,所述请求信息包括:配置请求和配置策略中的至少一项。
  8. 根据权利要求7所述的测量间隔的配置方法,其中,所述获取第二节点发送的测量间隔的请求信息的步骤,包括:
    通过X2接口或者OAM架构的S1接口,接收第二节点发送的测量间隔的请求信息;或者
    接收终端转发的第二节点发送的测量间隔的请求信息。
  9. 根据权利要求7所述的测量间隔的配置方法,其中,所述为终端进行测量间隔的配置的步骤,包括:
    根据所述请求信息,为终端进行测量间隔的配置;
    其中,所述测量间隔包括:针对终端per-UE的测量间隔、所述第一节点对应的测量间隔和所述第二节点对应的测量间隔中的至少一项。
  10. 根据权利要求9所述的测量间隔的配置方法,还包括:
    向第二节点发送所述第二节点对应的测量间隔的配置内容。
  11. 根据权利要求7所述的测量间隔的配置方法,其中,在所述获取第二节点发送的测量间隔的请求信息的步骤之后,还包括:
    根据所述请求信息,确定所述第二节点对应的测量间隔的配置内容。
  12. 根据权利要求11所述的测量间隔的配置方法,其中,在所述确定所述第二节点对应的测量间隔的配置内容的步骤之后,还包括:
    将所述第二节点对应的测量间隔的配置内容发送给第二节点。
  13. 根据权利要求11所述的测量间隔的配置方法,其中,所述第一节点为终端配置的测量间隔为第一节点对应的测量间隔。
  14. 根据权利要求7所述的测量间隔的配置方法,其中,在所述获取第二节点发送的测量间隔的请求信息的步骤之后,还包括:
    根据所述请求信息,确定所述第一节点和所述第二节点对应的测量间隔的配置内容。
  15. 根据权利要求14所述的测量间隔的配置方法,其中,在所述确定所述第一节点和所述第二节点对应的测量间隔的配置内容的步骤之后,还包括:
    将所述第一节点和所述第二节点对应的测量间隔的配置内容发送给第二节点。
  16. 根据权利要求1所述的测量间隔的配置方法,其中,在所述为终端进行测量间隔的配置的步骤之前,还包括:
    将测量间隔的配置策略发送给中心控制节点,使得中心控制节点根据所述配置策略确定测量间隔的配置内容,并接收所述中心控制节点反馈的所述配置内容。
  17. 根据权利要求16所述的测量间隔的配置方法,其中,所述为终端进行测量间隔的配置的步骤,包括:
    根据所述配置内容,为终端进行测量间隔的配置;
    其中,所述第一节点为终端配置的测量间隔为第一节点对应的测量间隔或者所述第一节点为终端配置的测量间隔为第一节点和第二节点分别对应的测量间隔。
  18. 根据权利要求1、9或16所述的测量间隔的配置方法,其中,所述为终端进行测量间隔的配置的步骤,包括:
    获取终端上报的或第二节点发送的测量间隔配置相关信息;
    根据所述测量间隔配置相关信息,为终端进行测量间隔的配置;
    其中,所述测量间隔配置相关信息包括:终端需求的测量间隔和/或终端能力支持的测量间隔。
  19. 根据权利要求18所述的测量间隔的配置方法,其中,在获取终端上报的测量间隔配置相关信息的步骤之后,还包括:
    将所述测量间隔配置相关信息中所述第一节点对应的测量间隔配置相关信息和/或所述第二节点对应的测量间隔配置相关信息,发送给第二节点。
  20. 根据权利要求18所述的测量间隔的配置方法,其中,在所述根据所述测量间隔配置相关信息,为终端进行测量间隔的配置的步骤之后,还包括:
    将配置的所述测量间隔中第二节点对应的测量间隔的配置内容和/或第一节点与第二节点分别对应的测量间隔的配置内容发送给第二节点。
  21. 根据权利要求18所述的测量间隔的配置方法,其中,当所述测量间隔配置相关信息由终端上报时,所述获取终端上报的测量间隔配置相关信息的方式为:
    在终端发送的目标预设消息或辅助消息中,获取终端上报的测量间隔配置相关信息;
    其中,所述目标预设消息为无线资源控制RRC消息或能力上报消息。
  22. 根据权利要求18所述的测量间隔的配置方法,其中,在获取终端上报的测量间隔配置相关信息的步骤之前,还包括:
    发送测量间隔配置相关信息的指示信息给终端,所述指示信息用于指示是否允许测量间隔配置相关信息的上报。
  23. 根据权利要求1所述的测量间隔的配置方法,还包括:
    将配置的测量间隔发送给终端;
    其中,所述测量间隔包括:针对终端per-UE的测量间隔、所述第一节点对应的测量间隔和第二节点对应的测量间隔中的至少一项。
  24. 一种测量间隔的配置方法,应用于第二节点,包括:
    接收第一节点发送的测量间隔的配置内容,所述测量间隔为所述第一节点为终端配置的;
    其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。
  25. 根据权利要求24所述的测量间隔的配置方法,其中,在所述接收第一节点发送的测量间隔的配置内容的步骤之后,还包括:
    根据所述测量间隔的配置内容,为终端进行测量间隔的配置。
  26. 根据权利要求25所述的测量间隔的配置方法,还包括:
    向第一节点发送所述测量间隔的配置内容。
  27. 根据权利要求26所述的测量间隔的配置方法,其中,所述向第一节点发送所述测量间隔的配置内容的步骤包括:
    通过X2接口或者操作维护管理OAM架构的S1接口,向第一节点发送所述测量间隔的配置内容;或者
    将所述测量间隔的配置内容发送给终端,使得终端将所述测量间隔的配置内容上报给第一节点。
  28. 根据权利要求24所述的测量间隔的配置方法,其中,所述接收第一节点发送的测量间隔的配置内容的步骤包括:
    通过X2接口或者操作维护管理OAM架构的S1接口,接收所述第一节点发送的测量间隔的配置内容;或者
    接收终端转发的第一节点发送的测量间隔的配置内容。
  29. 根据权利要求28所述的测量间隔的配置方法,其中,所述测量间隔的配置内容包括:针对终端per-UE的测量间隔的配置内容、所述第一节点对应的测量间隔的配置内容和所述第二节点对应的测量间隔的配置内容中的至少一项;
    其中,所述第一节点对应的测量间隔的配置内容包括:第一节点对应的针对终端对应的每个小区组per-CG的测量间隔的配置内容和针对终端对应的成分载波per-CC的测量间隔的配置内容中的至少一项;
    其中,所述第二节点对应的测量间隔的配置内容包括:第二节点对应的针对终端对应的每个小区组per-CG的测量间隔的配置内容和针对终端对应的成分载波per-CC的测量间隔的配置内容中的至少一项。
  30. 根据权利要求24所述的测量间隔的配置方法,其中,所述接收第一节点发送的测量间隔的配置内容的步骤,包括:
    发送第二节点的测量间隔的请求信息给所述第一节点;
    获取所述第一节点根据所述请求信息,反馈的测量间隔的配置内容;
    其中,所述请求信息包括:配置请求和配置策略中的至少一项。
  31. 根据权利要求30所述的测量间隔的配置方法,其中,所述发送第二节点的测量间隔的请求信息给所述第一节点的步骤,包括:
    通过X2接口或者OAM架构的S1接口,发送第二节点的测量间隔的请求信息给所述第一节点;或者
    将第二节点的测量间隔的请求信息发送给终端,使得终端将所述第二节 点的测量间隔的请求信息上报给第一节点。
  32. 根据权利要求24所述的测量间隔的配置方法,其中,在接收所述第一节点发送的测量间隔的步骤之前,还包括:
    发送测量间隔的配置策略给中心控制节点,使得中心控制节点根据所述配置策略确定测量间隔的配置内容,并接收所述中心控制节点反馈的所述配置内容。
  33. 根据权利要求30或32所述的测量间隔的配置方法,还包括:
    根据测量间隔的配置内容,为终端进行测量间隔的配置;
    其中,所述测量间隔包括:所述第一节点对应的测量间隔和/或所述第二节点对应的测量间隔。
  34. 根据权利要求33所述的测量间隔的配置方法,其中,在为终端进行测量间隔的配置的步骤之后,还包括:
    将配置的测量间隔发送给终端;
    其中,所述测量间隔包括:针对终端per-UE的测量间隔、所述第一节点对应的测量间隔和所述第二节点对应的测量间隔中的至少一项。
  35. 根据权利要求24所述的测量间隔的配置方法,还包括:
    获取终端上报的测量间隔配置相关信息;
    其中,所述测量间隔配置相关信息包括:终端需求的测量间隔和/或终端能力支持的测量间隔。
  36. 根据权利要求35所述的测量间隔的配置方法,其中,在所述获取终端上报的测量间隔配置相关信息的步骤之后,还包括:
    将所述测量间隔配置相关信息发送给第一节点。
  37. 根据权利要求36所述的测量间隔的配置方法,其中,所述接收第一节点发送的测量间隔的配置内容的步骤,包括:
    接收第一节点根据所述测量间隔配置相关信息,反馈的测量间隔的配置内容。
  38. 根据权利要求37所述的测量间隔的配置方法,其中,在所述接收第一节点根据所述测量间隔配置相关信息,反馈的测量间隔的配置内容的步骤之后,还包括:
    根据所述配置内容,为终端进行测量间隔的配置。
  39. 根据权利要求35所述的测量间隔的配置方法,其中,在所述获取终端上报的测量间隔配置相关信息的步骤之后,还包括:
    根据所述测量间隔配置相关信息,为终端进行测量间隔的配置。
  40. 根据权利要求35所述的测量间隔的配置方法,其中,所述获取终端上报的测量间隔配置相关信息的步骤,包括:
    在终端发送的目标预设消息或辅助消息中,获取终端上报的测量间隔配置相关信息;
    其中,所述目标预设消息为无线资源控制RRC消息或能力上报消息。
  41. 根据权利要求35所述的测量间隔的配置方法,其中,在获取终端上报的测量间隔配置相关信息的步骤之前,还包括:
    发送测量间隔配置相关信息的指示信息给终端,所述指示信息用于指示是否允许测量间隔配置相关信息的上报。
  42. 根据权利要求39所述的测量间隔的配置方法,其中,在所述为终端进行测量间隔的配置的步骤之后,还包括:
    将所述测量间隔的配置内容通知给所述第一节点;
    其中所述测量间隔的配置内容包括:第二节点对应的测量间隔的配置内容。
  43. 根据权利要求42所述的测量间隔的配置方法,其中,所述将所述测量间隔的配置内容通知给所述第一节点的步骤,包括:
    通过X2接口或者操作维护管理OAM架构的S1接口,将所述测量间隔的配置内容通知给所述第一节点;或者
    将所述测量间隔的配置内容发送给终端,使得终端将所述测量间隔的配置内容上报给所述第一节点。
  44. 根据权利要求25、38或39所述的测量间隔的配置方法,其中,在为终端进行测量间隔的配置的步骤之后,还包括:
    将配置的测量间隔发送给终端;
    其中,所述测量间隔包括:针对终端per-UE的测量间隔、所述第一节点对应的测量间隔和第二节点对应的测量间隔中的至少一项。
  45. 一种测量间隔的配置方法,应用于终端,包括:
    接收第一节点和/或第二节点配置的测量间隔;
    其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。
  46. 根据权利要求45所述的测量间隔的配置方法,其中,当接收到第一节点发送的测量间隔时,还包括:
    将所述测量间隔的配置内容发送给第二节点;
    其中,所述测量间隔的配置内容包括:第一节点对应的测量间隔的配置内容或者第一节点和第二节点分别对应的测量间隔的配置内容。
  47. 根据权利要求45所述的测量间隔的配置方法,还包括:
    接收第二节点发送的测量间隔的请求信息,并将所述请求信息发送给第一节点;
    其中,所述请求信息包括:配置请求和配置策略中的至少一项。
  48. 根据权利要求45所述的测量间隔的配置方法,还包括:
    将测量间隔配置相关信息发送给第一节点和第二节点中的至少一者;
    其中,所述测量间隔配置相关信息包括:终端需求的测量间隔和/或终端能力支持的测量间隔。
  49. 根据权利要求48所述的测量间隔的配置方法,其中,所述将测量间隔配置相关信息发送给第一节点和第二节点中的至少一者的步骤包括:
    在预设消息中添加测量间隔配置相关信息,生成目标预设消息;
    通过所述目标预设消息,将所述测量间隔配置相关信息发送给第一节点和第二节点中的至少一者;
    其中,所述目标预设消息为无线资源控制RRC消息或能力上报消息。
  50. 根据权利要求48所述的测量间隔的配置方法,其中,所述将测量间隔配置相关信息发送给第一节点和第二节点中的至少一者的步骤包括:
    生成一辅助消息,所述辅助消息中包含所述测量间隔配置相关信息;
    通过所述辅助消息,将所述测量间隔配置相关信息发送给第一节点和第二节点中的至少一者。
  51. 根据权利要求48所述的测量间隔的配置方法,还包括:
    开启禁止测量间隔配置相关信息上报定时器;
    其中,在所述禁止测量间隔配置相关信息上报定时器的定时时间内,停止上报测量间隔配置相关信息。
  52. 根据权利要求48所述的测量间隔的配置方法,其中,所述将测量间隔配置相关信息发送给第一节点和第二节点中的至少一者的步骤包括:
    接收第一节点和第二节点中的至少一者发送的测量间隔配置相关信息的指示信息,所述指示信息用于指示是否允许测量间隔配置相关信息的上报;
    在所述指示信息用于指示允许测量间隔配置相关信息的上报时,将测量间隔配置相关信息发送给第一节点和第二节点中的至少一者。
  53. 根据权利要求45所述的测量间隔的配置方法,其中,当同时接收到第一节点和第二节点发送的测量间隔、且第一节点和第二节点配置的第一节点对应的测量间隔与第二节点对应的测量间隔不一致时,还包括:
    在所述测量间隔为针对终端per-UE的测量间隔时,选择第一节点或第二节点发送的测量间隔;
    在所述测量间隔为针对终端对应的每个小区组per-CG的测量间隔和/或针对终端对应的成分载波per-CC的测量间隔时,选择第一节点发送的属于第一节点对应的测量间隔,选择第二节点发送的属于第二节点对应的测量间隔。
  54. 一种第一节点,包括:
    第一配置模块,用于为终端进行测量间隔的配置;
    其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。
  55. 根据权利要求54所述的第一节点,还包括:
    第一发送模块,用于向第二节点发送所述测量间隔的配置内容。
  56. 根据权利要求55所述的第一节点,其中,所述第一发送模块用于:
    通过X2接口或者操作维护管理OAM架构的S1接口,向第二节点发送所述测量间隔的配置内容;或者
    将所述测量间隔的配置内容发送给终端,使得终端将所述测量间隔的配 置内容上报给第二节点。
  57. 根据权利要求54所述的第一节点,还包括:
    第一接收模块,用于接收第二节点发送的测量间隔的配置内容。
  58. 根据权利要求57所述的第一节点,其中,所述第一接收模块用于:
    通过X2接口或者OAM架构的S1接口,接收第二节点发送的测量间隔的配置内容;或者
    接收终端转发的第二节点发送的测量间隔的配置内容。
  59. 根据权利要求55或57所述的第一节点,其中,所述测量间隔的配置内容包括:针对终端per-UE的测量间隔的配置内容、所述第一节点对应的测量间隔的配置内容和所述第二节点对应的测量间隔的配置内容中的至少一项;
    其中,所述第一节点对应的测量间隔的配置内容包括:第一节点对应的针对终端对应的每个小区组per-CG的测量间隔的配置内容和针对终端对应的成分载波per-CC的测量间隔的配置内容中的至少一项;
    其中,所述第二节点对应的测量间隔的配置内容包括:第二节点对应的针对终端对应的每个小区组per-CG的测量间隔的配置内容和针对终端对应的成分载波per-CC的测量间隔的配置内容中的至少一项。
  60. 根据权利要求54所述的第一节点,还包括:
    第一获取模块,用于获取第二节点发送的测量间隔的请求信息;
    其中,所述请求信息包括:配置请求和配置策略中的至少一项。
  61. 根据权利要求60所述的第一节点,其中,所述第一获取模块用于:
    通过X2接口或者OAM架构的S1接口,接收第二节点发送的测量间隔的请求信息;或者
    接收终端转发的第二节点发送的测量间隔的请求信息。
  62. 根据权利要求60所述的第一节点,其中,所述第一配置模块用于:
    根据所述请求信息,为终端进行测量间隔的配置;
    其中,所述测量间隔包括:针对终端per-UE的测量间隔、所述第一节点对应的测量间隔和所述第二节点对应的测量间隔中的至少一项。
  63. 根据权利要求62所述的第一节点,还包括:
    第二发送模块,用于向第二节点发送所述第二节点对应的测量间隔的配置内容。
  64. 根据权利要求60所述的第一节点,还包括:
    第一确定模块,用于根据所述请求信息,确定所述第二节点对应的测量间隔的配置内容。
  65. 根据权利要求64所述的第一节点,还包括:
    第三发送模块,用于将所述第二节点对应的测量间隔的配置内容发送给第二节点。
  66. 根据权利要求64所述的第一节点,其中,所述第一节点为终端配置的测量间隔为第一节点对应的测量间隔。
  67. 根据权利要求60所述的第一节点,还包括:
    第二确定模块,用于根据所述请求信息,确定所述第一节点和所述第二节点对应的测量间隔的配置内容。
  68. 根据权利要求67所述的第一节点,还包括:
    第四发送模块,用于将所述第一节点和所述第二节点对应的测量间隔的配置内容发送给第二节点。
  69. 根据权利要求54所述的第一节点,还包括:
    第五发送模块,用于将测量间隔的配置策略发送给中心控制节点,使得中心控制节点根据所述配置策略确定测量间隔的配置内容,并接收所述中心控制节点反馈的所述配置内容。
  70. 根据权利要求68所述的第一节点,其中,所述第一配置模块用于:
    根据所述配置内容,为终端进行测量间隔的配置;
    其中,所述第一节点为终端配置的测量间隔为第一节点对应的测量间隔或者所述第一节点为终端配置的测量间隔为第一节点和第二节点分别对应的测量间隔。
  71. 根据权利要求54、62或69所述的第一节点,其中,所述为终端进行测量间隔的配置的方式为:
    获取终端上报的或第二节点发送的测量间隔配置相关信息;
    根据所述测量间隔配置相关信息,为终端进行测量间隔的配置;
    其中,所述测量间隔配置相关信息包括:终端需求的测量间隔和/或终端能力支持的测量间隔。
  72. 根据权利要求71所述的第一节点,还包括:
    第六发送模块,用于将所述测量间隔配置相关信息中所述第一节点对应的测量间隔配置相关信息和/或所述第二节点对应的测量间隔配置相关信息,发送给第二节点。
  73. 根据权利要求71所述的第一节点,还包括:
    第七发送模块,用于将配置的所述测量间隔中第二节点对应的测量间隔的配置内容和/或第一节点与第二节点分别对应的测量间隔的配置内容发送给第二节点。
  74. 根据权利要求71所述的第一节点,其中,当所述测量间隔配置相关信息由终端上报时,所述获取终端上报的测量间隔配置相关信息的方式为:
    在终端发送的目标预设消息或辅助消息中,获取终端上报的测量间隔配置相关信息;
    其中,所述目标预设消息为无线资源控制RRC消息或能力上报消息。
  75. 根据权利要求71所述的第一节点,还包括:
    第八发送模块,用于发送测量间隔配置相关信息的指示信息给终端,所述指示信息用于指示是否允许测量间隔配置相关信息的上报。
  76. 根据权利要求54所述的第一节点,还包括:
    第九发送模块,用于将配置的测量间隔发送给终端;
    其中,所述测量间隔包括:针对终端per-UE的测量间隔、所述第一节点对应的测量间隔和第二节点对应的测量间隔中的至少一项。
  77. 一种第二节点,包括:
    第二接收模块,用于接收第一节点发送的测量间隔的配置内容,所述测量间隔为所述第一节点为终端配置的;
    其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。
  78. 根据权利要求77所述的第二节点,还包括:
    第二配置模块,用于根据所述测量间隔的配置内容,为终端进行测量间隔的配置。
  79. 根据权利要求78所述的第二节点,还包括:
    第九发送模块,用于向第一节点发送所述测量间隔的配置内容。
  80. 根据权利要求79所述的第二节点,其中,所述第九发送模块用于:
    通过X2接口或者操作维护管理OAM架构的S1接口,向第一节点发送所述测量间隔的配置内容;或者
    将所述测量间隔的配置内容发送给终端,使得终端将所述测量间隔的配置内容上报给第一节点。
  81. 根据权利要求77所述的第二节点,其中,所述第二接收模块用于:
    通过X2接口或者操作维护管理OAM架构的S1接口,接收所述第一节点发送的测量间隔的配置内容;或者
    接收终端转发的第一节点发送的测量间隔的配置内容。
  82. 根据权利要求81所述的第二节点,其中,所述测量间隔的配置内容包括:针对终端per-UE的测量间隔的配置内容、所述第一节点对应的测量间隔的配置内容和所述第二节点对应的测量间隔的配置内容中的至少一项;
    其中,所述第一节点对应的测量间隔的配置内容包括:第一节点对应的针对终端对应的每个小区组per-CG的测量间隔的配置内容和针对终端对应的成分载波per-CC的测量间隔的配置内容中的至少一项;
    其中,所述第二节点对应的测量间隔的配置内容包括:第二节点对应的针对终端对应的每个小区组per-CG的测量间隔的配置内容和针对终端对应的成分载波per-CC的测量间隔的配置内容中的至少一项。
  83. 根据权利要求77所述的第二节点,其中,所述第二接收模块包括:
    第一发送单元,用于发送第二节点的测量间隔的请求信息给所述第一节点;
    获取单元,用于获取所述第一节点根据所述请求信息,反馈的测量间隔的配置内容;
    其中,所述请求信息包括:配置请求和配置策略中的至少一项。
  84. 根据权利要求83所述的第二节点,其中,所述发送单元用于:
    通过X2接口或者OAM架构的S1接口,发送第二节点的测量间隔的请求信息给所述第一节点;或者
    将第二节点的测量间隔的请求信息发送给终端,使得终端将所述第二节点的测量间隔的请求信息上报给第一节点。
  85. 根据权利要求77所述的第二节点,还包括:
    第十发送模块,用于发送测量间隔的配置策略给中心控制节点,使得中心控制节点根据所述配置策略确定测量间隔的配置内容,并接收所述中心控制节点反馈的所述配置内容。
  86. 根据权利要求83或85所述的第二节点,还包括:
    第三配置模块,用于根据测量间隔的配置内容,为终端进行测量间隔的配置;
    其中,所述测量间隔包括:所述第一节点对应的测量间隔和/或所述第二节点对应的测量间隔。
  87. 根据权利要求86所述的第二节点,还包括:
    第十一发送模块,用于将配置的测量间隔发送给终端;
    其中,所述测量间隔包括:针对终端per-UE的测量间隔、所述第一节点对应的测量间隔和所述第二节点对应的测量间隔中的至少一项。
  88. 根据权利要求77所述的第二节点,还包括:
    获取模块,用于获取终端上报的测量间隔配置相关信息;
    其中,所述测量间隔配置相关信息包括:终端需求的测量间隔和/或终端能力支持的测量间隔。
  89. 根据权利要求88所述的第二节点,还包括:
    第十二发送模块,用于将所述测量间隔配置相关信息发送给第一节点。
  90. 根据权利要求89所述的第二节点,其中,所述第二接收模块用于:
    接收第一节点根据所述测量间隔配置相关信息,反馈的测量间隔的配置内容。
  91. 根据权利要求90所述的第二节点,还包括:
    第四配置模块,用于根据所述配置内容,为终端进行测量间隔的配置。
  92. 根据权利要求88所述的第二节点,还包括:
    第五配置模块,用于根据所述测量间隔配置相关信息,为终端进行测量间隔的配置。
  93. 根据权利要求88所述的第二节点,其中,所述获取模块用于:
    在终端发送的目标预设消息或辅助消息中,获取终端上报的测量间隔配置相关信息;
    其中,所述目标预设消息为无线资源控制RRC消息或能力上报消息。
  94. 根据权利要求88所述的第二节点,还包括:
    第十三发送模块,用于发送测量间隔配置相关信息的指示信息给终端,所述指示信息用于指示是否允许测量间隔配置相关信息的上报。
  95. 根据权利要求92所述的第二节点,还包括:
    通知模块,用于将所述测量间隔的配置内容通知给所述第一节点;
    其中所述测量间隔的配置内容包括:第二节点对应的测量间隔的配置内容。
  96. 根据权利要求95所述的第二节点,其中,所述通知模块用于:
    通过X2接口或者操作维护管理OAM架构的S1接口,将所述测量间隔的配置内容通知给所述第一节点;或者
    将所述测量间隔的配置内容发送给终端,使得终端将所述测量间隔的配置内容上报给所述第一节点。
  97. 根据权利要求87、91或92所述的第二节点,还包括:
    第十四发送模块,用于将配置的测量间隔发送给终端;
    其中,所述测量间隔包括:针对终端per-UE的测量间隔、所述第一节点对应的测量间隔和第二节点对应的测量间隔中的至少一项。
  98. 一种终端,包括:
    第三接收模块,用于接收第一节点和/或第二节点配置的测量间隔;
    其中,所述测量间隔包括:针对终端per-UE的测量间隔、针对终端对应的每个小区组per-CG的测量间隔和针对终端对应的成分载波per-CC的测量间隔中的至少一项。
  99. 根据权利要求98所述的终端,还包括:
    第十五发送模块,用于将所述测量间隔的配置内容发送给第二节点;
    其中,所述测量间隔的配置内容包括:第一节点对应的测量间隔的配置内容或者第一节点和第二节点分别对应的测量间隔的配置内容。
  100. 根据权利要求98所述的终端,还包括:
    第四接收模块,用于接收第二节点发送的测量间隔的请求信息,并将所述请求信息发送给第一节点;
    其中,所述请求信息包括:配置请求和配置策略中的至少一项。
  101. 根据权利要求98所述的终端,还包括:
    第十六发送模块,用于将测量间隔配置相关信息发送给第一节点和第二节点中的至少一者;
    其中,所述测量间隔配置相关信息包括:终端需求的测量间隔和/或终端能力支持的测量间隔。
  102. 根据权利要求101所述的终端,其中,所述第十六发送模块包括:
    第一生成单元,用于在预设消息中添加测量间隔配置相关信息,生成目标预设消息;
    第二发送单元,用于通过所述目标预设消息,将所述测量间隔配置相关信息发送给第一节点和第二节点中的至少一者;
    其中,所述目标预设消息为无线资源控制RRC消息或能力上报消息。
  103. 根据权利要求101所述的终端,其中,所述第十六发送模块包括:
    第二生成单元,用于生成一辅助消息,所述辅助消息中包含所述测量间隔配置相关信息;
    第三发送单元,用于通过所述辅助消息,将所述测量间隔配置相关信息发送给第一节点和第二节点中的至少一者。
  104. 根据权利要求101所述的终端,还包括:
    开启模块,用于开启禁止测量间隔配置相关信息上报定时器;
    其中,在所述禁止测量间隔配置相关信息上报定时器的定时时间内,停止上报测量间隔配置相关信息。
  105. 根据权利要求101所述的终端,其中,所述第十六发送模块包括:
    指示信息接收模块,用于接收第一节点和第二节点中的至少一者发送的测量间隔配置相关信息的指示信息,所述指示信息用于指示是否允许测量间 隔配置相关信息的上报;
    第四发送单元,用于在所述指示信息用于指示允许测量间隔配置相关信息的上报时,将测量间隔配置相关信息发送给第一节点和第二节点中的至少一者。
  106. 根据权利要求98所述的终端,其中,当同时接收到第一节点和第二节点发送的测量间隔、且第一节点和第二节点配置的第一节点对应的测量间隔与第二节点对应的测量间隔不一致时,还包括:
    第一选择模块,用于在所述测量间隔为针对终端per-UE的测量间隔时,选择第一节点或第二节点发送的测量间隔;
    第二选择模块,用于在所述测量间隔为针对终端对应的每个小区组per-CG的测量间隔和/或针对终端对应的成分载波per-CC的测量间隔时,选择第一节点发送的属于第一节点对应的测量间隔,选择第二节点发送的属于第二节点对应的测量间隔。
  107. 一种第一节点,包括处理器、存储器及存储在所述存储器上并可在所述处理器上运行的网络接入程序,所述网络接入程序被所述处理器执行时实现如权利要求1至23中任一项所述的测量间隔的配置方法的步骤。
  108. 一种计算机可读取存储介质,其中,所述计算机可读取存储介质上存储有网络接入程序,所述网络接入程序被处理器执行时实现如权利要求1至23中任一项所述的测量间隔的配置方法的步骤。
  109. 一种第二节点,包括处理器、存储器及存储在所述存储器上并可在所述处理器上运行的网络接入程序,所述网络接入程序被所述处理器执行时实现如权利要求24至44中任一项所述的测量间隔的配置方法的步骤。
  110. 一种计算机可读取存储介质,其中,所述计算机可读取存储介质上存储有网络接入程序,所述网络接入程序被处理器执行时实现如权利要求24至44中任一项所述的测量间隔的配置方法的步骤。
  111. 一种终端,包括处理器、存储器及存储在所述存储器上并可在所述处理器上运行的网络接入程序,所述网络接入程序被所述处理器执行时实现如权利要求45至53中任一项所述的测量间隔的配置方法的步骤。
  112. 一种计算机可读取存储介质,其中,所述计算机可读取存储介质上 存储有网络接入程序,所述网络接入程序被处理器执行时实现如权利要求45至53中任一项所述的测量间隔的配置方法的步骤。
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