Patent Description:
The present disclosure relates to the field of wireless communications, and in particular, to a method and system for transmitting neighbor cell configuration information.

In the related art, there are two measurement references for inter-cell handover, which are SSB (Synchronization Signal Block) based measurement and CSI (Channel State Information) -RS (Reference Signal) based measurement.

The SSB has a frequency domain width of only <NUM> PRBs (Physical Resource blocks), and cannot measure the condition of the whole channel, while the CSI-RS can be configured to be full-band. In addition, the beams of the CSI-RS are narrower than the beams of the SSB, and can reflect the actual service beam condition. In some scenarios, the beamwidth of the SSB may differ significantly from that of the service beam of the user. Therefore, the measurement result based on the CSI-RS has higher accuracy than the handover based on the SSB based measurement.

The publication <NPL>, discloses a method and network for transmitting cell Channel State Information Reference Signal (CSI-RS) resource configuration information of neighbor cell for subsequent L3 mobility.

The publication <NPL>, is a discussion upon solutions to avoid intra-system mobility failures due to slice availability.

Other features of the present disclosure and advantages thereof will become apparent from the following detailed description of exemplary embodiments thereof, which proceeds with reference to the accompanying drawings. The scope of the present invention is defined by the scope of the appended claims.

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the disclosure and together with the description, serve to explain the principles of the disclosure.

The present disclosure may be more clearly understood from the following detailed description with reference to the accompanying drawings, in which:.

It should be understood that the dimensions of the various parts shown in the drawings are not drawn to scale. Further, the same or similar reference numerals denote the same or similar component.

The technical solutions in the embodiments of the present disclosure will be described clearly and completely with reference to the drawings in the embodiments of the present disclosure, and it is obvious that the embodiments described are only some, rather than all, of the embodiments of the present disclosure. The following description of at least one exemplary embodiment is merely illustrative in nature and is in no way intended to limit the disclosure, its application, or uses. The scope of the present invention is defined by the scope of the appended claims.

The relative arrangement of parts and steps, numerical expressions and numerical values set forth in these embodiments do not limit the scope of the present disclosure unless specifically stated otherwise.

Meanwhile, it should be understood that, for the convenience of description, the sizes of the respective portions shown in the drawings are not drawn in an actual proportional relationship.

Techniques, methods, and apparatus known to one of ordinary skill in the relevant art may not be discussed in detail but are intended to be part of the specification where appropriate.

In all examples shown and discussed herein, any particular value should be construed as exemplary only and not as limiting. Thus, other examples of the exemplary embodiments may have different values.

It should be noted that: similar reference numbers and letters refer to similar items in the following figures, and thus, once an item is defined in one figure, it need not be discussed further in subsequent figures.

The inventors have noticed that because the configuration of the CSI-RS information is at least one cell granularity and the CSI-RS information is a time-varying parameter, completely completing the configuration of the CSI-RS information through network management or manually leads to a large optimization workload and is prone to configuration errors. In order to reduce the error probability and improve the network automation degree, some schemes are proposed in the related art for updating based on CSI-RS. But these schemes only support SA (standalone) mode and there is a scenario of an Xn interface. Since there is no interface between base stations in an NSA (Non-Standalone) scenario, these related techniques cannot be applied to the NSA scenario.

Therefore, the present disclosure provides a scheme for an NR base station to automatically acquire CSI-RS configuration information without an interbase station interface.

<FIG> is a flowchart illustrating a method for transmitting a neighbor cell configuration information according to an embodiment of the present disclosure.

In step <NUM>, a first base station determines a second base station corresponding to a neighbor cell of a cell whose CSI-RS configuration is updated according to a neighboring cell relationship under a condition that the CSI-RS configuration for mobility measurement in at least one associated cell is updated.

It should be noted that, both the first base station and the second base station support NR (New Radio), and there is no interface for direct communication between the first base station and the second base station.

In step <NUM>, the first base station transmits the updated CSI-RS configuration information to a selected first relay node.

The first relay node is associated with modes of the first base station and the second base station.

For example, the first relay node is a first AMF (Access and Mobility Management Function) entity connected to the first base station under a condition that the first base station and the second base station are both in an SA mode.

The first relay node is a third base station having a direct communication interface with the first base station under a condition that the first base station is in a NSA mode, and the third base station supports an air interface of the LTE (long term evolution).

In some embodiments, the CSI-RS configuration information comprises at least one of the following:.

In step <NUM>, the first relay node transmits the updated CSI-RS configuration information to the second base station.

In step <NUM>, the second base station indicates the terminal located in the coverage of the second base station to perform corresponding measurement on a cell associated with the first base station according to the updated CSI-RS configuration information.

In the method for transmitting a neighbor cell configuration information provided in the foregoing embodiment of the present disclosure, under a condition that both the first base station and the second base station support the NR but have no interface for direct communication therebetween, the updated CSI-RS configuration information is transmitted from the first base station to the second base station by using the first relay node. The present disclosure can effectively reduce the workload of manual configuration and reduce the possibility of configuration errors. Furthermore, the present disclosure can utilize existing protocol processes without requiring extensive modifications to existing protocols.

<FIG> is a flowchart illustrating a method for transmitting a neighbor cell configuration information according to another embodiment of the disclosure. In the embodiment shown in <FIG>, the first base station and the second base station both support the NR, and there is no interface for direct communication between the first base station and the second base station, and both the first base station and the second base station are in an SA mode.

In step <NUM>, the first base station transmits an Uplink RAN (Radio Access Network) Configuration Transfer information to the first AMF by using an interface (for example, an NG interface) between the first base station and the first AMF. Here, the first AMF connected to the first base station is used as the first relay node.

In some embodiments, at least a first base station identifier and a TAI (Tracking Area identifier) corresponding to the first base station identifier, a second base station identifier and a TAI corresponding to the second base station identifier, and updated CSI-RS Configuration information are included in a SON (Self-Organized Network) Configuration Transfer information element (SON Configuration Transfer IE) of the uplink RAN Configuration Transfer information.

In step <NUM>, the first AMF determines whether the second base station is located in the coverage of the first AMF according to the second base station identifier and the TAI corresponding to the second base station identifier.

In step <NUM>, the first AMF transmits the updated CSI-RS Configuration information to the second base station by using a Downlink RAN Configuration transmission information under a condition that the second base station is located within the coverage of the first AMF.

In step <NUM>, the second base station updates a current CSI-RS configuration information of a cell whose CSI-RS configuration is updated in a neighbor cell list by using the updated CSI-RS configuration information and the first base station identifier.

In some embodiments, the neighbor cell list includes at least one of the following:.

In step <NUM>, the second base station determines whether the CSI-RS measurement is in an on state by using the updated CSI-RS configuration information.

In step 207a, under a condition that the CSI-RS measurement is in an on state, the second base station indicates the terminal within the coverage of the second base station to measure the cell associated with the first base station by using the CSI-RS by using a RRC (Radio Resource Control) reconfiguration information.

In step 207b, under a condition that the CSI-RS measurement is in the off state, the second base station indicates the terminal within the coverage of the second base station to measure the cell associated with the first base station by using the SSB through the RRC reconfiguration information.

<FIG> is a flowchart illustrating a method for transmitting a neighbor cell configuration information according to another embodiment of the disclosure. In the embodiment shown in <FIG>, the first base station and the second base station both support the NR, and have no interface for direct communication therebetween, and both the first base station and the second base station are in an SA mode.

At step <NUM>, the first base station transmits a uplink RAN configuration transfer information to the first AMF using an interface (e.g., an NG interface) between the first base station and the first AMF. Here, the first AMF connected to the first base station is used as the first relay node.

In some embodiments, at least the first base station identifier and the TAI associated with the first base station identifier, the second base station identifier and the TAI associated with the second base station identifier, and the updated CSI-RS configuration information are included in a SON configuration transmission information element of the uplink RAN configuration transmission information.

In step <NUM>, the first AMF determines whether the second base station is located within the coverage of the first AMF according to the second base station identifier and the TAI associated with the second base station identifier.

In step <NUM>, the first AMF transmits the updated CSI-RS configuration information to the second AMF according to the TAI associated with the second base station identifier under a condition that the second base station is not located in the coverage of the first AMF. Here, the second AMF connected to the second base station is used as the second relay node.

In step <NUM>, the second AMF transmits the updated CSI-RS configuration information to the second base station by using the downlink RAN configuration transmission information.

In step 308a, under a condition that the CSI-RS measurement is in the on state, the second base station indicates, by means of the RRC reconfiguration information, the terminal within the coverage of the second base station to measure the cell associated with the first base station by using the CSI-RS.

In step 308b, under a condition that the CSI-RS measurement is in the off state, the second base station indicates, by means of the RRC reconfiguration information, the terminal within the coverage of the second base station to measure the cell associated with the first base station by using the SSB.

<FIG> is a flowchart illustrating a method for transmitting a neighbor cell configuration information according to another embodiment of the disclosure. In the embodiment shown in <FIG>, the first base station and the second base station both support the NR, and there is no interface for direct communication between them, and the first base station is in the NSA mode.

In step <NUM>, the first base station transmits the updated CSI-RS Configuration information to the first LTE base station by using the EN-DC (EUTRAN-NR DC) configuration update information. Here, the first LTE base station having a direct communication interface connection with the first base station is used as the first relay node.

In step <NUM>, the first LTE base station updates the corresponding neighbor list with the updated CSI-RS configuration information.

In step <NUM>, the first LTE base station sends an EN-DC Configuration update ACK (acknowledgement) information to the first base station.

In step <NUM>, the first LTE base station determines whether the second base station is located within the coverage of the first LTE base station. If the second base station is located in the coverage of the first LTE base station, the first LTE base station further determines whether the second base station supports the preset signaling radio bearer measurement according to network management configuration.

In some embodiments, the preset signaling radio bearer measurement is SRB (signaling Radio Bearer) <NUM>.

In step <NUM>, under a condition that the second base station supports the preset signaling radio bearer measurement, the first LTE base station transmits the updated CSI-RS configuration information to the second base station by means of the EN-DC configuration update information.

In some embodiments, under a condition that the second base station does not support the preset signaling radio bearer measurement, the first LTE base station discards the updated CSI-RS configuration information and does not perform the subsequent processing.

In step <NUM>, the second base station updates the corresponding neighbor cell list by using the updated CSI-RS configuration information after receiving the EN-DC configuration update information.

In step <NUM>, the second base station transmits an EN-DC configuration update acknowledge message to the first LTE base station.

In step <NUM>, under a condition that the first base station starts CSI-RS measurement, the second base station indicates the NSA terminal located within the coverage of the second base station to perform CSI-RS measurement for a cell supporting CSI-RS measurement among cells associated with the first base station.

<FIG> is a flowchart illustrating a method for transmitting neighbor cell configuration information according to another embodiment of the disclosure. In the embodiment shown in <FIG>, the first base station and the second base station both support the NR, and there is no interface for direct communication between them, and the first base station is in the NSA mode.

In step <NUM>, the first base station transmits the updated CSI-RS Configuration information to the first LTE base station by using the EN-DC configuration update information. Here, the first LTE base station having a direct communication interface connection with the first base station is used as the first relay node.

In step <NUM>, the first LTE base station updates the corresponding neighbor cell list with the updated CSI-RS configuration information.

In step <NUM>, the first LTE base station transmits an EN-DC configuration update acknowledge message to the first base station.

In step <NUM>, the first LTE base station determines whether the second base station is located within the coverage of the first LTE base station.

In step <NUM>, under a condition that the second base station is not located in the coverage of the first relay node, the first relay node transmits the updated CSI-RS configuration information to the second LTE base station through an eNB (Evolved NodeB) configuration update information. Here, the second LTE base station having a direct communication interface with the second base station is used as the second relay node. The second relay node supports an air interface of the LTE, and the second base station is located in the coverage range of the second relay node.

In step <NUM>, the second LTE base station updates the corresponding neighbor cell list with the updated CSI-RS configuration information.

In step <NUM>, the second LTE base station transmits the eNB configuration update confirmation information to the first LTE base station.

In step <NUM>, the second LTE base station determines whether the second base station supports the preset signaling radio bearer measurement according to the network management configuration.

In some embodiments, the preset signaling radio bearer measurement is SRB3.

In step <NUM>, under a condition that the second base station supports the predetermined signaling radio bearer measurement, the second LTE base station transmits the updated CSI-RS configuration information to the second base station through the EN-DC configuration update information.

In some embodiments, under a condition that the second base station does not support the predetermined signaling radio bearer measurement, the second LTE base station discards the updated CSI-RS configuration information and does not perform the subsequent processing.

In step <NUM>, the second base station transmits an EN-DC configuration update confirmation information to the second LTE base station.

In step <NUM>, under a condition that the first base station starts CSI-RS measurement, the second base station indicates the NSA terminal within the coverage of the second base station to perform CSI-RS measurement for a cell supporting CSI-RS measurement among cells associated with the first base station.

<FIG> is a schematic structural diagram of a neighbor cell configuration information transmission system according to an embodiment of the present disclosure. As shown in <FIG>, the system includes a first base station <NUM>, a second base station <NUM>, and a first relay node <NUM>. The first base station <NUM> and the second base station <NUM> both support the NR, and there is no interface for direct communication between the first base station <NUM> and the second base station <NUM>.

The first base station <NUM> determines a second base station <NUM> corresponding to a neighbor cell of a cell whose CSI-RS configuration is updated according to a neighboring cell relationship under a condition that the CSI-RS configuration for mobility measurement in at least one associated cell is updated. The first base station <NUM> transmits the updated CSI-RS configuration information to the selected first relay node <NUM>.

The first relay node <NUM> is associated with modes of the first base station <NUM> and the second base station <NUM>.

For example, the first relay node <NUM> is a first AMF entity connected to the first base station <NUM> under a condition that the first base station <NUM> and the second base station <NUM> are both in an SA mode.

The first relay node <NUM> is a third base station having a direct communication interface with the first base station <NUM> under a condition that the first base station <NUM> is in a NSA mode, wherein the third base station supports an air interface of the LTE.

The first relay node <NUM> transmits the updated CSI-RS configuration information to the second base station <NUM>. The second base station <NUM> indicates the terminal in the coverage of the second base station <NUM> to perform corresponding measurements on the cell associated with the first base station <NUM> according to the updated CSI-RS configuration information.

In some embodiments, under a condition that the first base station <NUM> and the second base station <NUM> are both in the SA mode, and the first AMF connected to the first base station <NUM> is used as the first relay node <NUM>, the first base station <NUM> transmits the uplink RAN configuration transmission information to the first relay node <NUM> using an interface (for example, an NG interface) between the first base station and the first relay node <NUM>.

For example, the SON configuration transmission information element in the uplink RAN configuration transmission information contains a first base station identifier and a tracking area identifier corresponding to the first base station identifier, a second base station identifier and a tracking area identifier corresponding to the second base station identifier, and updated CSI-RS configuration information.

The first relay node <NUM> determines whether the second base station <NUM> is located within the coverage of the first relay node <NUM> according to the second base station identifier and the tracking area identifier corresponding to the second base station identifier. Under a condition that the second base station <NUM> is located within the coverage of the first relay node <NUM>, the first relay node <NUM> transmits the updated CSI-RS configuration information to the second base station <NUM> by using the downlink RAN configuration transmission information.

The second base station <NUM> updates a current CSI-RS configuration information of a cell whose CSI-RS configuration is updated in a neighbor cell list by using the updated CSI-RS configuration information and the first base station identifier.

In some embodiments, the neighbor cell list includes at least one of a first base station identifier, a cell identifier of a cell whose CSI-RS configuration is updated, a mode of the first base station, an indicating information of whether a direct connection interface exists with the first base station, an indicating information of whether to enable CSI-RS measurement, and a CSI-RS configuration information.

In some embodiments, the second base station <NUM> determines whether the CSI-RS measurement is in an on state by using the updated CSI-RS configuration information. Under a condition that the CSI-RS measurement is in the on state, the second base station <NUM> indicates, through the RRC reconfiguration information, the terminal within the coverage of the second base station <NUM> to measure the cell associated with the first base station by using the CSI-RS. Under a condition that the CSI-RS measurement is in the off state, the second base station <NUM> indicates, through the RRC reconfiguration information, the terminal within the coverage of the second base station <NUM> to measure the cell associated with the first base station by using the SSB.

<FIG> is a schematic structural diagram of a neighboring cell configuration information transmission system according to another embodiment of the present disclosure.

<FIG> differs from <FIG> in that, in the embodiment shown in <FIG>, the first relay node <NUM> is further configured to send the updated CSI-RS configuration information to the second relay node <NUM> under a condition that the second base station <NUM> is not located in the coverage of the first relay node <NUM>. The second relay node <NUM> is a second AMF connected to the second base station <NUM>. The second relay node <NUM> transmits the updated CSI-RS configuration information to the second base station using the downlink RAN configuration transmission information.

In some embodiments, as shown in <FIG>, when the first base station <NUM> is in the NSA mode, a third base station having a direct communication interface connection with the first base station <NUM> is used as the first relay node <NUM>, where the third base station supports an LTE air interface.

The first base station <NUM> transmits the updated CSI-RS configuration information to the first relay node <NUM> through the EN-DC configuration update information. The first relay node <NUM> updates the corresponding neighbor cell list by using the updated CSI-RS configuration information, and sends an EN-DC configuration update acknowledge message to the first base station <NUM>. The first relay node <NUM> determines whether the second base station <NUM> is within the coverage of the first relay node <NUM>. Under a condition that the second base station <NUM> is located in the coverage of the first relay node <NUM>, the first relay node <NUM> determines whether the second base station <NUM> supports the preset signaling radio bearer measurement, and under a condition that the second base station <NUM> supports the preset signaling radio bearer measurement, the first relay node <NUM> transmits the updated CSI-RS configuration information to the second base station <NUM> through the EN-DC configuration update information.

After receiving the EN-DC configuration update information, the second base station <NUM> updates the corresponding neighbor cell list by using the updated CSI-RS configuration information, and transmits an EN-DC configuration update acknowledge message to the first relay node <NUM>. The second base station <NUM> indicates the NSA terminal within the coverage of the second base station <NUM> to perform CSI-RS measurement for a cell supporting CSI-RS measurement among cells associated with the first base station under a condition that the first base station starts CSI-RS measurement.

In some embodiments, the first relay node <NUM> discards the updated CSI-RS configuration information under a condition that the second base station <NUM> does not support the preset signaling radio bearer measurement.

In some embodiments, the first relay node <NUM> transmits the updated CSI-RS configuration information to the second relay node <NUM> through the eNB configuration update information under a condition that the second base station <NUM> is not located in the coverage of the first relay node <NUM>, as shown in <FIG>. The second relay node <NUM> supports LTE air interfaces, and the second base station <NUM> is located within the coverage of the second relay node <NUM>.

The second relay node <NUM> updates the corresponding neighbor cell list by using the updated CSI-RS configuration information, and transmits an eNB configuration update acknowledge information to the first relay node. The second relay node <NUM> determines whether the second base station <NUM> supports the preset signaling radio bearer measurement, and if the second base station <NUM> supports the preset signaling radio bearer measurement, the second relay node <NUM> transmits the updated CSI-RS configuration information to the second base station <NUM> through the EN-DC configuration update information.

The second base station <NUM> updates the corresponding neighbor cell list by using the updated CSI-RS configuration information, and transmits an EN-DC configuration update acknowledge message to the second relay node <NUM>. The second base station <NUM> indicates the NSA terminal in the coverage of the second base station <NUM> to perform CSI-RS measurement for a cell supporting CSI-RS measurement among cells associated with the first base station under a condition that the first base station <NUM> starts CSI-RS measurement.

In some embodiments, the second relay node <NUM> discards the updated CSI-RS configuration information under a condition that the second base station <NUM> does not support the preset signaling radio bearer measurement.

The present disclosure also provides a computer-readable storage medium. The computer readable storage medium stores computer instructions which, when executed by the processor, implement the method according to any one of <FIG>.

The present disclosure is illustrated by the following specific examples.

In an EN-DC scenario, there are two NR base stations within the coverage of LTE base station <NUM>, which are NR base station <NUM> and NR base station <NUM>, respectively. The NR base station <NUM> and NR base station <NUM> are configured with CSI-RS configuration information for mobility measurement. The NSA terminal <NUM> is located within the coverage of the NR base station <NUM>. This embodiment describes a process in which the NR base station <NUM> configures CSI-RS measurement for the NSA terminal <NUM> after the CSI-RS configuration of the NR base station <NUM> is updated.

Step <NUM>: the NR base station <NUM> updates CSI-RS configuration information. Since the NR base station <NUM> and the peripheral NR base stations do not have a direct connection interface and the NR base station <NUM> is in a NSA mode, the NR base station <NUM> transmits the updated CSI-RS configuration information to the LTE base station <NUM> by using an EN-DC configuration update information.

Step <NUM>: after receiving the EN-DC configuration update information, the LTE base station <NUM> stores the CSI-RS configuration information of the relevant cells in the NR base station <NUM>.

Step <NUM>: the LTE base station <NUM> transmits an EN-DC configuration update acknowledge message to the NR base station <NUM>.

Step <NUM>: since the NR base station <NUM> supports SRB3, the LTE base station <NUM> transmits the updated CSI-RS configuration information of the NR base station <NUM> to the NR base station <NUM> through the EN-DC configuration update information.

Step <NUM>: the NR base station <NUM> saves the updated CSI-RS configuration information of the base station <NUM>, and transmits the updated CSI-RS configuration information of the NR base station <NUM> to the NR base station <NUM> by using the EN-DC configuration update confirm message.

Step <NUM>: the NR base station <NUM> performs CSI-RS measurement configuration for the NSA terminal <NUM>, wherein the measurement configuration includes identifiers of cells related to the NR base station <NUM> and the NR base station <NUM> and configuration information of the CSI-RS.

Step <NUM>: the NSA terminal <NUM> transmits the measurement result on the NR base station <NUM> to the NR base station <NUM> by using the SRB3 according to the measurement result.

in an EN-DC scenario, there is an NR base station <NUM> in the coverage of the LTE base station <NUM>, and an NR base station <NUM> in the coverage of the LTE base station <NUM>. The NR base station <NUM> and the NR base station <NUM> are configured with CSI-RS configuration information for mobility measurements. The NSA terminal <NUM> is located within the coverage of the NR base station <NUM>. This embodiment describes a process in which the NR base station <NUM> configures CSI-RS measurement for the NSA terminal <NUM> after the CSI-RS configuration of the NR base station <NUM> is updated.

Step <NUM>: the NR base station <NUM> updates a CSI-RS configuration information. The NR base station <NUM> and peripheral NR base stations do not have direct connection interfaces, and the NR base station <NUM> is in an NSA mode, and the NR base station <NUM> transmits an updated CSI-RS configuration information to the LTE base station <NUM> by using an EN-DC configuration updating message.

Step <NUM>: after receiving the EN-DC configuration updating message, the LTE base station <NUM> stores the CSI-RS configuration information of the relevant cells in the NR base station <NUM>.

Step <NUM>: the LTE base station <NUM> transmits the updated CSI-RS configuration information to the LTE base station <NUM> through an eNB configuration updating message.

Step <NUM>: the LTE base station <NUM> saves the CSI-RS configuration of the NR base station <NUM> and transmits an eNB configuration update acknowledge message to the LTE base station <NUM>.

Step <NUM>: since the NR base station <NUM> supports SRB3, the LTE base station <NUM> transmits the updated CSI-RS configuration information of the NR base station <NUM> to the NR base station <NUM> by means of the EN-DC configuration updating message.

Step <NUM>: the NR base station <NUM> saves CSI-RS configuration information of the NR base station <NUM>, and transmits an EN-DC configuration update acknowledge message to the LTE base station <NUM>.

Step <NUM>: the NR base station <NUM> performs CSI-RS measurement configuration for the NSA terminal <NUM>, wherein the measurement configuration includes identifiers of cells related to the NR base station <NUM> and the NR base station <NUM> and CSI-RS configuration information.

Step <NUM>: according to the measurement results, the NSA terminal <NUM> transmits the measurement result regarding the NR base station <NUM> to the NR base station <NUM> by using the SRB3.

In the SA scenario, there is no Xn interface between NR base station <NUM> and NR base station <NUM>, and NR base station <NUM> and NR base station <NUM> are connected by AMF, respectively. The CSI-RS measurement configuration of the NR base station <NUM> has been turned off for energy-saving reasons, and the NR base station <NUM> triggers CSI-RS configuration updating, and informs the NR base station <NUM> of changing strategies through AMF. The NR base station <NUM>, after receiving the notification, adopts the SSB-based measurement scheme for all users.

Step <NUM>: the NR base station <NUM> turns off the CSI-RS transmission and updates CSI-RS configuration information because there is no terminal connected in the coverage area. The NR base station <NUM> selects an AMF as a relay node because there is no direct connection interface between the NR base station <NUM> and the peripheral NR base stations and the NR base station <NUM> is in an SA mode.

Step <NUM>: the NR base station <NUM> transmits an uplink RAN configuration transfer information to the AMF connected to the NR base station <NUM> using an NG interface, wherein the following information is included:.

Step <NUM>: after receiving the uplink RAN configuration transmission information, the AMF determines that the base station <NUM> is located within the coverage of the AMF according to the TAI of the NR base station <NUM>. The AMF transmits an downlink RAN configuration transfer information to the NR base station <NUM>, so as to send CSI-RS configuration information to the NR base station <NUM>.

Step <NUM>: the NR base station <NUM> saves the CSI-RS configuration information. Since the CSI-RS configuration information only includes a cell identifier, the NR base station <NUM> deletes the CSI-RS configuration information of the cell related to the NR base station <NUM>.

Step <NUM>: the NR base station <NUM> triggers the terminals <NUM> within its coverage to make relevant measurements on the NR base station <NUM> by using the SSB.

In some embodiments, the functional unit modules described above can be implemented as a general purpose Processor, a Programmable Logic Controller (PLC), a Digital Signal Processor (Digital Signal Processor, DSP), an Application Specific Integrated Circuit (ASIC), a Field Programmable Gate Array (FPGA) or other Programmable Logic device, discrete Gate or transistor Logic, discrete hardware components, or any suitable combination thereof for performing the functions described in this disclosure.

It will be understood by those skilled in the art that all or part of the steps for implementing the above embodiments may be implemented by hardware, or may be implemented by a program instructing relevant hardware, where the program may be stored in a computer-readable storage medium, and the storage medium may be a read-only memory, a magnetic disk or an optical disk.

Although some specific embodiments of the present disclosure have been described in detail by way of example, it should be understood by those skilled in the art that the above examples are for illustration only and are not intended to limit the scope of the present disclosure.

Claim 1:
A method for transmitting a neighbor cell configuration information, the method comprising:
determining (<NUM>) by a first base station, a second base station corresponding to a neighbor cell of a cell associated with the first base station according to a neighboring cell relationship under a condition that channel state information reference signal, CSI-RS, configuration information for mobility measurement in at least one cell associated with the first base station is updated, wherein the CSI-RS configuration information of the cell associated with the first base station is updated, the first base station and the second base station both support a New Radio, NR, air interface, the method being characterized in that no interface for direct communication exists between the first base station and the second base station, and by further comprising:
transmitting (<NUM>), by the first base station, the updated CSI-RS configuration information to a selected first relay node, wherein the first relay node is associated with modes of the first base station and the second base station, wherein the first relay node is a third base station having a direct communication interface with the first base station under a condition that the first base station is in a non-standalone, NSA, mode, and the third base station supports a long term evolution, LTE, air interface;
transmitting (<NUM>), by the first relay node, the updated CSI-RS configuration information to the second base station;
indicating (<NUM>), by the second base station, a terminal in a coverage of the second base station to measure cells associated with the first base station according to the updated CSI-RS configuration information.