KR20150020031A - Method and apparatus for radio link failure handling in multi-base station connectivity based wireless communication system - Google Patents

Abstract

The present invention relates to a method and device for communications between a terminal and a base station in a wireless communications system. A multi-station connection communications method for a base station according to an embodiment of the present invention may comprise the steps of: receiving, from a terminal, a radio link failure (RLF) expectation message associated with a first link; searching for a target cell for handover of the terminal according to the radio link failure expectation message; selecting the target cell if the target cell exists as a result of the searching; receiving, from the terminal, a radio link failure message associated with the first link through a second link; and transmitting, to the terminal, a command for handover to the selected target cell. According to an embodiment of the present invention, in a system in which a terminal is connected to at least one base station, a mechanism for efficiently handling radio link failure and reducing an effect on application level connection can be provided.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a method and a device for processing a radio link failure in a wireless communication system based on multiple base station connection,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and apparatus for communication between a terminal and a base station in a wireless communication system, and more particularly,

The 3rd Generation Partnership Project (3GPP) Long Term Evolution (LTE) system is based on a single connectivity model in which UEs are connected to a base station eNB one by one. In this system, a radio link failure (RLF) process is based on detection of a radio link failure by the UE, and since the link with the base station itself is in a radio link failure state, Based on additional actions.

1 is a diagram illustrating a radio link failure process in a mobile communication system, and FIG. 2 is an example of a flowchart of a radio link failure process in a mobile communication system.

Referring to FIG. 1, in order to detect a radio link failure, a UE can perform a procedure known as Radio Link Monitoring (RLM). The terminal can measure the BLER of the PDCC for a predetermined period of time. An out-of-sync indicator may be generated at the PHY layer if the BLER falls below a predetermined threshold Qout for the predetermined time period. When a predetermined number N310 of out-of-sync indicators are reported by the physical layer to the RRC layer, a radio link failure timer T310 is initiated by the RRC layer. At this time, a radio link failure (RLF) may be declared when the radio link failure timer expires. And, if the N311 number of consecutive in-sync indicators are reported by the physical layer after the timer T310 is started, the timer T310 may be stopped.

Referring to FIG. 2, in step 251, the UE 210 may generate a radio link failure on the first link. Then, after expiration of the T310 timer, the UE 210 can make a radio link failure declaration. Upon declaration of a radio link failure, the terminal 210 may stop all uplink transmissions and deactivate all radio bearers to avoid the possibility of generating uplink interference. In step 252, the terminal 210 scans the target cell 240 and transmits a connection re-establishment request message to the target cell 240 in step 253. In step 253, Lt; / RTI > If the target cell 240 already has a UE context 254, the target cell 240 transmits a re-establishment success message to the UE 210 in step 255, Re-establishment can be successful. After the re-establishment is successful, the connection between the UE 210 and the target cell 240 may be resumed in step 256.

However, if the target cell 240 does not have a terminal context (step 257), the target cell 240 transmits a re-establishment failure message to the terminal 210 in step 258 to perform a re-establishment ) Can fail. After the re-establishment failure, the UE 210 moves to idle mode in step 259, and in step 260 and step 261, the UE 210 finally notifies the target cell 240 of a new connection (trigger). This may result in termination of the application level connection, which is highly undesirable. Moreover, it should be noted that the target cell 240 has a UE context only if a handover is in progress before a radio link failure occurs. So the re-establishment procedure can only be successful in these scenarios.

In the event that random access fails for a set maximum number of attempts, the presence of a system radio link failure (RLF) may also be triggered. In addition, the radio link failure can be triggered even when the maximum number of set RLC retransmissions is completed.

In the prior art, after declaring a radio link failure in a single connection system (3GPP LTE Release 11 and earlier), the mobile station scans the appropriate target cell and notifies the radio link failure (by notifying the ID of the previous base station) And transmits a failure indication to the selected target cell. The target cell forwards this information to the previous base station. The previous base station that received this information may improve parameters such as handover parameters and other radio link parameters that may cause radio link failure.

Meanwhile, among the terms used in the following description, the base station and the cell can be used interchangeably.

A communication method of a terminal and a communication method of a base station according to an embodiment of the present invention can be applied to a mechanism in which a terminal is connected to one or more base stations in a system capable of efficiently processing a radio link failure and reducing an influence on application- And to provide the above objects.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not restrictive of the invention, unless further departing from the spirit and scope of the invention as defined by the appended claims. It will be possible.

According to an aspect of the present invention, there is provided a method for establishing a multiple base station connection in a base station, the method comprising: receiving a radio link failure (RLF) prediction message associated with a first link; Searching for a target cell for handover according to the radio link failure prediction message; Selecting the target cell if the search target cell exists; Receiving a radio link failure message associated with the first link from the terminal over a second link; And transmitting a handover command to the selected target cell to the terminal.

Selecting a base station for a single connection to the second link if the search result target cell does not exist; And transmitting a single connection change message to the terminal with the base station selected for the single connection.

According to another aspect of the present invention, there is provided a method of a multi-base station connection communication method of a terminal, the method comprising: transmitting a radio link failure (RLF) prediction message associated with a first link to a base station; Transmitting a radio link failure message associated with the first link to the base station via a second link; And receiving a handover command to the target cell selected by the base station according to the radio link failure prediction message.

Receiving a single connection change message from the base station to the second link; And switching to a single connection mode with one base station according to the received single connection switching message.

According to another aspect of the present invention, there is provided a method of a multi-base station connection communication method in a base station, the method comprising: receiving a Radio Link Failure (RLF) message associated with a first link ; Searching for a target cell for handover according to the radio link failure message; Selecting the target cell if the search target cell exists; And transmitting a handover command to the selected target cell to the terminal.

Selecting a base station for a single connection to the second link if the search result target cell does not exist; And transmitting a single connection change message to the terminal with the base station selected for the single connection.

According to another aspect of the present invention, there is provided a method of a multi-base station connection communication method in a terminal, the method comprising: transmitting a radio link failure (RLF) message associated with a first link to a base station via a second link ; And receiving a handover command to the target cell selected by the base station according to the radio link failure message.

Receiving a single connection change message from the base station to the second link; And switching to a single connection mode with one base station according to the received single connection switching message.

According to another aspect of the present invention, there is provided a method of a multi-base station connection communication method in a base station, the method comprising: receiving a Radio Link Failure (RLF) message associated with a first link ; Selecting a base station for a single connection to the second link according to the radio link failure message; And transmitting a single connection change message to the terminal with the base station selected for the single connection.

According to another aspect of the present invention, there is provided a method of a multi-base station connection communication method in a terminal, the method comprising: transmitting a radio link failure (RLF) message associated with a first link to a base station via a second link ; Receiving a single connection transition message from the base station to the second link; And switching to a single connection mode with one base station according to the received single connection switching message.

According to another aspect of the present invention, there is provided a base station for performing multi-base station connection communication, comprising: a communication unit for communicating with other base stations and terminals; The method includes receiving a radio link failure (RLF) prediction message associated with a first link from a mobile station, searching for a target cell for handover according to the radio link failure prediction message, A control unit for selecting the target cell, receiving a radio link failure message associated with the first link from the terminal through a second link, and controlling the terminal to transmit a handover command to the selected target cell; . ≪ / RTI >

According to another aspect of the present invention, there is provided a terminal for performing multi-base station connection communication comprising: a communication unit for communicating with a base station; Transmitting a radio link failure (RLF) expectation message associated with a first link to a base station, transmitting a radio link failure message associated with the first link to the base station via a second link, And a controller for controlling the base station to receive a handover command to a target cell selected by the base station.

According to another aspect of the present invention, there is provided a base station for performing multi-base station connection communication, comprising: a communication unit for communicating with other base stations and terminals; The method includes receiving a radio link failure (RLF) message associated with a first link from a terminal through a second link, searching for a target cell for handover according to the radio link failure message, And a controller for selecting the target cell and transmitting a handover command to the selected target cell when the cell exists.

According to another aspect of the present invention, there is provided a terminal for performing multi-base station connection communication comprising: a communication unit for communicating with a base station; A control unit for transmitting a radio link failure (RLF) message associated with a first link to a base station via a second link and controlling the base station to receive a handover command to a target cell selected by the base station according to the radio link failure message ; ≪ / RTI >

According to another aspect of the present invention, there is provided a base station for performing multi-base station connection communication, comprising: a communication unit for communicating with other base stations and terminals; Receiving a radio link failure (RLF) message associated with a first link from a terminal via a second link, selecting a base station for a single connection to the second link according to the radio link failure message, And a controller for controlling the terminal to transmit a single connection change message to the base station selected for the single connection.

According to another aspect of the present invention, there is provided a terminal for performing multi-base station connection communication comprising: a communication unit for communicating with a base station; Transmitting a Radio Link Failure (RLF) message associated with a first link to a base station via a second link, receiving a single connection transition message from the base station to the second link, And a control unit for controlling switching to a single connection mode with one base station according to the message.

A communication method of a terminal and a communication method of a base station in accordance with an embodiment of the present invention can be applied to a mechanism in which a terminal is connected to one or more base stations in a system capable of efficiently processing a radio link failure and reducing the influence on application- Can be provided.

The effects obtained by the present invention are not limited to the above-mentioned effects, and other effects not mentioned can be clearly understood by those skilled in the art from the following description will be.

1 is an exemplary diagram illustrating a radio link failure process in a mobile communication system.
2 is an example of a flowchart of a radio link failure processing in a mobile communication system.
3 is a schematic view illustrating an example of a double connection according to an embodiment of the present invention.
4 is a flowchart illustrating a method of processing a radio link failure in a dual connection according to an exemplary embodiment of the present invention.
FIG. 5 is a flowchart illustrating a method of processing a radio link failure in a dual connection according to another embodiment of the present invention. Referring to FIG.
FIG. 6 is a flowchart illustrating a method of processing a radio link failure in a dual connection according to another embodiment of the present invention. Referring to FIG.
FIG. 7 shows an example of a flowchart of a method of processing a radio link failure when the link of the master base station in the case of a radio link failure related to FIG. 6 is a radio link failure.
FIG. 8 illustrates an example of a flowchart of a method of processing a radio link failure when a link of a supplementary base station is a radio link failure in the case of a radio link failure associated with FIG. 6;
9 is a diagram showing an early indication flow chart of a radio link failure in a single connection system.
10 is a flowchart illustrating a method of switching from a dual connection to a single connection according to an embodiment of the present invention.
11 is a flowchart illustrating a method of switching from a dual connection to a single connection according to another embodiment of the present invention.
12 is a flowchart illustrating a method of switching from a dual connection to a single connection according to another embodiment of the present invention.
13 is a flowchart illustrating a method of switching from a dual connection to a single connection according to another embodiment of the present invention.
14 is a flowchart illustrating a method of switching from a single connection to a dual connection according to an embodiment of the present invention.
15 is a flowchart illustrating a method of switching from a single connection to a dual connection according to another embodiment of the present invention.
16 is a block diagram of a terminal according to an embodiment of the present invention.
17 is a block diagram of a base station according to an embodiment of the present invention.
18 is a flowchart illustrating an operation of transmitting a radio link failure indicator of a terminal and a master base station according to an embodiment of the present invention.
FIG. 19 is a flowchart illustrating a transmission operation of a radio link failure indicator between a terminal and a master base station according to an embodiment of the present invention. Referring to FIG.
20 is a flowchart illustrating a method of transmitting a radio link failure indicator including a radio link failure cause value according to an embodiment of the present invention.
FIG. 21 is a flowchart illustrating a method of transmitting a radio link failure indicator included in a measurement report configuration according to an embodiment of the present invention. Referring to FIG.
22 is a flowchart illustrating a method of transmitting a radio link failure indicator included in a measurement report configuration according to an embodiment of the present invention.
23 to 25 are diagrams showing examples of MAC CEs according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In describing the embodiments, descriptions of techniques which are well known in the art to which the embodiments of the present invention belong, and which are not directly related to the embodiments of the present specification are not described. This is for the sake of clarity of the gist of the embodiment of the present invention without omitting the unnecessary explanation.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description of the embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present disclosure rather unclear. DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. The following terms are defined in consideration of the functions of the present invention, and these may be changed according to the intention of the user, the operator, or the like. Therefore, the definition should be based on the contents throughout this specification.

3 is a schematic view illustrating an example of a double connection according to an embodiment of the present invention.

Referring to FIG. 3, dual connectivity is discussed as a core technology for increasing user efficiency and achieving high mobility robustness in 3GPP (Long Term Evolution) Release 12 (3GPP) have. In this dual connection scenario, a UE can be connected to a macro cell and a pico cell at the same time. However, simultaneous transmission and reception to two cells may or may not be possible depending on the capabilities of the terminal. Macro cells and picocells are harmonized to help the terminal. In such a system, the macrocell serves as a mobility anchor and hides the picocell change from the core network, which can significantly reduce the signaling load to the core network. While picocells handle large amounts of traffic, macrocells can handle more important traffic such as VoIP. One cell (macro cell) serves as a master base station (MeNB) and a remaining cell (picocell) serves as a secondary eNB (SeNB).

At this time, it is desirable to maintain as many terminals as possible in the dual connection mode while the RRC connection is in the RRC_CONNECTED state so that high user efficiency can be maintained.

A Radio Link Failure (RLF) on any one link may result in loss of duplex mode and thereby interfere with an ongoing connection. Therefore, it is important for the wireless link failure handling technology in the dual connection to allow the terminal to maintain the dual link mode even if one of the wireless links is in the RLF state.

Hereinafter, the radio link failure processing in the dual connection system will be described in detail.

In a dual connection, either or both of the master base station (MeNB) link and the secondary base station (SeNB) link may be in a radio link failure state. May be referred to as "radio link failure of a single link" or "partial radio link failure" when one link is in a radio link failure state, as described below. And may be referred to as "radio link failure of dual link" or "complete radio link failure" when both links are in a radio link failure state. Thus, the radio link failure scenario may be as follows.

1. Wireless link failure of a single link

a. If the master base station (MeNB) link is in a radio link failure state

b. A secondary base station (SeNB) link is in a wireless link failure state

2. Wireless link failure of dual link

a. Both the master base station (MeNB) link and the secondary base station (SeNB) link are in a wireless link failure state

In a dual connection, because the terminal has two links (one for the master base station and one for the auxiliary base station), the terminal has one good link even if one link is in the radio link failure state The radio link failure processing can be improved. That is, a good link can be utilized to handle the radio link failure of another link.

3GPP LET Rel. In Carrier Aggregation (CA) of 10/11, PCell can judge the SCell link quality based on the Channel Quality Indicator (CQI) report. It does not perform radio link monitoring (RLM) for SCell because SCell can be deactivated accordingly. The CQIs of all the cells are set to be reported to the PCs only through the PUCCH (Packet Uplink Common CHannel) to which the CQI is transmitted. However, it has not yet been agreed whether the master base station can have a CQI report of the auxiliary base station in the dual connection (scenario 1b). It is also unclear how the master base station can have its own CQI if the connection between the master base station and the terminal is not of good radio quality (scenario 1a).

And Rel. In CA of 10/11, PUCCH is transmitted only in PCell. However, if the same approach is not possible in a dual connection, non-ideal backhaul can affect operation.

In a double connection, Rel. The application of the CA radio link failure processing of 10/11 performs the application of the radio link failure processing only when the master base station (PCell) link is in the radio link failure state and performs all the connections including the connections of the auxiliary base station This can mean re-establishment of the re-establishment. If re-establishment is not successful, all connections may need to be terminated and re-established. This approach can not seem to justify that the link of the auxiliary base station is good, but still considered to be in the radio link failure.

The re-establishment procedure may only be successful if the cell on which the re-establishment is to be performed is already prepared to accommodate the terminal. In a non-handover situation this may not be the case for an ongoing connection.

On the other hand, there is no legacy procedure for handling the radio link failure of the auxiliary base station (SCell).

With the method of the radio link failure processing, the radio link failure processing can be performed independently for the link in the radio link failure state. For example, in scenario 1b, after a radio link failure is declared to a serving base station, the terminal finds an appropriate target cell and attempts to re-establish it. If the target cell already has a UE context, re-establishment will be successful. Otherwise, the active connections for the link of the auxiliary base station (the base station with the link where the radio link failure occurred) will be removed and an initial connection establishment for these connections should be performed (as initial duplex mode establishment). This method is suitable as Scenario 1b, but can also be applied to Scenario 1a.

Alternatively, if re-establishment fails, it may be replaced by a single connection with a base station having a good link with the terminal.

The wireless link failure handling methods described above can negatively impact application level connections, resulting in loss of duplex mode and increased transitions between duplex and single connections.

A method in which a good link (a link that is not in a radio link failure state) in the present invention is utilized to indicate a radio link failure state of another link to a master base station will be described. The master base station may prepare an alternative alternative cell instead of a cell of the link in the radio link failure state to the terminal. The master base station may then trigger the terminal to perform a handover to a prepared cell instead of a legacy re-establishment. This avoids the loss of the dual connection mode and allows it to maintain continuous connections in a seamless manner. Alternatively, if a suitable alternative cell is not found, the master base station may prepare a cell (from cells associated with providing a dual connection to the terminal) with a link that is sufficient to provide the terminal with a single connection mode. A radio link monitoring (RLM) procedure may be performed on the link to detect a radio link failure (RLF) on the link.

The proposed solution can be applied well to both the radio link failure scenario 1a and the scenario 1b. At this time, the terminal context needs to be maintained until a certain time after expiration of the radio link failure timer T310. Also, in order to perform fast preparation of alternative cells, the radio link failure indicator may be sent to the master base station over another good link before the radio link failure is declared on one link.

18 is a flowchart illustrating an operation of transmitting a radio link failure indicator of a terminal and a master base station according to an embodiment of the present invention.

Referring to FIG. 18, the terminal 1810 according to an embodiment of the present invention is double-connected to the master base station 1820 and the auxiliary base station 1830 in step 1851. In step 1852, the terminal 1810 may perform a radio link monitoring (RLM) procedure on the cells of one or more of the auxiliary base stations 1830 (as well as performing the RLM on the cells of the one or more master base stations 1820) have. If the terminal 1810 detects a radio link failure on the cell of the auxiliary base station 1830 in step 1853, the terminal 1810 notifies the PCell of the master base station 1820 of the cause of the radio link failure Lt; RTI ID = 0.0 > a < / RTI > After transmitting the radio link failure indicator, in step 1855, the UE 1810 suspends all uplink transmissions including the configured PUCCH, and in step 1856, the UE 1810 transmits data in progress on the cell where the radio link failure is detected Stop the radio bearer.

FIG. 19 is a flowchart illustrating a transmission operation of a radio link failure indicator between a terminal and a master base station according to an embodiment of the present invention. Referring to FIG.

Referring to FIG. 19, a terminal 1910 according to an embodiment of the present invention is double-connected to a master base station 1920 and an auxiliary base station 1930 in step 1951. FIG. In step 1952, the UE 1910 transmits a RLM (RLM) message to only one cell of the auxiliary base station 1930 set as a pathloss reference, in addition to performing the RLM in the PCELL of the master base station 1920 in step 1952. [ Can be performed. The cell set as the path loss reference may be referred to as a pSCell or a special cell of the auxiliary base station 1930. If the terminal 1910 detects a radio link failure on the pSCell in step 1953, the terminal 1910 transmits a radio link failure indicator including the cause of the radio link failure to the PCell of the master base station 1820 in step 1854 Lt; / RTI > After transmitting the radio link failure indicator, in step 1955, the UE 1910 suspends all uplink transmissions including the configured PUCCH, and in step 1956, the UE 1910 transmits data in progress on the cell where the radio link failure is detected Stop the radio bearer. According to an embodiment, the PUCCH may be set on a cell set to pass through reference.

According to another embodiment of the present invention, the indicator of radio link failure for one link may be transmitted to the master base station at the next time point via another good link.

1. Before declaration of radio link failure (before expiration of T310)

a. A radio link failure indicator (RLF expected indication)

2. Declaration of radio link failure (at the expiry of T310)

a. A radio link failure indication indicator (RLF declaration indication)

Upon receiving an indication of the status of the radio link failure, the master base station may prepare a replacement cell capable of servicing the terminal on behalf of the cell for which a radio link failure is expected (or has already occurred). This can prevent re-establishment.

4 is a flowchart illustrating a method of processing a radio link failure in a dual connection according to an exemplary embodiment of the present invention.

Referring to FIG. 4, a method of processing a radio link failure according to an exemplary embodiment of the present invention can be replaced with a single connection for a base station with a good link when a radio link failure is declared in the dual link.

When a radio link failure for one of the two radio links is declared (e.g., when the T310 timer expires), the result is reported to the master station via the second link (i.e., the link with a good connection) . Then, the master base station can prepare the base station with good link to serve the terminal in the single connection mode, and operate the terminal to perform the switching to the single connection mode.

More specifically, in step 451, a radio link failure (RLF) for the first link may occur. For example, a radio link failure may be declared if the T310 timer expires.

Then, in step 452, the terminal 410 may transmit a radio link failure message to the master base station (MeNB) At this time, the radio link failure message may be transmitted to the master base station 420 through a second link having a good connection state.

In accordance with an embodiment, the terminal 410 may send a message to the master base station 420 including an indicator indicating that a radio link failure has already occurred. At this time, the radio link failure indicator may be defined as a new indicator according to the embodiment.

Alternatively, the UE 410 may transmit a legacy message RRC Connection Re-establishment message to the master BS 420 via the second link according to an embodiment of the present invention. The RRC connection re-establishment message may be the same as that transmitted in the legacy 3GPP LTE at the expiration of T310. For example, a Random Access Chennel (RACH) code may be provided to the terminal 410 for this purpose. At this time, the transmitted RRC connection re-establishment message can be handled like the radio link failure indicator.

At this time, the L2 / L3 context for the first link may be maintained for a predetermined period as shown at 450. [ The L2 / L3 context needs to be maintained for a period of time to perform a single connection replacement preparation. Then, the L1 context for the first link may be released.

In step 453, the master base station 420 may perform communication with the auxiliary base station 430 to prepare the terminal 410 so that the terminal 410 having a good link and the terminal 410 can replace the single connection.

For example, the radio link of the master base station 420 is in a good state, but the radio link of the auxiliary base station 430 may be in a radio link failure state. At this time, the master base station 420 may switch the terminal 410 to a single connection with the master base station 420 instead of the dual connection with the master base station 420 and the auxiliary base station 430. At this time, the context of the flow serviced by the auxiliary base station 430 needs to be transferred to the master base station 420. A detailed description thereof will be given later.

In step 454, the master base station 420 operates to switch to a single connection, and may transmit a single connection change message to the terminal 410 in step 455. At this time, the flow information changed in step 453 may be transferred together.

In step 456, the MS 410 can perform a single connection with a BS having a good link.

4, the radio link failure processing of the auxiliary base station 430 link may be delayed, and in particular, when the auxiliary base station 430 link is in a radio link failure state and the master base station 420 link is in a good state May be suitable for the case of the radio link failure scenario 1b, but this case is not applicable.

FIG. 5 is a flowchart illustrating a method of processing a radio link failure in a dual connection according to another embodiment of the present invention. Referring to FIG.

5, the method for processing a radio link failure according to an exemplary embodiment of the present invention includes a step 510 for allowing a master base station 520 to prepare an alternative cell for serving a terminal 510 in a dual connection, The radio link failure message may be transmitted to the master base station 520 via the good link after expiration of the radio link failure timer T310.

Upon receiving this radio link failure message, the master base station 520 can confirm whether or not an appropriate target cell 540 that can be prepared for handover already exists. If an appropriate target cell 540 is not present, appropriate measurements may be made to determine and prepare the appropriate target cell 540 for handover. The master base station 520 may then instruct the terminal 510 to perform handover to the appropriate target cell 540.

On the other hand, if an appropriate target cell capable of performing a handover is not found, the master base station 520 can prepare a base station corresponding to a good link serving the terminal 510 in a single connection mode. The master base station 520 may then instruct the terminal 510 to replace the selected base station with a single connection mode operation.

More specifically, in step 551, a radio link failure for the first link may occur. For example, a radio link failure may be declared when the T310 timer expires.

In step 552, the UE 510 may transmit a radio link failure message to the master base station 520. At this time, the radio link failure message can be transmitted to the master base station 520 through the second link having a good connection state. At this time, it is necessary to retain the L2 / L3 context for the first link for a predetermined time period to perform handover preparation or to perform a single connection replacement preparation. To this end, a new A timer is required. While the L1 context for the first link is released.

According to an embodiment, the terminal 510 may send a message to the master base station 520 including an indicator indicating that a radio link failure has already occurred. At this time, the radio link failure indicator may be defined as a new indicator according to the embodiment.

Alternatively, the UE 510 may transmit a legacy message RRC Connection Re-establishment message to the master BS 520 via the second link according to an embodiment of the present invention. The RRC connection re-establishment message may be the same as that transmitted in the legacy 3GPP LTE at the expiration of T310. For example, a RACH code may be given to the terminal 510 for this purpose. At this time, the transmitted RRC connection re-establishment message can be handled like the radio link failure indicator. Accordingly, the RRC connection re-establishment message corresponding to the radio link failure indicator may alternatively perform link identification of the link where the radio link failure occurred.

If the master base station 520 does not have a valid measurement report available from the terminal 510, the measuring terminal can transmit a measurement command to the terminal 510 in step 553. [ However, this measurement may not be required if, for example, the master base station 520 already has a valid measurement report from the terminal 510 as indicated in step 554-1. In step 554, the terminal 510 may perform measurement according to a measurement command of the master base station 520 and transmit the measurement report to the master base station 520.

In this case, the master base station 520 can set a one shot measurement when the master base station 520 receives the radio link failure branch according to the embodiment. Or, according to an embodiment, when the master BS 520 receives a radio link failure indicator, the master BS 520 sets a one-time measurement if the first link is a macro link, Can be set.

The master base station 520 may receive a measurement report from the terminal 510 through steps 553 and 554 or may prepare a cell for handover in step 555 if it has already a valid measurement report. At this time, the master base station 520 may prepare a target base station 540 suitable for handover by the terminal 510 based on the measurement report. The target BS 540 may be a pico-base station, but is not limited thereto, and may be a macro base station.

If no suitable target cell for handover is found as shown in 556-1, the master base station 520 determines that the base station 520 having a good link and the terminal 510 have a single connection The base station 530 may perform communication with the auxiliary base station 530 in order to prepare the terminal 510 to be replaced with the auxiliary base station 530. [

At this time, according to the embodiment, the master base station 520 can select one target cell 540 suitable for handover from the measurement report to the terminal 510 among the plurality of cells. However, if an appropriate cell is not found, the master base station 520 may prepare a second base station for a single connection mode. For example, the radio link of the master base station 520 is in a good state, but the radio link of the auxiliary base station 530 may be in a radio link failure state. At this time, the master base station 520 may switch the terminal 510 to a single connection with the master base station 520 instead of the dual connection with the master base station 520 and the auxiliary base station 530. At this time, the context of the flow served by the auxiliary base station 530 needs to be transferred to the master base station 520. A detailed description thereof will be given later.

Or in accordance with an embodiment, the master base station 520 may select one suitable target cell 540 for handover of the terminal 510 among the plurality of cells from the measurement report. However, if an appropriate cell is not found, the master base station 520 may prepare a replacement cell for handover. The alternate cell may be semi-statically determined by the master base station 520 and / or the auxiliary base station 530. Or alternatively, the alternate cell may be dynamically indicated by the first base station to the master base station 520 according to an embodiment. Thereafter, if no cell is set as a replacement cell, the master base station 520 can prepare a second base station for a single connection mode. At this time, the context of the flow served by the first base station needs to be transferred to the second base station as described above. A detailed description thereof will be described later.

In step 555, if the master base station 520 prepares an appropriate target cell 540 for handover (step 557), the master base station 520 operates to perform a handover to the prepared target cell 540 in step 558 . For example, the master base station 520 may send a handover command to the terminal 510. At this time, the handover command can be transmitted through the second link having a good connection state. According to an embodiment, the prepared target cell 540 may be at least one of a cell from the measurement report transmitted by the terminal 510, a replacement cell, and second base stations with good links.

Meanwhile, if the master base station 520 fails to select the appropriate target cell 540 for handover 559, the master base station 520 operates to switch to a single connection with the second base station in step 560, Lt; RTI ID = 0.0 > 510 < / RTI > At this time, the flow information changed in step 556 may be transferred together.

5, the radio link failure processing of the link of the auxiliary base station 530 may be delayed, and in particular, when the link of the auxiliary base station 530 is in a radio link failure state and the master base station 520 link is in a good state May be suitable for the case of the radio link failure scenario 1b, but this case is not applicable.

FIG. 6 is a flowchart illustrating a method of processing a radio link failure in a dual connection according to another embodiment of the present invention. Referring to FIG.

6, a method for processing a radio link failure according to an exemplary embodiment of the present invention includes a step in which a terminal 610 is connected to a master base station 620 so that the master base station 620 can prepare a replacement cell for serving the terminal 610 in a dual connection, This link connection may send a RLF expected message to the master base station 620 before expiration of the radio link failure timer T310 over a good link.

The radio link failure prediction message may be transmitted at the start of the radio link failure timer (T310) or after a predetermined time after the start of the T310 in order to secure some time for early radio link failure recovery.

The master base station 620 receiving the radio link failure prediction message can confirm whether or not a suitable target cell 640 that can be prepared for handover already exists. If an appropriate target cell 640 is not present, appropriate measurements may be made to determine and prepare the appropriate target cell 640 for handover. Thereafter, if a radio link failure actually occurs (e.g., the T310 timer has expired), the terminal 610 may send a message, such as a radio link failure message, to the master base station 620 ) To explicitly indicate that a radio link failure has occurred. And the master base station 620 may instruct the terminal 610 to perform handover to the prepared target cell 640 based on the detection of the radio link failure.

On the other hand, if no suitable target cell 640 capable of performing a handover is found, the master base station 620 can prepare a base station corresponding to a good link serving the terminal 610 in a single connection mode. The master base station 620 may then instruct the terminal 610 to replace it with a single connection mode operation with the selected base station based on detection of a radio link failure.

More specifically, in step 651, a radio link failure for the first link may be expected. For example, a radio link failure may be expected when the radio link failure timer T310 is started.

In step 652, the UE 610 may transmit a radio link failure prediction message to the master base station 620. At this time, the radio link failure prediction message can be transmitted to the master base station 620 through the second link having a good connection state.

According to an embodiment, the terminal 610 may send a message to the master base station 620, including a radio link failure indicator indicating that a radio link failure is expected. At this time, the radio link failure prediction indicator may be defined as a new indicator according to the embodiment.

According to an embodiment, the terminal 610 may send a radio link failure prediction message for the first link to the master base station 620 when the T310 timer is started.

Alternatively, if a T310 timer is started according to an embodiment, a new timer, the RLF preparation timer, may be started. When the radio link failure preparation timer expires, the terminal 610 may transmit a radio link failure prediction message for the first link to the master base station 620. The time of the radio link failure preparation timer may be shorter than the time of the radio link failure timer (T310). Or out-of-sync indicators are continuously reported for a preset time period when the radio link failure timer is started, the terminal 610 informs the master base station 620 of the radio link A failure prediction message may also be transmitted.

Also, according to an exemplary embodiment, a threshold value of a new reference signal reception strength (RSRP) may be defined as a radio link failure report threshold value. At this time, after the T310 timer is started, if the radio link failure report threshold value is satisfied, the terminal 610 can transmit a radio link failure prediction message for the first link to the master base station 620. [

Alternatively, hysteresis may be defined based on the radio link failure preparation timer and the radio link failure reporting threshold according to an embodiment. At this time, when the average of the reference signal reception strength for the radio link failure preparation timer is maintained below the radio link failure reporting threshold value, the terminal 610 notifies the master base station 620 of the radio link failure prediction Message can be transmitted.

Also, according to an embodiment, CQI reports of the first link may be transmitted on the second link, and these CQI reports act as indicators of the radio link failure situation. The master base station 620 and the auxiliary base station 630 may be aware of the radio link failure situation based on these reports.

If the master base station 620 does not have a valid measurement report available from the terminal 610 after the master base station 620 receives the radio link failure prediction message for the relevant layer, 610). ≪ / RTI > However, this measurement may not be required if, for example, the master base station 620 already has a valid measurement report from the terminal 610, as indicated at step 654-1. In step 654, the terminal 610 may perform measurement according to a measurement command of the master base station 620 and transmit the measurement report to the master base station 620.

The master base station 620 may set a one shot measurement when the master base station 620 receives a radio link failure predicted party according to the embodiment. The master base station 620 sets a one-time measurement if the first link is a macro link, and if the first link is not a normal measurement if the first link is a macro link, Can be set.

The master base station 620 may receive a measurement report from the terminal 610 through steps 653 and 654 or may prepare a cell for handover in step 655 if it already has a valid measurement report. At this time, the master base station 620 can prepare a target base station 640 suitable for handover of the terminal 610 based on the measurement report. The target base station 640 may be a macro base station, but it is not limited thereto, and may be a pico base station.

Meanwhile, if no suitable target cell for handover is found as shown in 656-1, the master base station 620 determines that the base station and the terminal 610, which are good in link, The base station 630 may perform communication with the auxiliary base station 630 in order to prepare the terminal 610 to be replaced with the auxiliary base station 630. [

At this time, according to the embodiment, the master base station 620 can select a suitable target cell 640 for handover from the measurement report to the terminal 610 among the plurality of cells. However, if an appropriate cell is not found, the master base station 620 may prepare a second base station for a single connection mode. For example, the radio link of the auxiliary base station 630 is in a good state, but the radio link of the master base station 620 may be in the radio link failure state. At this time, the master base station 620 may switch the terminal 610 to a single connection with the auxiliary base station 630 instead of the dual connection with the master base station 620 and the auxiliary base station 630. At this time, the context of the flow served by the master base station 620 needs to be transferred to the auxiliary base station 630. A detailed description thereof will be given later.

Or in accordance with an embodiment, the master base station 620 may select a suitable target cell 640 for handover from the measurement report to the terminal 610 among the plurality of cells. However, if an appropriate cell is not found, the master base station 620 may prepare a replacement cell for handover. The alternate cell may be semi-statically determined by the master base station 620 and / or the auxiliary base station 630. Or alternatively, the alternate cell may be dynamically indicated by the first base station to the master base station 620 according to an embodiment. Thereafter, if no cell is set as a replacement cell, the master base station 620 can prepare a second base station for a single connection mode. At this time, the context of the flow served by the first base station needs to be transferred to the second base station as described above. A detailed description thereof will be described later.

Then, in step 657, a radio link failure may be declared. That is, the T310 timer has expired and a radio link failure can be declared.

In step 658, the terminal 610 may transmit a radio link failure message to the master base station 620. At this time, the radio link failure message can be transmitted to the master base station 620 through the second link having a good connection state.

In accordance with an embodiment, the terminal 610 may send a message to the master base station 620 that includes an indicator indicating that a radio link failure has already occurred. At this time, the radio link failure indicator may be defined as a new indicator according to the embodiment.

Alternatively, the UE 610 may transmit a legacy message RRC Connection Re-establishment message to the master base station 620 via the second link according to the embodiment. The RRC connection re-establishment message may be the same as that transmitted in the legacy 3GPP LTE at the expiration of T310. For example, a RACH code may be provided to the terminal 610 for this purpose. At this time, the transmitted RRC connection re-establishment message can be handled like the radio link failure indicator. Alternatively, the master base station 610 may determine that a radio link failure has occurred on the first link, which is a link other than the second link on which the RRC connection re-establishment message was received. Accordingly, the RRC connection re-establishment message corresponding to the radio link failure indicator may alternatively perform link identification of the link where the radio link failure occurred.

At this time, the L2 / L3 context needs to be maintained for a predetermined period of time in order to perform handover preparation or perform a single connection replacement preparation.

In step 655, if the master base station 620 prepares a suitable target cell 640 for handover 659, the master base station 620 operates to perform a handover to the prepared target cell 640 in step 660 . For example, the master base station 620 may send a handover command to the terminal 610. At this time, the handover command can be transmitted through the second link having a good connection state. According to an embodiment, the prepared target cell 640 may be at least one of a cell from a measurement report transmitted by the terminal 610, an alternative cell, and second base stations with good links.

Meanwhile, if the master base station 620 fails to select an appropriate target cell 640 for handover 661, the master base station 620 operates to switch to a single connection with the second base station in step 662, Lt; RTI ID = 0.0 > 610 < / RTI > At this time, the flow information changed in step 656 may be transferred together.

6, since the radio state of the link of the master base station 620 is prioritized, the link state of the link of the master base station 620 and that of the auxiliary base station 630, It may be appropriate for the case of the radio link failure scenario 1a, but this case is not applicable.

FIG. 7 shows an example of a flowchart of a method of processing a radio link failure when the link of the master base station in the case of a radio link failure related to FIG. 6 is a radio link failure.

Referring to FIG. 7, in step 701, the terminal can determine whether the T310 timer of the master base station link is started. When the T310 timer of the master base station is started, the T310 timer of the auxiliary base station link can be determined in step 703 whether or not the T310 timer is not operating. As a result of the determination, if the auxiliary base station link is good, the radio link failure preparation timer may be started in step 705. Thereafter, in step 707, it is determined whether or not the radio link failure preparation timer expires. If the radio link failure preparation timer is before expiration, the expiration can be waited in step 709.

Then, if the radio link failure preparation timer expires, it may be determined in step 711 whether the Ncell measurement is valid. If it is determined in step 713 that the Ncell measurement is valid, a message including information on the start of T310 of the master base station link may be transmitted to the auxiliary base station along with the Ncell measurement report. At this time, the auxiliary base station can indicate the replacement cell in step 714. Thereafter, in step 721, it is possible to wait for a preset time. At this time, the standby of the terminal may be preferable through the radio link failure preparation timer.

On the other hand, if the Ncell measurement is not valid, a message including information on the start of T310 of the master base station link may be transmitted to the auxiliary base station in step 715. In this case, the auxiliary base station may instruct the UE to perform the Ncell measurement in step 717. [ In step 719, the UE can report the Ncell measurement result performed by the serving BS.

In step 721 or step 719, the BS determines whether there is a suitable macro cell for handover based on the report of the measurement result of the MS in step 723. If an appropriate macro cell does not exist, the master base station may select one or more macro cells that are preset to the replacement cell or set as the current replacement cell by the auxiliary base station in step 725.

If an appropriate macro cell is selected in step 723 or a master cell selects a replacement cell as a macro cell in step 725, the master base station transmits the context to the selected macro cell in step 727 and can prepare for handover. Thereafter, in step 729, the T310 expires, and if the T310 expires, the master base station can instruct the MS to perform handover to the prepared macro cell in step 731. [ At this time, the handover execution instruction may be made through the auxiliary base station.

However, if the master base station fails to select an appropriate replacement cell as a macro cell in step 725, the master base station can perform context transfer and handover for the auxiliary base station in step 733. [ Then, in step 735, it waits for the expiration of T310. When the T310 expires, it can instruct the terminal to replace the single connection with the auxiliary base station in step 737. [ At this time, the replacement instruction of the single connection path may be made through the auxiliary base station.

FIG. 8 illustrates an example of a flowchart of a method of processing a radio link failure when a link of a supplementary base station is a radio link failure in the case of a radio link failure associated with FIG. 6;

Referring to FIG. 8, in step 801, the UE can determine whether the T310 timer of the auxiliary base station link is started. If the T310 timer of the auxiliary base station is started, the T310 timer of the master base station link may be determined to be inoperative in step 803. As a result of the determination, if the master base station link is good, the radio link failure preparation timer may be started in step 805. Thereafter, in step 807, it is determined whether or not the radio link failure preparation timer expires. If the radio link failure preparation timer is before expiration, the expiration can be waited in step 809.

Then, if the radio link failure preparation timer has expired, it may be determined in step 811 whether the Ncell measurement is valid. As a result of the determination, if the Ncell measurement is valid, a message including information on the T310 start of the auxiliary base station link may be transmitted to the master base station together with the Ncell measurement report in step 813. At this time, the auxiliary base station can indicate the replacement cell in step 814. Thereafter, in step 821, it is possible to wait for a preset time. At this time, the standby of the terminal may be preferable through the radio link failure preparation timer.

On the other hand, if the Ncell measurement is not valid, a message including information on the start of T310 of the master base station link may be transmitted to the master base station in step 815. In step 817, the master base station may instruct the terminal to perform the Ncell measurement. In step 819, the UE can report the Ncell measurement result performed by the master base station.

In step 823 or step 821 or step 819, the BS may determine whether there is a picocell suitable for handover based on the report of the measurement result of the MS. If the proper picocell is not present, the master base station may select one or more picocells preset to the replacement cell or set as the current replacement cell by the auxiliary base station in step 825. [

If a proper picocell is selected in step 823 or the master station selects a picocell as a replacement cell in step 825, the master base station transmits the context to the selected picocell in step 827 and can prepare for handover. At this time, the same process can be carried out in the auxiliary base station. Then, in step 829, the T310 expires. If the T310 expires, the master base station can instruct the terminal to perform handover to the prepared picocell in step 831. FIG.

However, if the master base station fails to select an appropriate replacement cell as a picocell in step 825, it waits for the expiration of T310 in step 833, and when the T310 expires, it instructs the terminal to replace with a single connection with the auxiliary base station in step 835 .

Embodiments for handling a radio link failure as described in connection with FIGS. 4-8 may be generalized to a multi-base station setup in which a terminal is connected to multiple base stations and one of them operates as a master base station. For example, when the terminal reports an expected radio link failure on one link connected to the master base station in the embodiment for processing a radio link failure described in FIG. 6 (preparation of an early radio link failure) Other cells may be prepared to handle the flows serviced by the base station with the link in the failed state. The alternative cell selected by this preparation may be one cell in the set of existing cells serving the terminal or may be a new cell not belonging to the cell set serving the terminal. Likewise, the embodiment for processing the radio link failure explained in the section related to FIG. 4 and FIG. 5 can also be applied in the case of multiple base station setting.

According to an embodiment, the base station receiving the radio link failure prediction message can prepare one or more cells for handover. This can increase the success rate of re-establishment because more cells are prepared for re-establishment and the opportunity of the terminal selecting a cell prepared for re-establishment is higher. In another embodiment, such a radio link failure prediction message may be transmitted more than once.

The radio link failure message in the above embodiments may be a new layer 2 or layer 3 message, an information element in an existing message, or a layer 1 level signal for faster and robust indication. For example, a dedicated access code (RACH code) may be given to the terminal for this purpose. Or, according to an embodiment, a legacy connection re-establishment request may be used for the radio link failure message. The master base station can determine whether the link to which the connection re-establishment request is in the radio link failure state based on the received link.

In the embodiments described above, it has been described that the radio link failure is triggered based on expiration of T310. However, the above-described embodiments can equally be applied to a radio link failure trigger due to other causes such as RACH failure on the auxiliary base station and radio link failure including RLC failure on the auxiliary base station.

According to an embodiment of the present invention, the radio link failure indicator may include a radio link failure cause value. The cause of the radio link failure may include at least one of an expiration of the T 310, a random access (RACH) failure on the auxiliary base station, and a radio link control layer (RLC) failure on the auxiliary base station. The random access may be supported by one of the cells of the auxiliary base station.

20 is a flowchart illustrating a method of transmitting a radio link failure indicator including a radio link failure cause value according to an embodiment of the present invention.

Referring to FIG. 20, in step 2051, the terminal 2010 is dual-connected to the master base station 2020 and the auxiliary base station 2030. At this time, for example, when the random access fails, the auxiliary base station 2030 can not know this. Similarly, when the maximum number of retransmissions is reached in the cell of the auxiliary base station 2030, the radio link failure needs to be triggered. In all scenarios such as L1 out-of-sync during a pre-set time period (e.g., T310), or RACH failure of a secondary base station, or RLC failure of a secondary base station, wireless link failure Is triggered. In order to allow the master base station to perform the proper operation, this information may be transmitted to the master station of the dual connection in step 2053. [ Also, if a radio link failure is detected on the link of the auxiliary base station, the UE may stop all uplink transmissions such as CQI / SR / SRS as quickly as possible to prevent the generation of unnecessary uplink interference.

For example, in order to identify the cause of the radio link failure on the auxiliary base station, the IE may be defined as follows.

SeNB-RLF-Cause ENUM {T310 Expiry, RACH Failure, RLC Failure}

In an alternative embodiment, the radio link failure indicator may include a cause value. The cause may include a random accessor (RACH) failure on the auxiliary base station and a radio link control layer (RLC) failure on the auxiliary base station.

For example, in order to identify the cause of the radio link failure on the auxiliary base station, the IE may be defined as follows.

SeNB-RLF-Cause ENUM {RACH Failure, RLC Failure}

In another alternative embodiment, when a radio link failure occurs at the same time, the auxiliary base station-radio link failure-cause IE (SeNB-RLF-Cause IE) indicates a multiple type of radio link failure It is possible. For example, the IE may be defined as follows to identify the cause of the radio link failure on the auxiliary base station.

RACH Failure, T310 Expiry & RACH Failure, RACH Failure & RLC Failure, T310 Expiry & RLC Failure, T310 Expiry & RACH Failure & RLC Failure,

In such a case, the serving BS-SeLB-RLF-Cause IE may be regarded as a radio link failure indicator itself according to the embodiment.

Depending on the embodiment, such an IE may be included in an existing RRC message. Alternatively, a new RRC message may be created to carry the IE.

FIG. 21 is a flowchart illustrating a method of transmitting a radio link failure indicator included in a measurement report configuration according to an embodiment of the present invention. Referring to FIG.

Referring to FIG. 21, in step 2151, the terminal 2110 is double-connected to the master base station 2120 and the auxiliary base station 2130. At this time, if the terminal 2110 detects a radio link failure on the cell of the auxiliary base station 2130 in step 2153, the terminal 2110 informs the master base station 2120 of the cause of the radio link failure For example, an auxiliary base station - radio link failure - cause IE) may be included in a measurement report. At this time, the master base station 2120 may transmit a message for the measurement configuration to report the failure of the radio link of the auxiliary base station 2130 to the terminal 2110 in step 2152. [

Meanwhile, a new determined measurement report may be generated to include the cause information of the radio link failure according to an embodiment. In this case, if the terminal 2110 detects a radio link failure on the cell of the auxiliary base station 2130 in step 2153, the terminal 2110 transmits a failure report indicating failure of the auxiliary base station-radio link failure - send an extended measurement report including the cause IE (SeNB-RLF-Cause IE) to the master base station 2120. At this time, in step 2152, the UE 2110 may be configured by the base station (master) to transmit the extended measurement lift when a radio link failure is detected on the cell of the auxiliary base station.

22 is a flowchart illustrating a method of transmitting a radio link failure indicator included in a measurement report configuration according to an embodiment of the present invention.

22, in step 2251, the terminal 2210 is dual-connected to the master base station 2220 and the auxiliary base station 2230. In this case, if the terminal 2210 detects a radio link failure on the cell of the auxiliary base station 2230 in step 2252, the terminal 2210 can always transmit the extended measurement report to the master base station 2220. The embodiment related to FIG. 22 does not require a measurement configuration, unlike the embodiment described in connection with FIG. If the UE 2210 detects a radio link failure on the cell of the auxiliary base station 2230 in step 2252, the UE 2210 transmits information on the cause of the radio link failure (for example, Cause IE) can be prepared. At this time, according to an embodiment, the extended measurement report may include measurement results of a serving cell and neighboring cells if possible. The terminal 2210 may transmit the extended measurement report to the master base station 2220 in step 2253.

On the other hand, depending on the embodiment, the RRCConnectionReestablishmentRequest may be used to indicate the radio link failure on the auxiliary base station and the cause of the failure. At this time, a spare field of ReestablishmentCause can be used as a signal of the radio link failure indicator of the auxiliary base station. A detailed description thereof will be given later. Upon receiving the RRCConnectionReestablishmentRequest , the master base station can determine , based on the ReestablishmentCause , whether the RRCConnectionReestablishmentRequest is due to the radio link failure of the auxiliary base station. And the master base station may perform appropriate operations instead of processing the RRCConnectionReestablishmentRequest message in a legacy manner. Alternatively, in accordance with an embodiment, the master base station may use a re-establishment request to indicate a radio link failure on the auxiliary base station if the physCellId field corresponding to the PUCCH corresponds to a cell of the auxiliary base station. In yet another embodiment, a supplementary base station-radio link failure-cause IE as described above may be included in the RRCConnectionReestablishmentRequest to clearly indicate the cause of the radio link failure of the auxiliary base station. Only if RRCConnectionReestablishmentRequest is used to indicate the radio link failure on the secondary base station, the IE may be included in RRCConnectionReestablishmentRequest.

For example, messages can be constructed as shown in [Table 1].

- ASN1START

RRCConnectionReestablishmentRequest :: = SEQUENCE {
criticalExtensions CHOICE {
rrcConnectionReestablishmentRequest-r8
RRCConnectionReestablishmentRequest-r8-IEs,
criticalExtensionsFuture SEQUENCE {}
}
}

RRCConnectionReestablishmentRequest-r8-IEs :: = SEQUENCE {
ue-Identity Reestabue-Identity,
reestablishmentCause ReestablishmentCause,
spare BIT STRING (SIZE (2))
}

Reestabue-Identity :: = SEQUENCE {
c-RNTI C-RNTI,
physCellId PhysCellId,
shortMAC-I ShortMAC-I
}

ReestablishmentCause :: = ENUMERATED {
reconfigurationFailure, handoverFailure,
otherFailure, SeNB-RLF}

- ASN1STOP

Meanwhile, according to another embodiment of the present invention, the UE can notify the master base station by transmitting a UE assistance information (UEAssistanceInformation) message to the master base station (MeNB) in a radio link failure (RLF) situation occurring in the sub base station (SeNB). At this time, the UE assistance information message transmitted from the UE to the master base station includes at least one of a cause of the radio link failure occurring in the auxiliary base station, that is, a physical layer failure, a RACH failure and an RLC failure Or more.

The UE can perform a radio link monitoring (RLM) operation on cells of at least one sub-base station (SeNB) on which an uplink control channel (PUCCH) is set. The radio link monitoring operation for the auxiliary base station (SeNB) cell may be performed in the same manner as the radio link monitoring operation for the master base station (MeNB) cell in which the PUCCH is set, that is, the PCell. At this time, parameters such as T310, N310, N311 and the like can be used. When the UE detects a radio link failure for the auxiliary base station by performing the radio link monitoring operation, the UE stops the uplink transmission to all the cells of the corresponding auxiliary base station and informs the master base station that the radio link failure has occurred in the auxiliary base station UE can send a UE assistance information message. Here, the UE assistance information message may include the cause of the radio link failure occurring in the auxiliary base station, and may be specifically as shown in Table 2 below.

UEAssistanceInformation message - ASN1START

UEAssistanceInformation-r11 :: = SEQUENCE {
criticalExtensions CHOICE {
c1 CHOICE {
ueAssistanceInformation-r11 UEAssistanceInformation-r11-IEs,
spare3 NULL, spare2 NULL, spare1 NULL
},
criticalExtensionsFuture SEQUENCE {}
}
}

UEAssistanceInformation-r11-IEs :: = SEQUENCE {
powerPrefIndication-r11 ENUMERATED {normal, lowPowerConsumption} OPTIONAL,
lateNonCriticalExtension OCTET STRING OPTIONAL,
nonCriticalExtension UEAssistanceInformation-r12-IEs OPTIONAL
}

UEAssistanceInformation-r12-IEs :: = SEQUENCE {
SCGRLFCause ENUMERATED {
t310-Expiry, randomAccessProblem,
rlc-MaxNumRetx, spare1} OPTIONAL,
lateNonCriticalExtension OCTET STRING OPTIONAL,
nonCriticalExtension SEQUENCE {} OPTIONAL
}



- ASN1STOP UEAssistanceInformation field descriptions powerPrefIndication
Value lowPowerConsumption indicates that the UE prefers a configuration that is primarily optimized for power saving. Otherwise the value is set to normal . SCGRLFCause
This field is used to indicate the cause of the problem.

23 to 25 are diagrams showing examples of MAC CEs according to an embodiment of the present invention.

According to an embodiment, a radio link failure indicator having a cause value of a radio link failure may be defined as a new message or a new MAC CE. Or a radio link failure indicator having a cause value of a radio link failure may be added as a new information element in an existing message. The identifier of the cell may be identified with a radio link failure indicator. If the radio link failure indicator does not include a cell identifier, it can be regarded as indicating a radio link failure on the auxiliary base station cell (for example, the PUCCH cell of the auxiliary base station). For example, a new MAC CE as shown in Figs. 23 to 24 can be defined.

Referring to FIG. 23, C ₇ of the new MAC CE may indicate a radio link failure due to RACH failure on the PUCCH carrier cell of the auxiliary base station, and C ₆ may indicate radio link failure due to RLC failure of the PUCCH carrier cell of the auxiliary base station. . And the other bits may be in a reserved state.

Referring to FIG. 24, a MAC CE may be defined to indicate the cause of a radio link failure due to RACH failure and RLC failure. C ₇ of the MAC CE indicates a radio link failure due to L1 out-of-sync on the PUCCH carrier cell of the auxiliary base station, C ₆ may indicate radio link failure due to RACH failure on the PUCCH carrier cell of the auxiliary base station, C ₅ may indicate a radio link failure due to RLC failure of the PUCCH carrying cell of the auxiliary base station. And the other bits may be in a reserved state.

Referring to FIG. 25, according to an embodiment of the present invention, a radio link failure can be transmitted to a master base station using an existing message ( VarRLF-Report ). At this time, ' failedPCellId ' may be set to identify the cell of the master base station or the auxiliary base station where the radio link failure has occurred, according to the embodiment. For example, the failedPCellId may be set to PCell (of the master base station) or pSCell (which is a special cell with the PUCCH of the auxiliary base station). rlf-Cause can be set to one of the above-mentioned causes. The availability of the stored radio link failure report may be identified by the master base station requesting the terminal to transmit a stored radio link failure report. In one embodiment, the indication of availability to be transmitted to the master base station may indicate that the radio link failure report is for the auxiliary base station. For example, the availability may be indicated by transmitting a MAC CE. At this time, C ₇ , C ₆ , and C ₅ of the MAC CE can transmit the above-described information. That is, C ₇ is L1 out on the PUCCH carries a cell of the secondary base station-of-represents a sync from a radio link failure, C ₆ may indicate a radio link failure due to the RACH failures on the PUCCH carries a cell of the secondary base station, C ₅ is It may indicate a radio link failure due to an RLC failure of the PUCCH carrying cell of the auxiliary base station. Alternatively, although not shown, C ₇ may indicate a radio link failure due to a RACH failure on the PUCCH bearer cell of the auxiliary base station, as shown in FIG. 23, and C ₆ may indicate a radio link failure due to the RLC failure of the PUCCH bearer cell of the auxiliary base station. Link failure may be indicated. On the other hand, C ₀ may indicate the availability of the radio link failure report. The base station can use a legacy UE Information Request and a UE Information Response message to acquire a report from the UE.

In yet another embodiment, a PHY layer signal may be used to indicate a radio link failure on the auxiliary base station and its cause. For example, the RACH code may be preconfigured to specify the cause of each radio link failure.

In one embodiment, a timer value (T310) for detection of a radio link failure may be configured differently for each base station.

The causes of one or more radio link failures may be applied to one or more cells served by a serving base station. For example, the RACH may be supported for only one cell of the auxiliary base station (which may be referred to as pSCell), so that the RACH failure can only be triggered on the pSCell.

Further, according to the embodiment, the radio link failure message may include link identification information of a link on which a radio link failure occurs. The link identification information may indicate whether it is a link of the master base station or a link of the auxiliary base station. For example, it may be a 1 bit identifier in a dual connection. And may be extended accordingly in a multi-BS system.

9 is a diagram showing an early indication flow chart of a radio link failure in a single connection system.

Referring to FIG. 9, early indication of radio link failure before expiration of the radio link failure timer can also be used in a single connection system. In step 951, the UE 910 may expect a radio link failure on the first link. For example, a radio link failure may be expected when the radio link failure timer T310 is started. Or a radio link failure may be expected after a predetermined time has elapsed since the start of T310. A detailed description thereof has been described above, and thus will be omitted.

In step 952, the UE 910 may transmit a radio link failure prediction message to the source base station 920. If the source base station 920 successfully receives the radio link failure prediction message, the target cell 930 can be prepared for early re-establishment sufficiently. Since the contents of steps 952 through 955 are similar to those of the above-described embodiments, a detailed description thereof will be omitted.

Thereafter, when a radio link failure actually occurs in step 956 and the UE 910 attempts a re-establishment procedure with a new cell 930, a new cell 930 already prepared for re-establishment (with user context) , The success rate of re-establishment can be increased.

In the above, a method of handling a failure of a wireless link in a dual connection or a single connection has been described.

Hereinafter, switching between a single connection and a double connection will be described in detail.

10 is a flowchart illustrating a method of switching from a dual connection to a single connection according to an embodiment of the present invention.

Referring to FIG. 10, the terminal 1010 may be connected to the master base station 1020 and the auxiliary base station 1030 in a dual connection mode. Then, the switching can be operated in a single connection with the master base station 1020. [ In step 1051, the MS 1010 determines to switch to the single connection mode. In step 1052, the MS 1010 may transmit a single connection change request message indicating that the MS 1020 wishes to switch to the single connection mode. At this time, the single connection change request message may include an identifier (ID) of the master base station 1020.

The master base station 1020 may then fake information about the flows (e.g., QoS, etc.) serviced by the auxiliary base station 1030. [ Specifically, the master base station 1020 can determine to acquire the flow information of another base station (e.g., the auxiliary base station 1030) that it does not have in step 1053. In step 1054, the master base station 1020 can transmit a request message of the flow information being serviced by the auxiliary base station 1030 to the auxiliary base station 1030. The auxiliary base station 1030 can transmit an information response message to the master base station 1020 in step 1055. [

The master base station 1020 can perform admission control of flows in step 1056 based on the received flow information. If the flows can not be supported, the master base station 1020 may downgrade or terminate the flows in step 1056-1.

In step 1057, the master base station 1020 may transmit a single connection indication message to the auxiliary base station 1030 to confirm that the terminal 1010 is to be serviced in the single connection mode. In step 1058, the auxiliary base station 1030 may delete the terminal context. In this case, the auxiliary base station 1030 may delete the UE context after a predetermined time elapses.

In step 1059, the master base station 1020 triggers the switching to the single connection and transmits a single connection switching response message to the terminal 1010 together with the changed flow information in step 1060 so as to perform the single connection switching. . In step 1061, the terminal 1010 deletes the context of the auxiliary base station 1030 and transmits the changed flows to the master base station 1020, thereby switching to the single connection mode with the master base station 1020. [

11 is a flowchart illustrating a method of switching from a dual connection to a single connection according to another embodiment of the present invention.

Referring to FIG. 11, the terminal 1110 may be connected to the master base station 1120 and the auxiliary base station 1130 in a dual connection mode. Then, the switching can be performed by a single connection with the auxiliary base station 1130. In step 1151, the MS 1110 determines to switch to the single connection mode. In step 1152, the MS 1110 transmits a single connection change request message indicating that the MS 1120 desires to switch to the single connection mode. At this time, the single connection change request message may include an identifier (ID) of the auxiliary base station 1130.

The master base station 1120 may then decide to provide the auxiliary base station 1130 with information about the flows (e.g., QoS, etc.) it is servicing in step 1153. [ In step 1154, the master base station 1120 can transmit a single connection request message to the auxiliary base station 1130. At this time, the master base station 1120 can transmit the information of the flows that it is servicing together.

The auxiliary base station 1130 can perform admission control of the flows in step 1155 based on the received flow information. If the flows can not be supported, the serving base station 1130 may downgrade or terminate the flows in step 1156. [

The secondary base station 1130 can transmit a single connection response message to the master base station 1120 in step 1157 to confirm that the terminal 1110 is to be serviced in the single connection mode. At this time, the changed flow information may be transmitted to the master base station 1120 together with the single connection response message.

In step 1158, the master base station 1120 deletes the terminal context. At this time, according to the embodiment, the master base station 1120 can delete the terminal context after a predetermined time has elapsed.

In step 1159, the master base station 1120 triggers the switching to the single connection and transmits a single connection change response message to the terminal 1110 together with the changed flow information in step 1160 so as to perform the single connection change. . In step 1161, the AT 1110 deletes the context of the master base station 1120 and transmits the changed flows to the auxiliary base station 1130, thereby switching to the single connection mode with the auxiliary base station 1130.

12 is a flowchart illustrating a method of switching from a dual connection to a single connection according to another embodiment of the present invention.

12, the terminal 1210 may be connected to the master base station 1220 and the auxiliary base station 1230 in a dual connection mode. Then, switching can be performed by a single connection with the master base station 1220. [ In step 1251, the master base station 1220 can determine that the terminal 1210 switches to the single connection mode with itself.

The master base station 1220 may then fake information about the flows (e.g., QoS, etc.) serviced by the auxiliary base station 1230. Specifically, the master base station 1220 may determine to acquire the flow information of another base station (e.g., the auxiliary base station 1230) that it does not have in step 1252. [ In step 1253, the master base station 1220 can transmit a request message of the flow information being serviced by the auxiliary base station 1230 to the auxiliary base station 1230. The auxiliary base station 1230 can transmit an information response message to the master base station 1220 in step 1254.

The master base station 1220 may perform admission control of flows in step 1255 based on the received flow information. If the flows can not be supported, the master base station 1220 may downgrade or terminate the flows in step 1256. [

The master base station 1220 can transmit a single connection indication message to the auxiliary base station 1230 in step 1257 to confirm that the terminal 1210 is to be serviced in the single connection mode. In step 1258, the auxiliary base station 1230 may delete the terminal context. In this case, the auxiliary base station 1230 may delete the UE context after a predetermined time has elapsed.

In step 1259, the master base station 1220 triggers the switching to the single connection and transmits a single connection change message to the terminal 1210 together with the identifier (ID) of the master base station 1220 and the changed flow information in step 1260, The terminal 1210 can be operated to perform connection switching. The terminal 1210 may delete the context of the auxiliary base station 1230 and transmit the changed flows to the master base station 1220 to switch to the single connection mode with the master base station 1220. [

13 is a flowchart illustrating a method of switching from a dual connection to a single connection according to another embodiment of the present invention.

Referring to FIG. 13, the terminal 1310 may be connected to the master base station 1320 and the auxiliary base station 1330 in a dual connection mode. Then, the switching can be operated by a single connection with the auxiliary base station 1330. In step 1351, the master base station 1320 may determine that the terminal 1310 switches to the single connection mode with the auxiliary base station 1330. [

The master base station 1320 may then decide to provide the auxiliary base station 1330 with information about the flows (e.g., QoS, etc.) it is servicing in step 1352. [ Then, in step 1353, the master base station 1320 can transmit a single connection change request message to the auxiliary base station 1330. At this time, the master base station 1320 can transmit the information of the flows that it is servicing together.

The auxiliary base station 1330 can perform admission control of flows in step 1354 based on the received flow information. If the flows can not be supported, the auxiliary base station 1330 may downgrade or terminate the flows in step 1155. [

Subsequently, in step 1356, the serving base station 1330 may transmit a single connection response message to the master base station 1320 to confirm that the terminal 1310 desires to service the terminal 1310 in the single connection mode. At this time, the changed flow information may be transmitted to the master base station 1320 together with the single connection response message.

In step 1357, the master base station 1320 triggers the switching to the single connection and transmits a single connection switching response message to the terminal 1310 together with the identifier (ID) of the auxiliary base station 1320 and the changed flow information in step 1358 The terminal 1310 can be operated to perform a single connection switching.

The master base station 1320 may then delete the terminal context in step 1359. [ At this time, according to the embodiment, the master base station 1320 can delete the terminal context after a predetermined time elapses.

In step 1360, the terminal 1310 deletes the context of the master base station 1320, transmits the changed flows to the auxiliary base station 1330, and can switch to the single connection mode with the auxiliary base station 1330.

14 is a flowchart illustrating a method of switching from a single connection to a dual connection according to an embodiment of the present invention.

Referring to FIG. 14, the terminal 1410 may be operating in a single connection with the current master base station 1420. In step 1451, the MS 1410 determines to switch from the single connection to the dual connection. In step 1452, the MS 1410 transmits a dual connection switching request message indicating that the MS 1420 desires switching to the dual connection mode have. At this time, the double connection change request message may include the identifier of the auxiliary base station 1430.

The master base station 1420 can perform duplex connection confirmation with the auxiliary base station 1430 in step 1453. For example, the double connection confirmation may be flow acknowledgment control, confirmation of the master base station and the auxiliary base station pair to support double connection, but is not limited thereto.

The master base station 1420 may then send a dual connection request message to the auxiliary base station 1430. At this time, flow information may be included in the double connection request message. The auxiliary base station 1430 can perform admission control of flows in step 1455 based on the received flow information. If the flows can not be supported, the serving base station 1430 may downgrade or terminate the flows in step 1456. [

In step 1457, the auxiliary base station 1430 can confirm the support for accepting the dual connection by transmitting a dual connection response message to the master base station 1420. In step 1458, the master base station 1420 can trigger the switching of the dual link. Then, in step 1459, the master base station 1420 transmits a dual connection switching response message to the terminal 1410, thereby operating the terminal 1410 to perform the dual connection switching. Then, in step 1460, the terminal 1410 can switch to the dual connection mode with the master base station 1420 and the auxiliary base station 1430.

15 is a flowchart illustrating a method of switching from a single connection to a dual connection according to another embodiment of the present invention.

Referring to FIG. 15, the terminal 1510 may be operating in a single connection with the current master base station 1520. In step 1551, the master base station 1520 can determine the switching from the single connection to the dual connection. At this time, the master base station 1520 can perform duplex connection confirmation with the auxiliary base station 1530. For example, the double connection confirmation may be flow acknowledgment control, confirmation of the master base station and the auxiliary base station pair to support double connection, but is not limited thereto.

Then, in step 1552, the master base station 1520 can transmit a dual connection request message to the auxiliary base station 1530 specifying that it desires to switch to the dual connection mode. At this time, flow information may be included in the double connection request message.

The auxiliary base station 1530 can perform admission control of flows in step 1553 based on the received flow information. If the flows can not be supported, the serving base station 1530 may downgrade or terminate the flows at step 1555. [

In step 1554, the auxiliary base station 1530 transmits a dual connection response message to the master base station 1520 to confirm the support for accepting the dual connection. In step 1556, the master base station 1520 may trigger the switching of the dual link. Then, in step 1557, the master base station 1520 transmits a dual connection switching response message including the identifier and flow information of the auxiliary base station 1530 to the terminal 1510 to perform the switching of the dual connection path to the terminal 1510 . Thereafter, in step 1558, the terminal 1510 can switch to the dual connection mode with the master base station 1520 and the auxiliary base station 1530. Then, the terminal 1510 can transmit a dual connection response message to the master base station 1520.

16 is a block diagram of a terminal according to an embodiment of the present invention.

Referring to FIG. 16, the controller 1610 controls the terminal to perform any one of the above-described embodiments. For example, the control unit 1610 may transmit a radio link failure (RLF) prediction message associated with the first link to the base station, and send a radio link failure message associated with the first link to the base station, And controls the base station to receive a handover command to the target cell selected by the base station according to the radio link failure prediction message.

The communication unit 1620 transmits and receives signals according to any one of the above-described embodiments. For example, the communication unit 1620 may transmit a radio link failure message and a radio link failure prediction message to the master base station.

17 is a block diagram of a base station according to an embodiment of the present invention.

Referring to FIG. 17, the control unit 1710 controls the base station to perform the operation of any one of the above-described embodiments. For example, the control unit 1710 receives a radio link failure (RLF) prediction message associated with the first link from the UE, and searches for a target cell for handover of the UE according to the radio link failure prediction message Selecting a target cell from the terminal if the search result indicates that there is a target cell, receiving a radio link failure message associated with the first link from the terminal through a second link, Over command is transmitted.

The communication unit 1720 transmits and receives signals according to any one of the above-described embodiments. For example, the communication unit 1720 can receive a radio link failure message and a radio link failure prediction message from the terminal.

The embodiments disclosed in the present specification and drawings are merely illustrative of specific examples for the purpose of easy explanation and understanding, and are not intended to limit the scope of the present invention. It is to be understood by those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, And is not intended to limit the scope of the invention. It is to be understood by those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

410, 510, 610: terminals 420, 520, 620:
430, 530, 630: auxiliary base station 440, 540, 640: target base station

Claims (20)

A method of a multiple base station connection communication method of a base station,
Receiving a radio link failure (RLF) prediction message associated with the first link from the terminal;
Searching for a target cell for handover according to the radio link failure prediction message;
Selecting the target cell if the search target cell exists;
Receiving a radio link failure message associated with the first link from the terminal over a second link; And
Transmitting a handover command to the selected target cell to the terminal;
The base station comprising: The method according to claim 1,
Selecting a base station for a single connection to the second link if the search result target cell does not exist; And
Transmitting a single connection change message to the terminal with the base station selected for the single connection;
Further comprising the step of: A method of a multiple base station connection communication method of a terminal,
Transmitting a Radio Link Failure (RLF) prediction message associated with the first link to the base station;
Transmitting a radio link failure message associated with the first link to the base station via a second link; And
Receiving a handover command to a target cell selected by the base station according to the radio link failure prediction message;
The method comprising the steps of: The method of claim 3,
Receiving a single connection transition message from the base station to the second link; And
Switching to a single connection mode with one base station according to the received single connection switching message;
Further comprising the steps of: determining whether the terminal is connected to the base station. A method of a multiple base station connection communication method of a base station,
Receiving a Radio Link Failure (RLF) message associated with a first link from a terminal via a second link;
Searching for a target cell for handover according to the radio link failure message;
Selecting the target cell if the search target cell exists; And
Transmitting a handover command to the selected target cell to the terminal;
The base station comprising: 6. The method of claim 5,
Selecting a base station for a single connection to the second link if the search result target cell does not exist; And
Transmitting a single connection change message to the terminal with the base station selected for the single connection;
Further comprising the step of: A method of a multiple base station connection communication method of a terminal,
Transmitting a Radio Link Failure (RLF) message associated with a first link to a base station via a second link; And
Receiving a handover command to a target cell selected by the base station according to the radio link failure message;
The method comprising the steps of: 8. The method of claim 7,
Receiving a single connection transition message from the base station to the second link;
Switching to a single connection mode with one base station according to the received single connection switching message;
Further comprising the steps of: determining whether the terminal is connected to the base station. A method of a multiple base station connection communication method of a base station,
Receiving a Radio Link Failure (RLF) message associated with a first link from a terminal via a second link;
Selecting a base station for a single connection to the second link according to the radio link failure message; And
Transmitting a single connection change message to the terminal with the base station selected for the single connection;
The base station comprising: A method of a multiple base station connection communication method of a terminal,
Transmitting a Radio Link Failure (RLF) message associated with a first link to a base station via a second link;
Receiving a single connection transition message from the base station to the second link; And
Switching to a single connection mode with one base station according to the received single connection switching message;
The method comprising the steps of: A base station for performing multiple base station connection communication,
A communication unit for communicating with other base stations and terminals;
The method includes receiving a radio link failure (RLF) prediction message associated with a first link from a mobile station, searching for a target cell for handover according to the radio link failure prediction message, A control unit for selecting the target cell, receiving a radio link failure message associated with the first link from the terminal through a second link, and controlling the terminal to transmit a handover command to the selected target cell;
/ RTI > 12. The apparatus according to claim 11,
And selects a base station for a single connection to the second link when the search result does not exist, and controls the terminal to transmit a single connection change message to the base station selected for the single connection. . In a terminal performing multi-base station connection communication,
A communication unit for communicating with the base station;
Transmitting a radio link failure (RLF) expectation message associated with a first link to a base station, transmitting a radio link failure message associated with the first link to the base station via a second link, A control unit for controlling the base station to receive a handover command to a target cell selected by the base station;
. 14. The apparatus of claim 13,
The method comprising: receiving a single connection change message from the base station to the second link and controlling the single connection change message to a single connection mode according to the received single connection change message; . A base station for performing multiple base station connection communication,
A communication unit for communicating with other base stations and terminals;
The method includes receiving a radio link failure (RLF) message associated with a first link from a terminal through a second link, searching for a target cell for handover according to the radio link failure message, A control unit for selecting the target cell and transmitting a handover command to the selected target cell when the cell exists;
/ RTI > 16. The apparatus of claim 15,
And selects a base station for a single connection to the second link when the search result does not exist, and controls the terminal to transmit a single connection change message to the base station selected for the single connection. . In a terminal performing multi-base station connection communication,
A communication unit for communicating with the base station;
A control unit for transmitting a radio link failure (RLF) message associated with a first link to a base station via a second link and controlling the base station to receive a handover command to a target cell selected by the base station according to the radio link failure message ;
. 18. The apparatus of claim 17,
Receives a single connection change message from the base station to the second link, and controls to switch to a single connection mode with one base station according to the received single connection change message. A base station for performing multiple base station connection communication,
A communication unit for communicating with other base stations and terminals;
Receiving a radio link failure (RLF) message associated with a first link from a terminal via a second link, selecting a base station for a single connection to the second link according to the radio link failure message, A controller for controlling the terminal to transmit a single connection change message to the base station selected for the single connection;
/ RTI > In a terminal performing multi-base station connection communication,
A communication unit for communicating with the base station;
Transmitting a Radio Link Failure (RLF) message associated with a first link to a base station via a second link, receiving a single connection transition message from the base station to the second link, A control unit to control switching to a single connection mode with one base station according to a message;
.

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