KR20180047413A - Base station and terminal device, beam switching method and base station hand over method - Google Patents

Abstract

Disclosed is a technology for providing the maximum performance in an ultra-low latency service even for a moving terminal without degradation of the performance thereof by realizing a new method (technology) capable of securing beam mobility between base stations and mobility between beams within the same quick and seamless base station in a multiple input multiple output (MIMO) communication system. To this end, a base station device comprises: a report information recognition unit; a beam determination unit; and an optimal beam control unit.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a base station apparatus, a terminal apparatus, an optimal beam switching method, and a base station handover method.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a technique capable of ensuring mobility between beams in a same base station and beam mobility between base stations in a MIMO communication system using a plurality of antenna beam-based beamforming techniques.

(Hereinafter referred to as " Ultra Reliable & Low Latency Communication ") service based on near real-time data transmission / reception in accordance with the development of mobile communication networks for mass data / high- , 5G) environment.

In this 5G, a multiple input multiple output (MIMO) technique based on beamforming technology capable of transmitting and receiving a beamformed signal with different antennas in different directions is adopted in order to increase transmission efficiency between a base station and a terminal.

In the case of a communication system (hereinafter, referred to as a MIMO communication system) employing MIMO technology, an antenna beam having various directions / shapes capable of forming a base station and antenna beams having various directions / Find the beam link (beam pair), and communicate using this optimum beam link.

In this case, in the MIMO communication system, the channel environment between the base station and the terminal is changed, and the optimal beam link (s) Is no longer valid.

In this case, the UE must quickly find and move (hand over) the optimal beam link according to the movement position, for example, another optimal beam link in the same base station or an optimal beam link with another base station.

In the 5G that has been discussed so far, a method for searching for an optimal beam link in a base station, a beam having a sequence of steps such as TX beam sweeping at the base station, RX beam sweeping at the end of the terminal, Tracking is used, and a separate method is not proposed for a situation in which handover is required to quickly find another optimal beam link in the same base station (hereinafter referred to as optimal beam switching during movement).

Thus, at this time, the terminal must, during the move, perform beam tracking when it is no longer valid and find another optimal beam link in the same base station. Therefore, in this case, since the moving position of the terminal rapidly changes while the beam tracking is completed and it takes a certain time until the optimum beam link is found, the optimal beam link is adaptively used according to the movement, There is a limit to using seamlessly.

In addition, in the 5G that has been discussed so far, although the terminal also has a structural feature (hereinafter, referred to as a MIMO structure characteristic) capable of transmitting and receiving a beamformed signal in various directions with a plurality of antennas, (Hereinafter referred to as " base station handover ") in order to improve performance.

At this time, if the optimal beam link with the current base station is no longer valid, the terminal must perform beam tracking with another base station that becomes the handover target only until the optimal beam link in the target base station is found do. Therefore, in this case, since the moving position of the terminal rapidly changes while the beam tracking is completed and it takes a certain time to find the optimum beam link, the optimal beam link is adaptively used according to the movement, There is a limit to use seamlessly.

As a result, in the future 5G that is aiming at ultra low-latency service, there is a need for a technology that allows the mobile terminal to seamlessly utilize the communication service using the optimal beam link adaptively according to the movement.

Accordingly, the present invention proposes a technique for ensuring fast and seamless mobility between beams in the same base station and beam mobility between base stations in a MIMO communication system.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a method for ensuring mobility between beams in the same base station and beam mobility between base stations in a MIMO communication system, .

In order to achieve the above object, a base station apparatus in a MIMO communication system according to a first aspect of the present invention includes: a base station apparatus for measuring a channel state of each beam link formed for each of multiple antenna beams of the base station apparatus, And reporting information on a predetermined number of beam links according to the number of beam links; A beam determining unit for determining an active beam link for the terminal based on information reported from the terminal; And notifies the terminal of information on the determined active beam link, and causes the terminal to use the active beam link as an optimal beam link for communication with the base station.

Preferably, the reporting information receiving unit recognizes information on the predetermined number of beam links included in a specific header in the uplink packet when processing uplink packets from the terminal, and reports the information.

Preferably, the optimum beam control unit includes information on the active beam link in a specific header in a downlink packet transmitted to the terminal, and notifies the terminal of the information.

Preferably, the specific header may be a header of an L (Layer) 2 level which is processed first in the uplink packet or the downlink packet processing.

Preferably, the beam determining unit determines, based on the information reported from the terminal, if there is a specific beam link having a better channel state than the current optimal beam link used for communication with the terminal, It can be determined as an active beam link.

According to a second aspect of the present invention, there is provided an optimal beam switching method performed by a base station of a MIMO communication system, the method comprising: measuring a channel state of each beam link formed for each of multiple antenna beams of the base station apparatus; And reporting information for reporting information on a predetermined number of beam links in the order of excellent channel state; A beam determining step of determining an active beam link for the terminal based on information reported from the terminal; And notifying the terminal of information on the determined active beam link, and causing the terminal to use the active beam link as an optimal beam link for communication with the base station.

Preferably, the information in the reporting information step is reported from a specific header in the uplink packet when processing the uplink packet from the terminal, and the information of the optimum beam control step is transmitted to the terminal To be included in a specific header in the downlink packet.

Advantageously, said specific header may be a header of L2 level that is processed first in said uplink packet or said downlink packet processing.

According to a third aspect of the present invention, there is provided an optimal beam switching method comprising: measuring a channel state of each beam link formed for each of multiple antenna beams of a base station; A reporting step of reporting information on a predetermined number of beam links to the base station in the order of superior channel conditions; Determining, by the base station, an active beam link based on information reported from the terminal; And an optimal beam control step of causing the base station to inform the terminal of information on the determined active beam link so that the terminal uses the active beam link as an optimal beam link for communication with the base station.

Preferably, in the reporting step and the optimum beam control step, the terminal and the base station can report and notify information by including the information in a specific header that is processed first in a packet transmitted to the counterpart.

According to a fourth aspect of the present invention, there is provided a terminal device in a MIMO communication system, which uses a part of antenna beams as an optimal beam link with a connection base station, A pre-monitoring unit for pre-monitoring the antenna beam of the neighboring base station using the received signal; A confirmation unit for checking whether a beam link of the antenna beam of the peripheral base station has a specific beam link that is superior to an optimal beam link with the connection base station; A handover request for transmitting the information of the specific beam link to the access point and requesting a handover and a radio resource setting operation for using the specific base station and the specific beam link, And a control unit.

Preferably, the handover control unit performs handover to the neighbor base station under the control of the connection base station, and during the handover, performs the radio resource setting to transmit the available specific beam link To receive data of the communication service delivered by the access point base station.

According to a fifth aspect of the present invention, there is provided a base station handover method performed by a terminal apparatus of a MIMO communication system, which uses a part of antenna beams as an optimal beam link with a connection base station, Monitoring an antenna beam of a peripheral base station using the remaining antenna beams; Checking whether a channel state of a beam link among the antenna beams of the peripheral base station is greater than an optimal beam link with the connection base station; Performing a handover request by transmitting the specific beam link information to the access point and performing a radio resource setting operation for using the specific base station and the specific beam link when the specific beam link exists; And a base station for performing handover to the neighbor base station according to the control of the connection base station, the base station comprising: And receiving the data.

In order to achieve the above object, a base station handover method according to a sixth aspect of the present invention is a method for a base station handover method, in which a terminal using a communication service using an antenna beam of a plurality of antenna beams as an optimal beam link with a connection base station, Pre-monitoring the antenna beam of the neighboring base station using the received signal; Determining whether a channel state of a beam link of the antenna beam of the peripheral base station is greater than an optimal beam link with the connection base station, as a result of the monitoring; The terminal transmits a specific beam link information to the access point and requests a handover and a radio resource setting operation to use the specific base station and the specific beam link at the same time ; Transmitting to the neighbor BS the data of the communication service transmitted to the MS while performing a handover procedure for the neighbor BS to the MS based on the information of the specific beam link; And transmitting, by the peripheral base station, the data of the communicated communication service to the terminal using the specific beam link which is enabled by performing the setting of the radio resource.

Therefore, according to the base station apparatus, the terminal apparatus, the optimal beam switching method, and the base station handover method of the present invention, a new scheme capable of ensuring mobility between beams in the same base station and beam mobility between base stations in a MIMO communication system Technology), the effect of providing the maximum performance without deteriorating the performance of the ultra low-latency service is derived for the mobile terminal.

1 is an exemplary diagram illustrating an example of movement of a terminal in a MIMO communication system to which the present invention is applied.
2 is an exemplary diagram illustrating a configuration of a base station apparatus according to a preferred embodiment of the present invention.
3 is an exemplary diagram illustrating a configuration of a terminal device according to a preferred embodiment of the present invention.
4 and 5 are exemplary diagrams for explaining the flow of an optimum beam switching method according to a preferred embodiment of the present invention.
6 and 7 are exemplary diagrams for explaining a flow of a base station handover method according to a preferred embodiment of the present invention.

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

1 is an exemplary diagram illustrating a MIMO communication system using a plurality of antenna beam-based beamforming techniques to which the present invention is applied.

The MIMO (Multiple Input Multiple Output) technique is a technique that can expect a transmission capacity gain proportional to the number of transmission antennas and the number of reception antennas even if no additional frequency or power is used. And a diversity gain and a multiplexing gain.

For this purpose, beamforming techniques used in MIMO communication systems are divided into digital beamforming, analog beamforming, and hybrid beamforming.

In the case of digital beamforming, the number of beams that can be formed is determined by the number of RF chains, and a plurality of beams formed by digital beamforming improves the diversity of the receiving end to improve the signal to interference ratio (SINR) ), And can also be used for multiplexing to separate multiple receivers into different beams, each receiving a different signal.

On the other hand, in the case of the analog beamforming, a plurality of beams formed by the analog beamforming can be used only as means for improving the diversity of the receiving end and increasing the signal quality (SINR).

As a result, in the MIMO communication system, due to the disadvantages of the digital beamforming technique in which an RF chain is required for the number of antennas and the installation cost is increased as described above and the analog beamforming technique in which the performance gain is limited, Beam forming technique is mainly used.

Hereinafter, the present invention will be described with reference to a hybrid beam forming technique.

1, a MIMO communication system using a plurality of antenna beam-based beamforming techniques to which the present invention is applied will be referred to as a mobile communication system for transmitting and receiving signals between a base station and terminals. Hereinafter, the base station 100 refers to each of the base stations 100A, 100B,... Shown in FIG. 1, and the base station 100A and the base station 100B will be referred to when necessary.

Therefore, the base station 100 includes a plurality of antennas, and can form a plurality of antenna beams through the antenna, thereby transmitting and receiving beamformed signals in different directions.

Also, the terminal 100 may also include a plurality of antennas, through which a plurality of antenna beams may be formed to transmit and receive beamformed signals in different directions.

Accordingly, in the MIMO communication system, an optimal beam link (beam pair) having the best channel environment is formed between the antenna beams in various directions / shapes in which the base station 100 can be formed and the antenna beams in various directions / ), And communicates using this optimum beam link.

For example, as shown in FIG. 1, when the base station 100 forms a plurality of antenna beams # A1, # A2 ... and the terminal 200 transmits a plurality of antenna beams UE # 1, # UE # 2 ...), when the terminal 200 is located in the cell A of the base station 100A, a plurality of antenna beams (# A1, # A2 ...) and a plurality of antenna beams UE # 1 , The UE 100 performs beam tracking for finding an optimal beam link having the best channel environment between the base station 100A and the UE 200 and the optimal beam pair For example, # A2-UE # 2.

On the other hand, the terminal 200 can use the communication service while moving on a moving vehicle (e.g., a train, an automobile, etc.) while moving.

In this case, in the MIMO communication system, the channel environment between the base station 100A and the UE 200 is changed, and the optimal beam link # A2-UE # 2 found earlier is no longer valid.

In this case, the terminal 200 must quickly find and move (hand over) the optimal beam link according to the movement position, for example, the optimal beam link with another optimal beam link in the same base station 100A or with another base station (e.g., 100B) A situation arises.

In the 5G that has been discussed so far, a method for searching for an optimal beam link in a base station, a beam having a sequence of steps such as TX beam sweeping at the base station, RX beam sweeping at the end of the terminal, Tracking is used, and a separate scheme is not proposed for a situation in which handover is required to quickly find another optimal beam link in the same base station (hereinafter referred to as optimal beam switching during movement).

Conventionally, when the terminal 200 moves by a predetermined distance d1 as shown in FIG. 1, when the optimal beam link (# A2-UE # 2) is no longer valid, beam tracking is performed Another optimal beam link in the same base station 100A is found.

In this case, since the moving position of the terminal 200 rapidly changes while the beam tracking is performed and a certain amount of time is required until the optimum beam link is found, the optimal beam link is adaptively used in accordance with the movement, There is a limit to using seamlessly.

In addition, in the 5G that has been discussed so far, although a terminal has a MIMO structure characteristic of forming a plurality of antenna beams, a situation in which such a MIMO structure feature must be handed over to an optimal beam link with another base station The base station handover during the movement).

1, when the terminal 200 moves by a predetermined distance d2 and the optimal beam link (# A2-UE # 2) is no longer valid, only at this point in time, And performs beam tracking with another base station 100B as an over-target to find an optimal beam link in the target base station 100B.

In this case, since the moving position of the terminal 200 rapidly changes while the beam tracking is performed and a certain amount of time is required until the optimum beam link is found, the optimal beam link is adaptively used in accordance with the movement, There is a limit to use seamlessly.

As a result, in the future 5G that is aiming at ultra low-latency service, there is a need for a technology that allows the mobile terminal to seamlessly utilize the communication service using the optimal beam link adaptively according to the movement.

Accordingly, the present invention proposes a technique for ensuring mobility between beams in the same base station and beam mobility between base stations in a MIMO communication system.

Hereinafter, a new scheme proposed by the present invention will be described with reference to FIG. 2. More specifically, a scheme for ensuring mobility between beams in the same base station, which is fast and seamless, (hereinafter referred to as an optimal beam switching scheme) will be described.

The optimal beam switching method proposed by the present invention is realized by interlocking between a base station and a terminal, but since the role of a base station is relatively important, a base station will be described as a core.

As shown in FIG. 2, the base station 100 according to the present invention is configured to receive, from a terminal measuring channel conditions of each beam link formed for each of multiple antenna beams of the base station 100, A beam determining unit 120 for determining an active beam link for the mobile station based on information reported from the mobile station, And an optimal beam controller 130 for notifying the terminal of information on the active beam link and causing the terminal to use the active beam link as an optimal beam link for communication with the base station.

Hereinafter, for convenience of explanation, the base station apparatus 100 shown in FIG. 2 will be described as a base station 100A in FIG.

Therefore, it is assumed that the base station apparatus 100 and the terminal 200 use the communication service using the optimal beam link (# A2-UE # 2) found through the beam tracking performed previously.

On the other hand, if the multi-beam is supported when the communication service is used, the communication between the base station 100 and the terminal 200 may be performed by simultaneously using two or more optimal beam links. In this case, the beam determining unit 120, which will be described later, will determine two or more beam links as active beam links.

Hereinafter, for convenience of explanation, it is assumed that one optimal beam link is used.

The report information hold unit 110 detects the channel state of each beam link formed for each of the multiple antenna beams (# A1, # A2 ...) of the base station apparatus 100 from the terminal 200 And receives and reports information on a predetermined number of beam links according to the order.

More specifically, the base station apparatus 100 can measure a channel state for each of multiple antenna beams (# A1, # A2, ...) for a period defined by a predefined period of time, for example, 5 ms (E.g., Beam Reference Signal, Beam Refinement RS).

Therefore, the terminals located in the cell A of the base station apparatus 100 receive (receive) the multiple antenna beams # A1, # A2 ... from the base station apparatus 100 every predetermined period (e.g., 5 ms) (RSRP) of the reference signal (e.g., BRS, or BRRS) to be measured.

The terminal 200 includes a plurality of antenna beams (# A1) received through the plurality of antenna beams (UE # 1, # UE # 2 ...) formed by the terminal 200, , # A2 ...) of the base station apparatus 100 by measuring the signal reception strength (RSRP) of the reference signal (e.g., # 2, ..., (Or channel environment) of each beam link (beam pair) formed as a pair between the multiple antenna beams UE # 1, # UE # 2, ... of the mobile station UE # 1.

The terminal 200 measures the channel state of each beam link formed for each of the multiple antenna beams # A1 and # A2 ... of the base station apparatus 100. As a result, (N) beam links to the base station apparatus 100 periodically.

At this time, the predetermined number (N) can be predetermined by the base station apparatus 100 or can be predetermined by the terminal 200 itself.

Hereinafter, for the sake of convenience of explanation, three N pieces will be described.

The report information hold unit 110 receives the channel status information from the terminal 200 measuring the channel status of each beam link formed for the multiple antenna beams # A1 and # A2 ... of the base station apparatus 100, Can receive and report information on a predetermined number, for example, three beam links in good order.

Here, the report information hold unit 110 can recognize and receive information on a predetermined number of beam links included in a specific header in an uplink packet when processing the uplink packet from the terminal 200.

More specifically, in the present invention, a field for reporting information to the base station, a so-called Beam Indicator field (hereinafter, BI field) can be additionally defined in a specific header in an uplink packet transmitted from the terminal.

In particular, it is preferable that a specific header is a header of an L (Layer) 2 level that is processed first in a receiving end (base station) at the time of uplink packet processing.

Accordingly, if there is information to be reported, the terminal 200 transmits information to the BI field in the L2 header of the uplink packet when the uplink packet is transmitted to the base station apparatus 100, without any signaling for reporting information on the beam link Information on the beam link can be periodically reported to the base station apparatus 100 in a manner of recording and transmitting the information.

Accordingly, the report information hold unit 110 recognizes information on a predetermined number, for example, three beam links, in the BI field in the L2 header that is to be processed first in the processing of the uplink packet from the terminal 200, Can receive.

At this time, the information on the three beam links reported from the terminal 200 will include the information of the optimal beam link (# A2-UE # 2) currently used for the communication service.

The beam determining unit 120 determines an active beam link for the terminal 200 based on information reported from the terminal 200. [

For example, the beam determining unit 120 determines a beam link having a better channel condition than the current optimal beam link (# A2-UE # 2) based on the information on the three beam links reported from the terminal 200 And if there is a specific beam link, it can be determined as an active beam link to the terminal 200. [

Of course, if there is no specific beam link having a better channel condition than the current optimal beam link (# A2-UE # 2), the beam determining unit 120 transmits the current optimal beam link (# A2- Lt; RTI ID = 0.0 > beamlink < / RTI >

The optimal beam control unit 130 notifies the terminal 200 of information on the active beam link determined by the beam determining unit 120 and determines whether or not the active beam link is optimal for communication with the base station apparatus 100 Be used as a beam link.

For example, as shown in FIG. 1, when the UE 200 moves by a predetermined distance d1, a specific beam link (for example, # A1-UE # 1) is generated and the current optimal beam link (# A2-UE # 2) is no longer valid.

Assuming that there is a specific beam link (# A1-UE # 1) having a channel state superior to the current optimal beam link (# A2-UE # 2), the optimal beam control unit (130) Notifies the terminal 200 of the information about the link (# A1-UE # 1) and informs the terminal 200 of the optimum beam link used for the communication service from the current beam link (# A2-UE # 2) (Handover) to the active beam link (# A1-UE # 1) notified this time.

Here, the optimum beam control unit 130 may include information on the active beam link in a specific header in the downlink packet transmitted to the terminal 200, and notify the terminal 200 of the information.

More specifically, in the present invention, a bitmap indicating which beam link among active beam links among a base station and a terminal can be newly defined in a specific header in a downlink packet transmitted to a terminal .

Particularly, it is preferable that the specific header is a header of L (Layer) 2 level that is processed first in the receiving end (terminal) at the time of downlink packet processing.

More specifically, the aforementioned Bitmap can be defined in the MAC Control Element field in the L2 header.

Accordingly, the base station apparatus 100, in particular, the optimum beam control unit 130, transmits down-packet to the terminal 200 without any signaling for information notification of the active beam link, And informs the terminal 200 of information on the currently determined active beam link.

That is, assuming that there is a specific beam link (# A1-UE # 1) having better channel conditions than the current optimal beam link (# A2-UE # 2), the optimum beam control unit In the bitmap defined in the MAC CE field in the packet L2 header, the beam link (# A2-UE # 2) which was the previous (current) active beam link is deactivated and the beam link And then transmits the information on the active beam link to the terminal 200. In this case,

In this case, the terminal 200 looks at the bitmap defined in the MAC CE field in the L2 header that is to be processed first in downlink packet processing from the base station apparatus 100, and determines which beam link is notified to be an active beam link It can be recognized.

That is, the terminal 200 moves the optimal beam link used for the communication service from the current beam link (# A2-UE # 2) to the active beam link (# A1-UE # 1) Thereby performing optimum beam switching for moving between beams in the same base station.

On the other hand, if there is no specific beam link having a better channel state than the current optimal beam link (# A2-UE # 2), the optimum beam control unit 130 determines whether the beam link defined in the MAC CE field in the downlink packet L2 header to the terminal 200 In the Bitmap, the beam link (# A2-UE # 2), which is the previous (current) active beam link, will be kept active and unchanged.

In this case, the terminal 200 reports the bitmap defined in the MAC CE field in the L2 header to be processed first in the downlink packet processing from the base station apparatus 100, and transmits the optimal beam link used for the communication service to the current (# A2-UE # 2).

As described above, according to the base station apparatus 100 of the present invention, using L2 level-based reporting and notification in an uplink packet / downlink packet without any additional signal, Over) can be performed quickly. At this time, since there is no change in the base station movement (handover) in the same base station, the communication service of the terminal will be guaranteed seamlessly.

According to the present invention, as shown in FIG. 1, when a situation occurs in which the terminal 200 moves by a predetermined distance d1 and quickly moves to another optimal beam link in the same base station (handover) It is possible to guarantee the mobility between beams in the same base station, which is fast and seamless.

Hereinafter, a new scheme proposed by the present invention will be described with reference to FIG. 3, and more specifically, a scheme for ensuring beam mobility between base stations that is fast and seamless (hereinafter referred to as a base station handover method) will be described.

The base station handover method proposed by the present invention is realized by interworking between a base station and a terminal, but since the role of the terminal is relatively important, the terminal will be described as a core.

3, a terminal apparatus 200 according to the present invention uses a part of antenna beams as an optimal beam link with a connection base station to use a communication service, A pre-monitoring unit (210) for pre-monitoring the antenna beam of the base station, and a monitoring unit (210) for monitoring whether the beam status of the beam link of the peripheral base station is higher than that of the optimal beam link (220) for transmitting the specific beam link information to the access point (200), and for transmitting the information of the specific beam link to the access point And a handover control unit 230 for simultaneously performing the handover operation.

Hereinafter, for convenience of explanation, the terminal device 200 shown in FIG. 3 will be described as the terminal 200 shown in FIG.

It is assumed that the base station 100A and the peripheral base station are the base station 100B and the base station 100A and the terminal device 200 respectively assume that the optimum beam It is assumed that the communication service is used by using the link (# A2-UE # 2).

The preliminary monitoring unit 210 uses a part of the multiple antenna beams UE # 1 and # UE # 2 ... as the optimal beam link with the connection base station 100A, And pre-monitors the antenna beam of the neighbor base station 100B using the beam.

That is, the proactive monitoring unit 210 determines whether or not the terminal apparatus 200 receives some antenna beams UE # 2 among the multiple antenna beams UE # 1 and # UE # The antenna beam of the peripheral base station 100B is proactively monitored using the remaining antenna beams UE # 1 and # UE # 3 ... while using the communication service using the beam links # A2 to UE # 2 .

More specifically, the neighbor base station 100B can measure the channel state for each of the multiple antenna beams (# B1, # B2, ...) for each period defined by a predefined period of time, for example, 5 ms (E.g., BRS, or BRRS) to be transmitted.

Therefore, the terminal apparatus 200, particularly the proactive monitoring unit 210, uses the remaining antenna beams UE # 1 and # UE # 3 ... which are not used for communication with the connection base station 100A, By measuring the signal reception strength (RSRP) of the reference signals (e.g., BRS or BRRS) of the multiple antenna beams (# B1, # B2 ...) of the peripheral base station 100B, (Or a pair of beam links) formed in pairs between the first antenna beams # B1, # B2, ... and their remaining antenna beams UE # 1, # UE # Channel environment) can be monitored (measured).

As described above, in the present invention, the terminal apparatus 200 can pre-monitor the beam link channel state with the antenna beam of the peripheral base station 100B, that is, the peripheral base station 100B, while using the communication service through the connection base station 100A The reason for this is that the terminal device 200 has a MIMO structure feature capable of transmitting and receiving a beamformed signal in a plurality of directions with a plurality of antennas.

The confirmation unit 220 determines that the channel status of the beam link among the antenna beams # B1 and # B2 ... of the neighbor base station 100B as a result of the monitoring described above is the optimal beam link # A2- RTI ID = 0.0 > UE # 2). ≪ / RTI >

For example, as shown in FIG. 1, when the UE 200 moves by a certain distance d2, a specific beam link (for example, # B1-UE # 3) is generated and the current optimal beam link (# A2-UE # 2) is no longer valid.

In this case, the confirmation unit 220 transmits the beam link (# B1-UE # 3) with the neighbor base station 100B to the channel state (# 2-UE # Will be identified by an excellent specific beam link.

The handover control unit 230 transmits the information of the specific beam link (# B1-UE # 3) to the access terminal 100A when there is the specific beam link (# B1-UE # 3) And a radio resource setting operation for using the peripheral base station 100B and the specific beam link (# B1-UE # 3) simultaneously.

More specifically, if there is a specific beam link (# B1-UE # 3) to be a target of inter-base-station handover, the handover control unit 230 transmits information To the connection base station 100A and performs a general operation for requesting a handover.

At this time, the handover control unit 230 performs a general operation for requesting a handover to the access point 100A, and transmits an RRC Connection Reconfiguration message to the neighbor base station 100B to transmit the specific beam link (# B1- (E.g., RRC setting) operation for using the UE # 3 or the UE # 3 separately or independently.

In this case, in the case of the access point 100A, based on the information of the specific beam link (# B1-UE # 3), a handover procedure to the peripheral base station 100B for the terminal 200 is performed, To the peripheral base station 100B.

That is, when the neighbor base station 100B requests the handover of the terminal 200 from the neighbor base station 100B and receives a handover response (Acknowledge) from the neighbor base station 100B, ) To the neighbor base station 100B by the handover procedure.

In this process, when data of a communication service transmitted from the core network (not shown) to the terminal 200 is received, the connection base station 100A transmits the data to the peripheral base station 100B, To be seamless.

Accordingly, the handover control unit 230 performs handover to the neighboring base station 100B under the control of the connection base station 100A.

Here, since the handover controller 230 has already performed radio resource setting (e.g., RRC setting) for using the specific beam link (# B1-UE # 3) from the neighbor base station 100B, The base station 100A can receive the data of the communication service forwarded by the connection base station 100A using the specific beam link (# B1-UE # 3) during the handover to the base station 100A.

That is, the terminal apparatus 200 transmits the data of the communication service using the optimal beam link (# A2-UE # 2) of the connection base station 100A during the handover to the peripheral base station 100B, And seamlessly receives the data of the communication service using the target (specific) beam link (# B1-UE # 3) of the base station 100B.

As described above, according to the terminal device 200 of the present invention, by using the antenna beam proactive monitoring / radio resource setting function of the neighbor base station utilizing the MIMO structure characteristic of the terminal device 200, (Handover) can be quickly performed without interruption of the communication service.

According to the present invention, even when a situation occurs in which the terminal 200 is moved by a predetermined distance d2 as shown in FIG. 1 and the optimum beam link of another base station is quickly located (handed over) , Beam mobility between the fast and seamless base stations can be guaranteed.

Accordingly, the present invention realizes a new scheme capable of ensuring mobility between beams in the same base station, and beam mobility between base stations in a MIMO communication system, which is fast and seamless, and thereby achieving maximum performance without degrading the ultra low delay service Thereby providing an effect to be provided.

Referring to FIGS. 4 and 5, an optimal beam switching method according to a preferred embodiment of the present invention will be described. Here, for convenience of explanation, reference numerals shown in FIG. 1 will be referred to.

First, the process of performing the optimum beam switching method of the present invention will be briefly described from the viewpoint of a system, with reference to FIG.

Beam tracking is performed between the base station 100 or 100A and the terminal 200 by a series of steps including TX beam sweeping, RX beam sweeping, and optimal beam selection based on the sweeping, The communication service can be used by using the beam link (# A2-UE # 2) (S20).

The terminal 200 transmits a reference signal (for example, BRS (# 1, # 2 ...)) for each of the multiple antenna beams (# A1, # A2 ...) received via the multiple antenna beams # A2, ...) of the base station 100 and its own multiple antenna beams UE # 1, # UE # 2, ..., by measuring the signal reception strength (RSRP) (Or a channel environment) of each beam link (beam pair) formed as a pair between adjacent beam links (or beam pairs) (S30).

The terminal 200 measures the channel states of the beam links formed for the multiple antenna beams # A1 and # A2 ... of the base station 100 and finds a predetermined number N) beamlinks to the base station 100 (S40).

At this time, the terminal 200 records information in the BI field in the L2 header of the uplink packet and transmits the uplink packet when transmitting the uplink packet to the base station 100, without signaling for reporting information on the beam link, And may report information on the N beam links to the base station 100. [

The base station 100 can recognize and report information on a predetermined number, for example, three beam links, in the BI field in the L2 header to be processed first in the uplink packet processing from the terminal 200. [

The base station 100 determines an active beam link to the terminal 200 based on information reported from the terminal 200 (S50).

For example, the base station 100 determines whether there is a specific beam link having a better channel state than the current optimal beam link (# A2-UE # 2) based on the information on the three beam links reported from the terminal 200 And if there is a specific beam link, it can determine an active beam link for the terminal 200. [

Hereinafter, for convenience of explanation, it is assumed that there is a specific beam link (# A1-UE # 1) having a better channel state than the current optimum beam link (# A2-UE # 2).

In this case, the base station 100 will determine the specific beam link (# A1-UE # 1) as the active beam link for the terminal 200.

The base station 100 notifies the terminal 200 of information on the active beam link determined in step S50 (S60).

At this time, the base station 100 reflects the bitmap defined in the MAC CE field in the L2 header of the downlink packet when the downlink packet is transmitted to the terminal 200 without signaling for information notification of the active beam link, and transmits , The terminal 200 can be informed of the currently determined active beam link (# A1-UE # 1).

In this case, the terminal 200 checks the bitmap defined in the MAC CE field in the L2 header, which is to be processed first in the downlink packet processing from the base station 100, and determines whether a beam link is notified to make an active beam link can do.

That is, the terminal 200 moves the optimal beam link used for the communication service from the current beam link (# A2-UE # 2) to the active beam link (# A1-UE # 1) The optimal beam switching for moving between the beams in the same base station is performed (S70).

Accordingly, the terminal 200 will use the active beam link (# A1-UE # 1) as an optimal beam link and seamlessly use the communication service (S80) by performing optimal beam switching.

Hereinafter, the optimal beam switching method of the present invention will be described in detail with reference to FIG. 5 in view of a base station.

According to the optimal beam switching method of the present invention, the base station 100 performs beam tracking with the terminal 200 (S100).

That is, the base station 100 performs beam tracking with respect to the terminal 200 in a series of steps, such as TX beam sweeping, RX beam sweeping, and optimal beam selection based thereon, thereby searching for an optimal beam link.

Accordingly, the base station 100 can support the communication service to the terminal 200 using the optimal beam link (# A2-UE # 2) found by performing the beam tracking (S110).

According to the optimum beam switching method of the present invention, the base station 100 measures a channel state of each beam link formed for each of multiple antenna beams # A1, # A2, ... of the base station 100, Information on a predetermined number of beams, for example, three beam links, in an order excellent in channel state is reported (S120).

More specifically, in the present invention, a field for reporting information to the base station, a so-called BI field, can be additionally defined in a specific header in an uplink packet transmitted from the terminal.

In particular, it is preferable that a specific header is a header of an L (Layer) 2 level that is processed first in a receiving end (base station) at the time of uplink packet processing.

Accordingly, if there is information to be reported, the terminal 200 records information in the BI field in the L2 header of the uplink packet when transmitting the uplink packet to the base station 100, without any signaling for reporting information on the beam link And transmit the information on the beam link to the base station 100 periodically.

Therefore, according to the optimum beam switching method of the present invention, the base station 100 transmits information on a predetermined number, for example, three beam links, in the BI field in the L2 header to be processed first in the processing of the uplink packet from the terminal 200 And can receive and report information.

At this time, the information on the three beam links reported from the terminal 200 will include the information of the optimal beam link (# A2-UE # 2) currently used for the communication service.

According to the optimal beam switching method of the present invention, the base station 100 determines an active beam link to the terminal 200 based on information reported from the terminal 200.

For example, according to the optimal beam switching method of the present invention, the base station 100 may determine the current optimal beam link (# A2-UE # 2) based on the information on the three beam links reported from the terminal 200, It is checked whether there is a specific beam link having a better channel state (S130).

For example, as shown in FIG. 1, when the UE 200 moves by a predetermined distance d1, a specific beam link (for example, # A1-UE # 1) is generated and the current optimal beam link (# A2-UE # 2) is no longer valid.

In this case, according to the optimum beam switching method of the present invention, the base station 100 determines that there is a specific beam link (# A1-UE # 1) having a better channel state than the current optimum beam link (# A2- (S130 Yes), the specific beam link (# A1-UE # 1) will be determined as the active beam link for the terminal 200 (S140).

According to the optimal beam switching method of the present invention, the base station 100 notifies the terminal 200 of information on the beam link (# A1-UE # 1) determined as the current active beam link (S150) (Handover) the optimum beam link used for the communication service from the present beam link (# A2-UE # 2) to the active beam link (# A1-UE # 1) .

Here, according to the optimal beam switching method of the present invention, the base station 100 includes information on active beam link in a specific header in a downlink packet transmitted to the terminal 200, and notifies the terminal 200 of information can do.

More specifically, in the present invention, a bitmap indicating which beam link among active beam links among a base station and a terminal can be newly defined in a specific header in a downlink packet transmitted to a terminal .

Particularly, it is preferable that the specific header is a header of L (Layer) 2 level that is processed first in the receiving end (terminal) at the time of downlink packet processing.

More specifically, the aforementioned Bitmap can be defined in the MAC Conrol Element field in the L2 header.

Therefore, according to the optimum beam switching method of the present invention, the base station 100 can transmit the downlink packet to the terminal 200 without any signaling for information notification of the active beam link, It is possible to notify the terminal 200 of information on the currently determined active beam link in such a manner that it is reflected on the Bitmap defined in the CE field.

That is, assuming that there is a specific beam link (# A1-UE # 1) having a better channel state than the current optimal beam link (# A2-UE # 2), the base station 100 transmits the downlink packet L2 (# A2-UE # 2) which is the previous (current) active beam link and the beam link (# A1-UE # 1) determined this time as the active beam link in the Bitmap defined in the MAC CE field in the header It is possible to notify the terminal 200 of information on the current active beam link.

In this case, the terminal 200 checks the bitmap defined in the MAC CE field in the L2 header, which is to be processed first in the downlink packet processing from the base station 100, and determines whether a beam link is notified to make an active beam link can do.

That is, the terminal 200 moves the optimal beam link used for the communication service from the current beam link (# A2-UE # 2) to the active beam link (# A1-UE # 1) Thereby performing optimal beam switching for moving between beams in the same base station (S160).

Accordingly, the terminal 200 will use the active beam link (# A1-UE # 1) as the optimal beam link and seamlessly use the communication service (S170) as the optimal beam switching is performed.

On the other hand, if there is no specific beam link having a better channel state than the current optimal beam link (# A2-UE # 2) (No at S130), the base station 100 sets the MAC CE field in the downlink packet L2 header to the terminal 200 , The beam link (# A2-UE # 2) which is the previous (current) active beam link will be kept active without change (S180).

In this case, the terminal 200 reports the bitmap defined in the MAC CE field in the L2 header to be processed first in the downlink packet processing from the base station 100, and transmits the optimal beam link used for the communication service to the current Beam link (# A2-UE # 2).

6 and 7, a base station handover method according to a preferred embodiment of the present invention will be described. Here, for convenience of explanation, reference numerals shown in FIG. 1 will be referred to.

6 is a flowchart illustrating a base station handover method according to an embodiment of the present invention.

Beam tracking is performed between the terminal 200 and the connection base station 100A at step S200 and the communication service can be used at the optimal beam link # 2-UE # 2 thus found at step S210.

The UE 200 transmits some antenna beams UE # 2 among the multiple antenna beams UE # 1, # UE # 2 ... to the optimal beam link # 2-UE # 2 with the connecting base station 100A, The antenna beam of the peripheral base station 100B is proactively monitored using the remaining antenna beams UE # 1 and # UE # 3 in step S230.

The terminal 200 determines that the channel state of the beam link among the antenna beams # B1, # B2 ... of the neighbor base station 100B as a result of the monitoring described above is the optimal beam link # A2 - UE # 2) (S240).

For example, as shown in FIG. 1, when the UE 200 moves by a certain distance d2, a specific beam link (for example, # B1-UE # 3) is generated and the current optimal beam link (# A2-UE # 2) is no longer valid.

In this case, the UE 200 sets the beam link (# B1-UE # 3) with the neighbor base station 100B to a channel state of the optimal beam link (# A2-UE # 2) We will check with excellent specific beam links.

When there is a specific beam link (# B1-UE # 3) as a result of the checking in step S240, the terminal 200 transmits the information of the specific beam link (# B1-UE # 3) And a radio resource setting operation S255 for using the peripheral base station 100B and the specific beam link (# B1-UE # 3) at the same time.

The serving base station 100A requests the handover of the terminal 200 to the neighbor base station 100B and receives a handover response from the neighbor base station 100B in operation S260, , The mobile station 200 may instruct the handover to the neighbor base station 100B (S265).

In this process, when data of the communication service transmitted from the core network (not shown) to the terminal 200 is received, the connection base station 100A transmits the data to the peripheral base station 100B (S270) , And to provide seamless communication services.

Meanwhile, the terminal 200 performs handover to the neighboring base station 100B according to the control (command) of the connected base station 100A in step S265 (S280).

At this time, since the terminal 200 has already performed the radio resource setting (e.g., RRC setting) for using the specific beam link (# B1-UE # 3) with the neighbor base station 100B (S255) It is possible to receive the data of the communication service forwarded by the connection base station 100A using the specific beam link (# B1-UE # 3) during handover to the base station 100B (S280) Continuity of communication service is maintained.

After completing the handover to the neighbor base station 100B, the terminal 200 will continue to use the communication service using the optimal beam link (# B1-UE # 3) with the neighbor base station 100B S290).

Hereinafter, a base station handover method of the present invention will be described in detail with reference to FIG. 7 from the viewpoint of a terminal.

According to the base station handover method of the present invention, the UE 200 performs beam tracking with a series of steps including TX beam sweeping, RX beam sweeping with the connecting base station 100A, and optimum beam selecting based on the sweeping , The optimum beam link is searched (S300)

Accordingly, the terminal 200 can use the communication service through the access point 100A using the optimal beam link (# A2-UE # 2) found by performing beam tracking (S310).

In this case, according to the base station handover method of the present invention, the terminal 200 transmits some antenna beams UE # 2 among its multiple antenna beams UE # 1, # UE # ... of the neighbor base station 100B using the remaining antenna beams UE # 1, # UE # 3 ... while using the communication service using the optimal beam link (# A2-UE # 2) (S320).

More specifically, the neighbor base station 100B can measure the channel state for each of the multiple antenna beams (# B1, # B2, ...) for each period defined by a predefined period of time, for example, 5 ms (E.g., BRS, or BRRS) to be transmitted.

Accordingly, the terminal 200 uses the remaining antenna beams UE # 1 and # UE # 3 ... that are not used for communication with the connection base station 100A, (# B1, # B2, ...) of the peripheral base station 100B by measuring the signal receiving strength (RSRP) of the reference signals (e.g., BRS or BRRS) (Or channel environment) of each beam link (beam pair) formed as a pair between the base station antenna # 1 and its remaining antenna beams UE # 1, # UE # can do.

As described above, in the present invention, the reason that the terminal 200 can proactively monitor the beam link channel state with the antenna beam of the peripheral base station 100B, that is, the peripheral base station 100B, while using the communication service through the connection base station 100A Is a characteristic feature of the MIMO structure in which the terminal 200 includes a plurality of antennas and can transmit and receive a beamformed signal in various directions.

According to the base station handover method of the present invention, the terminal 200 monitors the channel status of the beam link among the antenna beams # B1, # B2, ... of the neighbor base station 100B as a result of the monitoring, And confirms whether there is a specific beam link that is superior to the optimal beam link (# A2-UE # 2) in step S330.

For example, as shown in FIG. 1, when the UE 200 moves by a certain distance d2, a specific beam link (for example, # B1-UE # 3) is generated and the current optimal beam link (# A2-UE # 2) is no longer valid.

In this case, the UE 200 sets the beam link (# B1-UE # 3) with the neighbor base station 100B to a channel state of the optimal beam link (# A2-UE # 2) We will check with a good specific beam link (S330 Yes).

According to the base station handover method of the present invention, when there is a specific beam link (# B1-UE # 3), the terminal 200 transmits information of the specific beam link (# B1- And a radio resource setting operation for using the specific base station 100B and the specific beam link (# B1-UE # 3) at step S340.

More specifically, when there is a specific beam link (# B1-UE # 3) that is a target of inter-base station handover, the terminal 200 transmits information of the specific beam link (# B1-UE # 3) To the base station 100A, and performs a general operation for requesting a handover.

At this time, the UE 200 performs a general operation for requesting handover to the access point 100A, and transmits an RRC Connection Reconfiguration message to the neighbor base station 100B to transmit the specific beam link (# B1-UE # 3) to perform radio resource setting (e.g., RRC setting) operations separately or independently.

In this case, in the case of the access point 100A, based on the information of the specific beam link (# B1-UE # 3), a handover procedure to the peripheral base station 100B for the terminal 200 is performed, To the peripheral base station 100B.

That is, when the neighbor base station 100B requests the handover of the terminal 200 from the neighbor base station 100B and receives a handover response (Acknowledge) from the neighbor base station 100B, ) To the neighbor base station 100B by the handover procedure.

In this process, when data of a communication service transmitted from the core network (not shown) to the terminal 200 is received, the connection base station 100A transmits the data to the peripheral base station 100B, To be seamless.

Accordingly, according to the base station handover method of the present invention, the terminal 200 performs handover to the neighboring base station 100B under control of the connection base station 100A (S350).

Since the terminal 200 has already performed a radio resource setting (e.g., RRC setting) for using the specific beam link (# B1-UE # 3) from the neighbor base station 100B, The base station 100A can receive the data of the communication service forwarded by the connection base station 100A using the specific beam link (# B1-UE # 3) during the handover to the base station 100A.

That is, during the handover to the neighbor base station 100B, the terminal 200 transmits data of the communication service using the optimal beam link (# A2-UE # 2) of the connection base station 100A, (Seamless) reception of data of the communication service using the target (specific) beam link (# B1-UE # 3) of the base station 100B.

After completing the handover to the neighbor base station 100B, the terminal 200 will continue to use the communication service using the optimal beam link (# B1-UE # 3) with the neighbor base station 100B S360).

As described above, according to the present invention, by implementing a new scheme capable of guaranteeing mobility between beams in the same base station and beam mobility between base stations in a MIMO communication system, it is possible to improve the performance The effect of providing the maximum performance without degradation is derived.

The optimal beam switching method and base station handover method according to an embodiment of the present invention can be implemented in a form of a program command that can be executed through various computer means and recorded in a computer readable medium. The computer-readable medium may include program instructions, data files, data structures, and the like, alone or in combination. The program instructions recorded on the medium may be those specially designed and constructed for the present invention or may be available to those skilled in the art of computer software. Examples of computer-readable media include magnetic media such as hard disks, floppy disks, and magnetic tape; optical media such as CD-ROMs and DVDs; magnetic media such as floppy disks; Magneto-optical media, and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions include machine language code such as those produced by a compiler, as well as high-level language code that can be executed by a computer using an interpreter or the like. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

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 exemplary embodiments, but, on the contrary, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

According to the base station apparatus and the terminal apparatus, the optimal beam switching method and the base station handover method according to the present invention, a new scheme capable of ensuring mobility between beams in the same base station and beam mobility between base stations in a MIMO communication system, ), It is possible to carry out not only the use of the related technology but also the possibility of commercialization or sales of the applied device as it is beyond the limit of the existing technology, It is an invention.

100: base station device
110: report information hold unit 120: beam determining unit
130: Optimum beam control unit
200: terminal device
210: pre-monitoring unit 220:
230: handover control unit

Claims (14)

A base station apparatus in a MIMO communication system,
A report unit for reporting information on a predetermined number of beam links in order of channel state from a terminal measuring a channel state of each beam link formed for each of multiple antenna beams of the base station apparatus;
A beam determining unit for determining an active beam link for the terminal based on information reported from the terminal; And
And notifies the terminal of information on the determined active beam link, and causes the terminal to use the active beam link as an optimal beam link for communication with the base station. The method according to claim 1,
The reporting information,
And receives information on the predetermined number of beam links included in a specific header in the uplink packet when the uplink packet processing is performed from the terminal. The method according to claim 1,
Wherein the optimum beam control unit comprises:
And notifies information to the mobile station by including information on the active beam link in a specific header in a downlink packet transmitted to the mobile station. The method according to claim 2 or 3,
The specific header includes:
(L) 2 level header that is processed first in the uplink packet or the downlink packet processing. The method according to claim 1,
Wherein the beam determining unit comprises:
And the specific beam link is determined to be an active beam link when there is a specific beam link having a better channel state than a current optimal beam link used for communication with the terminal based on information reported from the terminal . In an optimal beam switching method performed by a base station of a MIMO communication system,
Receiving report information on a predetermined number of beam links in order of superior channel state from a terminal measuring a channel state of each beam link formed for each of multiple antenna beams of the base station apparatus;
A beam determining step of determining an active beam link for the terminal based on information reported from the terminal; And
And notifying the terminal of information on the determined active beam link so that the terminal uses the active beam link as an optimal beam link for communication with the base station. Switching method. The method according to claim 6,
In the step of reporting information,
When the uplink packet is processed from the terminal, the header is reported from the specific header in the uplink packet,
Wherein the information of the optimum beam control step comprises:
In a specific header in a downlink packet transmitted to the terminal. 8. The method of claim 7,
The specific header includes:
Level header of the uplink packet or the L2 level header processed first in the downlink packet processing. The terminal measuring a channel state of each beam link formed for each of multiple antenna beams of the base station;
A reporting step of reporting information on a predetermined number of beam links to the base station in the order of superior channel conditions;
Determining, by the base station, an active beam link based on information reported from the terminal; And
The base station notifies the terminal of information on the determined active beam link and causes the terminal to use the active beam link as an optimal beam link for communication with the base station. / RTI > 10. The method of claim 9,
In the reporting step and the optimum beam control step,
Wherein the terminal and the base station include information in a specific header to be processed first in a packet transmitted to a counterpart and report and report the information. A terminal apparatus in a MIMO communication system,
A preliminary monitoring unit for preliminarily monitoring an antenna beam of a peripheral base station using the remaining antenna beams while using some of the multiple antenna beams as an optimal beam link with the connection base station;
A confirmation unit for checking whether a beam link of the antenna beam of the peripheral base station has a specific beam link that is superior to an optimal beam link with the connection base station;
A handover request for transmitting the information of the specific beam link to the access point and requesting a handover and a radio resource setting operation for using the specific base station and the specific beam link, And a control unit. 12. The method of claim 11,
The handover control unit includes:
Performs handover to the neighbor BS according to the control of the connection BS,
Wherein during the handover, the terminal apparatus receives the data of the communication service transmitted by the access point using the specific beam link that is enabled by setting the radio resource. A base station handover method performed by a terminal apparatus of a MIMO communication system,
Monitoring an antenna beam of a peripheral base station using a remaining antenna beam while using a part of the multiple antenna beams as an optimal beam link with a connection base station;
Checking whether a channel state of a beam link among the antenna beams of the peripheral base station is greater than an optimal beam link with the connection base station;
Performing a handover request by transmitting the specific beam link information to the access point and performing a radio resource setting operation for using the specific base station and the specific beam link when the specific beam link exists; And
Wherein the handover to the neighboring base station is performed according to the control of the connection base station, the handover of the communication service carried out by the connection base station by using the specific beam link, Wherein the base station handover method comprises the steps of: Monitoring a preamble of an antenna beam of a neighbor base station using a remaining antenna beam using a part of the multiple antenna beams as an optimal beam link with a connection base station and using a communication service;
Determining whether a channel state of a beam link of the antenna beam of the peripheral base station is greater than an optimal beam link with the connection base station, as a result of the monitoring;
The terminal transmits a specific beam link information to the access point and requests a handover and a radio resource setting operation to use the specific base station and the specific beam link at the same time ;
Transmitting to the neighbor BS the data of the communication service transmitted to the MS while performing a handover procedure for the neighbor BS to the MS based on the information of the specific beam link; And
And transmitting, by the neighboring base station, the data of the communicated communication service to the terminal using the specific beam link that is enabled by performing the setting of the radio resource.

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