KR101973948B1 - Terminal and basestation, dual connectivity operating method and dual connectivity control method thereof - Google Patents

Abstract

In managing a secondary node (SN) of a non-standalone terminal using a communication service based on mutual interworking between different heterogeneous networks, a concrete / optimal scheme for minimizing the control of the MN (Master Node) ).

Description

TECHNICAL FIELD [0001] The present invention relates to a terminal apparatus and a base station apparatus, a dual connection operation method, and a dual connection control method for the apparatus, a dual connection operation method,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a non-standalone technology using communication services based on mutual interworking between different types of networks, and more particularly to a non-standalone technology for managing a secondary node of a non- will be.

In accordance with the development of mobile communication networks for mass data / high-speed transmission, a mobile communication network environment aiming at ultra low latency (URLLC: Ultra Reliable & Low Latency Communication) service based on close data transmission / 5G) environment.

5G allows for a very short level of data transmission (transmission and reception) delays to provide very low delay services, and a relatively long level of control information transmission (for example, 10 ms) Transmission and reception) delays.

On the other hand, studies are underway to develop and develop the 5G system while increasing the cost efficiency by utilizing the 4G systems that have already been widely used and built at the present time, which is developing as 5G.

One of the results of this research is a non-standalone technology that uses communication services based on interworking between different 4G and 5G networks.

Non-Standalone technology uses 4G (LTE) as a primary network to ensure seamless coverage, while using 5G as a secondary network, it transmits / receives data with higher capacity / lower latency. It supports interworking between 4G and 5G networks Based communication service.

Accordingly, a terminal operating in a non-standalone state accesses a 4G network as a primary and a 5G network as a secondary in a network initial connection.

At this time, the 4G base station connected to the 4G network, which is the primary node, is called the master node, and the 5G base node connecting the terminal to be connected to the secondary 5G network is called the secondary node.

On the other hand, a technology in which a terminal accesses two or more different base stations (Master / Secondary) and uses a communication service is referred to as a Dual Connectivity (hereinafter referred to as DC) technology.

In other words, in order to use communication service by using 4G as a primary network and using 5G as a secondary network, a non-standalone terminal operates DC technology to access both a 4G base station as a master node and a 5G base station as a secondary node .

In the current DC technology, a method in which a terminal additionally connects to a secondary node is a method in which a connection procedure between a terminal and a secondary node proceeds under the control of a master node to which the terminal is connected.

On the other hand, considering the environment in which 5G is gradually evolving / developing in the future, DC technology between 4G and 5G is discussed in the direction of minimizing the control of the master node in managing the secondary node of the terminal, The plan is not presented.

Therefore, in the present invention, a concrete / optimal implementation method meeting the requirement of minimizing the control of the master node in the secondary node management of the terminal, such as a procedure in which the terminal additionally connects to the secondary node, is newly proposed.

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 and apparatus for managing a secondary node in a terminal, such as a procedure in which a terminal operating in a non- (Technology) that minimizes the number of users.

According to a first aspect of the present invention, there is provided a terminal device for transmitting measurement information of a second access device for additional connection in a state of being connected to a first network through a connection with a first access device, A measurement information reporting unit for transmitting the measurement information to the access device; And means for, upon receipt of a message from the first access device to connect to the second access device, sending a message to the first access device for the message if the second access device is a device of a second network different from the first network And a connection performing unit for performing a random access to set up a connection with the second access device without response response.

Preferably, the connection performing unit is configured to perform, based on the type information of the random access to be performed with the second access device, which is confirmed in the message only when the second access device is the device of the second network, It is possible to perform random access with the access device.

Preferably, when the connection with the second access device is established, the wireless environment information measured for the second access device is transmitted to the second access device, and the wireless environment information transmitted from the first access device to the terminal device And a radio environment information transmitting unit for transmitting radio environment information of the second access device used for scheduling of downlink data traffic to the first access device by the second access device.

Preferably, when the connection with the second access device is established, the radio environment information transmitter may include the radio environment information in a response message in response to the message received from the first access device, To the second access device.

Preferably, the measurement information reporting unit may transmit the measurement information of the specific second access device for switching the additional connection to the second access device during the dual connection operation in a state of being connected to the first access device and the second access device, And to cause the connection switching procedure between the second access device and the specific second access device to proceed under the control of the second access device without involvement of the first access device.

In order to achieve the above object, a base station apparatus according to a second aspect of the present invention includes: a connection setting unit configured to establish a connection with a specific access device when measurement information of a specific access device for additional connection from the connected terminal is received; A confirmation unit for checking whether the specific access device is a device of a specific network different from the base station device; And a control unit for controlling an additional connection between the terminal and the specific access device in a different procedure depending on whether or not the specific access device is a device of the specific network.

Preferably, when the specific access device is the device of the specific network, the control section may further include random access type information in a message to be transmitted to the terminal so as to be connected to the specific access device, To perform a random access to establish a connection with the specific access device, without a response to the base station device for the message, due to the random access type information included in the random access type information.

Preferably, the specific network may be a network capable of supporting a specific communication service of Ultra Reliable & Low Latency Communication (URLLC) compared to the network of the base station apparatus.

According to a third aspect of the present invention, there is provided a dual connection operation method for a terminal device, comprising: a first access device connected to a first network, A measurement information reporting step of transmitting information to the first access device; And when receiving a message from the first access device to connect to the second access device, if the second access device is a device of a second network other than the first network, And performing a random access to set up a connection with the second access device without responding to the request.

Preferably, the connection performing step includes a step of, in accordance with the type information of the random access to be performed with the second access device, which is confirmed in the message only when the second access device is the device of the second network, 2 random access with the access device.

Preferably, when the connection with the second access device is established, the wireless environment information measured for the second access device is transmitted to the second access device, and the wireless environment information transmitted from the first access device to the terminal device The radio environment information of the second access device used in scheduling the downlink data traffic may be transmitted by the second access device to the first access device.

Preferably, the method further comprises transmitting measurement information of a specific second access device to change the connection to the second access device during a dual connection operation in a state of being connected to the first access device and the second access device can do.

According to a fourth aspect of the present invention for achieving the above object, there is provided a dual connection control method for a base station apparatus, comprising the steps of: when receiving measurement information of a specific access device for additional connection from a connected terminal, ; A confirming step of confirming whether the specific access device is a device of a specific network different from the base station device; And controlling the additional connection between the terminal and the specific access device in a different procedure depending on whether or not the specific access device is a device of the specific network.

Preferably, when the specific access device is the device of the specific network, the control step may further include random access type information in a message to be transmitted to the terminal so as to be connected to the specific access device, The random access type information included in the message makes it possible to perform a random access setting connection with the specific access device without a response to the base station device for the message.

According to the terminal apparatus, the base station apparatus, the dual connection operation method and the dual connection control method of the present invention, in the secondary node management of the terminal, such as a procedure in which the terminal operating in the non-standalone additionally connects to the secondary node, By implementing a concrete / optimal scheme (technique) that minimizes the control of the master node, the effect of providing a high-performance service at the beginning of the network connection is derived.

1 is an exemplary diagram showing a communication environment in which a terminal (Non-Standalone) according to the present invention operates.
2 is a flowchart showing an existing method in which a non-standalone terminal additionally connects to a secondary node.
3 is an exemplary diagram illustrating a configuration of a terminal device according to a preferred embodiment of the present invention.
4 is an exemplary diagram illustrating a configuration of a base station apparatus according to a preferred embodiment of the present invention.
5 is a flowchart illustrating a method for managing a secondary node of a non-standalone terminal according to an exemplary embodiment of the present invention.
6 is a control flowchart illustrating a dual connection (DC) operation method of a terminal device according to a preferred embodiment of the present invention.
7 is a control flowchart illustrating a dual connection (DC) control method of a base station apparatus 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.

FIG. 1 shows a communication environment in which a terminal (Non-Standalone) according to the present invention operates.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a non-standalone technology that utilizes communication services based on interworking between different types of networks.

As shown in FIG. 1, the communication environment to which the present invention is applied is limited to a communication environment in which different types of wireless networks, for example, 4G and 5G wireless access devices coexist.

Hereinafter, the base station 200 shown in FIG. 1 will be referred to as a 4G base station, which is an access device supporting the wireless section connection of the 4G network, and the base stations 10 and 20 shown in FIG. I will refer to the 5G base station, which is an access device that supports it.

5G is aimed at Ultra Reliable & Low Latency Communication (URLLC) service based on near real-time data transmission and reception, and allows for a very short level (eg 0.5ms) data transmission , And is discussed in terms of allowing relatively long (eg, 10 ms) control information transmission (transmission / reception) delays when compared with data.

On the other hand, studies are underway to develop and develop the 5G system while increasing the cost efficiency by utilizing the 4G systems that have already been widely used and built at the present time, which is developing as 5G.

One of the results of this research is non-standalone technology that uses communication services based on interworking between 4G and 5G networks.

This non-standalone technology uses 4G (LTE) as a primary network to ensure seamless coverage, while using 5G as a secondary network, it transmits / receives data with higher capacity / lower delay. It is a technology that uses communication service based on interworking.

Accordingly, a terminal operating in a non-standalone state accesses a 4G network as a primary network and an additional 5G network as a secondary network at initial connection.

At this time, the 4G base station connected to the 4G network, which is the primary node, is called the master node, and the 5G base node connecting the terminal to be connected to the secondary 5G network is called the secondary node.

Meanwhile, a technology in which a terminal accesses two or more different base stations (Master / Secondary) and uses a communication service is referred to as a Dual Connectivity (hereinafter referred to as DC) technology.

In other words, a terminal operating in a non-standalone mode is connected to a 4G base station as a master node and a 5G base station as a secondary node in order to use a communication service by using 4G as a primary network and 5G as a secondary network. .

In the current DC technology, it is defined that processing such as secondary node addition / deletion / connection switching of the terminal proceeds under the control of the master node, that is, the master node manages the secondary node of the terminal.

In particular, a method in which a terminal additionally connects to a secondary node is a method in which a connection procedure between a terminal and a secondary node proceeds under the control of a master node to which the terminal is connected.

Referring to FIG. 2, a conventional method in which a non-standalone terminal additionally connects to a secondary node will be briefly described as follows.

After the terminal accesses the 4G base station (hereinafter referred to as MN) (S1), the terminal measures the reception signals of the neighbor base stations and transmits the measurement information of the best secondary node (SN) having the best measurement result to the MN (S2).

Accordingly, the MN receives the SN Addition Request / Request Ack. (S3, S4), and transmits a message (RRC Connection Reconfiguration) to the SN to connect to the SN (S5).

In step S6, the MN sends an SN Reconfiguration Complete message according to the response message from the mobile station to the SN. In step S7, the MN transmits an RRC Connection Reconfiguration Complete message to the MN. A connection procedure (Random Access Procedure) for establishing connection of the wireless section between the terminal and the SN may be performed (S8).

If the data traffic of the terminal is received during the DC operation from the network N / W (S9), the MN uses the radio environment information of the SN (e.g., the beam information_optimum beam ID, CQI, RI, (S11), how much data is forwarded to the SN, and transmits the data to the terminal via the SN (S12) (S10).

In this way, the existing scheme in which the non-standalone terminal additionally connects to the secondary node proceeds under the RRC control of the MN to which the terminal is connected.

At this time, the MN also transmits radio environment information (e.g., beam information_optimum_beam_id, CQI, RI, etc.) of the SN necessary for initial scheduling for scheduling data traffic of a terminal during DC operations received from the network N / W And acquires from the terminal through the RRC message received in step S6.

Meanwhile, in the DC technology between 4G and 5G in consideration of the environment in which the 5G gradually evolves / develops in the future, in managing the SN of the terminal including the processing of the SN addition connection in which the terminal additionally connects to the SN, Minimizing and managing SN is discussed in the direction.

However, the non-standalone technology discussed so far only minimizes the MN's control of the SN of the mobile station and presents only the level of technology that the SN manages. However, the specific realization method has not yet been proposed.

Therefore, in the present invention, a concrete / optimal implementation method meeting the objective of minimizing the control of the MN in SN management of the terminal, such as a procedure in which the terminal additionally connects to the SN, is newly proposed.

More specifically, the present invention proposes a terminal device and a base station device that realize a concrete / optimal proposal scheme (technology) for allowing a terminal operating in a non-standalone to manage an SN by an SN.

Hereinafter, with reference to FIG. 3, a configuration of a terminal device for realizing a solution (technology) proposed in the present invention will be described in detail. Here, for convenience of explanation, the reference numerals shown in Fig. 1 will be used for explanation.

First, a terminal device 100 according to a preferred embodiment of the present invention will be described with reference to FIG.

The terminal device 100 of the present invention is a terminal device that is connected to a first network through a connection with a first access device and transmits measurement information of a second access device for additional connection to the first access device (110) for receiving a message from the first access device to the second access device, and a second access device for receiving the message from the first access device And a connection performing unit (120) for performing a random access for establishing a connection with the second access apparatus without responding to a response to the access apparatus (1).

Furthermore, the terminal apparatus 100 may further include a radio environment information transmitting unit 130. [

The terminal device 100 of the present invention is a terminal capable of non-standalone operation, and therefore, it will connect to the primary 4G (base station) when the network is initially connected in the case of non-standalone operation.

Thus, the first network means a 4G network and the first access device means 4G base station.

Hereinafter, for convenience of explanation, the 4G base station 200 and the 5G base stations 10 and 20 of FIG. 1 will be described. In addition, the terminal device 100 of the present invention operates in a non-standalone manner.

The terminal device 100 performs random access to set up a connection with the first access device, that is, the 4G base station 200, at the time of network initial connection in the case of operating in Non-Standalone mode.

At this time, the 4G base station 200 corresponds to a master node (hereinafter referred to as MN) in the case of the terminal device 100 operating as a non-standalone.

The terminal device 100 measures the reception signals of the neighboring base stations while being connected to the 4G network through the connection with the 4G base station 200. [

The measurement information reporting unit 110 may transmit measurement information of the base station having the best measurement result obtained by measuring the reception signals of the neighbor base stations, that is, 2 measurement information of the access device to the 4G base station 200. [

At this time, since the terminal device 100 operates in a non-standalone manner, the second access device means a 5G base station and the second network means a 5G network.

That is, the measurement information reporting unit 110 transmits the measurement information of the 5G base station, which has the best measurement result of measuring the received signal, to the 4G base station 200 while being connected to the 4G network through the connection with the 4G base station 200 will be.

Hereinafter, for convenience of explanation, it is assumed that the measurement information of the 5G base station 10 is transmitted to the 4G base station 200. [

At this time, the 5G base station 10 corresponds to a Best Secondary Node (hereinafter SN) having the best measurement result of the received signal in the case of the terminal device 100 operating as a non-standalone.

When the 5G base station 10 is a device of a 5G network different from the 4G network, the connection performing unit 120 transmits the message to the 4G base station 10 200 to the 5G base station 10 without any response.

More specifically, when the terminal device 100 transmits the measurement information of the 5G base station 10 to the 4G base station 200, the 4G base station 200 as the MN transmits the measurement information as the best SN to the 5G base station 10 (SN 10) and an SN Addition Request / Request Ack. And establishes an interconnection with the SN 10. This process is the same as the existing method.

Thereafter, the 4G base station 200 as an MN will transmit a message (RRC Connection Reconfiguration) to the terminal device 100 to connect to the SN 10. [

In this case, the 4G base station 200 transmits a message (RRC Connection Reconfiguration) to the terminal device 100 operating in the non-standalone mode, and the SN (10) and type information of the random access to be performed.

The random access type information at this time may be information indicating whether the random access to be performed with the SN 10 is contention based or content based.

When receiving a message (RRC Connection Reconfiguration) to connect to the SN 10 from the 4G base station 200, that is, the MN 200, the connection performing unit 120 transmits the SN (10) The presence or absence of the random access type information which is confirmed only when the random access type information exists.

When the random access type information is confirmed in the message (RRC Connection Reconfiguration), the connection performing unit 120 directly accesses the random access for establishing a connection with the SN 10 without returning a response to the MN 200 for the message .

In other words, the connection performing unit 120 performs random access procedure based on contention-based or contention-based random access procedure with the SN 10 according to the random access type information confirmed in the message (RRC Connection Reconfiguration) (10).

The radio environment information transmitting unit 130 transmits the radio environment information (e.g., the beam information_optimum beam ID, the CQI, the RI, and the like) measured for the SN 10 when the connection with the second access device, Etc.) to the SN 10 so that the radio environment information of the SN 10 used in the scheduling of the downlink data traffic transmitted from the first access device, that is, the MN 200 to the terminal device 100, 10 to the MN 200.

That is, when the connection with the SN 10 is established according to the random access performance, the radio environment information transmitting unit 130 transmits the radio environment information measured with respect to the SN 10 (e.g., the beam information_optimum beam ID, the CQI , RI, etc.) to the SN 10.

More specifically, when the connection with the SN 10 is established according to the random access, the radio environment information transmitting unit 130 transmits a response message in response to the RRC Connection Reconfiguration message received from the MN 200 RRC Connection Reconfiguration Complete) to the SN 10 by including the radio environment information of the SN 10 in the RRC Connection Reconfiguration Complete.

At this time, the radio environment information (e.g., beam information_optimum beam ID, CQI, RI, etc.) of the SN 10 is generated from the measurement information of the SN 10 transmitted by the measurement information reporting unit 110 Information, or may be information generated by separately measuring.

Accordingly, according to the present invention, the SN 10 that has received the RRC Connection Reconfiguration Complete message from the terminal device 100 transmits the radio environment information (e.g., the beam information_optimum beam ID, CQI, RI, etc.) To the MN 200 so that the MN 200 can utilize the MN 200 itself.

More specifically, the SN 10 includes radio environment information (e.g., a beam information_optimum beam ID, CQI, RI, etc.) of the SN 10 in an SN Reconfiguration Complete message transmitted to the MN 200, And can transmit environment information (e.g., beam information_optimum beam ID, CQI, RI, etc.) to the MN 200. [

In this case, the MN 200 performs the initial scheduling for downlink data traffic of the terminal apparatus 100 during the DC operation received from the network N / W, between the terminal apparatus 100 and the SN 10 (For example, beam information_optimum beam ID, CQI, RI, etc.) of the mobile terminal 100 from the terminal device 100 via the SN 10. [

As described above, according to the terminal device of the present invention, it is possible to provide a simple change (for example, random access type information) necessary for performing a random access between a terminal and an SN to add / provide an RRC message The random access with the SN is performed without returning the response message to the MN for the RRC message and the SN environment information is also acquired without failure in the MN so that the SN of the SN is minimized to the SN It is possible to realize a concrete / optimal SN additional access scheme that meets the management (processing of additional access).

Furthermore, the measurement information reporting unit 130 may notify the user of the additional access during the dual connectivity (DC) operation in the state that the first access device, that is, the MN 200 and the second access device, that is, The measurement information of the specific second access device for switching is transferred to the SN 10 and the connection switching procedure between the SN 10 and the specific second access device proceeds under the control of the SN 10 without involvement of the MN 200 .

More specifically, as shown in FIG. 1, the terminal device 100 measures the reception signals of the neighbor base stations during the DC operation connected to the MN 200 and the SN 10, and as a result, The Best SN having the best result of the received signal measurement can be changed from the 5G base station 10 to the 5G base station 20.

The above-mentioned specific second access device means the 5G base station 20, that is, the SN 20.

In this case, the terminal 100 transmits the measurement information of the 5G base station 20 to the MN 200, so that the SN (for the terminal 100) 10) and the SN 20 have been proceeding.

However, according to the present invention, the terminal apparatus 100, and more specifically, the measurement information reporting unit 130 may be configured to transmit measurement information of a new Best SN 20 when the Best SN is changed, And transmits the measurement information of the SN 20 to the SN 10.

In this case, the SN 10 connected to the terminal device 100 operates as if it is an MN in view of the new SN 20 to which the additional connection is to be switched, so that the SN (10 The connection switching procedure between the SN 10 and the SN 20 with respect to the terminal device 100 can be performed under the control of the subscriber.

Specifically, for example, the SN 10 that has received the measurement information of the new Best SN 20 from the terminal device 100 receives the SN 20 and the SN Change Request / Request Ack. (RRC Connection Reconfiguration) to the terminal device 100 so as to set up the interconnection with the SN 20 and connect to the SN 20. [

Thereafter, random access between the terminal device 100 and the SN 20 is performed based on the RRC message transmitted to the terminal device 100, and when the terminal device 100 is connected to the SN 20, Requests the MN 100 to disconnect the existing SN 10 and establishes connection with the MN 200 connected to the terminal 100 and transmits the radio environment information of the SN 20 to the MN 200 ).

As described above, according to the terminal device of the present invention, when the connection switching of the SN is required during the DC operation, the measurement information of the new SN to be connected is reported to the currently connected SN instead of the MN, SN connection switching procedure between the SNs under the control of the currently connected SN, the SN of the terminal is minimized by minimizing the control of the MN so as to meet the SN management (connection switching processing) It is possible to realize a solution.

Hereinafter, a base station apparatus 200 according to a preferred embodiment of the present invention will be described with reference to FIG.

The base station apparatus 200 of the present invention includes a connection establishing unit 210 for establishing a connection with the specific access apparatus when measurement information of a specific access apparatus to be additionally connected is received from the terminal in connection, (220) for confirming whether or not the specific access device is a device of a specific network different from the base station device, and a determination section (220) for determining whether an additional connection between the terminal and the specific access device And a control unit 230 that controls different processes.

In the following description, the terminal 100 will be described in the same manner as the example assumed in the above description.

The connection setting unit 210 establishes a connection with a specific access device when measurement information of a specific access device for additional connection from the connected terminal 100 is received.

When the terminal 100 transmits the measurement information of the access device to be additionally connected to the base station 200, the terminal 100 additionally connects to the SN in addition to the base station 200 .

Upon reception of measurement information as a specific access device to be additionally connected, i.e. Best SN, from the currently connected terminal 100, the connection setting unit 210 sets the SN Addition Request / Request Ack. Send and receive messages, and set up interconnections. This process is the same as the existing method.

The confirmation unit 220 confirms whether the Best SN of the particular access device, i.e., the terminal 100 interconnected as described above, is a device of a specific network different from the base station 200, that is, the MN 200. [

In this case, since the MN 200 is limited to the 4G base station and the terminal 100 operates in the non-standalone mode, the Best SN to be additionally accessed in the terminal 100 is a 5G base station of the 5G network .

Hereinafter, for convenience of explanation, it will be assumed that the Best SN of the specific access device, that is, the terminal 100 is assumed to be the 5G base station 10.

In this case, the confirming unit 220 confirms that the Best SN 10 of the terminal 100 interconnected by the connection setting unit 210 is a device of a 5G network different from the MN 200.

The control unit 230 controls the additional connection between the terminal 100 and the SN 10 in a different procedure depending on whether the specific access device, i.e., the SN 10 is a device of the 5G network.

Specifically, when the specific access device, that is, the SN 10 is a device of the 5G network, the control section 230 further includes random access type information in a message to be transmitted to the terminal 100 so as to be connected to the SN 10 .

That is, when the SN 10 is a device of the 5G network, the control unit 230 transmits a message (RRC Connection Reconfiguration) to be transmitted to the terminal 100 operating as a non-standalone, And transmits the type information of the random access.

The random access type information at this time may be information indicating whether the random access to be performed with the SN 10 is contention based or content based.

In response to the random access type information included in the message (RRC Connection Reconfiguration), the UE 100 performs a random access to set up a connection with the SN 10 without returning a response to the MN 200 for the message You can do it right away.

That is, the UE 100 performs a random access procedure based on the random access type information confirmed in the RRC Connection Reconfiguration with the SN 10 by performing a contention-based or contention based random access procedure, Lt; / RTI >

On the other hand, when the SN 10 is a device of the 4G network such as the MN 200, the case where the terminal 100 additionally connects to the SN in the same network.

Accordingly, when the SN 10 is not a device of the 5G network but a device of the 4G network such as the MN 200, the control unit 230 transmits a message (RRC Connection Reconfiguration) according to the existing method as shown in FIG. 2 To the terminal 100 (S5), and performs the SN addition connection procedure under the control of the MN 200. [

As described above, according to the base station apparatus of the present invention, by adding / providing the minimum information (e.g., random access type information) necessary for random access between the terminal and the SN to the RRC message transmitted to the terminal, It is possible to perform the random access with the SN without returning the response message to the MN for the RRC message, thereby minimizing the control of the MN of the terminal to meet the SN management (additional connection processing) / Optimal SN additional access scheme can be realized.

Hereinafter, a method of managing a secondary node of a non-standalone terminal according to a preferred embodiment of the present invention will be described with reference to FIG.

5, after the terminal 100 accesses the base station 200 (hereinafter, referred to as MN) (S1), the terminal 100 measures the reception signals of the neighbor base stations, (Hereinafter referred to as SN) to the MN 200 (S2).

Accordingly, the MN 200 receives the SN Addition Request / Request Ack (hereinafter referred to as " SN Addition Request / Request Ack. &Quot; And transmits a message (RRC Connection Reconfiguration) to the terminal 100 to establish a mutual connection with the SN 10 (S3, S4) and access the SN 10 (S13).

At this time, since the SN 10 is a 5G base station other than 4G, the MN 200 transmits a message (RRC Connection Reconfiguration) to the terminal 100 operating as a non-standalone in step S13, And transmits the type information of the random access to be performed.

When receiving a message (RRC Connection Reconfiguration) to connect to the SN 10 from the MN 200, the UE 100 receives random access type information that is confirmed only when the SN 10 is a device of the 5G network Based on the random access type information, a random access procedure (Random Access Procedure) with the SN 10 (S20), and transmits the SN (10) 10).

When a connection with the SN 10 is established according to random access, the AT 100 transmits a response message (RRC Connection Reconfiguration Complete) to the RRC Connection Reconfiguration message received from the MN 200 to the SN (10) (E.g., beam information_optimum beam ID, CQI, RI, and the like) of the base station 10 to the SN 10 (S30).

The SN 10 that has received the RRC Connection Reconfiguration Complete message from the AT 100 transmits SN information (e.g., beam information_optimum_beam ID, CQI, RI, etc.) obtained from the message to the MN 200 Included in the Reconfiguration Complete message and transmitted to the MN 200 (S40).

In this case, even if the MN 200 fails to acquire the radio environment information of the SN 10 through a response to the RRC Connection Reconfiguration message to the AT 100, The wireless environment information of the SN 10 can be acquired without fail.

When the data traffic of the terminal 100 is received during the DC operation from the network N / W (S50), the MN 200 transmits the radio environment information of the SN 10 (e.g., the beam information_optimum beam ID, CQI, RI, etc.) to the terminal 100 by itself (S70), forwarding as much data as the SN 10 to the terminal (100) through the SN (10) (S80), it is possible to perform initial scheduling (S60).

As described above, according to the present invention, it is possible to realize a concrete / optimal SN additional access method in which the control of the MN of the terminal is minimized and the SN is managed (processing of additional connection).

Meanwhile, when the UE 100 measures the reception signals of the neighbor base stations during the DC operation connected to the MN 200 and the SN 10, it is determined that the Best SN having the best reception signal measurement result according to the positional movement is the 5G base station (10) to the 5G base station (20).

Hereinafter, it is assumed that the best SN is changed from the 5G base station 10 to the 5G base station 20 among the DC operations in which the terminal 100 is connected to the MN 200 and the SN 10 for convenience of explanation (S100).

In this case, the terminal 100 transmits the measurement information of the new Best SN 20, in other words, the measurement information of the SN 20 for switching the additional connection, to the SN 10 instead of the MN 200 S110).

In this case, the SN 10 connected to the terminal 100 operates as if it is the MN in view of the new SN 20 to which the additional connection is to be switched, so that the SN 10, without actually participating in the MN 200, A connection switching procedure (dotted line) between the SN 10 and the SN 20 for the terminal 100 can be performed.

More specifically, the SN 10 that has received the measurement information of the new Best SN 20 from the terminal 100 receives the SN 20 and the SN Change Request / Request Ack. (RRC Connection Reconfiguration) to the terminal device 100 by transmitting and receiving a message (S113, S114), establishing an interconnection with the SN 20, and accessing the SN 20.

When the terminal 100 is connected to the SN 20 (S120), a random access between the terminal 100 and the SN 20 is performed due to the RRC message transmitted to the terminal 100, Requests the existing SN 10 to disconnect the terminal device 100 in step S130 and also establishes connection with the MN 200 connected to the terminal 100 and wireless environment information of the SN 20 To the MN 200 (S140).

In this case, even if the MN 200 fails to acquire the radio environment information of the new Best SN 20 while participating in the connection switching between the SNs of the AT 100, the MN 200 transmits the new Best SN 20 from the AT 100 via the new Best SN 20 It is possible to acquire the radio environment information of the SN 20 without fail.

When the data traffic of the terminal 100 is received during the DC operation from the network N / W (S150), the MN 200 transmits the radio environment information of the SN 20 (e.g., the beam information_optimum beam ID, CQI, RI, etc.) to the terminal 100 by itself (S170), forwarding as much data as the SN 20 to the terminal 100 through the SN 20 (S180), it is possible to perform initial scheduling (S160).

As described above, according to the present invention, it is possible to realize a concrete / optimal SN connection switching scheme that minimizes control of the MN of the terminal and conforms to the fact that the SN is managed (connection switching processing).

Hereinafter, a dual connection (DC) operation method of a terminal apparatus according to a preferred embodiment of the present invention will be described with reference to FIG.

Particularly, since the present invention relates to a non-standalone technique using 4G and 5G networks, a DC operation method of a terminal device operating in a non-standalone manner will be described in detail.

According to the DC operation method of the terminal device according to the present invention, the terminal device 100 will connect to the 4G base station 200 which is the primary when the network is initially connected (S200).

At this time, the 4G base station 200 corresponds to a master node (hereinafter referred to as MN) in the case of the terminal device 100 operating as a non-standalone.

According to the DC operation method of the terminal device according to the present invention, the terminal device 100 has the best measurement result obtained by measuring the reception signals of peripheral base stations in a state of being connected to the 4G network through the connection with the MN 200 The measurement information of the 5G base station is transmitted to the MN 200 (S210).

Hereinafter, for convenience of explanation, it is assumed that the measurement information of the 5G base station 10 (hereinafter referred to as SN) is transmitted to the MN 200. [

According to the DC operation method of the terminal device according to the present invention, the terminal device 100 transmits the measurement information of the SN 10 to the MN 200, and then connects the MN 200 to the SN 10 Message (RRC Connection Reconfiguration) (S220).

At this time, in the present invention, random access type information exists only in the case where the SN 10 is a device of a 5G network different from the 4G network of the MN 200 in the message.

At this time, according to the DC operation method of the terminal apparatus according to the present invention, when the random access type information is confirmed in the received RRC Connection Reconfiguration (S230, Yes), the terminal apparatus 100 transmits the MN 200) without performing a response to the SN 10 (S250).

That is, the terminal device 100 performs random access procedure based on contention-based or contention-based random access procedure with the SN 10 according to the random access type information confirmed in the message (RRC Connection Reconfiguration) 10).

According to the DC operation method of the terminal device according to the present invention, when the connection with the SN 10 is established, the terminal device 100 transmits the response format to the RRC Connection Reconfiguration message received from the MN 200 (E.g., beam information_optimum_beam_id, CQI, RI, etc.) of the SN 10 to a response message (RRC Connection Reconfiguration Complete) to the SN 10 (S260).

The SN 10 having received the RRC Connection Reconfiguration Complete message from the terminal device 100 transmits the radio environment information (e.g., the beam information_optimum beam ID, CQI, RI, etc.) And transmits it to the MN 200 (S270).

Therefore, even if the MN 200 fails to acquire the radio environment information of the SN 10 through a response to the RRC Connection Reconfiguration message transmitted to the terminal device 100, 10), the wireless environment information of the SN 10 can be obtained without fail.

On the other hand, if the random access type information is not confirmed in the message (RRC Connection Reconfiguration) received by the terminal device 100 (S230, No), the SN 10 transmits the random access type information to the device And the terminal device 100 additionally connects to the SN in the same network.

Therefore, if the random access type information is not confirmed in the received RRC Connection Reconfiguration (S230, No), the terminal device 100 determines that the SN 10 is not a device of the 5G network but the same as the MN 200 (RRC Connection Reconfiguration Complete) to the MN 200 (S6) according to the existing method, as shown in FIG. 2, and transmits the response message (RRC Connection Reconfiguration Complete) to the MN 200 under the control of the MN 200 (S240).

On the other hand, the terminal device 100 measures the reception signals of the neighbor base stations during the DC operation connected to the MN 200 and the SN 10, and as a result, 5G base station 10 to the 5G base station 20 as shown in FIG.

Hereinafter, it is assumed that the best SN is changed from the 5G base station 10 to the 5G base station 20 among the DC operations in which the terminal 100 is connected to the MN 200 and the SN 10 for convenience of explanation (S280).

In this case, according to the DC operation method of the terminal apparatus according to the present invention, the terminal apparatus 100 can acquire the measurement information of the new Best SN 20, the measurement information of the SN 20 for switching the additional connection To the SN 10, not to the MN 200 (S290).

In this case, the SN 10 connected to the terminal device 100 operates as if it is an MN in view of the new SN 20 to which the additional connection is to be switched, so that the SN (10 The connection switching procedure between the SN 10 and the SN 20 with respect to the terminal device 100 can be performed under the control of the terminal 100 (S300).

Hereinafter, a dual connection (DC) control method of a base station apparatus according to a preferred embodiment of the present invention will be described with reference to FIG.

In particular, since the present invention relates to a non-standalone technique using 4G and 5G networks, a DC control method for a terminal operating in a non-standalone manner will be described in detail.

According to the DC control method of the base station apparatus according to the present invention, after connection with the terminal 100 (S310), the base station apparatus 200 receives the measurement information as the best SN for further connection from the connected terminal 100 (S320), the Node B as the best SN and the SN Addition Request / Request Ack. Message, and establishes a mutual connection (S330).

According to the DC control method of the base station apparatus according to the present invention, the base station apparatus 200 determines whether the Best SN of the terminal 100 interconnected in step S330 is a 5G network different from the base station apparatus 200, (S340). ≪ / RTI >

In this case, since the MN 200 is limited to the 4G base station and the terminal 100 operates in the non-standalone mode, the Best SN to be additionally accessed in the terminal 100 is a 5G base station of the 5G network .

For convenience of explanation, the following description will be made assuming that the Best SN of the specific access device, i.e., the terminal 100 is assumed to be the 5G base station 10.

In this case, the base station apparatus 200 confirms that the Best SN 10 of the interconnected terminal 100 is a device of a 5G network different from the MN 200 (S340 Yes).

According to the DC control method of the base station apparatus according to the present invention, when it is determined that the Best SN 10 is a device of the 5G network (Yes in S330), the base station apparatus 200 determines whether the terminal (RRC Connection Reconfiguration), and transmits the random access type information to be performed to the SN 10 (S360).

In response to the random access type information included in the message (RRC Connection Reconfiguration), the UE 100 performs a random access to set up a connection with the SN 10 without returning a response to the MN 200 for the message (S370).

In addition, according to the DC control method of the base station apparatus according to the present invention, the base station apparatus 200 transmits a message (RRC Connection Reconfiguration) including random access type information to the terminal 100, The radio environment information of the SN 10 transmitted from the terminal 100 through the SN 10 through a connection with the SN 10 is received at step S380.

That is, according to the DC control method of the base station apparatus according to the present invention, the base station apparatus 200 transmits a direct response response from the terminal 100 to a message (RRC Connection Reconfiguration) The wireless environment information of the SN 10 can be acquired without fail even if the wireless environment information of the SN 10 is received from the terminal 100 via the SN 10. [

According to the DC control method of the base station apparatus according to the present invention, when the data traffic of the terminal 100 is received during the DC operation from the network N / W, the base station 200, that is, the MN 200, By using the wireless environment information (e.g., beam information_optimum beam ID, CQI, RI, and the like) of the mobile terminal 10 to forward the data to the terminal 100 And transmit it to the terminal 100 through the SN 10, as shown in FIG.

On the other hand, if the base station 200 determines that the Best SN 10 of the interconnected terminal 100 is a device of a 4G network such as the MN 200 instead of the 5G network (S340 No) It is preferable that an RRC Connection Reconfiguration message according to the existing method is transmitted to the AT 100 in step S5 and the SN additional connection procedure is performed under the control of the MN 200 in step S350.

As described above, according to the present invention, it is possible to provide a concrete / optimal method (hereinafter referred to as " MN control ") for minimizing control of an MN in SN management of a terminal, such as a procedure in which a terminal operating in non- Technology), thereby providing an effect of providing a high-performance service even in the early stage of network connection.

The DC operation method of the terminal apparatus and the DC control method of the base station apparatus according to the embodiment of the present invention can be implemented in the form of a program command which 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 dual connection (DC) operation method and the dual connection (DC) control method of the terminal apparatus and the base station apparatus, the apparatus and the apparatus according to the present invention, a procedure in which a terminal operating in non- (Technique) that minimizes the control of the MN in the SN management of the terminal such as the mobile node, Or is likely to be industrially applicable because it is capable of being practically and practically obvious.

100: terminal device
110: measurement information reporting unit 120: connection performing unit
130: radio environment information transmission unit
200: base station device
210: connection setting unit 220:
230:

Claims (14)

In the terminal device,
A measurement information reporting unit for transmitting measurement information of a second access device for additional connection to the first access device in a state of being connected to the first access device; And
And a connection performing unit for performing a random access for connection with the second access device upon reception of a message from the first access device to the second access device,
Wherein the measurement information reporting unit comprises:
When switching an additional connection from the second access device to a specific second access device during a dual connection operation in a state connected to the first access device and the second access device, To the second access device,
The terminal apparatus comprises:
When the second access device that has received the measurement information of the specific second access device is connected to the specific second access device, receives a message from the second access device to connect to the specific second access device, And connects to the second access device. The method according to claim 1,
The connection-
And performs random access with the second access device according to the type information of the random access to be performed with the second access device, which is confirmed in the message. The method according to claim 1,
When the connection with the second access device is established, the wireless environment information measured for the second access device is transmitted to the second access device,
The wireless environment information of the second access device used for scheduling the downlink data traffic transmitted from the first access device to the terminal device is transmitted to the first access device by the second access device Further comprising an information transmission unit. The method of claim 3,
Wherein the radio environment information transmitter comprises:
When the connection with the second access device is established, the wireless environment information is transmitted to the second access device by including the wireless environment information in a response message in response to the message received from the first access device Terminal device. delete delete delete delete A measurement information reporting step of, when the first access device is connected to the first access device, transmitting measurement information of the second access device for additional connection to the first access device;
A connection performing step of performing a random access for connection with the second access device upon receiving a message from the first access device to the second access device; And
When switching an additional connection from the second access device to a specific second access device during a dual connection operation in a state connected to the first access device and the second access device, To the second access device,
When the second access device that has received the measurement information of the specific second access device is connected to the specific second access device, receives a message from the second access device to connect to the specific second access device, And connecting the second access device to the second access device. 10. The method of claim 9,
The connection step may include:
And performing a random access with the second access device according to the type information of the random access to be performed with the second access device, which is confirmed in the message. 10. The method of claim 9,
When the connection with the second access device is established, the wireless environment information measured for the second access device is transmitted to the second access device,
The step of causing the second access device to transmit the radio environment information of the second access device used for scheduling the downlink data traffic transmitted from the first access device to the terminal device to the first access device Further comprising the steps of: determining whether the terminal device is connected to the terminal device. delete delete delete

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