KR102201516B1 - Terminal device, network initial access method - Google Patents

Abstract

A method (technology) for minimizing the connection time required for initial network access of a terminal operating as a non-standalone using a communication service based on interworking between different heterogeneous networks is disclosed.

Description

Terminal device and network initial access method {TERMINAL DEVICE, NETWORK INITIAL ACCESS METHOD}

The present invention relates to a non-standalone technology that uses a communication service based on interworking between different heterogeneous networks, and more particularly, it is possible to minimize the connection time required for initial network access of a terminal operating in a non-standalone manner. It's about the technology that exists.

With the development of mobile communication networks for large-capacity data/high-speed transmission, a mobile communication network environment that aims for Ultra Reliable & Low Latency Communication (URLLC) services based on near-real-time data transmission and reception in the future, such as a 5th generation mobile communication network ( Hereinafter, it will develop into a 5G) environment.

In 5G, in order to provide ultra-low-latency services, very short (e.g. 0.5ms) data transmission (transmission) delay is allowed, and relatively long (e.g., 10ms) control information transmission ( It is being discussed in the direction of allowing delays.

On the other hand, research to evolve/develop to 5G is being started while increasing cost efficiency by utilizing 4G systems that are already widely deployed and used at the time of development to 5G.

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

Non-Standalone technology uses 4G (LTE) as a primary network to secure seamless coverage while transmitting and receiving 5G-related control information (Control Plane) through 4G, and using 5G as a secondary network to transmit and receive data through 5G. This is a method of transmitting and receiving User (User Plane)), which is a technology that uses communication services based on interworking between 4G and 5G networks.

Accordingly, a terminal operating as a non-standalone accesses a primary 4G (base station) and a secondary 5G (base station) upon initial network access.

On the other hand, 5G will adopt MIMO (Multiple Input Multiple Output) technology that can transmit and receive beamformed signals in different directions based on multiple antennas. In this 5G environment, the terminal (multiple antennas) is a 5G base station (multiple antennas). ), a procedure of finding and synchronizing the optimal beam between the two is required, and it takes a considerable amount of time according to this procedure.

However, the Non-Standalone technology discussed so far suggests the level of accessing the 5G base station after accessing the 4G base station when the non-standalone terminal initially accesses the network, and in this case, the time required for the connection of the terminal is to access the 4G base station. In addition to the time required, a considerable amount of time is required to access the 5G base station.

In other words, even though the Non-Standalone technology is also a 5G technology that aims for ultra-low-latency services, it takes a fairly long connection time when the Non-Standalone terminal initially connects to the network, causing limitations in providing ultra-low-latency services. There is a problem.

Accordingly, there is a need for a method of minimizing the time required for access when a non-standalone terminal initially accesses a network.

The present invention was created in view of the above circumstances, and an object to be reached in the present invention is to provide a specific technology (plan) capable of minimizing the time required for connection during initial network access of a terminal operating in a non-standalone manner. do.

In order to achieve the above object, the terminal device according to the first aspect of the present invention performs an RA performing random access to establish a connection with a first network through a first access device upon initial access to a network for communication service use. part; A simultaneous execution unit configured to simultaneously perform radio resource setting with the first network and another second network-based second access device when the radio resource is set with the first access device after performing the random access; And a determining unit for determining whether to maintain the connection with the second network according to the type of the communication service when the radio resource setting is completed and the first and second networks are simultaneously connected.

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

Preferably, the determination unit may maintain a connection with the second network when the type of communication service is the specific communication service, and release the connection with the second network when it is not the specific communication service. have.

Preferably, when using the communication service by simultaneously accessing the first and second networks, a radio resource with the first access device is used for transmission and reception of control information related to the second network, and the second access It may include a communication control unit that uses radio resources with the device for data transmission and reception of the communication service.

Preferably, the simultaneous execution unit, when information on the second network-based second access device capable of simultaneous access with the first access device is previously registered, the second access device and the second access device based on the previously registered information Radio resource setting of can be performed.

Preferably, the radio resource setting with the second access device includes a time synchronization process with the second access device, an optimal beam synchronization process between the plurality of antenna beams of the second access device and the plurality of antenna beams of the terminal device. Can include.

The terminal device according to the second aspect of the present invention for achieving the above object is to perform an RA performing random access to establish a connection with a first network through a first access device upon initial access to a network for communication service use. part; And when setting radio resources with the first access device after performing the random access, determining whether to simultaneously perform radio resource setting between the first network and another second network-based second access device according to the type of the communication service. It includes a simultaneous execution unit.

The initial network access method performed in the terminal according to the third aspect of the present invention for achieving the above object is, at the time of initial network access for communication service use, a random connection with a first network is established through a first access device. RA performing step of performing access; A simultaneous performing step of simultaneously performing radio resource setting with the first network and a second network-based second access device other than the first network when setting radio resources with the first access device after performing the random access; And a maintenance determination step of determining whether or not to maintain the connection with the second network according to the type of the communication service when the radio resource setting is completed and the first and second networks are simultaneously connected.

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

Preferably, in the maintenance decision step, if the type of the communication service is the specific communication service, the connection with the second network is maintained, and if the communication service is not the specific communication service, the connection with the second network is established. Can be released.

Preferably, when using the communication service by simultaneously accessing the first and second networks, a radio resource with the first access device is used for transmission and reception of control information related to the second network, and the second access It may include the step of using radio resources with the device for data transmission and reception of the communication service.

Accordingly, according to the terminal device and the initial network access method of the present invention, when a terminal operating as a non-standalone terminal using a communication service based on interworking between different heterogeneous networks (eg 4G/5G) initially accesses a network, By realizing a method to minimize the connection time required, the effect of providing the maximum performance without deteriorating the performance of the ultra-low latency service is derived even in the initial network connection.

1 is an exemplary diagram showing a communication environment in which a terminal (Non-Standalone) according to the present invention operates.
2 and 3 are exemplary diagrams showing the configuration of a terminal device according to a preferred embodiment of the present invention.
4 is a flowchart illustrating a method of initial network access according to a preferred embodiment of the present invention from a system perspective.
5 and 6 are flowcharts illustrating a method of initial network access according to a preferred embodiment of the present invention from a terminal perspective.

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

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

The present invention relates to a non-standalone technology that uses a communication service based on interworking between different heterogeneous networks.

Accordingly, as shown in FIG. 1, the communication environment to which the present invention is applied is limited to a communication environment in which different heterogeneous networks, such as 4G and 5G wireless section access devices, coexist.

Hereinafter, the base station 10 shown in FIG. 1 will be referred to as a 4G base station, which is a radio section access device for a 4G network, and the base station 20 shown in FIG. 1, will be referred to as a 5G base station, which is a radio section access device for a 5G network. .

5G aims for an ultra-low-latency (URLLC: Ultra Reliable & Low Latency Communication) service based on near-real-time data transmission and reception, and allows very short (e.g. 0.5ms) data transmission (transmission) delay for this purpose. It is being discussed in the direction of allowing a relatively long (eg, 10 ms) control information transmission (transmission/reception) delay compared to data.

On the other hand, research to evolve/develop to 5G is being started while increasing cost efficiency by utilizing 4G systems that are already widely deployed and used at the time of development to 5G.

One of the results of this study is a 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 secure seamless coverage while transmitting and receiving 5G-related control information (Control Plane) through 4G, and data through 5G by using 5G as a secondary network. This is a method of transmitting and receiving (User Plane), a technology that uses communication services based on interworking between 4G and 5G networks.

Accordingly, a terminal operating as a non-standalone accesses a primary 4G (base station) and a secondary 5G (base station) upon initial network access.

Meanwhile, in 5G, a multiple input multiple output (MIMO) technology capable of transmitting and receiving beamformed signals in different directions based on multiple antennas will be employed.

Accordingly, in the process of accessing the terminal (multiple antennas) to the 5G base station (multiple antennas), a procedure of finding and synchronizing an optimal beam between the terminal and the 5G base station is required.

Briefly explaining the procedure of finding and synchronizing the optimal beam, the first time synchronization procedure between the terminal and the 5G base station (5G Synchronization Procedure), then multiple antenna beams according to the multiple antennas formed by the 5G base station and multiple antennas formed by the terminal. It can be classified into an optimal beam synchronization process between multiple antenna beams according to the following.

More specifically, the optimal beam synchronization process is a beam measuring the channel state for each beam pair in order to find the optimal beam pair (optimum beam) with the best channel state among the multiple antenna beams of the 5G base station and the multiple antenna beams of the terminal. The process of reporting the tracking and beam tracking results to the base station (Measurement Report), when the optimal beam pair (optimal beam) is determined based on the information reported by the base station, the optimal beam for synchronizing the optimal beam between the 5G base station and the terminal It can be classified as a synchronization process (Initial Access Procedure).

In this way, the process of accessing the terminal (multiple antennas) to the 5G base station (multiple antennas) requires several procedures to find and synchronize the optimal beam between the terminal and the 5G base station, and a considerable amount of time is required according to this procedure.

However, the Non-Standalone technology discussed so far suggests the level of accessing a 5G base station after accessing a 4G base station during initial network access of a non-standalone terminal.

Therefore, according to the current level of Non-Standalone technology, the access time required for the non-Standalone terminal to initially access the network is in addition to the time required to access the 4G base station, plus a considerable amount of time required to access the 5G base station. It becomes necessary.

In other words, even though the Non-Standalone technology is also a 5G technology that aims for ultra-low-latency services, it takes a fairly long connection time when the Non-Standalone terminal initially connects to the network, causing limitations in providing ultra-low-latency services. There is a problem.

Accordingly, in the present invention, a specific technique (plan) capable of minimizing the connection time required for initial network access of a non-standalone terminal is proposed.

More specifically, in the present invention, it is intended to propose a terminal device that can minimize the time required for initial network access of a non-standalone terminal and realizes the proposed technique (measure).

Hereinafter, the configuration of a terminal device that realizes the technique (scheme) in the present invention will be described in detail with reference to FIGS. 2 and 3. In this case, for convenience of description, the reference numerals shown in FIG. 1 will be used.

First, a terminal device according to a first embodiment of the present invention will be described with reference to FIG. 2, when the terminal device 100 of the present invention is initially connected to a network for use of a communication service, the first access device is RA performing unit 110 performing random access to establish a connection with a network, and when radio resources are set with the first access device after performing the random access, a second network-based second access different from the first network The simultaneous execution unit 120 for performing radio resource setting with the device at the same time, and when the radio resource setting is completed and simultaneously connected to the first and second networks, the communication with the second network is performed according to the type of the communication service. It includes a determination unit 130 that determines whether to maintain the connection.

Furthermore, the terminal device 100 may further include a communication control unit 140.

The terminal device 100 of the present invention is a terminal capable of non-standalone operation, and thus, when operating in a non-standalone operation, upon initial network access, it will access the primary 4G (base station).

Accordingly, the first network refers to a 4G network, the first access device refers to a 4G base station, the second network refers to a 5G network, and the second access device refers to a 5G base station.

In the following, for convenience of description, the 4G base station 10 and the 5G base station 20 of FIG. 1 will be described. In addition, it will be limited to the case where the terminal device 100 of the present invention operates in a non-standalone mode.

The RA performing unit 110 performs random access for establishing a connection with the 4G network through the first access device, that is, the 4G base station 10, upon initial access to the network for communication service use.

The random access procedure performed by the RA performing unit 110 can be classified into the following four stages of message transmission.

Basically, the RA performing unit 110 receives information related to random access periodically transmitted (broadcasting) from the 4G base station 10 through a system information (SI) message, and uses this information for subsequent random access procedures. I can.

The RA performing unit 110 transmits a random access request message (Random Access Preamble message, hereinafter referred to as RAP message) for attempting random access upon initial network access to the 4G base station 10 to initiate a random access procedure.

That is, the RA performing unit 110 selects an arbitrary preamble from a range of available preambles previously recognized from the 4G base station 10, and uses the selected preamble into a preset random access slot of the uplink physical channel (hereinafter , RA slot) to the 4G base station 10 to transmit the RAP message to the 4G base station 10.

When the 4G base station 10 receives the RAP message from the terminal device 100, it transmits a random access response message (Random Access Response message, hereinafter RAR message) to the terminal device 100 through a downlink physical channel.

Thereafter, the RA performing unit 110, upon successfully receiving the RAR message for the RAP message transmitted by the 4G base station 10, transmits a Connection Request message to the 4G base station 10 to establish connection with the 4G network. request.

Thereafter, when the 4G base station 10 successfully receives the Connection Request message from the terminal device 100, it transmits a Contention Resolution message to the terminal device 100 in response thereto.

Accordingly, when the RA performing unit 110 successfully receives the Contention Resolution message from the 4G base station 10, the random access procedure is terminated to establish a connection with the 4G network.

The simultaneous execution unit 120 performs a random access by the RA execution unit 110, and when radio resources are set with the first access device, that is, the 4G base station 10, the second access device based on the second network, that is, the 5G base station of the 5G network. Radio resource setting with (20) is performed simultaneously.

More specifically, when the connection with the 4G network is established according to the random access performed by the RA performing unit 110, the simultaneous execution unit 120 sets a radio resource for setting radio resources to be used through the 4G base station 10 ( RRC Connection Procedure) is performed.

At this time, the simultaneous execution unit 120, when performing the radio resource setting (RRC Connection Procedure) with the 4G base station 10, the radio resource setting with the 5G base station 20 to set the radio resources to be used through the 5G base station 20 Separately and simultaneously.

More specifically, for each 4G base station (4G cell), information on co-located co-location 5G base stations (5G cells) may be pre-registered/managed. In the case of FIG. 1, with respect to the 4G base station 10, information of the 5G base station 20 will be pre-registered.

Accordingly, the terminal device 100, in particular the simultaneous execution unit 120, checks whether information on a 5G base station (5G cell) capable of simultaneous access with the 4G base station 10 is already registered, and if there is information already registered, Based on the radio resource setting with the 5G base station 20 may be performed.

In other words, when the connection with the 4G network is established according to the random access performed by the RA performing unit 110, the simultaneous execution unit 120, when setting radio resources with the 5G base station 20, the 4G base station 10 It is the same as performing the radio resource setting (RRC Connection Procedure) separately and at the same time.

Here, the radio resource setting with the 5G base station 20 includes a time synchronization process with the 5G base station 20, an optimal beam synchronization process between the multiple antenna beams of the 5G base station 20 and the multiple antenna beams of the terminal device 100. Include.

Specifically, radio resource setup with the 5G base station 20 includes a time synchronization procedure with the 5G base station 20 (5G Synchronization Procedure) that precedes the first, and a plurality of antenna beams of the 5G base station 20 and the terminal device 100 ) Can be classified as an optimal beam synchronization process between multiple antenna beams.

More specifically, the optimal beam synchronization process between the plurality of antenna beams of the 5G base station 20 and the plurality of antenna beams of the terminal device 100 may include multiple antenna beams of the 5G base station 20 and multiple antenna beams of the terminal device 100. In order to find the optimal beam pair (optimum beam) with the best channel state among them, the process of measuring the channel state for each beam pair and reporting the beam tracking result to the 4G base station 10 (Measurement Report), 4G base station (10) The process of receiving a response by requesting Cell Add from the 5G base station 20 based on the reported information, and determining the optimal beam pair (optimum beam), the optimal beam between the 5G base station 20 and the terminal device 100 It can be classified into an optimal beam synchronization process (Initial Access Procedure) that performs synchronization with respect to.

Therefore, the simultaneous execution unit 120 performs a radio resource setting with the 4G base station 10 (RRC Connection Procedure), and at the same time, first performs a time synchronization process with the 5G base station 20 (5G Synchronization Procedure), and then By sequentially performing the processes, the radio resource setting with the 5G base station 20 is separately performed together.

As described above, the terminal device 100 of the present invention performs simultaneous access to the 4G base station 10 and the 5G base station 20, unlike the existing technology of accessing the 5G base station after accessing the 4G base station during initial network access. .

In this case, from the viewpoint of the access time required for the terminal operating as a non-standalone to initially access the network, in the present invention, in addition to the time required to access the 4G base station (hereinafter, the time required for 4G access), the 5G base station is accessed. Unlike the previous one that requires a considerable amount of time (hereinafter, referred to as 5G connection time) additionally, the time required for 4G connection and the time required for 5G connection partially overlap, so a little additional time in addition to the time required for 4G connection (5G connection time required) -4G connection time required).

That is, in the present invention, a 4G base station access and a 5G base station access are simultaneously performed, thereby minimizing the connection time required for initial network access of a terminal operating in a non-standalone manner.

When the above-described radio resource setting is completed and simultaneously (both) connected to the first and second networks, that is, 4G and 5G networks, the determination unit 130 determines whether to maintain the connection with the 5G network according to the type of communication service. .

More specifically, the determination unit 130 maintains access to the 5G network when the type of communication service is an ultra-low-latency specific communication service, and releases the connection to the 5G network when it is not a specific communication service. Is to do.

In this case, the terminal device 100 of the present invention minimizes the time required for initial network access by simultaneously performing 4G base station access and 5G base station access at the same time when initial network access for communication service is used, but the communication service to be used. If the use of the 5G network is unnecessary, terminal power consumption can be saved by disconnecting the 5G network.

On the other hand, when the communication service to be used is an ultra-low-latency specific communication service requiring the use of a 5G network, the terminal device 100 will maintain access to the 5G network.

In this case, the communication control unit 140, when using a communication service by simultaneously (both) accessing the first and second networks, that is, 4G and 5G networks, transmits radio resources with the 4G base station 10 to control information related to the 5G network ( Control Plane) is used for transmission and reception, and radio resources with the 5G base station 20 are used for transmission and reception of data (User Plane) of a communication service.

That is, the communication unit 140 transmits and receives control information related to the 5G network through the 4G network while securing seamless coverage by using 4G as the primary network according to the Non-Standalone technology, and using the 5G as a secondary network. It is a method of transmitting and receiving data (User Plane) of communication service through 5G network, using communication service based on interworking between 4G and 5G networks.

Hereinafter, a terminal device according to a second embodiment of the present invention will be described with reference to FIG. 3.

As shown in FIG. 3, the terminal device 100 of the present invention performs an RA performing random access to establish a connection with a first network through a first access device when initial access to a network for communication service is used. When setting the radio resource with the first access device after performing the random access, the unit 110 simultaneously sets the radio resource with the first network and another second network-based second access device according to the type of the communication service It includes a simultaneous execution unit 150 to determine whether to perform.

Furthermore, the terminal device 100 may further include a communication control unit 140.

In the following description, too, the first network will mean a 4G network, the first access device will mean a 4G base station, the second network will mean a 5G network and the second access device will mean a 5G base station.

Therefore, the 4G base station 10 and the 5G base station 20 of FIG. 1 will be described. In addition, it will be limited to the case where the terminal device 100 of the present invention operates in a non-standalone mode.

The RA performing unit 110 performs random access for establishing a connection with the 4G network through the first access device, that is, the 4G base station 10, upon initial access to the network for communication service use.

Since the random access procedure performed by the RA performing unit 110 is the same as in the first embodiment described above, a detailed description will be omitted.

The simultaneous execution unit 150 is a second network-based second access device according to the type of communication service when radio resources are set with the first access device, that is, the 4G base station 10 after performing random access by the RA performing unit 110. That is, it is determined whether to perform radio resource setting simultaneously with the 5G base station 20 of the 5G network.

More specifically, when the connection with the 4G network is established according to the random access performed by the RA performing unit 110, the simultaneous execution unit 150 sets radio resources to set radio resources to be used through the 4G base station 10 ( RRC Connection Procedure) is performed.

At this time, the simultaneous execution unit 150 determines the simultaneous execution of radio resource setting with the 5G base station 20 when the type of communication service is an ultra-low-latency specific communication service, and the radio resource to be used through the 5G base station 20 The radio resource setting with the 5G base station 20 is performed separately and simultaneously.

More specifically, for each 4G base station (4G cell), information on co-located co-location 5G base stations (5G cells) may be pre-registered/managed. In the case of FIG. 1, with respect to the 4G base station 10, information of the 5G base station 20 will be pre-registered.

Accordingly, the terminal device 100, in particular, the simultaneous execution unit 150 checks whether information of a 5G base station (5G cell) capable of simultaneous access to the 4G base station 10 is already registered, and there is information already registered and the 5G If it is determined to simultaneously perform radio resource setting with the base station, radio resource setting with the 5G base station 20 may be performed based on previously registered information.

In other words, when the connection with the 4G network is established according to the random access performed by the RA performing unit 110, the simultaneous execution unit 150, the communication service to be used later, is an ultra-low-latency specific communication requiring the use of the 5G network. In the case of a service, when radio resources are set with the 5G base station 20, radio resource settings with the 4G base station 10 (RRC Connection Procedure) are simultaneously performed separately.

Here, the radio resource setting with the 5G base station 20 includes a time synchronization process with the 5G base station 20, an optimal beam synchronization process between the multiple antenna beams of the 5G base station 20 and the multiple antenna beams of the terminal device 100. Include.

Specifically, radio resource setup with the 5G base station 20 includes a time synchronization procedure with the 5G base station 20 (5G Synchronization Procedure) that precedes the first, and a plurality of antenna beams of the 5G base station 20 and the terminal device 100 ) Can be classified as an optimal beam synchronization process between multiple antenna beams.

More specifically, the optimal beam synchronization process between the plurality of antenna beams of the 5G base station 20 and the plurality of antenna beams of the terminal device 100 may include multiple antenna beams of the 5G base station 20 and multiple antenna beams of the terminal device 100. In order to find the optimal beam pair (optimum beam) with the best channel state among them, the process of measuring the channel state for each beam pair and reporting the beam tracking result to the 4G base station 10 (Measurement Report), 4G base station (10) The process of receiving a response by requesting Cell Add from the 5G base station 20 based on the reported information, and determining the optimal beam pair (optimum beam), the optimal beam between the 5G base station 20 and the terminal device 100 It can be classified into an optimal beam synchronization process (Initial Access Procedure) that performs synchronization with respect to.

Therefore, the simultaneous execution unit 150 performs a radio resource setting with the 4G base station 10 (RRC Connection Procedure), and at the same time, first performs a time synchronization process with the 5G base station 20 (5G Synchronization Procedure), and then By sequentially performing the processes, the radio resource setting with the 5G base station 20 is separately performed together.

As described above, the terminal device 100 of the present invention accesses the 4G base station 10, unlike the existing technology of accessing the 5G base station after accessing the 4G base station under the premise that a specific communication service with ultra-low latency is used during initial network access. And 5G base station 20 access is performed at the same time.

In this case, from the viewpoint of the access time required for the terminal operating as a non-standalone to initially access the network, in the present invention, in addition to the time required to access the 4G base station (hereinafter, the time required for 4G access), the 5G base station is accessed. Unlike the previous one that requires a considerable amount of time (hereinafter, referred to as 5G connection time) additionally, the time required for 4G connection and the time required for 5G connection partially overlap, so a little additional time in addition to the time required for 4G connection (5G connection time required) -4G connection time required).

That is, in the present invention, a 4G base station access and a 5G base station access are simultaneously performed, thereby minimizing the connection time required for initial network access of a terminal operating in a non-standalone manner.

In addition, the terminal device 100 of the present invention can fundamentally prevent unnecessary power consumption of the terminal because it does not simultaneously perform 4G base station access and 5G base station access if the communication service does not require 5G network use.

In addition, the terminal device 100 according to the second embodiment of the present invention, in particular, the communication control unit 140, also connects to the first and second networks, i.e., 4G and 5G networks at the same time (both) to use communication services. The radio resource with (10) is used for transmission and reception of control information (Control Plane) related to the 5G network, and the radio resource with the 5G base station 20 is used for transmission and reception of data (User Plane) of the communication service.

That is, the communication unit 140 transmits and receives control information related to the 5G network through the 4G network while securing seamless coverage by using 4G as the primary network according to the Non-Standalone technology, and using the 5G as a secondary network. It is a method of transmitting and receiving data (User Plane) of communication service through 5G network, using communication service based on interworking between 4G and 5G networks.

As described above, according to the present invention, upon initial network access of a terminal operating as a non-standalone using a communication service based on interworking between different heterogeneous networks (eg 4G/5G), 4G and 5G By realizing a method (technology) that minimizes the time required for connection by simultaneously accessing and prevents unnecessary 5G access from occurring (maintaining), the ultra-low latency service is provided even at the initial stage of network access. It derives the effect of providing maximum performance without performance degradation.

Hereinafter, a method of initial network access according to a preferred embodiment of the present invention will be described in terms of a system with reference to FIG. 4.

For convenience of explanation, the terminal 100 will be limited to a case of non-standalone operation.

The terminal 100 performs random access to establish a connection with the 4G network through the 4G base station 10 upon initial access to the network for communication service use (Random Access Procedure, S10).

When the connection with the 4G network is established according to the random access in step S10, the terminal 100 performs a radio resource setting (RRC Connection Procedure) for setting radio resources to be used through the 4G base station 10 (S20). ).

At this time, when performing step S20, the terminal 100 performs radio resource setting with the 5G base station 20, which sets radio resources to be used through the 5G base station 20, separately and simultaneously (S30).

In other words, when the connection with the 4G network is established according to the random access in step S10, the terminal 100 sets radio resources with the 4G base station 10 (S30) when setting up radio resources with the 5G base station 20 ( RRC Connection Procedure) is performed separately and simultaneously (S20).

Here, the radio resource setting with the 5G base station 20 includes a time synchronization process with the 5G base station 20, an optimal beam synchronization process between the multiple antenna beams of the 5G base station 20 and the multiple antenna beams of the terminal device 100. Include.

Specifically, the radio resource setting with the 5G base station 20 is a time synchronization procedure (5G Synchronization Procedure, S32) with the 5G base station 20 that precedes the first, and a plurality of antenna beams and a terminal device of the 5G base station 20 It can be divided into an optimal beam synchronization process (34, S36, S38) between multiple antenna beams of (100).

More specifically, the optimal beam synchronization process between the plurality of antenna beams of the 5G base station 20 and the plurality of antenna beams of the terminal device 100 may include multiple antenna beams of the 5G base station 20 and multiple antenna beams of the terminal device 100. In order to find the optimal beam pair (optimal beam) with the best channel state among them, the process of reporting the beam tracking and beam tracking results for measuring the channel state for each beam pair to the 4G base station 10 (Measurement Report, S34), Based on the information reported by the 4G base station 10, the process of receiving a response by requesting a cell add from the 5G base station 20 (S36), and determining the optimal beam pair (optimum beam), the 5G base station 20 and the terminal device ( 100) can be classified into an optimal beam synchronization process (Initial Access Procedure, S38) that performs synchronization on the optimal beam.

Accordingly, the terminal 100 performs a radio resource setting (RRC Connection Procedure, S20) with the 4G base station 10 and at the same time first performs a time synchronization process (5G Synchronization Procedure, S32) with the 5G base station 20, and By performing the following processes in sequence, the radio resource setting performance (S30) with the 5G base station 20 is separately performed together.

In this way, the terminal 100 connects to the 4G and 5G networks by simultaneously accessing the 4G base station 10 and the 5G base station 20, unlike the existing technology of accessing the 5G base station after accessing the 4G base station during initial network access. Simultaneous (all) connections are made (S40).

In this case, from the viewpoint of the access time required for the terminal operating as a non-standalone to initially access the network, in the present invention, in addition to the time required to access the 4G base station (hereinafter, the time required for 4G access), the 5G base station is accessed. Unlike the previous one that requires a considerable amount of time (hereinafter, referred to as 5G connection time) additionally, the time required for 4G connection and the time required for 5G connection partially overlap, so a little additional time in addition to the time required for 4G connection (5G connection time required) -4G connection time required).

That is, in the present invention, a 4G base station access and a 5G base station access are simultaneously performed, thereby minimizing the connection time required for initial network access of a terminal operating in a non-standalone manner.

Hereinafter, with reference to FIG. 5, an initial network access method according to a first embodiment of the present invention will be described from the viewpoint of a terminal. For convenience of explanation, the terminal device 100 will be described as a terminal implementing the initial network access method of the present invention.

According to the network initial access method of the present invention, the terminal device 100 performs random access for establishing a connection to a 4G network through the 4G base station 10 when initial network access for communication service is used (S100). .

According to the network initial access method of the present invention, when a connection with a 4G network is established according to random access, the terminal device 100 sets radio resources to be used through the 4G base station 10 (RRC Connection). Procedure) is performed (S110).

At this time, according to the network initial access method of the present invention, the terminal device 100 separately sets radio resources with the 5G base station 20 for setting radio resources to be used through the 5G base station 20 when performing step S110. Simultaneous execution (S120).

In other words, according to the initial network access method of the present invention, when the connection with the 4G network is established according to the random access in step S100, the terminal device 100 sets radio resources with the 5G base station 20 (S120 ), it is the same as performing radio resource setup (RRC Connection Procedure) with the 4G base station 10 separately at the same time (S110).

Here, the radio resource setting with the 5G base station 20 in step S120 is a time synchronization process with the 5G base station 20, the optimal beam between multiple antenna beams of the 5G base station 20 and the multiple antenna beams of the terminal device 100 Includes the synchronization process.

Specifically, the radio resource setting with the 5G base station 20 is a time synchronization procedure (5G Synchronization Procedure, S32) with the 5G base station 20 that precedes the first, and a plurality of antenna beams and a terminal device of the 5G base station 20 It can be classified as an optimal beam synchronization process between multiple antenna beams of (100).

More specifically, the optimal beam synchronization process between the plurality of antenna beams of the 5G base station 20 and the plurality of antenna beams of the terminal device 100 may include multiple antenna beams of the 5G base station 20 and multiple antenna beams of the terminal device 100. In order to find the optimal beam pair (optimum beam) with the best channel state among them, the process of measuring the channel state for each beam pair and reporting the beam tracking result to the 4G base station 10 (Measurement Report), 4G base station (10) The process of receiving a response by requesting Cell Add from the 5G base station 20 based on the reported information, and determining the optimal beam pair (optimum beam), the optimal beam between the 5G base station 20 and the terminal device 100 It can be classified into an optimal beam synchronization process (Initial Access Procedure) that performs synchronization with respect to.

As described above, according to the network initial access method of the present invention, the terminal device 100 accesses the 4G base station 10 and accesses the 5G base station 20, unlike the existing technology of accessing the 5G base station after accessing the 4G base station during initial network access. ) Simultaneous (both) access to 4G and 5G networks by performing access simultaneously (S130).

According to the network initial access method of the present invention, when the terminal device 100 is simultaneously (both) connected to the 4G and 5G networks (S130), it determines whether to maintain the connection with the 5G network according to the type of communication service (S150). ).

More specifically, when the type of communication service is an ultra-low-latency specific communication service (S150 Yes), the terminal device 100 maintains a connection with the 5G network.

In this case, the terminal device 100, when using a communication service by simultaneously (both) accessing 4G and 5G networks, transmits and receives radio resources with the 4G base station 10 for transmission and reception of control information (Control Plane) related to the 5G network. And, the radio resources with the 5G base station 20 are used for transmission and reception of data (User Plane) of the communication service (S180).

That is, according to the Non-Standalone technology, the terminal device 100 transmits and receives control information (Control Plane) related to the 5G network through the 4G network while securing seamless coverage by using 4G as the primary network, and transmits and receives 5G to the secondary network. It is a method of transmitting and receiving data (User Plane) of communication service through 5G network by using it as a network, and it uses communication service based on interworking between 4G and 5G networks.

On the other hand, when the type of communication service is not a specific communication service with ultra-low delay (S150 No), the terminal device 100 releases the connection to the 5G network (S160).

In this case, the terminal device 100 will use the radio resources with the 4G base station 10 to transmit and receive control information (Control Plane) and transmit and receive data (User Plane) of the communication service, and use the communication service through the 4G network. .

Hereinafter, with reference to FIG. 6, an initial network access method according to a second exemplary embodiment of the present invention will be described from the viewpoint of a terminal. For convenience of explanation, the terminal device 100 will be described as a terminal implementing the initial network access method of the present invention.

According to the network initial access method of the present invention, the terminal device 100 performs random access for establishing a connection with a 4G network through the 4G base station 10 when initial access to the network for communication service is used (S200). .

According to the network initial access method of the present invention, when a connection with a 4G network is established according to random access, the terminal device 100 sets radio resources to be used through the 4G base station 10 (RRC Connection). Procedure) is performed (S210).

At this time, according to the initial network access method of the present invention, the terminal device 100, when performing step S110, checks whether the type of communication service is a specific communication service with ultra-low delay (S215).

According to the network initial access method of the present invention, when the type of communication service is an ultra-low delay specific communication service (S215 Yes), radio resource setting with the 5G base station 20 is simultaneously performed. (S220).

In other words, according to the network initial access method of the present invention, the terminal device 100, when the connection with the 4G network is established according to the random access performed in step S200, the communication service to be used later is the ultra-low latency that requires the use of the 5G network. In the case of a specific communication service, when radio resources are set with the 5G base station 20 (S215 Yes and S220), radio resource settings with the 4G base station 10 (RRC Connection Procedure) are simultaneously performed separately (S210).

Here, the radio resource setting with the 5G base station 20 in step S220 is a time synchronization process with the 5G base station 20, the optimal beam between the multiple antenna beams of the 5G base station 20 and the multiple antenna beams of the terminal device 100 Includes the synchronization process.

Specifically, the radio resource setting with the 5G base station 20 is a time synchronization procedure (5G Synchronization Procedure, S32) with the 5G base station 20 that precedes the first, and a plurality of antenna beams and a terminal device of the 5G base station 20 It can be classified as an optimal beam synchronization process between multiple antenna beams of (100).

More specifically, the optimal beam synchronization process between the plurality of antenna beams of the 5G base station 20 and the plurality of antenna beams of the terminal device 100 may include multiple antenna beams of the 5G base station 20 and multiple antenna beams of the terminal device 100. In order to find the optimal beam pair (optimum beam) with the best channel state among them, the process of measuring the channel state for each beam pair and reporting the beam tracking result to the 4G base station 10 (Measurement Report), 4G base station (10) The process of receiving a response by requesting Cell Add from the 5G base station 20 based on the reported information, and determining the optimal beam pair (optimum beam), the optimal beam between the 5G base station 20 and the terminal device 100 It can be classified into an optimal beam synchronization process (Initial Access Procedure) that performs synchronization with respect to.

As described above, according to the network initial access method of the present invention, the terminal device 100 accesses the 4G base station 10 and accesses the 5G base station 20, unlike the existing technology of accessing the 5G base station after accessing the 4G base station during initial network access. ) Simultaneous access to (both) 4G and 5G networks is performed (S230).

According to the network initial access method of the present invention, when the terminal device 100 is simultaneously (both) connected to the 4G and 5G networks (S230), the radio resources with the 4G base station 10 are controlled by control information related to the 5G network. Plane) is used for transmission and reception, and radio resources with the 5G base station 20 are used for transmission and reception of data (User Plane) of a communication service (S240).

That is, according to the Non-Standalone technology, the terminal device 100 transmits and receives control information (Control Plane) related to the 5G network through the 4G network while securing seamless coverage by using 4G as the primary network, and transmits and receives 5G to the secondary network. It is a method of transmitting and receiving data (User Plane) of communication service through 5G network by using it as a network, and it uses communication service based on interworking between 4G and 5G networks.

On the other hand, the terminal device 100, when the type of the communication service is a specific communication service with ultra-low delay (S215 No), the radio resources with the 4G base station 10 control information (Control Plane) transmission and reception and data of the communication service. (User Plane) It is used for transmission and reception, and a communication service will be used through a 4G network (S250).

As described above, according to the present invention, upon initial network access of a terminal operating as a non-standalone using a communication service based on interworking between different heterogeneous networks (eg 4G/5G), 4G and 5G By realizing a method (technology) that minimizes the time required for connection by simultaneously accessing and prevents unnecessary 5G access from occurring (maintaining), the ultra-low latency service is provided even at the initial stage of network access. It derives the effect of providing maximum performance without performance degradation.

The initial network access method according to an embodiment of the present invention may be implemented in the form of program instructions 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 specially designed and configured for the present invention, or may be known and usable to those skilled in computer software. Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks, and magnetic tapes, optical media such as CD-ROMs and DVDs, and magnetic media such as floptical disks. -A hardware device specially configured to store and execute program instructions such as magneto-optical media, and ROM, RAM, flash memory, and the like. Examples of program instructions include not only machine language codes such as those produced by a compiler but also high-level language codes that can be executed by a computer using an interpreter or the like. The above-described hardware device may be configured to operate as one or more software modules to perform the operation of the present invention, and vice versa.

Although the present invention has been described in detail with reference to preferred embodiments so far, the present invention is not limited to the above-described embodiments, and the technical field to which the present invention belongs without departing from the gist of the present invention claimed in the following claims. Anyone of ordinary skill in the art will say that the technical idea of the present invention extends to the range in which various modifications or modifications are possible.

According to the terminal device and network initial access method according to the present invention, a method for minimizing the connection time required for initial network access of a non-standalone terminal is newly proposed. It is an invention that has industrial applicability because the possibility of commercialization or business of the applied device is sufficient as well as the degree to be practically clearly implemented, not just the use of the device.

100: terminal device
110: RA execution department 120,150: Simultaneous execution department
130: decision unit 140: communication control unit

Claims (11)

An RA performing unit performing random access for establishing a connection with the first network through the first access device upon initial access to the network for communication service use;
A simultaneous execution unit configured to simultaneously perform radio resource setting between the first network and another second network-based second access device when the radio resource is set with the first access device after performing the random access; And
When the radio resource setting with the first access device and radio resource setting with the second access device are completed and connected to the first and second networks, connection with the second network is maintained according to the type of communication service A terminal device comprising a determining unit to determine whether or not. The method of claim 1,
The second network,
And a network capable of supporting a specific communication service of Ultra Reliable & Low Latency Communication (URLLC) compared to the first network. The method of claim 2,
The determination unit,
A terminal device, characterized in that, when the type of the communication service is the specific communication service, the connection with the second network is maintained, and when the communication service is not the specific communication service, the connection with the second network is released. The method of claim 1,
When using the communication service by simultaneously accessing the first and second networks,
And a communication control unit that uses radio resources with the first access device to transmit and receive control information related to the second network, and uses radio resources with the second access device to transmit and receive data of the communication service. Terminal device characterized by. The method of claim 1,
The simultaneous execution unit,
When information on the second network-based second access device capable of simultaneous access with the first access device is previously registered, radio resource setting with the second access device is performed based on the previously registered information. Terminal equipment. The method of claim 1,
Radio resource setting with the second access device,
And a process of synchronizing time with the second access device and an optimal beam synchronization process between multiple antenna beams of the second access device and multiple antenna beams of the terminal device. delete ◈ Claim 8 was abandoned upon payment of the set registration fee. In the initial network access method performed in the terminal,
An RA performing step of performing random access for establishing a connection with a first network through a first access device upon initial access to a network for communication service use;
A simultaneous performing step of simultaneously performing radio resource setting with the first network and a second network-based second access device other than the first network when the radio resource is set with the first access device after performing the random access; And
When the radio resource setting with the first access device and radio resource setting with the second access device are completed and connected to the first and second networks, connection with the second network is maintained according to the type of communication service And a maintenance decision step of determining whether or not to access a network. ◈ Claim 9 was abandoned upon payment of the set registration fee. The method of claim 8,
The second network,
A network initial access method, characterized in that it is a network capable of supporting a specific communication service of Ultra Reliable & Low Latency Communication (URLLC) compared to the first network. ◈ Claim 10 was abandoned upon payment of the set registration fee. The method of claim 9,
The maintenance determination step,
When the type of the communication service is the specific communication service, the connection with the second network is maintained, and when the communication service is not the specific communication service, the connection with the second network is released. ◈ Claim 11 was abandoned upon payment of the set registration fee. The method of claim 8,
When using the communication service by simultaneously accessing the first and second networks,
And using a radio resource with the first access device for transmitting and receiving control information related to the second network, and using a radio resource with the second access device for transmitting and receiving data of the communication service. Network initial access method.

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