JP6877320B2 - Base station equipment, terminal equipment, control methods and programs - Google Patents

Description

The present invention relates to an interference control technique in a wireless communication system.

In the 3rd Generation Partnership Project (3GPP), the 5th generation (NR, New Radio) communication system is being studied. In particular, a study on a configuration in which a terminal establishes a connection in the form of Dual Connectivity in which a conventional LTE (Long Term Evolution) base station (eNB) is used as a master base station and an NR base station (gNB) is used as a secondary base station. Is progressing. This configuration is called NSA (Non Standalone) because the gNB does not independently connect to a terminal that is not connected to the eNB.

3GPP, RP-171485

It is being considered that NR is used for applications such as touchless entry and exit of a specific facility. In such a case, when a terminal enters a specific gNB area, the gNB is immediately used. You need to establish a connection with the terminal. However, the establishment of such a connection needs to be led by the eNB, which is the master base station, but the eNB cannot recognize that the terminal in the IDLE state has entered the area of the gNB, and the connection cannot be established. Can not be established immediately.

The present invention has been made in view of such a problem, and provides a technique for establishing a connection between a terminal and a base station at high speed when a terminal in an IDLE state enters an area of a specific base station. The purpose.

The base station apparatus according to an aspect of the present invention, there is provided a first information specifies at least one or more of the first other base station apparatus, it has been the first other designated by the first information When the terminal device in the IDLE state enters the area provided by one of the other base station devices, the base station device is notified of the second information regarding the other base station device . When the terminal device in the IDLE state enters the area provided by the second other base station device that is not designated by the first information, the second information regarding the second other base station device is displayed. At least a communication means for transmitting the first information that is not notified to the base station device to the terminal device and receiving the second information from the terminal device and receiving the second information from the terminal device. Based on this, it has a control means for executing control as a master base station for establishing a connection with the terminal device by using the other base station device notified by the second information as a secondary base station.

Further, the terminal device according to one aspect of the present invention is based on a receiving means for receiving at least one first information designating one or more first other base station devices from the base station device, and the first information. When entering the area provided by one of the designated first other base station devices in the IDLE state, the second information regarding the one other base station device is transmitted to the base. When the terminal device in the IDLE state enters the area provided by the second other base station device that has notified the station device and is not designated by the first information, the second other base station. The notification means that does not notify the base station device of the second information about the device, and the other one that is notified by the second information by controlling the base station device as a master base station in response to the notification. The base station apparatus is used as a secondary base station, and has a connecting means for connecting to the other base station apparatus.

According to the present invention, when a terminal in the IDLE state enters the area of a specific base station, the connection between the terminal and the base station can be established at high speed.

The figure which shows the configuration example of a wireless communication system. The figure which shows the hardware configuration example of a device. The block diagram which shows the functional configuration example of a base station apparatus. A block diagram showing an example of a functional configuration of a terminal device. A sequence diagram showing an example of a processing flow executed in a wireless communication system.

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

(System configuration)
FIG. 1 shows a configuration example of the wireless communication system according to the present embodiment. The wireless communication system includes a long-term evolution (LTE) base station device (eNB101) and a next-generation communication standard (New Radio, NR) base station device (gNB102 and gNB103). The terminal device (UE104) is a mobile wireless communication terminal. In the present embodiment, the gNB 102 and the gNB 103 do not independently provide the communication service, but can provide the communication service to the UE 104 that has established a connection with the eNB 101 under the control of the eNB 101. When the UE 104 is not in the IDLE state but in the ACTIVE state, the eNB 101 can establish a connection in the form of Dual Connectivity with the eNB 101 as the master base station and the gNB 102 or gNB 103 as the secondary base station.

Here, when the UE 104 enters the area of a specific gNB 102 for a local service such as touchless entry / exit to a facility, the UE 104 needs to immediately establish a connection with the gNB 102. Suppose there is. Here, when the eNB 101 detects that the UE 104 has entered the service area of the gNB 102, the eNB 101 can establish a connection between the UE 104 and the gNB 102 accordingly. Since the eNB 101 can receive the Measurement Report (MR) from the UE 104 when the UE 104 is in the ACTIVE state, it can detect that the UE 104 has entered the service area of the gNB 102. On the other hand, when the UE 104 is in the IDLE state, the eNB 101 cannot receive notifications such as MR from the UE 104, and therefore cannot detect that the UE 104 has entered the service area of the gNB 102. As a result, the eNB 101 cannot establish a connection between the UE 104 and the gNB 102 when the UE 104 in the IDLE state enters the service area of the gNB 102.

On the other hand, when the UE 104 enters the service area of one of the gNBs, the state transitions to the ACTIVE state and the MR is transmitted to the eNB 101, so that the eNB 101 can use the UE 104 and its gNB. The connection between can be established. However, in this case, the UE 104 transitions from the IDLE state to the ACTIVE state even when entering the service area of the gNB 103 that does not need to be connected as well as the gNB 102 that needs to be connected. As a result, the power consumption of the UE 104 may increase, and unnecessary MR-related signaling may result in wasted radio resources. Therefore, in the present embodiment, the eNB 101 detects that the UE 104 in the IDLE state has entered the service area of the gNB 102, which can be the target for the UE 104 to immediately establish a connection, without such an increase in power consumption or waste of wireless resources. Make it possible.

In one example, the eNB 101 notifies the UE 104 of a first piece of information designating one or more gNBs (gNB102) for which a connection should be established immediately upon entry. The gNB (gNB at least the connection should be established immediately) is, for example, information that can identify itself (gNB ID, etc.) together with or separately from the notification of Radio Frame Timing and System Frame Number (SFN). ) Can be notified. By receiving this broadcast information, the UE 104 can identify the ID of the gNB existing in the surroundings. Here, the first information may be, for example, information for transitioning the UE 104 that has entered the designated gNB service area in the IDLE state to the ACTIVE state. By transitioning to the ACTIVE state, the UE 104 measures the radio quality of the gNB that provides the service area that has entered, and notifies the eNB 101 of the MR including the measurement result and the identification information of the gNB. The first information may be, for example, information that causes the UE 104 that has entered the designated gNB service area in the IDLE state to notify the identification information such as the gNB ID (for example, without converting it to ACTIVE). Good. When the UE 104 detects the gNB designated in the IDLE state by the above-mentioned notification signal, the UE 104 notifies the eNB 101 of the ID of the gNB included in the notification signal. At this time, the UE 104, for example, transitions to the RRC_INACTIVE state in which a small amount of data can be newly transmitted, and notifies the ID of the gNB. By notifying the gNB ID without the UE 104 transitioning to the ACTIVE state, for example, the eNB 101 does not establish a connection with the UE 104 when the notified gNB is congested, and puts the UE 104 in the non-ACTIVE state as it is. You can stay. As a result, the UE 104 does not unnecessarily transition to the ACTIVE state, so that the power consumption of the UE 104 can be reduced. Further, the UE 104 may transition to the ACTIVE state and notify the ID of the gNB. In either case, when the UE 104 receives the notification of the first information and enters the service area of one or more gNBs specified by the first information in the IDLE state, the 1 Notify the eNB 101 of the second information regarding the two gNBs.

In this way, the eNB 101 can detect that the UE 104 has entered the service area of the designated gNB (gNB 102) by receiving the second information. Then, the eNB 101 executes the control for establishing the connection between the gNB 102 and the UE 104 notified by the UE 104, at least based on the receipt of this second information. For example, the eNB 101 uses its own device as a master base station and gNB 102 as a secondary base station to execute control for establishing a connection with the UE 104 using the dual connectivity mechanism. The eNB 101 may establish a connection between the UE 104 and the gNB 102 by other control.

Further, the eNB 101 does not necessarily have to establish a connection between the gNB 102 and the UE 104 in response to receiving the second information. For example, the eNB 101 establishes a connection between the UE 104 and the gNB indicated by the second information when there are many other UEs in the service area of the gNB indicated by the second information received from the UE 104. It does not have to be. Thereby, the eNB 101 may wait for receiving the second information about another gNB from the UE 104, for example, and connect the UE 104 with the gNB. According to such processing, for example, when a plurality of gNBs exist along a passage in a touchless entrance / exit system of a facility, a large number of UEs visiting the facility are distributed and connected to the plurality of gNBs. You will be able to do it. Further, the eNB 101 may execute a control for establishing a connection between the gNB and the UE 104 when the second information regarding the same gNB is received a predetermined number of times. According to this, for the UE 104 staying in a certain area for a long period of time, it is possible to establish a connection with the gNB that provides the area even when the area is congested, while the area can be used. It is possible to prevent the connection from being established for the passing UE.

The first information includes information that specifies the processing that the UE 104 should execute for transmitting the second information (for example, the transition to the ACTIVE state described above and the notification of the gNB ID). May be good. However, if the process to be executed by the UE 104 for transmitting the second information is uniquely determined, the specification of such process may be omitted. That is, even if the first information includes only information that specifies one or more gNBs for which information such as identification information should be notified when the UE 104 enters the service area in the IDLE state among the plurality of gNBs. Good.

The first information can be simultaneously notified to each UE 104 in the service area of the eNB 101 by a broadcast signal (for example, System Information Block (SIB)). According to this, the first information can be notified to a large number of UEs 104 with high radio resource utilization efficiency. In addition, the first information may be individually notified to each UE (while each UE is in the ACTIVE state) by individual signaling (individual control signals) such as RRC signaling. According to this, the eNB 101 can perform fine control, and can identify the gNB that gives a trigger for transmitting the second information for each UE, for example. According to this, it is possible to prevent the load from being concentrated only on a part of the gNBs existing in the vicinity of each other in advance. In this case, the UE 104 may move to another eNB service area in the IDLE state after acquiring the first information. Therefore, the eNB 101 may notify the first information about the gNB existing in the TA (Tracking Area) to which the own device belongs. That is, when the UE 104 moves across the TA, it once transitions to the ACTIVE state and communicates with the eNB. Therefore, by notifying the UE 104 of the first information for each TA, the UE 104 receives the above-mentioned second information in response to entering the service area of the gNB that needs to establish a connection immediately. You will be able to send. In this case, for example, an eNB whose service area is an area around a predetermined facility may use a TAC (TAC Code) different from that of an eNB whose service area is another area. As a result, it is possible to reduce the gNB information notified at once by the first information. That is, for areas where gNBs to be notified are sparsely distributed, the first information regarding gNBs in a large number of eNB service areas is collectively notified, and for areas where such gNBs are densely distributed, they are individually notified. The TA can be set to collectively notify the first piece of information. As a result, it is possible to suppress an increase in the amount of information of the first information and to perform fine control even when the UE moves in the IDLE state.

Hereinafter, the configurations of the base station devices (eNB, gNB) and the terminal devices (UE) that execute such processing, and an example of the flow of the processing executed by these devices will be described.

(Hardware configuration)
FIG. 2 shows an example of hardware configuration of a base station device and a terminal device. In one example, the base station device and the terminal device have a hardware configuration as shown in FIG. 2, and include, for example, a CPU 201, a ROM 202, a RAM 203, an external storage device 204, and a communication circuit 205. In the base station device and the terminal device, the CPU 201 executes, for example, a program recorded in any one of the ROM 202, the RAM 203, and the external storage device 204, which realizes each function of the base station device and the terminal device as described above.

Then, the base station device and the terminal device control the communication circuit 205 by, for example, the CPU 201 to communicate with other devices. The communication circuit 205 of the base station device can communicate with another base station device, for example, through a wired line. Further, the communication circuit 205 of the base station apparatus may be capable of forming one or more (plural) beams and wirelessly communicating with the terminal apparatus. Further, in this case, the communication circuit 205 of the terminal device is configured to be connectable to at least one of the beams formed by the communication circuit 205 of the base station device, and wirelessly communicates with the base station device using these beams. It is configured to be able to. In the configuration of FIG. 2, the base station device and the terminal device are shown in a schematic diagram such that they have one communication circuit 205, but the present invention is not limited to this, and a plurality of communication circuits may be provided. For example, a base station device may have a first communication circuit for wired communication with another base station device and a second communication circuit for wireless communication with the terminal device. Further, the terminal device may have, for example, a first communication circuit for LTE and a second communication circuit for NR. Further, the terminal device may have a wireless communication circuit related to a standard other than cellular such as a wireless LAN, and may further have a wired communication circuit used for a wired connection such as a USB connection.

The base station device and the terminal device may be provided with dedicated hardware for executing each function, or a part of the base station device and the terminal device may be executed by the hardware and the other part may be executed by the computer running the program. .. Also, all functions may be performed by a computer and a program.

(Functional configuration)
FIG. 3 is a diagram showing a functional configuration example of the eNB 101 according to the present embodiment. The eNB 101 has a communication unit 301, an information generation unit 302, and a control unit 303 as an example of its function. Note that this functional configuration example is an example, and the eNB 101 naturally has a function (not shown) as a general LTE base station device, and may have a further function. The communication unit 301 performs wireless communication with the UE 104 and wired or wireless communication between the gNB 102 and the gNB 103. The information generation unit 302 generates first information that specifies the gNB (gNB102) to which the UE 104 should immediately establish a connection. The control unit 303 operates as a master base station device and executes control for establishing a Dual Connectivity-based connection with the UE 104 using the gNB 102 or gNB 103 as the secondary base station device.

The eNB 101 transmits the first information generated by the information generation unit 302 to the UE 104 via, for example, the communication unit 301, by a broadcast signal such as SIB, or by individual signaling (individual control signal) such as RRC signaling. And send. After that, the eNB 101 receives the second information transmitted from the UE 104 in response to the UE 104 (for example, in the IDLE state) entering the service area of the gNB specified by the first information via the communication unit 301. To do. When the eNB 101 receives the second information, the control unit 303 establishes the connection between the gNB and the UE 104 indicated by the second information. For example, the eNB 101 performs predetermined communication with the gNB to be connected and the UE 104 based on the connection sequence of the Dual Connectivity, and executes additional processing of the secondary base station apparatus. Since this additional processing can be executed according to the processing sequence specified in 3GPP, detailed description of the processing will be omitted.

Although not shown, gNB102 and gNB103 have a function as, for example, a general NR base station device. However, the gNB 102 and the gNB 103 are configured to be able to transmit a signal for notifying the UE 104 in the IDLE state of identification information such as the ID of its own device. For example, the gNB 102 and the gNB 103 can transmit the identification information of the own device together with or separately from the notification of the Radio Frame Timing and the System Frame Number (SFN).

FIG. 4 is a diagram showing a functional configuration example of the UE 104 according to the present embodiment. The UE 104 has a communication unit 401, an information acquisition unit 402, a detection unit 403, and a notification processing unit 404 as an example of its function. Note that this functional configuration example is an example, and the UE 104 naturally has a function (not shown) as a terminal device conforming to general LTE and NR, and may have a further function.

The communication unit 401 wirelessly communicates with the eNB 101 or gNB 102 or gNB 103. The information acquisition unit 402 acquires the first information transmitted from the eNB 101 via the communication unit 401, and sets, for example, the information of one or more gNBs specified in the first information in the detection unit 403. .. Further, the information acquisition unit 402 specifies the process to be executed when the UE 104 detects the gNB specified in the IDLE state (for example, transition to the ACTIVE state or notification of the detected gNB) by the first information. If so, the process is set in the notification processing unit 404. If the process to be executed is uniquely determined, the setting for the notification processing unit 404 may not be performed. The detection unit 403 monitors radio waves arriving at an antenna (not shown) through the communication unit 401, and has received a signal from the gNB specified by the first information, that is, the UE 104 within the service area of such a gNB. Determines whether or not has entered. When the UE 104 is operating in the ACTIVE state, the detection unit 403 detects a base station device existing in the vicinity regardless of the first information.

When the detection unit 403 detects a gNB (for example, gNB 102 or gNB 103) or another eNB when the UE 104 is operating in the ACTIVE state, the communication unit 401 transmits a radio quality measurement report (MR) to the eNB 101. .. In this case, the eNB 101 can establish a Dual Connectivity-based connection between the UE 104 and the gNB based on this MR. According to this, the UE 104 can perform high-speed and large-capacity communication by connecting with a gNB (for example, gNB 103) not specified by the first information, for example.

On the other hand, when the detection unit 403 detects the gNB specified by the first information while the UE 104 is in the non-ACTIVE state, the notification processing unit 404 notifies the eNB 101 of the information (for example, identification information) regarding the detected gNB. Execute the processing for. The notification processing unit 404, for example, shifts the UE 104 to the ACTIVE state. In this case, the UE 104 will transmit the measurement report (MR) regarding the radio quality of the gNB specified by the first information to the eNB 101 after the transition to the ACTIVE state. Further, the notification processing unit 404 can execute a process of notifying the eNB 101 of gNB information, for example, without transitioning to the ACTIVE state (for example, transitioning to the RRC_INA ACTIVE state or the like). The information about the gNB may be not only information that can uniquely identify the gNB such as an ID, but also information such as a group number that is collectively assigned to a plurality of gNBs.

(Processing flow)
Subsequently, with reference to FIG. 5, the flow of processing executed in the wireless communication system according to the present embodiment will be described. In the process of FIG. 5, the UE 104 is assumed to be in the IDLE state unless otherwise specified. In this process, first, the eNB 101 includes information on the gNB (notification target gNB) to be notified when the eNB 101 enters the service area in the IDLE state to the UE 104 existing in the service area of the own device. Information is transmitted (S501). In the example of FIG. 5, it is assumed that gNB 102 is designated as the notification target gNB by the first information, and gNB 103 is not designated. In addition, in one example, the transmission of the first information may be performed by a broadcast signal such as SIB, or may be performed by individual signaling such as RRC signaling performed in the UE 104 in the ACTIVE state. In addition, the first information may include information that specifies a process to be executed for notification of information about the gNB when the UE 104 enters the service area of the notification target gNB. The process to be executed includes, for example, a process of transitioning from the IDLE state to the ACTIVE state and a process of notifying the gNB ID without transitioning to the ACTIVE state.

Upon receiving the first information, the UE 104 starts monitoring whether or not the user has entered the service area of the notification target gNB. In this state, it is assumed that the UE 104 has entered the service area of the gNB 103, for example. In this case, the UE 104 can receive, for example, a signal including the identification information (gNB ID) of the gNB 103 (S502). As an example, this signal shall be transmitted together with Radio Frame Timing and System Frame Number. Upon receiving this signal, the UE 104 determines, for example, whether its gNB ID matches the gNB ID of the notification target gNB acquired by the first information. In this case, since the gNB 103 is not the notification target gNB, the UE 104 does not notify the eNB 101.

After that, it is assumed that the UE 104 moves and enters the service area of the gNB 102. In this case, the UE 104 can receive, for example, a signal including the identification information (gNB ID) of the gNB 102 (S503). In this case, since the gNB 102 is the notification target gNB, the UE 104 executes the notification process of the information regarding the gNB 102 to the eNB 101 (S504). For example, the UE 104 transitions to the ACTIVE state and transmits MR to the eNB 101. Further, the UE 104 notifies the eNB 101 of information such as the gNB ID without transitioning to, for example, the ACTIVE state. As a result, the eNB 101 detects that the UE 104 has entered the service area of the gNB for which the connection should be established immediately, establishes a Dual Connectivity-based connection between the UE 104 and the gNB 102, and provides the communication service (S505). ). Since the process of S505 is executed in the same manner as the connection establishment process in the existing Dual Connectivity, detailed description here will be omitted.

In this way, the eNB 101 causes the UE 104 that has entered the service area of the predetermined gNB (gNB 102) in the IDLE state to notify the information regarding the gNB. As a result, the eNB 101 can recognize that the UE 104 has entered the area where the connection with the gNB should be established, and can immediately execute the control for establishing the connection between the gNB and the UE 104.

The above-mentioned systems and terms are examples, and do not limit the present invention. For example, the process of establishing a connection between the UE and the gNB by operating the LTE eNB as a master base station and the NR gNB as a secondary base station has been described, but the process is not limited to this, and LTE and NR are not limited to this. The present invention may be applied in systems other than the above. Further, the connection between the gNB and the UE does not have to be made based on the Dual Connectivity, and any connection process can be executed.

Claims (14)

It ’s a base station device,
A first information specifies at least one or more of the first other base station apparatus, one other base of said first of said designated by the information first other base station apparatus When the terminal device in the IDLE state enters the area provided by the station device, the base station device is notified of the second information regarding the one other base station device , and the first information is not specified. When the terminal device in the IDLE state enters the area provided by the other base station device of 2, the first information is not notified to the base station device regarding the second other base station device . A communication means that transmits information to a terminal device and receives the second information from the terminal device.
A master base for establishing a connection with the terminal device by using another base station device notified by the second information as a secondary base station, at least based on receiving the second information from the terminal device. A control means that executes control as a station,
A base station apparatus characterized by having. The first information is a process to be executed in order for the terminal device to transmit the second information when the terminal device enters the area provided by the first other base station device in the IDLE state. Contains information that specifies
The base station apparatus according to claim 1. The first information is a process in which the terminal device transitions from the IDLE state to the ACTIVE state, or a process in which the terminal device transmits identification information of the one other base station device, as the process to be executed. Contains the information you specify,
The base station apparatus according to claim 2. The communication means transmits the first information by a broadcast signal.
The base station apparatus according to any one of claims 1 to 3. The communication means transmits the first information by individual control signals.
The base station apparatus according to any one of claims 1 to 3. It ’s a terminal device,
A receiving means for receiving a first piece of information from a base station device that designates at least one or more first other base station devices.
When entering the area provided by one of the other base station devices of the first other base station device designated by the first information in the IDLE state, the first related to the other base station device. When the terminal device in the IDLE state enters the area provided by the second other base station device which has notified the information of 2 to the base station device and is not designated by the first information, the first information is concerned. A notification means that does not notify the base station device of the second information regarding the other base station device of 2.
By controlling the base station device as a master base station in response to the notification, the one other base station device notified by the second information is used as a secondary base station and connected to the other base station device. Connection method and
A terminal device characterized by having. The first information is a process to be executed in order for the terminal device to transmit the second information when the terminal device enters the area provided by the first other base station device in the IDLE state. Contains information that specifies
The notification means executes the designated process and notifies the base station apparatus of the second information.
The terminal device according to claim 6. The first information is a process in which the terminal device transitions from the IDLE state to the ACTIVE state, or a process in which the terminal device transmits identification information of the one other base station device, as the process to be executed. Contains the information you specify,
The terminal device according to claim 7. The receiving means receives the first information by a broadcast signal.
The terminal device according to any one of claims 6 to 8. The receiving means receives the first information by individual control signals.
The terminal device according to any one of claims 6 to 8. A control method performed by a base station device,
A first information specifies at least one or more of the first other base station apparatus, one other base of said first of said designated by the information first other base station apparatus When the terminal device in the IDLE state enters the area provided by the station device, the base station device is notified of the second information regarding the one other base station device , and the first information is not specified. When the terminal device in the IDLE state enters the area provided by the other base station device of 2, the first information is not notified to the base station device regarding the second other base station device . A communication process in which information is transmitted to a terminal device and the second information is received from the terminal device.
Based at least on the front SL terminal to receiving the second information, the master for establishing a connection with the terminal device notified another base station apparatus in the second information as the secondary base station A control process that executes control as a base station,
A control method characterized by having. A control method performed by a terminal device
From group Chikyoku device, a reception step of receiving first information specifies at least one or more of the first other base station apparatus,
When entering in the IDLE state before Symbol areas subjecting one other base station apparatus of the first of said first specified by the information of the other base station apparatus, relating to the one other base station apparatus A notification process for notifying the base station device of the second information, and
Under the control of the master base station of the base station apparatus according to the prior SL notification, the one other base station apparatus notified by the second information as the secondary base station, and the one other base station apparatus The connection process to connect and
Have a,
In the notification step, when the terminal device in the IDLE state enters the area provided by the second other base station device not designated by the first information, the second other base station device is related to the above. A control method characterized in that the second information is not notified to the base station apparatus. On the computer installed in the base station equipment,
A first information specifies at least one or more of the first other base station apparatus, one other base of said first of said designated by the information first other base station apparatus When the terminal device in the IDLE state enters the area provided by the station device, the base station device is notified of the second information regarding the one other base station device , and the first information is not specified. When the terminal device in the IDLE state enters the area provided by the other base station device of 2, the first information is not notified to the base station device regarding the second other base station device . Send information to the terminal device
The second information is received from the terminal device, and the second information is received from the terminal device.
A master base for establishing a connection with the terminal device by using another base station device notified by the second information as a secondary base station, at least based on receiving the second information from the terminal device. To execute control as a station,
Program for. To the computer installed in the terminal device
Receive a first piece of information from a base station device that specifies at least one or more first other base station devices.
When entering the area provided by one of the other base station devices of the first other base station device designated by the first information in the IDLE state, the first related to the other base station device. When the terminal device in the IDLE state enters the area provided by the second other base station device which is not designated by the first information and notifies the base station device of the information of 2. Without notifying the base station apparatus of the second information regarding the other base station apparatus of 2.
By controlling the base station device as a master base station in response to the notification, the one other base station device notified by the second information is used as a secondary base station and connected to the other base station device. Let,
Program for.

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