JP7010297B2 - Base station equipment, wireless communication system and connection setting method - Google Patents

Description

The present invention relates to a base station device, a terminal device, a wireless communication system, and a connection setting method.

In recent years, a base station device provided in a wireless communication system has been separated into a wireless control device such as a BBU (Base Band Unit) and a wireless device such as an RRH (Remote Radio Head), and the wireless control device and the wireless device are, for example. It may be connected by an interface such as CPRI (Common Public Radio Interface). Further, in 3GPP, the base station device is separated into a CU (Central Unit), which is a wireless control device that controls various things, and a DU (Distributed Unit), which is a wireless device that wirelessly transmits and receives signals, and the CU and DU are separated. Connection by F1 interface is being considered.

By separating the functions of the base station equipment in this way, for example, by connecting a plurality of DUs to one CU and arranging the DUs in a distributed manner, it is possible to construct a wireless communication system that covers a large area at low cost. Is possible.

By the way, in general, the function of the base station apparatus includes processing of a PDCP (Packet Data Convergence Protocol) layer, an RLC (Radio Link Control) layer, a MAC (Media Access Control) layer, and a physical layer in order from the upper layer. In the 5th generation (5G) wireless communication system under consideration by 3GPP, it is possible to introduce the processing of the SDAP (Service Data Adaptation Protocol) layer, which is the upper layer of the PDCP layer, into the function of the user plane (U plane). It is being discussed.

When the base station equipment is functionally separated into CU and DU, the HLS (High Layer Split) that separates between the PDCP layer and the RLC layer, and the space between the MAC layer and the physical layer or the physical layer are divided into two. LLS (Low Layer Split) to separate is being studied.

Special Table 2017-510157

3GPP TR 38.801 V14.0.0 (2017-03) 3GPP TR 38.912 V14.0.0 (2017-03)

When the base station equipment is functionally separated into CU and DU, it is preferable to perform functional separation suitable for the required service quality and communication conditions. For example, in a service such as URLLC (Ultra-Reliable and Low Latency Communications) that requires low latency, an HLS in which an RLC layer and a MAC layer related to data retransmission control are mounted on each DU is preferable. This is because the retransmission control is possible in each DU, so that the data can be retransmitted at high speed, and it is easy to achieve a low delay.

On the other hand, by adopting LLS in which only the physical layer is mounted on each DU, the production cost of the DU can be reduced, and the cost of the wireless communication system can be reduced. As described above, since HLS connecting the higher layer with the F1 interface and LLS connecting the lower layer with the F1 interface have advantages and disadvantages, functional separation by HLS and LLS may coexist in one wireless communication system. Conceivable. Further, it is conceivable that functional separation by a plurality of LLS having different separation points between the upper layer and the lower layer of the physical layer coexist.

However, in a wireless communication system in which HLS and LLS are mixed or a wireless communication system in which a plurality of LLS are mixed, there is no study on a method of setting an F1 interface for connecting CU and DU. Therefore, there is a problem that it is difficult to set the interface between the CU and the DU.

The disclosed technology is made in view of the above points, and provides a base station device, a terminal device, a wireless communication system, and a connection setting method capable of setting an optimum interface for connecting a wireless control device and a wireless device. The purpose is to provide.

The base station device disclosed in the present application is, in one embodiment, a base station device including a wireless control device and a wireless device and communicating with a terminal device, and the wireless device provides functional information regarding the function of the own device. The wireless control device has a generation unit to generate, and the wireless control device acquires a request unit that requests a higher-level device to establish a session corresponding to the service requested by the terminal device , and functional information generated by the generation unit. Connection between the wireless control device and the wireless device based on the functional information acquired by the acquisition unit or based on the service quality or communication conditions required for the service after the session is established. It has a connection control unit that controls.

According to one aspect of the base station device, the terminal device, the wireless communication system, and the connection setting method disclosed in the present application, it is possible to set an optimum interface for connecting the wireless control device and the wireless device.

FIG. 1 is a diagram showing an example of a configuration of a wireless communication system. FIG. 2 is a block diagram showing the configuration of the base station apparatus according to the first embodiment. FIG. 3 is a diagram showing a specific example of functional information. FIG. 4 is a diagram showing another specific example of functional information. FIG. 5 is a block diagram showing another configuration of the base station apparatus according to the first embodiment. FIG. 6 is a block diagram showing the configuration of the terminal device according to the first embodiment. FIG. 7 is a sequence diagram showing an interface setting method according to the first embodiment. FIG. 8 is a block diagram showing still another configuration of the base station apparatus according to the first embodiment. FIG. 9 is a block diagram showing still another configuration of the base station apparatus according to the first embodiment. FIG. 10 is a sequence diagram showing another interface setting method according to the first embodiment. FIG. 11 is a sequence diagram showing an interface setting method according to the second embodiment. FIG. 12 is a block diagram showing the configuration of the base station apparatus according to the third embodiment. FIG. 13 is a block diagram showing another configuration of the base station apparatus according to the third embodiment. FIG. 14 is a sequence diagram showing an interface setting method according to the third embodiment. FIG. 15 is a block diagram showing the configuration of the base station apparatus according to the fourth embodiment. FIG. 16 is a sequence diagram showing an interface setting method according to the fourth embodiment.

Hereinafter, embodiments of the base station device, the terminal device, the wireless communication system, and the connection setting method disclosed in the present application will be described in detail with reference to the drawings. The present invention is not limited to this embodiment.

(Embodiment 1)
FIG. 1 is a diagram showing an example of a configuration of a wireless communication system. In the wireless communication system shown in FIG. 1, the base station device 100 is connected to the core network, and the base station device 100 and the terminal device (UE: User Equipment) 200 communicate wirelessly.

The core network includes UPF (User Plane Function) 11, AMF (Access and Mobility Management Function) 12, SMF (Session Management Function) 13, PCF (Policy Control Function) 14, AUSF (Authentication Server Function) 15 and UDM (Unified). Data Management) 16 is arranged.

The UPF 11 is a device that controls the user plane, and executes routing and transfer of user data. The AMF 12 is a device that controls the control plane and terminates the control plane in a radio access network (RAN). SMF13 manages sessions. The PCF 14 provides policy rules and the like regarding the control plane. AUSF15 performs authentication processing of UE200. The UDM 16 stores subscriber information and the like.

The base station apparatus 100 is connected to UPF11 and AMF12 of the core network, and wirelessly communicates with the UE 200. The base station device 100 is functionally separated into a CU, which is a wireless control device that controls wireless communication, and a DU, which is a wireless device that executes wireless communication. Then, the CU which is a wireless control device is connected to the UPF11 and the AMF12, and the DU which is a wireless device wirelessly communicates with the UE 200. The base station device 100 does not necessarily have to have one wireless control device and one wireless device, and may have a plurality of wireless control devices or a plurality of wireless devices. Further, the wireless control device and the wireless device constituting the base station device 100 may be arranged at remote locations from each other. The wireless control device and the wireless device are connected by an interface such as an F1 interface.

FIG. 2 is a block diagram showing a configuration of the base station apparatus 100 according to the first embodiment. The base station device 100 shown in FIG. 2 has a radio control device 110 corresponding to a CU and a radio device 120 corresponding to a DU.

The wireless control device 110 is connected to UPF11 and AMF12 of the core network, and controls wireless communication by the wireless device 120. Specifically, the wireless control device 110 includes a PDCP processing unit 111, an RLC processing unit 112, a MAC processing unit 113, a function information acquisition unit 114, an interface control unit (hereinafter abbreviated as “IF control unit”) 115, and a switching unit. Has 116.

The PDCP processing unit 111 executes processing of the PDCP layer such as data ordering and header compression, for example. That is, the PDCP processing unit 111 executes the processing of the PDCP layer on the transmission signal acquired from the UPF 11 or AMF 12, and outputs the transmission signal to the RLC processing unit 112 or the wireless device 120 via the switching unit 116. Further, the PDCP processing unit 111 acquires a received signal from the wireless device 120 or the RLC processing unit 112 via the switching unit 116, and executes the processing of the PDCP layer on the received signal.

The RLC processing unit 112 executes processing of the RLC layer such as retransmission control. That is, the RLC processing unit 112 acquires a transmission signal from the PDCP processing unit 111 via the switching unit 116, and executes RLC layer processing on the transmission signal. Further, the RLC processing unit 112 acquires a received signal from the MAC processing unit 113 and executes RLC layer processing on the received signal.

The MAC processing unit 113 executes processing of the MAC layer such as scheduling and retransmission control. That is, the MAC processing unit 113 acquires the transmission signal from the RLC processing unit 112 and executes the processing of the MAC layer on the transmission signal. Further, the MAC processing unit 113 acquires a received signal from the wireless device 120 and executes processing of the MAC layer on the received signal.

The function information acquisition unit 114 acquires functional information indicating the function of the wireless device 120 from the wireless device 120 connected to the wireless control device 110. Specifically, the functional information acquisition unit 114 acquires functional information indicating the type of interface that can be set by the wireless device 120, the type of service supported by the wireless device 120, and the like.

FIG. 3 is a diagram showing a specific example of functional information. The upper figure of FIG. 3 is an example of functional information indicating the types of interfaces that can be set. There are seven types of functional information shown in the upper figure of FIG. 3 from category "0" to category "6", and in each category, whether or not the wireless device 120 can support HLS (High Layer Split). , Whether or not it is compatible with LLS (Low Layer Split), and whether or not it is compatible with CPRI is shown.

For example, if the wireless device 120 has an RLC processing unit, a MAC processing unit, and a physical layer processing unit, an HLS that sets an interface between the PDCP processing unit 111 of the wireless control device 110 and the RLC processing unit of the wireless device 120. Is possible. Further, if the wireless device 120 has a physical layer processing unit, an LLS that sets an interface between the MAC processing unit 113 of the wireless control device 110 and the physical layer processing unit of the wireless device 120 is possible. For example, in the functional information of the category "0", "1" indicates that the wireless device 120 is compatible with HLS, and "0" indicates that the wireless device 120 is not compatible with LLS and CPRI. ing.

The middle figure of FIG. 3 is an example of functional information indicating the type of corresponding service. There are seven types of functional information shown in the middle diagram of FIG. 3, from category "a" to category "g". In each category, whether or not the wireless device 120 can support eMBB (enhanced Mobile BroadBand). , It is shown whether or not it is compatible with URLLC (Ultra-Reliable and Low Latency Communications) and whether or not it is compatible with mMTC (massive Machine Type Communications). For example, in the functional information of the category "a", "1" indicates that the wireless device 120 is compatible with eMBB, and "0" indicates that the wireless device 120 is not compatible with URLLC and mMTC. ing.

The lower figure of FIG. 3 is an example of functional information indicating whether or not the wireless device 120 corresponds to the separation into the control plane (C plane) and the user plane (U plane). There are four types of functional information shown in the lower figure of FIG. 3 from category "A" to category "D". In each category, the wireless device 120 functions as a wireless control device corresponding to the CU, and the C plane and It is shown whether or not the separation into the U plane is possible, and whether or not it functions as a wireless device corresponding to the DU and can be separated into the C plane and the U plane.

For example, if the wireless device 120 has a PDCP processing unit, an RLC processing unit, a MAC processing unit, and a physical layer processing unit, the wireless device 120 can function as a wireless control device corresponding to a CU. Further, if the wireless device 120 can set the interface between the C plane and the U plane, the wireless device 120 can be separated into the C plane and the U plane. For example, in the functional information of the category "B", it is indicated by "1" that when the wireless device 120 functions as a wireless control device (CU), it can be separated into a C plane and a U plane, and the wireless device is indicated by "1". It is indicated by "0" that the separation into the C plane and the U plane is not possible when the 120 functions as a radio device (DU).

The function information acquisition unit 114 acquires at least one type of function information shown in the upper figure, the middle figure, and the lower figure of FIG. 3 from the wireless device 120 connected to the wireless control device 110. At this time, the function information acquisition unit 114 may request each wireless device 120 to transmit the function information to acquire the function information, or each wireless device 120 may notify at a predetermined timing such as at the time of activation. You may acquire the function information to be performed.

The functional information is not limited to the ones shown in the upper, middle and lower figures of FIG. For example, in addition to the upper figure of FIG. 3, function information may indicate whether or not a different interface type can be set. Specifically, for example, as shown in FIG. 4, in each category from category "0" to category "30", whether or not the wireless device 120 is compatible with HLS and whether or not it is compatible with CPRI. At the same time, it is shown whether or not it is possible to correspond to LLS1 and LLS2 having different separation points of the physical layer, and it is shown whether or not it is possible to correspond to eCPRI (enhanced Common Public radio Interface) in addition to CPRI. In addition, it is shown whether or not it is compatible with eCPRI1 and eCPRI2, which have different physical layer separation points, and whether or not it is compatible with an interface conforming to the IEEE (Institute of Electrical and Electronics Engineers) 1914. You may.

Returning to FIG. 2, the IF control unit 115 controls the interface between the radio control device 110 and the radio device 120. Specifically, the IF control unit 115 sets the interface between the wireless control device 110 and the wireless device 120 when the session corresponding to the service is set in response to the session setting request from the UE 200. At this time, the IF control unit 115 sets an interface suitable for the service quality and communication conditions required in the set session. That is, when the HLS is suitable for the session to be set, the IF control unit 115 sets an interface for connecting the PDCP processing unit 111 and the wireless device 120. On the other hand, the IF control unit 115 sets an interface for connecting the MAC processing unit 113 and the wireless device 120 when the LLS is suitable for the session to be set. The interface setting by the IF control unit 115 is executed by switching the connection destination by the switching unit 116.

The switching unit 116 switches between connecting the PDCP processing unit 111 and the RLC processing unit 112, or connecting the PDCP processing unit and the wireless device 120. That is, the switching unit 116 connects the PDCP processing unit 111 and the RLC processing unit 112 according to the control by the IF control unit 115, and sets an interface between the MAC processing unit 113 and the wireless device 120, or the PDCP processing unit 111. To switch whether to set the interface between the wireless device 120 and the wireless device 120. When the switching unit 116 connects the PDCP processing unit 111 and the RLC processing unit 112, the interface is set between the MAC processing unit 113 and the wireless device 120, so that the functions are separated by the LLS. On the other hand, when the switching unit 116 sets the interface between the PDCP processing unit 111 and the wireless device 120, the functions are separated by HLS.

The wireless device 120 wirelessly transmits a transmission signal and transmits it to the UE 200, receives the signal transmitted from the UE 200, and wirelessly receives and processes the received signal. Specifically, the wireless device 120 has a physical layer processing unit 121 and a functional information generation unit 122.

The physical layer processing unit 121 executes physical layer processing such as D / A (Digital / Analog) conversion of a signal, A / D (Analog / Digital) conversion, and amplification. That is, the physical layer processing unit 121 acquires a transmission signal from the MAC processing unit 113 of the wireless control device 110, executes physical layer processing on the transmission signal, and transmits the transmission signal to the UE 200 via the antenna. Further, the physical layer processing unit 121 receives the signal transmitted from the UE 200 via the antenna, and executes the physical layer processing on the received signal.

The function information generation unit 122 generates functional information of the wireless device 120 and transmits it to the wireless control device 110 connected to the wireless device 120. The function information generation unit 122 may generate and transmit the function information when requested by the wireless control device 110, or generate the function information at a predetermined timing such as when the wireless device 120 is started. You may notify.

FIG. 2 illustrates the functional separation of an LLS in which the wireless device 120 has a physical layer processing unit 121 and a functional information generation unit 122, and an interface is set between the MAC processing unit 113 and the physical layer processing unit 121. There is. However, the wireless device 120 may have a processing unit of a higher layer, and the HLS function can be separated between the wireless device 120 and the wireless control device 110. FIG. 5 is a block diagram showing a configuration of a base station apparatus 100 whose functions are separated by HLS. In FIG. 5, the same parts as those in FIG. 2 are designated by the same reference numerals, and the description thereof will be omitted. The base station apparatus 100 shown in FIG. 5 has a configuration in which the wireless apparatus 120 corresponding to the DU has an RLC processing unit 125 and a MAC processing unit 126 in addition to the physical layer processing unit 121 and the functional information generation unit 122.

The RLC processing unit 125 executes processing of the RLC layer such as retransmission control. That is, the RLC processing unit 125 acquires a transmission signal from the PDCP processing unit 111 of the wireless control device 110, and executes the processing of the RLC layer on the transmission signal. Further, the RLC processing unit 125 acquires a received signal from the MAC processing unit 126 and executes the processing of the RLC layer on the received signal.

The MAC processing unit 126 executes processing of the MAC layer such as scheduling and retransmission control. That is, the MAC processing unit 126 acquires a transmission signal from the RLC processing unit 125 and executes processing of the MAC layer on the transmission signal. Further, the MAC processing unit 126 acquires a received signal from the physical layer processing unit 121 and executes the processing of the MAC layer on the received signal.

As described above, in FIG. 5, the base station apparatus 100 is functionally separated by HLS. In other words, the IF control unit 115 sets an interface for connecting the PDCP processing unit 111 of the wireless control device 110 and the RLC processing unit 125 of the wireless device 120.

FIG. 6 is a block diagram showing a configuration of the UE 200 according to the first embodiment. The UE 200 shown in FIG. 6 has a processor 210, a memory 220, and a wireless transmission / reception unit 230.

The processor 210 includes, for example, a CPU (Central Processing Unit), an FPGA (Field Programmable Gate Array), a DSP (Digital Signal Processor), or the like, and controls the entire UE 200 in an integrated manner. Specifically, the processor 210 has a communication control unit 211, a random access processing unit (hereinafter abbreviated as “RA processing unit”) 212, and a session request generation unit 213.

The communication control unit 211 executes, for example, an application in which communication occurs, generates a transmission signal, and decodes a reception signal. That is, the communication control unit 211 generates a transmission signal and outputs it to the wireless transmission / reception unit 230, acquires a reception signal from the wireless transmission / reception unit 230, and decodes it.

The RA processing unit 212 executes random access processing for establishing a connection with the base station apparatus 100 when the communication control unit 211 determines to start communication. Specifically, the RA processing unit 212 executes a message exchange including transmission of a randomly selected preamble with the base station device 100, and establishes a connection between the UE 200 and the base station device 100.

The session request generation unit 213 generates a session request for requesting the setting of the session corresponding to the service when the communication control unit 211 requests the start of the service due to the execution of the application or the like. Specifically, the session request generation unit 213 generates a session request including information on service quality and communication conditions such as QoS (Quality of Service) requested according to the service.

The memory 220 includes, for example, a RAM (Random Access Memory) or a ROM (Read Only Memory), and stores various information when a process is executed by the processor 210.

The wireless transmission / reception unit 230 performs a predetermined wireless transmission process on the transmission signal and transmits the transmission signal via the antenna. Further, the wireless transmission / reception unit 230 receives a signal via the antenna and performs a predetermined wireless reception process on the received signal. Specifically, the wireless transmission / reception unit 230 transmits the transmission signal generated by the communication control unit 211, and outputs the reception signal received from the base station device 100 to the communication control unit 211. Further, the wireless transmission / reception unit 230 transmits a message regarding the random access processing generated by the RA processing unit 212, and outputs a message regarding the random access processing to the RA processing unit 212. Further, the wireless transmission / reception unit 230 transmits the session request generated by the session request generation unit 213.

Next, the interface setting method according to the first embodiment will be described with reference to the sequence diagram shown in FIG. 7.

The functional information generation unit 122 of the wireless device 120 generates functional information indicating the function of the wireless device 120 at a predetermined timing such as when requested by the wireless control device 110 or when the wireless device 120 is activated, and wirelessly. It is transmitted to the control device 110 (step S101). The functional information is acquired by the functional information acquisition unit 114 of the wireless control device 110, and the information regarding the function of the wireless device 120 is notified to the IF control unit 115.

Then, the IF control unit 115 sets an initial interface corresponding to the function of the wireless device 120 between the wireless control device 110 and the wireless device 120 (step S102). Specifically, for example, when it is found from the functional information that the wireless device 120 corresponds to HLS, an initial stage is established between the PDCP processing unit 111 of the wireless control device 110 and the RLC processing unit 125 of the wireless device 120. The interface is set. Further, for example, when it is found from the functional information that the wireless device 120 corresponds to LLS, an initial interface is provided between the MAC processing unit 113 of the wireless control device 110 and the physical layer processing unit 121 of the wireless device 120. Set. Of course, the initial interface may be CPRI.

In this way, by setting the initial interface between the wireless control device 110 and the wireless device 120 according to the function of the wireless device 120, the function of the base station device 100 is provisionally separated. After that, when the UE 200 wishes to start communication with the base station device 100, a preamble related to the random access process is transmitted from the RA processing unit 212 of the UE 200, and the random access process is executed between the UE 200 and the base station device 100. (Step S103). Random access processing establishes a connection between the UE 200 and the base station device 100.

When the communication control unit 211 of the UE 200 requests the start of a session related to a specific service, the session request generation unit 213 generates a session request including information on the requested service quality and communication conditions, and the wireless transmission / reception unit. It is transmitted from 230. The transmitted session request is transferred to the AMF 12 and SMF 13 of the core network via the radio device 120 and the radio control device 110 (step S104). Then, the AMF 12 and SMF 13 execute a process of sharing the address of the communication path with the UPF 11 (step S105), a process of notifying the wireless control device 110 of the address of the communication path, and a process of establishing a session (step S106). Will be done. When the session is established, AMF12 and SMF13 notify UPF11 to that effect (step S107).

On the other hand, when the session is established, the IF control unit 115 of the wireless control device 110 sets the interface between the wireless control device 110 and the wireless device 120 based on the service quality and communication conditions provided by the established session. (Step S108). That is, the initial interface set between the wireless control device 110 and the wireless device 120 is changed to an interface suitable for achieving the required service quality and communication conditions. For example, when a session corresponding to a service requiring low delay is established, an interface is set between the PDCP processing unit 111 of the wireless control device 110 and the RLC processing unit 125 of the wireless device 120 to control retransmission. Function separation by HLS that can be speeded up is executed.

At this time, the interface to be set is selected from the interfaces that are known to be compatible with the wireless device 120 based on the functional information. Further, when setting the interface, mutual identification information is notified between the wireless control device 110 and the wireless device 120. As the identification information, an identifier assigned to each device can be used, or an IP (Internet Protocol) address of each device can be used.

When the interface between the wireless control device 110 and the wireless device 120 is set, the wireless device 120 notifies the UE 200 to that effect (step S109). Upon receiving this notification, the UE 200 transmits and receives user data according to the service to and from the UPF 11 via the wireless device 120 and the wireless control device 110 (step S110).

As described above, according to the present embodiment, when a session corresponding to the service is established in response to the request from the UE, the interface for achieving the service quality and communication conditions required for the service is wirelessly provided. Set between the control device and the wireless device. Therefore, the interface according to the service used by the UE can be individually set, and the optimum interface for connecting the wireless control device and the wireless device can be set.

In the first embodiment, functional separation by LLS (FIG. 2) in which an interface is set between the MAC processing unit 113 of the wireless control device 110 and the physical layer processing unit 121 of the wireless device 120 and wireless control are performed. An example of functional separation by HLS (FIG. 5) in which an interface is set between the PDCP processing unit 111 of the device 110 and the RLC processing unit 125 of the wireless device 120 is illustrated. However, the interface between the wireless control device 110 and the wireless device 120 is not limited to these, and may be set between other processing units. Further, for example, as shown in FIG. 8, the wireless control device 110 is provided with a physical layer processing unit 117 that executes processing of an upper layer in the physical layer, and the physical layer processing unit 117 and the physical layer processing unit of the wireless device 120 are provided. An interface may be set between 121 and 121. In this case, the physical layer processing unit 121 of the wireless device 120 executes the processing of the lower layer in the physical layer.

Further, different separation points may be provided in the physical layer so that the connection between the wireless control device 110 and the wireless device 120 can be switched at each separation point. That is, for example, as shown in FIG. 9, the switching unit 116 of the wireless control device 110 is provided between the first physical layer processing unit 118 and the second physical layer processing unit 119. The first physical layer processing unit 118 executes processing of the upper layer of the physical layer such as addition of CRC (Cyclic Redundancy Check), error detection, scrambling, descramble, error correction coding, and error correction decoding. On the other hand, the second physical layer processing unit 119 adds and deletes, for example, modulation, demodulation, D / A transform, A / D transform, FFT (Fast Fourier Transform), IFFT (Inverse Fast Fourier Transform), and CP (Cyclic Prefix). Executes the processing of the lower layer of the physical layer such as.

Then, the switching unit 116 switches whether to set an interface between the first physical layer processing unit 118 and the wireless device 120, or to set an interface between the second physical layer processing unit 119 and the wireless device 120. When an interface is set between the first physical layer processing unit 118 and the wireless device 120, the wireless device 120 executes a process corresponding to the second physical layer processing unit 119. When an interface is set between the second physical layer processing unit 119 and the wireless device 120, the wireless device 120 executes processing such as signal amplification. In this way, it is also possible to switch between a plurality of LLS having different separation points in the physical layer.

Further, in the first embodiment, the IF control unit 115 of the wireless control device 110 determines the interface to be set after the session is established, but the interface may be determined by the AMF12 or SMF13 of the core network. It is possible. FIG. 10 is a sequence diagram showing an interface setting method when the AMF 12 or SMF 13 determines the interface. In FIG. 10, the same parts as those in FIG. 7 are designated by the same reference numerals.

As shown in FIG. 10, when the IF control unit 115 sets an initial interface corresponding to the function of the wireless device 120 between the wireless control device 110 and the wireless device 120 (step S102), information regarding the initial interface is set in the AMF12. And SMF13 are notified (step S201). This information is retained by AMF12 and SMF13.

After that, when the session is established according to the request from the UE 200, the AMF 12 or SMF 13 determines whether or not the interface between the radio control device 110 and the radio device 120 needs to be changed from the initial interface (. Step S202). That is, it is determined whether or not the interface suitable for achieving the required service quality and communication conditions is different from the initial interface, and the determination result is notified to the wireless control device 110 (step S203).

Then, the IF control unit 115 of the wireless control device 110 sets the interface between the wireless control device 110 and the wireless device 120 according to the determination result notified from the AMF 12 or the SMF 13 (step S204). That is, the initial interface set between the wireless control device 110 and the wireless device 120 is changed to an interface suitable for achieving the required service quality and communication conditions. If the interface is set correctly, the radio control device 110 reports to AMF12 and SMF13 (step S205).

In this way, by reporting the information about the interface between the radio control device 110 and the radio device 120 to the AMF 12 or SMF 13, it is also possible to determine the interface at the time of session establishment in the AMF 12 or SMF 13.

(Embodiment 2)
The feature of the second embodiment is that when a new session is added, an interface corresponding to the new session is added.

Since the configuration of the base station apparatus according to the second embodiment is the same as that of the base station apparatus 100 (FIGS. 2, 5, 8, 9) according to the first embodiment, the description thereof will be omitted. In the second embodiment, the session is established according to the request from the UE 200, the interface is set between the radio control device 110 and the radio device 120, and then the UE 200 requests the setting of a new session. Since the session is established for each service, one UE 200 can use the service by using a plurality of sessions. In addition, individual networks with different service qualities and communication conditions may be formed in the core network that establishes the session. This network is also called a "network slice" or simply a "slice", and UPF, AMF, SMF, etc. are arranged in each network slice.

Hereinafter, the interface setting method according to the second embodiment will be described with reference to FIG. In the following, after a session is established in the network slice in which UPF11, AMF12 and SMF13 are arranged (hereinafter referred to as “first network slice”), UPF21, AMF22 and SMF23 different from UPF11, AMF12 and SMF13 are arranged. A case where a session in the network slice (hereinafter referred to as “second network slice”) is added will be described. Since the session establishment (steps S101 to S110) in the first network slice is the same as that in the first embodiment, the description thereof will be omitted.

While a session is established in the first network slice and the UE 200 uses the service by this session, the UE 200 may wish to add other services. In such a case, the session request generation unit 213 of the UE 200 generates a session request including information on the required service quality and communication conditions, and the session request is transmitted from the wireless transmission / reception unit 230. The transmitted session request is transferred to AMF22 and SMF23 of the second network slice according to the service to be added via the radio device 120 and the radio control device 110 (step S301). Then, the AMF 22 and SMF 23 execute a process of sharing the address of the communication path with the UPF 21 (step S302), a process of notifying the wireless control device 110 of the address of the communication path, and a process of establishing a session (step S303). Will be done. When the session is established, AMF22 and SMF23 notify UPF21 to that effect (step S304).

On the other hand, when the session is established, the IF control unit 115 of the wireless control device 110 sets the interface between the wireless control device 110 and the wireless device 120 based on the service quality and communication conditions provided by the established session. (Step S305). That is, an interface suitable for achieving the service quality and communication conditions required by the added service is newly set.

At this time, the interface to be set is selected from the interfaces that are known to be compatible with the wireless device 120 based on the functional information. In addition, a new interface is added while leaving the interface for the session established in the first network slice. When adding the interface, the identification information of each other is notified between the wireless control device 110 and the wireless device 120. As the identification information, it is possible to use an identifier assigned to each device, or it is also possible to use an IP address or the like of each device.

In this way, since the session of the second network slice is established while the session of the first network slice is continued, the UE 200 transmits / receives user data according to the service to / from UPF11 (step S306). It also transmits and receives to and from UPF21 (step S307).

As described above, according to the present embodiment, when a session for a new service is added, a new interface is provided while leaving the interface between the wireless control device and the wireless device in the established session. to add. Therefore, the UE can use a plurality of services at the same time.

In the second embodiment, the case where the interface is added between the same wireless control device 110 and the wireless device 120 has been described, but the added interface is that of the wireless control device 110 and another wireless device. It may be set between other wireless control devices and the wireless device 120. The radio resource corresponding to the added interface may be the same as or different from the radio resource used in the established session. Here, the radio resource refers to a frequency band and time, and includes a subcarrier, a subband including a plurality of subcarriers, a subcarrier block, and the like.

(Embodiment 3)
The feature of the third embodiment is that the base station device that operates without separating the functions into the wireless control device and the wireless device is changed to a wireless control device or a wireless device as needed, and becomes an external wireless control device or a wireless device. It is a point to connect.

FIG. 12 is a block diagram showing the configuration of the base station apparatus 100 according to the third embodiment. The base station apparatus 100 shown in FIG. 12 includes a PDCP processing unit 301, a connection unit 302, an RLC processing unit 303, a MAC processing unit 304, a connection unit 305, a physical layer processing unit 306, and an IF control unit 307. The base station device 100 shown in FIG. 12 is not functionally separated into a wireless control device and a wireless device, and performs processing from the upper layer to the lower layer to wirelessly transmit and receive signals.

The PDCP processing unit 301 executes processing of the PDCP layer such as data ordering and header compression, for example. That is, the PDCP processing unit 301 executes the processing of the PDCP layer on the transmission signal acquired from the UPF 11 or AMF 12, and outputs the transmission signal to the RLC processing unit 303 via the connection unit 302. Further, the PDCP processing unit 301 acquires a received signal from the RLC processing unit 303 via the connection unit 302, and executes processing of the PDCP layer on the received signal.

The connection unit 302 connects to the external wireless control device 110 or the wireless device 120. Then, the connection unit 302 sets an interface for connecting the PDCP processing unit 301 to the external wireless device 120 or an interface for connecting the external wireless control device 110 to the RLC processing unit 303 according to the control by the IF control unit 307. Set it.

The RLC processing unit 303 executes processing of the RLC layer such as retransmission control. That is, the RLC processing unit 303 acquires a transmission signal from the PDCP processing unit 301 via the connection unit 302, and executes RLC layer processing on the transmission signal. Further, the RLC processing unit 303 acquires a received signal from the MAC processing unit 304 and executes RLC layer processing on the received signal.

The MAC processing unit 304 executes processing of the MAC layer such as scheduling and retransmission control. That is, the MAC processing unit 304 acquires the transmission signal from the RLC processing unit 303 and executes the processing of the MAC layer on the transmission signal. Further, the MAC processing unit 304 acquires a received signal from the physical layer processing unit 306 via the connection unit 305, and executes the processing of the MAC layer on the received signal.

The connection unit 305 connects to an external wireless control device 110 or wireless device 120. Then, the connection unit 305 sets an interface for connecting the MAC processing unit 304 to the external wireless device 120 or connects the external wireless control device 110 to the physical layer processing unit 306 according to the control by the IF control unit 307. Or set.

The physical layer processing unit 306 executes physical layer processing such as D / A conversion, A / D conversion, and amplification of signals. That is, the physical layer processing unit 306 acquires a transmission signal from the MAC processing unit 304 via the connection unit 305, executes physical layer processing on the transmission signal, and transmits the transmission signal to the UE 200 via the antenna. Further, the physical layer processing unit 306 receives the signal transmitted from the UE 200 via the antenna, and executes the physical layer processing on the received signal.

The IF control unit 307 determines whether or not to separate the functions of the base station device 100, and when the functions are separated, the interface between the external wireless control device 110 or the wireless device 120 and the base station device 100. To control. Specifically, the IF control unit 307 determines whether or not to execute the function separation based on, for example, the processing load in the base station apparatus 100. That is, for example, when the processing load of the base station device 100 is larger than the predetermined reference, the IF control unit 307 decides to change the base station device 100 to a wireless device and connect it to the external wireless control device 110. Then, the IF control unit 307 sets an interface for connecting the external wireless control device 110 and the RLC processing unit 303 or the physical layer processing unit 306.

Further, for example, when requested by an external wireless device 120, the IF control unit 307 decides to change the base station device 100 to a wireless control device and connect it to the external wireless device 120. Then, the IF control unit 307 sets an interface for connecting the external wireless device 120 and the PDCP processing unit 301 or the MAC processing unit 304.

The interface setting by the IF control unit 307 is executed by setting the connection destination in the connection unit 302 or the connection unit 305.

FIG. 13 is a block diagram showing another configuration of the base station apparatus 100 according to the third embodiment. In FIG. 13, the same parts as those in FIG. 12 are designated by the same reference numerals, and the description thereof will be omitted. The base station apparatus 100 shown in FIG. 13 replaces the connection unit 302 and the physical layer processing unit 306 of the base station apparatus 100 shown in FIG. 12, with the connection unit 309, the first physical layer processing unit 308, and the second physical layer processing unit. It has 310. The base station device 100 shown in FIG. 13 is not functionally separated into a wireless control device and a wireless device, and performs processing from the upper layer to the lower layer to wirelessly transmit and receive signals.

The first physical layer processing unit 308 executes processing of the upper layer of the physical layer such as addition of CRC, error detection, scrambling, descramble, error correction coding, and error correction decoding. That is, the first physical layer processing unit 308 acquires a transmission signal from the MAC processing unit 304 via the connection unit 305, and executes processing of the upper layer of the physical layer on the transmission signal. Further, the first physical layer processing unit 308 acquires a received signal from the second physical layer processing unit 310 via the connection unit 309, and executes processing of the lower layer of the physical layer on the received signal.

The connection unit 309 connects to the external wireless control device 110 or the wireless device 120. Then, the connection unit 309 sets an interface for connecting the first physical layer processing unit 308 to the external wireless device 120 according to the control by the IF control unit 307, or sets the external wireless control device 110 to the second physical layer processing unit. Set the interface to connect to 310.

The second physical layer processing unit 310 executes processing of the lower layer of the physical layer such as modulation, demodulation, D / A conversion, A / D conversion, FFT, IFFT, and addition and deletion of CP. That is, the second physical layer processing unit 310 acquires a transmission signal from the first physical layer processing unit 308 via the connection unit 309, executes processing of the lower layer of the physical layer on the transmission signal, and via the antenna. Is transmitted to the UE 200. Further, the second physical layer processing unit 310 receives the signal transmitted from the UE 200 via the antenna, and executes the processing of the lower layer of the physical layer with respect to the received signal.

Next, the interface setting method according to the third embodiment will be described with reference to the sequence diagram shown in FIG. In FIG. 14, the same parts as those in FIG. 7 are designated by the same reference numerals. In the following description, the interface setting method in the base station apparatus 100 shown in FIG. 12 will be described, but the interface can be set in the base station apparatus 100 shown in FIG. 13 by the same interface setting method. ..

When the UE 200 wishes to start communication with the base station device 100, a preamble related to the random access process is transmitted from the RA processing unit 212 of the UE 200, and the random access process is executed between the UE 200 and the base station device 100. (Step S103). Random access processing establishes a connection between the UE 200 and the base station device 100.

When the communication control unit 211 of the UE 200 requests the start of a session related to a specific service, the session request generation unit 213 generates a session request including information on the requested service quality and communication conditions, and the wireless transmission / reception unit. It is transmitted from 230. The transmitted session request is transferred to the AMF 12 and SMF 13 of the core network via the radio device 120 and the radio control device 110 (step S104). Then, the AMF 12 and SMF 13 execute a process of sharing the address of the communication path with the UPF 11 (step S105), a process of notifying the wireless control device 110 of the address of the communication path, and a process of establishing a session (step S106). Will be done. When the session is established, AMF12 and SMF13 notify UPF11 to that effect (step S107).

On the other hand, the IF control unit 307 monitors the state of the base station device 100, and executes the function separation of the base station device 100 based on, for example, the processing load of the base station device 100 or a request from an external device. It is determined whether or not to do so (step S401). As a result of this determination, when it is determined that the function separation is not executed, the processing by the PDCP processing unit 301, the RLC processing unit 303, the MAC processing unit 304, and the physical layer processing unit 306 is executed, and the processing is executed via the base station apparatus 100. User data is transferred between the UE 200 and the UPF 11. If it is determined that the function separation is to be executed, the base station device 100 is changed to a wireless control device or a wireless device, and an interface for connecting to an external wireless control device or wireless device is set. Here, the description will be continued assuming that the base station device 100 is changed to a wireless device.

When the IF control unit 307 determines that the base station device 100 is changed to a wireless device, an interface between the base station device 100 and the external wireless control device 110 is set (step S402). That is, an interface suitable for achieving the service quality and communication conditions required for the service corresponding to the established session is set. For example, when a session corresponding to a service requiring low delay is established, the connection destination of the connection unit 302 is changed, so that the RLC processing unit 303 of the base station device 100 and the external wireless control device 110 are used. An interface is set between the two, and functional separation by HLS that can speed up retransmission control is executed. Further, when the function separation by LLS is executed, the connection destination of the connection unit 305 is changed, so that an interface is provided between the physical layer processing unit 306 of the base station device 100 and the external wireless control device 110. Set.

When the base station device 100 is changed to a wireless control device, the connection destination of the connection unit 302 is changed, so that an interface is set between the PDCP processing unit 301 and the external wireless device 120. By changing the connection destination of the connection unit 305, an interface may be set between the MAC processing unit 304 and the external wireless device 120.

When the interface between the base station device 100 and the external wireless control device 110 is set, the base station device 100 notifies the UE 200 to that effect (step S109). Upon receiving this notification, the UE 200 transmits and receives user data according to the service to and from the UPF 11 via the base station device 100 and the wireless control device 110 (step S110).

As described above, according to the present embodiment, when the base station device whose functions are not separated is changed to the wireless control device or the wireless device, the space between the base station device and the external wireless control device or the wireless device is reached. Set the interface to. Therefore, it is possible to form a function-separated base station device by using a base station device that is not function-separated in the initial state.

In the third embodiment, the base station device 100 is connected to the external wireless control device 110 or the wireless device 120, but it is also possible to separate the functions inside the base station device 100. .. In this case, the IF control unit 307 may set an interface suitable for the service quality and communication conditions required in the session between the internal processing units of the base station apparatus 100.

(Embodiment 4)
The feature of the fourth embodiment is that the interface is set when the wireless control device is separated into a control plane (C plane) and a user plane (U plane).

FIG. 15 is a block diagram showing the configuration of the base station apparatus 100 according to the fourth embodiment. In FIG. 15, the same parts as those in FIG. 2 are designated by the same reference numerals, and the description thereof will be omitted. The base station apparatus 100 shown in FIG. 15 has a configuration in which a U-plane processing unit 130 is added to the base station apparatus 100 shown in FIG. 2 and the IF control unit 115 is replaced with the IF control unit 401.

In the fourth embodiment, the radio control device 110 executes the processing of the C plane. Therefore, the PDCP processing unit 111 is connected to the AMF 12 that controls the C plane, and the PDCP processing unit 111, the RLC processing unit 112, and the MAC processing unit 113 process the transmission signal and the reception signal of the C plane.

The U-plane processing unit 130 is connected to the UPF 11 that controls the U-plane and executes U-plane processing. The U-plane processing unit 130 may have a PDCP processing unit, an RLC processing unit, and a MAC processing unit (not shown), and may further have a SDAP processing unit. A C / U interface is set between the wireless control device 110 and the U-plane processing unit 130, and the C-plane wireless control device 110 and the U-plane processing unit 130 as a whole correspond to a CU (Central Unit).

The IF control unit 401 includes an interface between the wireless control device 110 and the wireless device 120, an interface between the U-plane processing unit 130 and the wireless device 120, and an interface between the wireless control device 110 and the U-plane processing unit 130 (hereinafter,). Controls the "C / U interface"). Specifically, the IF control unit 401 sets each interface when the session corresponding to the service is set in response to the session setting request from the UE 200.

At this time, the IF control unit 401 sets an interface suitable for the service quality and communication conditions required in the set session. That is, when the HLS is suitable for the session to be set, the IF control unit 401 sets the interface for connecting the PDCP processing unit 111 of the wireless control device 110 and the wireless device 120, and also sets the interface of the U plane processing unit 130. An interface for connecting the PDCP processing unit and the wireless device 120 is set. Further, the IF control unit 401 sets a C / U interface between the wireless control device 110 and the U plane processing unit 130.

On the other hand, when the LLS is suitable for the session to be set, the IF control unit 401 sets the interface for connecting the MAC processing unit 113 of the wireless control device 110 and the wireless device 120, and also sets the interface of the U plane processing unit 130. An interface for connecting the MAC processing unit and the wireless device 120 is set. Further, the IF control unit 401 sets a C / U interface between the wireless control device 110 and the U plane processing unit 130.

Next, the interface setting method according to the fourth embodiment will be described with reference to the sequence diagram shown in FIG. In FIG. 16, the same parts as those in FIG. 7 are designated by the same reference numerals.

The functional information generation unit 122 of the wireless device 120 generates functional information indicating the function of the wireless device 120 at a predetermined timing such as when requested by the wireless control device 110 or when the wireless device 120 is activated, and wirelessly. It is transmitted to the control device 110 (step S101). The functional information is acquired by the functional information acquisition unit 114 of the wireless control device 110, and the information regarding the function of the wireless device 120 is notified to the IF control unit 401.

Then, the IF control unit 401 sets an initial interface according to the function of the wireless device 120 between the wireless control device 110 and the wireless device 120 and between the U plane processing unit 130 and the wireless device 120 (step S501). .. Specifically, for example, when it is found from the functional information that the wireless device 120 supports HLS, an initial interface is set between the PDCP processing unit 111 of the wireless control device 110 and the wireless device 120, and the initial interface is set. , An initial interface is set between the PDCP processing unit of the U plane processing unit 130 and the wireless device 120. Further, for example, when it is found from the functional information that the wireless device 120 corresponds to LLS, an initial interface is set between the MAC processing unit 113 of the wireless control device 110 and the wireless device 120, and the U plane is set. An initial interface is set between the MAC processing unit of the processing unit 130 and the wireless device 120. Further, at the same time as setting the interface between these CUs and DUs, the C / U interface between the wireless control device 110 and the U plane processing unit 130 is set.

As described above, by setting the initial interface between the wireless control device 110 and the wireless device 120 and between the U plane processing unit 130 and the wireless device 120 according to the function of the wireless device 120, the base station device 100 Is provisionally separated from function. After that, when the UE 200 wishes to start communication with the base station device 100, a preamble related to the random access process is transmitted from the RA processing unit 212 of the UE 200, and the random access process is executed between the UE 200 and the base station device 100. (Step S103). Random access processing establishes a connection between the UE 200 and the base station device 100.

When the communication control unit 211 of the UE 200 requests the start of a session related to a specific service, the session request generation unit 213 generates a session request including information on the requested service quality and communication conditions, and the wireless transmission / reception unit. It is transmitted from 230. The transmitted session request is transferred to the AMF 12 and SMF 13 of the core network via the radio device 120 and the radio control device 110 (step S104). Then, the AMF 12 and SMF 13 execute a process of sharing the address of the communication path with the UPF 11 (step S105), a process of notifying the wireless control device 110 of the address of the communication path, and a process of establishing a session (step S106). Will be done. When the session is established, AMF12 and SMF13 notify UPF11 to that effect (step S107).

On the other hand, when the session is established, the IF control unit 401 of the wireless control device 110 determines between the wireless control device 110 and the wireless device 120, and the U plane, based on the service quality and communication conditions provided by the established session. The interface between the processing unit 130 and the wireless device 120 is set (step S502). That is, the initial interface set between the wireless control device 110 and the wireless device 120 is changed to an interface suitable for achieving the required service quality and communication conditions. Further, the initial interface set between the U-plane processing unit 130 and the wireless device is changed to an interface suitable for achieving the required service quality and communication conditions.

For example, when a session corresponding to a service requiring low delay is established, an interface is set between the PDCP processing unit 111 of the wireless control device 110 and the wireless device 120, and the PDCP processing unit of the U plane processing unit 130 is set up. An interface is set between the wireless device 120 and the wireless device 120, and functional separation by HLS capable of speeding up retransmission control is executed.

At this time, the interface to be set is selected from the interfaces that are known to be compatible with the wireless device 120 based on the functional information. Further, if necessary, the C / U interface between the wireless control device 110 and the U plane processing unit 130 is also changed. When setting or changing the interface, the wireless control device 110, the wireless device 120, and the U-plane processing unit 130 are notified of each other's identification information. As the identification information, an identifier assigned to each device or processing unit can be used, or an IP address of each device or processing unit can be used.

When each interface is set, the wireless device 120 notifies the UE 200 to that effect (step S109). Upon receiving this notification, the UE 200 transmits and receives user data according to the service to and from the UPF 11 via the wireless device 120 and the U plane processing unit 130 (step S110).

As described above, according to the present embodiment, the interface for achieving the service quality and communication conditions required for the service is provided between the wireless control device and the wireless device for managing the C plane and the U plane processing unit. And set between the wireless device. In addition, a C / U interface is set between the wireless control device and the U plane processing unit. Therefore, even when the CU is separated into the C plane and the U plane, the interface according to the service used by the UE can be individually set, and the optimum interface for connecting the CU and the DU can be set. ..

Although the case where the CU is separated into the C plane and the U plane has been described in the fourth embodiment, it is also possible to separate the DU into the C plane and the U plane. Even in this case, the interface according to the service can be individually set between the wireless control device 110 and the C plane and U plane of the DU.

Further, in the fourth embodiment, it has been described that the wireless control device 110 that manages the C plane and the U plane processing unit 130 are separated in advance, but the separation of the C plane and the U plane is performed by the base station device. It may be executed while 100 is in operation. In this case, the C / U interface is set when the C plane and the U plane are separated, and between the wireless control device 110 and the wireless device 120 that manage the C plane, and between the U plane processing unit 130 and the wireless device 120. The interface between is set.

In each of the above embodiments, after the interface between the wireless control device 110 and the wireless device 120 is set, the signal transmission delay, round trip delay time (RTT), and the like are monitored, and if necessary. The interface may be reconfigured. Specifically, if the transmission delay or RTT is monitored by the MAC processing unit of the wireless control device 110 or the wireless device 120 and the transmission delay or RTT does not meet a predetermined standard according to the service, the wireless control device 110 and the wireless device 110 are wirelessly monitored. The interface between the devices 120 is reconfigured. In addition, a table is generated to store the transmission delay and the information related to the interface settings in association with each other, and when the interface is set from the next time onward, the interface is set by referring to the table and corresponding to the desired transmission delay. You may do so.

Each of the above embodiments can be combined as appropriate. For example, by combining the second embodiment and the fourth embodiment, it is possible to add an interface according to the session to be added when the CU is separated into the C plane and the U plane. Further, for example, when the base station apparatus is separated into the C plane and the U plane by combining the third embodiment and the fourth embodiment, the function separation into the CU and the DU is further executed between the CU and the DU. It is possible to set the interface of.

111, 301 PDCP processing unit 112, 125, 303 RLC processing unit 113, 126, 304 MAC processing unit 114 Function information acquisition unit 115, 307, 401 IF control unit 116 Switching unit 117, 121, 306 Physical layer processing unit 118, 308 1st physical layer processing unit 119, 310 2nd physical layer processing unit 122 Function information generation unit 130 U plane processing unit 210 Processor 211 Communication control unit 212 RA processing unit 213 Session request generation unit 220 Memory 230 Wireless transmission / reception unit 302, 305, 309 Connection

Claims (7)

A base station device that has a wireless control device and a wireless device and communicates with a terminal device.
The wireless device is
It has a generator that generates functional information about the function of its own device.
The wireless control device is
A request unit that requests a higher-level device to establish a session corresponding to the service requested by the terminal device, and a request unit.
An acquisition unit that acquires the functional information generated by the generation unit, and
Layer processing for connecting the wireless control device and the wireless device to each other based on the functional information acquired by the acquisition unit or based on the service quality or communication conditions required for the service after the session is established. A base station apparatus having a connection control unit that determines a unit and sets an interface for connecting between the determined layer processing units. The connection control unit
The base station apparatus according to claim 1, wherein information regarding a connection between the wireless control device and the wireless device is notified to the higher-level device. The request part is
When the terminal device uses another service, the higher-level device is requested to establish a session corresponding to the other service.
The connection control unit
A claim comprising adding a connection between the radio control device and the radio device according to the quality of service or communication conditions required for the other service when establishing a session corresponding to the other service. Item 1. The base station apparatus according to item 1. The connection control unit
When the wireless control device is separated into a first processing unit that processes control information and a second processing unit that processes user data, between the first processing unit and the layer processing unit of each of the wireless devices. An interface for connecting the second processing unit and the wireless device, and an interface for connecting the first processing unit and the second processing unit are set . The base station apparatus according to claim 1. The wireless control device is
The first layer processing unit that executes the processing of the first layer,
It further has a second layer processing unit that executes processing of a second layer lower than the first layer.
The wireless device is
A third layer processing unit that executes processing of a third layer lower than the first layer, and
It has a fourth layer processing unit that executes processing of a fourth layer lower than the second layer.
The connection control unit
The first aspect of the present invention, wherein the first layer processing unit and the third layer processing unit are connected, or the second layer processing unit and the fourth layer processing unit are connected. Base station equipment. A wireless communication system having a terminal device, a base station device, and a host device.
The base station device includes a radio control device and a radio device.
The wireless device is
It has a generator that generates functional information about the function of its own device.
The wireless control device is
A requesting unit that requests the host device to establish a session corresponding to the service requested by the terminal device, and a requesting unit.
An acquisition unit that acquires the functional information generated by the generation unit, and
Layer processing for connecting the wireless control device and the wireless device to each other based on the functional information acquired by the acquisition unit or based on the service quality or communication conditions required for the service after the session is established. A wireless communication system comprising a connection control unit that determines a unit and sets an interface for connecting between the determined layer processing units . A connection setting method executed by the wireless control device of a base station device including a wireless control device and the wireless device.
Obtain functional information about the function of the terminal device from the terminal device that uses the service,
Based on the acquired functional information, each layer processing unit that connects the wireless control device and the wireless device to each other is determined, and an interface for connecting the determined layer processing units is set .
According to the request of the terminal device, the host device is requested to establish a session corresponding to the service.
At the time of session establishment, the setting of the interface is changed according to the service quality or communication conditions required for the service.
A connection setting method characterized by having a process.

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