JP6477901B2 - Gateway, radio base station, and communication system - Google Patents

Description

  The present disclosure relates to a communication system in which a core network, a gateway, and a radio base station are connected.

  When a UE (User Equipment) and a CN (Core Network) communicate, a radio base station having a communication coverage of a cell in which the UE is located and a CN are connected to a gateway between them. Radio base station user data and control signals are relayed between the UE and the CN.

  Patent Document 1 describes that a radio base station transmits an HNBAP (Home Node B Application Part) message including location information and access mode information of the radio base station to a gateway.

JP 2011-124869 A

  However, the gateway cannot grasp the load applied to the gateway only by the wireless base station transmitting the HNBAP message to the gateway.

In order to solve the above problem, the gateway of the exemplary embodiment is:
A gateway connected between a core network and a radio base station,
It is a gateway which has a means to receive the 1st information about the traffic of the radio base station from the radio base station.

  According to the gateway of the exemplary embodiment, the wireless base station transmits information on the traffic amount of the wireless base station to the gateway, so that the gateway can grasp the load applied to the gateway.

The figure which shows the structural example of the communication system concerning 1st-3rd embodiment. Sequence diagram showing operations according to the first to third embodiments The figure which shows the structural example of HNB-GW concerning the 2nd-3rd embodiment. The sequence diagram which shows the operation | movement concerning 2nd-3rd embodiment. Table showing HNB REGISTER REQUEST Information Elements Diagram for explaining operation in related technology Flow chart showing operations according to the second to third embodiments. The block diagram which shows the operation | movement concerning 2nd-3rd embodiment. The block diagram which shows the operation | movement concerning 2nd-3rd embodiment. The block diagram showing the operation | movement concerning 2nd-3rd embodiment. The sequence diagram which shows the operation | movement concerning 3rd Embodiment. The figure which shows the structural example of the communication system concerning 4th-6th embodiment. Sequence diagram showing operations according to the fourth to sixth embodiments The figure which shows the structural example of HeNB-GW concerning 5th-6th embodiment. Sequence diagram showing operations according to the fifth to sixth embodiments Table showing S1 SET UP REQUEST Information Elements Sequence diagram showing operations according to the sixth embodiment The block diagram which shows the operation | movement regarding other embodiment.

Hereinafter, a communication system according to an exemplary embodiment will be described in detail with reference to the drawings.
(First embodiment)
FIG. 1 illustrates the configuration of a communication system targeted by an exemplary embodiment. An HNB (Home Node B; radio base station) 3 is connected to a CN (Core Network; core network) 1 via an HNB-GW (Home Node B-Gateway; gateway) 2. HNB-GW2 is a gateway that accommodates one or more HNB3, and relays user data, control signals, and the like between HNB3 and CN1. The HNB 3 has a cell 4 that is each communication coverage, and performs radio communication with one or a plurality of UEs (User Equipment) 5 located there.

FIG. 2 is a sequence diagram showing the operation of the system according to the present embodiment.
HNB3 transmits the 1st information regarding the traffic of HNB3 to HNB-GW2. The HNB-GW 2 receives the first information.

According to this embodiment, the HNB-GW2 connected between the CN1 and the HNB3 receives the first information related to the traffic of the HNB3 from the HNB3 (for example, a receiving device, a receiver, a receiver, a receiving interface). HNB-GW2 can grasp the load applied to HNB-GW2.
(Second Embodiment)
The present embodiment is an example in which the first embodiment is more specific based on the configuration of the communication system shown in FIG.

  FIG. 3 illustrates an internal configuration of the HNB-GW 2 in the present embodiment. The HNB-GW 2 includes a load distribution module 8, a control signal processing server 7, and a SeGW (security gateway) 6.

  When there is a connection request from the HNB 3 to the HNB-GW 2, the load distribution module 8 selects an optimal control signal processing server 7 for connecting the HNB 3. The selected control signal processing server 7 accommodates the connection with the HNB 3. And HNB3 establishes SCTP (Stream Control Transmission Protocol) Association with respect to the said selected control signal processing server 7, and performs a communication process with CN1 through it. The load distribution module 8 holds and manages the number of SCTP Associations established by each control signal processing server 7. The SeGW (security gateway) 6 establishes a secure connection such as IPSec (IP Security Architecture) with the HNB 3 and encrypts information.

  FIG. 4 is a sequence diagram showing the operation of the communication system according to the present embodiment. When the HNB 3 is activated (S1), a secure connection is first established between the HNB 3 and the SeGW (security gateway) 6 (S2). Thereafter, the HNB 3 transmits a DNS (Domain Name System) Query to the load distribution module 8 (S 3). The load distribution module 8 selects the control signal processing server 7 to be connected to the HNB 3 (S4), and returns the IP address of the selected control signal processing server 7 to the HNB 3 with a DNS Query Response (S5). Thereafter, SCTP Association for connecting HNB3 and HNB-GW2 is established between HNB3 and control signal processing server 7 (S6).

  Subsequently, the HNB 3 requests registration to the HNB-GW 2 by transmitting an HNB Register Request message to the control signal processing server 7 in the HNB-GW 2 (S7). For this request, IE (Information Elements) such as Message Type, HNB Identity, and HNB Location Information as shown in FIG. 5 can be used, but is not limited thereto. As shown in FIG. 4, the HNB Register Request message transmitted from the HNB 3 to the HNB-GW 2 in this embodiment is a message in which the first information regarding the traffic of the HNB 3 and the HNB-Identity are combined.

  From the viewpoint of improving the efficiency of information transmission / reception between the HNB3 and the HNB-GW2, the first information is preferably transmitted by an HNB Register Request message as in the present embodiment, and is transmitted together with other IEs. May be. However, the first information does not necessarily have to be transmitted together with other IEs. As the first information, information including the traffic volume assumed in the HNB 3 may be set as an IE of a new character string of the HNB Register Request message. For example, you may set as IE shown by the character string Assembled Load as shown in FIG. The first information may be the traffic amount assumed in the HNB 3 itself.

  When the control signal processing server 7 receives the first information from the HNB 3 as in the present embodiment, as described above, the HNB 3 transmits the first information at the timing of transmitting the HNB Register Request message. Can do.

  Here, the first information is set so that the SCTP Association is distributed with an equal traffic amount. In the present embodiment, the first information is set in advance before the UE 5 is in the HNB 3.

  By the way, HNB3 connects with HNB-GW2 and establishes SCTP Association before UE5 exists in HNB3. Moreover, only one SCTP Association is established for one HNB3. And UE5 located in HNB3 or HNB-GW2 which has established the SCTP Association shares the SCTP Association.

  Among the control signal processing servers 7-1 to 7-N (N is an arbitrary integer), the control signal processing server with the smallest number of SCTP Associations is the control signal processing server with the least load. There was an assumption that there was. Under the assumption, the load distribution module 8 has selected the control signal processing server with the smallest number of SCTP Associations as the control signal processing server 7 to which the HNB 3 that has newly requested connection to the HNB-GW 2 is connected ( FIG. 6). However, if the number of SCTP Association is used as a selection criterion, for example, a problem that the load on the control signal processing server 7 is not evenly distributed may occur. Therefore, it is preferable that the selection criterion of the control signal processing server 7 is not the number of SCTP Associations but the load that will be applied to the control signal processing server 7.

  On the other hand, when the established SCTP Association is disconnected in order to adjust the load on the control signal processing server 7, all of the UEs 5 under the control of the HNB 3 or HNB-GW 2 that established the SCTP Association There is a risk of becoming.

  That is, by setting the traffic volume assumed in the HNB 3 before the SCTP Association is established, the SCTP Association can be evenly distributed without disconnecting the SCTP Association. Therefore, as in the present embodiment, the first information is information that is set in advance before the UE 5 is located in the HNB 3, in particular, information that includes the traffic amount assumed in the HNB 3, and thus SCTP Association. Is established (S6), for example, actual traffic volume in HNB3, and traffic volume resulting from actual identification information and number of UE5 that will be in HNB3 as will be described later Compared to the case, it is advantageous in that the SCTP Association can be evenly distributed while preventing the call loss of the UE 5.

  When the control signal processing server 7 permits the HNB Register Request, the HNB Register Accept to the HNB 3 is returned (S8), and the HNB 3 is connected to the control signal processing server 7.

  The control signal processing server 7 transmits second information based on the first information received from the HNB 3 in S7 to the load distribution module 8 (S9). The load distribution module 8 manages the load state of the control signal processing server 7 as third information based on the received second information. When the second information is further transmitted from the control signal processing server 7 that has transmitted the second information based on the already managed third information, the third information is updated (S10). .

  The second information may be information including the traffic volume assumed in the HNB3. When the HNB3 is connected to the HNB-GW2, the second information is the traffic volume expected in the HNB3. It may be information indicating that has increased. The third information may be a cumulative value of the second information. Note that the first information, the second information, and the third information may be the same or different from each other.

  The update of the third information may be performed by adding the traffic volume assumed in the HNB 3 and the number of SCTP Associations in the assumed traffic volume table as shown in FIG. 8, for example. When there is a new HNB requesting registration from the HNB-GW 2, the load distribution module 8 may select the control signal processing server 7 to which the HNB is connected based on the third information (S4). .

After a Location Area Update Request is transmitted from the UE 5 to the HNB 3 (S11), the UE 5 enters a registration procedure for the UE 5 between the HNB 3 and the control signal processing server 7 in the HNB-GW 2 (S12). Then, the Location Area Update Request is transmitted from the HNB 3 to the control signal processing server 7 (S13).
And UE5 will be located in the cell which HNB3 has jurisdiction over.

FIG. 7 shows a processing flow of the control signal processing server 7. First, the control signal processing server 7 receives an HNBAP: HNB REGISTER REQUEST message from the HNB 3 (T1). FIG. 7 shows a case where the IE of the HNB REGISTER REQUEST message is HNB-Identity. Next, the control signal processing server 7 performs a realm check of the HNB-Identity (T2). The format of HNB-Identity is defined as 0 <IMSI> @ <realm> or 1 <OUI>-<SerialNumber> @ <realm> (Non-patent Document 1). <IMSI> is a 16-digit code specified in Non-Patent Document 2, and <OUI> and <SerialNumber> are codes specified in Non-Patent Document 3.
3GPP TS 25.469: “UTRAN Iuh interface Home Node B (HNB) Application Part (HNBAP) signaling”. 3GPP TS 23.003: “Numbering, addressing and identification”. Broadband Forum TR-069 Amendment 2, CPE WAN Management Protocol, Broadband Forum Technical Report, 2007. In the HNB-Identity format, the realm part (for example, nec.com) does not have the realm part (for example, nec.com). In other words, when there is no value determined as the traffic volume, the control signal processing server 7 does not include the traffic volume and includes information including the default value set in advance by the control signal processing server 7 as shown in FIG. It can be held together with Identity (T3). In this case, the control signal processing server 7 can transmit information including a default value preset by the control signal processing server 7 to the load distribution module 8 as the second information. The information including the default value may be the default value itself or an IE that combines the default value and the HNB-Identity.

  If there is a value defined as the traffic volume assumed in the HNB 3 in the realm part, the control signal processing server 7 holds the value, 50,000 in FIG. 6, as the traffic quantity assumed in the HNB 3 (T4 ), A numeric character string indicating the first information about the traffic is added to the realm portion, and it can be set to, for example, nec.com_50000BHCA.

  Then, the control signal processing server 7 transmits to the load distribution module 8 information indicating that the traffic amount assumed in the HNB 3 or the traffic amount assumed in the HNB 3 is increased, which is determined in the default value or the realm part. (T6).

  FIG. 8 shows an update operation of the assumed traffic volume table in the load distribution module 8. The third information in this case is an accumulated value of the traffic amount of the HNB 3 indicated by the second information transmitted from the control signal processing server 7. The assumed traffic volume table includes the identifier of the control signal processing server 7, the cumulative value of the traffic volume assumed in the HNB 3, and the number of SCTP Associations. When the load distribution module 8 receives information indicating that the traffic volume assumed in the HNB 3 has increased from the control signal processing server 7, the load distribution module 8 is assumed in the HNB 3 regarding the control signal processing server 7 that has transmitted the information. The increase in traffic volume assumed in HNB3 is added to the cumulative value of traffic volume, and the number of SCTP Association is increased by one.

  FIG. 9 shows the selection processing operation of the control signal processing server 7 in the load distribution module 8. Also in this case, the third information is an accumulated value of the traffic amount of the HNB 3 indicated by the second information transmitted from the control signal processing server 7, and the load distribution module 8 is based on the third information. The control signal processing server 7 to which the HNB 3 is connected is selected. When the DNS query is received from the HNB 3, the load distribution module 8 updates the assumed traffic volume table and selects the control signal processing server 7 having the smallest accumulated traffic volume assumed in the HNB 3. Then, the IP address of the selected control signal processing server 7 is included in the DNS Query Response and returned.

  According to the communication system according to the present embodiment, the load distribution module 8 of the HNB 3 that has newly requested the HNB-GW 2 to connect to the control signal processing server 7 having the smallest accumulated traffic amount assumed in the HNB 3. It becomes possible to instruct as a connection destination. Therefore, by appropriately setting the traffic volume assumed in the HNB 3, it becomes possible to equalize the actual traffic volume, and the traffic volume bias caused by the actual identification information and the number of the UEs 5.

FIG. 10 shows how the HNB 3 that has newly requested connection to the HNB-GW 2 is connected to the control signal processing server 7 in this embodiment. In the table of FIG. 9, the cumulative value of the traffic amount of HNB 3 as the third information is the smallest in the control signal processing server 7 whose identifier is N. Therefore, the load distribution module 8 instructs to select the control signal processing server 7-N as the connection destination of the HNB 3 that has newly requested connection to the HNB-GW 2.
(Third embodiment)
FIG. 11 is a sequence diagram when the HNB 3 already connected to the control signal processing server 7 releases the connection.

  From S1 to S13, the same operation as that shown in FIG. 4 is performed.

  Thereafter, when the HNB 3 releases the connection with the control signal processing server 7, HNB De-Registration and SCTP Association disconnection (S 14) are performed between the HNB 3 and the control signal processing server 7. At this time, the control signal processing server 7 that has been disconnected transmits to the load distribution module 8 information indicating that the traffic volume assumed in the HNB 3 that has been disconnected has decreased as the second information. (S15). Based on this information, the load distribution module 8 further updates the third information (S101).

  The update operation of the assumed traffic volume table in the load distribution module 8 of the present embodiment will be described with reference to FIG.

  When the load distribution module 8 receives from the control signal processing server 7 information indicating that the traffic amount assumed in the HNB 3 has decreased, the traffic amount assumed in the HNB 3 of the control signal processing server 7 that has transmitted the information. From the accumulated value, a decrease in the traffic volume assumed in the HNB 3 is subtracted, and the number of SCTP Associations is decreased by one.

  The operation after the selection processing operation of the control signal processing server 7 in the load distribution module 8 is the same as in the second embodiment.

According to the communication system according to the present embodiment, when the HNB 3 already connected to the control signal processing server 7 releases the connection, the load distribution module 8 has the smallest cumulative value of traffic volume assumed in the HNB 3. The control signal processing server 7 can be instructed as a connection destination of the HNB 3 that has newly requested connection to the HNB-GW 2. Therefore, by appropriately setting the traffic volume assumed in the HNB 3, it becomes possible to equalize the actual traffic volume, and the traffic volume bias caused by the actual identification information and the number of the UEs 5.
(Fourth embodiment)
So far, the embodiment assuming HNB as the radio base station has been described, but the present invention is not limited to this, and the radio base station is HeNB and the gateway is HeNB-GW by applying to LTE. It is good also as being.

  FIG. 12 illustrates the configuration of the LTE system targeted by the exemplary embodiment. A HeNB (Home evolved Node B; radio base station) 31 is connected to the CN 11 via a HeNB-GW (Home evolved Node B-Gateway; gateway) 21. The HeNB-GW 21 is a gateway that accommodates one or a plurality of HeNBs 31 and relays user data, control signals, and the like between the HeNB 31 and the CN 11. HeNB31 has the cell 41 which is each communication coverage, and performs radio | wireless communication with one or some UE (User Equipment) 51 located there.

FIG. 13 is a sequence diagram showing the operation of the communication system according to the present embodiment.
HeNB31 transmits the 1st information regarding the traffic of HeNB31 to HeNB-GW21. The HeNB-GW 21 receives the first information.

According to the communication system concerning this embodiment, HeNB-GW can grasp | ascertain the information regarding the traffic of HeNB.
(Fifth embodiment)
The present embodiment is an example in which the fourth embodiment is more specific based on the configuration of the communication system shown in FIG.

  FIG. 14 illustrates the internal configuration of the HeNB-GW 21 and the SeGW (security gateway) 61. The HeNB-GW 21 includes a load distribution module 81 and a control signal processing server 71. The load distribution module 81 holds and manages the number of SCTP Associations established by each control signal processing server 71. When there is a connection request from the HeNB 31 to the HeNB-GW 21, the load distribution module 81 selects an optimal control signal processing server 71 for connecting the HeNB 31. The control signal processing server 7 accommodates connection with the HeNB 31 and performs communication processing with the CN 11. The SeGW 61 establishes a secure connection such as IPSec (IP Security Architecture) with the HeNB 31 and encrypts information.

  FIG. 15 is a sequence diagram showing the operation of the communication system according to the present embodiment. When the HeNB 31 is activated (L1), a secure connection is first established between the HeNB 31 and the SeGW 61 (L2). Thereafter, the HeNB 31 transmits a DNS (Domain Name System) Query to the load distribution module 81 (L3). The load distribution module 8 selects the control signal processing server 7 to be connected to the HeNB 31 (L4), and returns the IP address of the selected control signal processing server 7 to the HeNB 31 with a DNS Query Response (L5). Then, SCTP Association for connecting HeNB31 and HeNB-GW21 is established between HeNB31 and the control signal processing server 71 (L6).

  Subsequently, the HeNB 31 requests the HeNB-GW 21 to establish an S1 interface by transmitting an S1 Setup Request to the HeNB-GW 21 (L7). In this request, IEs such as Message Type, Global eNB ID, and eNB Name as shown in FIG. 16 can be used, but are not limited thereto. As illustrated in FIG. 15, the S1 Setup Request transmitted from the HeNB 31 to the HeNB-GW 21 in the present embodiment is a message in which the first information regarding the traffic of the HeNB 31 and the Global eNB ID are combined.

  The operations from L8 to L13 are performed in the same manner as the operations from S8 to S13 in the second embodiment described with reference to FIG.

According to the communication system according to the present embodiment, in the LTE system, the load distribution module 81 newly requests the HeNB-GW 21 to connect the control signal processing server 71 having the smallest accumulated traffic amount assumed in the HeNB 31. It can be instructed as a connection destination of the HeNB 31 that has been performed. Therefore, by appropriately setting the traffic volume assumed in the HeNB 31, it is possible to level the actual traffic volume and the traffic volume bias caused by the actual identification information and the number of the UEs 51.
(Sixth embodiment)
FIG. 17 is a sequence diagram when the HeNB 31 already connected to the control signal processing server 71 releases the connection.

  From L1 to L13, the same operation as that shown in FIG. 15 is performed.

  Then, when HeNB31 cancels | releases the connection with the control signal processing server 71, HeNB De-Registration and SCTP Association disconnection (L14) are performed between HeNB31 and the control signal processing server 71. At this time, the control signal processing server 71 that has been disconnected may transmit information indicating that the traffic volume assumed in the HeNB 31 that has been disconnected has decreased to the load distribution module 81 as second information. Yes (L15). Based on this information, the load distribution module 81 further updates the third information (L101).

  The update operation of the assumed traffic volume table in the load distribution module 81 of the present embodiment is the same as that in the third embodiment. The operation after the selection processing operation of the control signal processing server 71 in the load distribution module 81 is the same as that in the second embodiment.

According to the communication system according to the present embodiment, in the LTE system, when the HeNB 31 already connected to the control signal processing server 71 releases the connection, the load distribution module 81 is assumed to be the cumulative value of the traffic amount assumed in the HeNB 31. The control signal processing server 71 having the smallest value can be instructed as a connection destination of the HeNB 31 that has newly requested connection to the HeNB-GW 21. Therefore, by appropriately setting the traffic volume assumed in the HeNB 31, it is possible to level the actual traffic volume and the traffic volume bias caused by the actual identification information and the number of the UEs 51.
(Other embodiments)
FIG. 18 shows another embodiment. A mapping table of traffic volume assumed in HNB-Identity and HNB3 is stored in advance in the load distribution module 8, and the load distribution module 8 calculates a cumulative value of traffic volume assumed in the HNB3 using the information. In this example, the control signal processing server 7 is used for selection processing based on information including the traffic volume assumed in the HNB 3.

  Here, a parameter (for example, Option Codes 65001-65534 Local / Experiment is used to transmit information including the amount of traffic assumed in HNB-ID and HNB3 to DNS Query using DNS extension by EDNS0 (Extension Mechanisms for DNS). The load distribution module 8 obtains the traffic volume assumed in the HNB at the time of receiving the DNS Query, updates the traffic volume table assumed in the HNB, and selects the control signal processing server 7. You may go.

  The exemplary embodiment has been described above. The present invention is not limited to the embodiments described above, and various modifications can be made within the scope of the gist of the present invention. The above-described embodiments are exemplifications, and various modifications are possible for combinations of the embodiments, combinations of the respective components and processing processes, and such modifications are also within the scope of the present invention. That is understood by the contractor.

  For example, the steps in the processing described in this specification are not necessarily executed in time series in the order described in the sequence diagram. For example, the steps in the processing may be executed in an order different from the order described as the sequence diagram or may be executed in parallel.

Further, the radio base station described in the present specification may include components such as a communication processing unit, a request unit, an information acquisition unit, a control unit, and / or a report unit. Furthermore, a module (for example, a radio base station apparatus or a module for the radio base station apparatus) including these components may be provided. In addition, a method including processing of the constituent element may be provided, and a program for causing the processor to execute processing of the constituent element may be provided. A recording medium in which the program is recorded may be provided.
Of course, such modules, methods, programs and recording media are also included in the present invention.

  In addition, the UE described in the present specification may include components such as an RF (Radio Frequency) transceiver, an antenna, a baseband processor, an application processor, and a memory.

An RF transceiver (RF) transceiver performs analog RF signal processing to communicate with a radio base station. Analog RF signal processing performed by the RF transceiver may include frequency up-conversion, frequency down-conversion, and amplification.
The RF transceiver may be coupled with an antenna and a baseband processor. That is, the RF transceiver may receive modulation symbol data (or OFDM symbol data) from the baseband processor, generate a transmit RF signal, and provide the transmit RF signal to the antenna. The RF transceiver may generate a baseband received signal based on the received RF signal received by the antenna and supply this to the baseband processor.

  The baseband processor performs digital baseband signal processing (data plane processing) and control plane processing for wireless communication. Digital baseband signal processing includes (a) data compression / decompression, (b) data segmentation / concatenation, (c) transmission format (transmission frame) generation / decomposition, and (d) transmission path encoding / decoding. , (E) modulation (symbol mapping) / demodulation, and (f) generation of OFDM symbol data (baseband OFDM signal) by Inverse Fast Fourier Transform (IFFT). On the other hand, the control plane processing includes layer 1 (eg, transmission power control), layer 2 (eg, radio resource management, and hybrid automatic repeat request (HARQ) processing), and layer 3 (eg, attach). , Mobility, and signaling regarding call management) communication management.

  For example, in the case of LTE and LTE-Advanced, digital baseband signal processing by the baseband processor is performed by PDCP (Packet Data Convergence Protocol) layer, RLC (Radio Link Control) layer, MAC (Medium Access Control) layer, and PHY (Phy). ) Layer signal processing may be included. The control plane processing by the baseband processor may include NAS (Non-Access Stratum) protocol, RRC (Radio Resource Control) protocol, and MAC CE (MAC Control Element) processing.

  The baseband processor includes a modem processor (eg, Digital Signal Processor (DSP)) that performs digital baseband signal processing and a protocol stack processor (eg, CPU, Central Processing Unit) that performs control plane processing. Or MPU (Micro Processing Unit). In this case, the protocol stack processor that performs control plane processing may be shared with an application processor to be described later.

  The application processor is also called CPU, MPU, microprocessor, or processor core. The application processor may include a plurality of processors (a plurality of processor cores). The application processor is a system software program (OS (Operating System)) read from a memory or a memory (not shown) and various application programs (for example, a call application, a WEB browser, a mailer, a camera operation application, a music playback application). By executing the above, various functions of the UE are realized.

  In some implementations, the baseband processor and the application processor may be integrated on a single chip. In other words, the baseband processor and the application processor may be implemented as one SoC (System on Chip) device. The SoC device is sometimes called a system LSI (Large Scale Integration) or a chip set.

  The memory is volatile memory or non-volatile memory or a combination thereof. The memory may include a plurality of physically independent memory devices. The volatile memory is, for example, SRAM (Static Random Access Memory), DRAM (Dynamic RAM), or a combination thereof. The non-volatile memory is a mask M (Mask) ROM (Read Only Memory), an EEPROM (Electrically Erasable Programmable ROM), a flash memory, or a hard disk drive, or any combination thereof. For example, the memory may include a baseband processor, an application processor, and an external memory device accessible from the SoC. The memory may include an embedded memory device integrated within the baseband processor, within the application processor, or within the SoC. Further, the memory may include a memory in a UICC (Universal Integrated Circuit Card).

The memory may store a software module (computer program) including a group of instructions and data for performing processing by the UE described in the above embodiments.
In some implementations, the baseband processor or application processor may be configured to perform the UE processing described in the above embodiments by reading and executing the software module from memory.
(Appendix 1)
A communication system having a core network, a radio base station, and a gateway connected therebetween,
A communication system, wherein the gateway includes means for receiving, from the radio base station, first information related to traffic of the radio base station.

  This application claims the priority on the basis of Japanese application Japanese Patent Application No. 2015-185572 for which it applied on September 18, 2015, and takes in those the indications of all here.

1 CN
2 HNB-GW
3 HNB
4, 41 cell 5, 51 UE
6, 61 SeGW
7, 71, 7-1 to 7-N, 71-1 to 71-N Control signal processing server 8, 81 Load distribution module 21 HeNB-GW
31 HeNB

Claims (6)

A gateway connected between a core network and a radio base station,
From the wireless base station, it has a means for receiving a first information about the traffic on the radio base station,
The gateway has at least one server;
The server receives the first information from the radio base station;
The gateway has a load balancing module;
The server transmits second information based on the first information received from the radio base station to the load distribution module;
When the traffic amount assumed in the radio base station is not set as the first information, the server includes information including a default value preset by the server as the second information. Gateway to send to the load balancing module .   The gateway according to claim 1, wherein the first information is information including a traffic volume assumed in the radio base station, which is set in advance.   The gateway according to claim 1 or 2, wherein the first information is transmitted by a Home Node B (HNB) REGISTER REQUEST message. The load distribution module is based on the second information,
Managing the load state of the server as third information;
The gateway according to claim 1 . When the radio base station is connected to the gateway, the second information indicates that the amount of traffic assumed in the radio base station has increased,
When the radio base station is released from said gateway, said second information indicates that the amount of traffic is assumed in the radio base station is reduced, according to any one of claims 1 to 4 gateway. The gateway according to claim 4 , wherein the load distribution module selects a server to which the radio base station is connected based on the third information.

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