JP2014075664A - Bearer relay device, communication method for bearer relay device, communication program for bearer relay device, and communication system - Google Patents

Abstract

The present invention relates to a bearer relay device, a bearer relay device communication method, a bearer relay device communication program, which can reduce network congestion and prevent a decrease in service to a user of a mobile terminal device in communication, An object is to provide a communication system.
An SGW 3c as a bearer relay device is configured such that an access restriction signal receiving unit 4 that receives an access restriction signal that restricts voice transmission from a UE 9 or the like, and a UE 9 or the like that has established a control signal bearer 2a or the like. The determination unit 6 that determines whether or not a call is in progress with reference to the value of the QCI, and the determination unit 6 does not discard the packet signal transmitted from the UE that the determination unit 6 determines to be in a voice call. A UE that is determined not to be in a voice call is a mobile terminal device subject to access restriction, and a signal discard unit 8 that discards a packet signal transmitted from the mobile terminal device subject to restriction.
[Selection] Figure 2

Description

  The present invention relates to a bearer relay device that relays data transmission / reception between a mobile terminal device and a network via a bearer, a communication method for the bearer relay device, a communication program for the bearer relay device, and a communication system.

  Conventionally, methods for reducing network congestion are known (see Patent Documents 1 and 2). Patent Document 1 discloses that when it is determined that a receiving-side mobile device exists in a communication restriction area, communication control according to a communication request from a calling-side mobile device is stopped. Further, Patent Document 2 discloses that a reception rate related to signal reception is obtained, and a received signal related to a SIP telephone terminal whose obtained reception rate reaches a preset reception rate is discarded. .

JP 2009-147634 A JP 2007-251419 A

In the techniques disclosed in Patent Documents 1 and 2, the contents of signals transmitted and received by terminal devices such as mobile devices and SIP telephone terminals at the time of communication restriction are not considered. For this reason, for example, in a VoLTE (Voice over LTE (Long Term Evolution)) service, when a SIP (Session Initiation Protocol) bearer (packet transmission path) is always connected by default, the communication restriction of a terminal device during a voice call is established. If this technology is used, the congestion of the network can be reduced, but the SIP packet signal passing through this bearer may be discarded and the call may not be disconnected. As a result, even if the user of the terminal device intends to end the call, the billing is continued and the user is disadvantaged.
An object of the present invention is to reduce a network congestion and prevent a service degradation for a user of a mobile terminal device during communication, a bearer relay device, a bearer relay device communication method, a bearer relay device communication program, and a communication To provide a system.

  A bearer relay device according to an aspect of the present invention is a bearer relay device that relays transmission / reception of IP packets between an IP network and a mobile terminal device, and transmits an access restriction signal that restricts voice transmission from the mobile terminal device. When an access restriction signal receiving unit receives from the access restriction control device and the access restriction signal receiving unit receives the access restriction signal, an IP packet indicates whether or not the mobile terminal device with the bearer established is in a voice call. A determination unit that determines with reference to the communication control parameters, and the determination unit does not discard the packet signal transmitted from the mobile terminal device that is determined to be in the voice call, and the determination unit is in the voice call The mobile terminal device that has been determined not to be a mobile terminal device subject to access control is defined as a mobile terminal device subject to access control. And having a preparative signal discard signal discarding unit. According to such a configuration, it is possible to reduce network congestion and prevent a decrease in service to a user of a mobile terminal device during communication.

The communication control parameter may be a QoS (Quality of Service) class identifier. According to such a configuration, it is possible to determine whether or not voice data is included in the transmitted packet, and it is possible to prevent a decrease in service to the user of the mobile terminal device during communication.
In addition, the signal discarding unit originates from the restriction target mobile terminal device corresponding to a predetermined ratio with respect to the total number of the mobile terminal devices or the total number of restriction target mobile terminal devices that have been determined whether or not a voice call is in progress The packet signal to be discarded may be discarded. According to such a configuration, network congestion can be further reduced.

In addition, the signal discarding unit may not discard a packet signal transmitted from a mobile terminal device with an access restriction function having an access restriction function. According to such a configuration, it is possible to prevent the mobile terminal device with an access restriction function from being excessively restricted and to restrict access to the mobile terminal device with the access restriction function and the mobile terminal device that does not have the access restriction function. Can ensure fairness.
In addition, the determination unit may not determine whether or not the mobile terminal device with access restriction function is in a voice call. According to such a configuration, it is possible to prevent the mobile terminal device with an access restriction function from being excessively restricted as compared with a mobile terminal device that does not have an access restriction function.

  A communication system according to an aspect of the present invention is a communication system including a network including a gateway device, and a wireless base station that connects the network and a mobile terminal device, and includes the gateway device and the wireless base station. Either one is the bearer relay device of the present invention described above. According to such a configuration, since it is possible to regulate communication with a device closer to the mobile terminal device, it is possible to reduce network traffic.

  A bearer relay device communication method according to an aspect of the present invention is a bearer relay device communication method that relays transmission / reception of IP packets between an IP network and a mobile terminal device, and performs voice transmission from the mobile terminal device. When receiving the access restriction signal to be restricted from the access restriction control device and receiving the access restriction signal, refer to the communication control parameter of the IP packet whether or not the mobile terminal device with the bearer established is in a voice call. The mobile terminal device determined not to be in a voice call without discarding the packet signal transmitted from the mobile terminal device determined to be in a voice call The target mobile terminal device is discarded, and a packet signal transmitted from the restricted mobile terminal device is discarded. According to such a configuration, it is possible to reduce network congestion and prevent a decrease in service to a user of a mobile terminal device during communication.

  A communication program for a bearer relay device according to an aspect of the present invention is a communication program for a bearer relay device that relays transmission / reception of IP packets between an IP network and a mobile terminal device. An access restriction signal receiving unit that receives an access restriction signal for restricting voice transmission from the access restriction control device; and when the access restriction signal receiving unit receives the access restriction signal, the mobile terminal device with the bearer established A determination unit that determines whether or not a call is in progress with reference to a communication control parameter of an IP packet, and discards a packet signal transmitted from the mobile terminal device that the determination unit determines to be in the voice call Without restricting the mobile terminal device that is determined not to be in the voice call by the determination unit to be subject to access restriction And device, characterized in that to function packet signal transmitted from the regulated mobile terminal device as a discard signal discarding unit. According to such a configuration, it is possible to reduce network congestion and prevent a decrease in service to a user of a mobile terminal device during communication.

  ADVANTAGE OF THE INVENTION According to this invention, while reducing network congestion, the fall of the service with respect to the user of the mobile terminal device in communication can be prevented.

1 is a block diagram showing a schematic configuration of a communication system 1 according to a first embodiment of the present invention. It is a block diagram which shows schematic structure of SGW (Serving-Gateway) 3c as a bearer relay apparatus by the 1st Embodiment of this invention. It is a sequence diagram for demonstrating the communication method of the general communication system as a comparative example with respect to Example 1-1 of the 1st Embodiment of this invention. It is a sequence diagram for demonstrating the bearer relay apparatus by Example 1-1 of the 1st Embodiment of this invention, and the communication method of the communication system 1 provided with the same. It is a flowchart which shows the flow of the access control process in SGW3c as a bearer relay apparatus by the 1st Embodiment of this invention. It is a sequence diagram for demonstrating the communication method of the general communication system as a comparative example with respect to Example 1-2 of the 1st Embodiment of this invention. It is a sequence diagram for demonstrating the bearer relay apparatus by Example 1-2 of the 1st Embodiment of this invention, and the communication method of the communication system 1 provided with the same. It is a flowchart which shows the flow of the access control process in SGW3c as a bearer relay apparatus by the modification of the 1st Embodiment of this invention. It is a block diagram which shows schematic structure of the communication system 100 by the 2nd Embodiment of this invention. It is a sequence diagram for demonstrating the communication method of the general communication system as a comparative example with respect to Example 2-1 of the 2nd Embodiment of this invention. It is a sequence diagram for demonstrating the bearer relay apparatus by Example 2-1 of the 2nd Embodiment of this invention, and the communication method of the communication system 1 provided with the same. It is a sequence diagram for demonstrating the communication method of the general communication system as a comparative example with respect to Example 2-2 of the 2nd Embodiment of this invention. It is a sequence diagram for demonstrating the bearer relay apparatus by Example 2-2 of the 2nd Embodiment of this invention, and the communication method of the communication system 100 provided with the same.

[First Embodiment]
(Schematic configuration of communication system 1 and EPC network device 3)
A bearer relay device, a bearer relay device communication method, and a communication system according to a first embodiment of the present invention will be described with reference to FIGS. First, a schematic configuration of a bearer relay device according to the present embodiment and a communication system including the same will be described with reference to FIGS. 1 and 2. In the present embodiment, a description will be given taking an SGW (Serving-Gateway) as an example of a bearer relay device. In this embodiment, a mobile communication system that transmits and receives data between a mobile terminal device and an IP network will be described as an example.

  FIG. 1 shows a schematic configuration of a communication system 1 according to the present embodiment. In FIG. 1, the interface of EPC (Evolved Packet Core) -related control signals between nodes is represented by a broken line, and the interface for transferring user data (for example, a SIP (Session Initiation Protocol) signal) between nodes is represented by a solid line. ing.

  As shown in FIG. 1, a communication system 1 according to the present embodiment transmits an IP packet with an IMS (IP Multimedia Subsystem) 5 that provides an IP-based multimedia communication service such as VoIP (Voice over Internet Protocol). EPC network device 3 that is a core network and mobile user equipment (User Equipment: UE) 9a1, 9a2, 9a3, 19a1 to 19an, 29a1 to 29an (n is a natural number of 2 or more) , UE9a1, 9a2, 9a3, 19a1 to 19an, 29a1 to 29an may be abbreviated as “UE9a1, 9a2, 9a3, etc.”, UE9a1, 9a2, 9a3, etc. and LTE (Long Term Evol) radio base station (eNodeB: eNB) 7 that performs radio communication according to the (uttion) scheme and connects the UEs 9a1, 9a2, 9a3, etc. to the EPC network device 3, respectively, and holds user information about the UEs 9a1, 9a2, 9a3, etc. A subscriber management server (Home Subscriber Server: HSS) 11 is provided. The EPC network apparatus 3, IMS 5, eNB 7 and HSS 11 constitute an IP network.

  The eNB 7 is configured to form an LTE coverage area E by sending, for example, a cell ID to a specific range. The LTE area E is divided into a plurality of areas (in this example, three areas E1, E2, and E3). The area E1, the area E2, and the area E3 may be provided so as not to overlap in the LTE area E, or may be provided so as to partially overlap. The area E1, the area E2, and the area E3 are included in the information to be controlled that is transmitted together with the access restriction signal that restricts the voice transmission of the mobile terminal device located in the LTE area E (details will be described later) . For example, when the area E1 is included in the restriction target information, the SGW 3c as the relay device determines that the area E1 is a restriction target area for restricting the voice transmission of the mobile terminal device, and the area E1 is connected to the PGW 3b. Then, it is determined whether or not the voice transmission is restricted for each of the UEs 9a1, 9a2, and 9a3 for which the control signal bearer is established (details will be described later).

  The communication system 1 is monitored by an operation system (OPS) 10. The maintenance person monitors the traffic of the communication system 1 and the load state of the node, and if any of the areas E1 to E3 in the IP network of the communication system 1 is expected to be congested or is congested. If determined, a restriction operation (command registration) is executed for the OPS 10. As a result, the OPS 10 sends an access restriction signal for restricting voice transmission from the mobile terminal device to the MME 3d together with a signal including restriction target information (a restriction target area in the present embodiment) (details will be described later).

The HSS 11 is a subscriber information database that holds user information related to the UEs 9a1, 9a2, 9a3, etc., and manages authentication information and location information.
The IMS 5 is provided with an SCSCF (Serving Call / Session Control Function) 5a, a PCSCF (Proxy Call / Session Control Function) 5b, and an application server (not shown). The SCSCF 5a, the PCSCF 5b, and the application server may be realized as physically separate devices, or may be realized as a function of the IMS 5, respectively. The SCSCF 5 a of IMS 5 and the application server are connected to the HSS 11.

  The SCSCF 5a is a SIP server having a function of acquiring and holding user information of a UE located in the LTE area E from the HSS 11 holding the user information, and performing session control and the like. The SCSCF 5a manages the connection between the private user IDs of the logged-in UEs 9a1, 9a2, 9a3, and the public user ID.

  The PCSCF 5b is connected to the SCSCF 5a, and can send and receive SIP signals to and from the SCSCF 5a. The PCSCF 5b is assigned to each of the UEs 9a1, 9a2, 9a3, etc. when the UEs 9a1, 9a2, 9a3, etc. are registered. The PCSCF 5b is a function that, after authenticating the UEs 9a1, 9a2, 9a3, etc., transmits / receives IP packets to / from the authenticated UEs 9a1, 9a2, 9a3, etc., and compresses data in order to efficiently transfer SIP messages. have.

  The EPC network device 3 is connected to the IMS 5 and the eNB 7 and connects between the IMS 5 and the eNB 7. The EPC network apparatus 3 is provided with PCRF (Policy and Charging Rules Function) 3a, PGW (Packet Data Network (PDN) -Gateway) 3b, SGW 3c, and MME (Mobility Management Entity) 3d. The PCRF 3a, PGW 3b, SGW 3c, and MME 3d may be respectively realized as physically separate devices, or may be realized as one function exhibited by the EPC network device 3.

The PCRF 3a is connected to a PCSCF 5b provided in the IMS 5, and a predetermined control signal can be transmitted to and received from the PCSCF 5b. The PCRF 3a determines an IP packet transmission policy such as QoS (Quality of Service) and a charging method for performing transmission quality control in the PGW 3b and the SGW 3c.
The PGW 3b is connected to the PCRF 3a and the SGW 3c, and can transmit / receive a predetermined control signal to / from these nodes. The PGW 3b is a connection point with the PDN such as the IMS 5, and is a gateway device that assigns an IP address and receives all user data packets from the PDN to the UEs 9a1, 9a2, 9a3, and the like.

  The MME 3d is connected to the HSS 11. The MME 3d performs mobility management of the UEs 9a1, 9a2, 9a3, etc., authentication (security control) of the UEs 9a1, 9a2, 9a3, etc. based on authentication information notified from the HSS 11, and control that is a user data transfer path between the SGW 3c and the eNB 7 Signal bearers 2a1, 2a2, 2a3, 12a1 to 12an, 22a1 to 22an (n is a natural number of 2 or more) (hereinafter 2a1, 2a2, 2a3, 12a1 to 12an, 22a1 to 22an are referred to as “2a1, 2a2, 2a3, etc.”) (This may be abbreviated.)

  The SGW 3c is connected to the MME 3d and is a gateway device that performs transmission control of user data packets based on a command from the MME 3d. The SGW 3c relays the user data packet transferred from the PGW 3b or the eNB 7 to the eNB 7 or the PGW 3b. In addition, when the SGW 3c receives an access restriction signal sent from the OPS 10 to restrict voice transmission from the mobile terminal equipment via the MME 3d, the mobile terminal equipment existing in the restricted area sent together with the access restriction signal. The packet signal transmitted from the mobile terminal device is discarded based on whether or not the voice call is in progress.

  In FIG. 1, UE 9 a 1 is in a voice call with an unillustrated called-side mobile terminal device, and a session is established between UE 9 a 2, 9 a 3, 19 a 1 to 19 an, and 29 a 1 to 29 an with the IP network of communication system 1. The communication system 1 is illustrated as being in a state where a voice call is not being made. Therefore, a control signal bearer 2a1 (details will be described later) and a voice signal bearer 2b1 (details will be described later) are established between the PGW 3b and the UE 9a1 via the SGW 3c. In contrast, control signal bearers 2a2 and 2a3 (details will be described later) are established between the PGW 3b and the UEs 9a2 and 9a3 via the SGW 3c, but between the PGW 3b and the UE 9a2 and between the PGW 3b and the UE 9a3. Has no established voice signal bearer. Furthermore, control signal bearers 12a1 to 12an are established between the PGW 3b and the UEs 19a1 to 19an via the SGW 3c, and control signal bearers 22a1 to 22an are established between the PGW 3b and the UEs 29a1 to 29an via the SGW 3c. However, no voice signal bearer is established between the PGW 3b and the UE 19 and between the PGW 3b and the UE 29.

  The control signal bearers 2a1, 2a2, 2a3, and the like are packet transmission paths through which SIP signals are transmitted and received. The control signal bearers 2a1, 2a2, 2a3, etc. are held respectively after the UE 9a1, 9a2, 9a3, etc. are attached to the IP network until they are detached. The PCSCF 5b is IP-connected to the PGW 3b. Thereby, the SIP signals transmitted from the UEs 9a1, 9a2, 9a3, etc. and transmitted through the control signal bearers 2a1, 2a2, 2a3, etc. are transmitted from the PGW 3b to the PCSCF 5b. Further, the SIP signal transmitted from the PCSCF 5b is transmitted to the PGW 3b, and is transmitted to the UEs 9a1, 9a2, 9a3, etc. through the control signal bearers 2a1, 2a2, 2a3, etc. The voice signal bearer 2b1 is a packet transmission path through which voice data converted into IP packets is transmitted and received. The voice signal bearer 2b1 is established every time a voice signal is transmitted or received. The voice signal bearer 2b1 is held until a voice call is started and ended between the UE 9a1 and a mobile terminal device (not shown) on the receiving side via, for example, an IP network (not shown). The audio signal is transmitted from the PGW 3b to the mobile terminal device on the receiving side via, for example, the IP network.

(Schematic configuration of SGW3c as a bearer relay device)
FIG. 2 is a block diagram of a schematic configuration of the SGW 3c related to the restriction of voice transmission of the mobile terminal device. In FIG. 2, PCRF 3 a, OPS 10, and UEs 9, 19, and 29 are shown together with SGW 3 c for easy understanding. As illustrated in FIG. 2, the SGW 3 c includes an access restriction signal reception unit 4, a determination unit 6, and a signal discard unit 8.

  The access restriction signal receiving unit 4 is an access restriction that restricts voice transmission from UEs in the restricted area that is subject to restriction, for example, when a disaster occurs or an event is held in the LTE area E. A signal is received from the OPS 10 as an access restriction control device. When the access restriction signal receiving unit 4 receives the access restriction signal, the determination unit 6 receives the UE (in this example, the control signal bearer) in which the control signal bearer has been established in the restriction target area (area E1 in this example). Whether or not the UEs 9a1, 9a2, and 9a3 in which 2a1, 2a2, and 2a3 are established is in a voice call, determines whether or not a communication control parameter (for example, a QoS (Quality of Service) class identifier (QoS Class Identifier), It is determined with reference to “QCI”)). The determination unit 6 acquires the QCI value corresponding to the UE that determines whether or not a voice call is in progress from the PCRF 3a. The QCI value is divided into nine types according to the type and priority of data included in the transmitted packet, and takes one of “1” to “9”. When the data type is audio data, the QCI value is “1”. Therefore, by determining the QCI value, it can be determined whether or not the UEs 9a1, 9a2, and 9a3 are in a voice call.

  The signal discarding unit 8 is configured not to discard the packet signal transmitted from the UE that is determined by the determination unit 6 to be in a voice call. Further, the signal discarding unit 8 sets the UE determined by the determining unit 6 not to be in a voice call as a restricted mobile terminal device subject to access restriction, and discards a packet signal transmitted from the restricted mobile terminal device. It has become. Further, the signal discarding unit 8 discards packet signals transmitted from a regulated mobile terminal device at a predetermined ratio among the regulated mobile terminal devices.

  In this example, since the UE 9a1 is in a voice call, the signal discarding unit 8 determines that the UE 9a1 is not subject to access restriction and is not a restricted mobile terminal device, and does not discard the packet signal from the UE 9a1. In this example, since the UE 9a2 and the UE 9a3 are not in a voice call, the signal discarding unit 8 determines that the UE 9a2 and the UE 9a3 are the restriction target mobile terminal devices, and the UE 9a2 corresponding to a predetermined ratio with respect to the restriction target mobile terminal device. , 9a3 is discarded. In this example, for example, the signal discarding unit 8 discards the packet signal that is output from the UE 9a2 and transmits the control signal bearer 2a2, and does not discard the packet signal that is output from the UE 9a3 and transmits the control signal bearer 2a3. Further, although the UEs 19a1 to 19an and the UEs 29a1 to 29an are located in the LTE area E, the UEs 19a1 to 19an do not exist in the area E1 that is the restriction target area, and thus are not subject to voice transmission restriction. The signal discarding unit 8 may be configured to determine the predetermined ratio based on the number of restriction target mobile terminal devices determined by the determination unit 6 as an access restriction target. Alternatively, the signal discarding unit 8 may be configured to determine the predetermined ratio based on the number of mobile terminal devices that have determined whether or not the SGW 3c is in a voice call.

(Communication Method of Communication System 1 (Example 1-1))
Next, a communication method of the communication system 1 according to Example 1 of the present embodiment will be described with reference to FIGS. 3 to 5 with reference to FIGS. First, before describing the communication method of the communication system 1 according to the present embodiment, a communication method of a general communication system as a comparative example with respect to the present embodiment will be described with reference to FIG. FIG. 3 is a sequence diagram showing a communication method of a general communication system. The communication system has substantially the same configuration as the communication system 1 according to the present embodiment except for the SGW. In FIG. 3, UEs 9a1, 9a2, 9a3, SGW53c and PGW3b provided in the communication system (in FIG. 3, SGW53c and PGW3b are collectively represented as “S / PGW53c, 3b”), MME3d, and PCSCF5b. Only the OPS 10 for monitoring the communication system is shown. The UEs 9a1, 9a2, 9a3, PGW3b, MME3d, and PCSCF5b have the same configuration as the UE9a1, 9a2, 9a3, PGW3b, MME3d, and PCSCF5b provided in the communication system 1 and perform the same functions. . The OPS 10 that monitors the communication system has the same configuration as the OPS 10 that monitors the communication system 1 and exhibits the same functions. The SGW 53c has the same configuration as that of the SGW 3c provided in the communication system 1 except that the determination unit 6 and the signal discard unit 8 are not provided and does not exhibit these functions. It is supposed to be.

  As illustrated in FIG. 3, an IP session is established between the UE 9 a 1 and the PGW 3 b when the UE 9 a 1 is powered on, and the control signal bearer 2 a 1 is established (step S 51). Next, when the UE 9a1 performs, for example, VoLTE (Voice over LTE) transmission, the transmission signal is transferred to the PCSCF 5b that performs call control via the PGW 3b via the control signal bearer 2b1. The PCSCF 5b proceeds with call processing with the terminating IP network (not shown), and requests the PCRF 3a (see FIG. 1) to secure the voice communication bearer 2b1 of the UE 9a1. The PCRF 3a instructs the bearer resource for the audio signal to the PGW 3b and the SGW 53c from the audio information received from the PCSCF 5b. When the PGW 3b and the SGW 53c set the voice signal bearer, the voice signal bearer 2b1 that secures the voice quality is established between the UE 9a1 and the PGW 3b (step S52).

  In addition, an IP session is established between the UE 9a2 and the PGW 3b when the UE 9a2 is powered on, and the control signal bearer 2a2 is established (step S53). Further, an IP session is established between the UE 9a3 and the PGW 3b when the UE 9a3 is turned on, and the control signal bearer 2a3 is established (step S54). In this example, since the UE 9a2 and the UE 9a3 do not perform VoLTE transmission, for example, no voice signal bearer is established between the UEs 9a2, 9a3 and the PGW 3b.

  Thereafter, when the maintenance person monitoring the communication system predicts that the area E1 of the LTE coverage area E of the IP network of the communication system becomes congested due to, for example, occurrence of a disaster or holding of a predetermined event, the OPS 10 A restriction operation (command registration) is executed on Thereby, the OPS 10 sends an access restriction signal for restricting voice transmission from the mobile terminal device to the MME 3d together with a signal including information on the restriction target area (area E1 in this example) to notify the access restriction (step S55). ). The MME 3d transfers a signal including information on the restriction target area together with the received access restriction signal to the SGW 53c (Step S56).

  The SGW 53c that has received the access restriction signal is a predetermined ratio (for example, 50% in this example) of the mobile terminal devices that exist in the area E1 that is the restriction target area and that have established a control signal bearer with the PGW 3b. The access restriction process for discarding the SIP signal from the mobile terminal device is executed. The SGW 53c executes access restriction processing for the UE 9a1 with which the control signal bearer 2a1 is established with the PGW 3b. Currently, 0 of the 3 SIP signals are discarded, and the signal discard rate is 0%. Therefore, it is determined that it has not reached 50% (step S59), and the SIP signal from the UE 9a1 is discarded (step S58). Further, the SGW 53c executes access restriction processing for the UE 9a2 with which the control signal bearer 2a2 is established with the PGW 3b, and the SIP signal discarded at this time is one out of three, and the signal discard ratio is 33. %, And it is determined that it has not reached 50% (step S59), and the SIP signal from the UE 9a2 is discarded (step S60). Further, the SGW 53c executes access restriction processing for the UE 9a3 with which the control signal bearer 2a3 is established with the PGW 3b, and two SIP signals discarded at this time are two, and the signal discard ratio is 66. It is determined that it has reached 50% (step S61), and the SIP signal from the UE 9a3 is not discarded. As a result, the SIP signal transmitted from the UE 9a3 and transmitted through the control signal bearer 2a3 is transmitted to the PCSCF 5b via the PGW 3b (step S62).

  As described above, a general communication system regulates voice transmission for a certain percentage of mobile terminal devices regardless of whether or not a voice call is in progress. For this reason, in the communication system, when the SIP signal transmitted from the mobile terminal device already carrying out the voice call when the access restriction is applied and transmitting the control signal bearer is discarded, the call cannot be disconnected. As a result, even if the user of the mobile terminal device intends to end the call, there is a problem that the voice call is actually continued and charging is continued.

In contrast, the bearer relay device according to the present embodiment determines whether or not the mobile terminal device is in a voice call, and does not discard the SIP signal from the mobile terminal device determined to be in a voice call. As a result, the mobile terminal device during the voice call is not restricted from the voice call, and the above-described problem of a general communication system does not occur.
FIG. 4 is a sequence diagram illustrating a communication method of the communication system 1 according to the present embodiment. 4, UEs 9a1, 9a2, 9a3, SGW3c, and PGW3b provided in the communication system 1 (in FIG. 4, SGW3c and PGW3b are collectively represented as “S / PGW3c, 3b”), MME3d, and PCSCF5b. Only the OPS 10 for monitoring the communication system 1 is shown.

  The operations from Steps S1 to S6 shown in FIG. 4 are the same as the operations from Steps S51 to S56 shown in FIG. As shown in FIG. 4, the MME 3 d includes an access restriction signal for restricting voice transmission from the mobile terminal device and information on the restriction target area (in this embodiment, the restriction target area, which is the area E <b> 1 in this example). The signal is transferred to the SGW 3c together with the signal. The SGW 3c that has received the access restriction signal from the MME 3d determines whether or not a voice call is in progress for each of the mobile terminal devices for which the control signal bearer is established in the restriction target area (in this example, the area E1). Access control including voice call determination processing and signal discard processing for discarding SIP signals from a predetermined percentage (for example, 50% in this example) of mobile terminal devices determined not to be in a voice call Processing is executed (step S7).

  FIG. 5 is a flowchart showing the flow of access restriction processing executed in the SGW 3c. The access restriction process is executed when the SGW 3c receives a restriction request signal (access restriction signal), for example. The SGW 3c executes the access restriction process shown in FIG. 5 for the mobile terminal device that is transmitted together with the access restriction signal and has the control signal bearer established in the restriction target area included in the restriction target information. For example, when the access restriction signal receiving unit 4 provided in the SGW 3c receives the access restriction signal, as shown in FIG. 5, a voice call determination process and a signal discard process are performed for each mobile terminal apparatus for which the control signal bearer is established. Are sequentially executed (step S101). In this example, since the mobile terminal devices for which the control signal bearers 2a1, 2a2, and 2a3 are established in the area E1 are the UEs 9a1, 9a2, and 9a3, the SGW 3c performs the voice call determination process for any of the UEs 9a1, 9a2, and 9a3. Then, it is determined that the signal discarding process is to be executed, and the process proceeds to step S102. For example, the SGW 3c determines the execution of both processes for the UE 9a1 in which the control signal bearer 2a1 is established with the PGW 3b.

  If it is determined in step S101 that both the processes are executed for the UE 9a1, the process proceeds to step S102 to determine whether or not the QCI value corresponding to the UE 9a1 is “1”. The QCI value is stored in the PCRF 3a in association with each of the UEs 9a1, 9a2, and 9a3. For this reason, for example, the determination unit 6 provided in the SGW 3c acquires the QCI value corresponding to the UE 9a1 from the PCRF 3a, determines whether or not the value is “1”, and determines that it is “1”. Then, the process proceeds to step S103, and if it is any of “2” to “9” and not “1”, the process proceeds to step S104. In this example, since the voice communication bearer 2b1 is established and the UE 9 is in a voice call, the QCI value acquired from the PCRF 3a is “1”. Therefore, the determination unit 6 determines that the QCI value is “1”, and proceeds to step S103.

  In step S103 following step S102, it is determined not to discard the packet signal transmitted from the mobile terminal device determined to be in a voice call. For example, the signal discarding unit 8 provided in the SGW 3c proceeds to Step S105 without discarding the SIP signal transmitted from the UE 9a1 that is performing a voice call. Thereby, the SIP signal transmitted from the UE 9a1 and transmitting the control signal bearer 2a1 is transmitted to the PCSCF 5b via the PGW 3b (see step S8 in FIG. 4).

  In step S105 following step S103, it is determined whether or not there is a mobile terminal device that has not been subjected to access restriction processing. If it is determined that there is an unexecuted mobile terminal device, the process proceeds to step S101, and an unexecuted mobile terminal is performed. If it is determined that there is no device, the access restriction process is terminated. For example, the SGW 3c determines that the access restriction process is not performed on the UEs 9a2 and 9a3 in which the control signal bearers 2a2 and 2a3 are established with the PGW 3b in the area E1 that is the restriction target area, The process proceeds to S101. If the SGW 3c determines in step S102 that the mobile terminal device is in a voice call, in step S105, the SGW 3c executes a process for reducing the number of restriction target mobile terminal devices serving as a reference of a predetermined ratio. For example, the SGW 3c subtracts 1 from the total number of mobile terminal devices that execute access restriction processing (in this example, “3”), and sets the number of restriction-target mobile terminal devices that serve as a reference of a predetermined ratio to “2”.

  If it is determined in step S101 that the voice call determination process and the signal discard process are performed for the UE 9a2, the process proceeds to step S102, and it is determined whether or not the QCI value corresponding to the UE 9a2 is 1. For example, the determination unit 6 acquires the QCI value corresponding to the UE 9a2 from the PCRF 3a, and determines whether or not the value is “1”. In this example, since the UE 9a2 has not established a voice communication bearer and is not in a voice call, the QCI value acquired from the PCRF 3a is a value other than “1”. For this reason, the determination unit 6 determines that the QCI value is not “1” and proceeds to step S104.

  In step S104 subsequent to step S102, packet signals transmitted from a predetermined percentage of the restriction target mobile terminal devices out of the restriction target mobile terminal devices that are determined not to be in a voice call and are subject to access restriction are discarded. For example, the signal discarding unit 8 determines that the number of SIP signals discarded at this time is 0 out of 2 and the signal discard rate is 0% and has not reached 50%, and the SIP signal from the UE 9a2 is received. Discard (see step S9 in FIG. 4), and proceed to step S105.

  In step S105 subsequent to step S103, for example, the SGW 3c determines that the access restriction process is not executed for the UE 9a3 in which the control signal bearer 2a3 is established in the area E1 that is the restriction target area, The process proceeds to S101. Since the SGW 3c determines in step S102 that the UE 9a2 is not in a voice call, in step S105, the SGW 3c does not change the number of restriction-target mobile terminal devices serving as a reference for a predetermined ratio.

  If it is determined in step S101 that the voice call determination process and the signal discard process are executed for the UE 9a3, the process proceeds to step S102, and it is determined whether or not the QCI value corresponding to the UE 9a3 is “1”. For example, the determination unit 6 acquires the QCI value corresponding to the UE 9a3 from the PCRF 3a, and determines whether or not the value is “1”. In this example, since the UE 9a3 has not established a voice communication bearer and is not in a voice call, the QCI value acquired from the PCRF 3a is a value other than “1”. For this reason, the determination unit 6 determines that the QCI value is not “1” and proceeds to step S104.

In step S104 subsequent to step S102, for example, the signal discarding unit 8 discards one SIP signal at the present time, and the ratio of discarding the signal is 50% and reaches a predetermined ratio of 50%. It moves to step S105, without discarding the SIP signal transmitted from UE9a3. As a result, the SIP signal transmitted from the UE 9a3 and transmitted through the control signal bearer 2a3 is transmitted to the PCSCF 5b via the PGW 3b (see step S10 in FIG. 4).
In step S105 subsequent to step S103, for example, the SGW 3c determines that there is no mobile terminal device that has not performed the access restriction process in the area E1, and ends the access restriction process.

  Once the access restriction process shown in FIG. 5 is started, the SGW 3c executes the access restriction process at predetermined time intervals until an access restriction release signal is transmitted from the OPS 10 to the SGW 3c. In the access restriction process executed after a predetermined time elapses, for example, when the UE 9a1 has finished the voice call and the UE 9a3 has started the voice call, the UE 9a1 is connected to the restricted mobile terminal device subject to access restriction. It is determined (No in step S102), and the UE 9a3 is determined to be a mobile terminal device that is not subject to access restriction (Yes in step S102). In addition, every time the access restriction process is executed from the start to the release of the access restriction process, the SGW 3c sequentially changes the restriction target UEs among the UEs that are not in a voice call. Thereby, the SGW 3c prevents the restriction of voice transmission from concentrating on one UE.

  In the present embodiment, the reference of the predetermined ratio of the restriction on the mobile terminal device is the total number of restriction target mobile terminal devices, but is not limited thereto. For example, the reference of the predetermined ratio may be the total number of mobile terminal devices that are determined whether or not a voice call is in progress. In this case, in step S105 after it is determined in step S102 that the mobile terminal device is in a voice call, the process of subtracting the total number of mobile terminal devices that execute the access restriction process is unnecessary.

  As described above, according to the bearer relay apparatus according to the present embodiment, the communication system including the same, and these communication methods, it is possible to exclude mobile terminal devices that are engaged in a voice call from the targets for discarding SIP signals. It can be prevented that the SIP signal passing through the control signal bearer of the mobile terminal device during a call is discarded and the call cannot be disconnected. Thereby, according to the present embodiment, even if the user of the mobile terminal device intends to end the call, the problem that the billing is continued is solved, and the congestion of the network (IP network) is reduced. The service degradation of the user of the mobile terminal device during a voice call can be prevented, that is, the communication can be disconnected normally. Further, according to the present embodiment, it is possible to realize an IMS transmission restriction method that can discard an SIP signal by an apparatus closer to a mobile terminal device, and to reduce network traffic.

(Communication Method of Communication System 1 (Example 1-2))
Next, a communication method of the communication system 1 according to Example 1-2 of the present embodiment will be described with reference to FIGS. 1 and 2 with reference to FIGS. The communication method of the communication system 1 according to the present embodiment is characterized in that, for example, the access restriction process is executed when the PCSCF determines that the IP network of the communication system 1 is congested. The communication system 1 according to the present embodiment has the same configuration as the communication system 1 shown in FIG. 1, but has a PCSCF 55b instead of the PCSCF 5b (see FIG. 7). Further, the communication system according to the present embodiment is monitored by the OPS 50 instead of the OPS 10 (see FIG. 7). The PCSCF 55b has the same configuration as the PCSCF 5b shown in FIG. 3 except that it detects congestion of the IP network of the communication system, and exhibits the same function. The OPS 50 has the same configuration as that of the OPS 10 except that it sends a restriction notification to the MME 3d based on the reception of the congestion detection signal from the PCSCF 55b, and exhibits the same function.

  First, before describing the communication method of the communication system 1 according to the present embodiment, a communication method of a general communication system as a comparative example with respect to the present embodiment will be described with reference to FIG. FIG. 6 is a sequence diagram showing a communication method of a general communication system. The communication system has substantially the same configuration as the communication system 1 according to the present embodiment except for the SGW. In FIG. 6, UEs 9a1, 9a2, 9a3, SGW53c and PGW3b provided in the communication system (in FIG. 6, SGW53c and PGW3b are collectively represented as “S / PGW53c, 3b”), MME3d, PCSCF55b, Only the OPS 50 for monitoring the communication system is shown. UE9a1, 9a2, 9a3, S / PGW53c, 3b and MME3d in this comparative example have the same configuration as UE9a1, 9a2, 9a3, S / PGW53c, 3b and MME3d shown in FIG. It is like that. Further, the PCSCF 55b and OPS 50 in this comparative example have the same configuration as the PCSCF 55b and OPS 50 in this embodiment, and exhibit the same functions.

The operations in steps S251 to S254 shown in FIG. 6 are the same as the operations in S51 to S54 shown in FIG.
After the control signal bearers 2a1, 2a1, 2a1 and the voice signal bearer 2b1 are established, the PCSCF 55b periodically performs a network (IP network) congestion determination (step S255) and detects network congestion (step S255). In step S256), a congestion notification signal is transmitted to the OPS 50 (step S257). The PCSCF 55b determines that the network is congested when the usage rate of a control unit (for example, a CPU (Central Processing Unit)) provided in the PCSCF 55b exceeds a predetermined value.

  The OPS 50 that has received the congestion notification signal from the PCSCF 55b indicates that the access restriction signal for restricting voice transmission from the mobile terminal device is determined to be congested and indicates information on the restriction target area (in this example, area E1). An access restriction is notified by sending it to the MME 3d together with the signal (step S258). MME3d transfers the signal which shows area E1 which is a control object area to SGW53c with the received access control signal (step S259).

  The SGW 53c that has received the access restriction signal is a SIP signal from the mobile terminal device of a predetermined ratio (for example, 50% in this example) among the mobile terminal devices that have established a control signal bearer with the PGW 3b in the area E1. Execute access restriction processing to discard The SGW 53c executes access restriction processing for the UE 9a1 in which the control signal bearer 2a1 is established with the PGW 3b in the area E1, and the SIP signal discarded at this time is 0 out of 3, and the signal discard rate is It is determined that it is 0% and has not reached 50% (step S260), and the SIP signal from the UE 9a1 is discarded (step S261). Further, the SGW 53c executes access restriction processing for the UE 9a2 with which the control signal bearer 2a2 is established with the PGW 3b, and the SIP signal discarded at this time is one out of three, and the signal discard ratio is 33. %, And it is determined that it has not reached 50% (step S262), and the SIP signal from the UE 9a2 is discarded (step S263). As a result, the SIP signals transmitted from the UEs 9a1 and 9a2 and transmitted through the control signal bearers 2a1 and 2a2 are discarded in the SGW 53c and are not transmitted to the PCSCF 55b. Further, the SGW 53c executes access restriction processing for the UE 9a3 with which the control signal bearer 2a3 is established with the PGW 3b, and two SIP signals discarded at this time are two, and the signal discard ratio is 66. % And has reached 50% (step S264), and the SIP signal from the UE 9a3 is not discarded. Thereby, the SIP signal transmitted from the UE 9a3 and transmitted through the control signal bearer 2a3 is transmitted to the PCSCF 55b via the PGW 3b (step S265).

  As described above, the general communication system in this comparative example regulates voice transmission for a certain percentage of mobile terminal devices regardless of whether or not a voice call is in progress, as in the above comparative example. Yes. For this reason, in the communication system, when the SIP signal transmitted from the mobile terminal device already carrying out the voice call when the access restriction is applied and transmitting the control signal bearer is discarded, the call cannot be disconnected. As a result, even if the user of the mobile terminal device intends to end the call, there is a problem that the voice call is actually continued and charging is continued.

On the other hand, the bearer relay device according to the present embodiment determines whether or not the mobile terminal device is in a voice call, and does not discard the SIP signal from the mobile terminal device determined to be in a voice call. As a result, the mobile terminal device during the voice call is not restricted from the voice call, and the above-described problem of a general communication system does not occur.
FIG. 7 is a sequence diagram illustrating a communication method of the communication system 1 according to the present embodiment. 7, UEs 9a1, 9a2, 9a3, SGW3c, and PGW3b provided in the communication system 1 according to the present embodiment (in FIG. 7, SGW3c and PGW3b are collectively represented as “S / PGW3c, 3b”). Only the MME 3d, PCSCF 55b, and OPS 50 are shown.

  Since the operation | movement from step S201 to S208 shown in FIG. 7 is the same as the operation | movement from step S251 to S258 shown in FIG. 6, description is abbreviate | omitted. As shown in FIG. 7, the MME 3d uses the access restriction signal for restricting voice transmission from the mobile terminal device as the restriction target information (in this embodiment, the area determined to be congested becomes the restriction target area. In the example, it is transferred to the SGW 3c together with a signal indicating the area E1) (step S209). The SGW 3c that has received the access restriction signal has a control signal bearer established with the PGW in the restriction target area (area E1 in this example) included in the signal transmitted together with the access restriction signal. A voice call determination process for determining whether or not a voice call is in progress, and a predetermined ratio (for example, 50% in this example) of mobile terminal devices determined as not being in a voice call An access restriction process including a signal discard process for discarding the SIP signal is executed (step S210).

  In step S210, a process similar to the access restriction process in the first embodiment is executed (see FIG. 5). In this example, since the voice communication bearer 2b1 is established and the UE 9a1 is in a voice call (Yes in step S102 in FIG. 5), the signal discarding unit 8 provided in the SGW 3c is changed from the UE 9a1 in the voice call. The SIP signal to be transmitted is not discarded (step S103 in FIG. 5). Thus, the SIP signal transmitted from the UE 9a1 and transmitted through the control signal bearer 2a1 is transmitted to the PCSCF 55b via the PGW 3b (step S211 in FIG. 7). reference). In addition, the SGW 3c performs access restriction processing on the UEs 9a2 and 9a3 that have established the control signal bearers 2a2 and 2a3 with the PGW 5b in the area E1, and for example, the signal discarding unit 8 performs, for example, the SIP from the UE 9a2. It is determined to discard the signal (see step S212 in FIG. 7), and it is determined not to discard the SIP signal from the UE 9a3 (step S213 in FIG. 7). Thereby, as shown in FIG. 7, the SIP signal transmitted from the UE 9a2 and transmitted through the control signal bearer 2b2 is discarded in the SGW 3c. On the other hand, the SIP signal transmitted from the UE 9a3 and transmitted through the control signal bearer 2a3 is transmitted to the PCSCF 55b via the PGW 3b.

  As described above, according to the communication method of the communication system 1 according to the present embodiment, mobile terminal devices that are in a voice call can be excluded from targets for discarding SIP signals. It can be prevented that the SIP signal passing through the bearer is discarded and the call cannot be disconnected. Thus, according to the present embodiment, even if the user of the mobile terminal device intends to end the call, the problem that the billing is continued is solved, the network congestion is reduced, and the movement during the voice call is reduced. It is possible to prevent service degradation of the user of the terminal device, that is, to normally disconnect communication. Further, according to the present embodiment, it is possible to realize an IMS transmission restriction method that can discard an SIP signal by a device closer to a mobile terminal device, and to reduce network traffic.

(Modification)
Next, a bearer relay device, a communication method thereof, and a communication system according to a modification of the present embodiment will be described with reference to FIG. The bearer relay device, its communication method, and communication system according to the present modification are packets without determining whether or not a voice call is in progress for a mobile terminal device with an access restriction function having an access restriction function for restricting voice transmission. It is characterized in that the signal is not discarded. For example, when an access restriction signal is received from an OPS, the mobile terminal device with an access restriction function can voluntarily restrict voice transmission (access restriction). For this reason, the bearer relay device according to the present modification converts a plurality of mobile terminal devices connected to itself (the bearer relay device) into mobile terminal devices with an access restriction function and mobile terminal devices that do not have an access restriction function. Only the mobile terminal devices that do not have the function are selected and the same voice call determination process and signal discarding process as those described with reference to FIG. 4, FIG. 5 or FIG. 7 are executed. That is, the bearer relay device (for example, SGW3c) according to the present modification is the same as that shown in FIGS. 1, 2, 4, and 4 except that the determination unit 6 determines whether or not the mobile terminal device has an access restriction function. 5 or the configuration similar to that of the SGW 3c described with reference to FIG. 7, and the same function is exhibited. Hereinafter, taking the SGW 3c as an example of the bearer relay device, only the feature points of this modification will be described briefly.

  FIG. 8 is a flowchart showing the flow of access restriction processing in this modification. The process of step S301 in the access restriction process in this modification is the same process as step S101 of the access restriction process shown in FIG. 5, the process of step S303 is the same process as step S102, and the process of step S304. The process is the same as step S103, the process of step S305 is the same process as step S104, and the process of step S306 is the same process as step S105.

  As shown in FIG. 8, in the access restriction process in the present modification, the mobile terminal device in which the PGW 3b and the control signal bearer are established in the restricted area (area E1 in this example) is accessed after step S301. It is determined whether or not a restriction function is provided (step S302). For example, the determination unit 6 provided in the SGW 3c receives information on whether or not the mobile terminal device (for example, UE9a1, UE9a2, UE9a3) is a mobile terminal device with an access restriction function having an access restriction function from the HSS 11 via the MME 3d. If it is determined that the function is provided, the process proceeds to step S306 without executing steps S303 to S305. If it is determined that the function is not provided, the process proceeds to step S303. For this reason, the determination unit 6 does not determine whether the mobile terminal device with access restriction function is in a voice call. Further, in this modification, since the processing of steps S304 and S305 is not executed when the determination unit 6 determines that the mobile terminal device has an access restriction function, the signal processing unit 8 transmits a packet signal transmitted from the mobile terminal device with an access restriction function. Is not to be discarded.

  In this way, the SGW 3c in the present modification sorts a plurality of mobile terminal devices connected to the mobile terminal device with an access restriction function into a mobile terminal device with an access restriction function and an access restriction function. The mobile terminal device is determined as a mobile terminal device that is not subject to access restriction, and the mobile terminal device that does not have the function is determined as a restricted mobile terminal device subject to access restriction. As a result, the SGW 3c according to the present modification has a mobile terminal device that does not have the function when the mobile terminal device with an access restriction function and a mobile terminal device that does not have the access restriction function are connected together. As compared with the mobile terminal device, it is possible to prevent the mobile terminal device with an access restriction function from being excessively restricted. That is, in this modification, the mobile terminal device with an access restriction function is not subject to access restriction from the SGW 3c, but is subject to access restriction only from the OPS. As a result, the access restriction received by the mobile terminal device with an access restriction function and the mobile terminal device not provided with the access restriction function is one type, and the fairness of both terminal devices with respect to the access restriction is ensured.

In this modification, when the reference of the predetermined ratio of the restriction of the mobile terminal device is set to the total number of mobile terminal devices subject to restriction, the step after determining in step S303 that the mobile terminal device is in a voice call In S306, a process of subtracting the total number of mobile terminal devices that execute the access restriction process is required. On the other hand, the reference of the predetermined ratio is set to the total number of mobile terminal devices determined whether or not a voice call is in progress or the total number of mobile terminal devices that have established a control signal bearer in the restricted area. In this case, the process of subtracting the total number of mobile terminal devices that execute the access restriction process is unnecessary in step S306 after it is determined in step S303 that the mobile terminal device is in a voice call. Note that mobile terminal devices that are determined whether or not a voice call is in progress do not include mobile terminal devices with access restriction functions, and mobile terminal devices that have established a control signal bearer in the restricted area. Mobile terminal devices with access restriction functions are included.
As described above, the SGW 3c is described as an example of the bearer relay device. However, the PGW and the eNB include the access restriction signal reception unit 4, the determination unit 6, and the signal discard unit 8, and thus FIG. 1, FIG. 2, FIG. The functions similar to those described with reference to FIGS. 7 and 8 can be exhibited.

[Second Embodiment]
(Schematic configuration of communication system 1 and EPC network device 3)
A bearer relay device, a bearer relay device communication method, a bearer relay device communication program, and a communication system according to a second embodiment of the present invention will be described with reference to FIGS. 9 to 13. The bearer relay device, the bearer relay device communication method, the bearer relay device communication program, and the communication system according to the present embodiment are characterized in that the voice transmission of the mobile terminal device is restricted not in area units but in PCSCF units. doing. First, a schematic configuration of a bearer relay device according to the present embodiment and a communication system including the same will be described with reference to FIG. In this embodiment, an SGW will be described as an example of a bearer relay device. In this embodiment, a mobile communication system that transmits and receives data between a mobile terminal device and an IP network will be described as an example.

FIG. 9 shows a schematic configuration of the communication system 100 according to the present embodiment. In FIG. 9, the interface of EPC-related control signals between nodes is represented by a broken line, and the interface for transferring user data (for example, SIP signal) between nodes is represented by a solid line.
As shown in FIG. 9, a communication system 100 according to this embodiment includes IMSs 5, 15, and 25 that provide IP-based multimedia communication services such as VoIP, and an EPC network device 3 that is a core network that transmits IP packets. Mobile terminal equipment (UE) 9, 19, and 29, which are mobile terminal equipment, and UE 9, 19, and 29 perform LTE wireless communication and connect UE 9, 19, and 29 to the EPC network device 3, respectively. It has radio base stations (eNBs) 7, 17, and 27 and a subscriber management server (HSS) 11 that holds user information related to the UEs 9, 19, and 29. The EPC network device 3, IMS 5, 15, 25, eNB 7, 17, 27 and HSS 11 constitute an IP network. In this embodiment, for convenience of explanation, one mobile terminal device is connected to each of the eNBs 7, 17, and 27, but a plurality of mobile terminal devices may of course be connected. In the present embodiment, three IMSs and eNBs are connected to the EPC core network device 3 for convenience of explanation, but may be connected to 1, 2 or 4 or more.

  The communication system 1 is monitored by an operation system (OPS) 10. When the maintenance person monitors the traffic of the communication system 1 and the load state of the node and determines that the IP network of the communication system 1 is in a congested state, the maintenance person executes a restriction operation (command registration) on the OPS 10. As a result, the OPS 10 sends an access restriction signal for restricting voice transmission from the mobile terminal device to the MME 3d (details will be described later).

The HSS 11 is a subscriber information database that holds user information related to the UEs 9, 19, and 29, and manages authentication information and location information.
The IMS 5 is provided with an SCSCF 5a, a PCSCF 5b, and an application server (not shown). The SCSCF 5a and the PCSCF 5b may be realized as physically separate devices, or may be realized as a function of the IMS 5, respectively. The SCSCF 5 a of IMS 5 and the application server are connected to the HSS 11.

The SCSCF 5a is a SIP server having a function of acquiring and holding user information of the UE 9 from the HSS 11 holding user information and performing session control and the like. The SCSCF 5a manages the connection between the private user ID of the logged-in UE 9 and the public user ID.
The PCSCF 5b is connected to the SCSCF 5a, and can send and receive SIP signals to and from the SCSCF 5a. The PCSCF 5b is assigned to the UE 9 when the UE 9 is registered. The PCSCF 5b has a function of transmitting / receiving IP packets to / from the authenticated UE 9 after compressing the UE 9 and compressing data in order to efficiently transfer the SIP message.

  The IMS 15 is provided with an SCSCF 15a, a PCSCF 15b, and an application server (not shown). The SCSCF 15a and the PCSCF 15b may be realized as physically separate devices, or may be realized as a function of the IMS 15, respectively. The SCSCF 15 a of the IMS 15 and the application server are connected to the HSS 11.

The IMS 25 is provided with an SCSCF 25a, a PCSCF 25b, and an application server (not shown). The SCSCF 25a and the PCSCF 25b may be respectively realized as physical devices or may be realized as a function of the IMS 25. The SCSCF 25 a of IMS 25 and the application server are connected to the HSS 11.
The SCSCFs 15a and 25a have the same configuration as that of the SCSCF 5a except that the predetermined processes related to the UEs 19 and 29 are executed, and the PCSCFs 15b and 25b execute the predetermined processes related to the UEs 19 and 29. Except for this point, it has the same configuration as that of the PCSCF 5b and exhibits the same function, and thus detailed description thereof is omitted.

The EPC network apparatus 3 is connected to the IMS 5, 15, 25 and the eNBs 7, 17, 27, respectively. The EPC network device 3 connects IMS 5 and eNB 7, connects IMS 15 and eNB 17, and connects IMS 25 and eNB 27. The EPC network device 3 is provided with a PCRF 3a, a PGW 3b, an SGW 3c, and an MME 3d. The PCRF 3a, PGW 3b, SGW 3c, and MME 3d may be respectively realized as physically separate devices, or may be realized as one function exhibited by the EPC network device 3.
The PCRF 3a is connected to each of the PCSCFs 5b, 15b, and 25b provided in the IMS 5, and can transmit / receive a predetermined control signal to / from these nodes. The PCRF 3a determines an IP packet transmission policy such as a QoS and a charging method for performing transmission quality control in the PGW 3b and the SGW 3c.

The PGW 3b is connected to the PCRF 3a and the SGW 3c, and can transmit / receive a predetermined control signal to / from these nodes. The PGW 3b is a connection point with the PDN such as the IMS 5, 15, 25, and is a gateway device that assigns an IP address and receives all user data packets from the PDN to the UEs 9, 19, 29.
The MME 3d is connected to the HSS 11. The MME 3d includes the mobility management of the UE 9, 19, 29, the authentication (security control) of the UE 9, 19, 29 based on the authentication information notified from the HSS 11, and the transfer path of the user data between the SGW 3c and the eNB 7, 17, 27. The control signal bearers 2a, 12a, and 22a are set.

  The SGW 3c is connected to the MME 3d and is a gateway device that performs transmission control of user data packets based on a command from the MME 3d. SGW3c relays the user data packet transferred from PGW3b or eNB7 to eNB7 or PGW3b, relays the user data packet transferred from PGW3b or eNB17 to eNB17 or PGW3b, and transmits the user data packet transferred from PGW3b or eNB27. It relays to eNB27 or PGW3b. When the SGW 3c receives an access restriction signal sent from the OPS 10 and restricts voice transmission from the UEs 9, 19, and 29 via the MME 3d, the SGW 3c is based on whether or not the UEs 9, 19, and 29 are in a voice call. , The packet signals transmitted from the UEs 9, 19, and 29 are discarded.

  In FIG. 9, UE 9 is in a voice call with an unillustrated called-side mobile terminal device, and UE 19 and UE 29 are in a state where a session is established with the IP network of communication system 1 but is not in a voice call. A communication system 1 is illustrated. For this reason, the control signal bearer 2a and the voice signal bearer 2b are established between the PGW 3b and the UE 9 via the SGW 3c. In contrast, a control signal bearer 12a is established between the PGW 3b and the UE 19 via the SGW 3c, and a control signal bearer 22a is established between the PGW 3b and the UE 29 via the SGW 3c. No voice signal bearer is established between the UE 19 and the UE 19 and between the PGW 3 b and the UE 29.

  The control signal bearers 2a, 12a, and 22a are packet transmission paths through which SIP signals are transmitted and received. The control signal bearers 2a, 12a, and 22a are respectively held from when the UEs 9, 19, and 29 are attached to the IP network until they are detached. The PCSCFs 5b, 15b, and 25b are IP-connected to the PGW 3b. As a result, the SIP signals transmitted from the UEs 9, 19, and 29 and transmitted through the control signal bearers 2a, 12a, and 22a are transmitted from the PGW 3b to the PCSCFs 5b, 15b, and 25b. The SIP signals transmitted from the PCSCFs 5b, 15b, and 25b are transmitted to the PGW 3b, and transmitted to the UEs 9, 19, and 29 through the control signal bearers 2a, 12a, and 22a. The audio signal bearer 2b is a packet transmission path through which IP packetized audio data is transmitted and received. The voice signal bearer 2b is established every time a voice signal is transmitted and received. The voice signal bearer 2b is held until a voice call is started and ended between the UE 9 and a receiving-side mobile terminal device (not shown) via, for example, an IP network (not shown). The audio signal is transmitted from the PGW 3b to the mobile terminal device on the receiving side via, for example, the IP network.

(Schematic configuration of SGW3c as a bearer relay device)
The schematic configuration related to the regulation of voice transmission of the SGW 3c as the bearer relay device in the present embodiment has the same configuration as the SGW 3c (see FIG. 2) in the first embodiment and exhibits the same function. It has become. That is, the SGW 3c as the bearer relay device according to the present embodiment includes an access restriction signal reception unit, a determination unit, and a signal discard unit. The access restriction signal reception unit, the determination unit, and the signal discard unit have the same configuration as the access restriction signal reception unit 4, the determination unit 6, and the signal discard unit 8 illustrated in FIG. Therefore, detailed description is omitted. Hereinafter, for convenience of explanation, the access restriction signal reception unit, the determination unit, and the signal discard unit provided in the SGW 3c according to the present embodiment are the same as those provided in the SGW 3c according to the first embodiment. The same reference numerals are used and referred to as “access restriction signal receiving unit 4, determination unit 6 and signal discarding unit 8”. In addition, SGW3c in the said 1st Embodiment regulates the voice transmission of UE with which the bearer for control signals has been established between PGW3b in the area of regulation among the LTE area E. ing. On the other hand, the SGW 3c in the present embodiment regulates the voice transmission of the UE for which the control signal bearer has been established with the PGW connected to the PCSCF constituting the IP network of the communication network 100. ing.

(Communication Method of Communication System 1 (Example 2-1))
Next, a communication method of the communication system 100 according to Example 2-1 of the present embodiment will be described with reference to FIGS. 10 and 11 with reference to FIGS. First, before describing the communication method of the communication system 100 according to the present embodiment, a communication method of a general communication system as a comparative example with respect to the present embodiment will be described with reference to FIG. FIG. 10 is a sequence diagram illustrating a communication method of a general communication system. The communication system has substantially the same configuration as the communication system 100 according to the present embodiment except for the SGW. In FIG. 10, UEs 9, 19, 29, SGW 53c and PGW 3b provided in the communication system (in FIG. 10, SGW 53c and PGW 3b are collectively represented as “S / PGW 53c, 3b”), MME 3d, PCSCF 5b, Only 15b and 25b and the OPS 10 monitoring the communication system are shown. UE9, 19, 29, PGW3b, MME3d, PCSCF5c, 15b, 25b have the same configuration and the same functions as UE9, 19, 29, PGW3b, MME3d, PCSCF5c, 15b, 25b provided in the communication system 100 Has come to demonstrate. Further, the OPS 10 that monitors the communication system has the same configuration as the OPS 10 that monitors the communication system 100 and performs the same function. The SGW 53c has the same configuration as the SGW 3c provided in the communication system 100 except that the determination unit 6 and the signal discarding unit 8 are not provided and does not exhibit these functions, and performs the same functions. It is supposed to be.

  As shown in FIG. 10, the control signal bearer 2a is established by establishing an IP session between the UE 9 and the PGW 3b when the UE 9 is powered on or the like (step S451). Next, when the UE 9 performs VoLTE transmission, for example, the transmission signal is transferred via the control signal bearer 2a to the PCSCF 5b that performs call control via the PGW 3b. The PCSCF 5b proceeds with call processing with the terminating IP network (not shown), and requests the PCRF 3a (see FIG. 9) to secure the voice communication bearer 2b of the UE 9. The PCRF 3a instructs the bearer resource for the audio signal to the PGW 3b and the SGW 53c from the audio information received from the PCSCF 5b. When the PGW 3b and the SGW 53c set the voice signal bearer, the voice signal bearer 2b that ensures the voice quality is established between the UE 9 and the PGW 3b (step S452).

  Further, an IP session is established between the UE 19 and the PGW 3b when the UE 19 is turned on, and the control signal bearer 12a is established (step S453). Further, an IP session is established between the UE 29 and the PGW 3b when the UE 29 is turned on, and the control signal bearer 22a is established (step S454). In this example, since UE19 and UE29 are not performing VoLTE transmission, for example, the voice signal bearer is not established between UE19, 29 and PGW3b.

  Thereafter, when the maintenance person monitoring the communication system determines that the IP network of the communication system is congested due to, for example, the occurrence of a disaster or the holding of a predetermined event, a restriction operation (command registration) is performed on the OPS 10. Run. As a result, the OPS 10 sends an access restriction signal for restricting voice transmission from the mobile terminal device to the MME 3d together with the address of the PCSCF 5b to notify the access restriction (step S455). The MME 3d transfers the address of the PCSCF 5b together with the received access restriction signal to the SGW 53c (Step S456). When the maintenance person performs the same operation on the OPS 10, the OPS 10 sends an access restriction signal for restricting voice transmission from the mobile terminal device to the MME 3d together with the address of the PCSCF 15b to notify the access restriction (step). S457). The MME 3d transfers the address of the PCSCF 15b together with the received access restriction signal to the SGW 53c (Step S458). Further, when the maintenance person performs the same operation on the OPS 10, the OPS 10 sends an access restriction signal for restricting voice transmission from the mobile terminal device to the MME 3d together with the address of the PCSCF 25b to notify the access restriction (step). S459). The MME 3d transfers the address of the PCSCF 25b together with the received access restriction signal to the SGW 53c (Step S460).

  The SGW 53c that has received the access restriction signal has a predetermined ratio (for example, 50% in this example) of the mobile terminal devices for which the control signal bearer has been established with the PCSCF of the address transmitted together with the access restriction signal. An access restriction process for discarding the SIP signal from the mobile terminal device is executed. The SGW 53c executes access restriction processing for the UE 9 for which the control signal bearer 2a has been established with the PCSCF 5b, and the number of SIP signals discarded at this time is 0 out of 3, and the signal discard rate is 0%. Therefore, it is determined that it has not reached 50% (step S461), and the SIP signal from the UE 9 is discarded (step S462). Further, the SGW 53c executes access restriction processing for the UE 19 for which the control signal bearer 12a is established with the PCSCF 15b. At this time, one of the three SIP signals is discarded, and the signal discard ratio is 33. %, And it is determined that it has not reached 50% (step S463), and the SIP signal from the UE 19 is discarded (step S464). In addition, the SGW 53c executes access restriction processing for the UE 29 for which the control signal bearer 22a is established with the PCSCF 25b. Currently, two of the three SIP signals are discarded, and the signal discard ratio is 66. It is determined that it has reached 50% (step S465), and the SIP signal from the UE 29 is not discarded. Thereby, the SIP signal transmitted from the UE 29 and transmitted via the control signal bearer 22a is transmitted to the PCSCF 25b via the PGW 3b (step S466).

As described above, a general communication system regulates voice transmission for a certain percentage of mobile terminal devices regardless of whether or not a voice call is in progress. For this reason, in the communication system, when the SIP signal transmitted from the mobile terminal device already carrying out the voice call when the access restriction is applied and transmitting the control signal bearer is discarded, the call cannot be disconnected. As a result, even if the user of the mobile terminal device intends to end the call, there is a problem that the voice call is actually continued and charging is continued.
In contrast, the bearer relay device according to the present embodiment determines whether or not the mobile terminal device is in a voice call, and does not discard the SIP signal from the mobile terminal device determined to be in a voice call. As a result, the mobile terminal device during the voice call is not restricted from the voice call, and the above-described problem of a general communication system does not occur.

  FIG. 11 is a sequence diagram illustrating a communication method of the communication system 100 according to the present embodiment. In FIG. 11, UEs 9, 19, 29, SGW 3c and PGW 3b provided in the communication system 100 (in FIG. 11, SGW 3c and PGW 3b are collectively represented as “S / PGW 3c, 3b”), MME 3d, PCSCF 5b, Only the OPs 10 for monitoring the communication system 1 are illustrated.

  The operations from step S401 to S410 shown in FIG. 11 are the same as the operations from step S451 to S460 shown in FIG. As shown in FIG. 11, the SGW 3c that has received the access restriction signal from the MME 3d receives a control signal from the PGW 3b that is transmitted together with the access restriction signal and connected to the PCSCF of the address included in the restriction target information. A voice call determination process for determining whether or not a voice call is in progress for each of the mobile terminal devices for which a mobile bearer has been established, and a predetermined ratio of mobile terminal devices determined not to be in a voice call (in this example, (For example, 50%), an access restriction process including a signal discard process for discarding the SIP signal from the mobile terminal device is executed (step S411).

  In step S411, a process similar to the access restriction process in the first embodiment is executed (see FIG. 5). In this example, since the UE 9 has established the voice communication bearer 2b and is in a voice call (Yes in step S102 in FIG. 5), the signal discarding unit 8 provided in the SGW 3c The SIP signal to be transmitted is not discarded (step S103 in FIG. 5). Accordingly, the SIP signal transmitted from the UE 9 and transmitted through the control signal bearer 2a is transmitted to the PCSCF 5b via the PGW 3b (step S412 in FIG. 11). reference). Further, the SGW 3c executes access restriction processing for the UEs 19 and 29 in which the control signal bearers 12a and 22a are established with the PCSCFs 15b and 25b. For example, the signal discarding unit 8 discards SIP signals from the regulated mobile terminal devices at a predetermined ratio (for example, 50% in this example) with respect to the total number of regulated mobile terminal devices determined not to be in a voice call. For example, the signal discarding unit 8 decides to discard the SIP signal from the UE 19 among the UEs 19 and 29 determined to be the restriction target mobile terminal devices (see step S104 in FIG. 5), and does not discard the SIP signal from the UE 29. Determine (see step S104 in FIG. 5). Thereby, as shown in FIG. 11, the SIP signal transmitted from the UE 19 and transmitted through the control signal bearer 12a is discarded in the SGW 3c. On the other hand, the SIP signal transmitted from the UE 29 and transmitted through the control signal bearer 22a is transmitted to the PCSCF 25b via the PGW 3b.

In the access restriction process executed after a predetermined time, for example, when the UE 9 has finished the voice call and the UE 29 has started the voice call, the UE 9 is connected to the restriction-target mobile terminal device subject to access restriction. It is determined (No in step S102), and the UE 29 is determined as a mobile terminal device that is not subject to access restriction (Yes in step S102).
In this embodiment, when the reference of the predetermined ratio of restriction of mobile terminal devices is set to the total number of mobile terminal devices subject to restriction, the step after determining in step S102 that the mobile terminal device is in a voice call In S105, a process of subtracting the total number of mobile terminal devices that execute the access restriction process is required. On the other hand, if the predetermined percentage criterion is set to the total number of mobile terminal devices determined whether or not a voice call is in progress, it is determined in step S102 that the mobile terminal device is in a voice call. In the subsequent step S105, the process of subtracting the total number of mobile terminal devices that execute the access restriction process becomes unnecessary.

  As described above, according to the bearer relay apparatus according to the present embodiment, the communication system including the same, and these communication methods, it is possible to exclude mobile terminal devices that are engaged in a voice call from the targets for discarding SIP signals. It can be prevented that the SIP signal passing through the control signal bearer of the mobile terminal device during a call is discarded and the call cannot be disconnected. Thereby, according to the present embodiment, even if the user of the mobile terminal device intends to end the call, the problem that the billing is continued is solved, and the congestion of the network (IP network) is reduced. The service degradation of the user of the mobile terminal device during a voice call can be prevented, that is, the communication can be disconnected normally. Further, according to the present embodiment, it is possible to realize an IMS transmission restriction method that can discard an SIP signal by an apparatus closer to a mobile terminal device, and to reduce network traffic.

(Communication Method of Communication System 1 (Example 2-2))
Next, a communication method of the communication system 100 according to Example 2-2 of the present embodiment will be described with reference to FIGS. 12 and 13 with reference to FIGS. The communication method of the communication system 100 according to the present embodiment is characterized in that, for example, the access restriction process is executed when the PCSCF determines that the IP network of the communication system 100 is in a congestion state. The communication system 100 according to the present embodiment has the same configuration as the communication system 100 shown in FIG. 9, but includes PCSCFs 55b, 65b, and 75b instead of the PCSCFs 5b, 15b, and 25b (FIG. 13). reference). Further, the communication system according to the present embodiment is monitored by the OPS 50 instead of the OPS 10 (see FIG. 13). The PCSCFs 55b, 65b, and 75b have the same configuration as the PCSCFs 5b, 15b, and 25b shown in FIG. 10 except that they detect congestion of the IP network of the communication system, and perform the same functions. Yes. The OPS 50 has the same configuration as the OPS 10 except that the restriction notification is executed to the MME 3d based on the reception of the congestion detection signal from the PCSCFs 55b, 65b, and 75b, and performs the same function. Yes.

  First, before describing the communication method of the communication system 100 according to the present embodiment, a communication method of a general communication system as a comparative example with respect to the present embodiment will be described with reference to FIG. FIG. 12 is a sequence diagram illustrating a communication method of a general communication system. The communication system has substantially the same configuration as the communication system 100 according to the present embodiment except for the SGW. In FIG. 12, UEs 9, 19, 29, SGW 53c and PGW 3b provided in the communication system (in FIG. 12, SGW 53c and PGW 3b are collectively represented as “S / PGW 53c, 3b”), MME 3d, PCSCF 55b, Only 65b and 75b and the OPS 50 for monitoring the communication system are shown. UE 9, 19, 29, S / PGW 53c, 3b and MME 3d in this comparative example have the same configuration as UE 9, 19, 29, S / PGW 53c, 3b and MME 3d shown in FIG. It is like that. Further, the PCSCFs 55b, 65b, 75b and the OPS 50 in this comparative example have the same configuration as the PCSCFs 55b, 65b, 75b and the OPS 50 in the present example, and exhibit the same functions.

The operations in steps S551 to S554 shown in FIG. 12 are the same as the operations in S451 to S454 shown in FIG.
After the control signal bearer 2a, 12a, 22a and the voice signal bearer 2b are established, the PCSCF 55b periodically performs a congestion determination of the network (IP network), for example (step S555), and detects the congestion of the network (step S555). In step S556), a congestion notification signal is transmitted to the OPS 50 (step S557). For example, the PCSCF 65b periodically performs network congestion determination (step S558), and when detecting network congestion (step S559), transmits a congestion notification signal to the OPS 50 (step S560). For example, the PCSCF 75b periodically performs network congestion determination (step S561), and when detecting network congestion (step S562), transmits a congestion notification signal to the OPS 50 (step S563). The PCSCFs 55b, 65b, and 75b, for example, determine that the network is congested when the usage rate of a control unit (for example, a CPU (Central Processing Unit)) provided in the PCSCFs 55b, 65b, and 75b exceeds a predetermined value.

  The OPS 50 that has received the congestion notification signal from the PCSCF 55b sends an access restriction signal for restricting voice transmission from the mobile terminal device to the MME 3d together with the address of the PCSCF 55b to notify the access restriction (step S564). The MME 3d transfers the address of the PCSCF 55b to the SGW 53c together with the received access restriction signal (step S565). Further, the OPS 50 that has received the congestion notification signal from the PCSCF 65b sends an access restriction signal for restricting voice transmission from the mobile terminal device to the MME 3d together with the address of the PCSCF 65b to notify the access restriction (step S566). The MME 3d transfers the address of the PCSCF 65b to the SGW 53c together with the received access restriction signal (step S267). Further, the OPS 50 that has received the congestion notification signal from the PCSCF 75b sends an access restriction signal for restricting voice transmission from the mobile terminal device to the MME 3d together with the address of the PCSCF 75b to notify the access restriction (step S568). The MME 3d transfers the address of the PCSCF 75b to the SGW 53c together with the received access restriction signal (step S569).

  The SGW 53c that has received the access restriction signal has a predetermined ratio (for example, 50% in this example) of the mobile terminal devices for which the control signal bearer has been established with the PCSCF of the address transmitted together with the access restriction signal. An access restriction process for discarding the SIP signal from the mobile terminal device is executed. The SGW 53c executes access restriction processing for the UE 9 for which the control signal bearer 2a is established with the PCSCF 55b, and at this time, 0 of the 3 SIP signals are discarded, and the signal discard rate is 0%. Therefore, it is determined that it has not reached 50% (step S570), and the SIP signal from the UE 9 is discarded (step S571). Further, the SGW 53c executes access restriction processing for the UE 19 for which the control signal bearer 12a is established with the PCSCF 65b. At this time, one of the three SIP signals is discarded, and the signal discard ratio is 33. %, And it is determined that it has not reached 50% (step S572), and the SIP signal from the UE 19 is discarded (step S573). As a result, the SIP signals transmitted from the UEs 9 and 19 and transmitted through the control signal bearers 2a and 12a are discarded in the SGW 53c and are not transmitted to the PCSCFs 5b and 15b. In addition, the SGW 53c executes access restriction processing for the UE 29 for which the control signal bearer 22a is established with the PCSCF 25b. Currently, two of the three SIP signals are discarded, and the signal discard ratio is 66. % And has reached 50% (step S574), and the SIP signal from the UE 29 is not discarded. Thus, the SIP signal transmitted from the UE 29 and transmitted through the control signal bearer 22a is transmitted to the PCSCF 25b via the PGW 3b (step S575).

As described above, the general communication system in this comparative example regulates voice transmission for a certain percentage of mobile terminal devices regardless of whether or not a voice call is in progress, as in the above comparative example. Yes. For this reason, in the communication system, when the SIP signal transmitted from the mobile terminal device already carrying out the voice call when the access restriction is applied and transmitting the control signal bearer is discarded, the call cannot be disconnected. As a result, even if the user of the mobile terminal device intends to end the call, there is a problem that the voice call is actually continued and charging is continued.
On the other hand, the bearer relay device according to the present embodiment determines whether or not the mobile terminal device is in a voice call, and does not discard the SIP signal from the mobile terminal device determined to be in a voice call. As a result, the mobile terminal device during the voice call is not restricted from the voice call, and the above-described problem of a general communication system does not occur.

  FIG. 13 is a sequence diagram illustrating a communication method of the communication system 100 according to the present embodiment. In FIG. 13, UE9, 19, 29, SGW3c and PGW3b provided in the communication system 100 according to the present embodiment (in FIG. 13, SGW3c and PGW3b are collectively represented as “S / PGW3c, 3b”), Only the MME 3d, the PCSCFs 55b, 65b, 75b, and the OPS 50 are shown.

  The operations from Steps S501 to S519 shown in FIG. 13 are the same as the operations from Steps S551 to S569 shown in FIG. As illustrated in FIG. 13, the SGW 3 c that has received the access restriction signal establishes a control signal bearer with the PCSCF of the address that is transmitted as a signal including restriction target information together with the access restriction signal. A voice call determination process for determining whether or not a voice call is being made for each of the devices, and a predetermined percentage (for example, 50% in this example) of the mobile terminal devices that are determined not to be in a voice call An access restriction process including a signal discard process for discarding the SIP signal from is executed (step S520).

  In step S520, the same process as the access restriction process in Example 1-1 is executed (see FIG. 5). In this example, since the UE 9 has established the voice communication bearer 2b and is in a voice call (Yes in step S102 in FIG. 5), the signal discarding unit 8 provided in the SGW 3c The SIP signal to be transmitted is not discarded (step S103 in FIG. 5). Thus, the SIP signal transmitted from the UE 9 and transmitted through the control signal bearer 2a is transmitted to the PCSCF 5b via the PGW 3b (step S521 in FIG. 13). reference). Further, the SGW 3c executes access restriction processing for the UEs 19 and 29 for which the control signal bearers 12a and 22a are established with the PCSCFs 15b and 25b. For example, the signal discarding unit 8 receives, for example, the SIP signal from the UE 19 Is determined to be discarded (see step S522 in FIG. 13), and it is determined not to discard the SIP signal from the UE 29 (step S523 in FIG. 13). Thereby, as shown in FIG. 13, the SIP signal transmitted from the UE 19 and transmitted through the control signal bearer 12a is discarded in the SGW 3c. On the other hand, the SIP signal transmitted from the UE 29 and transmitted through the control signal bearer 22a is transmitted to the PCSCF 75b via the PGW 3b.

  As described above, according to the communication method of the communication system 100 according to the present embodiment, mobile terminal devices that are in a voice call can be excluded from targets for discarding SIP signals. It can be prevented that the SIP signal passing through the bearer is discarded and the call cannot be disconnected. Thus, according to the present embodiment, even if the user of the mobile terminal device intends to end the call, the problem that the billing is continued is solved, the network congestion is reduced, and the movement during the voice call is reduced. It is possible to prevent service degradation of the user of the terminal device, that is, to normally disconnect communication. Further, according to the present embodiment, it is possible to realize an IMS transmission restriction method that can discard an SIP signal by a device closer to a mobile terminal device, and to reduce network traffic.

(Modification)
Next, a bearer relay device, a communication method thereof, and a communication system according to a modification of the present embodiment will be briefly described. The bearer relay device, its communication method, and communication system according to the present modification are packets without determining whether or not a voice call is in progress for a mobile terminal device with an access restriction function having an access restriction function for restricting voice transmission. It is characterized in that the signal is not discarded. That is, the SGW 3c as the bearer relay apparatus according to the present modification accesses a plurality of mobile terminal devices by executing the same process as the access restriction process (see FIG. 8) in the modification of the first embodiment. The mobile terminal device with the restriction function is selected from the mobile terminal device without the access restriction function, and the mobile terminal device with the access restriction function is determined as the mobile terminal device that is not subject to the access restriction, and has the function. A mobile terminal device that does not exist can be determined as a mobile terminal device subject to access restriction. As a result, the SGW 3c according to the present modification has a mobile terminal device that does not have the function when the mobile terminal device with an access restriction function and a mobile terminal device that does not have the access restriction function are connected together. As compared with the mobile terminal device, it is possible to prevent the mobile terminal device with access restriction function from being excessively restricted. That is, in this modification, the mobile terminal device with an access restriction function is not subject to access restriction from the SGW 3c, and is subject to access restriction only from the OPS 10. As a result, the access restriction received by the mobile terminal device with an access restriction function and the mobile terminal device not provided with the access restriction function is one type, and the fairness of both terminal devices with respect to the access restriction is ensured.

In this modification, when the reference of the predetermined ratio of the restriction on the mobile terminal device is set to the total number of restriction target mobile terminal devices, it is determined in step S303 (see FIG. 8) that the mobile terminal device is in a voice call. After that, in step S306 (see FIG. 8), a process of subtracting the total number of mobile terminal devices that execute the access restriction process is required. On the other hand, the control signal between the total number of mobile terminal devices determined as to whether or not the predetermined ratio reference is in a voice call or the PGW connected to the PCSCF of the address transmitted as the information to be regulated If it is set to the total number of mobile terminal devices for which a bearer is established, the mobile terminal that executes access restriction processing in step S306 after it is determined in step S303 that the mobile terminal device is in a voice call The process of subtracting the total number of devices is not necessary. Note that the former mobile terminal device does not include a mobile terminal device with an access restriction function, and the latter mobile terminal device includes a mobile terminal device with an access restriction function.
As described above, the SGW 3c is described as an example of the bearer relay device. However, the PGW and the eNB have been described with reference to FIGS. 9 to 13 by including the access restriction signal reception unit 4, the determination unit 6, and the signal discard unit 8. The same function can be demonstrated.

  The present invention can be embodied as a computer program. For example, the function of each part of an EPC network apparatus (especially PGW or SGW) or eNB can also be realized as a communication program for the bearer relay apparatus. Thus, some or all of the present invention can be incorporated into hardware or software (including firmware, resident software, microcode, state machines, gate arrays, etc.). Furthermore, the present invention may take the form of a computer program product on a computer-usable or computer-readable storage medium, which incorporates computer-usable or computer-readable program code. It is done. In the context of this specification, a computer usable or computer readable medium includes, stores, communicates, propagates, programs that are used by or in conjunction with an instruction execution system, apparatus or device, Alternatively, any medium that can be transported can be used.

The present invention is not limited to the above embodiment, and various modifications can be made.
In the first and second embodiments, the communication control parameter used for determining whether or not a voice call is in progress is QCI, but the present invention is not limited to this. For example, when the bearer for voice signal is established, the bearer relay device includes a voice signal flag that is set to an on state, for example, and determines whether the voice call is in progress by determining the state of the voice signal flag. It may be judged.

In the first and second embodiments, the number of mobile terminal devices on which the bearer relay apparatus executes access restriction processing is three, but the present invention is not limited to this. As long as the mobile terminal device is connected to the bearer relay device, the number of mobile terminal devices on which the bearer relay device executes access restriction processing may be other than three.
The communication system may be configured such that an administrator of the operation system transmits an access restriction signal to the bearer relay device manually.

  The scope of the present invention is not limited to the illustrated and described exemplary embodiments, but includes all embodiments that provide the same effects as those intended by the present invention. Furthermore, the scope of the invention is not limited to the combinations of features of the invention defined by the claims, but can be defined by any desired combination of particular features among all the disclosed features.

DESCRIPTION OF SYMBOLS 1,100 Communication system 2a, 12a, 22a, 2a1, 2a2, 2a3, 12a1, 12an, 22a1, 22an Control signal bearer 2b, 2b1 Voice signal bearer 3 EPC network device 3a PCRF
3b PGW
3c SGW
3d MME
4 Access restriction signal receiver 5, 15, 25 IMS
5a, 15a, 25a SCSCF
5b, 15b, 25b, 55b, 65b, 75b PCSCF
6 determination unit 7, 17, 27 eNB
8 Signal discard unit 9, 19, 29, 9a1, 9a2, 9a3, 19a1, 19an, 29a1, 29an UE
10, 50 OPS
11 HSS

Claims (8)

A bearer relay device that relays transmission / reception of IP packets between an IP network and a mobile terminal device,
An access restriction signal receiving unit that receives an access restriction signal that restricts voice transmission from the mobile terminal device from an access restriction control device;
When the access restriction signal receiving unit receives the access restriction signal, a determination unit that determines whether a mobile terminal device with a bearer established is in a voice call with reference to a communication control parameter of an IP packet;
The mobile terminal device determined by the determination unit not to be in the voice call is not subject to discarding the packet signal transmitted from the mobile terminal device determined to be in the voice call by the determination unit. A bearer relay device comprising: a signal discard unit configured to discard a packet signal transmitted from the restriction target mobile terminal device. The bearer relay apparatus according to claim 1, wherein the communication control parameter is a QoS class identifier. The signal discarding unit is transmitted from the restriction target mobile terminal device corresponding to a predetermined ratio with respect to the total number of the mobile terminal devices or the total number of restriction target mobile terminal devices that have determined whether or not a voice call is in progress. The bearer relay device according to claim 1, wherein the packet signal is discarded. The bearer relay apparatus according to any one of claims 1 to 3, wherein the signal discard unit does not discard a packet signal transmitted from a mobile terminal device with an access restriction function having an access restriction function. . The bearer relay device according to claim 4, wherein the determination unit does not determine whether or not the mobile terminal device with access restriction function is in a voice call. A communication system comprising a network including a gateway device and a radio base station that connects the network and a mobile terminal device,
Either one of the said gateway apparatus and the said wireless base station is a bearer relay apparatus as described in any one of Claim 1-5. The communication system characterized by these. A bearer relay device communication method for relaying transmission / reception of an IP packet between an IP network and a mobile terminal device,
Receiving an access restriction signal for restricting voice transmission from the mobile terminal device from the access restriction control device;
When the access restriction signal is received, it is determined by referring to the communication control parameter of the IP packet whether or not the mobile terminal device with which the bearer is established is in a voice call,
Restricted mobile terminal device subject to access restriction for the mobile terminal device determined not to be in the voice call without discarding the packet signal transmitted from the mobile terminal device determined to be in the voice call And discarding the packet signal transmitted from the restricted mobile terminal device. A communication program for a bearer relay device that relays transmission / reception of an IP packet between an IP network and a mobile terminal device,
Computer
An access restriction signal receiving unit for receiving an access restriction signal for restricting voice transmission from the mobile terminal device from an access restriction control device;
When the access restriction signal receiving unit receives the access restriction signal, a determination unit that determines whether or not a mobile terminal device with a bearer established is in a voice call with reference to a communication control parameter of an IP packet; and ,
The mobile terminal device determined by the determination unit not to be in the voice call is not subject to discarding the packet signal transmitted from the mobile terminal device determined to be in the voice call by the determination unit. A communication program for a bearer relay device, wherein the communication program functions as a signal discard unit that discards a packet signal transmitted from the restriction-target mobile terminal device.

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