JP2010154463A - Mobile communication system, server device, gateway device and communication control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a mobile communication system in which communication delay variation during handover is suppressed. <P>SOLUTION: A mobile communication system includes: a plurality of gateway devices; and a management server. In the gateway device, when any one of the plurality of gateway devices is connected with a mobile node via a network, the gateway device relays data transmitted and received to a communicating partner by the mobile node and sends out delay information that is information indicating a communication delay time of a communication path through which the data are transmitted. The management server collects delay information received from the plurality of gateway devices via the network and controls the communication delay time based on the collected delay information so as to reduce a difference in the communication delay times of the communication path, between the mobile node and the communicating partner, being different in accordance with the gateway device to which the mobile node is connected. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a mobile communication system, a server apparatus, a gateway apparatus, and a communication control method for executing a handover for continuing communication performed by a mobile node with another communication node via a network before and after the movement of the mobile node.

  PMIPv6 (ProxyMobile IPv6) described in Non-Patent Document 1 is known as a method for realizing mobile communication by registering a mobile node address and a location registration gateway address in a communication network. Yes.

  PMIPv6 will be briefly described. FIG. 31 is a diagram for explaining the configuration of a mobile communication system based on PMIPv6.

  The mobile communication system based on PMIPv6 includes a mobility management server 100, location registration gateways 200a and 200b, and a mobile node 300, as shown in FIG. Here, the location registration gateway 200a and the location registration gateway 200b have the same configuration. When attention is paid to the function as the location registration gateway, the location registration gateway 200a is described as the location registration gateway 200 because there is no difference between the two. On the other hand, when it is necessary to distinguish the two, they are described as location registration gateway 200a and location registration gateway 200b, respectively. The same applies to the access networks 600a and 600b.

  The communication node 400 shown in FIG. 31 is not an essential component as a mobile communication system for explaining PMIPv6, but is described as a node that communicates with the mobile node 300. The mobility management server 100 and the location registration gateway 200 are connected via a network 500. On the other hand, the mobile node 300 is connected to the location registration gateway 200 via the access network 600.

  The mobility management server 100 is referred to as “Local Mobility Anchor (LMA)” in Non-Patent Document 1. The mobility management server 100 sends a Home Network Prefix (HNP) corresponding to the network prefix part of the address (HomeAddress (HoA)) used for communication, which is notified from the location registration gateway 200, and the address of the location registration gateway. (Hereinafter referred to as ProxyCare-of Address (Proxy-CoA)). Then, the data packet sent from the communication node 400 to HoA is tunneled with the address of the mobility management server 100 and Proxy-CoA as endpoints, and the data packet is transferred to the location registration gateway 200. On the contrary, after decapsulating the data packet from the mobile node 300 transferred from the location registration gateway 200 through the tunnel with the proxy-CoA and the address of the mobility management server as endpoints, the packet is transferred to the communication node 400.

  The location registration gateway 200 is referred to as “Mobile Access Gateway (MAG)” in Non-Patent Document 1. The location registration gateway 200 receives the Router Solicitation (RS) transmitted from the mobile node 300 after the mobile node 300 is connected to the access network 600, and then uses the Proxy Binding Update (PBU) to support the HNP and the Proxy-CoA. Is registered in the mobility management server 100. After that, when ProxyBinding Acknowledgment (PBA), which is a PBU response, is received from the mobility management server 100, it transmits Router Advertisement (RA) to the mobile node 300.

  Here, RS and RA are protocols defined in RFC4861 (see Non-Patent Document 2). RS is a signal transmitted when a node equipped with Internet Protocol version 6 (IPv6) requests an RA. The RA is a router to be used as a gateway when transmitting packet data to a network outside the connected link, that is, information necessary for automatically generating an IPv6 address for an IPv6 node (that is, a router that is an RA transmission source). It is intended to advertise information.

  Here, the trigger for PBU transmission is RS reception, but PBU may be transmitted at different triggers.

  The mobile node 300 is a terminal according to the IPv6 specification. Although it is called a mobile node because it is a node that is assumed to move between access networks 600, a mobile node in PMIPv6 has the same configuration as a normal IPv6 node. In MobileIPv6 (MIPv6) described in RFC3775 (see Non-Patent Document 3), the mobile node 300 itself performs a location registration process performed by the location registration gateway 200 using PBU in PMIPv6. The signal to be transmitted at this time is called BindingUpdate (BU).

  For this reason, the mobile node 300 needs a function for performing MIPv6 operations such as location registration in addition to a general IPv6 function. On the other hand, in PMIPv6, the mobile node 300 only needs to have a function as a general IPv6 node. This is the biggest difference between PMIPv6 and MIPv6, and is an element that characterizes PMIPv6.

  As described above, the communication node 400 is a node that communicates with the mobile node 300, and assumes a general IPv6 node. Therefore, the mobile node 300 has the same configuration. Although it is connected to the network 500 in FIG. 31, it may be connected to the access network 600 under the location registration gateway 200 like the mobile node 300.

  The network 500 is a network in which the mobility management server 100 and the location registration gateway 200 are connected. Note that the network 500 is generally a network managed by an operator who provides a mobile communication service.

  The access network 600 is a network to which the mobile node 300 is connected, and the location registration gateway 200 is also arranged in the network. In this access network 600, wireless technology is basically applied to communication. In addition, the access network, that is, the location registration gateway 200 and the mobile node 300 are layer 2 links, and basically has a configuration in which no router exists. However, there may be a router. In this case, the location registration gateway 200 and the mobile node 300 may be logically viewed as 1 hop by a technique such as tunneling.

  Next, with reference to FIG. 32, the operation | movement of the mobile communication system by PMIPv6 is demonstrated.

  First, the mobile node 300 connects to the access network 600a where the location registration gateway 200a is located (step a1). At this time, authentication processing of the mobile node 300 is performed depending on the mobile communication system, but since it is not directly related to the present invention, detailed description thereof is omitted here.

  Next, when the mobile node 300 detects a connection to the access network 600a, the mobile node 300 transmits an RS to the location registration gateway 200a (step a2). This is a normal IPv6 node operation.

  When receiving the RS, the location registration gateway 200a transmits a location registration request signal (indicating PBU) to the mobility management server 100 using RS reception as a trigger (step a3). The location registration request signal includes the identification information of the mobile node 300, the HNP corresponding to the network prefix portion of the HoA that is an IP address used when the mobile node 300 communicates, and the Proxy- assigned to the location registration gateway 200a itself. CoA information and the like are included. Here, the HNP needs to be a prefix routed to the mobility management server 100. At this time, when HNP allocation is requested to the mobility management server 100, 0 is set in the HNP.

  Next, when the mobility management server 100 receives the location registration request signal, the correspondence between the HNP stored in the location management request signal and the Proxy-CoA is recorded. When 0 is set in the HNP, the HNP is dynamically allocated by using the identification information of the mobile node 100, and the correspondence between the HNP and the Proxy-CoA is recorded. At the same time, preparation is made to transfer a packet addressed to the HNP to the location registration gateway 200a by tunneling with the address of the mobility management server 100 and Proxy-CoA as endpoints. Thereafter, the mobility management server 100 responds to the location registration gateway 200a with a location registration response signal (indicating PBA) storing a code indicating the processing result (step a4). In this location registration response signal, HNP, identification information of the mobile node 300, and the like are stored.

  Next, when the location registration gateway 200a receives the location registration response signal, the location registration gateway 200a confirms that a code indicating successful registration is set in the location registration response signal (here, it is assumed that the registration is successful), and the HNP Is stored in the mobile node 100 (step a5). Next, when the mobile node 300 receives the RA in which the HNP is set, the mobile node 300 generates a HoA from the HNP as necessary, like a general IPv6 node. Also, set the default gateway.

  As a result, the mobile node 300 and the communication node 400 can communicate (step a6). Specifically, the data packet transmitted from the mobile node 300 is transferred to the mobility management server 100 by tunneling at the location registration gateway 200a, and is transferred to the communication node 400 after the tunnel is removed at the mobility management server 100. . On the other hand, the data packet transmitted from the communication node 400 is routed to the mobility management server 100, transferred to the location registration gateway 200a by tunneling, and taken out after the tunnel is removed at the location registration gateway 200a. The packet is forwarded to the mobile node 300.

  The above is the basic operation when the mobile node 300 is connected to a network that supports PMIPv6.

  Next, with reference to FIG. 33, the operation when the mobile node 300 moves between access networks 600 supporting PMIPv6 will be described.

  First, it is assumed that the mobile node 300 is connected to the access network 600a under the location registration gateway 200a by the procedure described in FIG. At this point, the mobile node 300 and the communication node 400 are communicating via the tunnel between the location registration gateway 200a and the mobility management server 100 (step b1).

  Thereafter, the mobile node 300 disconnects from the access network 600a in order to move to the communication range of the access network 600b (step b2). Originally, the location registration gateway 200a transmits a signal for canceling the registration of the HNP and Proxy-CoA for the mobile node 300 to the mobility management server 100, but this is important for explaining the problem to the present invention. Since it is not, the description is abbreviate | omitted.

  Subsequent steps b3 (step in which the mobile node connects to the access network) to step b7 (step in which the mobile node receives the RA) are the same as steps a1 to a5 described in FIG. Is omitted.

When step b7 is completed, the communication that the mobile node 300 has performed with the mobile node 400 is switched to a new path (path via the location registration gateway 200b and the mobility management server 100). Although the path is switched in this way, the mobile node 300 can continue to use the same IP address before and after the movement, so that continuous communication can be realized.
RFC5213, "Proxy Mobile IPv6", http://tools.ietf.org/html/rfc5213 RFC4261, "Neighbor Discovery for IP version 6 (IPv6)", http://www.ietf.org/rfc/rfc4861 RFC3775, "Mobility Support in IPv6", http://www.ietf.org/rfc/rfc3775

  Unlike the system configuration shown in FIG. 31, as shown in FIG. 34, there are cases where the networks from the mobility management server 100 to the location registration gateway 200a and the location registration gateway 200b are different, such as the network 500a and the network 500b. is there. In this case, there is a high possibility that a large difference occurs between the packet transmission time from the mobility management server 100 to the location registration gateway 200a and the packet transmission time from the mobility management server 100 to the location registration gateway 200b.

  Also, the packet transmission delay from the location registration gateway 200a to the mobile node 300 and the packet transmission delay from the location registration gateway 200b to the mobile node 300 are different even when the access technologies are different (wireless LAN, WiMAX, 3G, etc.).

  When such a delay difference occurs, the packet transmission delay from the mobility management server 100 to the mobile node 300 causes a large difference before and after the mobile node 300 moves. As a result, there are problems that the communication of the mobile node 300 is interrupted and the communication speed is significantly reduced. This problem occurs, for example, when TCP (Transmission Control Protocol) is used for communication. This will be described in detail below.

  FIG. 35 shows a case where the packet transmission delay becomes smaller due to movement of the mobile node 300. As shown in FIG. 35, after the mobile node 300 moves, a case in which the order of packets arriving at the mobile node 300 is switched occurs. When this number of replacements increases, an algorithm called TCP early retransmission operates, and the communication node 400 retransmits packets despite no packet drop. Furthermore, when a reception timeout occurs due to packet dropping or the like, TCP shifts to a slow start state, and the communication speed is significantly reduced. The reception timeout time is updated depending on the transmission delay. Specifically, the shorter the transmission delay, the shorter the imout time. Accordingly, when the transmission delay of the network after movement becomes significantly smaller than the transmission delay before movement as in the case of FIG. 35, the timeout time is updated to be shorter, and the packet sent before movement is changed. A timeout may occur before it arrives, causing a slow start.

  Next, another case will be described. FIG. 36 shows a case where the packet transmission delay increases due to the movement of the mobile node 300. Since the packet transmission delay increases after the movement occurs, an interval is opened for packets arriving at the mobile node 300 as shown in FIG. Since the transmission delay is small in the network before movement, the above-described timeout time is set short. In this state, as shown in FIG. 36, when an opening occurs in packet arrival, a slow start state due to timeout occurs, and the communication speed is significantly reduced. In addition, when the packet arrival time is widened, there may be a problem in communication depending on the characteristics of the upper application.

  The present invention has been made to solve the above-described problems of the technology, and provides a mobile communication system, a server device, a gateway device, and a communication control method that suppress a change in communication delay during handover. Objective.

In order to achieve the above object, a mobile communication system of the present invention comprises:
When connected to a mobile node via a network, a plurality of gateway devices that relay data transmitted / received by the mobile node and transmit delay information that is information indicating a communication delay time of a communication path through which the data is transmitted When,
Collecting delay information received from the plurality of gateway devices via the network, and based on the collected delay information, a communication path between the mobile node and the communication partner that differs depending on the gateway device to which the mobile node is connected A management server that controls the communication delay time in order to reduce the difference in communication delay time;
It is the structure which has.

The server device of the present invention is a server device connected via a network to a plurality of gateway devices that relay data transmitted and received by a mobile node via a network with a communication partner.
A storage unit for storing delay information which is information indicating a communication delay time of a communication path through which the data is transmitted;
The delay information received from the plurality of gateway devices via the network is stored in the storage unit, and the mobile node differs depending on the gateway device to which the mobile node is connected based on the delay information stored in the storage unit And a control unit for controlling the communication delay time in order to reduce a difference in communication delay time of a communication path between the communication partner and the communication partner;
It is the structure which has.

The gateway device of the present invention is
A storage unit for storing delay information which is information indicating a communication delay time of a communication path through which data is transmitted via the own device;
When connected to a mobile node via a network, the mobile node relays data transmitted / received to / from a communication partner, collects the delay information of a communication path through which the data is transmitted, and stores the delay information in the storage unit. The management server that controls the communication delay time to reduce the difference in communication delay time between the mobile node and the communication partner before and after the movement of the mobile node, the delay information stored in the storage unit is transferred to the network. A control unit for transmitting via
It is the structure which has.

The communication control method of the present invention is a communication control method by a server device connected via a network to a plurality of gateway devices that relay data transmitted and received by a mobile node via a network with a communication partner,
Collecting delay information that is information indicating a communication delay time of a communication path through which the data is transmitted from the plurality of gateway devices via the network,
Based on the collected delay information, the communication delay time is controlled in order to reduce the difference in the communication delay time of the communication path between the mobile node and the communication partner, which differs depending on the gateway device to which the mobile node is connected. is there.

Further, the communication control method of the present invention is a communication control method by a gateway device that relays data transmitted and received by a mobile node via a network with a communication partner,
Collect delay information, which is information indicating the communication delay time of the communication path through which the data is transmitted via its own device,
The collected delay information is sent via the network to the management server that controls the communication delay time in order to reduce the difference in communication delay time of the communication path between the mobile node and the communication partner before and after the movement of the mobile node. To send.

  ADVANTAGE OF THE INVENTION According to this invention, the interruption of communication and the fall of a communication speed can be suppressed by suppressing the change of the transmission delay of a packet before and behind the movement of a mobile node.

(First embodiment)
The configuration of the mobile communication system of this embodiment will be described. FIG. 1 is a block diagram showing a configuration example of a mobile communication system according to this embodiment.

  As shown in FIG. 1, the mobile communication system of the present embodiment includes a mobility management server 700 and location registration gateways 800a and 800b. Here, the location registration gateway 800a and the location registration gateway 800b have the same configuration. When attention is paid to the function as the location registration gateway, there is no difference between the two, and the location registration gateway 800b is described as the location registration gateway 800. On the other hand, when it is necessary to distinguish between the two, they are described as location registration gateway 800a and location registration gateway 800b, respectively. This notation is the same for the networks 500a and 500b and the access networks 600a and 600b.

  The mobile node 300 is connected to the access network 600 as it moves. The communication node 400 shown in FIG. 1 is not essential to the present invention, but is described as a node that communicates with the mobile node 300.

  The mobility management server 700 and the location registration gateway 800a are connected via the network 500a. The mobility management server 700 and the location registration gateway 800b are connected via the network 500b. On the other hand, the mobile node 300 is connected to the location registration gateway 800a via the access network 600a, and is connected to the location registration gateway 800b via the access network 600b.

  In the configuration shown in FIG. 1, components whose names and symbols match those shown in FIG. 34 have the same functions as those of the same names and symbols described in the background art. Specifically, the configuration other than the mobility management server 700 and the location registration gateway 800 in the configuration shown in FIG. 1 is the same configuration as the PMIP mobile communication system described in the background art. Detailed description of the same configuration as that described in the background art will be omitted.

  A configuration of the mobility management server 700 shown in FIG. 1 will be described. FIG. 2 is a block diagram showing an example of the configuration of the mobility management server of this embodiment.

  As shown in FIG. 2, the mobility management server 700 includes a mobility management server function realization unit 711, a delay collection unit 712, a delay determination unit 713, and a delay implementation unit 714, a communication interface 710, and a delay storage device. 720.

  The communication interface 710 is connected to the network 500, has a function of transmitting and receiving packets, and mainly exchanges packets with the location registration gateway 800. Packets exchanged with the location registration gateway 800 include signal packets and data packets for location registration. The former signal packet is transmitted from the location management gateway 700 to the location registration gateway 800 as a response to the location registration request signal (PBU) sent from the location registration gateway 800 to the location management request server 700 or the location registration request signal. Is a location registration response signal (PBA). On the other hand, the latter data packet is a packet in which the packet sent from the communication node 400 to the mobile node 300 is encapsulated by the mobility management server 700, or conversely, a data packet sent from the mobile node 300 to the communication node 400. A packet encapsulated by the location registration gateway 800 is shown.

  When the communication interface 710 receives the location registration request signal, the communication interface 710 outputs the packet to the mobility management server function realizing unit 711. Here, the expression “output” is used, but it is assumed that only the arrival of the packet is notified to the mobility management server function realizing unit 711, and the packet management is actively performed by the mobility management server function realizing unit 711. Also good. That is, it is important where the information (including the packet) moves from where it is, and it is not important whether it is received passively or actively read out. This applies to all of the following descriptions unless otherwise noted. When a location registration response signal is input from the mobility management server function realizing unit 711, the communication interface 710 transmits the signal to the network 500.

  Further, when receiving the data packet, the communication interface 710 outputs the data packet to the delay execution unit 714 and transmits the data packet input from the delay execution unit 714 to the network 500.

  The mobility management server function realization means 711 has the same function as the general mobility management server 100 shown in FIG. 31 or FIG. That is, a function necessary for implementing the LMA function described in Non-Patent Document 1 is provided. Specifically, a function of processing a location registration request signal and a location registration response signal, a function of encapsulating a packet addressed to the mobile node 300 and transferring the packet to the location registration gateway 800, or being encapsulated from the location registration gateway 800 and transmitted A function of decapsulating the packet from the mobile node 300 and transferring it to the communication node 400 is provided. Since these functions are general operations as described in the background art, a detailed description thereof will be omitted.

  However, when the delay information is stored in the location registration request signal input from the communication interface 710, the delay information and the address of the location registration gateway 800 included in the location registration request signal are sent to the delay collection unit 712. Unlike the general mobility management server 100, the mobility management server function realizing unit 711 further includes an output unit. Note that the delay information is included in the location registration request signal is a part of the feature of the present invention. On the other hand, the address of the location registration gateway 800 is also included in a general location registration request signal.

  Further, the data packet is not directly input / output from / to the communication interface 710 but is also routed through the delay execution means 714, which is different from the operation of the mobility management server 100 shown in FIG.

  Further, if the location registration gateway 800 stores information indicating the transmission time of the location registration request signal in the location registration request signal, this is stored in the movement registration response signal as it is. In the location registration request signal, time information can also be stored in general PMIPv6 described in Non-Patent Document 1. Since this information is stored in the location registration response signal as described above, this is basically a category of operation of the general mobility management server 100, but the storage format of time and the accuracy of storage. Need not be the same as general ones.

  The delay information assumes a delay time in milliseconds in the present embodiment, but other units or other indicators may be used as information indicating the delay time.

  The delay collection unit 712 updates the information of the delay recording device 720 as information in which the delay information (meaning delay time) input from the mobility management server function realization unit 711 and the address of the location registration gateway 800 are associated with each other. . In the delay recording device 720, the location registration gateway 800 and the corresponding delay time are recorded in the format of the delay information table shown in FIG. For example, in the second row of the delay information table shown in FIG. 3, it can be seen that the address MAG_addr # 1 of the location registration gateway and the delay time Dlm # 1 are recorded as a set. At this time, the delay time associated with the location registration gateway 800 is searched from the delay information table recorded in the delay storage device 720 using the address of the location registration gateway 800. If the delay time is found as a result of the search, a new delay time is calculated using the found delay time and the delay time obtained this time, and the calculated delay time is associated with the location registration gateway 800. The delay information table is updated as the received delay time. On the other hand, if the corresponding delay time is not found, the delay time obtained this time is recorded in the delay information table as the delay time associated with the location registration gateway 800 as it is. At this time, for simplification of processing, even if the corresponding delay time is found as a result of the search, the delay time obtained this time may be directly overwritten without calculating a new delay time. However, in this case, if there is a large fluctuation in the obtained delay time, there is a possibility that appropriate delay compensation processing cannot be performed. The delay compensation process will be described later.

An example of a new delay time calculation method is shown in the following equation 1. However, Expression 1 is merely an example, and other calculation methods may be used.
Dnew = 0.9 × Dprev + 0.1 × Dcur Equation 1
In Equation 1, Dprev represents the delay time found as a result of the search, Dcur represents the delay time obtained this time, and Dnew represents the calculated new delay time. By using the calculation example of Equation 1, even when there is a variation in delay time, the variation can be smoothed, and stable delay compensation processing can be realized.

  Further, the delay collection unit 712 notifies the delay determination unit 713 of the opportunity for updating the delay information table.

  The delay determining unit 713 accesses the delay information table of the delay recording device 720 when receiving a notification indicating an opportunity to update the delay information table from the delay collecting unit 712, and sets the address management gateway 800 address and delay time combination. Are sequentially read out, and the maximum delay time among these delay times is determined. Further, a delay time to be added to a packet transmitted / received to / from the address of each location management gateway 800 is calculated from the read delay times and the maximum delay time.

The delay time to be added can be calculated by, for example, the following formula 2.
Ddiff_MAG # n = Dmax−D_MAG # n Equation 2
Here, Dmax is the maximum delay time, D_MAG # n is a delay time associated with the address (MAG_addr # n) of the location registration gateway 800 read from the delay information table, and Ddiff_MAG # n indicates a delay time to be added to the packet encapsulated to the address of the location registration gateway 800.

  Also, the delay determining unit 713 outputs the delay time to be added obtained as described above to the delay performing unit 714 together with the address of the location registration gateway 800.

  Here, it is assumed that the delay determining unit 713 reads all the information recorded in the delay information table of the delay recording device 720. However, in the case of narrowing down the location registration gateways 800 to be subjected to delay compensation processing. The delay time associated with the target location registration gateway 800 may be read out.

  In addition, although the notification from the delay collection unit 712 is used as a trigger for determining the additional delay time, the processing may be performed periodically without depending on the notification. In this case, the delay collection unit 712 does not need a function for notifying that the delay information table has been updated.

  The delay execution means 714 monitors the data packet transferred by the mobility management server 700, and when a packet addressed to the address of the location registration gateway 800 or a packet sent from the address is detected, queuing is performed on the corresponding packet. A delay compensation function that adds a delay corresponding to the delay time to be added corresponding to the address of the location registration gateway 800 is provided.

  In this case, a delay compensation target is a packet sent from the location registration gateway 800 by encapsulation or a packet that the mobility management server 700 sends to the location registration gateway 800 by encapsulation.

  Note that the target of delay compensation may be narrowed down more than shown here, and in this case, additional information may be used for narrowing down.

  The delay storage device 720 holds the delay information table shown in FIG. Processing such as addition, update, and reading is performed on the information in the delay information table from the delay collection unit 712 and the delay determination unit 713.

  A configuration of the location registration gateway 800 shown in FIG. 1 will be described. FIG. 4 is a block diagram illustrating a configuration example of the location registration gateway according to the present embodiment.

  As shown in FIG. 4, the location registration gateway 800 in the present embodiment includes a control unit 851 including a location registration gateway function realizing unit 812, a delay measuring unit 813, and a delay notifying unit 814, a communication interface 810, a communication interface 811, and the like. A delay storage device 820 and an access network delay storage device 821.

  The communication interface 810 is connected to the network 500 and transmits and receives packets. The communication interface 810 mainly exchanges packets with the mobility management server 700. Packets exchanged with the mobility management server 100 include a signal packet for PMIP operation and a data packet. The former signal packet includes a location registration request signal (PBU) and a location registration response signal (PBA). The location registration request signal is a signal sent from the location registration gateway 800 to the mobility management server 700, and the location registration response signal is sent from the mobility management server 700 to the location registration gateway 800 as a response to the location registration request signal. Signal. On the other hand, the latter data packet is a packet in which a data packet sent from the mobile node 300 to the communication node 400 is encapsulated by the location registration gateway 800, or a packet sent from the communication node 400 to the mobile node 300. , Packets encapsulated by the mobility management server 700, and the like.

  Further, the communication interface 810 outputs the received location registration response signal to the delay measuring unit 813 and outputs the data packet to the location registration gateway function realizing unit 812.

  Further, the communication interface 810 transmits a packet such as an input data packet or a location registration request signal to the network 500.

  The communication interface 811 is connected to the access network 600 and transmits and receives packets. The communication interface 811 mainly exchanges packets with the mobile node 300. Packets exchanged with the mobile node 300 include a data packet and a control packet used by a general IP terminal. The former is a data packet sent from the communication node 400 to the mobile node 300, and conversely a data packet sent from the mobile node 300 to the communication node 400. On the other hand, the latter control packet is RS or RA.

  The location registration gateway function realization means 812 includes a general location registration gateway, that is, a function necessary for implementing a function corresponding to the MAG described in Non-Patent Document 1. Specifically, a location registration request signal is transmitted to the mobility management server 700 in response to reception of an RS, etc., so that the correspondence between the HNP of the mobile node 300 and the Proxy-CoA of the location registration gateway 800 is transmitted to the mobility management server 700. When a registration request is made and a location registration response signal as a response is received, the RA storing the HNP is notified to the mobile node 300. Further, when the registration is successful here, the location registration gateway function realization means 812 encapsulates the packet sent from the mobile node 300 and transfers it to the mobility management server 700, and conversely from the mobility management server 700. The packet addressed to the mobile node 300 sent after being encapsulated is decapsulated and transferred to the mobile node 300.

  In the above description, the location registration request signal is transmitted in response to reception of the RS. However, another signal may be used as a trigger. For example, in a system that can detect that the mobile node 300 is connected to the access network 600, the location registration request signal can be transmitted when the mobile node 300 is connected to the access network 600.

  The delay measurement unit 813 inserts the time information at the time of transmission of the signal into the location registration request signal transmitted by the location registration gateway function realization unit 812 and outputs the signal to the delay notification unit 814. Further, the delay measuring unit 813 checks the location registration response signal received by the communication interface 810, and if time information is stored in the signal, the delay measuring unit 813 calculates a difference in reception time of the signal from the stored time information. Further, the delay time between the location registration gateway 800 and the mobility management server 700 is calculated by dividing by 2. The received location registration response signal is output to location registration gateway function realization means 812.

  Furthermore, the delay measurement unit 813 records the delay time calculated here in the delay storage device 820 in association with the address of the mobility management server 700 that is the destination of the location registration request signal. At this time, the delay storage device 820 records the delay time in a format such as the mobility management server / location registration gateway delay information table shown in FIG. When recording the delay time, a process similar to the smoothing process shown in Equation 1 may be performed here.

  In the delay information table between the mobility management server and the location registration gateway, a measurement delay time that is a delay time measured with the address of the mobility management server is recorded as a pair. In the example shown in FIG. 5, it can be seen that the mobility management server address LMA_addr # 1 and the measurement delay time Dlm # 1 are recorded as a pair in the second row of the table.

  When time information is stored in the location registration request signal by the function of the location registration gateway 812 as a general location registration gateway, the delay measuring unit 813 can measure the delay time using the time information. The time information may not be stored separately in the location registration request signal. Further, if the delay measuring means 813 holds the time when transmitting the location registration request signal and the identification information that can associate the location registration response signal with the time, the mobile registration response Since the transmission time can be acquired using the identification information when receiving the signal, the delay time can be measured without storing the transmission time information in the location registration request signal in this case as well. As identification information that is information that can uniquely specify a location registration request signal, for example, there is a SequenceNumber described in Non-Patent Document 1.

  When the movement registration request signal is transmitted, the delay notification unit 814 uses the identification information such as the address of the movement management server 700 and the address of the mobile node 300 set in the position registration request signal, and the delay storage device 820 and The access network delay storage device 821 is searched, the corresponding delay time between the mobility management server and the location registration gateway, and the access network delay time are acquired, and the sum of the two types of acquired delay times is calculated to obtain one delay time. Then, it is stored in the movement registration request signal and output to the communication interface 810. Here, two types of delay times are added to obtain one delay time, but two types of delay times may be individually stored in the position registration request signal.

  As described above, the delay storage device 820 holds the delay information table between the mobility management server and the location registration gateway shown in FIG. Further, processing such as writing or reading is performed by the delay measuring unit 813 or the delay notifying unit 814 on the delay information between the mobility management server and the location registration gateway.

  The access network delay storage device 821 holds the delay time of the access network. The access network delay is, for example, a delay time of a radio link portion. The delay time of the radio link part depends on various parameters such as the type of radio technology, modulation mode and error tolerance. It is assumed that the delay time can be uniquely determined by the wireless technology type and the parameters related to the delay time when the mobile node 300 establishes a wireless connection. Information on the determined delay time is shown in FIG. As shown, it is recorded in the access network delay storage device 821 in association with the mobile node 300. If the delay time cannot be uniquely determined as described above, a method of dynamically measuring the delay by exchanging packets with the mobile node 300 may be used.

  FIG. 6 shows an example of a location registration gateway / mobile node delay information table. The measurement delay time is recorded corresponding to the mobile node address. In the example of FIG. 6, it can be seen that the mobile node address MN_addr # 1 and the measurement delay time Dmm # 1 are registered as a pair in the second row.

  In the location registration gateway 800 of the present embodiment, the location registration request signal and the location registration response signal are used for the measurement of the delay time between the mobility management server 700 and the location registration gateway 800. For example, ICMP (Internet Control Protocol) is used. Alternatively, other signals such as Echo Request and Echo Response defined in ICMPv6 (Internet Control Protocol for IPv6) may be used. In this case, the position measuring unit 813 and the delay notifying unit 814 store the transmission time and delay information in the Echo Request. Further, the delay measuring unit 813 measures the delay time by EchoResponse. The Echo Request may be periodically transmitted to the address of the mobility management server 700 set in advance, or the Echo Request process may be repeated several times when the location registration management server is started up.

  On the other hand, the delay collection unit 712 of the mobility management server 700 collects the delay time from the delay time stored in the Echo Request. Further, when the transmission time information of the signal is set in Echo Response, the delay collection unit 712 stores it in the Echo Response as it is. The same processing may be performed when other signals are used.

  Each of the communication interfaces 710, 810, and 811 described above can be implemented by, for example, a network interface card (NIC) such as a LAN card and software (driver) that operates the network interface card (NIC). As the access network 600, a wireless link is usually used. At this time, the communication interface 811 may be a wireless interface, the wireless base station may be installed outside the location registration gateway 800, and the wireless base station and the communication interface 811 may be connected by wire. In either case, there is no influence on the elements that are characteristic of the present invention.

  On the other hand, each of the mobility management server function realizing means 711, the delay collecting means 712, the delay determining means 713, the delay executing means 714, the location registration gateway function realizing means 812, the delay measuring means 813, and the delay notifying means 814 is programmed by the processor. It is possible to configure virtually by executing. However, some or all of them can be configured by hardware such as a dedicated circuit.

  Each of the delay storage device 720, the delay storage device 820, and the access network delay storage device 821 can be configured by a device capable of recording information, such as a semiconductor memory or a hard disk drive.

  Further, the delay information to be collected may be both a communication delay time between the mobility management server 700 and the location registration gateway device 800 and a communication delay time between the location registration gateway device 800 and the mobile node 300. One may be sufficient. Further, the delay information may be measured in response to the connection from the mobile node 300, or the delay information may be measured in advance.

  Next, the operation procedure of the mobility management server 700 in this embodiment will be described using the flowchart of FIG.

  First, in step c1, the mobility management server 700 receives the location registration request signal sent from the location registration gateway 800.

  Subsequently, in step c2, the location registration request signal is processed by the action of the mobility management server function realization means 711, and preparation for transferring the data addressed to the mobile node 300 to the location registration gateway 800 by a method such as tunneling is performed. At this time, if the delay information is included in the location registration request signal, the delay information is extracted, the delay information is collected by the action of the delay collecting means 712, and the delay information is recorded in the delay recording device 720 (step). c3).

  Next, in step c4, the mobility management server 700 reads the delay information recorded in the delay storage device 720 by the action of the delay determining means 713, and determines the delay time to be added by using Equation 2 or the like. The determined delay time is output to the delay execution means 714.

  Subsequently, in step c5, the mobility management server 700 operates on the target traffic between the mobility management server 700 and the location registration gateway 800 according to the delay time notified from the delay determination means 713 by the action of the delay execution means 714. Process to add delay.

  Next, the operation procedure of the location registration gateway 800 in this embodiment will be described using the flowcharts of FIGS. 8 and 9. The flowchart of FIG. 8 shows processing until a location registration request signal storing information for delay measurement is transmitted. The flowchart of FIG. 9 shows a process in which the location registration gateway 800 receives the location registration response signal transmitted as a response to the location registration request signal by the mobility management server 700 and performs delay measurement from the location registration response signal.

  In step d 1 shown in FIG. 8, the location registration gateway 800 generates a location registration request signal by the action of the location registration gateway function realization means 812 when the mobile node 300 moves under the location registration gateway 800. To do.

  Subsequently, in step d2, the location registration gateway 800 stores the current time information for the location registration request signal by the action of the delay measuring unit 813. Further, in step d3, the delay time of the network 500 corresponding to the mobility management server 700 which is the destination of the location registration request signal is acquired from the delay storage device 820 by the action of the delay notification means 814. Further, the delay time of the access network 600 to which the mobile node 300 is connected is read from the access network delay storage device 821, and the delay time of the network 500 and the delay time of the access network 600 are stored in the location registration request signal. At that time, a delay time obtained by adding the above two types of delay times may be stored. If there is not much difference between the delay times of the plurality of access networks 600 (for example, the access network 600a and the access network 600b), the latter The delay time of the access network 600 can be omitted.

  In step d4, the location registration gateway 800 transmits the location registration request signal storing the current time information and the delay time to the mobility management server 700 via the communication interface 810 by the processing up to step d3.

  Next, the operation procedure shown in FIG. 9 will be described.

  In step e1 shown in FIG. 9, the location registration gateway 800 receives the location registration response signal transmitted by the mobility management server 700 as a response to the location registration request signal transmitted by the own device.

  Subsequently, in step e2, the location registration gateway 800 measures the delay time between the mobility management server 700 and the location registration gateway 800 from the time information stored in the location registration response signal by the action of the delay measuring means 813, and manages the mobility. The measured delay time is recorded in the delay storage device 820 together with information that can identify the mobility management server 700 such as the address of the server 700.

  In step e3, the location registration gateway 800 performs the same processing as when a general location registration gateway receives a location registration response signal by the action of the location registration gateway function realization means 812.

  As described above, in this embodiment, the location registration gateway 800 uses the location registration request signal and the location registration response signal to measure the delay time of communication between the mobility management server 700 and the location registration gateway 800, and the delay. The time is stored in the location registration request signal and notified to the mobility management server 700. The mobility management server 700 that has received the delay information reduces the difference in communication delay that differs depending on the location registration gateway 800 to which the mobile node 300 is connected based on the notified delay time, and the location registration gateway to which the mobile node 300 is connected. Regardless of 800, a delay time for matching the communication delay from the mobility management server 700 to the mobile node 300 is added. Therefore, even when the mobile node 300 moves between the location registration gateways 800, fluctuations in transmission delay of transmission / reception packets can be suppressed, and even when TCP is used as an upper protocol, communication delay is reduced. It is possible to avoid the influence of the change on the upper protocol.

(Second Embodiment)
The mobile communication system of this embodiment will be described. The overall configuration of the present embodiment is the same as the configuration shown in FIG. 1, except that the mobility management server 700 and the location registration gateway 800 are the mobility management server 701 shown in FIG. 10 and the location shown in FIG. The point which becomes the registration gateway 801 is different from the first embodiment.

  The mobility management server 701 in this embodiment will be described. FIG. 10 is a block diagram showing a configuration example of the mobility management server in the present embodiment.

  As shown in FIG. 10, the mobility management server 701 includes a mobility management server function realization unit 711, a delay collection unit 712, a delay determination unit 713, and a delay notification unit 715, a communication interface 710, and a delay storage device. 720.

  Among these, about the structure similar to 1st Embodiment, the same name and the same code | symbol are attached | subjected, and the detailed description is abbreviate | omitted in this embodiment. In this embodiment, the delay notification means 715 that is a new component will be described in detail.

  The delay notification means 715 indicates the additional delay time to be added to the path between the mobility management server 701 and the location registration gateway 801 determined by the delay determination means 713 as a response to the location registration request signal by the mobility management server function realization means 711. After storing the generated location registration response signal, the location registration response signal is transmitted to the location registration gateway 801.

  Next, the location registration gateway 801 in this embodiment will be described. FIG. 11 is a block diagram illustrating a configuration example of the location registration gateway in the present embodiment.

  As shown in FIG. 11, the location registration gateway 801 communicates with a control unit 852 including a location registration gateway function realization means 812, a delay measurement means 813, a delay notification means 814, an additional delay information acquisition means 815, and a delay execution means 816. It has an interface 810, a communication interface 811, a delay storage device 820, and an access network delay storage device 821.

  In addition, also about the location registration gateway 801, about the structure similar to 1st Embodiment, the same name and the same code | symbol are attached | subjected, and the detailed description is abbreviate | omitted in this embodiment. In this embodiment, the additional delay information acquisition unit 815 and the delay execution unit 816, which are new components, will be described in detail.

  The additional delay information acquisition unit 815 acquires the additional delay time stored in the location registration response signal transmitted from the mobility management server 701 and outputs the additional delay time to the delay execution unit 816.

  The delay execution unit 816 adds a delay to the data packet transmitted / received between the mobility management server 701 and the location registration gateway 801 according to the additional delay time output from the additional delay information acquisition unit 815. Specifically, the data packet transmitted or received from the communication interface 810 is monitored, and the address of the data packet is a combination of the address of the location registration gateway 801 and the address of the mobility management server 701, the source address and the destination address. Alternatively, if the destination address and the source address are used, an additional delay is added, and a delay corresponding to the additional delay time is generated by a method such as queuing. Here, for example, it may be added to the delay addition condition that the data packet detected by the above method is a packet from the mobile node 300 or a packet obtained by encapsulating the packet to the mobile node 300.

  If a plurality of mobility management servers 701 are provided, the location registration gateway 801 performs location registration with respect to different mobility management servers 701, and if additional delay information has been acquired from each location management server 701, mobility management is performed. Different delay addition processing is performed according to the additional delay information notified for each server 701.

  Each of the delay notification unit 715, the additional delay information acquisition unit 815, and the delay execution unit 816 can be virtually configured by a processor executing a program. However, some or all of them can be configured by hardware such as a dedicated circuit.

  Next, the operation procedure of the mobility management server 701 in the present embodiment will be described using the flowchart of FIG.

  First, in step f1, the mobility management server 701 receives a location registration request signal sent from the location registration gateway 801.

  Subsequently, in step f2, the mobility management server 701 processes the location registration request signal by the action of the mobility management server function realization means 711, and transfers the data packet addressed to the mobile node 300 to the location registration gateway 801 by a technique such as tunneling. Prepare to do. At this time, if the location registration request signal includes delay information, the mobility management server 701 extracts the delay information, collects the delay information by the action of the delay collection unit 712, and stores the delay information in the delay recording device 720. Information is recorded (step f3).

  In step f4, the mobility management server 701 reads the delay information recorded in the delay storage device 720 by the action of the delay determination means 713, and determines the delay amount to be added using Equation 2 or the like. The determined delay amount is output to the delay notification means 715.

  Further, in step f5, the mobility management server 701 stores the additional delay information notified from the delay determination unit 713 in the location registration response signal transmitted to the location registration gateway 801 by the action of the delay notification unit 715. The signal is transmitted to the location registration gateway 801 via the communication interface 710.

  Next, the operation procedure of the location registration gateway 801 in this embodiment will be described with reference to the flowchart of FIG. Since the process until the location registration gateway 801 transmits the location registration request signal is the same as the procedure shown in FIG. 8, the detailed description thereof is omitted here and the location registration response signal is received. Processing will be described.

  First, in step g1, the location registration gateway 801 receives the location registration response signal transmitted by the mobility management server 701 as a response to the location registration request signal transmitted by the own device.

  Subsequently, in step g2, the location registration gateway 801 measures the delay time between the mobility management server 701 and the location registration gateway 801 from the time information stored in the location registration response signal by the action of the delay measurement unit 813, and manages the mobility. The measured delay time is recorded in the delay storage device 820 together with information that can identify the mobility management server 700 such as the address of the server 701.

  In step g 3, the location registration gateway 801 acquires additional delay information stored in the location registration response signal by the action of the additional delay information acquisition unit 815, and outputs this information to the delay execution unit 816. Thereafter, as described above, the delay execution unit 816 starts processing for adding a delay to the data packet transmitted / received between the mobility management server 701 and the location registration gateway 801 based on the additional delay information output here. To do.

  Further, in step g4, the location registration gateway 801 performs the same processing as when a general location registration gateway receives a location registration response signal by the action of the location registration gateway function realization means 812.

  As described above, in the present embodiment, unlike the first embodiment, a communication delay is added in the location registration gateway 801 instead of the mobility management server 701. Therefore, it is possible to distribute the load of the mobility management server 701 where traffic is concentrated to each location registration gateway 801 while maintaining the effect of suppressing the delay variation obtained by the first embodiment.

(Third embodiment)
The mobile communication system of this embodiment will be described. The overall configuration of the present embodiment is the same as the configuration shown in FIG. 1, except that the mobility management server 700 and the location registration gateway 800 are respectively the mobility management server 702 shown in FIG. 14 and the location shown in FIG. The registration gateway 802 is different from the first and second embodiments.

  The mobility management server 702 in this embodiment will be described. FIG. 14 is a block diagram illustrating a configuration example of the mobility management server in the present embodiment.

  As shown in FIG. 14, a control unit 753 including a mobility management server function realization unit 711, a delay collection unit 712, a delay determination unit 713, a delay implementation unit 714, and a delay measurement unit 716, a communication interface 710, and a delay storage device 720 And have.

  Note that the communication interface 710, the mobility management server function realizing unit 711, and the delay execution unit 714 have the same functions as those described in the first embodiment, and detailed description thereof is omitted in this embodiment. . The delay collection unit 712 and the delay determination unit 713 have the same functions as the configuration described in the first embodiment, and thus are given the same reference numerals, but are different from the first embodiment. Therefore, this point will be described. In the present embodiment, the delay measuring unit 716 that is a new component will be described in detail.

  Similarly to the delay collection unit 712 of the first embodiment, the delay collection unit 712 records delay information as information in which the delay information input from the mobility management server function implementation unit 711 and the address of the location registration gateway 802 are associated with each other. The delay information table of the device 720 is updated. At that time, the delay time can be smoothed by the equation 1 as in the first embodiment.

  However, since only the delay time of the access network 600 is notified from the location registration gateway 802 in this embodiment, when recording delay information in the delay recording device 720, the delay collecting means 712 is shown in FIG. Thus, it is distinguished from the delay of the network 500 and recorded as the delay of the access network 600, that is, the delay time between the location registration gateway 802 and the mobile node 300. This point is different from the first embodiment.

  FIG. 15 is a diagram showing an example of the delay information table in the present embodiment. In the delay information table, the respective delay times of the network 500 and the access network 600 are recorded corresponding to the address of the location registration gateway. In the example shown in FIG. 15, the location registration gateway address MAG_addr # 1, the delay time Dlm # 1 of the network 500, and the delay time Dmn # 1 of the access network 600 are registered as a pair in the second row. .

  The delay determination unit 713 should be added to a packet to be transmitted to and received from the location registration gateway 802 based on the delay information table recorded in the delay recording device 720, similarly to the delay determination unit 713 of the first embodiment. The delay amount is calculated, and the calculated delay amount is output to the delay execution unit 714 together with the address of the location registration gateway 802.

  However, in this embodiment, the delay information table recorded in the delay recording device 720 records the delay time of the network 500 and the delay time of the access network 600 separately. Used to calculate additional delay time as the delay time. This point is different from the first embodiment.

  The delay measuring unit 716 measures a delay between the mobility management server 702 and the location registration gateway 802 using ICMP Echo Request, ICMP Echo Response, and the like, and further uses the measured delay time as a delay of the network 500. Recorded in the delay information table 720. At that time, similarly to the delay collection unit 712, the delay time may be smoothed using Equation 1. The delay measuring unit 716 can be virtually configured by a processor executing a program. However, some or all of them can be configured by hardware such as a dedicated circuit.

  In addition, although using Echo Request and Echo Response for delay measurement was illustrated, other signals may be used. For example, at present, in the IETF (Internet Engineering Task Force), a specification of a general-purpose message on which MIPv6 and PMIPv6 agents (LMA, MAG, HA) called “Mobile IPv6 Generic Signaling Message” can be loaded with various information is being studied. However, you may use this message.

  As described above, the delay recording device 720 holds the delay information table illustrated in the example of FIG.

  Next, the location registration gateway 802 in this embodiment will be described. FIG. 16 is a block diagram showing a configuration example of the location registration gateway in the present embodiment.

  As shown in FIG. 16, the location registration gateway 802 includes a control unit 853 including a location registration gateway function realizing unit 812 and a delay notification unit 814, a communication interface 810, a communication interface 811, and an access network delay storage device 821. Have.

  In addition, also about the location registration gateway 801, about the structure similar to 1st Embodiment, the same name and the same code | symbol are attached | subjected, and the detailed description is abbreviate | omitted in this embodiment. Compared with the first or second embodiment, there are no new components in the present embodiment, but differences from the first and second embodiments will be described.

  The delay notification means 814 of this embodiment stores the access network delay time read from the access network delay storage device 821 in the location registration request signal and outputs the signal to the communication interface 810. In the present embodiment, unlike the delay notification unit 814 described in the first embodiment, the delay time storage process between the network 500, that is, the mobility management server 702 and the location registration gateway 802 is not performed.

  In some cases, such as when the type and characteristics of the access network 600 are the same, it is not necessary to consider the delay of the access network 600. In such a case, the delay collection unit 712 of the mobility management server 702 is not necessary, and the information recorded in the delay storage device 720 may be only the delay information of the network 500. Further, the delay notification means 814 and the access network delay storage device 821 of the location registration gateway 802 are not necessary. In other words, the location registration gateway 802 may be a general location registration gateway that does not include the elements that characterize the present invention.

  Next, the operation procedure of the mobility management server 702 in this embodiment will be described.

  In this embodiment, the delay collection unit 712 records only the delay information of the access network 600 notified by the location registration gateway 802 in the delay storage device 720, and the delay determination unit 713 determines the additional delay time. In this case, not only the delay information of the access network 600 written by the delay collecting unit 712 but also the delay information written by the delay measuring unit 716 is used slightly differently, but the delay notified from the location registration gateway 800 is different. The flow of processing from reading the information to implementing the delay is the same as step c1 to step c5 in the flowchart shown in FIG. 7, and therefore detailed description thereof is omitted here.

  FIG. 17 is a flowchart showing an operation procedure when the mobility management server in this embodiment performs delay measurement.

  First, in step h 1, the mobility management server 702 transmits a delay measurement signal, which is a signal for measuring a delay, such as Echo Request, to the location registration gateway 802 by the action of the delay measurement unit 716. In step h2, a position signal response is received as a response to the signal transmitted in step h1.

  Subsequently, in step h3, the mobility management server 702 calculates a delay time from the round-trip time between the delay measurement signal transmitted in step h1 and the position signal received in step 2, and further calculates Formula 1 as necessary. After the delay time is smoothed by the above, the delay time is recorded in the delay storage device 720 in step h4.

  Next, the operation procedure of the location registration gateway 802 in this embodiment will be described with reference to the flowchart of FIG.

  First, in step i1, the location registration gateway 802 generates a location registration request signal by the action of the location registration gateway function realization means 812 when the mobile node 300 moves under its own device.

  Subsequently, in step i2, the location registration gateway 802 reads the delay time of the access network 600 connected to the mobile node 300 from the access network delay storage device 821 by the action of the delay notification means 814, and stores it in the location registration request signal.

  In step i3, the location registration gateway 802 transmits a location registration request signal in which the delay time of the access network 600 is stored by the processing up to step i2 to the mobility management server 702 via the communication interface 810.

  As described above, in this embodiment, unlike the first embodiment, the mobility management server 702 measures the communication delay time of the network 500 instead of the location registration gateway 802. As a result, the location registration gateway 802 only notifies the delay time of the access network 600.

  As described above, when the characteristics of the access networks 600 under the plurality of location registration gateways 802 are the same and there is no significant difference in delay, the location registration gateway 802 needs to notify the delay of the access network 600. Disappear. In this case, the location registration gateway 802 may be a general location registration gateway that does not include the features of the present invention. This case can be an effective embodiment when the administrator of the mobility management server 702 and the administrator of the location registration gateway 802 are different.

(Fourth embodiment)
The mobile communication system of this embodiment will be described. The overall configuration of the present embodiment is the same as the configuration shown in FIG. 1, but each of the mobility management server 700, the location registration gateway 800, and the mobile node 300 includes the mobility management server 703 shown in FIG. 20 differs from the first to third embodiments in that it is a location registration gateway 803 shown in FIG. 20 and a mobile node 301 shown in FIG.

  The mobility management server 703 in this embodiment will be described. FIG. 19 is a block diagram illustrating a configuration example of the mobility management server in the present embodiment.

  As shown in FIG. 19, the mobility management server 703 includes mobility management server function realization means 711, delay collection means 712, delay execution means 714, movement advance notification processing means 717, delay control means 718, and delay compensation completion notification means 719. The control unit 754 includes a communication interface 710, and a delay storage device 720.

  Note that the communication interface 710, the mobility management server function realization unit 711, and the delay collection unit 712 have the same functions as those described in the first embodiment, and a detailed description thereof is omitted in this embodiment. . Since the delay execution means 714 has the same function as the configuration described in the first embodiment, the same reference numeral is given, but there is a difference from the first embodiment. explain. In this embodiment, the advance movement notification processing unit 717, the delay control unit 718, and the delay compensation completion notification unit 719, which are new components, will be described in detail.

  The delay execution unit 714 in the present embodiment uses a mobile node 301 via a predetermined location registration gateway based on the address of the mobile node 301 output from the delay control unit 718, the address of the location registration gateway 803, and the additional delay time. Adds a delay time to the data packet sent and received by. The difference from the first embodiment is that the output source of the delay time to be added is not the delay determination means 713 but the delay control means 718 and that the delay is added not by the location registration gateway unit but by the mobile node 301 unit. That is.

  The movement advance notification processing means 717 receives the movement advance notification signal transmitted from the location registration gateway 803, and includes the addresses of the movement source 301 and the destination location registration gateway included in this signal, and the mobile node 301. A notification indicating that the signal has been received is output to the delay control means 718. At this time, the location registration gateway 803 that is the transmission source of the notification is the location registration gateway 803 that is the destination of the mobile node 301 or the location registration gateway 803 that is the source of the migration. In the following, the location registration gateway to which the mobile node was connected before moving is referred to as “source location registration gateway”, and the location registration gateway to which the mobile node has been connected after moving is referred to as “destination location registration gateway”. As a way of expression, the connection destination may be an “access network” instead of the “location registration gateway”, and in that case, it is expressed in the same way by adding a movement source or a movement destination in front of the access network. To do.

  Note that the advance movement notification may include information elements included in the notification stored in the location registration request signal. In this case, when the mobility management server function realization unit 711 receives the location registration request signal storing the advance notification, the location registration gateway 803 that has transmitted the location registration request signal indicates the transfer destination of the data packet addressed to the mobile node 301. It shall be provided with a function to hold the switch to as necessary.

  The delay control unit 718 uses the addresses of the source location registration gateway 803 and the destination location registration gateway 803 included in the notification when receiving the advance movement notification from the advance movement notification processing unit 717. Then, from the mobility management server 703, the delay time when passing through each location registration gateway 803 is read from the delay storage device 720.

Also, the delay control means 718 compares the delay time (Dpmag) via the source location registration gateway read from the delay storage device 720 with the delay time (Dnmag) via the destination location registration gateway, and moves the destination. When the delay time via the location registration gateway is large (when Dpmag <Dnmag), the address of the mobile node 301 and the address of the source location management gateway 803 are added to the delay execution means 714. Output delay time. At this time, the additional delay time (Dadd) output to the delay execution means 714 is initially set to 0 or a sufficiently small value, and gradually changes to a large value while the following expression 3 is satisfied. I will let you. The delay control unit 718 outputs a notification indicating the completion of delay addition to the delay compensation completion notification unit 719 when Expression 3 is satisfied.
Dpmag + Dadd [i] <Dnmag (3)
In Expression 3, Dadd [i] indicates an additional delay time output to the delay execution unit 714 by the delay control unit 718 for the i-th time.

  For example, Dadd [i] can be updated as shown in the following Expression 4 at intervals of 0.1 seconds. However, the update interval and the update method may be other than those described here.

In Expression 4, MIN (x, y) means that x is output when x is less than or equal to y, and y is output otherwise.
Equation 4 is
1) When i = 0: Dadd [0] = 0
2) When i> 0: Dadd [i] = MIN (Dpmag × 0.5 + Dadd [i−1] × 1.5, Dnmag−Dpmag)
It is.

  On the other hand, if the delay time via the source location registration gateway is longer (Dpmag> Dnmag), the delay control means 718 sends the address of the mobile node 300 to the delay execution means 714 and the destination address. The address of the location management gateway 803 and the delay time to be added are output. At this time, the delay control unit 718 sets the additional delay time (Dadd) to be output to the delay execution unit 714 to Equation 5, and immediately outputs a notification indicating the completion of delay addition to the delay compensation completion notification unit 719.

Dadd [0] is the initial value of the delay time as described above. After notifying completion of delay addition to the delay compensation completion notifying means 719, the location registration request signal for the mobile node 301 subject to delay compensation is sent from the destination location registration gateway 803. As shown in Equation 6, Dadd [i] is updated, and this delay time is output to the delay execution means 714. As a result, the delay time added by Equation 5 is gradually reduced.
Dadd [0] = Dpmag−Dnmag Equation 5
Dadd [i] = Dadd [i−1] − (Dadd [0] × 0.1) Expression 6
However, the update interval and the update method are not limited to the example shown here.

  When the delay compensation completion notifying unit 719 receives the notification indicating the completion of delay compensation from the delay control unit 718, the delay compensation completion notifying unit 719 indicates to the location registration gateway 803, which is the transmission source of the movement advance notification, that the delay compensation has been completed. Send delay compensation completion notification.

  Next, the location registration gateway 803 in this embodiment will be described. FIG. 20 is a block diagram showing a configuration example of the location registration gateway in the present embodiment.

  As shown in FIG. 20, the location registration gateway 803 includes a location registration gateway function realizing unit 812, a delay measurement unit 813, a delay notification unit 814, a movement advance notification unit 817, and a delay compensation completion notification processing unit 818; A communication interface 810, a communication interface 811, a location registration gateway information storage device 822, and an access network delay storage device 821.

  In addition, about the position registration gateway 803, about the structure similar to 1st Embodiment, the same name and the same code | symbol are attached | subjected, and the detailed description is abbreviate | omitted in this embodiment. Further, in this embodiment, the movement advance notification means 817, the delay compensation completion notification processing means 818, and the location registration gateway information storage device 822, which are new components, will be described in detail.

  When the movement advance notification means 817 receives the movement request signal transmitted from the mobile node 301, it transmits a movement prior notification signal to the movement management server 703.

  Here, the movement request signal includes information related to the access network 600 of the movement source or movement destination to which the mobile node 301 is connected and identification information of the mobile node 301. Examples of the information related to the access network 600 of the movement source include an identifier assigned to the access network 600, an identifier of a wireless base station for wireless communication, and an identifier of the location registration gateway 803. All, some of these, or other identifiers may be included.

  The identifier of the mobile node 301 may be an identifier called HoA, MAC (Media Access Control) address, or NAI (Network Access Identifier).

  The movement advance notification means 817 acquires the address of the corresponding location registration gateway 803 from the location registration gateway information storage device 822 by using information about the access network 600 as a search key, The identifier of the node 301 and the address of the location registration gateway 803 are stored in the movement advance notification signal and transmitted to the movement management server 703.

  At this time, the movement advance notification means 817 uses the address of the location registration gateway 803 as the address of the destination location registration gateway when the information notified by the mobile node 301 is the information of the source access network 600. The movement pre-notification signal is transmitted using the address read from the location registration gateway information storage device 822 as the address of the location registration gateway of the movement source. On the other hand, when the information notified by the mobile node 301 is the information of the access network 600 of the movement destination, the address of the location registration gateway 803 is used as the address of the location registration gateway of the movement source, and the location registration gateway information storage device The movement pre-notification signal is transmitted using the address read from 822 as the address of the destination location registration gateway.

  The movement advance notification signal may be replaced with a location registration request signal by including a necessary information element in the location registration request signal. However, in this case, even if the mobility management server 703 receives the location registration response signal, the mobility management server 703 switches the data packet addressed to the mobile node 301 from the source location registration gateway 803 to the destination location registration gateway 803. Is put on hold.

  When the delay compensation completion notification processing unit 818 receives the delay compensation completion notification from the movement management server 703, the delay compensation completion notification processing unit 818 notifies the mobile node 301 of a movement preparation completion notification indicating that the delay compensation is completed and the movement preparation is ready. To do. The movement preparation completion notification may be an RA that stores information that can determine the completion of movement preparation, or may be another new signal.

  The location registration gateway information storage device 822 stores the addresses of a plurality of location registration gateways 803 in association with information related to the access network 600.

  Next, the mobile node 301 in this embodiment is demonstrated. FIG. 21 is a block diagram showing a configuration example of a mobile node in the present embodiment. The mobile node 301 of this embodiment requires not only a general IP terminal function but also other functions. FIG. 21 omits the configuration of a function as a general IP terminal, and a detailed description thereof is omitted.

  As illustrated in FIG. 21, the mobile node 301 includes a terminal control unit 351 including a movement request notification unit 311 and an interface control unit 312, and a communication interface 310. Although not shown in the figure, it is assumed that the terminal control unit 351 is provided with a storage unit for temporarily storing data when executing processing related to the present invention.

  The communication interface 310 is connected to the access network 600, transmits and receives packets, and mainly exchanges packets with the location registration gateway 803. The number of communication interfaces 310 provided in the mobile node 301 is not limited to one and may be plural.

  Here, a case where a plurality of communication interfaces 310 are provided and a case where one communication interface 310 is provided will be described separately. First, a case where a plurality of communication interfaces 310 are provided will be described. In order to distinguish and describe the plurality of communication interfaces 310, it is assumed that communication interfaces 310a and 310b are provided.

  When one communication interface 310a among a plurality of communication interfaces 310 is connected to a certain access network 600 (reference numeral 600d) and is in a communicable state, another communication interface 310b is a new access network. It is assumed that it is connected to 600 (reference number is 600e). Subsequently, it is assumed that the mobile node 310 has moved to a position with better radio sensitivity in the newly connected access network 600e than in the currently connected access network 600d. In this case, the movement request notifying unit 311 registers a movement request signal storing information on the connected access network 600d that is the movement source together with the identifier of the mobile node 301, in the position registration of the newly connected access network 600e. Transmit to the gateway 803.

  When the interface control unit 312 receives a movement preparation completion notification from the location registration gateway 803, the interface control unit 312 controls packet routing so that the packet is transmitted from the communication interface 310 connected to the access network 600 to which the signal is transmitted. To do.

  Next, a case where the mobile node 301 has one communication interface 310 will be described. Prior to connection to the new access network 600e, the movement request notification means 311 transmits a movement request signal to the location registration gateway 803 arranged in the currently connected access network 600d. In the movement request signal, information on the access network 600e as the movement destination is stored together with the identifier of the mobile node 301.

  In this case, the mobile node 301 needs to know information about the access network 600e to be moved before connecting to the new access network 600e. For example, in many wireless communication systems, the identifier of the radio base station is The identifier can be obtained without connecting to the base station. When there is one communication interface 310, the interface control means 312 need not be provided.

  Note that the movement advance notification processing means 717, delay control means 718, delay compensation completion notification means 719, movement advance notification means 817, delay compensation completion notification processing means 818, movement request notification means 311 and interface control means 312 are each a processor. Can be virtually configured by executing a program. However, some or all of them can be configured by hardware such as a dedicated circuit. The location registration gateway information storage device 822 can be configured by a device capable of recording information, such as a semiconductor memory or a hard disk drive.

  Next, the operation procedure of the mobility management server 703 in this embodiment will be described. FIG. 22 is a flowchart showing an operation procedure when the movement management server in this embodiment receives a movement advance notice.

  Since the processing until the delay time of the route via each location registration gateway 803 is recorded in the delay storage device 720 is the same as that in the first embodiment, detailed description thereof is omitted. Here, the flow of processing when the advance movement notification processing that is the difference is received will be described.

  First, when the movement management server 703 receives the movement advance notification by the movement advance notification processing means 717 of the movement management server 703 (step j1), the delay control means 718 is input from the movement advance notification processing means 717 in step j2. The delay time of communication via each location registration gateway is read out from the delay storage device 720 using the address of the location registration gateway 803 of the source and destination of the mobile node 301 included in the previous notification of movement.

  Subsequently, in step j3, the delay control means 718 compares the delay time of communication via the movement source and the position registration gateway of the movement destination with the read delay time. As a result of the comparison, the process branches at step j4.

  If the result of the comparison in step j4 shows that the destination delay time is greater, the procedure proceeds to the procedure for “Y” meaning “Yes”, and step j5 and subsequent steps are processed. If it is larger, the procedure proceeds to the procedure in the case of “N” which means No, and step j8 and subsequent steps are processed. In FIG. 22, if the delay time of the movement source and the movement destination is equal in step j4, the process proceeds to step j8, but may proceed to step j5.

  In the case of “Y” in step j4, the process proceeds to step j5, and the movement management server 703 performs a process of adding a delay time to the communication via the movement source location registration gateway by the action of the delay control means 718 and the delay execution means 714. Do. At this time, as shown in Expression 4, the additional delay time is increased stepwise.

  In step j6, the mobility management server 703 determines whether or not the process for increasing the delay time has been completed. Formula 3 is used for the determination. When the process for adding the delay time is completed, the process proceeds to 'Y', and step j7 is processed. On the other hand, if it has not been completed, the process proceeds to 'N' and returns to step j5, and the process of adding the delay time is performed again. In step j 7, the mobility management server 703 transmits a delay compensation completion notification to the source location registration gateway 803 by the action of the delay compensation completion notification means 719.

  On the other hand, if “N” in step j4, the process proceeds to step j8, and the mobility management server 703 adds a delay time to the communication via the destination location registration gateway by the action of the delay control unit 718 and the delay execution unit 714. Process. At that time, for example, the delay time shown in Expression 5 is added. Thereafter, in step j9, a delay compensation completion notice is immediately transmitted to the destination location registration gateway 803.

  Subsequently, in step j10, the mobility management server 703 waits for a location registration request signal from the destination location registration gateway 803, and then performs processing for gradually reducing the added delay time according to Equation 6. In this process, as described above, it is better to wait until the location registration request signal is received, but it is also possible not to wait.

  Furthermore, in step j11, the mobility management server 703 evaluates whether or not the process for reducing the delay has been completed (whether the delay time added in step j8 has become 0). Proceed and complete the process. If not completed, the process proceeds to 'N' and returns to step j10, and the process of reducing the added delay is performed again.

  Next, the operation procedure of the location registration gateway 803 in this embodiment will be described with reference to FIGS.

  Similar to the description of the operation procedure of the mobility management server 703, the description of the processing with the same configuration as that of the first embodiment is omitted. Description will be focused on processing related to at least one of the completion notification processing unit 818 and the location registration gateway information storage device 822.

  FIG. 23 is a flowchart showing an operation procedure when the location registration gateway according to the present embodiment receives a movement request signal from a mobile node. An operation procedure until the location registration gateway 803 receives a movement request signal from the mobile node 301 and transmits a movement advance notification signal to the movement management gateway 703 will be described.

  In step k1, when the location registration gateway 803 receives the movement request signal from the mobile node 301, the location registration gateway information storage device based on the information about the access network 600 stored in the movement request signal by the movement advance notification means 817. As a result, the address of the location registration gateway 803 of the source and destination of the mobile node 301 is acquired (step k2).

  Thereafter, in step k <b> 3, the location registration gateway 803 transmits to the mobility management server 703 a movement advance notification signal storing the addresses of the source and destination location registration gateways 803 and the identification information of the mobile node 301.

  FIG. 24 is a flowchart showing an operation procedure when the location registration gateway in this embodiment receives a delay compensation completion notice. An operation procedure when the location registration gateway 803 receives a delay compensation completion notification from the mobility management server 703 will be described.

  When the location registration gateway 803 receives the delay compensation completion notification (step l1), the location registration gateway 803 transmits to the mobile node 301 a movement preparation completion notification in which information indicating that the delay compensation is completed and preparation for movement is set (step 11). l2).

  Next, the operation procedure of the mobile node 301 in the present embodiment will be described using FIG. 25 and FIG. FIG. 25 is a flowchart showing an operation procedure until the mobile node transmits a movement request signal in this embodiment.

  In step m1, the mobile node 301 determines whether or not to periodically transmit a movement request signal. If it is determined that the movement request signal should be transmitted, the process proceeds to 'Y', and the movement request signal is transmitted by the action of the movement request notification means 311 (step m2). On the other hand, if it is not determined that it should be transmitted, the process proceeds to ‘N’ and returns to step m1 to continue the signal transmission determination process periodically.

  The conditions for determining that the above-described movement request signal should be transmitted and the communication interfaces used for transmitting the movement request signal depend on whether the number of communication interfaces 310 included in the mobile node 301 is one or more.

  When the mobile node 301 includes a plurality of communication interfaces 310, the mobile node 301 transmits a movement request notification from the communication interface 310 connected to the movement destination access network 600 at the timing when the movement node 301 is connected to the movement destination access network 600. To do. In this case, connection to the destination access network 600 is a trigger for sending a movement request signal.

  On the other hand, when the mobile node 301 has one communication interface 310, the mobile node 301 can detect a radio base station with sufficient electric field strength while connected to the access network 600 of the movement source. As described above, when the access network 600 suitable for the destination is detected and it is determined to change the connection destination, a movement request notification is transmitted from the communication interface 310 connected to the current access network 600.

  The timing for determining the movement request signal transmission is not limited to that based on the strength of the electric field strength described above, but may be other timings such as when a specific application is activated. Various timings can be considered, and since the relevance to the characteristics of the present invention is low, detailed description thereof is omitted here.

  FIG. 26 is a flowchart showing an operation procedure when the mobile node according to the present embodiment receives a movement preparation completion notification.

  In step n1, the mobile node 301 receives a movement preparation completion notification. This notification indicates that the movement management server 703 has completed the compensation for the delay difference between the movement source communication path and the movement destination communication path.

  When the mobile node 301 includes a plurality of communication interfaces 310, the interface control means 312 uses the communication interface 310 to which the mobile node 301 sends out a data packet in step n2 as a trigger in response to the signal. The communication interface 310 connected to the communication interface 310 is switched to the communication interface 310 connected to the destination access network 600. At the same time, the communication interface 310 connected to the source access network 600 is disconnected.

  On the other hand, when the mobile node 301 includes one communication interface 310, the interface control means 312 moves the communication interface 310 from the source access network 600 in step n2 when the mobile preparation completion notification is received. Disconnect and connect to the destination access network 600.

  As described above, in the present embodiment, there is a difference in processing contents between the case where the mobile node 301 includes a plurality of communication interfaces 310 and the case where the mobile node 301 includes a single communication interface 310. Even in the case of having 310, the same processing as in the case of having one communication interface 310 may be performed.

  Up to this point, the configuration and operation procedure have been individually described for each of the mobility management server 703, the location registration gateway 803, and the mobile node 301 in the present embodiment. In the following, an example of processing when combining them will be described with reference to the sequence diagrams of FIGS.

  FIG. 27 is a sequence diagram when the mobile node 301 includes a plurality of communication interfaces 310 and the destination access network 600 has a longer delay time than the source access network 600.

  FIG. 28 is a sequence diagram when the mobile node 301 includes a plurality of communication interfaces 310 and the destination access network 600 has a smaller delay time than the source access network 600.

  FIG. 29 is a sequence diagram in the case where the mobile node 301 includes one communication interface 310 and the destination access network 600 has a longer delay time than the source access network 600.

  FIG. 30 is a sequence diagram in the case where the mobile node 301 includes one communication interface 310 and the destination access network 600 has a smaller delay time than the source access network 600.

  27 to 30, it is assumed that the mobile node 301 moves from the access network 600a under the location registration gateway 803a to the access network 600b under the location registration gateway 803b.

  First, a case where the mobile node 301 includes a plurality of communication interfaces 310 and the destination access network 600 has a longer delay time than the source access network 600 will be described with reference to FIG. . Here, the communication interface 310 provided in the mobile node 301 is the communication interface # 1 and the communication interface # 2, which are denoted as IF1 and IF2 in FIG.

  As an initial state, the mobile node 301 communicates with the communication node 400 via the location registration gateway 803a disposed in the access network 600a using the communication interface # 1 (step o1). The mobile node 301 finds a new access network 600b and connects to the network via the communication interface # 2 (step o2).

  Thereafter, the mobile node 301 transmits a movement request signal from the communication interface # 2 to the location registration gateway 803b according to the flowchart shown in FIG. 25 (step o3). As described above, this signal may be a unique signal or information necessary for the RS may be stored.

  Upon receiving the movement request signal from the mobile node 301, the location registration gateway 803b transmits a movement advance notification to the movement management server 703 in accordance with the flowchart of FIG. 23 (step o4). The movement advance notification stores the address of the location registration gateway 803b as the address of the destination location registration gateway, the address of the location registration gateway 803a as the address of the source location registration gateway, and the identifier of the mobile node 300. .

  When the movement management server 703 receives the movement advance notification from the location registration gateway 803b, the movement management server 703 performs delay compensation processing according to the flowchart of FIG. 22 (step o5), and after the completion, the delay management completion notification is sent to the location registration gateway 803b. Then, it is transmitted (step o6). Here, since it is assumed that the delay time at the destination is large, the delay compensation process is a process of gradually adding delays to the source communication path, and sending a delay compensation completion notification after matching the delay time at the destination. It becomes.

  When the location registration gateway 803b receives the delay compensation completion notification from the mobility management server 703, the location registration gateway 803b transmits a migration preparation completion notification to the mobile node 301 according to the flowchart shown in FIG. 24 (step o7). This movement preparation completion notification may be an RA storing information indicating completion of delay compensation.

  When the mobile node 301 receives the movement preparation completion notification from the location registration gateway 803b, the location registration gateway, which is not limited to the case of this embodiment, uses a location trigger signal (RS shown in FIG. 27) as a trigger for transmission of the location registration request signal. It transmits to the registration gateway 803b. Thereafter, a series of position registration processes according to the example shown in FIG. 32 are performed (step o8).

  After step o8, the mobile node 301 controls the communication interface according to the flowchart shown in FIG. That is, after setting the data packet to be transmitted from the communication interface # 2, the communication interface # 1 is disconnected from the access network 600a (step o9).

  As a result, the communication path is switched from the communication interface # 2 to the access network 600b (location registration gateway 803b) to the mobility management server 703 to the communication node 400 (step o10). With the above-described processing, a change in communication delay time can be suppressed before and after the movement of the mobile node 301.

  Next, with reference to FIG. 28, a case where the mobile node 301 includes a plurality of communication interfaces 310 and the destination access network 600b has a smaller delay time than the source access network 600a will be described. To do. As described with reference to FIG. 27, the communication interface 310 provided in the mobile node 301 is the communication interface # 1 and the communication interface # 2. In FIG. 28, they are denoted as IF1 and IF2. Yes.

  As an initial state, the mobile node 301 communicates with the communication node 400 via the location registration gateway 803a arranged in the access network 600a using the communication interface # 1 (step p1).

  The mobile node 301 discovers a new access network 600b and connects to the network through the communication interface # 2 (step p2). Thereafter, the mobile node 301 transmits a movement request signal from the communication interface # 2 to the location registration gateway 803b according to the flowchart shown in FIG. 25 (step p3). As described above, this signal may be a unique signal or information necessary for the RS may be stored.

  Upon receiving the movement request signal from the mobile node 301, the location registration gateway 803b transmits a movement advance notification to the movement management server 703 according to the flowchart shown in FIG. 23 (step p4). The movement advance notification stores the address of the location registration gateway 803b as the address of the destination location registration gateway, the address of the location registration gateway 803a as the address of the source location registration gateway, and the identifier of the mobile node 300. .

  When the movement management server 703 receives the advance movement notification from the location registration gateway 803b, the movement management server 703 performs a delay compensation process according to the flowchart shown in FIG. 22 (step p5). Transmit to 803b (step p6). Here, since it is assumed that the delay time at the movement destination is small, the delay compensation process is a process of adding a delay corresponding to the difference from the movement source to the communication path at the movement destination and immediately transmitting a delay compensation completion notification.

  When the location registration gateway 803b receives the delay compensation completion notification from the mobility management server 703, the location registration gateway 803b transmits a migration preparation completion notification to the mobile node 301 according to the flowchart shown in FIG. 24 (step p7). The movement preparation completion notification may be an RA that stores information indicating completion of delay compensation.

  When the mobile node 301 receives the movement preparation completion notification from the location registration gateway 803b, the location registration gateway, not limited to the case of the present embodiment, uses the location trigger signal (RS shown in FIG. 28) as a trigger for transmission of the location registration request signal. It transmits to the registration gateway 803b. Thereafter, a series of location registration processes according to the example shown in FIG. 32 are performed (step p8).

  After step p8, the mobile node 301 controls the communication interface according to the flowchart shown in FIG. That is, after setting the data packet to be transmitted from the communication interface # 2, the communication interface # 1 is disconnected from the access network 600a (step p9).

  As a result, the communication path is switched from the communication interface # 2 to the access network 600b (location registration gateway 803b) to the mobility management server 703 to the communication node 400 (step p10). With the above-described processing, a change in communication delay time can be suppressed before and after the movement of the mobile node 301.

  Then, after the communication path is switched as in step p10, the mobility management server 703 performs a process of gradually reducing the delay added to the new communication path (step p11). This process is a process corresponding to step j10 and step j11 in the flowchart shown in FIG. 22, and is actually a process started after the position registration process in step p8.

  Next, with reference to FIG. 29, a case where the mobile node 301 includes one communication interface 310 and the destination access network 600b has a longer delay time than the source access network 600a will be described. To do.

  As an initial state, the mobile node 301 communicates with the communication node 400 using the communication interface 310 via the location registration gateway 803a disposed in the access network 600a (step q1).

  When the mobile node 301 discovers a new access network 600b (step q2), a mobile request signal storing information on the discovered access network 600b is placed in the connected access network 600a according to the flowchart shown in FIG. To the location registration gateway 803a (step q3). As in the description so far, this signal may be a unique signal or information necessary for the RS may be stored.

  Upon receiving the movement request signal from the mobile node 301, the location registration gateway 803a transmits a movement advance notification to the movement management server 703 according to the flowchart shown in FIG. 23 (step q4). The movement advance notification stores the address of the location registration gateway 803b as the address of the destination location registration gateway, the address of the location registration gateway 803a as the address of the source location registration gateway, and the identifier of the mobile node 300. .

  When the movement management server 703 receives the movement advance notification from the location registration gateway 803a, the movement management server 703 performs a delay compensation process according to the flowchart shown in FIG. 22 (step q5), and after the completion, the delay management completion notification is sent to the location registration gateway. Transmit to 803a (step q6). Here, since it is assumed that the delay time of the movement destination is large, the delay compensation process gradually adds a delay to the communication path at the movement source, and after the delay time at the movement destination coincides, transmits a delay compensation completion notification. It becomes processing.

  When the location registration gateway 803a receives the delay compensation completion notification from the mobility management server 703, the location registration gateway 803a performs processing according to the flowchart shown in FIG. Since there is only one communication interface 310, a movement preparation completion notification is transmitted to the mobile node 301 (step q7). The movement preparation completion notification may be an RA that stores information indicating completion of delay compensation.

  When receiving the movement preparation completion notification from the location registration gateway 803a, the mobile node 301 controls the communication interface 310 according to the flowchart of FIG. That is, the communication interface 310 is connected to the destination access network 600b (step q8). Thereafter, each of the mobile node 301, the location management gateway 803b, and the migration management server 703 performs location registration processing according to the example shown in FIG. 32 (step q9), so that the mobile node 301 can access the destination. Data packets can be communicated with the communication node 400 via the network 600b (step q10).

  Next, a case where the mobile node 301 includes one communication interface 310 and the destination access network 600b has a smaller delay time than the source access network 600a will be described with reference to FIG. To do.

  As an initial state, the mobile node 301 communicates with the communication node 400 using the communication interface 310 via the location registration gateway 803a arranged in the access network 600a (step r1).

  When the mobile node 301 discovers a new access network 600b (step r2), a mobile request signal storing information of the discovered access network 600b is arranged in the connected access network 600a according to the flowchart shown in FIG. To the location registration gateway 803a (step r3). As in the description so far, this signal may be a unique signal or information necessary for the RS may be stored.

  When receiving the movement request signal from the mobile node 301, the location registration gateway 803a transmits a movement advance notice to the movement management server 703 according to the flowchart shown in FIG. 23 (step r4). The movement advance notification stores the address of the location registration gateway 803b as the address of the destination location registration gateway, the address of the location registration gateway 803a as the address of the source location registration gateway, and the identifier of the mobile node 301. .

  When the movement management server 703 receives the movement advance notification from the location registration gateway 803a, the movement management server 703 performs a delay compensation process according to the flowchart shown in FIG. 22 (step r5), and after the completion, the delay management completion notification is sent to the location registration gateway. Transmit to 803a (step r6). Here, since it is assumed that the delay time of the movement destination is small, the delay compensation process adds a delay time corresponding to the difference between the communication path delay and the movement source delay at the movement destination, and immediately transmits a delay compensation completion notification. It becomes.

  When the location registration gateway 803a receives the delay compensation completion notification from the mobility management server 703, the location registration gateway 803a performs processing according to the flowchart shown in FIG. 24, and transmits a migration preparation completion notification to the mobile node 301 (step r7). The movement preparation completion notification may be, for example, an RA that stores information indicating completion of delay compensation.

  When receiving the movement preparation completion notification from the location registration gateway 803a, the mobile node 301 controls the communication interface according to the flowchart of FIG. That is, the communication interface 310 is connected to the destination access network 600b (step r8). Thereafter, each of the mobile node 301, the location management gateway 803b, and the mobility management server 703 performs location registration processing according to the example shown in FIG. 32 (step r9), so that the mobile node 301 accesses the destination Data packets can be communicated with the communication node 400 via the network 600b (step r10).

  After the communication path is switched as in step r10, the mobility management server 703 performs a process of gradually reducing the delay added to the new communication path (step r11). This process corresponds to step j10 and step j11 in the flowchart shown in FIG. 22, and is actually a process started after the position registration process in step p9.

  In this embodiment, instead of performing delay compensation for matching the communication delay time in units of location registration gateways 803 as in the first embodiment, the mobile node only moves when the mobile node 301 moves. The communication delay is compensated in 301 units. Therefore, it is possible to reduce the load of keying processing for performing delay compensation in the mobility management server 703.

  In addition, the mobile node 301 can suppress a change in communication delay at the moment of movement, and at the same time, can enjoy the merit of communication with low delay when located in a network with a small delay. As a result, for example, the maximum communication rate for TCP communication is determined based on the delay time, and therefore communication at a higher rate is possible when performing communication using TCP. It is also advantageous when a delay sensitive application such as a TV phone is used.

  In the first to fourth embodiments described above, the node on the network side where the location registration gateway exists is located as in the case of PMIPv6 described in Non-Patent Document 1 because it is suitable for stable delay measurement. Although the description has been made on the mobility management protocol for performing registration, the present invention can also be applied to a mobility management protocol for performing location registration by a mobile node, such as MIPv6 shown in Non-Patent Document 3. In this case, the mobile node has the function provided in the location registration gateway of the present invention. It is also obvious that the present invention is applicable to other network-driven mobility management protocols such as PMIPv4.

  According to the present invention, it is possible to obtain an effect that it is possible to avoid a communication failure caused by a change in communication delay that may occur when a mobile node moves between location registration gateways. Note that it is also an important feature that the mobile node does not need to be changed to obtain this effect. This is because a mobile communication system using a network-driven mobility management protocol such as PMIPv6 or PMIPv4 is intended to minimize the addition of functions for mobility management to the mobile node. This is because the meaning of adopting a network-driven mobility management protocol will be greatly diminished if such changes are required.

  In this embodiment, each device is provided with a communication interface. However, it is only necessary to be able to transmit and receive data by connecting to at least an external device, and is indispensable for performing the processing that characterizes the present invention. is not.

  The present invention can be applied to a mobile communication system to which PMIPv6 or PMIPv4 is applied. PMIPv6 and PMIPv4 are adopted as mobility management protocols in various standardization organizations such as 3GPP, 3GPP2, and WiMAX Forum. Therefore, the present invention can be applied to mobile communication systems formulated by those standardization organizations and is effective.

It is a block diagram which shows the example of 1 structure of the mobile communication system in 1st Embodiment. It is a block diagram which shows the example of 1 structure of the movement management server in 1st Embodiment. It is a figure which shows an example of a delay information table. It is a block diagram which shows one structural example of the location registration gateway in 1st Embodiment. It is a figure which shows an example of the delay information table between a movement management server and a location registration gateway. It is a figure which shows an example of the delay information table between a location registration gateway and a mobile node. It is a flowchart which shows the operation | movement procedure of the movement management server in 1st Embodiment. It is a flowchart which shows the process until the location registration gateway in 1st Embodiment transmits a location registration request signal. It is a flowchart which shows the process at the time of the location registration gateway in 1st Embodiment receiving the location registration response signal. It is a block diagram which shows the example of 1 structure of the movement management server in 2nd Embodiment. It is a block diagram which shows the example of 1 structure of the location registration gateway in 2nd Embodiment. It is a flowchart which shows the operation | movement procedure of the movement management server in 2nd Embodiment. It is a flowchart which shows the process at the time of the location registration gateway in 2nd Embodiment receiving the location registration response signal. It is a block diagram which shows one structural example of the movement management server in 3rd Embodiment. It is a figure which shows an example of the delay information table in 3rd Embodiment. It is a block diagram which shows the example of 1 structure of the location registration gateway in 3rd Embodiment. It is a flowchart which shows the operation | movement procedure at the time of the mobility management server in 3rd Embodiment measuring delay. It is a flowchart which shows the operation | movement procedure at the time of the location registration gateway in 3rd Embodiment transmitting the location registration request signal which stored delay information. It is a block diagram which shows the example of 1 structure of the movement management server in 4th Embodiment. It is a block diagram which shows the example of 1 structure of the location registration gateway in 4th Embodiment. It is a block diagram which shows one structural example of the mobile node in 4th Embodiment. It is a flowchart which shows the operation | movement procedure at the time of the movement management server in 4th Embodiment receiving a movement advance notification. It is a flowchart which shows the operation | movement procedure at the time of the location registration gateway in 4th Embodiment receiving the movement request signal from a mobile node. It is a flowchart which shows the operation | movement procedure at the time of the position registration gateway in 4th Embodiment receiving delay compensation completion notification. It is a flowchart which shows the operation | movement procedure until the mobile node in 4th Embodiment transmits a movement request signal. It is a flowchart which shows the operation | movement procedure at the time of the mobile node in 4th Embodiment receiving a movement preparation completion notification. FIG. 10 is a sequence diagram showing an operation procedure when a mobile node moves to an access network having a plurality of communication interfaces and a larger delay in the fourth embodiment. In 4th Embodiment, it is a sequence diagram which shows the operation | movement procedure at the time of a mobile node moving to an access network provided with a some communication interface and with a smaller delay. In 4th Embodiment, it is a sequence diagram which shows the operation | movement procedure at the time of a mobile node moving to an access network with one communication interface and a larger delay. In 4th Embodiment, it is a sequence diagram which shows the operation | movement procedure at the time of a mobile node moving to an access network provided with one communication interface and with a smaller delay. It is a figure which shows the mobile communication system to which PMIPv6 is applied. FIG. 3 is a sequence diagram when a mobile node is connected to an access network in a mobile communication system to which PMIPv6 is applied. FIG. 10 is a sequence diagram when a mobile node moves between access networks in a mobile communication system to which PMIPv6 is applied. In a mobile communication system, a mobility management server is connected to different networks. It is a figure which shows the case where delay time becomes small by movement of a mobile node. It is a figure which shows the case where delay time becomes large by movement of a mobile node.

Explanation of symbols

300, 301 Mobile node 310 Communication interface 311 Movement request notification means 312 Interface control means 400 Communication node 500 Network 600 Access network 700, 701, 702, 703 Mobility management server 800, 801, 802, 803 Location registration gateway 710 Communication interface 711 Movement Management server function realization means 712 Delay collection means 713 Delay determination means 714, 816 Delay execution means 715, 814 Delay notification means 716, 813 Delay measurement means 717 Movement pre-notification processing means 718 Delay control means 719 Delay compensation completion notification means 720, 820 Delay storage device 810, 811 Communication interface 812 Location registration gateway function realization means 815 Additional delay information acquisition means 817 Pre-movement notification 818 delay compensation completion notification processing unit 821 access network delay line memory 822 location registration gateway information storage device

Claims (40)

When connected to a mobile node via a network, a plurality of gateway devices that relay data transmitted / received by the mobile node and transmit delay information that is information indicating a communication delay time of a communication path through which the data is transmitted When,
Collecting delay information received from the plurality of gateway devices via the network, and based on the collected delay information, a communication path between the mobile node and the communication partner that differs depending on the gateway device to which the mobile node is connected A management server that controls the communication delay time in order to reduce the difference in communication delay time;
A mobile communication system. The mobile communication system according to claim 1, wherein
Each of the plurality of gateway devices measures both or one of the communication delay time between the management server and the own device and the communication delay time between the own device and the mobile node, and determines the measured communication delay time. The mobile communication system which transmits the said delay information based on the said management server. The mobile communication system according to claim 1, wherein
Each of the plurality of gateway devices, before connecting to the mobile node, either or both of a communication delay time between the management server and the own device and a communication delay time between the own device and the mobile node. A mobile communication system that retains in advance and transmits the delay information based on the retained communication delay time to the management server. The mobile communication system according to claim 2,
Each of the plurality of gateway devices uses a signal for registering an address independent of the network and an address dependent on the network for measuring a communication delay time between the management server and the own device. . The mobile communication system according to claim 2 or 3,
Each of the plurality of gateway devices stores the delay information in a signal for registering an address independent of the network and an address dependent on the network when transmitting the delay information to the management server. Is transmitted to the management server. The mobile communication system according to claim 1, wherein
The management server stores delay information related to each of a source gateway device that is a gateway device to which the mobile node was connected before moving and a destination gateway device that is a gateway device to which the mobile node was connected after moving. The movement source delay information that is the delay information related to the movement source gateway apparatus is compared with the movement destination delay information that is the delay information related to the movement destination gateway apparatus. Is smaller than the destination delay information, a delay difference time that is a communication delay time corresponding to a difference between the source delay information and the destination delay information for communication via the source gateway apparatus A mobile communication system that adds in stages. The mobile communication system according to claim 6, wherein
The management server completes the delay addition process when the source delay information and the destination delay information become equal as a result of stepwise addition of the delay difference time for communication via the source gateway device. A mobile communication system for notifying the source gateway apparatus of the fact that it has been performed. The mobile communication system according to claim 1, wherein
The management server stores delay information related to each of a source gateway device that is a gateway device to which the mobile node was connected before moving and a destination gateway device that is a gateway device to which the mobile node was connected after moving. The movement source delay information, which is the delay information related to the movement source gateway device, is compared with the movement destination delay information, which is the delay information related to the movement destination gateway device. Is smaller than the movement source delay information, a delay difference time which is a communication delay time corresponding to a difference between the movement source delay information and the movement destination delay information for communication via the movement destination gateway device Add a mobile communication system. The mobile communication system according to claim 8,
The mobile communication system, wherein the management server notifies the destination gateway device that the delay addition processing has been completed after starting the addition of the delay difference time to the communication via the destination gateway device. The mobile communication system according to claim 8,
When the management server confirms that the mobile node has moved under the destination gateway device after starting to add the delay difference time to the communication via the destination gateway device, the management server responds to the communication. A mobile communication system that reduces the delay difference time to be added stepwise. This is a delay time to be added to delay information, which is information indicating the communication delay time of a communication path passing through its own device, by relaying data transmitted and received with the communication partner when the mobile node is connected via a network. A plurality of gateway devices that receive the additional delay time information and add the additional delay time to the delay information;
When the delay information received via the network from the plurality of gateway devices is collected, the delay between the mobile node and the communication partner varies depending on the gateway device to which the mobile node is connected based on the collected delay information A management server that obtains the additional delay time of the communication path passing through each gateway device in order to reduce the difference in information, and transmits information on the additional delay time corresponding to each of the plurality of gateway devices to each gateway device When,
A mobile communication system. When connected to a mobile node via a network, a plurality of gateway devices that relay data transmitted / received by the mobile node to / from a communication partner;
Collecting delay information, which is information indicating the communication delay time of a communication path from the own device to each of the plurality of gateway devices, and depending on the gateway device to which the mobile node is connected based on the collected delay information A management server for controlling the communication delay time in order to reduce a difference in communication delay time of a communication path between the node and the communication partner;
A mobile communication system. A server device connected via a network to a plurality of gateway devices that relay data exchanged between a mobile node and a communication partner via a network,
A storage unit for storing delay information which is information indicating a communication delay time of a communication path through which the data is transmitted;
The delay information received from the plurality of gateway devices via the network is stored in the storage unit, and the mobile node differs depending on the gateway device to which the mobile node is connected based on the delay information stored in the storage unit And a control unit for controlling the communication delay time in order to reduce a difference in communication delay time of a communication path between the communication partner and the communication partner;
A server device. The server device according to claim 13,
The control unit obtains delay information related to each of a source gateway device that is a gateway device to which the mobile node was connected before moving and a destination gateway device that is a gateway device to which the mobile node was connected after moving. The movement source delay information that is the delay information related to the movement source gateway apparatus is compared with the movement destination delay information that is the delay information related to the movement destination gateway apparatus. Is smaller than the destination delay information, a delay difference time that is a communication delay time corresponding to a difference between the source delay information and the destination delay information for communication via the source gateway apparatus A server device that is added step by step. The server device according to claim 14, wherein
The controller adds the delay difference time stepwise to the communication via the source gateway device, and as a result, when the source delay information and the destination delay information become equal, the delay addition process is completed. A server device that notifies the source gateway device of the fact that it has been performed. The server device according to claim 13,
The control unit obtains delay information related to each of a source gateway device that is a gateway device to which the mobile node was connected before moving and a destination gateway device that is a gateway device to which the mobile node was connected after moving. The movement source delay information, which is the delay information related to the movement source gateway device, is compared with the movement destination delay information, which is the delay information related to the movement destination gateway device. Is smaller than the movement source delay information, a delay difference time which is a communication delay time corresponding to a difference between the movement source delay information and the movement destination delay information for communication via the movement destination gateway device Add the server device. The server device according to claim 16, wherein
The control unit, after starting to add the delay difference time for communication via the destination gateway device, notifies the destination gateway device that the delay addition processing has been completed. The server device according to claim 16, wherein
When the control unit confirms that the mobile node has moved under the destination gateway device after starting to add the delay difference time to the communication via the destination gateway device, the control unit responds to the communication. A server apparatus that reduces the delay difference time added in a stepwise manner. A server device connected via a network to a plurality of gateway devices that relay data exchanged between a mobile node and a communication partner via a network,
A storage unit for storing delay information which is information indicating a communication delay time of a communication path through which the data is transmitted;
The delay information received via the network from the plurality of gateway devices is collected and stored in the storage unit, and based on the delay information stored in the storage unit, the gateway device to which the mobile node connects, A plurality of gateway devices for obtaining an additional delay time which is a delay time to be added to the delay information of a communication path passing through each gateway device in order to reduce a difference in the delay information between the mobile node and the communication partner; A control unit that transmits information of the additional delay time corresponding to each of the gateway devices,
A server device. A server device connected via a network to a plurality of gateway devices that relay data exchanged between a mobile node and a communication partner via a network,
A storage unit for storing delay information which is information indicating a communication delay time of a communication path through which the data is transmitted;
Collecting the delay information of the communication path from its own device to each of the plurality of gateway devices and storing it in the storage unit, and based on the delay information stored in the storage unit, by the gateway device to which the mobile node is connected A control unit that controls the communication delay time to reduce a difference in communication delay time between different communication paths of the mobile node and the communication partner;
A server device. A storage unit for storing delay information which is information indicating a communication delay time of a communication path through which data is transmitted via the own device;
When connected to a mobile node via a network, the mobile node relays data transmitted / received to / from a communication partner, collects the delay information of a communication path through which the data is transmitted, and stores the delay information in the storage unit. The management server that controls the communication delay time to reduce the difference in communication delay time between the mobile node and the communication partner before and after the movement of the mobile node, the delay information stored in the storage unit is transferred to the network. A control unit for transmitting via
A gateway device. The gateway device according to claim 21, wherein
The control unit measures the communication delay time between the management server and the own device and / or the communication delay time between the own device and the mobile node, and the delay information based on the measured communication delay time. Is transmitted to the management server. The gateway device according to claim 21, wherein
Before connecting to the mobile node, the control unit holds in advance both a communication delay time between the management server and the mobile device and / or a communication delay time between the mobile device and the mobile node, A gateway device that transmits the delay information based on the held communication delay time to the management server. The gateway device according to claim 22,
The control unit uses a signal for registering an address independent of the network and an address dependent on the network for measuring a communication delay time between the management server and the own device. The gateway device according to claim 22 or 23,
When transmitting the delay information to the management server, the control unit stores the delay information in a signal for registering an address independent of the network and an address dependent on the network, and sends the signal to the management server To the gateway device. A storage unit for storing delay information which is information indicating a communication delay time of a communication path through which data is transmitted via the own device;
When connecting to a mobile node via a network, the mobile node relays data transmitted and received with a communication partner, and information on an additional delay time, which is a delay time to be added to the delay information of the communication path passing through the own device, When receiving from the management server that controls the communication delay time in order to reduce the difference in communication delay time of the communication path between the mobile node and the communication partner before and after the movement of the mobile node, the additional delay time is stored in the memory A control unit to add to the delay information stored in the unit;
A gateway device. A communication control method by a server device connected via a network to a plurality of gateway devices that relay data transmitted and received by a mobile node via a network with a communication partner,
Collecting delay information that is information indicating a communication delay time of a communication path through which the data is transmitted from the plurality of gateway devices via the network,
A communication that controls the communication delay time in order to reduce a difference in communication delay time of a communication path between the mobile node and the communication partner, which differs depending on the gateway device to which the mobile node is connected, based on the collected delay information. Control method. The communication control method according to claim 27,
Obtaining delay information related to each of a source gateway device that is a gateway device to which the mobile node was connected before moving and a destination gateway device that is a gateway device to which the mobile node was connected after moving;
Comparing source delay information, which is delay information related to the source gateway device, and destination delay information, which is delay information related to the destination gateway device;
As a result of comparison, if the source delay information is smaller than the destination delay information, this corresponds to the difference between the source delay information and the destination delay information for communication via the source gateway device. A communication control method for adding a delay difference time, which is a communication delay time, in a stepwise manner. The communication control method according to claim 27,
As a result of stepwise addition of the delay difference time for the communication via the source gateway apparatus, when the source delay information and the destination delay information become equal, it is determined that the delay addition processing has been completed. A communication control method for notifying the former gateway device. The communication control method according to claim 27,
Obtaining delay information related to each of a source gateway device that is a gateway device to which the mobile node was connected before moving and a destination gateway device that is a gateway device to which the mobile node was connected after moving;
Comparing source delay information, which is delay information related to the source gateway device, and destination delay information, which is delay information related to the destination gateway device;
As a result of comparison, if the destination delay information is smaller than the source delay information, this corresponds to the difference between the source delay information and the destination delay information for communication via the destination gateway device. A communication control method for adding a delay difference time that is a communication delay time to be transmitted. The communication control method according to claim 30, wherein
A communication control method for notifying the destination gateway device of completion of delay addition processing after starting the addition of the delay difference time for communication via the destination gateway device. The communication control method according to claim 30, wherein
The delay to be added to the communication when the mobile node confirms that the mobile node has moved under the control of the destination gateway device after the addition of the delay difference time to the communication via the destination gateway device is started. A communication control method that gradually reduces the difference time. A communication control method by a server device connected via a network to a plurality of gateway devices that relay data transmitted and received by a mobile node via a network with a communication partner,
Collecting delay information that is information indicating a communication delay time of a communication path through which the data is transmitted from the plurality of gateway devices via the network,
Based on the collected delay information, the delay information of the communication path that passes through each gateway device in order to reduce the difference in the delay information between the mobile node and the communication partner, which differs depending on the gateway device to which the mobile node is connected. A communication control method for obtaining an additional delay time that is a delay time to be added to the gateway device and transmitting information on the additional delay time corresponding to each of the plurality of gateway devices to each gateway device. A communication control method by a server device connected via a network to a plurality of gateway devices that relay data transmitted and received by a mobile node via a network with a communication partner,
Collecting delay information that is information indicating a communication delay time of a communication path through which the data is transmitted from the plurality of gateway devices via the network,
A communication that controls the communication delay time in order to reduce a difference in communication delay time of a communication path between the mobile node and the communication partner, which differs depending on the gateway device to which the mobile node is connected, based on the collected delay information. Control method. A communication control method by a gateway device that relays data transmitted and received by a mobile node via a network with a communication partner,
Collect delay information, which is information indicating the communication delay time of the communication path through which the data is transmitted via its own device,
The collected delay information is sent via the network to the management server that controls the communication delay time in order to reduce the difference in communication delay time of the communication path between the mobile node and the communication partner before and after the movement of the mobile node. Communication control method. The communication control method according to claim 35,
The communication delay time between the management server and the own device and / or the communication delay time between the own device and the mobile node are measured, and the delay information based on the measured communication delay time is sent to the management server. Transmission control method to be transmitted. The communication control method according to claim 35,
Before connecting with the mobile node, the communication delay time between the management server and the mobile device and / or the communication delay time between the mobile device and the mobile node are held in advance, and the communication delay time is held. A communication control method for transmitting the delay information based on the management server to the management server. The communication control method according to claim 36,
A communication control method, wherein a signal for registering an address independent of the network and an address dependent on the network is used for measuring a communication delay time between the management server and the own device. The communication control method according to claim 36 or 37,
A communication for storing the delay information in a signal for registering an address independent of the network and an address dependent on the network when transmitting the delay information to the management server and transmitting the signal to the management server; Control method. A communication control method by a gateway device that relays data transmitted and received by a mobile node via a network with a communication partner,
Collect delay information, which is information indicating the communication delay time of the communication path through which the data is transmitted via its own device,
Information on the additional delay time, which is a delay time to be added to the delay information of the communication path passing through the own device, A communication control method of adding the additional delay time to the collected delay information when received from a management server that controls the communication delay time in order to reduce the difference.

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