JP2005175579A - Complex network system - Google Patents

Abstract

[Objective] To provide a network system capable of guaranteeing information transmission with a disaster-stricken area even when a regional disaster occurs.
[Configuration] For each information network, it is determined whether or not the transmission amount of information data flowing into the information network per unit time exceeds a predetermined amount, and the information network determined to exceed the predetermined amount is set as the destination Information data to be transmitted is excluded, and the transmission amount of information data transmitted between information networks per unit time is suppressed.
[Selection] Figure 2

Description

  The present invention relates to a complex network system including a plurality of information networks connected to each other.

  Currently, attention is focused on VoIP (Voice over Internet Protocol) as a technique for transmitting an audio signal on an IP (Internet Protocol) network. In a network employing the VoIP technology, voice communication between an IP telephone provided in the IP network and an existing subscriber telephone is enabled by connecting the existing telephone network and the IP network.

  In such a network, when the amount of information transmitted per unit time, so-called traffic, increases, information transmission delay or loss occurs. Therefore, in recent years, a network as shown in FIG. 1 that can control traffic has appeared (for example, see FIG. 1 of Patent Document 1).

In such a network, a plurality of telephone networks 1 a, 1 d, 1 e provided for each region are connected to the IP network 2, and traffic between the telephone networks is regulated by the congestion management device 7. That is, the congestion management device 7 first measures the congestion state on each path of the IP network 2 to determine whether congestion has occurred between the telephone networks (via the IP network 2). Determine whether. Here, the congestion management device 7 controls the traffic to the congestion control device 12 provided in the telephone network of the transmission source in each of the telephone networks determined to be congested. Send.
JP 2002-261925 A

  However, in the network as described above, in the event of a local disaster such as an earthquake, traffic is restricted because telephones for confirming the safety of victims are concentrated from other areas on the telephone network in the disaster area. This causes a problem that the call is interrupted.

  An object of the present invention is to provide a complex network system capable of guaranteeing information transmission with a stricken area even when a regional disaster occurs.

  The composite network system according to the present invention is a composite network system comprising a plurality of information networks connected to each other, and the transmission amount of information data flowing into each of the information networks per unit time exceeds a predetermined amount. A congestion determination means for generating a congestion occurrence signal indicating an information network determined to have exceeded the predetermined amount as a congestion network, and excluding information data destined for the congestion network, Traffic suppression means for suppressing a transmission amount per unit time of information data transmitted between each of the information networks.

  According to the composite network system of the present invention, when a local disaster occurs, even when calls to the disaster area are concentrated, telephone communication with the disaster area is guaranteed.

  For each information network, it is determined whether or not the transmission amount per unit time of the information data flowing into the information network exceeds a predetermined amount, and the information data destined for the information network determined to exceed the predetermined amount The amount of information data transmitted between information networks per unit time is reduced.

  Embodiments of the present invention will be described in detail with reference to the accompanying drawings.

  FIG. 2 is a diagram illustrating a complex network system according to the present invention.

  As shown in FIG. 2, IP networks 10 to 13 to which a plurality of IP telephones are respectively connected are provided corresponding to different areas A to D, respectively. On each of the IP networks 10 to 13, there are data packets based on various protocols in addition to voice data packets based on VoIP (hereinafter referred to as VoIP packets) by the IP telephones. The IP network 10 is connected to the IP network 11 via the traffic control device 21. The IP network 10 is connected to the IP network 12 via a traffic control device 22. Further, the IP network 10 is connected to the IP network 13 via the traffic control device 23. Note that an existing subscriber telephone network for each region is connected to each of the IP networks 10 to 13 (not shown).

  The traffic control device 21 converts the traffic of voice data packets (hereinafter referred to as VoIP packets) based on VoIP among various data packets transmitted to the IP network 11, that is, the transmission amount per unit time, the network address, Measure by referring to protocol ID, port number, etc. That is, the traffic control device 21 measures the number of VoIP packets flowing into the IP network 11 per unit time as traffic. Here, when the measured traffic becomes larger than the predetermined threshold, the traffic control device 21 determines that the information inflow to the IP network 11 is congested and manages the congestion occurrence signal F1 indicating that. Send to device 30. Further, when the control instruction signal G1 is supplied from the management apparatus 30, the traffic control device 21 responds to traffic of other data packets excluding the VoIP packet directed to the IP network indicated by the control instruction signal G1. Apply regulations. In other words, among the data packets passing through the traffic control device 21, only packets having a destination address belonging to the IP network indicated by the restriction instruction signal G1 and having a protocol ID unique to VoIP are allowed to pass without restriction. For other packets, the traffic is suppressed to a predetermined value or less.

  The traffic control device 22 measures the traffic of the VoIP packet among various data packets transmitted toward the IP network 12 by referring to the network address, protocol ID, port number, and the like. That is, the traffic control device 22 measures the number of VoIP packets flowing into the IP network 12 per unit time as traffic. Here, when the measured traffic becomes larger than the predetermined threshold, the traffic control device 22 determines that the information inflow to the IP network 12 is congested and manages the congestion occurrence signal F2 indicating that. Send to device 30. Further, when the restriction instruction signal G2 is supplied from the management apparatus 30, the traffic control device 22 responds to the traffic of other data packets excluding the VoIP packet directed to the IP network indicated by the restriction instruction signal G2. Apply regulations. In other words, among each data packet passing through the traffic control device 22, only a packet whose destination address belongs to the IP network indicated by the restriction instruction signal G2 and has a protocol ID unique to VoIP is allowed to pass without restriction. For other packets, the traffic is suppressed to a predetermined value or less.

  The traffic control device 23 measures the traffic of the VoIP packet among various data packets transmitted toward the IP network 13 by referring to the network address, protocol ID, port number, and the like. That is, the traffic control device 23 measures the number of VoIP packets flowing into the IP network 13 per unit time as traffic. Here, when the measured traffic becomes larger than the predetermined threshold, the traffic control device 23 determines that the information inflow to the IP network 13 is congested and manages the congestion occurrence signal F3 indicating that. Send to device 30. Further, when the restriction instruction signal G3 is supplied from the management apparatus 30, the traffic control device 23 responds to the traffic of other data packets excluding the VoIP packet directed to the IP network indicated by the restriction instruction signal G3. Apply regulations. In other words, among the data packets passing through the traffic control device 23, only packets having a destination address belonging to the IP network indicated by the restriction instruction signal G3 and having a protocol ID unique to VoIP are allowed to pass without restriction. For other packets, the traffic is suppressed to a predetermined value or less.

  In addition, when the restriction release command signal S is supplied from the management device 30, these traffic control devices 21 to 23 release the traffic restriction as described above.

  The management device 30 executes congestion control for each of the traffic control devices 21 to 23 according to the congestion management control subroutine flow shown in FIG.

  In FIG. 3, first, the management device 30 determines whether or not the congestion occurrence signal F1 is supplied from the traffic control device 21 (step S1). When it is determined in step S1 that the congestion occurrence signal F1 has been supplied, the management device 30 supplies the traffic control devices 22 and 23 with the restriction instruction signal G1 indicating the network address of the IP network 11 (step S2). . In response to step S2, each of the traffic control devices 22 and 23 determines the traffic of each packet excluding the packet that is a VoIP packet and whose destination address indicates the IP network 11 among the various data packets passing therethrough. The restriction mode is set to suppress below the value. As a result, only VoIP packets transmitted from each telephone network or IP network 12 or 13 to the IP network 11 are preferentially transmitted. That is, when the congestion generation signal F1 is supplied, the management device 30 determines that a disaster has occurred in the area B to which the IP network 11 belongs, and gives priority to the traffic of the VoIP packet transmitted to the IP network 11. Secure.

  If it is determined in step S1 that the congestion occurrence signal F1 is not supplied, the management device 30 next determines whether or not the congestion occurrence signal F2 is supplied from the traffic control device 22 (step S1). S3). When it is determined in step S3 that the congestion occurrence signal F2 is supplied, the management device 30 supplies the traffic control devices 21 and 23 with the restriction instruction signal G2 indicating the network address of the IP network 12 (step S4). . In response to step S4, each of the traffic control devices 21 and 23 determines the traffic of each packet excluding the packet that is a VoIP packet and whose destination address indicates the IP network 12 among the various data packets passing therethrough. The restriction mode is set to suppress below the value. As a result, only VoIP packets transmitted from each telephone network or IP network 11 or 13 to the IP network 12 are preferentially transmitted. That is, when the congestion occurrence signal F2 is supplied, the management device 30 determines that a disaster has occurred in the area C to which the IP network 12 belongs, and gives priority to the traffic of the VoIP packet transmitted toward the IP network 12 Secure.

  If it is determined in step S3 that the congestion occurrence signal F2 is not supplied, the management device 30 next determines whether or not the congestion occurrence signal F3 is supplied from the traffic control device 23 (step S3). S5). When it is determined in step S5 that the congestion occurrence signal F3 is supplied, the management device 30 supplies the traffic control devices 21 and 22 with the restriction instruction signal G3 indicating the network address of the IP network 13 (step S6). . In response to step S6, each of the traffic control devices 21 and 22 determines the traffic of each packet excluding the packet that is a VoIP packet and whose destination address indicates the IP network 13 among the various data packets passing therethrough. The restriction mode is set to suppress below the value. Thereby, only the VoIP packet transmitted from each telephone network or IP network 11 or 12 to the IP network 13 is preferentially transmitted. That is, when the congestion occurrence signal F3 is supplied, the management apparatus 30 determines that a disaster has occurred in the area D to which the IP network 13 belongs, and gives priority to the traffic of the VoIP packet transmitted to the IP network 13 Secure.

  If it is determined in step S5 that the congestion occurrence signal F3 is not supplied, the management device 30 supplies the restriction release command signal S to each of the traffic control devices 21 to 23 (step S7). In response to the execution of step S7, the restriction mode of each of the traffic control devices 21 to 23 is canceled. That is, when the congestion occurrence signals F1 to F3 are not supplied from the traffic control devices 21 to 23 and the congestion state is lost on the network, the management device 30 cancels the traffic restriction mode for each of the traffic control devices 21 to 23. To do.

  After executing step S2, S4, S6, or S7, the management device 30 exits from the congestion management control subroutine shown in FIG. 3 and proceeds to execution of the main routine (not shown). The management device 30 repeatedly executes the congestion management control subroutine every predetermined period.

  Therefore, according to the composite network system shown in FIG. 2, when a local disaster occurs and calls for safety confirmation using IP telephones or the like are concentrated in the affected area, only the communication band for the affected area is provided. Will be secured preferentially. Therefore, even immediately after the occurrence of a regional disaster, it is possible to communicate with the affected area without disconnecting the call.

  In FIG. 2, the IP networks 10 to 13 are shown as a composite network system in which a plurality of information networks are connected to each other, but each information network is not limited to an IP network. In short, each of the information networks only needs to be a packet-switching network that packetizes and transmits information data.

It is a figure which shows the network system which employ | adopted VoIP. 1 is a diagram illustrating a complex network system according to the present invention. FIG. It is a figure which shows an example of the congestion management control subroutine performed in the management apparatus 30 of FIG.

Explanation of symbols

10-13 IP network 21-23 Traffic control device 30 Management device

Claims (5)

A complex network system comprising a plurality of information networks connected to each other,
Congestion indicating the information network determined to have exceeded the predetermined amount as a congestion network by determining whether or not the transmission amount per unit time of the information data flowing into each of the information networks exceeds the predetermined amount Congestion determination means for generating a generation signal;
And a traffic suppression unit that excludes information data destined for the congestion network and suppresses a transmission amount of information data transmitted between each of the information networks per unit time. system.   The congestion determination means excludes only voice data in the information data destined for the congestion network, and suppresses a transmission amount per unit time of information data transmitted between the information networks. The composite network system according to claim 1.   2. The composite network system according to claim 1, wherein each of the information networks is provided for each different area.   2. The complex network system according to claim 1, wherein each of the information networks is a packet-switching network that packetizes and transmits the information data. 3. The composite network system according to claim 2, wherein the information network is an IP network, and the voice data is a VoIP packet.

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