JP4340731B2 - Network fault monitoring processing system and method - Google Patents

Description

  The present invention relates to a redundant LAN network. In particular, the present invention relates to a fault monitoring system and method for a redundant LAN network.

In general, a duplexed network has a configuration in which, for example, a LAN (Local Area Network) is physically separated as follows.
Conventionally, in a network configured by duplicating LANs, both can be used as working LANs during normal times, and when a failure occurs, the communication program automatically degenerates to one LAN without being aware of the LAN failure. In order to provide a network system that can continue communication between nodes, and can detect and switch over a LAN failure at an early stage, and can continue a connection between communication programs in each node. An address is set, each node detects a communication path failure for each LAN with respect to each communication partner node, has information on whether communication is possible for each communication path, and each node transmits data to the communication partner node. Some transmissions select and transmit a communication path based on the above information when transmitting (for example, refer to Patent Document 1).

  In addition, regarding the redundant LAN switching system, the host recognizes the failure of the system and sends a system switching signal to the switching device provided outside, so that each terminal can be instantaneously switched and switched from the master to the slave. The purpose of the present invention is to provide a redundant LAN switching system that alleviates various failures and effectively uses a redundant LAN, and a master system and a slave system for data communication between a host and a plurality of terminals by sharing an external database A transmission unit that transmits a switching signal when the host recognizes a transmission failure in the primary transmission line and the secondary transmission line and outputs a switching signal for switching the transmission line. A receiving unit that receives a switching signal from the transmitting unit, a host and a transmission line that switches between a main transmission line and a subordinate transmission line based on a switching signal output from the receiving unit; There are those composed of the switching apparatus for transmitting data in response to the terminal (e.g., see Patent Document 2).

  Also, regarding a LAN system with a bus configuration, one is currently used for the purpose of maintaining the inter-node communication function without stopping the system even when an abnormality of the bus or node device occurs or during maintenance. First and second buses for using the other as a standby system and the first and second buses for using the other as a standby system and each of a plurality of nodes, one of them as an active system and the other as a standby system Each node device has a selective connection means for selectively connecting to either one of the first and second buses, and the selective connection means is a node device used as an active system. There is a configuration in which a node device used as a standby system is connected to a bus for use as an active system, and a node device used as a standby system is connected to a bus used as a standby system (for example, Patent Document 3). Irradiation).

In the above conventional examples, all have a network configuration in which the LAN is physically separated. However, when a duplicated network is connected to another network, the other network that faces the other due to equipment cost and configuration problems is not used. There are cases where the network cannot be duplicated and the routers connecting the networks cannot be duplicated as follows.
FIG. 7 is a diagram for explaining an example in which a duplicated LAN as a premise of the present invention is connected to another LAN. Note that the same components are denoted by the same reference numerals and symbols throughout the drawings.

As shown in the figure, the node device 105 is connected to the duplicated LANs 107A and 107B, and the router 100 connects between the duplicated LANs 107A and 107B and the LAN 200 that is not duplicated.
One network address and one physical address are assigned to the node device 105, and without being aware of the LANs 107A and 107B that are duplicated in the application program running on the node device 105, one of the duplicated LANs 107A and 107B is further provided. Communication can be performed in the same manner as in the conventional technology described above without being aware of the failure.

By the way, when one of the redundant LANs 107A and 107B has a failure, it is impossible to detect which side of the LAN has a failure as follows.
For example, if a response is not received even if a response is requested by transmitting a continuity confirmation packet from the node device 105 to the router 100, it is determined that both of the redundant LANs 107A and 107B are faulty. Can do.
On the other hand, when there is a response from the router 100, it is only possible to determine whether both of the redundant LANs 107A and 107B are in failure or only one of the LANs 107A and 107B is in failure. It is vague. That is, it is impossible to determine whether the LAN 107A is in a failure state, the LAN 107B is in a failure state, or both of the LANs 107A and 107B are out of failure among the redundant LANs 107A and 107B.

The reason is that the packet monitoring the network status of the LANs 107A and 107B duplexed from the node device 105 assigned only one network address and one physical address to the router 100 via the LANs 107A and 107B duplexed. This is because each response cannot be identified and received.
That is, the physical address resolution table possessed by the opposite router 100 is duplicated in the same LAN of the duplicated LANs 107A and 107B with the node device 105 to which only one physical address and one physical address are assigned, and the duplicated LANs 107A and 107B. It is because it does not respond | correspond to identifying and communicating simultaneously via this.

  In this case, it is impossible to individually identify and monitor the state of failure occurrence and recovery for the redundant LANs 107A and 107B.

JP 2001-60959 A JP 7-226752 A JP-A-8-149145

  Accordingly, in view of the above problems, an object of the present invention is to provide a network failure monitoring processing system and method capable of monitoring the occurrence and recovery of failures in each network having a duplex configuration in the same LAN.

In order to solve the above problem, the present invention provides a network fault monitoring processing system for performing communication between node devices connected to a duplexed LAN, comprising a single network address and a single physical address. Each having a common network address, a router for connecting the connected LAN to a single other LAN , a switch for switching packets located between the redundant LAN and the router , and each having a physical network address Two active / standby interfaces that communicate with the node device via the duplicated LAN, and one of the two active / standby interfaces. Continuity confirmation packet from one side to the router with the network address and physical address of the router as the destination When a response packet is received from the router and the destination is the network address or physical address of one of the interfaces, it is determined that the LAN connected to one of the interfaces is normal. If the response packet is not received, it is determined that the LAN connected to one of the interfaces is in failure, and one of the two active / standby interfaces is connected to the other via the switch. When a response check packet is transmitted by sending a continuity confirmation packet with the network address and physical address of the interface as the transmission destination, and a response packet is received from the other interface with the network address and physical address of the one interface as the transmission destination In addition, the two operational / preliminary When it is determined that both LANs connected to the system interface are normal and the response packet is not received, the LAN connected to at least one of the two active / standby interfaces is in failure. Provided is a network failure monitoring processing system comprising a failure detection unit for determining .

Further, when both of the redundant LAN systems are normal, the failure detection unit switches the standby interface to the active interface when detecting a failure of the LAN connected to the active interface.
Furthermore, when the failure detection unit determines that the LAN connected to the standby interface is in failure and the LAN connected to the operational interface is in failure, both of the redundant LAN systems are Judged as a failure.

Further, the failure detection unit is configured to detect when the LAN connected to the standby interface is restored when the LAN connected to the active interface is normal and the LAN connected to the standby interface is in failure. , It is determined that both systems of the duplexed LAN are normal.
Further, the failure detection unit is connected to the restored LAN when the LAN connected to one of the active / standby interfaces is restored when both of the redundant LAN systems are in failure. One of the active / spare system interfaces is an active interface.

Further, an ICMP echo packet is used as the continuity confirmation packet.
Further, the switch performs packet switching using the physical address of the layer 2 of the OSI model.
Furthermore, the present invention provides a fault monitoring processing method for a network that performs communication between node devices connected to a duplicated LAN, and assigns a common network address to the operational interface and the standby interface of the node device, and , A step of assigning a physical address to each of the active interface and the standby interface and communicating the duplexed LAN with the node device, and the duplexed LAN and a single other LAN from the operational interface a step of requesting the network address of the router to the router having rows have and one network address and one physical address a connection, sends a continuity test packet to the destination physical address response with the Network from the router to the operational interface Determining that the LAN connected to the operational interface is normal when receiving a response packet having a destination address of the network address and physical address, and the operational interface when not receiving the response packet A step of determining that a LAN connected to the network is in failure, and from the standby interface to the operational interface via a switch located between the duplexed LAN and the router and performing packet switching, Sending a continuity confirmation packet with the network address and physical address of the operational interface as the transmission destination and requesting a response; and sending a response packet with the network address and physical address of the standby interface from the operational interface as the transmission destination If received A step of determining that the LAN connected to the standby interface is normal, and a step of determining that the LAN connected to the standby interface is in failure when the response packet is not received. A failure monitoring processing method for a network is provided.

Furthermore, the present invention provides a network fault monitoring processing system for performing communication between node devices connected to a duplicated LAN, having a common network address, each having a physical address, and one of which is an active system. With the other as a standby system, two active / standby interfaces that communicate with the node device via the duplexed LAN, and the other node via the LAN from the operational interface of one of the node devices When a continuity confirmation packet is sent with the network address and physical address of the device's active interface as the transmission destination, and a response packet is received with the network address and physical address of the operational interface of one of the node devices as the transmission destination Connect to the operational interface of one of the node devices LAN is determined to be normal to, LAN connected to the operating system interface of one of said node device when not receiving the response packet is determined to be in failure, further, the one of the node device From the standby system interface, via the LAN, transmit a continuity confirmation packet having the destination address of the standby system interface of the other node device as a destination, the network address of the standby system interface of the one of the node devices, When a response packet having a physical address as a transmission destination is received, it is determined that the LAN connected to the standby interface of one of the node devices is normal, and when the response packet is not received, one of the nodes The LAN connected to the standby interface of the device is faulty Providing fault monitoring processing system network and determines that that.

  As described above, according to the present invention, since a single network address is assigned to two interfaces of a node device connected to a duplicated LAN, and a physical address is assigned at the same time, connection to the duplicated LAN is performed. The opposite router, which has the same configuration, transmits a continuity confirmation packet from one of the two interfaces to the opposite node device, requests a response using one interface as the destination, and is duplexed depending on whether there is a response. It is now possible to confirm the occurrence and recovery of LAN failures individually.

  FIG. 1 is a block diagram showing a schematic configuration of a network failure monitoring processing system according to the present invention. As shown in the figure, in the network according to the present invention, the node device 105 is connected to the redundant LAN 107A and LAN 107B, and the router 100 is connected to face the node device 105. The router 100 is further connected to another single LAN 200 that is not duplexed.

  Note that an L2 (layer 2) switch 101 is provided between the router 100 and the duplicated LAN 107A and LAN 107B via a route 108, and further, a route is provided between each of the duplicated LAN 107A and the LAN 107B with the node device 105. An L2 (layer 2) switch 102A and an L2 (layer 2) switch 102B are provided via 109A and a path 109B.

  The L2 switch 101, the L2 switch 102A, and the L2 switch 102B are OSI (Open Systems Interaction) reference model layer switches that perform packet switching using a MAC (Media Access Control) address, and the L2 switch 101 is duplicated. The LAN 107A and the LAN 107B are bundled and connected to the router 100 via the path.

  In this way, a redundant configuration network in which the node device 105 and the L2 switch 101 are duplicated is formed, the interface 103A is connected to the L2 switch 102A and the interface 103B in a one-to-one relationship with the L2 switch 102B, and the data link layer ( The network is configured to be the same network in layer 2), that is, the same LAN (Local Area Network).

The node device 105 is a network device such as a host computer, and includes an interface 103A and an interface 103B. One of the interface 103A and the interface 103B is an operational interface, and the other is a standby interface.
The interface 103A and the interface 103B are connected to the L2 switch 102A and the L2 switch 102A via the path 109A and the path 109B, respectively, and further connected to the duplicated LAN 107A and LAN 107B.

The node device 105 is provided with a control unit 104. The control unit 104 is a control program for controlling the network such as an OS (Operating System), a device driver, etc., and controls the interface 103A and the interface 103B as a duplex interface. A failure detection unit 104A that performs detection processing is included.
The control unit 104 assigns one common network address to the interface 103A and the interface 103B. As an example, the IP address “IPB” is assigned to the interface 103A and the interface 103B.

Further, the control unit 104 has one physical address for each of the interface 103A and the interface 103B. As an example, “MACB” is assigned to the interface 103A as a MAC address, and “MACC” is assigned to the interface 103B as a MAC address.
The router 100, which is a network device facing the node device 105, is a general router that does not have a redundant configuration, and has an interface 106. The interface 106 and the L2 switch 101 via the path 108 as described above. Connected one-on-one.

The interface 106 has one physical address and one network address. As an example, the interface 106 is assigned a MAC address “MACA” and an IP address “IPA”.
In the failure detection unit 104A of the control unit 104, when the interface 103A is an active interface, the normality of the network ahead of the interface 103A is confirmed from the interface 103A through the L2 switch 101 to the continuity router 100. It is confirmed by a packet (for example, an ICMP (Internet Control Message Protocol) echo).

When the interface 103B is a standby interface, the normality of the network ahead of the interface 103B is confirmed by a continuity confirmation packet (for example, an ICMP echo) between the interface 103B and the interface 103A via the L2 switch 101. The
In this way, the router 100 that is the opposite network device identifies and communicates only with the interface 103A that is the active interface, and therefore a problem caused by the physical address resolution table of the opposite router 100 does not occur.
For this reason, when communication is performed through the interface 103A, which is an active interface, it is possible to confirm the occurrence of a failure or recovery from the interface 103B, which is a standby interface. Furthermore, it is possible to simultaneously confirm the occurrence of a failure with the interface 103A, which is the active interface, and to confirm the recovery with the interface 103B, which is the standby interface.

The operation of the network fault monitoring processing system of the present invention will be described in detail below.
FIG. 2 is a state transition diagram for explaining details of the redundant network failure detection processing method performed by the failure detection unit 104A of the control unit 104 in FIG.
As shown in the figure, in the failure detection unit 104A of the control unit 104, as an example, the statuses 200, 201, 202, depending on the operation of the LAN 107A and LAN 107B connected to the interface 103A and the interface 103B, the spare, and the presence of a failure 203 and 204 are classified.

Further, the detection events 205, 206, 207, and 208 are classified according to the failure detection and recovery detection of the LAN 107A and LAN 107B connected to the interface 103A and the interface 103B.
Here, in the state 200, the LAN 107A and the LAN 107B connected to the interface 103A and the interface 103B are in a normal operation state where there is no faulty LAN, and the interface 103A is an active interface. In this case, the interface 103A, which is an operational interface, performs all normal communication, and the interface 103B becomes a standby interface and is not used for normal communication.

  In the state 201, the LAN 107A and the LAN 107B connected to the interface 103A and the interface 103B are in a normal operation state where there is no faulty LAN, and the interface 103B is an active interface. In this case, the interface 103B, which is the active interface, performs all normal communication, and the interface 103A enters the standby interface state and is not used for normal communication.

In the state 202, the LAN 107A connected to the interface 103A is in a failure state, and the interface 103B is an active interface and is in a normal operation state.
In the state 203, the interface 103B is in a failure state, the interface 103A is an active interface, and is in a normal operation state.

In the state 204, both the LAN 107A and the LAN 107B connected to the interface 103A and the interface 103B are in a failure state, and there is no normal operation interface.
Next, the detection event 205 is an event for detecting a failure of the LAN 107A connected to the interface 103A.

The detection event 206 is an event for detecting a failure in the LAN 107B connected to the interface 103B.
The detection event 207 is an event for detecting recovery of the LAN 107A connected to the interface 103A.
The detection event 208 is an event for detecting recovery of the LAN 107B connected to the interface 103B.

Next, the state transition will be described below.
When there is a detection event 205 in the state 200, the system is switched from the interface 103A to the interface 103B, and a transition to the state 202 is performed.
When there is a detection event 205 in the state 203, a transition to the state 204 is performed.
When there is a detection event 206 in the state 200, a transition to the state 203 is performed.

When there is a detection event 206 in the state 201, the system is switched from the interface 103B to the interface 103A, and a transition to the state 203 is performed.
When there is a detection event 206 in the state 202, a transition to the state 204 is performed.
When there is a detection event 207 in the state 202, a transition to the state 201 is performed.
When there is a detection event 207 in the state 204, a transition to the state 203 is performed.

When there is a detection event 208 in the state 203, a transition to the state 200 is performed.
When there is a detection event 208 in the state 204, a transition to the state 202 is performed.

  FIG. 3 is a diagram illustrating an operation example of the failure detection unit 104A of the control unit 104 when the state of the interface 103A and the interface 103B is the state 200. As shown in this figure, when the operational interface is the interface 103A, the normality of the network ahead of the operational interface is determined by using an ICMP echo as a continuity confirmation packet between the interface 103A and the opposite router 100. This is confirmed as indicated by solid line arrows 300 and broken line arrows 301.

First, an ICMP echo request having the interface 106 of the opposite router 100 as a transmission destination (IP address “IPA”, MAC address “MACA”) is transmitted from the interface 103A.
The continuity confirmation packet used for this ICMP echo request flows through the L2 switch 101 to the opposite router 100 as indicated by the solid line arrow 300.

The facing router 100 transmits an ICMP echo response to the ICMP echo request with the interface 103A as a transmission destination (IP address “IPB”, MAC address “MACB”).
The continuity confirmation packet used for the ICMP echo response flows to the interface 103A via the L2 switch 101 as indicated by a broken line arrow 301.

When the failure detection unit 104A of the control unit 104 receives the ICMP echo response, the normality of the interface 103A that is the active interface is confirmed.
Next, regarding the normality of the network ahead of the standby interface, when the standby interface is the interface 103B, an ICMP echo is used as a continuity confirmation packet between the interface 103B and the interface 103A, and a solid arrow 302 and a dashed arrow 303 As shown in

First, an ICMP echo request is sent from the interface 103B, which is the standby interface, with the interface 103A, which is the active interface, as the transmission destination (IP address “IPB”, MAC address “MACB”).
The continuity confirmation packet used for this ICMP echo request flows through the L2 switch 101 to the interface 103A, which is the operational interface, as indicated by a solid arrow 302.

The failure detection unit 104A of the control unit 104 receives this ICMP echo request through the interface 103A which is an active interface.
Further, the failure detection unit 104A of the control unit 104 transmits an ICMP echo response to the ICMP echo request from the interface 103A that is the active system interface, with the interface 103B that is the standby system interface as the transmission destination (IP address “IPB”). .

The continuity confirmation packet used for the ICMP echo response flows through the L2 switch 101 to the interface 103B, which is the standby system interface, as indicated by the dashed arrow 303.
When the failure detection unit 104A of the control unit 104 receives the ICMP echo response, the normality of the interface 103B which is the standby interface is confirmed.

  Here, for example, it is assumed that a failure has occurred between the L2 switch 101 and the L2 switch 102A, and the failure detection unit 104A of the control unit 104 has not been able to receive a response to the ICMP echo request transmitted from the interface 103A that is the active interface. . At this time, the failure detection unit 104A of the control unit 104 determines that the interface 103A that is the active interface is a failure (detection event 205).

  Since the interface 103A, which is the active interface, has failed, the failure detecting unit 104A of the control unit 104 switches the active interface from the interface 103A to the interface 103B. In the failure detection unit 104A of the control unit 104, a transition is made from the state 200 to the failure state 202 of the interface 103A.

  FIG. 4 is a diagram for explaining an operation example of the failure detection unit 104A of the control unit 104 when the state of the interface 103A and the interface 103B is the state 202. As shown in this figure, the normality of the operational interface is indicated by a solid line arrow 400 and a broken line arrow 401 by using an ICMP echo as a continuity confirmation packet between the router 100 facing the interface 103B, which is the operational interface. Confirmed.

First, an ICMP echo request having the interface 106 of the opposite router 100 as a transmission destination (IP address “IPA”, MAC address “MACA”) is transmitted from the interface 103B which is an operational interface.
The continuity confirmation packet used for this ICMP echo request flows to the opposite router 100 via the L2 switch 101 as indicated by the solid line arrow 400.

The facing router 100 transmits an ICMP echo response to the ICMP echo request with the interface 103B as a transmission destination (IP address “IPB”, MAC address “MACC”).
The continuity confirmation packet used for this ICMP echo response flows to the interface 103B via the L2 switch 101 as indicated by the broken line arrow 401.

When the failure detection unit 104A of the control unit 104 receives this ICMP echo response, the normality of the interface 103B, which is the active interface, can be confirmed.
In the state 202, since the interface 103A that is the standby interface is in failure, an ICMP echo request that uses the interface 103B that is the active interface as the transmission destination (IP address “IPB”, MAC address “MACC”) is reserved. By transmitting from the interface 103A, which is the system interface, as indicated by a solid arrow 402, the failure recovery of the interface 103A, which is the standby system interface, is attempted.

Here, it is assumed that the failure detection unit 104A of the control unit 104 receives a response to the ICMP echo request transmitted from the interface 103A that is the standby interface.
At this time, the failure detection unit 104A of the control unit 104 determines that the failure of the interface 103A, which is the standby interface, has been recovered (detection event 207).
At this time, interface system switching does not occur, and the interface 103B continues to be the active interface.

In the failure detection unit 104A of the control unit 104, the state of the interface 103A and the interface 103B transitions to the state 201 in which both systems are in normal operation.
On the other hand, it is assumed that the failure detection unit 104A of the control unit 104 cannot receive a response to the ICMP echo request issued from the interface 103B that is the active interface. At this time, the failure detection unit 104A of the control unit 104 determines that the interface 103B, which is the active interface, is a failure (detection event 206).

  Since the interfaces of both systems have failed, the failure detection unit 104A of the control unit 104 makes a transition to the both-system interface failure state 204.

FIG. 5 is a diagram for explaining an operation example of the failure detection unit 104A of the control unit 104 when the state of the interface 103A and the interface 103B is the state 204. As shown in the figure, since the interfaces 103A and 103B, which are the interfaces of both systems, are in failure, recovery of the failure is attempted in each interface.
The interface 103A transmits an ICMP echo request with the interface 106 of the opposite router 100 as a transmission destination (IP address “IPA”, MAC address “MACA”) as indicated by a solid line arrow 500.

The interface 103B also transmits an ICMP echo request with the interface 106 of the opposite router 100 as the transmission destination (IP address “IPA”, MAC address “MACA”) as indicated by a solid arrow 501.
Here, it is assumed that the failure detection unit 104A of the control unit 104 receives a response to the ICMP echo request transmitted by the interface 103A. At this time, the failure detection unit 104A of the control unit 104 determines that the failure of the interface 103A has been recovered (detection event 207). At this time, the interface 103A that has recovered from the failure becomes the active interface, and the interface 103B that is still in failure becomes the standby interface. In the failure detection unit 104A of the control unit 104, a transition is made to the state 203 where the interface 103B is in failure.

In the above description, the continuity confirmation packet is transmitted from the node device 105 to the router 100 to monitor the failure. However, the present invention is not limited to this, and the continuity confirmation packet is transmitted between the node devices 105 as described below. Occurrence and recovery may be monitored.

FIG. 6 is a block diagram showing a schematic configuration of a network fault monitoring processing system according to a modification of FIG. As shown in the figure, in the network failure monitoring processing system according to the present invention, the node device 105-1 and the node device 105-2 having the same configuration are connected to the redundant LAN 107A and LAN 107B.
The node device 105-1 is assigned a common network address IPB-1, and each of the node device 105-1 includes an interface 103-1A and an interface 103-1B to which a physical address MACB-1 and MACC-1 are assigned, and the control unit 104-1. The control unit 104-1 includes a failure detection unit 104-1A.

Similarly, the node device 105-2 is assigned a common network address IPB-2, and the interfaces 103-2A and 103-2B to which the physical addresses MACB-2 and MACC-2 are assigned, and the control unit 104-. 2 and the control unit 104-2 includes a failure detection unit 104-2A.
In the failure detecting unit 104-1A of the control unit 104-1 in the node device 105-1, the interface 103-1 as the operational interface of the node device 105-2 is passed from the interface 103-1A as the operational interface via the LAN 107B. An ICMP echo request having 2A as a transmission destination (IP address “IPB-2”, MAC address “MACB-2”) is transmitted via the LAN 107B. In the failure detection unit 104-2A of the control unit 104-2 in the node device 105-2, an ICMP echo response to this ICMP echo request is transmitted as a continuity confirmation packet via the LAN 107B via the operational interface of the node device 105-1. A certain interface 103-1A is transmitted as a transmission destination (IP address “IPB-1”, MAC address “MACB-1”) from the interface 103-2A which is an operational interface.

In this way, in the node device 105-1, the failure detection unit 104-1A of the control unit 104-1 receives this ICMP echo response, thereby confirming the normality of the interface 103-1A that is the active interface. I got it.
In addition, in the failure detection unit 104-1A of the control unit 104-1 in the node device 105-1, the interface that is the standby interface of the node device 105-2 from the interface 103-1B that is the standby interface via the LAN 107A. An ICMP echo request having 103-2B as the transmission destination (IP address “IPB-2”, MAC address “MACC-2”) is transmitted as a continuity confirmation packet via the LAN 107A. In the failure detection unit 104-2A of the control unit 104-2 in the node device 105-2, the ICMP echo response to the ICMP echo request is transmitted as a continuity confirmation packet as a continuity confirmation packet via the LAN 107A. Is transmitted from the interface 103-2B, which is the standby interface, with the interface 103-1B, which is the standby system interface, as the transmission destination (IP address “IPB-1”, MAC address “MACB-2”).

In this way, in the node device 105-1, the failure detection unit 104-1A of the control unit 104-1 receives this ICMP echo response, thereby confirming the normality of the interface 103-1B which is the standby interface. I got it.
Next, the failure detection unit 104-2A of the control unit 104-2 in the node device 105-2 is an operation system interface of the node device 105-1 through the LAN 107B from the interface 103-2A which is an operation system interface. An ICMP echo request having the interface 103-1A as the transmission destination (IP address “IPB-1”, MAC address “MACB-1”) is transmitted as a continuity confirmation packet via the LAN 107B. In the failure detection unit 104-1A of the control unit 104-1 in the node device 105-1, the ICMP echo response to the ICMP echo request is transmitted as a continuity confirmation packet via the LAN 107B via the operational interface of the node device 105-2. A certain interface 103-2A is transmitted as the transmission destination (IP address “IPB-2”, MAC address “MACB-2”) from the interface 103-1A which is an operational interface.

In this way, in the node device 105-1, the failure detection unit 104-2A of the control unit 104-2 receives this ICMP echo response, thereby confirming the normality of the interface 103-2A that is the active interface. I got it.
In addition, in the failure detection unit 104-2A of the control unit 104-2 in the node device 105-2, the interface that is the standby interface of the node device 105-1 from the interface 103-2B that is the standby system interface via the LAN 107A. An ICMP echo request having 103-1B as the transmission destination (IP address “IPB-1”, MAC address “MACC-1”) is transmitted as a continuity confirmation packet via the LAN 107A. In the failure detection unit 104-1A of the control unit 104-1 in the node device 105-1, the ICMP echo response to the ICMP echo request is transmitted as a continuity confirmation packet via the LAN 107A via the standby interface of the node device 105-2. A certain interface 103-2B is transmitted as a transmission destination (IP address “IPB-2”, MAC address “MACC-2”) from the interface 103-1B which is a standby interface.

In this way, in the node device 105-2, the failure detection unit 104-2A of the control unit 104-2 receives this ICMP echo response, thereby confirming the normality of the interface 103-2B which is the standby system interface. I got it.
In this way, it becomes possible to individually monitor and confirm the occurrence and recovery of the redundant LAN 107A and LAN 107B.

It is a block diagram which shows schematic structure of the failure monitoring processing system of the network which concerns on this invention. FIG. 2 is a state transition diagram illustrating details of a redundant network failure detection processing method performed by a failure detection unit 104A of the control unit 104 in FIG. 1. FIG. 11 is a diagram for explaining an operation example of the failure detection unit 104A of the control unit 104 when the state of the interface 103A and the interface 103B is the state 200. FIG. 10 is a diagram for explaining an operation example of the failure detection unit 104A of the control unit 104 when the state of the interface 103A and the interface 103B is the state 202. 10 is a diagram for explaining an operation example of the failure detection unit 104A of the control unit 104 when the state of the interface 103A and the interface 103B is the state 204. FIG. It is a block diagram which shows schematic structure of the failure monitoring processing system of the network which concerns on the modification of FIG. It is a figure explaining the example in which the redundant LAN used as the premise of this invention connects with another LAN.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 ... Router 101, 102A, 102B ... L2 switch 103A, 103A-1, 103A-2, 103B, 103B-1, 103B-2, 106 ... Interface 104, 104-1, 104-2 ... Control part 104A, 104A- DESCRIPTION OF SYMBOLS 1, 104A-2 ... Failure detection part 105, 105-1, 105-2 ... Node apparatus 107A, 107B ... LAN
108, 109A, 109B ... route

Claims (9)

In a fault monitoring processing system for a network that performs communication between node devices connected to a redundant LAN,
A router having one network address and one physical address, and connecting the duplexed LAN to a single other LAN;
A switch located between the duplicated LAN and the router for switching packets;
Two operating / standby interfaces having a common network address, each having a physical address, one serving as an active system and the other serving as a standby system, and communicating with the node device via the duplicated LAN; ,
A network address of the router from one of the two active / standby interfaces, a continuity confirmation packet having the physical address as a transmission destination to request a response, and a network address of the one interface from the router; When a response packet having a physical address as a transmission destination is received, it is determined that the LAN connected to one of the interfaces is normal, and when the response packet is not received, the LAN connected to one of the interfaces Further, a continuity confirmation packet is transmitted from one of the two active / standby interfaces to the other via the switch with the network address and physical address of the other interface as the transmission destination. Request a response, and the other interface When a response packet is received from the interface with the network address and physical address of one of the interfaces as a destination, it is determined that both LANs connected to the two active / standby interfaces are normal, and A network failure monitoring processing system comprising: a failure detection unit that determines that a LAN connected to at least one of the two active / standby interfaces is in failure when a response packet is not received . The failure detection unit switches a standby interface to an operation interface when detecting a failure of a LAN connected to an operation interface when both of the redundant LAN systems are normal. Item 5. The network failure monitoring processing system according to Item 1. When the failure detection unit determines that the LAN connected to the standby interface is in failure and the LAN connected to the operational interface is in failure, both of the redundant LAN systems are in failure. The network failure monitoring processing system according to claim 1, wherein the network fault monitoring processing system is determined. When the LAN connected to the active interface is normal and the LAN connected to the standby interface is in failure, the failure detecting unit 2. The network failure monitoring processing system according to claim 1, wherein it is determined that both systems of the duplexed LAN are normal. The failure detection unit is connected to the restored LAN when the LAN connected to one of the active / spare system interfaces is restored when both of the redundant LAN systems are in failure. 2. The network failure monitoring processing system according to claim 1, wherein one of the active system / spare system interface is used as an active system interface. The network failure monitoring processing system according to claim 1, wherein an ICMP echo packet is used as the continuity confirmation packet. The network fault monitoring processing system according to claim 1, wherein the switch performs packet switching using a layer 2 physical address of the OSI model. In a network failure monitoring processing method for performing communication between node devices connected to a duplexed LAN,
A common network address is assigned to the operational interface and the standby interface of the node device, and further, a physical address is assigned to each of the operational interface and the standby interface, and communication between the redundant LAN and the node device is performed. A process of performing;
Network address of the router to the router having rows have and one network address and one physical address a connection with the duplexed LAN and singlet other LAN from the operation system interface, the destination physical address Sending a continuity confirmation packet and requesting a response;
A step of determining that the LAN connected to the operational interface is normal when a response packet having the network address of the operational interface as a transmission destination is received from the router as a transmission destination;
Determining that the LAN connected to the operational interface is in failure when not receiving the response packet ;
Check the continuity from the standby interface to the operational interface through the switch that switches between the duplicated LAN and the router and switches packets using the network address and physical address of the operational interface as the transmission destination. Sending a packet to request a response;
Determining that the LAN connected to the standby interface is normal when a response packet is received from the operational interface as the destination network address and physical address of the standby interface;
And a step of determining that the LAN connected to the standby interface is in failure when the response packet is not received. In a fault monitoring processing system for a network that performs communication between node devices connected to a redundant LAN,
Two operating / standby interfaces having a common network address, each having a physical address, one serving as an active system and the other serving as a standby system, and communicating with the node device via the duplicated LAN; ,
From the operational interface of one of the node devices, a continuity confirmation packet is transmitted via the LAN with the network address and physical address of the operational interface of the other node device as the destination, and the operation of the one of the node devices is performed. When receiving a response packet whose destination is the network address or physical address of the system interface, it is determined that the LAN connected to the operational interface of one of the node devices is normal, and the response packet is not received Determines that the LAN connected to the operational interface of one of the node devices is in failure, and from the spare interface of one of the node devices, the spare of the other node device is connected via the LAN. Network address of physical interface, physical address When a response packet having a destination address of the network interface and physical address of the standby interface of one of the node devices is received, a standby interface of the one of the node devices is transmitted. And determining that the LAN connected to the standby interface of one of the node devices is in failure when it is determined that the LAN connected to the network is normal and the response packet is not received. Fault monitoring processing system.

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