JP6894079B2 - Optical communication emergency restoration method and equipment - Google Patents

Description

The present invention relates to a method for restoring communication as an emergency measure when a failure occurs in an optical communication device, and a device and a system used in the method.

Japanese Unexamined Patent Publication No. 2013-157915 describes an optical network, a node, and a method for switching routes in the event of a failure.

Japanese Unexamined Patent Publication No. 2013-157915

Conventionally, when the control plane is disconnected in an optical network or a node, the node remains isolated from the network until the optical network is physically restored. Therefore, it was not easy to change the settings to use other networks.

An object of the present invention is to provide a method and an apparatus capable of urgently restoring an optical communication network in a damaged area. In particular, an object of the present invention is to provide a method and an apparatus for easily and quickly recovering a control plane (control of which node a light signal is transmitted through).

The first aspect of the present invention relates to a method for performing emergency restoration of a control plane. A network between optical communication devices that transmit and exchange user data is called a data plane (network). On the other hand, the control plane is also called the control plane. The control plane is a network that controls between the nodes that control the data plane network.

This method connects the recovery device to the control plane local network of the first node. A recovery device is a device for recovering the communication status of an optical communication device (as an emergency measure). The first node is a server located in the area where the failure would have occurred.

Next, the recovery device acquires the address information of one or more nodes in the first subnet including the first node existing in the control plane local network from the emergency connection server. The recovery device can usually send and receive wireless signals. Then, the information for connecting to the emergency connection server is stored. On the other hand, the emergency connection server stores address information for accessing a node, such as the IP addresses of a plurality of nodes. Therefore, when the recovery device requests the emergency connection server to send the address information of one or more nodes in the subnet including the first node, the emergency connection server sends the address information to the recovery device. .. The recovery device stores the received address information in the storage unit.

Next, the recovery device uses the address information of one or more nodes to check whether the first node in the first subnet can connect to other nodes in the first subnet. The recovery device reads the address information of one or more nodes in the subnet including the first node from the storage unit. Then, try to access each server using the read address. In this way, the node that can be connected to the first node is grasped. The recovery device stores the information (or address information) of the connected node in the storage unit.

Next, the recovery device notifies the emergency connection server of information about the nodes in the first subnet to which the first node can connect. For example, the recovery device reads the information of the node that can be connected using the address from the storage unit. Then, the read information is notified to the emergency connection server. At this time, information about the nodes in the first subnet to which the first node can be connected may be notified by radio.

The emergency connection server then analyzes the connectable nodes in the control plane local network. The emergency connection server receives connectable information of various nodes and stores it in the storage unit. Then, the control plane, which is the connection information between the nodes, is obtained by using the information of the connectable nodes stored in the storage unit. For example, by transmitting the control plane to the recovery device and controlling between the nodes that perform information communication according to the control plane, it is possible to perform emergency recovery of the control plane in the control plane local network including the first server.

In this method, in the control plane local network, when the first node cannot connect to the node in the first subnet, the recovery device may establish wireless communication with the emergency connection server.

In this method, when the recovery device determines that the first node can connect to a node in the first subnet, the recovery device may disconnect the wireless communication between the recovery device and the emergency connection server.

The second aspect of the present invention relates to a recovery device.
The recovery device has a connection unit, an address acquisition unit, a node confirmation unit, and a wireless notification unit.
The connection unit is an element for connecting the recovery device to the control plane local network of the first node.
The address acquisition unit is an element for acquiring the address information of one or more nodes in the first subnet from the emergency connection server.
The node confirmation unit can connect the first node in the first subnet to other nodes in the first subnet by using the address for acquiring the address information of one or more nodes in the first subnet. It is an element to confirm.
The wireless notification unit is an element for wirelessly notifying the emergency connection server of information about the nodes in the first subnet to which the first node can connect.

This recovery device may be an element of the recovery system of the optical communication system. In this case, the recovery system of the optical communication system includes the above-mentioned recovery device and one or more functional blocks that can be connected to the recovery device. The recovery system may have a functional block control unit. Further, the functional block may be connectable to the recovery device at the fixed portion. The recovery device may further have a control unit that controls the nodes and functional blocks according to the instructions sent from the control plane.

The present invention can provide a method or device capable of urgently restoring an optical communication network in a damaged area. In particular, the present invention can provide a method and an apparatus for easily and quickly restoring a control plane (control of which node an optical signal is transmitted through).

FIG. 1 is a conceptual diagram showing an example of a system configuration of the present invention. FIG. 2 is a conceptual diagram showing a configuration example of an emergency recovery system. FIG. 3 is a flowchart for explaining an example of an embodiment of the present invention. FIG. 4 is a conceptual diagram showing a process of connecting a recovery device to the control plane local network of the first node of the present invention. FIG. 5 is a conceptual diagram showing a process in which the recovery device acquires the address information of one or more nodes in the first subnet including the first node existing in the control plane local network from the emergency connection server. Is. FIG. 6 is a concept showing a process in which the recovery device uses the address information of one or more nodes to check whether the first node in the first subnet can connect to other nodes in the first subnet. It is a figure. FIG. 7 is a conceptual diagram showing a process in which the recovery device notifies the emergency connection server of information about a node in the first subnet to which the first node can be connected. FIG. 8 is a conceptual diagram showing a process in which the emergency connection server analyzes connectable nodes in the control plane local network. FIG. 9 is a conceptual diagram showing a process in which the recovery device establishes wireless communication with the emergency connection server when the first node cannot connect to the nodes in the first subnet in the control plane local network. FIG. 10 is a conceptual diagram showing a process of disconnecting wireless communication between the recovery device and the emergency connection server when the recovery device determines that the first node can connect to a node in the first subnet.

Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. The present invention is not limited to the forms described below, and includes those modified appropriately by those skilled in the art from the following forms.

Hereinafter, embodiments of the present invention will be described in detail.

FIG. 1 is a conceptual diagram showing an example of a system configuration of the present invention. As shown in FIG. 1, in the configuration of the optical network, the telecommunications carrier has a data plane network between optical communication devices that transmit and exchange user data, and a control plane network between nodes that control the data plane network. Is divided. For brevity, each network below refers to the data plane and control plane. Regarding the construction of the control plane, the telecommunications carrier (computer provided by the telecommunications carrier) can establish a link of the control plane by using the bandwidth resources in the data plane when constructing the control plane. In addition, telecommunications carriers can build control planes using other network lines and exchange facilities. If the data plane or control plane fails and the control plane is interrupted, the control function of the optical network is damaged. Therefore, the telecommunications carrier can improve the fault tolerance of the control plane by taking measures such as making the control plane resources redundant and making the route redundant. Regarding the configuration of the control plane, layer 3 can have a plurality of IP subnets. Hereinafter, it is also referred to as a subnet. In addition, each of the smallest divided IP subnets of Layer 3 can be installed in one Layer 2 segment (hereinafter referred to as a segment). Communication within the subnet is closed within the segment. IP routers are installed between subnets, and traffic routing can be performed between different subnets.

Optical networks are constructed to be fault tolerant. However, in the event of a large-scale disaster, as shown in Fig. 1, the data plane is physically divided due to fiber cutting at multiple locations or damage to optical exchange nodes beyond the design, and the data plane is constructed using the bandwidth resources of the data plane. The control plane is also divided. Emergency recovery based on the present invention can be performed, and the divided control plane network can be quickly communicated.

Target of control plane automatic emergency restoration In the present invention, the control plane automatic emergency restoration is performed for each layer 3 subnetwork of the control plane (one layer 2 segment corresponding thereto). For emergency recovery of multiple control plane subnets, subnetwork emergency recovery of each control plane is performed independently.

Control plane automatic emergency restoration approach As shown in Fig. 1, the telecommunications carrier has other surviving or partially restored wireless communication networks and the Internet in the area where the affected optical network is located. I know the access status. For emergency restoration of the control plane, the telecommunications carrier makes a temporary wired connection of the restoration device of the present invention to the target control plane network at a place where wireless connection and Internet access are possible. In addition, the telecommunications carrier installs the emergency connection server according to the present invention outside the disaster area and connects to the Internet via a secure access control device such as a firewall. The emergency connection server can automatically grasp the network damage status in cooperation with the recovery device. In addition, the emergency connection server can cooperate with the recovery device to perform emergency recovery of the fragmented target control plane network.

Configuration of emergency recovery system This recovery device may be an element of the recovery system of the optical communication system. In this case, the recovery system of the optical communication system may have a functional block control unit. This recovery system includes the above-mentioned recovery device and one or more functional blocks that can be connected to the recovery device by a fixed portion. The emergency connection server is a computer that can access the Internet securely, and is an element of the recovery system of the optical communication system that is used together with the recovery device.

FIG. 2 is a conceptual diagram of a recovery system including a recovery device and a functional block. Appropriate functional blocks may be adopted according to the failure of the target node or the like. The shape of the functional block is preferably a shape that can be fixed to the restoration device. Further, the functional blocks have, for example, the same shape on the upper surface and the lower surface, and a connection portion for connecting to each functional block or a restoration device may be provided.

FIG. 3 is a flowchart for explaining an example of an embodiment of the present invention. As shown in FIG. 3, the present invention includes the following plurality of steps for emergency restoration of the control plane.

Step 0: Preparation process for recovery device and emergency connection server In this preparation process, the telecommunications carrier takes the lead in performing the following preparation work.
Prepare one emergency connection server outside the disaster area for repairing the target control plane. Include secure access control devices, such as firewalls.
Set one GLOBAL IP address on the emergency connection server to enable Internet access.
In the emergency connection server, the IP address information set A of all the nodes in the subnet of the target control plane (before the disaster) is prepared as the communication confirmation target information of the target subnet.
Prepare a Q quantity recovery device for repairing the target control plane.
A unique ID is assigned to each recovery device and set in the recovery device.
Store the GLOBAL IP address of the emergency connection server in each recovery device.
In the emergency connection server, create a Q-quantity VPN logical network interface (for example, TapPort tap_0, tap_1, ..., tap_Q-1) for each of the Q recovery devices and the Virtual Private Network (VPN) connection. That is, one VPN logical network interface is created for one recovery device.
In the emergency connection server, one layer 2 soft breath, for example, br0 is created, and Q VPN logical network interfaces and br0 are connected.
In the emergency connection server, the Spanning Tree Protocol (STP) function is used for soft bleeding, for example, br0, and the STP priority of br0 is set to the lowest level.
In the emergency connection server, assign one free IP address in the subnet of the target control plane and set it to br0.
Create one VPN logical network interface (for example, TapPort, tap_0) for emergency connection server and VPN connection in each recovery device among the Q quantity recovery devices.
In each recovery device, one layer 2 soft breath, for example, br1 is created, and one VPN logical network interface created in the recovery device is connected to br1.
In each recovery device, the STP function is used for soft bleeding, for example, br1.
In each recovery device, assign one free IP address in the subnet of the target control plane and set it to br1.
Q or less Two or more recovery devices will be placed in the disaster area where the target network is accessible by wireless connection and Internet access.

Step 1: Step of connecting the recovery device to the control plane local network of the first node FIG. 4 is a conceptual diagram showing a step of connecting the recovery device to the control plane local network of the first node of the present invention. As shown in FIG. 4, each recovery device is placed in the disaster area and connected to the target control plane. Specifically, one network interface (interface 1) of the recovery device is connected to the local network of one node in the target control plane subnet. Hereinafter, the control plane subnet is referred to as the first subnet. The control plane node is the first node.

Step 2: The recovery device acquires the address information of one or more nodes in the first subnet including the first node existing in the control plane local network from the emergency connection server.

FIG. 5 is a conceptual diagram showing a process in which the recovery device acquires the address information of one or more nodes in the first subnet including the first node existing in the control plane local network from the emergency connection server. Is. As shown in FIG. 5, the recovery device accesses the Internet by using a network interface (interface 2) other than the interface 1 and a wireless connection device connected to the interface 2.
The recovery device connects to the emergency connection server via wireless connection and the Internet using the IP address of the emergency connection server for repairing the given target control plane. This connection utilizes existing secure access control and automatic authentication features.
The recovery device sends a request for address information of one or more nodes in the first subnet that includes the first node in the control plane local network to the emergency connection server.
The emergency connection server receives the request and sends the address information of one or more nodes in the first subnet to the recovery device. Specifically, the address information is the IP address information set A of all the nodes in the subnet (before the disaster) of the target control plane prepared in step 0.

Step 3: The recovery device uses the address information of one or more nodes to check whether the first node in the first subnet can connect to other nodes in the first subnet. It is a conceptual diagram which shows the process which a recovery apparatus confirms whether a 1st node in a 1st subnet can connect with another node in a 1st subnet using the address information of one or more nodes. As shown in FIG. 6, the recovery device of the interface 1 and the control plane of the first node based on the address information of one or more nodes in the first subnet acquired in step 2. Send to one or more nodes in the first subnet via the local network and check if the first node in the first subnet can connect to other nodes in the first subnet.
If the recovery device receives a reply from a certain node during the connection confirmation process, it determines that the node is still alive. If there is a node that does not reply during the connection confirmation process, it is determined that the first node and the relevant node are not connected.

Step 4: The recovery device notifies the emergency connection server of information about the nodes in the first subnet to which the first node can be connected. FIG. 7 shows a step in which the recovery device can connect to the first node. It is a conceptual diagram which shows the process of notifying the emergency connection server of the information about the node in 1 subnet. As shown in FIG. 7, the recovery device aggregates information about nodes in the first subnet to which the first node can connect.
The recovery device accesses the Internet via the interface 2 and the wireless connection device connected to the interface 2.
The recovery device uses the IP address of the emergency connection server for repairing the target control plane given to send information about the nodes in the first subnet to which the first node can connect via wireless connection and the Internet. To do.

Step 5: The emergency connection server analyzes the connectable nodes in the control plane local network. FIG. 8 is a conceptual diagram showing the process in which the emergency connection server analyzes the connectable nodes in the control plane local network. is there. As shown in FIG. 8, the emergency connection server organizes the connectable node information in the first subnet received from different recovery devices i during the confirmation process as a set R_i.
The emergency connection server can detect the node set R_i with different contents, determine that the relationship R_i is out of service, determine that the network between the relationship R_i is disconnected, and estimate the damaged location. For example, if the connectable node sets received from the two recovery devices are {a, b} and {c, d}, respectively, then a, b, c, d originally connected within the first subnet are It can be estimated that the control plane between {a, b} and {c, d} will be damaged by being separated into two layer 2 segments.
The emergency connection server calculates the union D of R_i received from all the recovery devices i already deployed.
The emergency connection server calculates and outputs a set of unconnected nodes U = AD in the first subnet.
Step 1 so that the telecommunications carrier confirms the contents of the set U, and if there is a node belonging to the set U, if it can be wirelessly connected to the disaster area, then multiple other recovery devices are placed in the disaster area. Make an emergency recovery from.

Step 6: In the control plane local network, when the first node cannot connect to the nodes in the first subnet, the recovery device establishes wireless communication with the emergency connection server. Step 6: The control plane is shown in FIG. FIG. 5 is a conceptual diagram showing a process in which a recovery device establishes wireless communication with an emergency connection server when a first node cannot connect to a node in the first subnet in a local network. As shown in FIG. 9, in step 3, the recovery device (for example, recovery device i) has a node in which there is no reply from the first node or other nodes in the first subnet, and the first node. If it is determined that there is no connection between the node and the node, the emergency connection server and VPN are connected via the interface 2 and the wireless connection device.
Specifically, the recovery device i is a VPN logic network interface (for example, TapPort, tap_0) for establishing a VPN created in the preparation step 0, and a VPN logic corresponding to the recovery device i created in the emergency connection server. A VPN tunnel is established between the network interface (for example, tap_i). A secure Layer 2 over Layer 3 tunnel can be used to establish a VPN tunnel.
The recovery device i connects the VPN logical network interface (for example, TapPort, tap_0) and its own interface 1 to the layer 2 soft breath br1 created in the preparation step 0. In this way, the first subnet is connected to the emergency connection server.
As described above, each of the other recovery devices independently establishes an emergency connection server and VPN, and connects to the target control plane and the emergency connection server.
By using each of the above VPN connections and the layer 2 soft breathing br0 set in the preparation step 0 in the emergency connection server, a layer 2 detour route to the first subnet is formed. The detour route at layer 2 becomes a redundant connection means of the target control plane network, and the damaged first subnet is automatically repaired.
If a loop occurs due to the establishment of a detour route for the first subnet, the existing STP function in the first subnet, emergency connection server, and recovery device automatically handles the loop and makes a VPN connection at the relevant location. It will be blocked. Therefore, even if a loop occurs, communication problems are automatically avoided.

Step 7: When the recovery device determines that the first node can connect to the node in the first subnet, the recovery device disconnects the wireless communication between the recovery device and the emergency connection server. It is a conceptual diagram which shows the process of disconnecting the wireless communication between a recovery device and an emergency connection server when it is determined that one node can connect with a node in the first subnet. As shown in FIG. 10, if the repair of the optical network progresses and the fiber optic link of the disconnected data plane is repaired again to restore the control plane network, the link of the repaired original control plane is also restored. It will coexist with the VPN detour route established for emergency restoration. In this case, a loop occurs in the control plane. Under this circumstance, the existing STP functions in the target control plane, emergency connection server, and recovery device automatically respond to the loop situation and block the VPN connection in the relevant location. In this way, communication problems are automatically avoided.
When the recovery device i monitors the STP status of its own softbridge br1 and can determine that the STP status of the VPN logical network interface (for example, TapPort, tap_0) is the Blocking status, or the recovery device i When it is possible to determine that the STP status of the VPN logical network interface (for example, TapPort, tap_i) corresponding to the ID of the recovery device i itself in the emergency connection server is the Blocking status in cooperation with the emergency connection server, the recovery device i is set. Automatically disconnects wireless communication between itself and the emergency connection server.
If the recovery device does not determine the above situation, it maintains a VPN connection by wireless communication between itself and the emergency connection server. In this way, the minimum required wireless communication can be maintained until the target control plane is completely restored.

When the control plane is disconnected within a wide range including multiple station buildings, if the product of the present invention is brought into the multiple station buildings and connected to the communication device, only the product of the present invention brought into the station building where the network is disconnected is the multiple communication method. Automatically reconnects to the control plane. The product of the present invention brought to another station automatically avoids loops and maintains the original control plane network.
When the control plane network is disconnected at a plurality of places, a plurality of products of the present invention automatically reconnect to the control plane by a plurality of communication methods.
When the disconnected part is repaired and restored, the product of the present invention automatically returns to the original control plane network connection means and disconnects the temporary emergency connection means.
If a disaster occurs again while the product of the present invention is left connected and the control plane network is disconnected, the product of the present invention at the position of the disconnected network automatically reconnects to the control plane by a plurality of communication methods. And make an emergency recovery.
Even if it cannot be used as an optical communication path, the recovery of the control plane enables the early recovery of the optical network by collecting the alarms of the optical communication device and determining the detour route of the optical signal at an early stage.

The present invention is used in the information and communication industry.

Claims (5)

The process of connecting the recovery device to the control plane local network of the first node,
The process of the recovery device acquiring the address information of one or more nodes in the first subnet including the first node existing in the control plane local network from the emergency connection server.
A step of confirming whether the first node in the first subnet can connect to another node in the first subnet by using the address information of the one or more nodes by the recovery device.
A process in which the recovery device notifies the emergency connection server of information about a node in the first subnet to which the first node can connect.
The process in which the emergency connection server analyzes connectable nodes in the control plane local network, and
A method of performing emergency restoration of the control plane in the control plane local network including. The method according to claim 1.
In the control plane local network, if the first node is not connectable to the nodes in the first subnet
The recovery device further includes a step of establishing wireless communication with the emergency connection server.
Method. The method according to claim 2.
When the recovery device determines that the first node can connect to a node in the first subnet,
Further including a step of disconnecting the wireless communication between the recovery device and the emergency connection server.
Method. The connection part for connecting to the control plane local network of the first node,
An address acquisition unit that acquires address information of one or more nodes in the first subnet from the emergency connection server,
Node confirmation to check whether the first node in the first subnet can connect to other nodes in the first subnet by using the address to acquire the address information of one or more nodes in the first subnet. Department and
A wireless notification unit that wirelessly notifies the emergency connection server of information about nodes in the first subnet to which the first node can connect.
A device control unit that controls nodes and functional block devices according to instructions placed on the control plane.
Restoration equipment, including. The recovery device according to claim 4 and
Includes one or more functional blocks that can be connected to the recovery device at a fixed portion.
Recovery system for optical communication system.

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