JP5518771B2 - Redundant network system, termination device and relay point adjacent device - Google Patents

Description

  The present invention relates to a redundant network system, a terminal device, and a relay point neighboring device, and more particularly, to a communication system that divides communication data into variable-length packets and performs communication between various grounds (many In this case, the present invention relates to a redundant network system, a terminal device, and a relay point neighboring device that perform communication path redundancy when communication paths are respectively set between two points but may be between three points or more.

In recent years, telecommunications carriers have established networks using packet communication systems such as the Internet protocol (hereinafter abbreviated as IP) and Ethernet (Ethernet is a registered trademark), and provide communication services such as dedicated lines and Internet connections. The Internet Engineering Task Force (IETF) standardizes a communication method centering on IP, and MPLS (Multiprotocol Label Switching) is a technology that has been standardized and attracted attention there.
In MPLS, a label is assigned to each IP packet, and each communication apparatus performs a transfer process based on the label. A transfer route with a label can be created from one end point of the network to another end point, and this is hereinafter referred to as a tunnel path. Since one tunnel path can be shared by a plurality of destination IP addresses, it is difficult to perform packet transfer processing based on the conventional IP address, and it is easy to control the bandwidth between network endpoints. .
In MPLS, label management is required in a certain unit such as a physical port of a communication apparatus so that the same label is not assigned to different tunnel paths. Which unit is managed depends on the policy determined by the network administrator, and the network range to which the same label management policy is applied is called a segment hereinafter. In a method called a transport profile (Transport Profile) in MPLS, a device control server is placed for each segment, thereby managing communication devices. Therefore, in order to set MPLS across segments, it is necessary to transfer the setting between the device control servers. For example, when crossing between segments managed by different network operators, it is necessary to negotiate the setting of each communication device in advance and set the result to each communication device through the device control server. In particular, when performing communication path redundancy, for each communication path to be made redundant, a consistent label for switching the communication path to the two communication devices that are the end points of the redundant section. Settings such as values are required. The setting transfer part between the device control servers is out of the scope of standardization, and the framework part that connects the segments and provides the MPLS communication service is standardized as RFC5659 by IETF.
When providing communication services, continuity of communication services when a device fails is very important, but it is generally solved by making communication paths redundant. The IETF is also standardizing a tunnel path redundancy method.

RFC3031 Multiprotocol Label Switching Architecture, http: // www. ietf. org / rfc / rfc3031. t segment 1 terminator 301t RFC5659 An Architecture for Multi-Segment Pseudowire Emulsion Edge-to-Edge, http: // www. ietf. org / rfc / rfc5659. t segment 1 terminator 301t

A configuration example of tunnel path redundancy is shown in FIG. 1 (tunnel path redundancy). In FIG. 1, if the inter-segment relay point device at the center fails, communication is interrupted. The point at which communication is interrupted due to a single failure is called a single point of failure. One method for solving this is user line redundancy as shown in FIG. This is effective when there are two or more segment relay points, and makes the user line itself across the segments redundant. However, as described in the previous paragraph, it is necessary for the network manager to negotiate in advance, so it is not easy to perform user line redundancy across segments. A combination of user line redundancy and tunnel path redundancy is shown in FIG.
Tunnel path redundancy, user line redundancy, user line redundancy, and tunnel path redundancy increase the reliability of communication paths that can be provided in this order. In FIG. 1, the communication service can be continued if either one of 110 failures or 111 failures is present, but there is a single point of failure where communication is interrupted if 112 failures occur. In FIG. 2-1, the communication service can be continued if one of the failures is 210 or 211, and there is no single point of failure, but communication occurs when a failure occurs in both 210 and 211 (hereinafter referred to as multiple failures). Is disrupted. In FIG. 2B, the communication service can be continued up to three failures 212 or one failure 213, and the most reliable communication service can be provided.
If the configuration of user line redundancy and tunnel path redundancy in FIG. 2-2 is adopted, there is no single point of failure, and communication service can be continuously provided even if multiple failures occur. However, four communication paths are required between the user and the user for one user line, and the utilization efficiency of the entire network becomes very low. In addition, negotiation between device control servers is required between segments, which is difficult to implement.
In view of the above points, an object of the present invention is to provide a redundant network system, a termination device, and a relay point neighboring device that do not have a single point of failure and can continue communication services even when multiple failures occur. Another object of the present invention is to provide a new redundancy method that can reduce the number of necessary communication paths between users and users from four and can be realized within a segment.

In order to solve the above problems, the following network configuration and means are provided.
Device redundancy is performed at points that become single points of failure, and these are hereinafter referred to as segment relay point device 0 system and segment relay point device 1 system. In addition, tunnel paths are respectively set between four devices adjacent to a single point of failure (hereinafter referred to as segment relay point adjacent devices) and the segment relay point device 0 system and the segment relay point device 1 system ( Hereinafter, they are referred to as a 0 system path and a 1 system path, respectively. The segment relay point neighboring device has a switching function of the 0-system path and the 1-system path. For the terminating device in contact with the user, tunnel path redundancy setting is made with the segment relay point device 0 system and the segment relay point device 1 system. This redundant path is called a working path (working path) and a standby path (protection path).
In the above network, when the relay point neighboring device detects a failure in units of physical ports, the relay point neighboring device includes means for determining which of the 0-system path and the 1-system path the failure port accommodates, and It is equipped with a means to determine whether the 0-system path or 1-system path accommodated on the failed port is a working system that is carrying communication data, or a standby system that is not. A means for creating a failure notification message storing the type of the system / standby system and transmitting it to the terminating device is provided. In addition, the terminating device selects either the tunnel path switching or the 0-system / 1-system switching from a plurality of failure notification messages received from the relay point neighboring device, the segment relay point device 0 system, and the segment relay point device 1 system. Means for determining whether to perform the system switching, and means for transmitting a system switching message to the relay point neighboring device when the system switching is necessary.

According to the first solution of the present invention,
A redundant 0-system relay point device and 1-system relay point device that relays two networks;
In one of the networks, a terminating device disposed on the user side;
Each comprises first and second relay point adjacent devices connected to both the 0-system relay point device and the 1-system relay point device,
Between the termination device and the 0-system relay point device, a 0-system first path through the first relay point adjacent device and a 0-system second network through the second relay point adjacent device. Redundant with the path,
Between the termination device and the 1-system relay point device, a 1-system first path through the first relay-point adjacent device and a 1-system second through the second relay-point adjacent device Redundant with the path,
The terminal device has switching information indicating which of system switching for switching between the 0 system and the 1 system, and path switching for switching between the first path and the second path, corresponding to the combination of the received fault notifications. It has a switching judgment table stored in advance,
When the first and second relay point neighboring devices and the 0-system and 1-system relay point devices detect a network or device failure, the failure notification is transmitted to the termination device,
The terminating device determines whether to perform system switching or path switching by referring to the switching determination table based on the received failure notification combination, and performs redundancy switching or path switching processing according to the determination result. A network system is provided.

According to the second solution of the present invention,
A redundant 0-system relay point device and 1-system relay point device that relays two networks;
In one of the networks, a terminating device disposed on the user side;
Each comprises first and second relay point adjacent devices connected to both the 0-system relay point device and the 1-system relay point device,
Between the termination device and the 0-system relay point device, a 0-system first path through the first relay point adjacent device and a 0-system second network through the second relay point adjacent device. Redundant with the path,
Between the termination device and the 1-system relay point device, a 1-system first path through the first relay-point adjacent device and a 1-system second through the second relay-point adjacent device A terminating device in a network system made redundant with a path,
Switching in which switching information indicating whether to perform system switching for switching between the 0 system and the 1 system and path switching for switching the first path and the second path is stored in advance corresponding to the combination of the failure notifications received. Has a decision table,
From the first and second relay point neighboring devices and the 0-system and 1-system relay point devices, receive a failure notification when a network or device failure is detected,
Based on the received failure notification combination, the terminating device refers to the switching determination table to determine whether to perform system switching or path switching,
The termination device that performs system switching or path switching processing according to the determination result is provided.
According to the third solution of the present invention,
A redundant 0-system relay point device and 1-system relay point device that relays two networks;
On one side of the network, either system switching for switching between the 0 system and the 1 system or path switching for switching between the first path and the second path is performed corresponding to a combination of fault notifications received and received on the user side. A switching determination table in which switching information indicating whether or not to perform is stored in advance, and based on the received failure notification combination, whether to perform system switching or path switching with reference to the switching determination table; ,
Each comprises first and second relay point adjacent devices connected to both the 0-system relay point device and the 1-system relay point device,
Between the termination device and the 0-system relay point device, a 0-system first path through the first relay point adjacent device and a 0-system second network through the second relay point adjacent device. Redundant with the path,
Between the termination device and the 1-system relay point device, a 1-system first path through the first relay-point adjacent device and a 1-system second through the second relay-point adjacent device The relay point neighboring device in a network system made redundant with a path,
When a network or device failure is detected, a failure notification is sent to the terminating device,
When a system switching instruction message transmitted from the terminal device is received in response to the failure notification, the 0-system relay point device and the 1-system relay point device to communicate are switched according to the system switching instruction message,
When a path switching instruction message transmitted from the terminating device in response to a failure notification is received, a relay point neighboring apparatus is provided that transfers the path switching instruction message to the 0-system relay point device and the 1-system relay point device.

  According to the present invention, it is possible to provide a redundant network system, a terminal device, and a relay point neighboring device that do not have a single point of failure and can continue communication services even when multiple failures occur. Further, according to the present invention, the number of required communication paths between users and users is 2, and it is possible to realize communication path redundancy that can be controlled by a conventional apparatus control server.

An example of a MPLS tunnel path redundancy configuration at the time of multi-segment. A configuration example at the time of multi-segment when the user line (PW) is made redundant (route 1 and route 2). An example of a MPLS tunnel path redundancy configuration in multi-segment when user lines (PW) are made redundant (route 1 and route 2). The network block diagram of this invention. List of faults that occur and alarms that are generated. A switching judgment table possessed by the terminating device. The segment relay point apparatus 0 system, segment relay point apparatus 1 system, switching sequence diagram by this invention. Processing flow of segment 1 terminal device: When switching between segment relay point device 0 system and segment relay point device 1 system. Processing flow of segment 1 working side relay point neighboring device: switching of segment relay point device 0 system and segment relay point device 1 system. The apparatus block diagram of a relay point adjacent apparatus and a segment relay point apparatus. FIG. The path information table on the control function part memory of a relay point adjacent apparatus. The transfer process table of the switch function part of a relay point adjacent apparatus. A path information table on the control function unit memory of the segment relay point device 0 system and 1 system. The transfer processing table of the switch function part of the segment relay point device 0 system and 1 system. A path information table on the control function unit memory of the terminal device. The transfer process table of the switch function part of a termination device. The MPLS tunnel path switching sequence diagram by this invention. Process flow of segment 1 termination device: In case of MPLS tunnel path switching (working to protection). Processing flow of relay device adjacent to segment 1 working side: MPLS tunnel path switching (from working to protection). The sequence which fails in the MPLS tunnel path switching by this invention, and switches segment relay point apparatus 0 system and segment relay point apparatus 1 system 308. Process flow of segment 1 termination device: When MPLS tunnel path switching fails and segment relay point device 0 system and segment relay point device 1 system are switched. Process flow of adjacent relay point device on segment 1 working side: When MPLS tunnel path switching fails and segment relay point device 0 system and segment relay point device 1 system switch. AIS frame format. Pre-setting method from the segment 1 control server to the devices in segment 1. Segment relay point device 0 system, segment relay point device 1 system switching sequence according to the present invention: switching determination at relay point neighboring device. Processing flow of the segment 1 terminal device: When switching between the segment relay point device 0 system and the segment relay point device 1 system is determined and executed by the relay point neighboring device. Processing flow of segment 1 working side relay point neighboring device: When switching between segment relay point device 0 system and segment relay point device 1 system is judged and executed by the relay point neighboring device.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 3 is a network system configuration diagram according to this embodiment. A user line is set between the segment 1 termination device 301 belonging to the segment 1 and the segment 2 termination device 304 belonging to the segment 2. The segment relay point has a redundant configuration of segment relay point device 0 system 305 and segment relay point device 1 system 308. Within segment 1, segment 1 termination device 301, segment relay point device 0 system 305, segment relay point device 1 An MPLS tunnel path is redundantly set with the system 308.
The MPLS tunnel path redundancy includes a working path 331 from the segment 1 termination device 301 to the segment relay point device 0 system 305 and the segment relay point device 1 system 308 via the segment 1 working side relay point neighboring device 302 and the segment 1 termination device. It consists of two paths, a protection path 332 from the device 301 to the segment relay point device 0 system 305 and the segment relay point device 1 system 308 via the segment 1 protection side relay point adjacent device 306. Similarly, in the segment 2, the path redundancy of the working path 337 and the protection path 338 is performed between the segment 2 terminal device 304, the segment relay point device 0 system 305, and the segment relay point device 1 system 308.
Segment relay point device 0 system 305, segment relay point device 1 system 308 and adjacent segment 1 working side relay point adjacent device 302, segment 2 working side relay point adjacent device 303, segment 1 protection side relay point adjacent device 306, The MPLS tunnel paths 333, 334, 335, 336, 339, 340, 341, and 342 between the segment 2 protection side relay point adjacent device 307 are hereinafter referred to as section paths.
In addition, this system includes apparatus control servers 108 and 109 for each segment.
Hereinafter, the segment 1 working side relay point adjacent device 302, the segment 1 protection side relay point adjacent device 306, and the segment relay point device 0 series 305 in the segment 1 will be mainly described. , Segment 2 working side relay point adjacent device 303, segment 1 protection side relay point adjacent device 306 and segment 2 protection side relay point adjacent device 307 are equivalent, segment relay point device 0 system 305 and segment relay point device 1 system 308. Since the segment 1 working side relay point adjacent device 302 and the segment 1 protection side relay point adjacent device 306 are also described, the segment 2 working side relay point adjacent device 303, the segment 2 protection side relay point adjacent device 306 It applies to 07, description of the segment relay point apparatus 0 system 305 applies to the segments relay point apparatus 1 system 308.

A path (segment 0 working path) set from the segment 1 termination device 301 through the segment 1 working side relay point adjacent device 302 and the segment relay point device 0 system 305, and the segment 1 working device relay from the segment 1 termination device 301 A path that passes through the point adjacent device 302 and is set as the segment relay point device 1 system 308 (system 1 working path) can be switched at the position of the segment 1 working side relay point adjacent device 302. For example, a user line passing through a segment 1 termination device 301, a segment 1 working side relay point adjacent device 302, a segment relay point device 0 series 305, a segment 2 working side relay point adjacent device 303, and a segment 2 termination device 304 This means switching to a route passing through the device 301, the segment 1 working side relay point adjacent device 302, the segment relay point device 1 system 308, the segment 2 working side relay point adjacent device 303, and the segment 2 termination device 304. Such switching is hereinafter referred to as system switching.
As is apparent from FIG. 3, if the system switching occurs in the segment 1 working side relay point adjacent device 302 in the segment 1 and the user line path is changed from the 0 system to the 1 system, the segment 2 working side relay point in the segment 2 It is necessary to perform system switching also in the adjacent device 303. As a result, the same route is passed in both directions. These system switching is realized by switching the section path in the segment 1 working side relay point neighboring device 302 and the segment 2 working side relay point neighboring device 303. In order to perform system switching, a message for switching control is exchanged between the segment 1 termination device 301, the segment 1 working side relay point adjacent device 302, and the segment 1 protection side relay point adjacent device 306. For this purpose, an MPLS path 361 is prepared exclusively for the main signal.

Further, the redundant switching of the MPLS tunnel path set between the segment 1 termination device 301, the segment relay point device 0 system 305, and the segment relay point device 1 system 308 is performed in the segment 1 termination device 301. As a result, the working path from the segment 1 terminal device 301 to the segment relay point device 0 system 305 / segment relay point device 1 system 308 through the segment 1 working side relay point adjacent device 302 and the segment 1 terminal device 301 to the segment 1 protection Switching between the protection path that passes through the side relay point adjacent device 306 and reaches the segment relay point device 0 system 305 / segment relay point device 1 system 308 is realized. Such switching is hereinafter referred to as path switching. Also in the case of path switching, a message for switching control is exchanged between the segment 1 terminating device 301 and the segment relay point device 0 system 305, and this message uses the same MPLS tunnel path as the main signal.
FIG. 20 shows a sequence for setting the communication path as described above in the segment 1. All set from the device control server 108 to the segment 1 end device 301, the segment 1 working side relay point adjacent device 302, the segment 1 protection side relay point adjacent device 306, the segment relay point device 0 system 305, and the segment relay point device 1 system 308 I do. Similarly, in the segment 2, the setting is performed from the device control server 109 to the segment 2 termination device 304, the segment 2 working side relay point adjacent device 303, and the segment 2 protection side relay point adjacent device 307.
For example, the device control server 108 transmits a control label path setting instruction (port, label) to the segment 1 working side relay point neighboring device and the segment 1 protection side relay point neighboring device to the segment 1 termination device 301 (2001). .
The device control server 108 transmits a control label path setting instruction (port, label) with the segment 1 termination device to the segment 1 working side relay point adjacent device 302 and the segment 1 protection side relay point adjacent device 306 (2002).
The device control server 108 transmits a main signal label path setting instruction with the segment 1 working side relay point neighboring device and the segment 1 protection side relay point neighboring device to the segment 1 termination device 301 (2003). For example, a working path ID, port, label, and protection path ID, port, and label are transmitted.

The device control server 108 transmits the main signal label path to the segment 1 working side relay point adjacent device 302 and the segment 1 protection side relay point adjacent device 306 to the segment 1 termination device, the segment relay point device 0 system, and the segment relay point device 1 system. A setting instruction is transmitted (2004). For example, a path ID, a 0 system port, a 0 system label, a 1 system port, and a 1 system label are transmitted.
The device control server 108 transmits to the segment relay point device 0 system 305 and the segment relay point device 1 system 308 a main signal label path setting instruction with the segment 1 working side relay point adjacent device and the segment 1 protection side relay point adjacent device. (2005). For example, a working path ID, port, label, and protection path ID, port, and label are transmitted.
FIG. 4A shows the types of failures that can occur in the segment relay point device 0 system 305, and failures and transmissions detected by the segment 1 working side relay point adjacent device 302 and the segment 1 protection side relay point adjacent device 306 at that time. A list of alarms to be transmitted, alarms to be transmitted by the segment relay point device, and alarms to be detected by the segment 1 terminal device 301 is shown.
FIG. 4B is a switching determination table for determining whether to perform system switching or path switching based on a combination of these alarms. For example, as illustrated in FIG. 4B, the segment 1 terminal device 301 includes a switch determination table corresponding to a combination of alarms detected by the terminal device (for example, a combination of alarms from the working side and the protection side) and switching information. Have. The switching information indicates whether path switching is performed, system switching is performed, switching is not performed, or the like. The segment 1 terminal device 301 determines a failure that has occurred in the segment relay point device 0 system 305 with reference to this table based on the detected alarm combination, and selects an appropriate one of system switching and path switching.

FIG. 8 shows segment 1 working side relay point adjacent device 302, segment 2 working side relay point adjacent device 303, segment 1 protection side relay point adjacent device 306, segment 2 protection side relay point adjacent device 307, and segment relay point device 0 system. 305 is a device configuration diagram of the segment relay point device 1 system 308. FIG. Each device includes, for example, an MPLS interface function unit 804, a switch function unit 806, and a control function unit 801. The MPLS interface function unit 804 has a function of transmitting / receiving user data (main signal) and an OAM frame to / from other apparatuses. The OAM function unit 805 has a function of creating and interpreting an OAM frame. The switch function unit 806 is connected to a plurality of MPLS interface function units 804, holds the transfer processing tables shown in FIGS. 10-2 and 11-2, refers to the table for each main signal frame, and outputs It has a function of selecting the MPLS interface function unit 804 to be performed. The control function unit 801 includes a CPU 802 and a memory 803. The CPU 802 interprets instructions from the device control servers 108 and 109, and creates and updates the path information table shown in FIGS. 10-1 and 11-1 on the memory 803. It has a function to do. The control function unit 801 also updates the transfer processing table included in the switch function unit 806.
FIG. 9 is a device configuration diagram of the segment 1 termination device 301. The segment 1 termination apparatus 301 includes, for example, an Ethernet interface function unit 902, an MPLS interface function unit 804, a switch function unit 903, and a control function unit 801. The Ethernet interface function unit 902 and the MPLS interface function unit 804 have functions of transmitting / receiving user data (main signal) and OAM frames to / from other devices. For example, the Ethernet interface function unit 902 is connected to the user side, and the MPLS interface function unit 804 is connected to the relay point adjacent device side. The OAM function unit 805 has a function of creating and interpreting an OAM frame. The switch function unit 903 is connected to a plurality of Ethernet interface function units 902 and an MPLS interface function unit 804, holds the transfer processing table shown in FIG. 12-2, and refers to the table for each main signal frame. The interface function unit 902 such as the Ethernet to be output or the MPLS interface function unit 804 is selected. The control function unit 801 has a CPU 802 and a memory 803. The CPU 802 has a function of interpreting instructions from the device control servers 108 and 109 and creating / updating the path information table 901 shown in FIG. Also, the transfer processing table of the switch function unit 903 is updated. The configuration of the segment 2 termination device 304 is the same.

FIG. 10A is a path information table stored in the memory 803 of the relay point neighboring device. FIG. 10B is a transfer processing table held by the switch function unit 806 of the relay point neighboring device. FIG. 11A is a path information table held on the memory 803 of the segment relay point device. FIG. 11B is a transfer processing table held by the switch function unit 806 of the segment relay point device. FIG. 12A is a path information table held on the memory 803 of the terminal device. FIG. 12B is a transfer processing table held by the switch function unit 903 of the terminating device.
In the path information table of FIG. 10A, for example, input information 1001, outgoing / exit route information 1004, main signal output port 1009, and path ID 1010 are stored in association with each other. The input information 1001 includes an input port 1002 and a label value 1003. The outgoing / exit route information 1004 includes a 0-system output port 1005 and its label value 1006, a 1-system output port 1007 and its label value 1008.
In the transfer processing table of FIG. 10-2, for example, the search key 1011 and the outgoing / exit route information 1014 are stored correspondingly. The search key 1011 includes a path ID 1010, an input port 1012, and a label value 1013. The exit / release route information 1014 includes an output port 1015 and a label value 1016.
In the path information table of FIG. 11A, for example, a search key 1101 and outgoing / exit route information 1105 are stored in association with each other. The search key 1101 includes a path ID 1102, an input port 1103, and a label value 1104. The outgoing / exit route information 1105 includes a working output port 1106, its label value 1107, its path ID 1108, a protection output port 1109, its label value 1110, and its path ID 1111.
In the transfer processing table of FIG. 11B, for example, a search key 1112 and outgoing / exit route information 1115 are stored in association with each other. The search key 1112 includes an input port 1113 and a label value 1114. The exit / release route information 1115 includes an output port 1116 and a label value 1117.
In the path information table of FIG. 12A, for example, a search key 1201 and outgoing / exit route information 1205 are stored in association with each other. The search key 1201 includes a path ID 1202, an input port 1203, and a destination MAC address 1204. The outgoing / exit route information 1205 includes a working port 1206, a label value 1207, a path ID 1208, a protection port 1209, a label value 1210, a path ID 1211, and a main signal output port 1212.

In the transfer processing table of FIG. 12-2, for example, a search key 1213 and outgoing / exit route information 1216 are stored in association with each other. The search key 1213 includes an input path 1202, an input port 1214, and a destination MAC address 1215. The exit / release route information 1216 includes an output port 1217 and a label value 1218.
The label values in FIGS. 10-1, 10-2, 11-1, 11-2, 12-1, and 12-2 indicate label values that are assigned one-to-one to the MPLS tunnel path. The path ID is an identifier assigned by the device control servers 108 and 109 in order to uniquely identify each MPLS tunnel path. In this specification, the MPLS tunnel path made redundant with the first 5 digits is identified, and the working and protection are identified with the last 1 digit. However, there is no particular rule, and it is free as long as it does not overlap in the entire network. May be set to
FIG. 5 is a sequence diagram when system switching is performed in the network shown in FIG. In the figure, user data (main signal) is indicated by a solid line, and an OAM frame for failure detection is indicated by a dotted line. As for the main signal, a black circle indicates which of the segment 1 working side relay point adjacent device 302 and the segment 1 protection side relay point adjacent device 306 is routed. The OAM frame is also transmitted on the MPLS tunnel path in the same manner as the main signal. However, although the main signal is transmitted by selecting either the working path or the protection path, the OAM frame is always transmitted independently on both the working path and the protection path.
For example, when a failure 311 occurs in the segment relay point device 0 system 305 (501), a LINKDOWN alarm is detected by the segment 1 working side relay point adjacent device 302 and the segment 1 protection side relay point adjacent device 306 (502). With this as a trigger, the segment 1 working side relay point neighboring device 302 and the segment 1 protection side relay point neighboring device 306 each send an AIS (Alarm Indication Signal) message to the segment 1 termination device 301 (503). This AIS is for notifying that some kind of failure has occurred. In this example, the segment 1 working side relay point adjacent device 302 and the segment 1 protection side relay point adjacent device 306 transmit a tunnel AIS (0 system) indicating a 0-system failure to the segment 1 termination device 301 as will be described later. . For example, the configuration of the segment 1 working side relay point neighboring device 302 and the segment 1 protection side relay point neighboring device 306 is as shown in FIG. 8, and the segment 1 working side relay point neighboring device 302 and the segment 1 protection side relay point neighboring device 306 are adjacent to each other. Details of the processing in the apparatus 306 will be described later with reference to FIG.

  When the segment 1 working side relay point adjacent device 302 and the segment 1 protection side relay point adjacent device 306 transmit the AIS to the segment 1 termination device 301, they are sent using the MPLS tunnel path in the same manner as the main signal. Therefore, when the segment 1 termination device 301 receives the AIS, it can know which MPLS tunnel path has failed, that is, which of the working path and the protection path constituting the redundancy has failed. When received from both the working path and the protection path, there is a possibility of failure in a location where both paths are common, for example, the segment relay point device 0 system 305 / segment relay point device 1 system 308. In the case of FIG. 5, the AIS is received from the segment 1 working side relay point neighboring device 302 by the working path, and the AIS is received from the segment 1 protection side relay point neighboring device 306 by the protection path (504). This corresponds to # 7. The segment 1 termination device 301 refers to the switching determination table 901 as shown in FIG. 4-2 and knows that system switching should be performed (505). As described in the explanation of FIG. 3, since the system switching is performed by the segment 1 working side relay point adjacent device 302 and the segment 1 protection side relay point adjacent device 306, the segment 1 termination device 301 is adjacent to the segment 1 working side relay point. A system switching instruction is sent to the device 302 and the segment 1 protection side relay point neighboring device 306 (506). The segment 1 working side relay point neighboring device 302 and the segment 1 protection side relay point neighboring device 306 perform section path switching triggered by this system switching instruction (507). If this switching is successful, a switching completion notification is transmitted to the segment 1 termination device 301 (508). The segment 1 termination device 301 receives the switching completion notification to complete the system switching process. The configuration of the segment 1 termination device 301 is as shown in FIG. 9, and the processing in the segment 1 termination device 301 will be described later with reference to FIG.

FIG. 6 is a processing flow diagram in the segment 1 termination apparatus 301 when system switching is performed.
First, in step 600, the segment 1 termination device 301 transmits user data (main signal) on the working path (the route passing through the segment 1 termination device 301, the segment 1 working side relay point neighboring device 302, and the segment relay point device 0 system 305). Is transmitting. In step 601, the segment 1 termination device 301 receives the AIS (504). The segment 1 terminator 301 continues to receive AIS for a predetermined period after receiving one AIS. The segment 1 termination device 301 knows that some failure has occurred by receiving this AIS. At this time, in consideration of the difference in processing delay time between the segment 1 working side relay point adjacent device 302 and the segment 1 protection side relay point adjacent device 306, another AIS reception is waited for a predetermined time, for example, 10 milliseconds. In step 602, the segment 1 termination apparatus 301 refers to the switching determination table 901 shown in FIG. 4B based on the received plurality of AISs, and determines whether or not system switching is necessary and path switching is necessary.

Steps 610 to 613 shown on the right side of FIG. In step 610, the segment 1 termination device 301 repeats the loop of 611 to 613 for all the path IDs included in the received AIS. In step 611, the segment 1 termination device 301 checks the 0 system / 1 system and ACT / STANDBY set in the AIS including the path ID. In step 612, it is checked whether all the results of step 611 are STANDBY. If YES, the loop is exited and the process returns to 610, and the processing from step 611 onward is executed for other path IDs. If NO, the segment 1 termination device 301 determines whether or not switching is necessary in step 613. If the AIS received from both the segment 1 working side relay point adjacent device 302 and the segment 1 protection side relay point adjacent device 306 is 0 system and ACT, the system is switched from the 0 system to the 1 system. Switch to. When VC AIS is received from the segment relay point device 0 system, the system is switched from the 0 system to the 1 system, and when VC AIS is received from the segment relay point apparatus 1 system, the system is switched from the 1 system to the 0 system.
When it is determined in step 602 that system switching is necessary, the segment 1 termination apparatus 301 transmits a system switching instruction to the segment 1 working side relay point adjacent apparatus 302 and the segment 1 protection side relay point adjacent apparatus 306 in step 603. (506). The system switching is performed by switching the section path in the segment 1 working side relay point adjacent device 302 and the segment 1 protection side relay point adjacent device 306. That is, switching is performed for each MPLS tunnel path. Therefore, the MPLS tunnel path to be switched is specified by setting the target path ID, and a system switching instruction is transmitted to the segment 1 working side relay point neighboring device 302 and the segment 1 protection side relay point neighboring device 306. Here, the target path ID is an ID of a path (path ID included in the AIS) for which path switching / path switching is determined for each path based on the AIS as described above, and path switching is determined. Thereafter, in step 604, a switching completion notification from the segment 1 working side relay point adjacent device 302 and the segment 1 protection side relay point adjacent device 306 is waited for a predetermined period. When these are received, the switching process is completed and a normal state is obtained. Note that if the switch completion notification is not received within a predetermined period, it is determined that the system switch has failed. In this case, the processing is the same as that in FIG.

FIG. 7 is a processing flow diagram in the segment 1 working side relay point adjacent device 302 when system switching is performed. The same applies to the segment 1 protection side relay point neighboring device 306.
First, in step 700, the segment 1 working side relay point neighboring device 302 transmits a main signal toward the segment relay point device 0 system 305. Here, for example, a failure 311 occurs in the segment relay point device 0 system 305, and in step 701, the segment 1 working side relay point adjacent device 302 detects a LINKDOWN alarm at the port number 9 of the segment 1 working side relay point adjacent device 302. (Corresponding to 502). In step 702, the segment 1 working side relay point neighboring device 302 searches the MPLS tunnel path group G having the port number 9 as an output port, using the path information table in the memory shown in FIG. In FIG. 10A, since the output port 0 system 1005 of the first entry is 9, this path corresponds to the MPLS tunnel path group G.
Next, in step 703, the segment 1 working side relay point neighboring device 302 determines whether each of the MPLS tunnel path group G is 0-system or 1-system, ACT, or STANDBY. Specifically, the determination is made with reference to the path information table of FIG. That is, the segment 1 working side relay point neighboring device 302 has the main signal output port (1009) s, the output port 0 system (1005), and the output port 1 system (1007) of the entry belonging to the MPLS tunnel path group G in the path information table. Check out. When the main signal output port s coincides with the output port 0 system (1005), it is 0 system ACT and 1 system STANDBY. When the main signal output port s matches the output port 1 system (1007), the system is ACT 1 and 0 system STANDBY.
In step 704, the segment 1 working side relay point neighboring device 302 creates an AIS message in the format shown in FIG. Next, in Step 705, the segment 1 working side relay point neighboring device 302 adds the 0 system / 1 system, ACT / STANDBY determined in Step 703 to the portion described as TLVs of the created AIS message (FIG. 19). Set the distinction. Further, the segment 1 working side relay point neighboring device 302 also sets the path ID 1010 obtained from the path information table of FIG. Next, in step 706, the segment 1 working side relay point neighboring device 302 transmits the created AIS to the segment 1 termination device 301 (corresponding to 503).

After a while, an instruction for switching the system to the first system is sent from the device segment 1 terminal device 301 (506), and is received in step 707. Since the target path ID is included in the switching instruction, in Step 708, the segment 1 working side relay point neighboring device 302 searches the path information table (FIG. 10-1) based on this path ID (1010). , The output port 1 system (1007) and the label value (1008) of the corresponding entry E are obtained. Here, whether to acquire the 0-system information 1005 and 1006 or the 1-system information 1007 and 1008 can be determined by an appropriate method. For example, the system switching instruction may include system information after switching indicating whether to switch to the 0 system or the 1 system, and the 0 system or 1 system information may be acquired in accordance with the system information. Further, since it can be determined in step 705 whether the failure is the 0 system / 1 system, information on the other system may be acquired. In the next step 709, the segment 1 working side relay point neighboring device 302 uses the acquired output port 1 system (1007) and label value (1008), and uses the transfer processing table of the switch function unit 806 (FIG. 10-2). ) Of the entry corresponding to the path ID (1010) of () is updated. As a result, in the segment 1 working side relay point adjacent device 302, the main signal input with respect to the path is searched for the first route for the system 1 with reference to the transfer table, and the section to the segment relay point device 1 system 308 is searched. It will be output to the path. Further, the segment 1 working side relay point neighboring device 302 updates the value of the main signal output port (1009) of the entry E in the path information table (FIG. 10-1) with the value of the output port 1 system (1007). Finally, in step 710, a switch completion notification is created and transmitted to the segment 1 termination device 301 (corresponding to 508).
In the above example, the segment 1 side has been described, but the same processing is performed on the segment 2 side to perform system switching.
The operation and processing at the time of system switching have been described so far. Next, MPLS tunnel path switching will be described with reference to FIGS.

13 is a sequence diagram of path switching, FIG. 14 is a processing flow diagram in the segment 1 termination device 301, and FIG. 15 is a processing flow diagram in the segment 1 working side relay point adjacent device 302. Various symbols in FIG. 13 are the same as those in FIG.
The difference between FIG. 13 and FIG. 5 is that, for example, a failure 311 occurred in the segment relay point device 0 system 305 (1301), but the failure was detected in the segment 1 working side relay point neighboring device 302 because it was a partial failure. (1302) is an example in which the segment 1 protection side relay point neighboring device 306 does not detect a failure. In this case, the segment 1 working side relay point neighboring device 302 notifies the segment 1 terminating device 301 of the AIS (1303), but the segment 1 protection side relay point neighboring device 306 does not notify the segment 1 terminating device 301. Therefore, the segment 1 termination device 301 receives only the working-side AIS (1304), and corresponds to # 1 of the switching determination table 901 in FIG. 4B, and selects path switching (1305).
Next, regarding path switching, system switching is performed by the segment 1 working side relay point adjacent device 302 and the segment 1 protection side relay point adjacent device 306, but path switching is performed by the segment 1 termination device 301. In addition, the path switching is also performed in the segment relay point device 0 system 305 facing the segment 1 terminal device 301 for matching. As a result, the same path is passed in both directions. Specifically, first, the segment 1 terminal device 301 transmits an instruction to switch to the protection path to the segment relay point device 0 system 305 (1306). When the path switching is completed in the segment relay point device 0 system 305 (1307), the segment relay point device 0 system 305 sends a path switching completion switching response to the segment 1 termination device 301 (1308). The path switching instruction and the path switching completion switching response are transferred, for example, by the segment 1 protection side relay point neighboring device 306 not notified of the failure.
The segment 1 termination device 301 executes its own path switching triggered by the reception of the switching response from the segment relay point device 0 system 305 (1309). The method of synchronizing the switching between the terminal device 301 and the segment relay point device 0 system is not limited to the above, and for example, APS (Automatic Protection Switching) defined by the ITU (International Telecommunication Union) can be used. As a result, the main signal communicates and the normal state is restored.

FIG. 14 shows a path switching process flow in the segment 1 termination apparatus 301. Steps 1400 to 1402 are the same as steps 600 to 602 in FIG. If path switching is necessary as a result of the switching determination with reference to the switching determination table 901 shown in FIG. 4-2 in step 1402, the segment 1 termination device 301 determines the segment relay point device 0 system 305 in step 1403. A path switching instruction message is transmitted (1306). Since it is path switching, it is necessary to switch one MPLS tunnel path at a time. Therefore, the segment 1 termination apparatus 301 sets the path ID to be switched in the path switching instruction message. The path ID to be switched is an ID of a path that is determined to be switched based on the AIS for each path as in the case of the system switching described above. Here, one path ID may be set for one instruction, or a plurality of path IDs may be set for one instruction.
After a while, the segment 1 termination device 301 receives a switching response (1308) from the segment relay point device 0 system 305 in step 1404. In step 1405, the segment 1 terminating device 301 searches the path information table (FIG. 12-1) using the path ID (1202) to be switched as a key, and acquires the corresponding protection port (1209) and label value (1210). To do. In step 1406, the segment 1 termination device 301 sets the output port (1217) and the label value (1218) of the outgoing route (1216) of the entry indicated by the path ID (1202) in the transfer processing table (FIG. 12-2). , Update with the acquired protection port (1209) and label value (1210). As a result, the main signal is output to the protection path.

FIG. 15 is a path switching process flow in the segment 1 working side relay point neighboring apparatus 302. The difference from FIG. 7 is that step 707 and subsequent steps in FIG. 7 do not exist, and steps 1500 to 1506 correspond to steps 700 to 706 in FIG.
The segment relay point device 0 system 305 receives the path switching instruction message (1608) from the segment 1 termination device 301. The segment relay point device 0 system 305 searches the path information table (FIG. 11-1) using the path ID to be switched included in the instruction as a key, and obtains the corresponding protection port (1109) and label value (1110). The output port (1116) and label value (1117) of the outgoing route (1115) of the corresponding entry indicated by the path ID (1202) of the segment relay point device 0 system 305 transfer processing table (FIG. 11-2) Update the acquired protection port (1109) and label value (1110). The corresponding entry acquires, for example, the input port (1103) and label value (1104) corresponding to the path ID to be switched in the path information table, and corresponds to the input port (1113) and label value (1114) of the transfer processing table. The entry to be performed may be specified. Further, the path ID may be stored in the transfer processing table, and the entry corresponding to the path ID to be switched may be specified. In addition, an appropriate method may be used. As a result, the main signal for the segment 1 termination device 301 is output to the protection path. The segment relay point device 0 system 305 transmits, for example, a switching response (1308) to the segment 1 termination device 301 after switching.
In the above example, the segment 1 side has been described, but the same operation is possible on the segment 2 side.
The operation and processing at the time of path switching has been described above. Next, a case where system switching is performed after MPLS tunnel path switching has failed will be described with reference to FIGS. Even when path switching is not successful due to some kind of failure, system switching is performed to ensure communication.

16 is a sequence diagram of path switching, FIG. 17 is a processing flow diagram in the segment 1 termination device 301, and FIG. 18 is a processing flow diagram in the segment 1 working side relay point neighboring device 302.
Various symbols in FIG. 16 are the same as those in FIG. FIG. 16 is a combination of the part before switching to protection (1309) in the segment 1 terminal device 301 in FIG. 13 and the part after system switching (from system 0 to system 1) in FIG. 5 (505). is there. Note that switching to protection fails in step 1607, and a switching failure response is transmitted in step 1608. After the segment 1 termination device 301 has transmitted one of the system switching and path switching instructions, for example, the segment 1 terminating apparatus 301 has switched by receiving a switching failure response or not receiving a response to the switching instruction within a predetermined time. Detect that failed.
FIG. 17 also shows the flow from 1400 to 1404 in FIG. 14 and the flow in 603 and 604 in FIG. However, in step 1704, a switching failure response is received. If the switch completion notice (1611) cannot be received in step 1706, it is determined in step 1707 that both systems have failed, and the communication service is interrupted.
FIG. 18 is the same as FIG.
On the contrary, path switching may be executed after system switching fails.
Finally, when performing system switching in FIGS. 21, 22, and 23, the case where the switching instruction is not sent from the segment 1 termination device 301 but the system switching determination is performed in the segment 1 working side relay point neighboring device 302 will be described. To do.
FIG. 21 is a sequence diagram when the system switching determination is performed in the segment 1 working side relay point neighboring device 302. When the LINKDOWN is detected (2102) in the segment 1 working side relay point neighboring device 302, the system is immediately switched (2103), and a switching completion notification is transmitted to the segment 1 terminating device 301 (2104). The segment 1 termination device 301 knows the fact that the system has been switched by the switching completion notification (2104) from the segment 1 working side relay point neighboring device 302.
At this time, the segment 1 protection side relay point adjacent device 306 in the protection path does not know the fact of system switching and is inconsistent with the working path. Therefore, in order to eliminate this, the segment 1 end device 301 is adjacent to the segment 1 protection side relay point. A system switching instruction is sent to the apparatus 306 (2108). The segment 1 protection side relay point neighboring device 306 receives the switching instruction, performs system switching (2109), and sends a switching completion notification to the segment 1 termination device 301 (2110). The segment 1 termination device 301 returns to the normal state upon receiving the switching completion notification from the segment 1 protection side relay point neighboring device 306. The system switching process in each device is the same as in the above example.

FIG. 22 is a processing flowchart in the segment 1 termination device 301. 6 and 14, the difference is that the AIS received from the segment 1 protection side relay point neighboring device 306 makes a switching judgment because the switching completion notification is received from the segment 1 working side relay point neighboring device 302. Is ignored (2202). This is because the system switching has already been performed in the segment 1 working side relay point neighboring device 302, and it is determined that the system switching is also performed in the segment 1 protection side relay point neighboring device 306 for matching. is there.
FIG. 23 is a processing flow diagram in the segment 1 working side relay point neighboring device 302. Processes similar to those in FIG. 7 are denoted by the same reference numerals. The difference from FIG. 7 is that the processing of steps 704 to 706 in FIG. 7 is performed for the path determined as STANDBY in step 703, and the processing of steps 2305 and 709 to 710 is performed for the path determined to be ACT. is there. In step 2305, the segment 1 working side relay point neighboring device 302 searches the path information table for the path determined to be ACT in the tunnel path group G by the path ID, and obtains the output port 1 system and the label value.
In the example of FIG. 21, the segment 1 working-side relay point neighboring device 302 is ACT, and the processing after step 2305 is executed. The flow of the segment 1 protection side relay point adjacent device 306 is the same. In the example of FIG. 21, the segment 1 protection side relay point adjacent device 306 is STANBY, and the processing of steps 704 to 706 is executed.

  The present invention can be used, for example, in a network system in which relay devices between segments are made redundant.

101 Segment 1 Termination Device 102 Segment 1 Relay Point Neighboring Device 103 Segment 2 Relay Point Neighboring Device 104 Segment 2 Termination Device 105 Segment Relay Point Device 106 Segment 1 Relay Point Neighboring Device 107 Segment 2 Relay Point Neighboring Device 108 Segment 1 Device Control Server 109 Segment 2 device control server 110 Device failure in segment 1 Device failure in segment 2 Device failure in segment relay point device 131 Segment 1 working path 132 Segment 1 protection path 133 Segment 2 working path 134 Segment 2 protection path 210 Active Device failure on PW 211 Device failure on standby PW 212 Device failure in segment 1 213 Device failure on segment relay point device 221 Segment
222 Segment 2
231 Path 1: Active user line 232 Path 2: Standby user line 241 Segment 1: Path 1: Working path 242 Segment 1: Path 1: Protection path 243 Segment 1: Path 2: Working path 244 Segment 1: Path 2: Protection path 245 Segment 2: Path 1: Working path 246 Segment 2: Path 1: Protection path 247 Segment 2: Path 2: Working path 248 Segment 2: Path 2: Protection path 301 Segment 1 termination device 302 according to the present invention Segment 1 according to the present invention Relay point adjacent device 303 Segment 2 relay point adjacent device 304 according to the present invention Segment 2 termination device 305 according to the present invention Segment relay point device according to the present invention (system 0)
306 Segment 1 relay point adjacent device 307 according to the present invention Segment 2 relay point adjacent device 308 according to the present invention 308 Segment relay point device according to the present invention (system 1)
311 Failed fault 331 Segment 1: Working path 332 Segment 1: Protection path 333 Segment 1: Working path: 0 system path 334 Segment 1: Working path: 1 system path 335 Segment 1: Protection path: 0 system path 336 Segment 1: Protection path: 1 system path 337 Segment 2: Working path 338 Segment 2: Protection path 339 Segment 2: Working path: 0 system path 340 Segment 2: Working path: 1 system path 341 Segment 2: Protection path: 0 system path 342 Segment 2: Protection path: 1 system path 351 AIS (0 system) notification 361 Switching control path 801 Control function unit 802 CPU
803 Memory 804 MPLS interface function unit 805 OAM function unit 806 Switch function unit 901 Switching determination table 902 Ethernet interface function unit 903 Switch function unit

Claims (20)

A redundant 0-system relay point device and 1-system relay point device that relays two networks;
In one of the networks, a terminating device disposed on the user side;
Each comprises first and second relay point adjacent devices connected to both the 0-system relay point device and the 1-system relay point device,
Between the termination device and the 0-system relay point device, a 0-system first path through the first relay point adjacent device and a 0-system second network through the second relay point adjacent device. Redundant with the path,
Between the termination device and the 1-system relay point device, a 1-system first path through the first relay-point adjacent device and a 1-system second through the second relay-point adjacent device Redundant with the path,
The terminal device has switching information indicating which of system switching for switching between the 0 system and the 1 system, and path switching for switching between the first path and the second path, corresponding to the combination of the received fault notifications. It has a switching judgment table stored in advance,
When the first and second relay point neighboring devices and the 0-system and 1-system relay point devices detect a network or device failure, the failure notification is transmitted to the termination device,
The terminating device determines whether to perform system switching or path switching by referring to the switching determination table based on the received failure notification combination, and performs redundancy switching or path switching processing according to the determination result. Network system. When the terminal device performs system switching, it transmits a system switching instruction message to the first and second relay point neighboring devices,
2. The redundant network system according to claim 1, wherein the first and second relay point neighboring devices switch between the 0-system relay point device and the 1-system relay point device to communicate in accordance with a system switching instruction message. When the path switching is performed, the terminating device switches a path used for communication to a standby path that is one of the first path and the second path, and further, the 0-system relay point device or the 1-system relay point device Send a path switching instruction message to
The redundant network system according to claim 1, wherein the 0-system relay point device or the 1-system relay point device that has received the path switching instruction message switches a path used for communication to a standby path. The first and second relay point neighboring devices are:
A first path information table storing 0-system output port information and path label values, 1-system output port information and path label values, for each path;
First transfer for storing output port information and path information including path label value for each path, and adding the label value to the input signal and transferring it to the port indicated by the output port information A processing table,
When the system switching instruction message is received, the output port information and the path label value corresponding to the system after switching are specified with reference to the first path information table, and the outgoing / exit path information of the first transfer processing table is stored in the first transfer processing table. The redundant network system according to claim 2, wherein the output port information and the path label value are rewritten. The terminator is
A second path information table storing the output port information of the standby path and the label value of the path for each path;
Output / route information including output port information and a path label value is stored for each path, and the second transfer for transferring the input signal to the port indicated by the output port information with the label value added A processing table,
If it is determined that the path switching is to be performed, the output port information of the standby path and the label value of the path are specified with reference to the second path information table, and the outgoing / exit route information of the second transfer processing table is set to The redundant network system according to claim 3, wherein the redundant network system is rewritten with a path label value. The 0-system and 1-system relay point devices are
A third path information table storing the output port information of the standby path and the label value of the path for each path;
Output / route information including output port information and a label value of the path is stored for each path, and the third transfer for transferring the label value to the input signal and transferring it to the port indicated by the output port information A processing table,
When the path switching instruction message is received, the output port information of the standby path and the label value of the path are specified with reference to the third path information table, and the output port information of the third transfer processing table is set to the output port information and The redundant network system according to claim 3, wherein the redundant network system is rewritten with a path label value. The first and second relay point neighboring devices are:
First path in which 0-system output port information, 1-system output port information, and working-system identification information for identifying which of the 0-system and the 1-system is the active system are stored for each path. Has an information table,
When a link-down is detected at a predetermined port, the first path information table is referenced to determine whether the port is 0-system or 1-system, and the 0-system or 1-system determined based on the working system identification information is 2. The redundant network according to claim 1, wherein the redundant network determines whether the current system is a standby system and transmits the failure notification including information indicating the determined 0 system or 1 system and information indicating the current system or the standby system to the terminal device. system.   The redundant network system according to claim 7, wherein the termination device determines whether to perform system switching or path switching, using a failure notification including information indicating the active system among the received failure notifications. The terminator is
When it is determined to perform system switching based on a failure notification including information indicating system 0, a system switching instruction message for switching to system 1 is transmitted to the first and second relay point neighboring devices,
The system switching instruction message for switching to the 0 system is transmitted to the first and second relay point neighboring devices when it is determined to perform the system switching based on the failure notification including information indicating the 1 system. Redundant network system.   When the termination device receives a switching failure response after transmitting one of the system switching or path switching instructions, or if it does not receive a response to the switching instruction within a predetermined time, the terminating device performs system switching or path switching. The redundant network system according to claim 1, wherein the other process is executed. A redundant 0-system relay point device and 1-system relay point device that relays two networks;
In one of the networks, a terminating device disposed on the user side;
Each comprises first and second relay point adjacent devices connected to both the 0-system relay point device and the 1-system relay point device,
Between the termination device and the 0-system relay point device, a 0-system first path through the first relay point adjacent device and a 0-system second network through the second relay point adjacent device. Redundant with the path,
Between the termination device and the 1-system relay point device, a 1-system first path through the first relay-point adjacent device and a 1-system second through the second relay-point adjacent device A terminating device in a network system made redundant with a path,
Switching in which switching information indicating whether to perform system switching for switching between the 0 system and the 1 system and path switching for switching the first path and the second path is stored in advance corresponding to the combination of the failure notifications received. Has a decision table,
From the first and second relay point neighboring devices and the 0-system and 1-system relay point devices, receive a failure notification when a network or device failure is detected,
Based on the received failure notification combination, the terminating device refers to the switching determination table to determine whether to perform system switching or path switching,
The termination device that performs system switching or path switching processing according to a determination result.   When the terminal device performs system switching, a system switching instruction message for switching between the 0-system relay point device and the 1-system relay point device with which the first and second relay point neighboring devices communicate, The terminal device according to claim 11, which transmits to the first and second relay point neighboring devices.   When the path switching is performed, the terminating device switches a path used for communication to a standby path that is one of the first path and the second path, and further, the 0-system relay point device or the 1-system relay point device The terminal device according to claim 11, which transmits a path switching instruction message. The terminator is
A second path information table storing the output port information of the standby path and the label value of the path for each path;
Output / route information including output port information and a path label value is stored for each path, and the second transfer for transferring the input signal to the port indicated by the output port information with the label value added A processing table;
When it is determined that the path switching is to be performed, the output port information of the standby path and the label value of the path are specified with reference to the second path information table, and the outgoing / exit route information of the second transfer processing table is set to the output port information and The termination device according to claim 13, wherein the termination device is rewritten with a label value of a path.   The termination apparatus according to claim 11, wherein the termination apparatus determines whether to perform system switching or path switching, using a failure notification including information indicating the active system among the received failure notifications. The terminator is
When it is determined to perform system switching based on a failure notification including information indicating system 0, a system switching instruction message for switching to system 1 is transmitted to the first and second relay point neighboring devices,
If it is determined that carrying out based system switching in the failure notification including information indicating a system, according to claim 11 for transmitting the system switching instruction message for switching the 0-system to the first and second relay point adjacent device Termination device.   When the termination device receives a switching failure response after transmitting one of the system switching or path switching instructions, or if it does not receive a response to the switching instruction within a predetermined time, the terminating device performs system switching or path switching. The termination device according to claim 11, which executes the other process. A redundant 0-system relay point device and 1-system relay point device that relays two networks;
On one side of the network, either system switching for switching between the 0 system and the 1 system or path switching for switching between the first path and the second path is performed corresponding to a combination of fault notifications received and received on the user side. A termination device that has a switching determination table in which switching information indicating whether to perform is stored in advance and determines whether to perform system switching or path switching with reference to the switching determination table based on a combination of received failure notifications When,
Each comprises first and second relay point adjacent devices connected to both the 0-system relay point device and the 1-system relay point device,
Between the termination device and the 0-system relay point device, a 0-system first path through the first relay point adjacent device and a 0-system second network through the second relay point adjacent device. Redundant with the path,
Between the termination device and the 1-system relay point device, a 1-system first path through the first relay-point adjacent device and a 1-system second through the second relay-point adjacent device The relay point neighboring device in a network system made redundant with a path,
When a network or device failure is detected, a failure notification is sent to the terminating device,
When a system switching instruction message transmitted from the terminal device is received in response to the failure notification, the 0-system relay point device and the 1-system relay point device to communicate are switched according to the system switching instruction message,
When receiving a path switching instruction message transmitted from the terminal apparatus in response to a failure notification, the relay point neighboring apparatus transfers the path switching instruction message to the 0-system relay point apparatus and the 1-system relay point apparatus. A path information table in which 0-system output port information and path label values, 1-system output port information and path label values are stored for each path;
Transfer processing table for storing output port information and path information including the label value of the path for each path, and adding the label value to the input signal and transferring it to the port indicated by the output port information And
When the system switching instruction message is received, the output port information and the path label value corresponding to the system after switching are identified with reference to the path information table, and the output port information of the transfer processing table is set as the output port information and The relay point adjacent device according to claim 18, wherein the relay point adjacent device is rewritten to a label value of a path. A path information table in which 0-system output port information, 1-system output port information, and working-system identification information for identifying which of the 0-system and the 1-system is the active system are stored for each path. Have
When a link-down is detected at a predetermined port, the path information table is referenced to determine whether the port is 0-system or 1-system, and 0-system or 1-system determined based on the active system identification information is the active system 19. The relay point adjacent apparatus according to claim 18, wherein the relay point neighboring apparatus transmits a failure notification including information indicating the determined 0 system or 1 system and information indicating the active system or the standby system to the termination apparatus. .

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