JP5527616B2 - Network system - Google Patents

Description

  The present invention relates to a network system.

  Conventionally, when two long-distance networks are connected by a relay link for long-distance transmission, the network device and the relay link are connected between the network device (switching hub) and the relay link in the network. There is known a prior art in which a network connection device (media converter) that performs medium conversion with the network is connected (for example, see Patent Document 1).

  In this prior art, when a failure occurs in a transmission path between one network device and a network connection device connected to the network device, the network connection device that detects the failure transmits a signal to the other network connection device. The other network connection apparatus that detects that the transmission is stopped and the signal from one network connection apparatus is not received is operated to stop the signal to the network device connected thereto. This makes it possible to notify the other network device of a failure that has occurred in the transmission path between one network device and the network connection device connected thereto.

JP 2004-187213 A

  On the other hand, the operation of a network defined by the international recommendation “Y.1731” standard of ITU-T (International Telecommunication Union Telecommunication Standardization Sector) and the communication standard of IEEE (Institute of Electrical and Electronics Engineers) 802.1ag, Ethernet (registered trademark) OAM (Operations Administration Maintenance) related to maintenance and management is known (hereinafter, “Ethernet (registered trademark) OAM” is abbreviated as OAM).

  It is assumed that the OAM function is implemented in the conventional media converter, and the connectivity between one media converter and the other media converter is monitored using the OAM CC (Continuity Check) function. The

  In this technique, it is preferable that the CC function of the OAM installed in the media converter can be applied to an operation for notifying a switching hub connected to the media converter of a failure occurring in the transmission path.

  Therefore, an object of the present invention is to provide a technique capable of notifying a switching hub connected to a media converter of a failure that has occurred in a transmission path by using the CC function of OAM.

  In order to achieve the above object, a network system of the present invention is connected to a first network repeater, a first network connection device connected to the first network repeater, and a first network connection device. A second network connection device and a second network repeater connected to the second network connection device, wherein the first network connection device and the second network connection device Monitors the connectivity of communication between each other by transmitting the OAM CCM frame to the other party, and the CCM frame has a fault information storage area for storing fault information, When the first network connection device detects the occurrence of a failure with the first network repeater, the failure information of the CCM frame Storing the fault information in the pay area, the second network connection device, when receiving the CCM frame fault information is stored in the fault information storage area, it notifies the occurrence of the fault to the second network repeater.

  According to the network system of the present invention, it is possible to notify a switching hub connected to a media converter of a failure that has occurred in a transmission path by using the CC function of OAM.

1 is a diagram schematically showing a configuration of a network system. It is a figure which shows the structural example of a CCM frame roughly. It is a figure which shows the detailed structure of the Optional TLVs area | region contained in a CCM frame. It is a figure which shows the operation | movement which notifies generation | occurrence | production of the failure using a CCM frame when a failure generate | occur | produces in the communication path | route which goes to a switching hub from a media converter. It is a figure which shows the operation | movement which notifies generation | occurrence | production of the failure using a CCM frame when a failure generate | occur | produces in the communication path | route which goes to a media converter from a switching hub. It is a figure which shows the operation | movement which notifies generation | occurrence | production of the failure using a CCM frame when a failure is detected with the media converter outside a management network. It is a figure which shows the operation | movement which notifies generation | occurrence | production of the failure using a CCM frame when a communication failure generate | occur | produces between media converters. It is a figure which shows the operation | movement which notifies generation | occurrence | production of the failure using a CCM frame when the communication failure generate | occur | produces between the switching hub and media converter corresponding to 1 Gbps.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. The network system of the present invention is realized by using a plurality of media converters that constitute one management network by the OAM function, and a switching hub connected to the management network.

  FIG. 1 is a diagram schematically showing the configuration of a network system. The media converters 1, 2, 4, and 6 correspond to communication speeds such as 1 Gbps (Gigabit per second) and 10 Gbps, for example, and convert data received as electrical signals into optical signals for transmission or received light The signal is converted into an electrical signal and transmitted. The switching hubs 8 and 10 are layer 2 switches or layer 3 switches, and these exchange frames with each other.

[Network system configuration]
The media converter 1 includes a user port 1a and a long distance port 1b. Similarly to the media converter 1, the media converters 2, 4 and 6 include user ports 2a, 4a and 6a and long-distance ports 2b, 4b and 6b, respectively. The switching hubs 8 and 10 are provided with ports 8a and 10a, respectively. The switching hubs 8 and 10 include other ports (not shown) and are connected to other networks (not shown).

  The user port 1a and the long-distance port 1b of the media converter 1 are connected to the port 8a of the switching hub 8 and the long-distance port 2b of the media converter 2 so as to face each other via a network cable (not shown). The second user port 2 a is connected to face the user port 4 a of the media converter 4. The long distance port 4b of the media converter 4 is connected to face the long distance port 6b of the media converter 6, and the user port 6a of the media converter 6 is connected to face the port 10a of the switching hub 10. Yes. User ports connected to face each other transmit and receive frames in the state of electrical signals. In addition, long distance ports connected to face each other transmit and receive frames in the state of optical signals.

  In this network system, two communication paths are formed roughly. The first is a communication path from one switching hub 8 to the other switching hub 10, and the second is a communication from the other switching hub 10 to one switching hub 8. It is a route. On the first communication path, a frame transmitted from the port 8a of the switching hub 8 passes through the user port 1a, the long-distance ports 1b and 2b, the user ports 2a and 4a, the long-distance ports 4b and 6b, and the user port 6a. And then transferred to the port 10a of the switching hub 10. On the second communication path, the frames transmitted from the port 10a of the switching hub 10 in the reverse direction are the user port 6a, the long distance ports 6b and 4b, the user ports 4a and 2a, and the long distance ports 2b and 1b. And to the port 8a of the switching hub 8 via the user port 1a.

  It should be noted that the port 8a of the switching hub 8 and the user port 1a of the media converter 1 are connected to each other with a single network cable, and even if two frames are transmitted and received bidirectionally, A format may be used in which a transmission side and a reception side are separately transmitted and received using a cable. Similarly, the media converter 2 and the media converter 4, the media converter 4 and the media converter 6, and the media converter 6 and the switching hub 10 are connected by a single network cable. Alternatively, it may be in the form of connecting with different network cables.

  In this way, the media converters are configured by alternately combining long-distance ports and user ports connected to face each other. With such a configuration, not only four media converters but also a plurality of media converters (not shown) can be combined. Thereby, for example, even if the switching hubs 8 and 10 are arranged apart from each other by several hundred kilometers to several thousand kilometers, if a plurality of media converters are connected according to the distance, the switching hubs 8 and 10 are connected. Communication is possible.

  In addition, the media converters 1, 2, 4, and 6 implement various functions of OAM that are standardized by ITU-T international recommendation “Y.1731”, IEEE802.1ag, and the like. Thereby, a maintenance domain for managing communication using media converters 1, 2, 4, and 6 is defined in the network. Among these, the two media converters 1 and 6 positioned at both ends of the maintenance domain are defined as management end points (MEP: Maintenance End Point) which are base points for managing communication in the maintenance domain. The other media converters 2 and 4 are set as management relay points (MHF: MIP Half Function) that relay frames transmitted from the above management end points based on the functions of the OAM.

  The media converters 1 and 6 set as management end points monitor whether or not communication is normally executed within the maintenance domain of the media converter using the CC function of the OAM. Specifically, each of the media converters 1 and 6 generates a CCM (Continuity Check Message) frame 12 by using the CC function of the OAM, and transmits it at a predetermined interval. Then, these two media converters 1 and 6 confirm the arrival of the CCM frame 12 transmitted from the other party so that the communication between the media converters 1, 2, 4 and 6 is normally performed. Monitoring. When the CCM frame 12 transmitted from one management endpoint does not arrive at the other management endpoint, the other management endpoint that has detected this determines that a communication failure has occurred and stores various types of failure information. The CCM frame 12 is transmitted to one management end point.

  In this embodiment, a failure information storage area for storing failure information is set inside the CCM frame 12. When the media converters 1 and 6 detect that a failure has occurred in the communication path between the connected switching hubs 8 and 10, the media converter 1 stores the failure information in the failure information storage area of the CCM frame 12, and Send to media converter 6,1. Further, when receiving the CCM frame 12 in which the failure information is stored in the failure information storage area, the media converters 1 and 6 notify the switching hubs 8 and 10 of the occurrence of the failure.

  In addition, when the switching hubs 8 and 10 detect that a failure has occurred in the communication path between the connected media converters 1 and 6, the switching hubs 8 and 10 notify the media converters 1 and 6 of the occurrence of the failure. When the switching hubs 8 and 10 are compatible with 10 Gbps Ethernet (registered trademark), the notification of the occurrence of the failure is performed by an LFS (Link Fault Signaling) function, and the switching hubs 8 and 10 are registered with 1 Gbps Ethernet (registered). In the case of a trademark), the auto negotiation function is used. A method for notifying various types of failure information by the media converters 1, 2, 4, 6 and the switching hubs 8 and 10 when a communication failure occurs will be described in more detail later with reference to another drawing.

  FIG. 2 is a diagram schematically illustrating a configuration example of the CCM frame 12. The CCM frame 12 is a frame conforming to a communication standard such as ITU-T international recommendation “Y.1731” or IEEE802.1ag, and the CCM frame 12 having such a format is a management end point shown in FIG. Is generated in the media converters 1 and 6 set as When a communication failure occurs, various types of failure information are stored in the CCM frame 12. Hereinafter, the configuration of the CCM frame 12 will be described. Note that the basic configuration of the CCM frame 12 conforms to the communication standard described above, and a detailed description thereof will be omitted as appropriate.

[CCM frame]
The CCM frame 12 shown in FIG. 2 includes a DA (Destination Address) area 14, an SA (Source Address) area 16, an S-TAG (Service VLAN-TAG) area 18, a TYPE area 20, a data area 22, and an FCS (Frame). (Check Sequence) area 24 is provided.

  For example, when the CCM frame 12 is transmitted from the media converter 1 to the media converter 6 in the DA area 14, a multicast address is stored. The SA area 16 stores a MAC (Media Access Control) address set in the transmission source media converter 1 that generated the CCM frame 12. In the S-TAG area 18, for example, when a VLAN (Vertical Local Area Network) is set in the maintenance domain of the media converters 1, 2, 4, and 6 shown in FIG. 1, the VLAN information is stored.

  The TYPE area 20 stores information indicating that data related to OAM is stored in the data area 22. The data area 22 includes a header area 26, a seq area 28, a MEP ID area 30, an MEG ID area 32, an Rsv1731 area 34, an optional TLVs (Type Length Values) area 36, and an END area 38.

  FIG. 3 is a diagram showing a detailed configuration of the Optional TLVs area 36 included in the CCM frame 12. Since the basic configuration of the optional TLV area 36 conforms to the ITU-T international recommendation “Y.1731” and the IEEE 802.1ag communication standard, detailed description of each area is omitted here.

  The optional TLVs area 36 includes a TYPE area 40, a Length area 42, and a Value area 44. Further, an OUI (Organizationally Unique Identifier) 46 can be set in each area, and the OUI 46 is an identification number uniquely assigned to a vendor, for example.

  In the Value area 44, a fault information storage area for storing fault information is set. The Value area 44 includes an AIS (Alarm Indication Signal) area 44a, an RF (Remote Fault) area 44b, an LF (Link Fault) area 44c, and a Reserved area 44d. In the present embodiment, the AIS area 44a, the RF area 44b, and the LF area 44c correspond to the failure information storage area. In the AIS area 44a, the RF area 44b, and the LF area 44c, for example, when communication is normally performed between the media converter 1 and the switching hub 8 shown in FIG. 1, the values are set to OFF (0). Has been. On the other hand, when a failure occurs in the communication executed between the above, the value of the area corresponding to the failure is set to ON (1) according to the state of the communication failure.

  FIG. 4 is a diagram illustrating an operation of notifying the occurrence of a failure using the CCM frame 12 when a failure occurs on the communication path from the media converter 1 to the switching hub 8. The switching hubs 8 and 10 are assumed to be compatible with 10 Gbps Ethernet (registered trademark).

  When a failure occurs in the communication path from the media converter 1 to the switching hub 8, the switching hub 8 detects the occurrence of the failure based on the interruption of the signal from the media converter 1. The switching hub 8 that has detected the occurrence of a failure transmits an RF (Remote Fault) signal from the port 8 a to the media converter 1.

  When the media converter 1 receives RF at the user port 1a, the media converter 1 generates a CCM (RF) 12a in which the value of the RF area 44b of the CCM frame 12 shown in FIG. 3 is set to ON (1), and the long distance port 1b Send from. The CCM (RF) 12 a transmitted from the media converter 1 is transferred to the media converter 6 via the media converters 2 and 4.

  When the media converter 6 receives the CCM (RF) 12a at the long-distance port 6b, the media converter 6 transmits RF to the switching hub 10 from the user port 6a. The switching hub 10 that has received the RF detects that a failure has occurred in the communication path from the switching hub 10 to the switching hub 8.

  As a result, when a failure occurs in the communication path from the media converter 1 to the switching hub 8, the occurrence of the failure can be notified to the switching hub 10 disposed facing the switching hub 8.

  FIG. 5 is a diagram illustrating an operation of notifying the occurrence of a failure using the CCM frame 12 when a failure occurs on the communication path from the switching hub 8 to the media converter 1. It is assumed that the switching hubs 8 and 10 are compatible with 10 Gbps Ethernet (registered trademark).

  When a failure occurs in the communication path from the switching hub 8 to the media converter 1, the media converter 1 detects the occurrence of the failure based on the interruption of the signal from the switching hub 8. The media converter 1 that has detected the occurrence of the failure generates a CCM (AIS) 12b in which the AIS area 44a of the CCM frame 12 is set to ON (1), and then moves from the long distance port 1b to the long distance port 6b of the media converter 6. Send to. The CCM (AIS) 12 b transmitted from the media converter 1 is transferred to the media converter 6 via the media converters 2 and 4.

  When the media converter 6 receives the CCM (AIS) 12b at the long-distance port 6b, the media converter 6 stops transmission of a signal from the user port 6a. The switching hub 10 detects the occurrence of a failure based on the interruption of the signal from the media converter 6 at the port 10a. The switching hub 10 that has detected the occurrence of the failure transmits RF from the port 10a. When the media converter 6 receives the RF transmitted from the switching hub 10 at the user port 6a, the media converter 6 generates a CCM (RF) 12a and transmits it to the media converter 1 from the long distance port 6b. On the other hand, when the media converter 1 receives the CCM (RF) 12a transmitted from the media converter 6 through the long-distance port 1b, the media converter 1 transmits RF from the user port 1a to the port 8a of the switching hub 8.

  As a result, when a failure occurs in the communication path from the switching hub 8 to the media converter 1, the occurrence of the failure can be notified to the switching hub 8 and the switching hub 10.

  FIG. 6 is a diagram illustrating an operation of notifying the occurrence of a failure using the CCM frame 12 when a failure is detected by a media converter outside the management network. FIG. 6 illustrates a method for notifying the switching hub 10 of the occurrence of a failure when the media converter 50 is connected to the user port 1a of the media converter 1 defined as a management endpoint in the management network.

  The media converter 50 includes a user port 50 a and a long distance port 50 b, and the user port 50 a is connected to the user port 1 a of the media converter 1. Further, another media converter (not shown) is connected to the long distance port 50b of the media converter 50. The media converter 50 is connected to the outside of the management network to which the media converters 1, 2, 4 and 6 belong, and does not transmit / receive the OCM-based CCM frame 12 to / from the media converter 1. And In addition, the user port 1a of the media converter 1 and the user port 50a of the media converter 50 use the LFS function as a method of notifying each other of a failure.

  When a failure occurs in the communication path from the other media converter to the media converter 50, the signal from the other media converter is interrupted at the long-distance port 50b of the media converter 50. The media converter 50 detects that a failure has occurred in the communication path (LF: Link Fault) based on the interruption of the signal. The media converter 50 that has detected the occurrence of the failure transmits an LF signal from the user port 50 a to the media converter 1.

  When the media converter 1 receives the LF at the user port 1a, the media converter 1 generates the CCM (LF) 12c in which the value of the LF area 44c of the CCM frame 12 is set to ON (1), and transmits it from the long distance port 1b. The CCM (LF) 12 c transmitted from the media converter 1 is transferred to the media converter 6 via the media converters 2 and 4.

  When the media converter 6 receives the CCM (LF) 12c at the long-distance port 6b, the media converter 6 transmits the LF from the user port 6a to the switching hub 10. The switching hub 10 that has received the LF detects that a failure has occurred in the communication path of the received signal.

  Thereby, the media converters 1, 2, 4, 6 in the management network can notify the switching hub 10 of the failure information (LF) detected by the media converter 50 connected outside the management network.

  In addition, the switching hub 10 that has received the LF transmits the RF to the media converter 6. When receiving the RF, the media converter 6 generates a CCM (RF) 12a and transmits it to the media converter 1 from the long-distance port 6b. When the media converter 1 receives the CCM (RF) 12a at the long-distance port 1b via the media converters 2 and 4, the media converter 1 transmits RF to the media converter 50 from the user port 1a.

  FIG. 7 is a diagram illustrating an operation of notifying the occurrence of a failure using the CCM frame 12 when a communication failure occurs between the media converters 1 and 6. In FIG. 7, a case where a failure occurs in the communication path from the media converter 2 to the media converter 4 will be described.

  When a failure occurs in the communication path from the media converter 2 to the media converter 4, the CCM frame 12 transmitted from the media converter 1 does not arrive at the media converter 6. The media converter 6 detects that a failure has occurred in the communication path (LOC: Loss Of Continuity) based on the interruption of the CCM frame 12 from the media converter 1.

  The media converter 6 that has detected the occurrence of the failure stops transmission of a signal from the user port 6a. In addition, the media converter 6 generates a CCM (RDI) 12d in which information (RDI: Remote Detect Indication) indicating that the LOC has been detected based on the function of the OAM is stored in the CCM frame 12, and generates the CCM (RDI) 12d. 6b is transmitted to the media converter 1. The switching hub 10 detects the occurrence of a failure based on the interruption of the signal from the media converter 6. The switching hub 10 generates RF and transmits RF from the port 10a.

  When the media converter 1 receives the CCM (RDI) 12d transmitted from the media converter 6 through the long-distance port 1b, the media converter 1 stops transmission of a signal from the user port 1a. The switching hub 8 detects the occurrence of a failure based on the interruption of the signal from the media converter 1. The switching hub 8 generates RF and transmits it from the port 8a.

  When the media converters 1 and 6 receive the RF transmitted from the switching hubs 8 and 10 at the respective user ports 1a and 6a, the media converters 1 and 6 generate a CCM (RF) 12a based on the RF. Since the media converter 6 detects the LOC, the RDI is stored in the CCM frame 12 and a frame in which the RF area 44b is set to ON (1) is generated (hereinafter, this frame is referred to as “CCM”). (RDI · RF) 12e ”). The media converters 1 and 6 transmit the generated CCM (RF) 12a and CCM (RDI / RF) 12e from the long-distance ports 1b and 6b, respectively.

  Note that the CCM (RF) 12a transmitted from the media converter 1 is blocked by a communication failure occurring between the media converters 2 and 4. On the other hand, the CCM (RDI / RF) 12 e transmitted from the media converter 6 is transferred to the long-distance port 1 b of the media converter 1 through the media converters 2 and 4.

  Thereby, when a failure occurs between the media converter 2 and the media converter 4, the occurrence of the failure can be notified to the switching hub 8 and the switching hub 10. The above operation is the same when a failure occurs between the media converter 1 and the media converter 2 and between the media converter 4 and the media converter 6.

  FIG. 8 is a diagram illustrating an operation for notifying the occurrence of a failure using the CCM frame 12 when a communication failure occurs between the switching hub 8 and the media converter 1 corresponding to 1 Gbps. Although FIGS. 4 to 7 illustrate an example in which the switching hubs 8 and 10 corresponding to 10 Gbps perform operations based on the LFS function, in FIG. 8, the switching hubs 8 and 10 corresponding to 1 Gbps operate based on the auto-negotiation function. An example of performing is described. In FIG. 8, a case where a failure occurs in the communication path from the media converter 1 to the switching hub 8 will be described.

  When a failure occurs in the communication path from the media converter 1 to the switching hub 8, the switching hub 8 detects the occurrence of the failure based on the interruption of the signal from the media converter 1. The switching hub 8 that has detected the occurrence of the failure transmits a failure notification signal (“A / N” shown in FIG. 8) by the auto-negotiation function to the media converter 1.

  The media converter 1 detects the occurrence of a failure by receiving a failure notification signal by the auto-negotiation function from the switching hub 8. The media converter 1 that has detected the occurrence of the failure generates a CCM (AIS) 12b and transmits it to the media converter 6 from the long-distance port 1b. The media converters 2 and 4 relay the CCM (AIS) 12b and transfer it to the media converter 6. When the media converter 6 receives the CCM (AIS) 12b, the media converter 6 stops transmission of signals from the user port 6a.

  The switching hub 10 detects that a failure has occurred based on the interruption of the signal from the media converter 6. Further, the switching hub 10 transmits a failure notification signal by the auto-negotiation function to the media converter 6.

  The media converter 6 detects the occurrence of a failure by receiving a failure notification signal by the auto-negotiation function from the switching hub 10. The media converter 6 that has detected the occurrence of the failure generates a CCM (AIS) 12b and transmits it to the long-distance port 6b media converter 1.

  As a result, when a failure occurs in the communication path from the media converter 1 to the switching hub 8, the occurrence of the failure can be notified to the switching hub 10 disposed facing the switching hub 8.

  As described above, in the network system according to the present embodiment, the switching hubs 8 and 10 connected to the media converters 1 and 6 are compatible with 10 Gbps Ethernet (registered trademark), or 1 Gbps Ethernet (registered trademark). In any case, the occurrence of a failure can be notified to the switching hubs 8 and 10 by the failure notification operation using the CCM frame 12 by the media converters 1 and 6. .

1, 2, 4, 6 Media converter (network connection device)
8,10 Switching hub (network repeater)
12 CCM frames 1a, 2a, 4a, 6a, 50a User ports 1b, 2b, 4b, 6b, 50b Long distance port 50 Media converter (network repeater)

Claims (3)

A first network connection device connected to the first network connection device; a second network connection device connected to the first network connection device; and a second network connection device connected to the first network connection device. A network system comprising a second network repeater connected to a network connection device,
The first network connection device and the second network connection device monitor the communication connectivity between each other by transmitting an OAM CCM frame to the other party,
In the CCM frame, a failure information storage area for storing failure information is set.
When the first network connection device detects a failure with the first network repeater, the first network connection device stores failure information in the failure information storage area of the CCM frame;
When the second network connection device receives the CCM frame in which failure information is stored in the failure information storage area, the second network connection device notifies the second network repeater of the occurrence of the failure ,
In the CCM frame, an RF area is set as the failure information storage area,
When the first network connection device detects the occurrence of a failure by receiving RF from the first network repeater, the failure information is stored in the RF region of the CCM frame;
When the second network connection device receives the CCM frame in which failure information is stored in the RF region, the second network connection device notifies the occurrence of the failure by transmitting an RF to the second network repeater,
In the CCM frame, an AIS area is set as the failure information storage area,
The first network connection device receives a failure notification signal by an auto-negotiation function when the occurrence of a failure is detected because the signal from the first network repeater is interrupted or from the first network repeater. When the occurrence of a failure is detected by receiving, the failure information is stored in the AIS area of the CCM frame
When the second network connection device receives the CCM frame in which failure information is stored in the AIS area, the second network connection device stops transmission of the signal to the second network repeater to stop the second network relay. Notify the device of the failure,
In the CCM frame, an LF area is set as the failure information storage area,
When the first network connection device detects an occurrence of a failure by receiving an LF from the first network repeater, the failure information is stored in an LF area of the CCM frame;
When the second network connection device receives the CCM frame in which failure information is stored in the LF area, the second network connection device notifies the failure by transmitting an LF to the second network repeater.
Network system. The network system according to claim 1 ,
When the CCM frame from the first network connection device is interrupted, the second network connection device stops transmission of a signal to the second network relay device to stop the second network relay device. To notify the occurrence of a failure,
Network system. The network system according to claim 1 or 2 ,
The first network connection device and the second network connection device are connected via one or more other network connection devices.
Network system.

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