JP4623661B2 - Automatic alarm release method for optical cross-connect equipment - Google Patents

Description

  The present invention relates to an automatic alarm canceling method for an optical cross-connect device, and in particular, when a fault in an optical network is recovered, the fault alarm by the optical cross-connect device is automatically canceled and the bandwidth of the link that has been avoided due to the fault. The present invention relates to an automatic alarm canceling method for an optical cross-connect device that can open the door.

  The GMPLS optical network includes an optical cross-connect device (PXC) and a transmission device such as WDM (hereinafter referred to as WDM). FIG. 3 is a block diagram showing a basic device configuration of a conventional GMPLS optical network.

  The GMPLS optical network includes WDM 3 and 4 arranged between PXC 1 and 2 and PXC 1 and 2. The PXCs 1 and 2 and the WDMs 3 and 4 respectively include a PXC-management system (EMS) 5 and a WDM-management system (EMS) 6. PXC-EMS5 monitors and manages the device status of PXC1,2. In addition, the WDM-EMS 6 monitors and manages the device status of the WDM 3 and 4. PXC1 and PXC2 exchange GMPLS control messages via the GMPLS control plane 7.

  FIG. 4 is a flowchart showing an operation when a failure occurs in the conventional GMPLS optical network. First, the operation when a failure occurs will be described. In the GMPLS optical network of FIG. 3, for example, when a failure occurs in a line (link) from WDM3 to WDM4 (S41), WDM4 notifies the failure to PXC2 (S42). If no failure has occurred, the processing from S42 onward is not performed. The notification of the failure is performed by a WDM forced light cut-off function in which the WDM 4 shuts down the downstream optical signal, or by a GMPLS-LMP (RFC4204; Link Management Protocol) function executed via the GMPLS control plane 7.

  Also, the WDM 4 sends a failure alarm to the WDM-EMS 6 (S43). When the WDM-EMS 6 receives a failure alarm from the WDM 4, it issues a failure alarm (S44).

  When a failure is notified from WDM 4, PXC 2 sends a failure alarm to PXC-EMS 5 and exchanges a failure notification signal with PXC 1 (S45). Upon receiving the failure notification signal from the PXC 2, the PXC 1 recognizes that the GMPLS traffic engineering link (TE link) is a failure, and sends a failure alarm to the PXC-EMS 5 (S46).

  Also, the PXC1 advertises that the TE link cannot be used by setting the band of the TE link to 0 (S47). Thereafter, the PXC 1 performs routing while avoiding the TE link that has failed, automatically changes the route of the optical path, and recovers the failure of the optical path (S48).

  PXC-EMS 5 issues a failure alarm when it receives a failure alarm from PXC 1 and 2, and manages the TE link between WDM 3 and 4 as a failure link (S49). The above is the operation when a failure occurs.

  Next, the operation at the time of failure recovery will be described. FIG. 5 is a continuation of the flowchart of FIG. 4 and shows the operation at the time of failure recovery. When the link failure between WDM 3 and 4 is restored (S50), an optical signal is input to WDM 4. If the failure is not recovered, the processing from S51 is not performed. WDM4 cancels the failure alarm to WDM-EMS 6 (S51), and WDM-EMS 6 stops issuing the failure alarm (S52). Based on the information on the WDM-EMS 6, the operator manually clears the fault alarm with the PXC-EMS 5 (S53). As a result of the failure alarm release operation, the PXC 1, 2 and PXC-EMS 5 transition from the failure state to the normal state, and release the failure alarm (S54). The PXC 1 releases the band of the TE link that has been disabled due to a failure (S55).

  Non-Patent Documents 1 and 2 describe a technique for automatically changing the path of an optical path by linking WDM and PXC in the event of a failure to execute routing while avoiding the TE link that has failed. .

The present inventor previously proposed a PXC-WDM linkage system in Patent Document 1 that can isolate a failure between PXC and WDM, and can operate an optical network with high reliability and high efficiency.
Japanese Patent Application No. 2005-33060 (prior application) “Interworking DWDM equipment and PXC operation GMPLS for a reliable optical network” Optical Fiber Communication Conference, 2004. OFC 2004 Volume 2, PDP3, 23-27 Feb. 2004 “Field test of GMPLS all-optical path rerouting” Optical Fiber Communication Conference, 2004. OFC 2004 Volume 2, PDP2, 23-27 Feb. 2004

  Conventionally, a mechanism has been defined to notify failure recovery from WDM to PXC when a failure between WDMs is recovered, and in that case, a mechanism to automatically shift the failure state to the normal state and cancel the failure alarm on the management system is defined. It has not been.

  If there is a failure between WDMs, the light to the PXC will be cut off, but even if the failure is recovered, the light off state to the PXC will continue, so detect the failure recovery on the data plane. Is difficult.

  Therefore, when the failure between WDMs is recovered, the PXC failure alarm clearing work must be done manually by the operator recognizing the failure recovery on the WDM-EMS6 as described above. As the burden increased, there was a problem that efficient maintenance operation was not possible.

  An object of the present invention is to solve the above-mentioned problems, and when a failure between WDMs in an optical network is recovered, the failure alarm of the optical cross-connect device is automatically canceled and the band of the link that has been avoided by the failure is released. It is an object of the present invention to provide an automatic alarm canceling method for an optical cross-connect device.

  In order to solve the above problems, the present invention is an automatic alarm canceling method for an optical cross-connect device in an optical network, the optical network includes a transmission device and an optical cross-connect device, and the transmission device is between the transmission devices. When a failure is recovered, the optical cross-connect device includes means for sending a failure recovery notification signal to the optical cross-connect device adjacent to the downstream side of the optical path, and the optical cross-connect device recovers from the failure transmitted from the transmission device adjacent to the upstream side of the optical path. Means for receiving a notification signal, means for sending a failure recovery notification signal to an optical cross-connect device adjacent on the upstream side of the optical path when a failure recovery notification signal is received from a transmission device adjacent on the upstream side of the optical path, and optical When a failure recovery notification signal is received from a transmission device adjacent to the upstream side of the path or an optical cross-connect device adjacent to the downstream side of the optical path, When a failure recovery notification signal is received from the optical cross-connect device adjacent to the downstream side of the optical path and the means for canceling the harm alarm, routing control information is sent out by multicast, and the link band that was avoided by the failure is released. It is characterized by having means.

  In the present invention, the optical cross-connect device further includes means for switching back the optical path to the path used before the failure when the failure recovery notification signal is received from the adjacent optical cross-connect device. It is characterized by that.

  According to the present invention, it is possible to automatically cancel the PXC failure alarm, which has been performed manually by an operator, using a failure recovery notification signal from WDM as a trigger. In addition, since resources between PXCs can be automatically released, the operator's workload can be reduced and efficient maintenance operations can be performed. In addition, even if there is an unexpected fluctuation in the recovery of failures between WDMs, it is possible to automatically deal with it.

  Further, when the optical path is switched back to the path used before the occurrence of the fault at the time of the fault recovery, the optical path can always be set to the optimum path in consideration of the economy.

  The present invention will be described below with reference to the drawings. FIG. 1 is a diagram showing a basic device configuration and a failure recovery sequence of a GMPLS optical network to which the present invention is applied. In the device configuration of FIG. 1, the same or equivalent elements as in FIG.

  In this device configuration, PXC1 and PXC2, PXC1 and WDM3, and PXC2 and WDM4 can exchange GMPLS control messages via the GMPLS control plane 7. The GMPLS control message includes a failure alarm from WDM to WDM-EMS, a failure alarm from PXC to PXC-EMS, a failure notification signal transmitted and received between WDM and PXC, and the like.

  In the GMPLS optical network of FIG. 1, for example, when a failure occurs in the link from WDM3 to WDM4, an optical signal is not input from the link to WDM4, and the optical signal from WDM4 to PXC2 is blocked. As a result, the WDM 4 recognizes that a failure has occurred, and notifies the PXC 2 of the failure by the WDM forced light interruption function or the GMPLS-LMP function. In addition, WDM4 sends a failure alarm to WDM-EMS 6, and when WDM-EMS 6 receives a failure alarm from WDM4, it issues a failure alarm.

  When a failure is notified from the WDM 4, the PXC 2 sends a failure alarm to the PXC-EMS 5 via the GMPLS control plane 7 and exchanges a failure notification signal with the PXC 1. Upon receiving the failure notification signal from the PXC 2, the PXC 1 recognizes that the GMPLS TE link has failed, and sends a failure alarm to the PXC-EMS 5.

  Also, PXC1 advertises that the TE link band cannot be used by setting the band of the TE link to 0 using a path control signal. Thereafter, the PXC 1 performs routing while avoiding the TE link that has failed, automatically changes the path of the optical path, and recovers the failure of the optical path. PXC-EMS 5 issues a failure alarm when it receives a failure alarm from PXC 1 and 2, and manages the TE link between WDM 3 and 4 as a failure link. The above operation when a failure occurs is the same as S41 to S48 in FIG.

  When the failure between WDM 3 and 4 is recovered, an optical signal is input to WDM 4, but the state where no light is input to PXC 2 is continued. WDM4 recognizes that the failure has been recovered when light is input from the link, and cancels the failure alarm to WDM-EMS6. As a result, the WDM-EMS 6 stops sending the fault alarm. Also. WDM4 sends a failure recovery notification signal to PXC2.

  When PXC2 receives the failure recovery notification signal from WDM4, PXC2 cancels the failure alarm to PXC-EMS5 and sends the failure recovery notification signal to PXC1. Note that the failure recovery notification signals transmitted by WDM4 and PXC2 need not be the same.

  Upon receiving the failure recovery notification signal from PXC2, PXC1 recognizes that the failure of the TE link that has been disabled due to the failure has been recovered, and cancels the failure alarm to PXC-EMS5. In addition, PXC1 sends routing control information by multicast, and releases the band of the TE link that has failed.

  When the failure alarm from PXC 1 and 2 is canceled, PXC-EMS 5 stops issuing the failure alarm and makes the system transition to a normal state.

  FIG. 2 is a flowchart showing the operation at the time of failure recovery in the present invention. When the failure of the link between WDM 3 and 4 (link from WDM 3 to WDM 4) is recovered (S21), WDM 4 cancels the alarm failure to WDM-EMS 6 (S22). If the failure is not recovered, the processing from S22 onward is not performed. The WDM-EMS 6 stops sending the fault alarm when the fault alarm from the WDM 4 is canceled (S23). Further, the WDM 4 sends a failure recovery notification signal to the PXC 2 adjacent on the downstream side of the optical path (S24).

  When PXC2 receives the failure recovery notification signal from WDM4, it recognizes that the link status is normal (recovery), cancels the failure alarm to PXC-EMS5, and fails to PXC1 adjacent to the upstream side of the optical path. A recovery notification signal is transmitted (S25).

  Upon receiving the failure recovery notification signal from PXC2, PXC1 recognizes that the TE link failure has been recovered and automatically cancels the failure alarm to PXC-EMS5 (S26). As a result, the PXC-EMS 5 cancels the fault alarm that has been issued (S27). Further, the PXC 1 sends the path control information by multicast, and releases the band of the TE link that has been disabled due to a failure (S28).

  Furthermore, it is possible to switch back the optical path to the path used before the failure when the TE link failure is recovered. For this purpose, the path information before the occurrence of the failure may be saved, and the PXC of the start node may reset the optical path based on the saved route information when the failure is recovered (S28). S28 is not always necessary, but if the process of S28 is added, the optical path can be reset to the optimum route in consideration of economy. In other words, the path of the optical path before the occurrence of the failure is presumed to be the optimal path selected by cost calculation from among a number of paths. Can do.

  As mentioned above, although embodiment was described, this invention is not limited to the said embodiment. For example, the failure alarm is not limited to an alarm sent from the PXC when a link failure between WDMs, but may be an alarm sent from the PXC when there is a WDM device failure or signal quality degradation between WDMs. The present invention is also effective for automatically canceling such a failure alarm.

It is a figure which shows the fundamental apparatus structure and failure recovery sequence of the GMPLS optical network to which this invention is applied. It is a flowchart which shows the operation | movement at the time of link failure recovery in this invention. It is a block diagram which shows the basic apparatus structure of the conventional GMPLS optical network. 10 is a flowchart showing an operation when a failure occurs in a conventional GMPLS optical network. 5 is a flowchart (continuation of FIG. 4) showing an operation at the time of failure recovery in a conventional GMPLS optical network.

Explanation of symbols

1,2 ... Optical cross-connect equipment (PXC), 3,4 ... Transmission equipment (WDM) 5,6 ... Management system (EMS), 7 ... GMPLS control plane

Claims (2)

An automatic alarm canceling method for an optical cross-connect device in an optical network,
The optical network includes a transmission device and an optical cross-connect device,
Transmission equipment
When a failure between the transmission devices is recovered, a means for sending a failure recovery notification signal to an optical cross-connect device adjacent to the downstream side of the optical path is provided.
Optical cross-connect equipment
Means for receiving a failure recovery notification signal sent from a transmission device adjacent to the upstream side of the optical path;
Means for sending a failure recovery notification signal to an optical cross-connect device adjacent to the upstream side of the optical path when a failure recovery notification signal is received from a transmission device adjacent to the upstream side of the optical path;
Means for canceling a failure alarm by the own device when a failure recovery notification signal is received from a transmission device adjacent to the upstream side of the optical path or an optical cross-connect device adjacent to the downstream side of the optical path;
When a failure recovery notification signal is received from an optical cross-connect device adjacent on the downstream side of the optical path, routing control information is transmitted by multicast, and a means for releasing a link band that has been avoided due to the failure is provided. Automatic alarm release method for optical cross-connect devices. The optical cross-connect device further includes means for switching the optical path back to the path used before the failure when the failure recovery notification signal is received from the optical cross-connect device adjacent to the downstream side of the optical path. The automatic alarm canceling method for the optical cross-connect device according to claim 1.

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