JP5556562B2 - Wavelength division multiplexing ring network and optical transmission apparatus - Google Patents

Description

  The present invention relates to a wavelength division multiplexing ring network that performs wavelength division multiplexing optical communication between optical transmission apparatuses and an optical transmission apparatus that constitutes a wavelength division multiplexing ring network.

  As a technology for realizing a large capacity of the core network, there is a wavelength division multiplexing (hereinafter referred to as WDM) technology for multiplexing and transmitting a plurality of wavelength signals on one optical fiber, particularly in a metro area or the like. Then, WDM ring networks using this technology are widely used. In a WDM ring network, a wavelength is assigned to each optical path, and each node (optical transmission equipment) constituting the network branches / inserts a main signal using an arbitrary optical path, so that there is no electrical conversion between the nodes. It is possible to transmit with. In addition, two rings, clockwise and counterclockwise, are prepared, one of which is used as the working optical path, and the ring around the opposite side of the working optical path is used as the standby optical path, enabling protection in the event of a failure. It is said. However, the above-described protection method has a problem that the wavelength cannot be effectively used because it is necessary to prepare the same number of standby optical paths that are not used in normal operation as the active optical paths.

  In order to solve this problem, a method as shown in Patent Document 1 has been proposed. In Patent Document 1, a server for monitoring and controlling the wavelength state of a WDM ring network is prepared, and when a failure occurs, the server is notified of the failure, and the server uses the wavelength usage status etc. By determining the path and notifying the ring node (optical transmission equipment), switching to the standby optical path is realized. Prepare the same number of standby optical paths as the active optical paths in advance. Therefore, it is possible to effectively use the wavelength.

JP 2009-206797 A (FIG. 3, pages 11 to 12)

  However, in the conventional optical transmission device, the failure occurrence is notified to the server, and then the standby optical path is determined by the server, and communication with the standby optical path is resumed only after notifying each node (optical transmission device). Therefore, there is a problem that it takes time from the occurrence of a failure to the restoration of the main signal conduction.

  The present invention has been made in order to solve the above-described problems, and by setting the optical path, which has been conventionally performed by the server, in each optical transmission apparatus, the server can be used when a failure occurs. The purpose of this is to set up a spare optical path promptly without inquiring.

In the wavelength division multiplexing ring network system according to the present invention, a plurality of optical transmission devices that mutually transfer a main signal using a wavelength for main signal transfer are connected to the plurality of optical transmission devices, and the plurality of optical transmission devices are connected. transmission device in cooperation with an optical fiber constituting the wavelength division multiplexing ring network for wavelength division multiplexing optical communication, the provided plurality of optical transmission devices, a plurality of said main signal transfer wavelength, each of said main signal Control information , wavelength usable information that is information about whether or not a plurality of main signal transfer wavelengths can be a transmission source, a control information transfer means for transferring to the optical transmission apparatus adjacent with transfer wavelength, the provided plurality of optical transmission devices, based on the information transferred by the control information forwarding unit Wavelength determining means for determining the wavelength for transferring the main signal used for transferring the main signal, and the wavelength for transferring the main signal determined by the wavelength determining means for use, provided in the plurality of optical transmission devices. And a main signal input / output means for inputting / outputting to / from the wavelength division multiplexing ring network .

  According to the present invention, when a failure occurs in a wavelength division multiplexing ring network, the wavelength used for transferring the main signal can be determined more quickly.

It is a block diagram of the optical transmission apparatus in the WDM ring network shown in Embodiment 1 of this invention. It is a WDM ring network block diagram shown in Embodiment 1 of this invention. It is recovery operation explanatory drawing at the time of the failure occurrence shown in Embodiment 1 of this invention. It is recovery operation explanatory drawing at the time of the failure occurrence shown in Embodiment 1 of this invention. It is a block diagram of the optical transmission apparatus in the WDM ring network shown in Embodiment 2 of this invention. It is recovery operation explanatory drawing at the time of the failure generation shown in Embodiment 2 of this invention. It is recovery operation explanatory drawing at the time of the failure generation shown in Embodiment 2 of this invention. It is a block diagram of the optical transmission apparatus in the WDM ring network shown in Embodiment 3 of this invention. It is recovery operation explanatory drawing at the time of the failure generation shown in Embodiment 3 of this invention. It is recovery operation explanatory drawing at the time of the failure generation shown in Embodiment 3 of this invention. It is a block diagram of the optical transmission apparatus in the WDM ring network shown in Embodiment 4 of this invention. It is recovery operation explanatory drawing at the time of the failure generation shown in Embodiment 4 of this invention. It is recovery operation explanatory drawing at the time of the failure generation shown in Embodiment 4 of this invention.

Embodiment 1 FIG.
The optical transmission apparatus and optical path monitoring method according to the first embodiment will be described with reference to FIGS. FIG. 1 shows a configuration diagram of an optical transmission apparatus according to Embodiment 1 of the present invention, and FIG. 2 shows a configuration example of a WDM ring network. 3 and 4 are explanatory diagrams showing an optical path restoration operation when a failure occurs. In each of the drawings, the same reference numeral represents the same or a corresponding part, and a plurality of similar devices existing in the network are distinguished by attaching an alphabet after the numeral. Note that when these are collectively referred to or representatively shown without distinction, they are represented only by numerals without adding alphabets. Further, in the description related to the first embodiment, for convenience of explanation, a headline wording is appropriately added corresponding to the corresponding paragraph number.

  First, the configuration of the WDM ring network will be described. 1 to 4, the WDM ring network includes a plurality of optical transmission devices 10 and a WDM optical fiber ring 11 that interconnects these optical transmission devices, and the WDM optical fiber ring 11 transmits a signal clockwise. WDM optical fiber ring 11a, and a WDM optical fiber ring 11b that transmits a signal in a counterclockwise direction. The WDM ring network is managed by the network management device 12, and the network management device 12 exchanges control information such as location information with the optical transmission device 10 via the communication path 13.

Explanation of wavelength allocation:
In the WDM ring network shown in FIGS. 1 to 4, optical wavelengths used for transferring main signals and control information are respectively assigned. For the main signal, three main signal transfer wavelengths 14a to 14c used for signal transfer in the clockwise WDM optical fiber ring 11a and three for signal transfer in the counterclockwise WDM optical fiber ring 11b are used. Wavelengths 15a to 15c for main signal transfer are assigned. Control information is assigned a control information transfer wavelength 16a used for signal transfer in the clockwise WDM optical fiber ring 11a, and a control information transfer wavelength 16b used for signal transfer in the counterclockwise WDM optical fiber ring 11b. It has been. 3 and 4 show examples in which three wavelengths are prepared as the main signal transfer wavelengths 14 and 15 in each WDM optical fiber ring 11, but there is no particular limitation on the number of wavelengths. A number of wavelengths other than three may be used. The number of wavelengths used in the WDM optical fiber rings 11a and 11b may be different. Moreover, it is not necessary to make all the wavelengths different in each WDM optical fiber ring 11, and the same wavelength may be used in the WDM optical fiber ring 11a and the WDM optical fiber ring 11b.

Configuration of the optical transmission apparatus 10:
In the WDM ring network shown in FIG. 2, the optical transmission devices 10a to 10f all have the same configuration, and the configuration of the optical transmission device 10a will be described here. The optical transmission apparatus 10 inputs and outputs optical signals transmitted by the monitoring control module 20 for monitoring and controlling the optical transmission apparatus and the WDM optical fiber ring 11 in units of wavelengths, that is, ADD (insertion), DROP (branch), Alternatively, the optical add / drop module 21 that performs THROUGH (relay) and the transponder module 22 that is connected to the optical add / drop module 21 and can transmit and receive an arbitrary wavelength are configured.

Configuration of the monitoring control module 20:
The supervisory control module 20 includes a control CPU circuit 23 that performs communication with the optical transmission device 10 and the network management device 12 and controls the optical transmission device 10, and a transmission path fault state, device alarm state, and wavelength use within the supervisory control module 20. Wavelength required for performing information transfer control within the optical path reachable count value control circuit 24 and the monitoring control module 20 for controlling the reachable count value 32 as wavelength usable information for each wavelength in consideration of the situation In the alarm transfer table 25 for storing information on the usage status (ADD / DROP / THROUGH), the alarm transfer control 26 for performing transfer control such as an OTN (Optical Transport Network) alarm in the monitoring control module, and in the monitoring control module 20 Transmission path alarm and apparatus alarm as fault information detected in the optical transmission apparatus 10 And a warning information collection 27 for collecting (alarm information), multiplexes the various control information in the monitoring control module 20 within / separation and optical / electrical conversion controlling optical terminal 28.

Configuration of the optical add / drop module 21:
The optical add / drop module 21 demultiplexes the control information transfer wavelength 16 from the WDM optical fiber ring 11 in the optical add / drop module 21, and the control information transfer wavelength 16 in the optical add / drop module 21 WDM. A multiplexer 30 that multiplexes the optical fiber ring 11 is provided. In the supervisory control module 20 or between the supervisory control module 20 and the optical add / drop module 21, communication information 31 with the other optical transmission device 10 and the network management device 12, and an optical path exchanged by the optical transmission device 10 can be reached. Count value 32, alarm information 33 such as OTN alarm exchanged by the optical transmission apparatus 10, transmission path alarm and apparatus alarm 34 collected by the alarm information collection 27, transmission path alarm and apparatus alarm 34 detected by the optical add / drop module 21 The transmission path alarm and the apparatus alarm 36 detected by the transponder module 22 are exchanged.

Explanation about the optical path:
An optical path having a function as a signal transfer path set by the optical transmission apparatus 10 will be described with reference to FIGS. In FIG. 3, an optical path 17a for transferring a main signal from the optical transmission device 10d to the optical transmission device 10a using the main signal transfer wavelength 14a in the WDM optical fiber ring 11a, and WDM from the optical transmission device 10a to the optical transmission device 10d. An optical path 18a for transferring a main signal using the main signal transfer wavelength 15a in the optical fiber ring 11b, and an optical transmission device 10f to the optical transmission device 10e using the main signal transfer wavelength 14b in the WDM optical fiber ring 11a. An optical path 17b for transferring the main signal and an optical path 18b for transferring the main signal from the optical transmission device 10e to the optical transmission device 10f using the main signal transfer wavelength 15b in the WDM optical fiber ring 11b are set.

  In addition, an optical path when a transmission path failure 19 occurs in the WDM optical fiber ring 11b between the optical transmission apparatus 10c and the optical transmission apparatus 10d will be described with reference to FIG. The optical paths 17a, 17b, and 18b are the same as the optical paths shown in FIG. 3, but an optical path 18c that uses the WDM optical fiber ring 11a is newly set in place of the failed optical path 18a.

  In the optical transmission apparatus shown in the first embodiment of the present invention, the wavelength for main signal transfer in the WDM optical fiber ring 11 using the control information transfer wavelength 16 provided separately from the main signal transfer wavelengths 14 and 15. Information about the optical path reachable count value 32 indicating which optical transmission device 10 is in the usable state is constantly transferred, and the optical path reachable count value 32 is updated in each optical transmission device.

Description of optical path reachable count value:
The optical path reachable count value 32 is prepared for each main signal transfer wavelength, and is transferred using the control information transfer wavelength 16 in the WDM optical fiber ring 11 in the reverse direction to the main signal transfer wavelengths 14 and 15. That is, the optical path reachable count values 32a to 32c corresponding to the respective wavelengths of the main signal transfer wavelength group 14 in the WDM optical fiber ring 11a are the control information transfer wavelengths 16b, and the main signal transfer in the WDM optical fiber ring 11b. The optical path reachable count values 32d to 32f corresponding to the wavelengths of the wavelength group 15 for use are transferred at the control information transfer wavelength 16a.

Aspects of control method of optical path reachable count value:
A method for controlling the optical path reachable count value 32 in the optical path reachable count value control circuit 24 will be described. Seven aspects of the control method relating to the optical path reachable count value are described (a total of 14 patterns corresponding to the WDM optical fiber rings 11a and 11b). Although a control method in the optical transmission device 10a is shown here, the optical path reachable count value is controlled in the same manner for the other optical transmission devices 10b to 10e. Further, information on the transmission path abnormality and the apparatus failure used for controlling the optical path reachable count value 32 is determined from the transmission path alarm and the apparatus alarm 34 from the monitoring control collection 27. Further, the wavelength use status (ADD / DROP / THROUGH) is determined from information from the alarm transfer table 25.

(1) The optical transmission device 10a detects a transmission path alarm between the optical transmission device 10b and the optical transmission device 10a of the WDM optical fiber ring 11a and a device alarm that propagates to all wavelengths of the WDM optical fiber ring 11a. In this case, the optical path reachable count value 32 corresponding to all the main signal transfer wavelengths 14 is set regardless of the value of the optical path reachable count value 32 received from the optical transmission device 10f via the control information transfer wavelength 16b. 0 is transferred to the optical transmission device 10b via the control information transfer wavelength 16b.
(2) The optical transmission device 10a detects a transmission path alarm between the optical transmission device 10f of the WDM optical fiber ring 11b and the optical transmission device 10a, and a device alarm that propagates to all wavelengths of the WDM optical fiber ring 11b. In this case, the optical path reachable count value 32 corresponding to all the main signal transfer wavelengths 15 is set regardless of the value of the optical path reachable count value 32 received from the optical transmission device 10b via the control information transfer wavelength 6a. 0 is transferred to the optical transmission device 10f via the control information transfer wavelength 16a.

(3) In the optical transmission device 10a, a transmission line alarm between the optical transmission device 10b and the optical transmission device 10a having a specific main signal transfer wavelength 14 in the WDM optical fiber ring 11a, and in the WDM optical fiber ring 11a When a device alarm that propagates to the reception side of the specific main signal transfer wavelength 14 is detected, the device corresponds to the specific main signal transfer wavelength 14 received from the optical transmission device 10f via the control information transfer wavelength 16b. Regardless of the value of the optical path reachable count value 32, the optical path reachable count value 32 corresponding to the specific main signal transfer wavelength 14 is set to 0, and is transmitted to the optical transmission device 10b via the control information transfer wavelength 16b. Forward.
(4) In the optical transmission apparatus 10a, a transmission line alarm between the optical transmission apparatus 10f and the optical transmission apparatus 10a having a specific main signal transfer wavelength 15 in the WDM optical fiber ring 11b and the WDM optical fiber ring 11b When a device alarm that propagates to the receiving side of the specific main signal transfer wavelength 15 is detected, it corresponds to the specific main signal transfer wavelength 15 received from the optical transmission device 10b via the control information transfer wavelength 16a. Regardless of the value of the optical path reachable count value 32, the optical path reachable count value 32 corresponding to the specific main signal transfer wavelength 15 is set to 0, and the optical information is transmitted to the optical transmission device 10f via the control information transfer wavelength 16a. Forward.

(5) In the case where the specific main signal transfer wavelength 14 in the WDM optical fiber ring 11a is THROUGH / DROP in the optical transmission apparatus 10a, the optical transmission apparatus 10a receives the control information transfer wavelength 16b from the optical transmission apparatus 10f. Regardless of the value of the optical path reachable count value 32 corresponding to the specific main signal transfer wavelength 14, the optical path reachable count value 32 corresponding to the specific main signal transfer wavelength 14 is set to 0, and control information is transferred. The light is transferred to the optical transmission device 10b via the wavelength 16b for use.
(6) In the case where the specific main signal transfer wavelength 15 in the WDM optical fiber ring 11b is THROUGH / DROP in the optical transmission apparatus 10a, the optical transmission apparatus 10a receives the control information transfer wavelength 16a from the optical transmission apparatus 10b. Regardless of the value of the optical path reachable count value 32 corresponding to the specific main signal transfer wavelength 15, the optical path reachable count value 32 corresponding to the specific main signal transfer wavelength 15 is set to 0 to transfer control information. The data is transferred to the optical transmission device 10f via the wavelength 16a for use.

(7) When the optical transmission device 10a does not correspond to the above (1), (3), and (5) and ADDs the specific main signal transfer wavelength 14 in the WDM optical fiber ring 11a, the optical transmission device 10f Regardless of the value of the optical path reachable count value 32 corresponding to the specific main signal transfer wavelength 14 received via the control information transfer wavelength 16b, the light corresponding to the specific main signal transfer wavelength 14 The path reachable count value 32 is set to 1, and the path information is transferred to the optical transmission device 10b via the control information transfer wavelength 16b.
(8) When the optical transmission device 10a does not correspond to the above (2), (4), or (6) and ADDs a specific main signal transfer wavelength 15 in the WDM optical fiber ring 11b, the optical transmission device 10b Regardless of the value of the optical path reachable count value 32 corresponding to the specific main signal transfer wavelength 15 received via the control information transfer wavelength 16a, the light corresponding to the specific main signal transfer wavelength 15 The path reachable count value 32 is set to 1, and the path information is transferred to the optical transmission device 10f via the control information transfer wavelength 16a.

(9) In the optical transmission device 10a, when the optical transmission device 10a does not correspond to the above (1), (3), (5), and (7) and is received from the optical transmission device 10f via the control information transfer wavelength 16b, the received optical path In addition to the value of the reachable count value 32, the count is transferred to the optical transmission device 10b via the control information transfer wavelength 16b.
(10) When the optical transmission apparatus 10a receives the control information transfer wavelength 16a from the optical transmission apparatus 10b that does not correspond to the above (2), (4), (6), and (8), the received optical path The reachable count value 32 is incremented by 1 and transferred to the optical transmission device 10f via the control information transfer wavelength 16a.

(11) The optical transmission device 10a does not correspond to the above (1), (3), (5), or (7), and sets the optical path reachable count value 32 from the optical transmission device 10f via the control information transfer wavelength 16b. When not received, the value of the optical path reachable count value 32 is set to 1, and the value is transferred to the optical transmission device 10b via the control information transfer wavelength 16b.
(12) The optical transmission device 10a does not correspond to the above (2), (4), (6), or (8), and the optical path reachable count value 32 is set from the optical transmission device 10b via the control information transfer wavelength 16a. If not received, the value of the optical path reachable count value 32 is set to 1, and the value is transferred to the optical transmission device 10f via the control information transfer wavelength 16a.

(13) In the optical transmission device 10a, the optical path reachable count value that does not correspond to the above (1), (3), (5), and (7) and is received from the optical transmission device 10f via the control information transfer wavelength 16b If 32 is the same value as the total number of optical transmission devices 10 on the WDM optical fiber ring 11a, the optical path reachable count value 32 is not counted up and remains as the received value, and is transmitted via the control information transfer wavelength 16b. Transfer to the transmission apparatus 10b.
(14) In the optical transmission device 10a, the optical path reachable count value that does not correspond to the above (2), (4), (6), and (8) and is received from the optical transmission device 10b via the control information transfer wavelength 16a When 32 is the same value as the total number of optical transmission apparatuses 10 on the WDM optical fiber ring 11b, the optical path reachable count value 32 is not counted up and remains as the received value, and is transmitted through the control information transfer wavelength 16a. Transfer to the transmission device 10f.

Next, the operation will be described.
First, a normal signal transmission operation will be described by taking as an example a case where a signal is transmitted from the optical transmission device 10a to the optical transmission device 10b. The main signal input to the transponder module 22 of the optical transmission apparatus 10a which is the transmission source is an optical signal having a specific main signal transfer wavelength 15 designated by the control CPU circuit 23 in the supervisory control module 22, and optical add / drop The signal is output to the module 21, wavelength-multiplexed by the optical add / drop module 21, and transferred to the optical transmission device 10 b as the transmission destination via the WDM optical fiber ring 11. In the optical add / drop module 21 of the optical transmission device 10b as the transmission destination, the corresponding wavelength 15 designated by the control CPU circuit 23 in the supervisory control module 22 is DROP to the transponder module 22 and output from the transponder module 22. Main signal transfer between the optical transmission apparatuses 10 is performed.

Explanation of optical path recovery operation when a failure occurs:
Next, with reference to FIG. 3 and FIG. 4, an optical path restoration operation when a failure occurs in the WDM ring network will be described. Note that location information of each optical transmission device 10 in the WDM optical fiber ring 11 (information on how many other optical transmission devices 10 exist ahead of the own optical transmission device 10 in each WDM optical fiber ring 11). Are notified in advance by the network management device 12 or the like, and are recognized by each optical transmission device 10.

  FIG. 3 shows the WDM network state and the transfer state of the optical path reachable count value 32 when a failure occurs in the WDM optical fiber ring 11b between the optical transmission device 10c and the optical transmission device 10d. The optical transmission device 10a detects that the optical path 18a addressed to the optical transmission device 10d has become unable to communicate due to a failure, and detects the arrival of the optical path based on alarm information 33 as failure information exchanged between the optical transmission devices 10. It is recognized that the reception state of the possible count value 32 has changed as shown below. Since the optical path reachable count value 32 is constantly updated / transferred along the same route as the alarm information transfer, a new optical path reachable count value 32 in the failure occurrence state is almost the same time as the alarm information recognition. Can be recognized.

Specific numerical value of the optical path reachable count value:
A specific update operation of the optical path reachable count value 32 in the optical path reachable count value control circuit 24 of each optical transmission apparatus 10 when a failure occurs will be described. Here, the optical path reachable count values 32a and 32d corresponding to the main signal transfer wavelengths 14a and 15a will be described.

  The optical path reachable count value 32a corresponding to the main signal transfer wavelength 14a is counted regardless of the optical path reachable count value transferred from the optical transmission apparatus 10f because the main signal is dropped in the optical transmission apparatus 10a. The value is set to 0 and transferred to the optical transmission device 10b (control method (5) described above). In the optical transmission devices 10b and 10c, since the main signal is THROUGH, the optical path reachable count value transferred from the adjacent optical transmission device is set to 0 and transferred to the opposite optical transmission device (described above). Control method (5)). Since the optical transmission device 10d ADDs the main signal, the optical path reachable count value is set to 1 and transferred to the optical transmission device 10e regardless of the optical path reachable count value transferred from the optical transmission device 10c. (Control method (7) described above). The optical transmission apparatuses 10c and 10d correspond to the case shown in the above control method (9), and add 1 to the optical path reachable count value transferred from the adjacent optical transmission apparatus, and the adjacent optical transmission on the opposite side. Transfer to device.

  The optical path reachable count value 32d corresponding to the main signal transfer wavelength 15a is related to the optical path reachable count value transferred from the optical transmission device 10b because the main signal is ADDed in the optical transmission device 10a. First, the optical path reachable count value is set to 1 and transferred to the optical transmission device 10f (the above-described control method (8)). The optical transmission apparatuses 10f and 10e correspond to the case shown in the above control method (9), and add 1 to the optical path reachable count value transferred from the optical transmission apparatuses 10a and 10f, so that the opposite optical transmission apparatus Transfer to 10e and 10d. The optical transmission device 10d detects a transmission path alarm between the optical transmission device 10c and the optical transmission device 10d, and the optical path reachable count regardless of the value of the optical path reachable count value transferred from the optical transmission device 10e. The value is set to 0 and transferred to the optical transmission device 10c. In the optical transmission devices 10c and 10b, the main signal is THROUGH, so the optical path reachable count value transferred from the adjacent optical transmission devices 10d and 10c is set to 0 and transferred to the opposite optical transmission devices 10b and 10a. (Control method (5) described above).

The optical path reachable count value for each main signal transfer wavelength in the optical transmission device 10a when a failure occurs is as follows.
Main signal transfer wavelength 14a compatible optical path reachable count value 32a = 3
Main signal transfer wavelength 14b compatible optical path reachable count value 32b = 1
Main signal transfer wavelength 14c compatible optical path reachable count value 32c = 6
Main signal transfer wavelength 15a compatible optical path reachable count value 32d = 0
Main signal transfer wavelength 15b compatible optical path reachable count value 32e = 2
Main signal transfer wavelength 15c compatible optical path reachable count value 32f = 2
That is, when a new optical path is newly set with the own optical transmission device 10a as a transmission source,
Main signal transfer wavelength 14a can be used up to 3 devices ahead (addressed to 10f, 10e, 10d) Main signal transfer wavelength 14b can be used up to 1 device ahead (addressed to 10f) Main signal transfer wavelength 14c can be used 6 devices ahead Can be used (to 10f, 10e, 10d, 10c, 10b, (10a)) The main signal transfer wavelength 15a cannot be used The main signal transfer wavelength 15b can be used up to 2 devices ahead (to 10b, 10c) Main It can be determined that the signal transfer wavelength 15c can be used up to two devices ahead (addressed to 10b and 10c).

How to determine a new optical path:
Here, the device distance of the optical transmission devices 10a → 10d is 3 devices when the WDM optical fiber ring 11a is used, and 3 devices when the WDM optical fiber ring 11b is used. As an alternative to the path 18a, it can be seen that the main signal transfer wavelength 14a and the main signal transfer wavelength 14c can be used. The optical transmission device 10a arbitrarily determines an alternative use wavelength from the usable main signal transfer wavelength candidates (the main signal transfer wavelength 14c in FIG. 4), and the optical transmission device 10d as a transmission destination and the light to be relayed The transmission apparatus 10f and 10e can be notified of the alternative use wavelength using the communication information 31, and a new optical path 18c as shown in FIG. 4 can be constructed.

  As described above, in the WDM ring network system shown in the first embodiment of the present invention, up to which optical transmission device 10 each of the main signal transfer wavelengths 14 and 15 in the WDM optical fiber ring 11 is usable. By constantly updating / transferring the indicated optical path reachable count value 32, in each optical transmission apparatus 10, the distance to each of the main signal transfer wavelengths 14, 15 from the own optical transmission apparatus 10 as a starting point (source) is reached. It is possible to autonomously determine whether it is possible, and when setting a new optical path in the event of a failure, etc., it is set only by negotiation between the optical transmission apparatuses 10 without inquiring of the network management apparatus 12 (server), etc. This makes it possible to shorten the recovery time in the event of a failure. In addition, since the conventional WDM ring network system is configured to notify the information of each optical transmission device to the server once, the server extracts only the information related to the optical transmission device for newly setting the optical path from the information of the entire network. However, since each optical transmission device grasps the vacant state of the wavelength in the ring, such complicated processing can be reduced.

  In the first embodiment, the optical path reachable count value 32 is expired by the total number of optical transmission devices 10 on the WDM optical fiber ring 11. By making it possible to count up to a value sufficiently larger than the total number of transmission apparatuses 10, it is possible to make the count expire at the maximum value. In addition, here, the case where the optical path reachable count value corresponding to the direction opposite to the transmission direction of the main signal is transferred is shown. However, the control method of the optical path reachable count value is changed, and the transmission direction of the main signal is changed. You may make it transfer in the same direction.

Embodiment 2. FIG.
In the first embodiment, when a new optical path is set in the event of a failure or the like, the transmission source optical transmission device 10a having determined the use wavelength transmits the communication information 31 to the relay and transmission destination optical transmission devices 10d to 10f. However, in the WDM ring network system shown in the second embodiment, the optical transmission apparatus is the transmission source before the own optical transmission apparatus 10 is used. Can be determined for each of the main signal transfer wavelengths 15, and a rule unified by each optical transmission device is established, so that a new optical path can be newly established without notification of the wavelength used between the optical transmission devices 10. Is set.

  FIG. 5 is a configuration diagram of an optical transmission device (node) in the WDM ring network according to the second embodiment of the present invention, and FIGS. 6 and 7 are diagrams for explaining a recovery operation when a failure occurs in the second embodiment of the present invention. . Also in the WDM ring network system shown in the second embodiment, each of the optical transmission devices 10a to 10f has the same configuration, and FIG. 5 shows the structure of the optical transmission device 10a. 5-7, the same code | symbol as FIGS. 1-4 represents the same or an equivalent part. In FIG. 5, the supervisory control module 20 controls the optical path hop count value 41 for each wavelength in consideration of the transmission path failure status, device alarm status, and wavelength usage status within the supervisory control module 20. A control circuit 40 is provided.

  In FIG. 6, optical path hop count count values 41 a to 41 f are values for determining how many devices before each main signal transfer wavelength 15 can be a transmission source in the transmission destination optical transmission apparatus 10. , Corresponding to the main signal transfer wavelengths 14a to 14c and 15a to 15c in the WDM optical fiber ring 11, respectively.

  In the optical transmission apparatus according to the second embodiment of the present invention, in addition to the optical path reachable count value 32 information described in the first embodiment, each wavelength in the WDM optical fiber ring 11 is controlled using the control information transfer wavelength 16. The optical path hop count count value 41 corresponding to the main signal transfer wavelengths 14 and 15 is also always transferred. The optical path hop count count value 41 is prepared for each of the main signal transfer wavelengths 14 and 15, and is transferred using the control information transfer wavelength 16 in the WDM optical fiber ring 11 in the same direction as the main signal transfer wavelengths 14 and 15. To do. The optical path hop count count value 41 corresponding to each wavelength of the main signal transfer wavelength 14 in the WDM optical fiber ring 11a is the control information transfer wavelength 16a, and each wavelength of the main signal transfer wavelength 15 in the WDM optical fiber ring 11b. The optical path hop count count value 41 corresponding to is transferred at the control information transfer wavelength 16b.

  The control of the optical path reachable count value 32 in the optical reachable count value control circuit 24 is the same as the control method shown in the first embodiment. Hereinafter, a method of controlling the optical path hop count count value 41 in the optical path hop count count control circuit 40 will be described. Although the control method in the optical transmission device 10a is shown here, the optical path hop count count value 41 is controlled in the same manner for the other optical transmission devices 10b to 10e. Also, transmission line abnormalities and device failures are determined from transmission line alarms and device alarms 34 from the monitoring control collection 27. Further, the wavelength usage status (ADD / DROP / THROUGH) is determined from information from the alarm transfer table 25.

(1) In the optical transmission apparatus 10a, when the specific main signal transfer wavelength 14 in the WDM optical fiber ring 11a is ADD / THROUGH, it is received from the optical transmission apparatus 10b via the control information transfer wavelength 16, Regardless of the value of the optical path hop count value 41 corresponding to the specific main signal transfer wavelength 14, the optical path hop count count value 41 corresponding to the specific main signal transfer wavelength 14 is set to 0, and the control information transfer wavelength The data is transferred to the optical transmission device 10f via 16a.
(2) In the optical transmission device 10a, when the specific main signal transfer wavelength 15 in the WDM optical fiber ring 11b is ADD / THROUGH, it is received from the optical transmission device 10f via the control information transfer wavelength 16b, Regardless of the value of the optical path hop count count value 41 corresponding to the specific main signal transfer wavelength 15, the optical path hop count count value 41 corresponding to the specific main signal transfer wavelength 15 is set to 0, and the control information transfer wavelength The data is transferred to the optical transmission device 10b via 16b.

(3) The optical transmission device 10a does not correspond to the above (1), and the transmission path alarm between the optical transmission device 10b → the optical transmission device 10a of the WDM optical fiber ring 11a and all wavelengths of the WDM optical fiber ring 11a When a device alarm that propagates to the receiving side is detected, all main signal transfer wavelengths 14 are supported regardless of the value of the optical path hop count count value 41 received from the optical transmission device 10b via the control information transfer wavelength 16. The optical path hop count count value 41 is set to 1 and transferred to the optical transmission device 10f via the control information transfer wavelength 16a. Further, it is determined that all wavelengths of the WDM optical fiber ring 11a in the own optical transmission device 10a cannot be used.
(4) In the optical transmission device 10a, the above-mentioned (2) is not met, and the transmission path alarm between the optical transmission device 10f → the optical transmission device 10a of the WDM optical fiber ring 11b and all wavelengths of the WDM optical fiber ring 11b When a device alarm that spreads to the receiving side is detected, all the main signal transfer wavelengths 15 are supported regardless of the value of the optical path hop count count value 41 received from the optical transmission device 10f via the control information transfer wavelength 16b. The optical path hop count count value 41 is set to 1 and transferred to the optical transmission device 10b via the control information transfer wavelength 16b. Further, it is determined that all wavelengths of the WDM optical fiber ring 11b in the own optical transmission device 10a are unusable.

(5) In the optical transmission apparatus 10a, a transmission path alarm between the optical transmission apparatus 10b and the optical transmission apparatus 10a having a specific main signal transfer wavelength 14 in the WDM optical fiber ring 11a that does not correspond to the above (1). And when a device alarm that spreads to the reception side of the specific main signal transfer wavelength 14 in the WDM optical fiber ring 11a is detected, the specific alarm received from the optical transmission device 10b via the control information transfer wavelength 16 is received. Regardless of the value of the optical path hop count count value 41 corresponding to the main signal transfer wavelength 14, the control information transfer wavelength 16a is set to 1 with the optical path hop count count value 41 corresponding to the specific main signal transfer wavelength 14 set to 1. To the optical transmission device 10f. Further, it is determined that the specific wavelength of the WDM optical fiber ring 11a in the own optical transmission device 10a cannot be used.
(6) In the optical transmission apparatus 10a, the transmission path alarm between the optical transmission apparatus 10f and the optical transmission apparatus 10a of the specific main signal transfer wavelength 15 in the WDM optical fiber ring 11b that does not correspond to the above (2) And, when a device alarm that spreads to the receiving side of the specific main signal transfer wavelength 15 in the WDM optical fiber ring 11b is detected, the specific alarm received from the optical transmission device 10f via the control information transfer wavelength 16b is received. Regardless of the value of the optical path hop count count value 41 corresponding to the main signal transfer wavelength 15, the optical path hop count count value 41 corresponding to the specific main signal transfer wavelength 15 is set to 1, and the control information transfer wavelength 16b is set to 1. To the optical transmission device 10b. Further, it is determined that the specific wavelength of the WDM optical fiber ring 11b in the own optical transmission device 10a cannot be used.

(7) In the optical transmission device 10a, when the specific main signal transfer wavelength 14 in the WDM optical fiber ring 11a is DROP not corresponding to the above (1), the control information transfer wavelength 16a is transmitted from the optical transmission device 10b. The optical path hop count count value 41 corresponding to the specific main signal transfer wavelength 14 is 1 regardless of the value of the optical path hop count count value 41 corresponding to the specific main signal transfer wavelength 14. Is transferred to the optical transmission device 10f via the control information transfer wavelength 16a.
(8) In the optical transmission device 10a, when the specific main signal transfer wavelength 15 in the WDM optical fiber ring 11b is DROP not corresponding to the above (2), the control information transfer wavelength 16b is transmitted from the optical transmission device 10f. The optical path hop count count value 41 corresponding to the specific main signal transfer wavelength 15 is 1 regardless of the value of the optical path hop count count value 41 corresponding to the specific main signal transfer wavelength 15 received via Is transferred to the optical transmission device 10b via the control information transfer wavelength 16b.

(9) When the optical transmission device 10a does not correspond to the above (1), (3), (5), and (7), the optical path hop count count value 41 received from the optical transmission device 10b via the control information transfer wavelength 16a 1 is added to this value and transferred to the optical transmission device 10f via the control information transfer wavelength 16a.
(10) When the optical transmission device 10a does not correspond to the above (2), (4), (6), or (8), the optical path hop count count value 41 received from the optical transmission device 10f via the control information transfer wavelength 16b 1 is added to this value and transferred to the optical transmission device 10b via the control information transfer wavelength 16b.

(11) When the optical transmission device 10a does not correspond to the above (1), (3), (5), and (7), the optical path hop count count value 41 is obtained from the optical transmission device 10b via the control information transfer wavelength 16a. When not received, the value of the optical path hop count count value 41 is set to 1 and transferred to the optical transmission device 10f via the control information transfer wavelength 16a.
(12) When the optical transmission device 10a does not correspond to the above (2), (4), (6), and (8), the optical path hop count count value 41 is obtained from the optical transmission device 10f via the control information transfer wavelength 16b. If not received, the value of the optical path hop count count value 41 is set to 1, and the value is transferred to the optical transmission device 10b via the control information transfer wavelength 16b.

(13) The optical path hop count count value received from the optical transmission device 10b via the control information transfer wavelength 16 when the optical transmission device 10a does not correspond to the above (1), (3), (5), and (7). If 41 is the same value as the total number of optical transmission devices 10 on the WDM optical fiber ring 11a, the optical transmission device is transmitted via the control information transfer wavelength 16a without counting up the optical path hop count value 41 value. Forward to 10f.
(14) The optical path hop count count value received from the optical transmission device 10f via the control information transfer wavelength 16b when the optical transmission device 10a does not correspond to the above (2), (4), (6), and (8). If 41 is the same value as the total number of optical transmission devices 10 on the WDM optical fiber ring 11b, the optical path hop count count value 41 is not counted up, and the optical value is transmitted through the control information transfer wavelength 16b without being incremented. Transfer to device 10b.

Next, the operation will be described.
Basic operations such as a main signal transfer method and a control information transfer method are the same as those in the first embodiment. Next, the optical path restoration operation when a failure occurs will be described with reference to FIGS. 6 and 7 show examples in which three wavelengths are prepared as the main signal transfer wavelengths 14 and 15 in each WDM optical fiber ring 11, but there is no particular limitation on the number of wavelengths. The same effect can be obtained even in cases other than three. In addition, it is not necessary for the WDM optical fiber rings 11 to have different wavelengths, that is, the wavelengths in the same WDM optical fiber ring 11 need to be different, but the same wavelength may be used between the rings. It is assumed that the location information of the optical transmission device 10 in the WDM optical fiber ring 11 is notified in advance by the network management device 12 or the like and recognized by each optical transmission device 10.

  FIG. 6 shows the WDM network state and the transfer state of the optical path reachable count value 32 and the optical path hop count count value 41 when a failure occurs in the WDM optical fiber ring 11b between the optical transmission device 10c and the optical transmission device 10d. ing. In the optical transmission apparatuses 10a and 10d, the alarm information 33 exchanged between the optical transmission apparatuses 1 detects that the optical path 18a of the optical transmission apparatus 10a → 10d has become unable to communicate due to a failure and can reach the optical path. It is recognized that the reception state of the count value 32 and the optical path hop count value 41 has changed as shown below. Since the optical path reachable count value 32 and the optical path hop count count value 41 are constantly updated / transferred through the same route as the alarm information transfer, a new state in the failure occurrence state is almost the same time as the alarm information recognition. The optical path reachable count value 32 and the optical path hop count count value 41 can be recognized.

  An operation of updating the optical path hop count value 41 in the optical path hop count count control circuit 40 of each optical transmission device 10 when a failure occurs will be described. Here, the optical path hop count count values 41a and 41d corresponding to the main signal transfer wavelengths 14a and 15a will be described.

  The optical path hop count value 41a corresponding to the main signal transfer wavelength 14a is set to 1 regardless of the count value transferred from the optical transmission device 10b because the optical signal is dropped in the optical transmission device 10a. Then, the data is transferred to the optical transmission device 10f (the control method (7) described above). The optical transmission devices 10f and 10e correspond to the case shown in the above control method (9), and add 1 to the count value transferred from the adjacent optical transmission devices 10a and 10f, and the adjacent optical transmission device on the opposite side. Transfer to 10e and 10d. In the optical transmission device 10d, since the optical transmission device 10d ADDs the main signal, the count value is set to 0 regardless of the count value transferred from the optical transmission device 10c and is transferred to the optical transmission device 10c (described above). Control method (1)). In the optical transmission devices 10c and 10b, since the main signal is THROUGH, the optical path hop count count value is set to 0 and transferred to the opposite optical transmission devices 10b and 10a (the above-described control method (1)).

  The optical path hop count value 41d corresponding to the main signal transfer wavelength 15a is set to 0 regardless of the count value transferred from the optical transmission device 10f because the main signal is ADDed in the optical transmission device 10a. Then, the data is transferred to the optical transmission device 10b (the above-described control method (2)). In the optical transmission apparatuses 10b and 10c, since the main signal is THROUGH, the count value is set to 0 and transferred to the previous optical transmission apparatus (the above-described control method (2)). Since the optical transmission device 10d receives the transmission path alarm between the optical transmission device 10c and the optical transmission device 10d of the WDM optical fiber ring 11b, the count value is set regardless of the count value transferred from the optical transmission device 10c. 1 is set and transferred to the optical transmission apparatus 10e (the above-described control method (4)). The optical transmission apparatuses 10e and 10f correspond to the case shown in the above control method (10), add 1 to the count value transferred from the adjacent optical transmission apparatus, and transfer to the adjacent optical transmission apparatus on the opposite side. .

The optical path reachable count value and the optical path hop count count value for each main signal transfer wavelength in the optical transmission apparatuses 10a and 10d are as follows.
Optical transmission device 10a received value:
Main signal transfer wavelength 14a compatible optical path reachable count value 32a = 3
Main signal transfer wavelength 14b compatible optical path reachable count value 32b = 1
Main signal transfer wavelength 14c compatible optical path reachable count value 32c = 6
Main signal transfer wavelength 15a compatible optical path reachable count value 32d = 0
Main signal transfer wavelength 15b compatible optical path reachable count value 32e = 2
Main signal transfer wavelength 15c compatible optical path reachable count value 32f = 2
Main signal transfer wavelength 14a optical path hop count value 41a = 0
Main signal transfer wavelength 14b corresponding optical path hop count value 41b = 4
Main signal transfer wavelength 14c optical path hop count value 41c = 6
Main signal transfer wavelength 15a corresponding optical path hop count value 41d = 3
Main signal transfer wavelength 15b corresponding optical path hop count value 41e = 1
Main signal transfer wavelength 15c compatible optical path hop count value 41f = 3
Optical transmission device 10d received value:
Main signal transfer wavelength 14a compatible optical path reachable count value 32a = 0
Main signal transfer wavelength 14b compatible optical path reachable count value 32b = 4
Main signal transfer wavelength 14c compatible optical path reachable count value 32c = 6
Main signal transfer wavelength 15a optical path reachable count value 32d = 3
Main signal transfer wavelength 15b optical path reachable count value 32e = 1
Main signal transfer wavelength 15c compatible optical path reachable count value 32f = 5
Main signal transfer wavelength 14a corresponding optical path hop count value 41a = 3
Main signal transfer wavelength 14b corresponding optical path hop count value 41b = 1
Main signal transfer wavelength 14c optical path hop count value 41c = 6
Main signal transfer wavelength 15a compatible optical path hop count value 41d = 0
Main signal transfer wavelength 15b compatible optical path hop count value 41e = 4
Main signal transfer wavelength 15c compatible optical path hop count value 41f = 6

As in the case of the first embodiment, when an optical path is newly set from the received optical path reachable count value 32 using the own optical transmission device 10a as a transmission source,
Main signal transfer wavelength 14a can be used up to 3 devices ahead (addressed to 10f, 10e, 10d) Main signal transfer wavelength 14b can be used up to 1 device ahead (addressed to 10f) Main signal transfer wavelength 14c can be used 6 devices ahead Can be used (to 10f, 10e, 10d, 10c, 10b, (10a)) The main signal transfer wavelength 15a cannot be used The main signal transfer wavelength 15b can be used up to 2 devices (to 10b, 10c) Main It can be determined that the signal transfer wavelength 15c can be used up to two devices ahead (to 10b and 10c). In addition, when setting an additional optical path with the own optical transmission device 10d as a transmission source,
Main signal transfer wavelength 14a cannot be used Main signal transfer wavelength 14b can be used up to 4 devices ahead (addressed to 10c, 10b, 10a, 10f) Main signal transfer wavelength 14c can be used up to 6 devices ahead (10c, 10b, 10a) , 10f, 10e, (to 10d) usable main signal transfer wavelength 15a up to 3 devices ahead (to 10e, 10f, 10a) Main signal transfer wavelength 15b up to 1 device ahead (to 10e) ) Usable It can be determined that the main signal transfer wavelength 15c can be used up to 5 devices ahead (addressed to 10e, 10f, 10a, 10b, 10c).

In the optical transmission device 10a, neither of the WDM optical fiber rings 11a and 11b has a transmission line alarm or a device alarm that affects each wavelength on the receiving side. When the optical transmission device 10a is set as a transmission destination (destination), when newly setting an optical path,
The main signal transfer wavelength 14a cannot be used (there is no optical transmission device 10 that can be a transmission source).
The main signal transfer wavelength 14b can be the transmission source of up to four devices (10b, 10c, 10d, 10e). The main signal transfer wavelength 14c is up to six devices (10b, 10c, 10d, 10e, 10f, (10a)) can be a transmission source The main signal transfer wavelength 15a can be a transmission source of up to three devices (10f, 10e, 10d) The main signal transfer wavelength 15b The device (10f) up to 1 device before can be the transmission source The wavelength 15c for main signal transfer can be the device (10f, 10e, 10d) up to 3 devices before transmission I can judge.

In the optical transmission device 10d, there is a transmission path alarm on the receiving side of the WDM optical fiber ring 11b and the received optical path hop count count value 41,
When the own optical transmission device 10d is set as a transmission destination (destination), when newly setting an optical path,
The main signal transfer wavelength 14a can be transmitted from up to three devices (10e, 10f, 10a). The main signal transfer wavelength 14b can be transmitted from one device (10e) before. The main signal transfer wavelength 14c can be the transmission source of up to six devices (10e, 10f, 10a, 10b, 10c, (10d)) The main signal transfer wavelength 15a cannot be used (transmission source) The optical transmission device 10 that can be
The main signal transfer wavelength 15b cannot be used (there is no optical transmission device 10 that can be a transmission source).
The main signal transfer wavelength 15c cannot be used (there is no optical transmission device 10 that can be a transmission source).
Can be determined.

  The device distance of the optical transmission device 10a → 10d is 3 devices when the WDM optical fiber ring 11a is used, and 3 devices when the WDM optical fiber ring 11b is used. As an alternative candidate for the failed optical path 18a, the main signal transfer wavelength 14a and the main signal transfer wavelength 14c can be used, and the failed light in the transmission destination optical transmission device 10d. It can be seen that the main signal transfer wavelength 14a and the main signal transfer wavelength 14c can be used as alternatives for the path 18a. (Wavelength candidates usable in the transmission destination optical transmission device 10a and the transmission source optical transmission device 10d are always the same)

  Here, as a method of determining an alternative use wavelength from a plurality of usable main signal transfer wavelength candidates, for example, in the WDM optical fiber ring 11a and the WDM optical fiber ring 11b, the WDM optical fiber ring 11a is given priority and the same WDM is used. If the optical transmission device 10 unifies the optical fiber ring 11 so as to give priority to the one with the larger wavelength number, the alternative use wavelength is different between the transmission destination optical transmission device 10a and the transmission source optical transmission device 10d. It is possible to use the same alternative use wavelength (main signal transfer wavelength 14c in the above decision rule) without notifying each of the optical transmission apparatuses 10, and a new optical path 18c as shown in FIG. Can be built. Note that if the optical transmission devices 10f and 10e that perform relaying are set to relay an unused wavelength, it is possible to omit notification of the wavelength again when a new optical path is established.

  As described above, the optical path reachable count value 32 information indicating which optical transmission device 10 is in a usable state for each of the main signal transfer wavelengths 14 and 15 in the WDM optical fiber ring 11, and the transmission destination light In the transmission apparatus 10, the transmission destination optical transmission apparatus is constantly updated / transferred with the optical path hop count count value 41 indicating how many of the main signal transfer wavelengths 14 and 15 can be transmission sources. 10 and the transmission source optical transmission device 10 can uniquely determine an alternative use wavelength, and when setting a new optical path in the event of a failure, without inquiring of the network management device 12 (server) or the like, In addition, the recovery time at the time of failure or the like can be further shortened compared to the case shown in the first embodiment without negotiation between the optical transmission apparatuses 10.

  Here, the optical path reachable count value 32 and the optical path hop count count value 41 are configured to expire with the total number of optical transmission devices 10 on the WDM optical fiber ring 11, but the optical path reachable count value 32 is transferred. It is also possible to make the count expire at the maximum value by enabling the area to be counted to a value sufficiently larger than the total number of the optical transmission devices 10.

Embodiment 3 FIG.
In the first embodiment, the optical path reachable count value 32 indicating which optical transmission device 10 is in a usable state for each of the main signal transfer wavelengths 14 and 15 in the WDM optical fiber ring 11 is constantly updated / transferred. However, in the WDM ring network system shown in the third embodiment, whether or not the main signal transfer wavelengths 14 and 15 in the WDM optical fiber ring 11 can be used instead of the optical path reachable count value 32. Bit information (bit information indicating that the corresponding wavelength can be used through the WDM optical fiber ring 11) is used.

  FIG. 8 is a configuration example of an optical transmission device (node) in a WDM ring network according to Embodiment 3 of the present invention, and FIGS. 9 and 10 are explanatory diagrams of recovery operation when a failure occurs in Embodiment 3 of the present invention. is there. Also in the WDM ring network system shown in the third embodiment, each of the optical transmission devices 10a to 10f has the same configuration, and FIG. 8 shows the structure of the optical transmission device 10a. 8 to 10, the same reference numerals as those in FIGS. 1 to 7 represent the same or corresponding parts. The optical path availability information control circuit 42 controls the optical path availability bit information 43 for each wavelength in the supervisory control module 20 in consideration of the transmission path failure status, device alarm status, and wavelength usage status.

  In FIG. 9, optical path availability bit information 43 a to 43 f is bit information indicating whether or not a corresponding wavelength can be used through the WDM optical fiber ring 11, and each is a main signal transfer wavelength in the WDM optical fiber ring 11. 14a to 14c and 15a to 15c. 9 and 10 show examples in which three wavelengths are prepared as the main signal transfer wavelengths in each WDM optical fiber ring 11, but there are no particular restrictions on the number of wavelengths. In addition, it is not necessary for the WDM optical fiber rings 11 to have different wavelengths, and the wavelengths in the same WDM optical fiber ring 11 need to be different, but the same wavelength may be used between the rings.

  In the WDM ring network according to the third exemplary embodiment of the present invention, the main signal transfer wavelengths 14 and 15 in the WDM optical fiber ring 11 can be used through the WDM optical fiber ring 11 using the control information transfer wavelength 16. It is characterized in that the optical path availability bit information 43 indicating whether or not there is always transferred. The optical path usability bit information 43 is prepared for each of the main signal transfer wavelengths 14 and 15, and uses the control information transfer wavelength 16 in the WDM optical fiber ring 11 in the reverse direction to the main signal transfer wavelengths 14 and 15. Forward. That is, the optical path availability bit information 43 corresponding to each wavelength of the main signal transfer wavelength group 14 in the WDM optical fiber ring 11a is the control information transfer wavelength 16b, and the main signal transfer wavelength in the WDM optical fiber ring 11b. The optical path availability bit information 43 corresponding to each wavelength of the group 15 is transferred by the control information transfer wavelength 16a.

  A method for controlling the optical path availability bit information 43 in the optical path availability information control circuit 42 will be described. Although the control method in the optical transmission device 10a is shown here, the optical path availability bit information 43 is controlled in the same manner for the other optical transmission devices 10b to 10e. Information on transmission path abnormality and device failure used for controlling the optical path availability bit information 43 is determined from the transmission path alarm and device alarm 34 from the monitoring control collection 27. Further, the wavelength usage status (ADD / DROP / THROUGH) is determined from information from the alarm transfer table 25.

(1) When a transmission line alarm between the optical transmission device 10b and the optical transmission device 10a of the WDM optical fiber ring 11a and a device alarm that affects all wavelengths of the WDM optical fiber ring 11a are detected in the optical transmission device 10a Regardless of the optical path availability bit information 43 received from the optical transmission device 10f via the control information transfer wavelength 16b, the optical path availability bit information 43 corresponding to all the main signal transfer wavelengths 14 is set to 0. The data is transferred to the optical transmission device 10b via the information transfer wavelength 16b.
When recovery from the alarm state is detected, all main signal transfer is performed regardless of the optical path availability bit information 43 received from the optical transmission device 10f via the control information transfer wavelength 16b for a certain time. The optical path availability bit information 43 corresponding to the wavelength 14 is set to 1 and transferred to the optical transmission device 10b via the control information transfer wavelength 16b.
(2) When the optical transmission device 10a detects a transmission path alarm between the optical transmission device 10f of the WDM optical fiber ring 11b and the optical transmission device 10a and a device alarm that affects all wavelengths of the WDM optical fiber ring 11b. Regardless of the optical path availability bit information 43 received from the optical transmission device 10b via the control information transfer wavelength 16, the optical path availability bit information 43 corresponding to all the main signal transfer wavelengths 15 is set to 0. The data is transferred to the optical transmission device 10f via the information transfer wavelength 16a.
When recovery from the alarm state is detected, all main signal transfer is performed regardless of the optical path availability bit information 43 received from the optical transmission apparatus 10b via the control information transfer wavelength 16a for a certain time. The optical path availability bit information 43 corresponding to the wavelength 15 is set to 1 and transferred to the optical transmission device 10f via the control information transfer wavelength 16a.

(3) In the optical transmission device 10a, a device that propagates the transmission path alarm of the specific main signal transfer wavelength 14 in the WDM optical fiber ring 11a and the specific main signal transfer wavelength 14 in the WDM optical fiber ring 11a. When the alarm is detected, the specific main signal is transmitted regardless of the optical path availability bit information 43 corresponding to the specific main signal transfer wavelength 14 received from the optical transmission device 10f via the control information transfer wavelength 16b. The optical path availability bit information 43 corresponding to the signal transfer wavelength 14 is set to 0 and transferred to the optical transmission device 10b via the control information transfer wavelength 16b. When recovery from the alarm state is detected, use of an optical path corresponding to the specific main signal transfer wavelength 14 received from the optical transmission device 10f via the control information transfer wavelength 16b for a predetermined time. Regardless of the enable / disable bit information 43, the optical path enable / disable bit information 43 corresponding to the specific main signal transfer wavelength 14 is set to 1 and transferred to the optical transmission device 10b via the control information transfer wavelength 16b.
(4) In the optical transmission device 10a, a device that propagates the transmission path alarm of the specific main signal transfer wavelength 15 in the WDM optical fiber ring 11b and the specific main signal transfer wavelength 15 in the WDM optical fiber ring 11b. When an alarm is detected, the specific main signal is transmitted regardless of the optical path availability bit information 43 corresponding to the specific main signal transfer wavelength 15 received from the optical transmission device 10b via the control information transfer wavelength 16. The optical path availability bit information 43 corresponding to the signal transfer wavelength 15 is set to 0 and transferred to the optical transmission device 10f via the control information transfer wavelength 16a. When recovery from the alarm state is detected, use of an optical path corresponding to the specific main signal transfer wavelength 15 received from the optical transmission device 10b via the control information transfer wavelength 16a for a predetermined time. Regardless of the availability bit information 43, the optical path availability bit information 43 corresponding to the specific main signal transfer wavelength 15 is set to 1, and transferred to the optical transmission device 10f via the control information transfer wavelength 16a.

(5) In the optical transmission device 10a, when the specific main signal transfer wavelength 14 in the WDM optical fiber ring 11a is ADD / THROUGH / DROP, it is received from the optical transmission device 10f via the control information transfer wavelength 16b. Regardless of the optical path availability bit information 43 corresponding to the specific main signal transfer wavelength 14, the optical path availability bit information 43 corresponding to the specific main signal transfer wavelength 14 is set to 0 to transfer control information. The light is transferred to the optical transmission device 10b via the wavelength 16b for use.
When the deletion of the optical path is detected, whether or not the optical path corresponding to the specific main signal transfer wavelength 14 received from the optical transmission device 10f via the control information transfer wavelength 16b for a certain period of time is determined. Regardless of the bit information 43, the optical path availability bit information 43 corresponding to the specific main signal transfer wavelength 14 is set to 1, and transferred to the optical transmission device 10b via the control information transfer wavelength 16b.
(6) When the optical transmission device 10a performs THROUGH / DROP on the specific main signal transfer wavelength 15 in the WDM optical fiber ring 11b, it is received from the optical transmission device 10b via the control information transfer wavelength 6a. Regardless of the optical path availability bit information 43 corresponding to the specific main signal transfer wavelength 15, the optical path availability bit information 43 corresponding to the specific main signal transfer wavelength 15 is set to 0, and the control information transfer wavelength The data is transferred to the optical transmission device 10f via 16a.
When the deletion of the optical path is detected, whether or not the optical path corresponding to the specific main signal transfer wavelength 15 received from the optical transmission device 10b via the control information transfer wavelength 16a for a certain period of time is determined. Regardless of the bit information 43, the optical path availability bit information 43 corresponding to the specific main signal transfer wavelength 15 is set to 1 and transferred to the optical transmission device 10f via the control information transfer wavelength 6a.

(7) When the optical transmission device 10a does not correspond to the above (1), (3), and (5), the optical path availability bit information 43 received from the optical transmission device 10f via the control information transfer wavelength 16b is changed. Instead, the received value is transferred to the optical transmission device 10b via the control information transfer wavelength 16b.
(8) When the optical transmission device 10a does not correspond to the above (2), (4), and (6), the optical path availability bit information 43 received from the optical transmission device 10b via the control information transfer wavelength 6a is changed. Instead, the received value is transferred to the optical transmission device 10f via the control information transfer wavelength 16a.

(9) The optical transmission device 10a does not receive the optical path availability bit information 43 from the optical transmission device 10f via the control information transfer wavelength 16b when the above (1), (3), and (5) are not met. In this case, the optical path availability bit information 43 is set to 1 and transferred to the optical transmission device 10b via the control information transfer wavelength 16b.
(10) The optical transmission device 10a does not receive the optical path availability bit information 43 from the optical transmission device 10b via the control information transfer wavelength 16a when the above conditions (2), (4), and (6) are not met. In this case, the optical path availability bit information 43 is set to 1 and transferred to the optical transmission device 10f via the control information transfer wavelength 16a.

  Next, the operation will be described. Basic operations such as a main signal transfer method and a control information transfer method are the same as those in the first embodiment. Next, with reference to FIG. 9 and FIG. 10, an optical path restoration operation when a failure occurs using the optical path availability bit information 43 will be described.

  FIG. 9 shows a WDM network state and a transfer state of the optical path availability bit information 43 when a failure 19 occurs in the WDM optical fiber ring 11b between the optical transmission device 10c and the optical transmission device 10d. In the optical transmission device 10a, the alarm information 33 exchanged between the optical transmission devices 10 detects that the optical path 18a addressed to the optical transmission device 10d has become unable to communicate due to a failure, and the optical path availability bit information 43 It is recognized that the reception state of has changed as shown below. Since the optical path availability bit information 43 is constantly updated / transferred along the same route as the alarm information transfer, the new optical path availability bit information 43 in the failure occurrence state is almost the same time as the alarm information recognition. Can be recognized.

  The update operation of the optical path availability bit information in the optical path availability information control circuit 42 of each optical transmission apparatus when a failure occurs will be described. Here, the optical path availability bit information 43a and 43d corresponding to the main signal transfer wavelengths 14a and 15a will be described.

  The optical path availability bit information 43a corresponding to the main signal transfer wavelength 14a is a bit regardless of the optical path availability bit information transferred from the optical transmission device 10f because the main signal is DROP in the optical transmission device 10a. Information is set to 0 and transferred to the optical transmission apparatus 10b (the above-described control method (5)). In the optical transmission apparatuses 10b and 10c, since the main signal is THROUGH, the optical path availability bit information transferred from the adjacent optical transmission apparatus is set to 0 and transferred to the opposite optical transmission apparatus (described above). Control method (5)). Since the optical transmission device 10d ADDs the main signal, the optical path availability bit information is set to 0 and transferred to the optical transmission device 10e regardless of the optical path availability bit information transferred from the optical transmission device 10c. (Control method (5) described above). The optical transmission devices 10e and 10f correspond to the case shown in the above control method (7), and the adjacent optical transmission device on the opposite side remains the received optical path availability bit information transferred from the adjacent optical transmission device. Forward to.

  The optical path availability bit information 43d corresponding to the main signal transfer wavelength 15a is related to the optical path availability bit information transferred from the optical transmission apparatus 10b because the main signal is ADDed in the optical transmission apparatus 10a. First, the optical path availability bit information is set to 0 and transferred to the optical transmission device 10f (control method (6) described above). In the optical transmission devices 10f and 10e, this corresponds to the case of the control method (8) described above, and the optical path availability bit information transferred from the adjacent optical transmission devices 10a and 10f is not changed, and the received value is reversed. To the optical transmission devices 10e and 10d on the side. The optical transmission device 10d detects a transmission path alarm between the optical transmission device 10c and the optical transmission device 10d, and the optical path availability bit regardless of the value of the optical path availability bit information transferred from the optical transmission device 10e. The information is set to 0 and transferred to the optical transmission device 10c (the control method (2) described above). In the optical transmission devices 10c and 10b, the main signal is THROUGH, so the optical path availability bit information transferred from the adjacent optical transmission devices 10d and 10c is set to 0 and transferred to the opposite optical transmission devices 10b and 10a. (Control method (6) described above).

The optical path availability bit information for each main signal transfer wavelength in the optical transmission device 10a is as follows.
Main signal transfer wavelength 14a compatible optical path availability bit information 43a = 0
Main signal transfer wavelength 14b compatible optical path availability bit information 43b = 0
Main signal transfer wavelength 14c compatible optical path availability bit information 43c = 1
Main signal transfer wavelength 15a compatible optical path availability bit information 43d = 0
Main signal transfer wavelength 15b compatible optical path availability bit information 43e = 0
Main signal transfer wavelength 15c compatible optical path availability bit information 43f = 0
That is, it can be seen that the main signal transfer wavelength 14c can be used as an alternative to the failed optical path 18a. The optical transmission device 10a determines an alternative use wavelength from the usable main signal transfer wavelength candidates, and uses the communication information 31 for the optical transmission device 10d as the transmission destination and the optical transmission devices 10f and 10e that perform the relay. The alternative use wavelength is notified, and a new optical path 18c as shown in FIG. 10 can be constructed.

  As described above, the availability / unavailability bit information for each wavelength (bit information indicating that the corresponding wavelength is usable / impossible through the WDM optical fiber ring 11) is constantly updated / transferred. It is possible to determine whether or not each of the main signal transfer wavelengths 14 and 15 can be used through the WDM optical fiber ring 11. When a new optical path is set in the event of a failure, the network management device 12 (server) or the like is used. Without any inquiry, it is possible to set only by negotiation between the optical transmission apparatuses 10, and it is possible to shorten the recovery time in the event of a failure. Further, in the WDM ring network shown in the present embodiment, although there are fewer main signal transfer wavelength candidates than in the case of the first embodiment, there is an advantage that the amount of information transferred by the optical transmission device 10 can be reduced. is there.

  Note that when a new optical path is constructed based on the optical path availability bit information 43 information, the transmission source optical transmission device 10a that has determined the wavelength used is the relay and transmission destination optical transmission device 10d, 10e, In 10f, the use wavelength is notified using the communication information 31, but the optical path availability bit information 43 is bit information indicating that the corresponding wavelength can be used through the WDM optical fiber ring 11. By making the same determination as that of the transmission source optical transmission apparatus 10a, the transmission destination optical transmission apparatus 10d can also construct a new optical path without negotiation between the optical transmission apparatuses 10.

Embodiment 4 FIG.
In the first to third embodiments, the case where one WDM ring network is used has been described. However, in the WDM ring network system according to the fourth embodiment of the present invention, a plurality of WDM ring networks are provided with optical switches and the like. A case will be described in which a WDM multi-ring network connected without electrical conversion via a transmission device is used.

  FIG. 11 is a configuration example of a WDM multi-ring network according to the fourth embodiment of the present invention, and FIGS. 12 and 13 are diagrams for explaining a recovery operation when a failure occurs according to the fourth embodiment of the present invention. 11 to 13, the WDM multi-ring network includes a WDM ring network X and a WDM ring network Y, and the WDM ring network X includes optical transmission devices 10a, 10b, 10d, 10e, and 10f. Y includes optical transmission devices 10g and 10h. The multi-degree optical transmission apparatus 101c is arranged in both the WDM ring network X and the WDM ring network Y, and has a function of interconnecting each ring in units of wavelengths in addition to the ADD / DROP / THROUGH function in units of wavelengths. doing. The WDM ring network X is connected between the optical transmission devices by a clockwise WDM optical fiber ring 11a and a counterclockwise WDM optical fiber ring 11b, and the WDM ring network Y is counterclockwise. The optical transmission devices are connected by a clockwise WDM optical fiber ring 102b. The control information in the WDM network is configured to be wavelength-multiplexed on the WDM optical fiber ring 11 and transferred to each optical transmission device 10.

  In the WDM ring network shown in FIGS. 11 to 13, optical wavelengths used for transferring a main signal and control information are respectively assigned. In the WDM optical fiber rings 11a, 11b, 102a, and 102b, three main signal transfer wavelengths (14a to 14c) are assigned, respectively, for control information transfer corresponding to the WDM optical fiber rings 11a, 11b, 102a, and 102b. Wavelengths 16a, 16b, 106a, and 106b are respectively assigned.

  An optical path having a function as a signal transfer path set by the optical transmission apparatus 10 will be described with reference to FIGS. 12 and 13. In FIG. 12, from the optical transmission apparatus 10g to the optical transmission apparatus 10a, that is, the main signal transfer wavelength 14a in the WDM optical fiber ring 102a → the wavelength switching in the optical transmission apparatus 101c → the main signal transfer in the WDM optical fiber ring 11a. The main signal is transferred using the optical path 17a of the wavelength 14a for use, and the wavelength 14a in the main signal transfer in the WDM optical fiber ring 11b from the optical transmission device 10a to the optical transmission device 10g is the wavelength in the optical transmission device 101c. Switching → The main signal is transferred using the optical path 17b of the main signal transfer wavelength 13a in the WDM optical fiber ring 102b.

  FIG. 13 shows an optical path when a transmission path failure 19 occurs in the WDM optical fiber ring 102b between the optical transmission apparatus 10c and the optical transmission apparatus 10d. The optical path 17a is the same as the optical path shown in FIG. 3, but an optical path 18c using the WDM optical fiber rings 11a and 102a is newly set in place of the failed optical path 18a.

  12 and 13, optical path reachable count values 32a to 32f are optical path reachable count values corresponding to the main signal transfer wavelengths 14a to 14c in the WDM optical fiber rings 11a and 11b, respectively. The possible count values 32g to 32l are optical path reachable count values corresponding to the main signal transfer wavelengths 14a to 14c in the WDM optical fiber rings 102a and 102b, respectively. The different ring optical path reachable count value 44 is the optical path reachable count value 32 corresponding to each of the main signal transfer wavelengths 14a to 14c in the WDM optical fiber ring 102 received by the multi-degree optical transmission apparatus 101c. It is transferred using the control information transfer wavelength 16 in the fiber ring 11. The different ring optical path reachable count value 45 is an optical path reachable count value 32 corresponding to each of the main signal transfer wavelengths 14a to 14c in the WDM optical fiber ring 11 received by the multi-degree optical transmission apparatus 101c. It is transferred using the control information transfer wavelength 106 in the fiber ring 102.

  In the fourth embodiment, in addition to the optical path reachable count value 32 information of the own WDM ring network shown in the first embodiment, different ring optical path reachable count value information 44, via the multi-degree optical transmission device 101c, 45 is also transferred. That is, in addition to the transfer process of the optical path reachable count value 32 information corresponding to the own WDM ring network described in the first embodiment, the multi-degree optical transmission apparatus 101c performs the following process.

(1) The optical path reachable count value 32 corresponding to each of the main signal transfer wavelengths 14a to 14c in the WDM optical fiber ring 11a received by the multi-degree optical transmission device 101c and each main signal transfer in the WDM optical fiber ring 11b The optical path reachable count value 32 corresponding to the optical wavelengths 14a to 14c is transferred as the different ring optical path reachable count value information 45 at the control information transfer wavelengths 106a and 106b in the WDM optical fiber rings 102a and 102b.
(2) The optical path reachable count value 32 corresponding to each of the main signal transfer wavelengths 14a to 14c in the WDM optical fiber ring 102a received by the multi-degree optical transmission apparatus 101c, and each main signal in the WDM optical fiber ring 102b The optical path reachable count value 32 corresponding to the transfer wavelengths 14a to 14c is transferred as the different ring optical path reachable count value information 44 at the control information transfer wavelengths 16a and 16b in the WDM optical fiber rings 11a and 11b. .
In the multi-degree optical transmission device 101c, when a device alarm that affects the mutual transfer between WDM ring networks occurs, the corresponding different ring optical path reachable count value information 44 corresponding to the main signal transfer wavelength 15 is obtained. 61 is transferred as 0 to the control information transfer wavelength of the opposite WDM ring network.

  Further, the different ring optical path reachable count value information 44 and 45 transferred from the multi-degree optical transmission device 101c is transferred to the subsequent optical transmission device 10 without being processed by each optical transmission device 10. The different ring optical path reachable count value information 44 and 45 that have made a round around the WDM optical fiber ring 11 and returned to the multi-degree optical transmission device 101c are terminated at the multi-degree optical transmission device 101c.

Next, the operation will be described.
Basic operations such as a main signal transfer method and a control information transfer method are the same as those in the first embodiment.
With reference to FIG. 12 and FIG. 13, the optical path restoration operation when a failure occurs will be described. 12 and 13 show an example in which three wavelengths are prepared as the main signal transfer wavelengths 15 in each WDM optical fiber ring 11, but there is no particular restriction on the number of wavelengths. Further, although the same wavelength group 14a to 14c is used as the main signal transfer wavelength in each WDM optical fiber ring 11, it is not always necessary to set the same wavelength group. Further, the location information of the optical transmission device 10 and the multi-degree optical transmission device 101c in the WDM optical fiber ring 11 (how many optical transmission devices 10 exist ahead of the optical transmission device 10 in each WDM optical fiber ring 11). ) Is notified in advance by the network management device 12 or the like and is recognized by each of the optical transmission devices 10 and the multi-degree optical transmission device 101c.

  FIG. 12 shows a WDM network state and a transfer state of the optical path reachable count value 32 when a failure occurs in the WDM optical fiber ring 102b between the multi-degree optical transmission device 101c and the optical transmission device 10g. In the optical transmission device 10a, the alarm information 33 exchanged between the optical transmission devices 10 detects that the optical path 16b addressed to the optical transmission device 10g has become unable to communicate due to a failure, and the optical path reachable count value 32 It is recognized that the reception state and the different ring optical path reachable count value information 44 have changed as shown below. Since the optical path reachable count value 32 and the different ring optical path reachable count value information 44 and 45 are constantly updated / transferred along the same route as the alarm information transfer, at almost the same time as the alarm information recognition, The new optical path reachable count value 32 and the different ring optical path reachable count value information 44 and 45 in the failure occurrence state can be recognized.

Optical signal reachable count value 32a = 4 corresponding to wavelength 14a for main signal transfer in WDM optical fiber ring 11a
Optical signal reachable count value 32b = 6 corresponding to wavelength 14b for main signal transfer in WDM optical fiber ring 11a
WDM optical fiber ring 11a main signal transfer wavelength 14c corresponding optical path reachable count value 32c = 6
Optical signal reachable count value 32d = 0 corresponding to wavelength 14a for main signal transfer in WDM optical fiber ring 11b
Optical signal reachable count value 32e = 6 corresponding to wavelength 14b for main signal transfer in WDM optical fiber ring 11b
Optical signal reachable count value 32f = 6 corresponding to wavelength 14c for main signal transfer in WDM optical fiber ring 11b
Different ring optical path reachable count value information 44 corresponding to wavelength 14a for main signal transfer in WDM optical fiber ring 102a
Different ring optical path reachable count value information 44 corresponding to wavelength 14b for main signal transfer in WDM optical fiber ring 102a
WDM optical fiber ring 102a main signal transfer wavelength 14c compatible different ring optical path reachable count value information 44 = 3
Different ring optical path reachable count value information 44 = 0 corresponding to wavelength 14a for main signal transfer in WDM optical fiber ring 102b
Different ring optical path reachable count value information 44 = 0 corresponding to wavelength 14b for main signal transfer in WDM optical fiber ring 102b
Different ring optical path reachable count value information 44 = 0 corresponding to wavelength 14c for main signal transfer in WDM optical fiber ring 102b
That is, when a new optical path is newly set with the own optical transmission device 10a as a transmission source,
In the own WDM network X,
The main signal transfer wavelength 14a in the WDM optical fiber ring 11a can be used up to 4 devices ahead (addressed to 10f, 10e, 10d, 101c). The main signal transfer wavelength 14b in the WDM optical fiber ring 11a can be used up to 6 devices ahead (10f, 10e, 10d, 101c, 10b, (to 10a)) The wavelength 14c for main signal transfer in the WDM optical fiber ring 11a is up to 6 devices (to 10f, 10e, 10d, 101c, 10b, (10a)) Usable Wavelength 14a for main signal transfer in WDM optical fiber ring 11b is unusable Wavelength 14b for main signal transfer in WDM optical fiber ring 11b is addressed to up to 6 devices ahead (10b, 101c, 10d, 10e, 10f, (10a) ) Usable Wavelength 14c for main signal transfer in the WDM optical fiber ring 11b is up to 6 devices ahead (10b, 101c) 10d, 10e, 10f, it is available (10a) to the addressed) can be determined.

In the WDM network Y starting from the multi-degree optical transmission device 101c,
The main signal transfer wavelength 14a in the WDM optical fiber ring 102a can be used up to 2 devices ahead (to 10h, 10g). The main signal transfer wavelength 14b in the WDM optical fiber ring 102a can be used up to 3 devices ahead (10h, 10g, (101c). Can be used) The main signal transfer wavelength 14c in the WDM optical fiber ring 102a can be used up to 3 devices ahead (to 10h, 10g, (101c)). The main signal transfer wavelength 14a in the WDM optical fiber ring 102b is used. Impossible The main signal transfer wavelength 14b in the WDM optical fiber ring 102b cannot be used. It can be determined that the main signal transfer wavelength 14c in the WDM optical fiber ring 102b cannot be used.

Here, the device distance from the optical transmission device 10a to the multi-degree optical transmission device 101c is 2 devices when the WDM optical fiber ring 11a is used, and 4 devices when the WDM optical fiber ring 11b is used, and the multi-degree optical transmission device 101c. → Since the optical transmission device 10g has two device distances when the WDM optical fiber ring 102a is used and one device when the WDM optical fiber ring 102b is used, the optical path 18a in which the failure has occurred can be substituted based on the above determination. As between the optical transmission device 10a and the multi-degree optical transmission device 101c,
Wavelength 14a for main signal transfer in the WDM optical fiber ring 11a
Wavelength 14b for main signal transfer in the WDM optical fiber ring 11a
Wavelength 14c for main signal transfer in the WDM optical fiber ring 11a
Wavelength 14b for main signal transfer in the WDM optical fiber ring 11b
Wavelength 14c for main signal transfer in the WDM optical fiber ring 11b
Is a wavelength candidate for main signal transfer that can be used between the multi-degree optical transmission device 101c and the optical transmission device 10g,
Wavelength 14a for main signal transfer in the WDM optical fiber ring 102a
Wavelength 14b for main signal transfer in the WDM optical fiber ring 102a
Wavelength 14c for main signal transfer in the WDM optical fiber ring 102a
Is a usable main signal transfer wavelength candidate.
The optical transmission device 10a determines an alternative wavelength to be used from the usable main signal transfer wavelength candidates, and transmits the optical transmission device 1g as a transmission destination, the optical transmission devices 10b and 10h that perform relaying, and the multi-degree optical transmission device 101c. The alternative use wavelength is notified using the communication information 31, and a new optical path 18c as shown in FIG. 13, for example, can be constructed.

  As described above, in the WDM ring network shown in the fourth embodiment, in addition to the optical path reachable count value 32 information of the own WDM ring network described in the first embodiment, different rings are transmitted via the multi-degree optical transmission apparatus 101c. By transferring the optical path reachable count value information 44 and 45 as well, in each optical transmission device 10, it is possible to determine how far each main signal transfer wavelength 5 can reach from the own optical transmission device 10 as a starting point (transmission source). Even in a WDM multi-ring network environment, when a new optical path is set up in the event of a failure or the like, only negotiation between the optical transmission apparatuses 10 is possible without inquiring of the network management apparatus 12 (server) or the like. This makes it possible to make settings and shorten the recovery time in the event of a failure.

  Here, the optical path reachable count value 32 expires by the total number of optical transmission devices 10 on the WDM optical fiber ring 11, but the area where the optical path reachable count value 32 is transferred is defined as the optical transmission device 10. By making it possible to count up to a value sufficiently larger than the total number, it is possible to make the count expire at the maximum value.

  Here, in the multi-degree optical transmission apparatus, only the different ring optical path reachable count value information is transferred between the WDM ring networks. In addition to the above information, the optical transmission described in the second embodiment is performed. Since the pass hop count value is also transferred between WDM ring networks, the recovery time in the event of a failure or the like can be further shortened compared to the fourth embodiment without negotiation between optical transmission apparatuses.

  In this example, the multi-degree optical transmission apparatus transfers different ring optical path reachable count value information between WDM ring networks. However, the optical path availability bit information described in the third embodiment is used. By transferring data between WDM ring networks, the number of wavelength candidates for main signal transfer is reduced as compared with the fourth embodiment, but the amount of information transferred between optical transmission apparatuses can be reduced.

  Also, here, a case is described in which there is one multi-degree optical transmission device connecting between WDM ring networks, but by adding a multi-degree optical transmission device number to the different ring optical path reachable count value information. It is also possible to support a configuration in which WDM ring networks are connected by a plurality of multi-degree optical transmission devices.

  In the fourth embodiment, two WDM ring networks are taken as an example of the WDM multi-ring network, but three or more tandem-connected by adding a WDM network number to different ring optical path reachable count value information. It is possible to correspond to other WDM ring networks. By adding the WDM network number and the multi-degree optical transmission apparatus number to the different ring optical path reachable count value information, it is possible to deal with three or more complicatedly intertwined WDM ring networks.

DESCRIPTION OF SYMBOLS 10 Optical transmission apparatus, 11 WDM optical fiber ring, 12 Network management apparatus, 13 Communication path, 14, 15 Main signal transfer wavelength, 16, 17 Control information transfer wavelength, 20 Supervisory control module, 21 Optical add / drop module, 22 Transponder module, 23 control CPU circuit, 24 optical path reachable count value control circuit, 25 alarm transfer table, 26 alarm transfer control, 27 alarm information collection, 28 control light termination, 29 demultiplexer, 30 multiplexer, 31 communication Information, 32 optical path reachable count value, 33 alarm information, 34-36 transmission path alarm and device alarm, 40 optical path hop count count control circuit, 41 optical hop count count value, 42 optical path availability information control circuit, 43 Optical path availability bit information, 44, 45 Different ring optical path reachable count value information

Claims (6)

A plurality of optical transmission devices for transferring a main signal to each other using a wavelength for main signal transfer;
An optical fiber that connects between the plurality of optical transmission devices and constitutes a wavelength division multiplexing ring network that performs wavelength division multiplexing optical communication in cooperation with the plurality of optical transmission devices;
Provided in the plurality of optical transmission devices, a plurality of the main signal transfer wavelength, information wavelengths usable information and a about what is available for the transfer of each of the main signal, a plurality of said main signal transfer Control information transfer means for transferring information about which optical transmission device each wavelength can be a transmission source to the adjacent optical transmission device using the control information transfer wavelength;
Provided in the plurality of optical transmission devices, based on the information transferred by the control information transfer means, a used wavelength determination means for determining a main signal transfer wavelength used for the transfer of the main signal,
A main signal input / output means for inputting / outputting the main signal to / from the wavelength division multiplexing ring network using the main signal transfer wavelength determined by the used wavelength determining means;
A wavelength division multiplex ring network system comprising: The wavelength usable information, according to claim 1, wherein said main signal transfer wavelengths of multiple is information about whether available from the optical transmission device respectively to any other optical transmission device Wavelength division multiplexing ring network system. An information collecting means for collecting fault information about the failure that occurred on the usage and the wavelength multiplexing ring network of the main signal transfer wavelength,
Wavelength usable information updating means for updating the transferred wavelength usable information based on the usage status and failure information collected in the information collecting means;
The wavelength division multiplexing ring network system according to claim 1, comprising: Comprising an optical transmission device you interconnecting multiple wavelength division multiplexing ring network,
The optical transmission device is
Comprising information transfer means for transferring the wavelength usable information received in the wavelength division multiplexing ring network to an optical transmission device of a wavelength division multiplexing ring network different from the wavelength division multiplexing ring network;
The wavelength division multiplexing ring network system according to any one of claims 1 to 3, wherein: An optical transmission device that is connected to each other by an optical fiber and constitutes a wavelength division multiplexing ring network that performs wavelength division multiplexing optical communication,
A plurality of main signal transfer wavelength, the wavelength available information and information about whether it is available for the transfer of the main signals, a plurality of said main signal transfer wavelength, a source to which the optical transmission unit, respectively Control information transfer means for transferring information about whether or not it is possible to transfer to the adjacent optical transmission device using a control information transfer wavelength;
Based on the information transferred by the control information transfer means, a used wavelength determination means for determining a main signal transfer wavelength used for the transfer of the main signal,
Main signal input / output means for inputting / outputting the main signal to / from the wavelength division multiplexing ring network using the wavelength for main signal transfer determined by the used wavelength determining means;
An optical transmission device comprising: An information collecting means for collecting fault information about the failure that occurred on the usage and the wavelength multiplexing ring network of the main signal transfer wavelength,
Wavelength usable information updating means for updating the transferred wavelength usable information based on the usage status and failure information collected in the information collecting means;
The optical transmission device according to claim 5, further comprising:

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