JP4757742B2 - Ring type optical transmission system - Google Patents

Description

  The present invention relates to a ring-type optical transmission system that compensates for chromatic dispersion of an optical path between end-to-end (transmitting end and receiving end) of optical communication.

  In current optical networks, in order to compensate for signal distortion caused by optical fiber dispersion, a dispersion compensation fiber according to the amount of chromatic dispersion between adjacent nodes is designed in advance (specifically, the amount of chromatic dispersion between nodes). Mounted on each node based on the measurement results. That is, dispersion compensation is performed so that the chromatic dispersion amount becomes zero between all adjacent nodes.

  However, this means that dispersion compensation is performed multiple times for each optical path that relays a plurality of nodes in units of links (here, the nodes are called links). Compensation costs are significant.

  Therefore, the chromatic dispersion amount between each node (link unit) is measured, the information is exchanged between nodes, and the chromatic dispersion amount management server is notified, so that the chromatic dispersion amount of the entire optical path can be determined in link units. Is obtained by accumulating the amount of chromatic dispersion (see, for example, Patent Document 1 and Patent Document 2). As a result, for one optical path that relays a plurality of nodes, only dispersion compensation for compensating the accumulated chromatic dispersion amount needs to be performed. Therefore, dispersion compensation cost is lower than dispersion compensation for each link. Can be reduced.

JP 2003-121303 A JP 2004-274238 A

  In the future, when the bit rate is increased (for example, from 10 Gb / s to 40 Gb / s or 160 Gb / s), more accurate dispersion compensation is required.

  For this reason, if an attempt is made to realize a function for measuring the chromatic dispersion amount as many as the number of links accommodated by the node, a function for measuring the highly accurate and expensive chromatic dispersion amount is required for the number of links. The cost of the entire transmission system increases.

  Further, even if a highly accurate chromatic dispersion amount is measured for each link, the error is accumulated in the process of accumulating the chromatic dispersion amount for each link. Further, in the link unit measurement, the chromatic dispersion amount of the optical device or the like in the relay node of the optical path cannot be ignored.

  In order to solve the above problems, the present invention operates a dispersion-compensated optical path in a ring-type optical transmission system by measuring chromatic dispersion amounts of all optical path candidates in advance at high speed and low cost. It is an object of the present invention to provide a ring-type optical transmission system that can be set up in an automatic manner.

  The ring-type optical transmission system according to the present invention is a ring-type optical transmission system in which a plurality of nodes are connected via optical fibers, and the plurality of nodes are connected to other nodes on the ring using a supervisory control wavelength. Node control means for controlling the communication of the network and chromatic dispersion amount measurement means for measuring the chromatic dispersion quantity between the nodes on the ring, and the node control means collects address information of the nodes connected on the ring A node that holds the chromatic dispersion amount measurement token for measuring the chromatic dispersion amount based on the address information of each node, and a node that holds the chromatic dispersion amount measurement token using the chromatic dispersion amount measurement unit; Measure the chromatic dispersion of the optical path between the nodes on the ring where the chromatic dispersion is to be measured, and measure the chromatic dispersion after completing the measurement of the chromatic dispersion to all nodes. And wherein the passing the token to the next node.

  According to the present invention, it is possible to provide a ring-type optical transmission system capable of dynamically setting dispersion-compensated optical paths by measuring chromatic dispersion amounts of all optical path candidates in advance at high speed and at low cost. it can.

Embodiment 1 FIG.
1 is a block diagram showing a configuration of a ring-type optical transmission system according to Embodiment 1 of the present invention. As shown in FIG. 1, the nodes 1, 2, 3 of the ring type optical transmission system are connected via optical fibers 4, 5, 6. In practice, client devices 7 and 8 such as routers and switches are connected to the ring optical transmission system via control networks 11 and 12.

  FIG. 2 is a block diagram showing a configuration of a node, for example, node 1 in the ring type optical transmission system shown in FIG. The node 1 accommodates a client device, and communicates with a destination client accommodation unit that accommodates a destination client device by a desired optical signal via a ring optical transmission system (here, client accommodation units 21 and 22). Then, the client device 7 is accommodated in the client accommodating unit 21), the chromatic dispersion amount measuring unit 23 for measuring the chromatic dispersion amount, and communication with other nodes on the ring using the monitoring control wavelength. In addition to the control, the node control unit 24 that accommodates the control network 11 with the client device, and the optical signals of different wavelengths transmitted from the client accommodation units 21 and 22, the chromatic dispersion amount measurement unit 23, and the node control unit 24 The optical signal may be multiplexed to the fiber 4 or the optical fiber 6, or the optical signals of multiple wavelengths that have propagated through the optical fiber may be demultiplexed for each wavelength. An optical multiplexer / demultiplexer 25 and an optical signal demultiplexed by the optical multiplexer / demultiplexer 25 are passed through or connected to a desired client accommodating portion, or an optical signal from the client accommodating portion is connected to a desired optical fiber. And an optical switch 26. The nodes 2 and 3 have the same configuration.

Next, the operation of the ring-type optical transmission system according to the above configuration will be described with reference to the flowchart showing the control operation of the node control unit 24 shown in FIG.
It is assumed that address information (for example, an IP address, etc.) for communicating with each node on the ring is set in advance in each of the nodes 1, 2, and 3 through the monitoring control wavelength. For example, an IP address 10.0.0.1 is set for node 1, an IP address 10.0.0.2 is set for node 2, and an IP address 10.0.0.3 is set for node 3.

  The node control unit 24 of each of the nodes 1, 2, 3 communicates with adjacent nodes via the monitoring control wavelength, and holds a right to measure the chromatic dispersion amount on the ring (a chromatic dispersion amount measurement token) Is determined (step S30 in FIG. 3). For example, if the node having the smallest set IP address holds the chromatic dispersion measurement token first, then the node 1 holds the chromatic dispersion measurement token.

  First, for example, the node control unit 24 of the node 1 transmits a ring monitoring message for collecting the order of the nodes connected on the ring and address information for communicating with those nodes, for example, clockwise. I will do it.

FIG. 4 is a diagram illustrating an example of a ring monitoring message.
As shown in FIG. 4, the ring monitoring message includes the number of entries and address information. When transmitting the ring monitoring message, the node 1 registers its own address information and transmits it to the node 2 that is the right node. Since node 2 refers to the first entry and is not the ring monitoring message transmitted by itself, it additionally registers its own node address information 10.0.0.2 and transmits it to node 3 which is the right node. To do. Similarly, since the node 3 refers to the first entry and is not the ring monitoring message transmitted by itself, the node 3 additionally registers the address information 10.0.0.3 of its own node, and is the node that is the right node. Send to 1. Similarly, the node 1 refers to the first entry, and since the address information 10.0.0.1 of the own node is registered, the node 1 determines that the ring monitoring message is transmitted by itself.

  As a result, the node 1 can collect node address information in the order of the nodes connected on the ring, based on the entry information registered in the ring monitoring message. Based on the address information of each node, the node that holds the chromatic dispersion measurement token is determined. In this case, the node that holds the chromatic dispersion measurement token is determined as node 1 and notified to other nodes. The

Next, the node control unit 24 of the node 1 holding the chromatic dispersion measurement token sequentially measures the chromatic dispersion amount with each node (step S31 in FIG. 3).
First, a case where the node 1 measures the clockwise chromatic dispersion amount with the node 2 will be described with reference to FIG.
The node control unit 24 of the node 1 first sets the optical switch 26 to connect the chromatic dispersion amount measuring unit 23 to the optical fiber 4 and transmits a chromatic dispersion amount measurement start request to the node 2.

  Similarly, the node 2 that has received the chromatic dispersion measurement start request sets the optical switch so that the chromatic dispersion measurement unit 23 is connected to the optical fiber 4, performs the measurement start setting, and starts the chromatic dispersion measurement measurement OK. A response is returned.

  Upon receiving the chromatic dispersion amount measurement start OK response, the node 1 controls the chromatic dispersion amount measurement unit 23 to start measuring the chromatic dispersion amount with the node 2. The chromatic dispersion amount is measured by, for example, using a fixed wavelength for measurement λ1 and a fixed wavelength for measurement λ2, transmitting a specific signal pattern at the same time, and measuring the time difference between the signal patterns on the receiving side. carry out.

  The chromatic dispersion measuring unit of node 2 notifies the measured chromatic dispersion to node 1 by means of a chromatic dispersion measurement result notification message.

  When receiving the chromatic dispersion amount measurement result notification message, the node control unit 24 of the node 1 determines that the measurement of the chromatic dispersion amount is completed, sets the optical switch 26, and sets the chromatic dispersion amount measurement unit 23 and the optical fiber. 4 is released, and a chromatic dispersion measurement completion request is transmitted to the node 2.

  When the node 2 receives the chromatic dispersion amount measurement completion request, similarly, the node 2 sets the optical switch 26 to release the connection between the chromatic dispersion amount measuring unit 23 and the optical fiber 4, and the node 1 A quantity measurement completion OK response is transmitted.

  As described above, the node 1 can measure the amount of chromatic dispersion with the node 2.

  Similarly, the node 1 measures the clockwise chromatic dispersion amount with the node 3. When the measurement of the clockwise chromatic dispersion amount for all the nodes is completed, the node 1 next measures the counterclockwise chromatic dispersion amount.

  As described above, the node 1 can measure the clockwise and counterclockwise chromatic dispersion amounts between all the nodes on the ring.

  When the node control unit 24 of the node 1 completes the measurement of the chromatic dispersion amount with respect to all the nodes (step S32 in FIG. 3), it transmits the chromatic dispersion measurement token to the next node, for example, the node 2 (FIG. 3). 3 step S33). The node 2 that has received the chromatic dispersion measurement token measures the clockwise and counterclockwise chromatic dispersion amounts with all the nodes on the ring in the same manner as the node 1, and then further follows the chromatic dispersion measurement token. By transmitting to this node, it becomes possible for all nodes to measure the amount of chromatic dispersion between all nodes.

Next, a case where the client device 7 sets an optical path to the client device 8 will be described.
The client device 7 transmits an optical path setting request to the client device 8 via the control network 11 to the node control unit 24 of the node 1. The node control unit 24 selects an optimum optical path as the optical path to the node 2. For example, the chromatic dispersion amounts of the clockwise optical path and the counterclockwise optical path are compared, an optical path with a small chromatic dispersion amount is selected, and a wavelength to be used at the same time is determined.

  Here, it is assumed that a clockwise optical path is selected. The node control unit 24 of the node 1 sets a wavelength to be used for the client accommodation unit 21 that accommodates the client device 7, controls the optical switch 26, and connects the client accommodation unit 21 and the optical fiber 4. . Then, an optical path setting request is transmitted to the node control unit of node 2. The optical path setting request includes the wavelength to be used, the path of the optical path (clockwise), and the chromatic dispersion amount of the optical path.

  When the node control unit of the node 2 receives the optical path setting request, the node control unit sets the wavelength to be used for the client accommodating unit accommodating the client device 8 and controls the optical switch to control the client accommodating unit and the optical fiber. 4 is connected. Then, an optical path setting request is transmitted to the client device 8.

  As described above, the client accommodating units of the node 1 and the node 2 are connected, and can communicate with each other by the dispersion compensation using the chromatic dispersion amount measured in advance.

  As a result, the dispersion-compensated optical path between the client device 7 and the client device 8 can be set. The specific procedure for setting the optical path is realized by the GMPLS technology being standardized by the IETF.

  As described above, in the ring-type optical transmission system, the chromatic dispersion amount of all the optical paths is measured in advance using the chromatic dispersion amount measurement token. Therefore, the following effects can be obtained.

(1) Since the measurement of the amount of chromatic dispersion is performed by starting from the node holding the token, it is not necessary to check whether the chromatic dispersion amount measuring unit 23 can be used.
(2) Since there is no need to accumulate chromatic dispersion amounts in units of links, there are few errors.
(3) Since it is not necessary to measure the amount of chromatic dispersion when setting an optical path, the optical path setting time can be shortened.

  In the above embodiment, the node control unit 24 of the node holding the chromatic dispersion measurement token completes the measurement of the chromatic dispersion measurement token between all the nodes on the ring. However, the same effect can be obtained by calculating the chromatic dispersion amount between the nodes while keeping the chromatic dispersion measurement token and notifying all the nodes on the ring.

It is a block diagram which shows the structure of the ring type optical transmission system which concerns on Embodiment 1 of this invention. FIG. 2 is a block diagram showing a configuration of a node 1 in the ring type optical transmission system shown in FIG. 1. It is a flowchart explaining the control operation | movement by the node control part 24 of the node shown by FIG. It is a figure which shows the example of a ring monitoring message. FIG. 6 is a diagram for explaining a case where the node 1 measures the clockwise chromatic dispersion amount between the node 1 and the node 2.

Explanation of symbols

  1 to 3 Ring type optical transmission system node, 4 to 6 optical fiber, 7 and 8 client device, 11 and 12 control network, 21 and 22 client accommodation unit, 23 wavelength dispersion measurement unit, 24 node control unit, 25 optical coupling Demultiplexer, 26 optical switch.

Claims (2)

In a ring-type optical transmission system in which a plurality of nodes are connected via optical fibers,
Each of the plurality of nodes includes a node control unit that controls communication with other nodes on the ring using a supervisory control wavelength, and a chromatic dispersion amount measurement unit that measures a chromatic dispersion amount between nodes on the ring. ,
The node control means includes
By collecting the address information of the nodes connected on the ring, the node holding the chromatic dispersion measurement token that measures the chromatic dispersion based on the address information of each node is determined,
Measure the chromatic dispersion of the optical path between the node holding the chromatic dispersion measurement token using the chromatic dispersion measuring means and the nodes on the ring where the chromatic dispersion is to be measured,
The ring-type optical transmission system, wherein after completion of measurement of the chromatic dispersion amount to all nodes, the chromatic dispersion measurement token is passed to the next node. The ring-type optical transmission system according to claim 1,
The node control means includes
A ring-type optical transmission system characterized by notifying all nodes on the ring of the amount of chromatic dispersion between nodes.

Images