JP2012004800A - Node device of optical network system and redundancy changeover method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a node device of an optical network system and a redundancy changeover method.SOLUTION: A node device of an optical network system is formed of a combination of an OXC inputting and outputting WDM signals on a plurality of paths to switch their routes for individual unit wavelengths and an ODU-XC connecting, in a cross connect manner, functions of reproduction processing and wavelength conversion of an optical signal for each wavelength. On an input side and an output side of a user IF part, first and second optical SWs are disposed, respectively. Add ports of the user IF connect to add ports of the OXC via the first optical SW and a first high speed transponder, and connect to add ports of the ODU-XC via the first optical SW and a first low speed transponder. Drop ports of the user IF connect to drop ports of the OXC via the second optical SW and a second high speed transponder and connect to drop ports of the ODU-XC via the second optical SW and a second low speed transponder.

Description

  The present invention relates to an optical cross-connect (OXC) that inputs / outputs WDM signals and switches paths in units of wavelengths, and an ODU (Optical Data) that switches paths of electrical signals that have undergone regeneration processing and wavelength conversion of optical signals of each wavelength. The present invention relates to a node device and a redundant switching method of an optical network system combining Unit) -XC.

  The optical network system has a function of inserting an optical signal from a client into the optical network and extracting it to the client, and a device that multiplexes and outputs the inserted optical signal to the optical network and outputs it as an optical cross connect (OXC). Yes. It is known that the OXC is configured with a multiplexer / demultiplexer, an optical switch, a wavelength selective switch, and the like (Patent Document 1).

  Also, a WDM transmission device using OXC or WDM signals is connected to a terminal device that performs client signal path switching, multiplexing, and demultiplexing. In recent years, in order to reduce the transponder between the WDM transmission apparatus and the terminal station apparatus and the operation cost, a node apparatus that integrates the functions of OXC and ODU-XC as shown in FIG. 10 has been proposed.

  In FIG. 10, a node device is connected to a WDM transmission line and switches between OXCs that perform path switching in units of wavelengths, and a user IF add-drop port and an OXC add-drop port via IF units 31 and 32. Between the high-speed transponders 13 and 14 that perform signal processing, the ODU-XC that performs electrical signal path switching, and the user IF add-drop port and the ODU-XC add-drop port via the IF units 31 and 32. Low-speed transponders 15 and 16 that perform optical / electrical conversion and electrical / optical conversion, and transponders 17 and 18 that perform multiplexing / separation between OXC and ODU-XC are provided. The ODU-XC and each transponder have a function of a terminal device connected to the user IF unit of the OXC.

JP 2008-252664 A

  Due to the diversification of services used by users, the required signal bandwidth is varied. When the connection port of the node device differs depending on the service, it can be considered that the reliability is reduced and the device space is increased due to erroneous connection of the operator.

  In addition, a transponder for performing electrical / optical conversion and optical / electrical conversion of a signal processed by the ODU-XC has a high possibility of failure of the laser and the receiver unit, and it is necessary to examine the response when the transponder fails. Further, it is known that a transponder is required for each wavelength signal, and the number of transponders increases as the transmission capacity increases. For this reason, the increase in the number of failures, power consumption, and arrangement space due to an increase in transponders has been a problem.

  The present invention provides a node device and a redundancy switching method for an optical network system that unify input / output IF connection ports regardless of the signal band and type, thereby reducing the device space and simplifying the operations of the operator. For the purpose.

  The first invention includes an OXC that inputs / outputs WDM signals of a plurality of routes and switches the route in units of wavelengths, and an ODU-XC that cross-connects each function of optical signal reproduction processing and wavelength conversion of each wavelength. In the node device of the combined optical network system, the first and second optical SWs are arranged on the input side and the output side of the user IF unit, respectively, and the add port of the user IF is the first optical SW and the first high-speed transponder Is connected to the add port of the OXC via the first optical SW and the first low speed transponder, and is connected to the add port of the ODU-XC. The drop port of the user IF is the second optical SW and the second high speed It is connected to the drop port of OXC via a transponder, and the ODU-XC is dropped via a second optical SW and a second low-speed transponder. Is a configuration that is connected to the port.

  According to a second invention, in the node device of the first invention, the L2SW connected to the OXC and the ODU-XC is provided, and an add port of the user IF is connected to the L2SW via the first optical SW and the third low-speed transponder. The drop port of the user IF is connected to the add port, and is connected to the drop port of the L2SW via the second optical SW and the fourth low-speed transponder.

  Each of the first or second high-speed transponders is composed of a plurality of working transponders and a spare transponder having the same characteristics as the plurality of working transponders, and performs a fault monitoring of the working transponder. When the failure is detected, a monitoring control unit is provided that controls path switching between the optical SW and the OXC and performs redundant switching from the current transponder to the spare transponder.

  Each of the first or second low-speed transponder is composed of a plurality of working transponders and a spare transponder having the same characteristics as the plurality of working transponders, and performs a failure monitoring of the working transponder. When the failure is detected, a monitoring control unit is provided that controls path switching between the optical SW and the ODU-XC and performs redundant switching from the current transponder to the standby transponder.

  Each of the third or fourth low-speed transponders has a plurality of working transponders and a spare transponder that has the same characteristics as the plurality of working transponders and is shared by the plurality of working transponders. When the failure is detected, a monitoring control unit is provided that controls path switching between the optical SW and the L2SW and performs redundant switching from the current transponder to the standby transponder.

  In the redundant switching method of the node device according to the first aspect of the invention, each of the first or second high-speed transponder has a plurality of working transponders and a standby characteristic shared by the plurality of working transponders, having the same characteristics as the plurality of working transponders. It is composed of transponders, and the monitoring control unit monitors the failure of the working transponder. When the failure is detected, the path switching between the optical SW and the OXC is controlled, and the redundant switching from the working transponder to the standby transponder is performed.

  In the redundant switching method of the node device according to the first aspect of the invention, each of the first or second low-speed transponders has a plurality of working transponders and a standby characteristic shared by the plurality of working transponders, and has the same characteristics as the plurality of working transponders. It is composed of transponders, and the supervisory control unit monitors the failure of the active transponder. When the failure is detected, the path switching between the optical SW and the ODU-XC is controlled, and the redundant switching from the active transponder to the standby transponder is performed.

  In the redundant switching method for a node device according to the second aspect of the invention, each of the third or fourth low-speed transponders has a plurality of working transponders and a standby characteristic shared by the plurality of working transponders. It is composed of transponders, and the monitoring control unit monitors the failure of the active transponder, and when the failure is detected, the path switching between the optical SW and the L2SW is controlled, and the redundant switching from the active transponder to the standby transponder is performed.

  According to the present invention, a transponder having a high failure rate is made into a redundant configuration, and a plurality of working transponders share a spare transponder, so that switching at the time of working transponder failure and quick redundancy construction at the time of working transponder failure can be realized. .

It is a figure which shows the structure of Example 1 of the node apparatus of the optical network system of this invention. It is a figure which shows the operation example 1 of the node apparatus of the optical network system of this invention. It is a figure which shows the operation example 2 of the node apparatus of the optical network system of this invention. It is a figure which shows the operation example 3 of the node apparatus of the optical network system of this invention. It is a figure which shows the operation example 4 of the node apparatus of the optical network system of this invention. It is a figure which shows the structure of Example 2 of the node apparatus of the optical network system of this invention. It is a figure which shows the operation example 5 of the node apparatus of the optical network system of this invention. It is a figure which shows the operation example 6 of the node apparatus of the optical network system of this invention. It is a figure which shows the other structural example of an OXC function part. It is a figure which shows the structural example of the conventional node apparatus.

FIG. 1 shows a configuration of a first embodiment of a node device of an optical network system according to the present invention.
In FIG. 1, a node device is connected to a WDM transmission line, and switches OXC that performs path switching in units of wavelengths, and a high-speed transponder 13 that performs predetermined signal processing between an add / drop port of a user IF and an add / drop port of a user IF. , 14, ODU-XC for switching the path of the electrical signal, and low-speed transponders 15, 16 for performing optical / electrical conversion and electrical / optical conversion between the add / drop port of the user IF and the add / drop port of the ODU-XC And transponders 17 and 18 that perform multiplexing / separation between OXC and ODU-XC. The ODU-XC and each transponder have a function of a terminal device connected to the user IF unit of the OXC.

  For example, the high-speed transponders 13 and 14 are 100 GbE (OTU4 (100 Gbps)), the low-speed transponders 15 and 16 are ODU2 (10 Gbps), and the transponders 17 and 18 that perform ODU multiplexing / demultiplexing are ODU2 (10 Gbps) × 10 (OTU4 (100 Gbps)) ).

  A feature of the present invention is a configuration in which non-blocking matrix optical switches (optical SW) 11 and 12 are arranged in the user IF unit (UNI / NNI). The user IF add port is connected to the OXC add port (from Add) via the optical SW 11 and the high speed transponder 13, and is connected to the ODU-XC add port (from Add) via the optical SW 11 and the low speed transponder 15. The user IF drop port is connected to the OXC drop port (to drop) via the optical SW 12 and the high-speed transponder 14, and is connected to the ODU-XC drop port (to drop) via the optical SW 12 and the low-speed transponder 16. The

  The high-speed transponders 13 and 14 are configured to share a spare transponder among a plurality of working transponders, such as one spare transponder for three working transponders. Similarly, the low-speed transponders 15 and 16 have a configuration in which a spare transponder is shared by a plurality of active transponders. The monitoring control unit 19 monitors the operation of each transponder and controls the path switching of the optical SWs 11 and 12, OXC, and ODU-XC.

  Accordingly, since the user IF can connect to the OXC or ODU-XC regardless of the optical SW input port, for example, an erroneous connection when the operator connects to the user IF can be eliminated. Also, since the user IF can be connected to OXC or ODU-XC regardless of the optical SW input port, it can be connected to ODU-XC according to the transmission capacity of the client signal, or directly to OXC without going through ODU-XC. Can be connected, and the load on the ODU-XC can be reduced. In addition, since the current transponder and the spare transponder can be selected and connected from the user IF regardless of the input port of the optical SW, the redundant configuration of the transponder having a high failure rate optical / electrical conversion and electrical / optical conversion function Can respond flexibly.

  The OXC function unit of the node device may be configured as shown in FIG. That is, the coupler (CPL) receives the WDM signal and branches it, and inputs it to a plurality of wavelength selective switches (WSS) and OXC duplexers. The demultiplexer demultiplexes the WDM signal into optical signals of respective wavelengths and inputs them to the OXC. The OXC outputs the optical signal received by the client from the optical signal of each wavelength to the drop port, inputs the optical signal transmitted by the client from the add port, outputs it to the multiplexer corresponding to the predetermined outgoing route, Wavelength multiplexed optical signals with wavelengths are output to WSS. The WSS receives and demultiplexes a WDM signal input from the CPL and a WDM signal input from the OXC, exchanges wavelengths transmitted and received by the client, and transmits a WDM signal combined with a through wavelength.

FIG. 2 shows an operation example 1 of the node device of the optical network system of the present invention.
Here, in the low-speed transponder 15 on the input side of the ODU-XC, the supervisory control unit 19 detects the failure of the working transponder, controls the optical SW 11 and the ODU-XC, and sets the spare transponder from the broken line path passing through the working transponder. The state switched to the path of the continuous line which passes is shown.

The route switching control procedure is as follows.
(1) The supervisory control unit 19 detects a failure of the current transponder and detects an input interruption by the ODU-XC.
(2) The supervisory control unit 19 switches to the spare transponder by switching the path between the optical SW 11 and the ODU-XC.
(3) The monitoring control unit 19 changes the setting of the spare transponder based on the setting information. There is no change in OXC.

  The redundant configuration of the point-to-point WDM system and the ring system so far has to be combined with the path redundancy in which two active and spare transponders output to different paths. However, in this embodiment, by realizing a redundant configuration in the apparatus, it is possible to realize high reliability by combining the redundancy of the transponder and the path redundancy.

FIG. 3 shows an operation example 2 of the node device of the optical network system of the present invention.
Here, in the low-speed transponder 16 on the output side of the ODU-XC, the supervisory control unit 19 detects the failure of the working transponder, controls the optical SW 12 and the ODU-XC, and sets the spare transponder from the broken line path passing through the working transponder. The state switched to the path of the continuous line which passes is shown.

The route switching control procedure is as follows.
(1) The supervisory control unit 19 detects a failure of the current transponder.
(2) The supervisory control unit 19 switches to the spare transponder by switching the path between the optical SW 12 and the ODU-XC.
(3) The monitoring control unit 19 changes the setting of the spare transponder based on the setting information. There is no change in OXC.

  When the input and output are mounted on the same transponder, both patterns shown in FIG. 2 and FIG. 3 are collated under the OR condition, and the location of the failure is detected.

FIG. 4 shows an operation example 3 of the node device of the optical network system of the present invention.
Here, in the high-speed transponder 13 on the input side of the OXC, the supervisory control unit 19 detects a failure of the working transponder, controls the optical SW 11 and the OXC, and passes through the standby transponder from the broken line path passing through the working transponder. The state switched to the route is shown.

The route switching control procedure is as follows.
(1) The supervisory control unit 19 detects a failure of the current transponder.
(2) The monitoring control unit 19 switches to the spare transponder by switching the path between the optical SW 11 and the OXC.
(3) The monitoring control unit 19 changes the setting of the spare transponder based on the setting information.

FIG. 5 shows an operation example 4 of the node device of the optical network system according to the present invention.
Here, in the high-speed transponder 14 on the output side of the OXC, the supervisory control unit 19 detects a failure of the working transponder, controls the optical SW 12 and the OXC, and passes through the standby transponder from the broken line path passing through the working transponder. The state switched to the route is shown.

The route switching control procedure is as follows.
(1) The supervisory control unit 19 detects a failure of the current transponder.
(2) The supervisory control unit 19 switches to the spare transponder by switching the path between the optical SW 12 and the OXC.
(3) The monitoring control unit 19 changes the setting of the spare transponder based on the setting information.

  If the input and output are mounted on the same transponder, both patterns shown in FIGS. 4 and 5 are collated under the OR condition, and the location of the failure is detected.

FIG. 6 shows a configuration of a second embodiment of the node device of the optical network system according to the present invention.
The node device according to the present embodiment includes an L2SW connected to the OXC and the ODU-XC in the configuration of the first embodiment illustrated in FIG. The add port of the user IF is connected to the add port (from Add) of the L2SW via the optical SW 11 and the low speed transponder 21, and the drop port of the user IF is the drop port (to drop) of the L2SW via the optical SW 12 and the low speed transponder 22. Connected to. OXC and L2SW are connected via high-speed transponders 23 and 24.

FIG. 7 shows an operation example 5 of the node device of the optical network system of the present invention.
Here, in the low-speed transponder 21 on the input side of the L2SW, the supervisory control unit 19 detects a failure of the working transponder, controls the optical SW11 and the L2SW, and is a solid line that passes through the standby transponder from the broken line path that passes through the working transponder. The state switched to the route is shown.

The route switching control procedure is as follows.
(1) The supervisory control unit 19 detects the failure of the current transponder and detects the input interruption of the L2SW.
(2) The supervisory control unit 19 switches to the spare transponder by switching the path between the optical SW 11 and the L2SW.
(3) The monitoring control unit 19 changes the setting of the spare transponder based on the setting information.

FIG. 8 shows an operation example 6 of the node device of the optical network system according to the present invention.
Here, in the low-speed transponder 22 on the output side of the L2SW, the supervisory control unit 19 detects the failure of the working transponder, controls the optical SW 12 and the L2SW, and passes through the spare transponder from the broken line path passing through the working transponder. The state switched to the route is shown.

The route switching control procedure is as follows.
(1) The supervisory control unit 19 detects a failure of the current transponder.
(2) The supervisory control unit 19 switches to the spare transponder by switching the path between the optical SW 12 and the L2SW.
(3) The monitoring control unit 19 changes the setting of the spare transponder based on the setting information.

  When the input and output are mounted on the same transponder, both patterns shown in FIGS. 7 and 8 are collated under the OR condition, and the location of the failure is detected.

  The same control procedure can be used to switch the route to the spare transponder for the failure of the current transponder of the high-speed transponder 23 from L2SW to OXC and the failure of the current transponder of the high-speed traffic 24 from OXC to L2SW. It is.

11,12 Matrix optical switch (optical SW)
13, 14 High-speed transponder 15, 16 Low-speed transponder 17, 18 Transponder 19 Monitoring control unit 21, 22 Low-speed transponder 23, 24 High-speed transponder

Claims (8)

OXC (optical cross-connect) that inputs / outputs WDM signals in multiple paths and switches the path in units of wavelengths, and ODU (Optical Data Unit) that cross-connects each function of optical signal regeneration processing and wavelength conversion for each wavelength In the node device of the optical network system combined with -XC,
First and second matrix optical switches (hereinafter referred to as “optical SW”) are arranged on the input side and output side of the user IF unit (UNI / NNI), respectively.
The user IF add port is connected to the OXC add port via the first optical SW and the first high-speed transponder, and the ODU-XC add port via the first optical SW and the first low-speed transponder. Connected to
The drop port of the user IF is connected to the drop port of the OXC via the second optical SW and the second high-speed transponder, and the ODU-XC is connected via the second optical SW and the second low-speed transponder. A node device of an optical network system, characterized in that the node device is connected to a drop port. In the node apparatus of the optical network system of Claim 1,
L2SW connected to the OXC and the ODU-XC,
The user IF add port is connected to the L2SW add port via the first optical SW and a third low-speed transponder;
The node port of the optical network system, wherein the drop port of the user IF is connected to the drop port of the L2SW via the second optical SW and a fourth low-speed transponder. In the node apparatus of the optical network system of Claim 1,
Each of the first or second high-speed transponders includes a plurality of working transponders and a spare transponder having the same characteristics as the plurality of working transponders and shared by the plurality of working transponders,
A monitoring control unit that performs failure monitoring on the working transponder, controls path switching between the optical SW and the OXC when the failure is detected, and performs redundancy switching from the working transponder to the spare transponder; A node device of an optical network system. In the node apparatus of the optical network system of Claim 1,
Each of the first or second low-speed transponders includes a plurality of working transponders and a spare transponder having the same characteristics as the plurality of working transponders and shared by the plurality of working transponders,
A monitoring control unit is provided that performs failure monitoring of the working transponder, controls path switching between the optical SW and the ODU-XC when the failure is detected, and performs redundancy switching from the working transponder to the backup transponder. A node device of an optical network system. The node device of the optical network system according to claim 2,
Each of the third or fourth low-speed transponders includes a plurality of working transponders and a spare transponder having the same characteristics as the plurality of working transponders and shared by the plurality of working transponders,
A monitoring control unit that performs failure monitoring on the current transponder, controls path switching between the optical SW and the L2SW when the failure is detected, and performs redundancy switching from the current transponder to the spare transponder; A node device of an optical network system. In the redundant switching method of the node device of the optical network system according to claim 1,
Each of the first or second high-speed transponders includes a plurality of working transponders and a spare transponder having the same characteristics as the plurality of working transponders and shared by the plurality of working transponders,
The monitoring control unit performs failure monitoring of the working transponder, and when the failure is detected, controls path switching between the optical SW and the OXC, and performs redundancy switching from the working transponder to the backup transponder. A redundant switching method for node devices in an optical network system. In the redundant switching method of the node device of the optical network system according to claim 1,
Each of the first or second low-speed transponders includes a plurality of working transponders and a spare transponder having the same characteristics as the plurality of working transponders and shared by the plurality of working transponders,
The monitoring control unit performs failure monitoring of the working transponder, and when the failure is detected, controls path switching between the optical SW and the ODU-XC, and performs redundancy switching from the working transponder to the standby transponder. A redundant switching method for node devices in an optical network system. In the redundant switching method of the node device of the optical network system according to claim 2,
Each of the third or fourth low-speed transponders includes a plurality of working transponders and a spare transponder having the same characteristics as the plurality of working transponders and shared by the plurality of working transponders,
The monitoring control unit performs failure monitoring of the working transponder, and when the failure is detected, controls path switching between the optical SW and the L2SW, and performs redundancy switching from the working transponder to the backup transponder. A redundant switching method for node devices in an optical network system.

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