JP4805135B2 - Optical cross-connect device - Google Patents

Description

  The present invention is an optical cross-connect that is disposed at one or more connection points of a plurality of optical networks and connects two systems of optical paths across the plurality of optical networks interposed between the transmitting end side and the receiving end side. It relates to the device.

  As an optical cross-connect device used in a wide-area optical network composed of a plurality of optical networks, here, in order to facilitate understanding of the present invention, an optical cross-connect device in a multi-ring network in which a plurality of optical ring networks are connected is taken as an example. Will be described. As an optical cross-connect device used in a multi-ring network, for example, the one disclosed in Patent Document 1 is known. The outline will be described below with reference to FIGS. FIG. 14 is a system diagram illustrating a configuration example of a multi-ring network including a conventional optical cross-connect device and a control operation during normal operation. FIG. 15 is a diagram showing a configuration example of the conventional optical cross-connect device shown in FIG. 16 and 17 are diagrams for explaining a recovery operation when a failure occurs.

  FIG. 14 shows a multi-ring network in which two of an optical ring network A (RingA) and an optical ring network B (RingB) are connected by an optical cross connect device (OXC) 2f. RingA and RingB are both composed of westward optical transmission lines 301 and 304 and eastward optical transmission lines 302 and 303, and the optical cross-connect device 2f is also two optical transmission lines in RingA and B. Are provided with ports W and E corresponding to.

A large number of optical add / drop multiplexers 1a, 1b, and 1c for branching and inserting wavelength-multiplexed optical signals in units of wavelengths are arranged on two optical transmission lines on Ring A, and a large number of optical add / drop multiplexers 1d on Ring B as well. , 1e, 1f are arranged. FIG. 14 shows a case where the optical add / drop multiplexer 1a on RingA is the transmitting end and the optical add / drop multiplexer 1f on RingB is the receiving end. That is, each optical add / drop device has the same configuration, the transmission system is configured as shown in the optical add / drop device 1a, and the reception system is configured as shown in the optical add / drop device 1f.

  The optical add / drop multiplexer 1a includes a splitter (DIS) 101, transponders (transceivers) 102a and 102b, and OADMs (Optical Add Drop Multiplexers) 103a and 103b. The branching device 101 splits an optical signal input from the outside into two and supplies it to the transponders 102a and 102b. The transponder 102a generates a transmission signal (wavelength multiplexed optical signal) for the westbound optical transmission line 301. The transponder 102b generates a transmission signal (wavelength multiplexed optical signal) for the eastbound optical transmission line 302. The OADM 103a inserts the transmission signal from the transponder 102a into the Ring A westbound optical transmission line 301, and the like. The OADM 103b inserts the transmission signal from the transponder 102b into the Ring A eastbound optical transmission line 302, and the like.

  The optical add / drop device 1f includes OADMs 103c and 103d, transponders 102c and 102d, and a selector (SEL) 104. The OADM 103c takes in an optical signal (wavelength multiplexed optical signal) from the Ring B westbound optical transmission line 304 and supplies the optical signal to the transponder 102d. The OADM 103d takes an optical signal (wavelength multiplexed optical signal) from the RingB eastbound optical transmission line 303 and supplies the optical signal to the transponder 102d. Each of the transponders 102c and 102d performs a reception process and supplies it to the selector 104. The selector 104 selects one received optical signal and outputs it to the outside.

  As illustrated in FIG. 15, the optical switch unit included in the optical cross-connect device 2f includes a westbound optical transmission path and a eastbound optical transmission path for RingA, and a westbound optical transmission path for RingB. As a configuration for switching the connection between the eastbound optical transmission line and the eastbound optical transmission line, in RingA and RingB, there is an input / output relationship between the westbound optical transmission line and the eastbound optical transmission line. Although they are opposite to each other, four 1 × 3 wavelength selective switches (WSS) 208a, 208b, 208c, 208d are provided on the input side in a one-to-one relationship with each optical transmission line. On the output side, four 3 × 1 wavelength selective switches (3 × 1 WSS) 202a, 202b, 202c, 202d are provided.

  Each of the 1 × 3 wavelength selective switches 208 (a, b, c, d) organizes wavelength-multiplexed optical signals from one input port into three sets obtained by combining one or more optical signals of arbitrary wavelengths. Sends to the corresponding output port of the output port. Each of the 3 × 1 wavelength selective switches 202 (a, b, c, d) selects one of the wavelength multiplexed optical signals from the three input ports and sends it to one output port. Since the configuration of the 3 × 1 wavelength selective switch is described in detail in Patent Document 2, description thereof is omitted here.

  For example, three output ports of the 1 × 3 wavelength selective switch 208a connected to the WestA optical transmission line of RingA are connected to the eastward optical transmission line of the same RingA. One of the three input ports of the switch 202a, one of the three input ports of the 3 × 1 wavelength selective switch 202c connected to a different RingB east optical transmission line, and the west of the different RingB It is connected to one of the three input ports of the 3 × 1 wavelength selective switch 202d connected to the surrounding optical transmission line. The same applies to the other 1 × 3 wavelength selective switches 208 (b, c, d). As described above, in the optical cross-connect device 2f, an optical path of a certain Ring can be connected to the reverse optical transmission path of the same Ring, or can be connected to one of the two optical transmission paths included in the other Ring. It can be carried out.

  Thereby, as shown in FIG. 14, the optical cross-connect device 2f normally has a transmitting end side (optical add / drop device 1a) existing on Ring A and a receiving end side (optical add / drop device 1f) existing on Ring B, as shown in FIG. The active system optical path (solid line) and the standby system optical path (broken line) straddling both Rings are formed between them, and when a failure occurs, route switching to avoid the failed route is performed as shown in FIGS. Go and take measures to relieve the working optical path. This will be specifically described below.

  In FIG. 14, the wavelength division multiplexed optical signal transmitted by the transponder 102a of the optical add / drop multiplexer 1a on Ring A in the normal state is sent from the OADM 103a to the westward optical transmission line 301 as shown by the solid line, and the optical cross-connect device. It is sent to the eastbound optical transmission line 303 of RingB at 2f, which is taken in by the OADM 103d of the optical add / drop multiplexer 1f on RingB and delivered to the transponder 102d.

  Further, the wavelength multiplexed optical signal transmitted by the transponder 102b of the optical add / drop multiplexer 1a on Ring A is sent from the OADM 103b to the eastbound optical path 302 as shown by a broken line, and is westbound on RingB by the optical cross-connect device 2f. It is sent to the optical path 304, which is taken in by the OADM 103c of the optical add / drop multiplexer 1f on Ring B and delivered to the transponder 102c.

  In FIG. 14, the optical transmission lines 301 and 303 are formed between the optical add / drop multiplexer 1a on Ring A on the transmitting end side and the optical add / drop multiplexer 1f on Ring B on the receiving end side. A state is shown in which a working optical path and a standby optical path composed of optical transmission lines 302 and 304 are formed, and wavelength multiplexed optical signals are transmitted using the respective optical paths. In the optical cross-connect device 2f, in FIG. 15, a control unit (not shown) sends the transmission end sent to the westward optical transmission line 301 of Ring A to the output port on the 3 × 1 wavelength selective switch 202c side of the 1 × 3 wavelength selective switch 208a. The wavelength-multiplexed optical signal on the transmission side is output, and the wavelength-multiplexed optical signal on the transmitting side sent to the east-bound optical transmission line 302 of Ring A is output to the 3 × 1 wavelength selective switch 202d-side output port of the 1 × 3 wavelength selective switch 208b It is output. Also, a control unit (not shown) causes the 3 × 1 wavelength selective switch 202c to select the output of the 1 × 3 wavelength selective switch 208a, and causes the 3 × 1 wavelength selective switch 202d to select the output of the 1 × 3 wavelength selective switch 208b. Yes.

  In this case, as shown in FIG. 16, when a transmission failure occurs in the Ring A westward optical transmission line 301, the optical cross-connect device 2f detects that an optical signal abnormality detector (not shown) detects an abnormality in the working optical path. A control unit (not shown) switches the output port of the 1 × 3 wavelength selective switch 208b from the 3 × 1 wavelength selective switch 202d side to the 3 × 1 wavelength selective switch 202c side and performs the selection operation of the 3 × 1 wavelength selective switch 202d. By stopping and switching the selection target of the 3 × 1 wavelength selective switch 202c to the output of the 1 × 3 wavelength selective switch 208b, the eastbound optical transmission path 302 of RingA connected to the westbound optical transmission path 304 of RingB is changed. It switches so that it may connect to the eastbound optical transmission line 303 of RingB. As a result, the working optical path is reconfigured by the eastbound optical transmission path 302 of Ring A and the eastbound optical transmission path 303 of RingB, and an optical signal can be normally transmitted across both Rings.

  Next, as shown in FIG. 17, when a transmission failure occurs in the RingB eastbound optical transmission line 303, the optical cross-connect device 2f is connected to the output port of the 1 × 3 wavelength selective switch 208b. Are switched from the 3 × 1 wavelength selective switch 202c side to the 3 × 1 wavelength selective switch 202d side, and the selection operation of the 3 × 1 wavelength selective switch 202c is stopped and 1 × is applied to the 3 × 1 wavelength selective switch 202d. By selecting the output of the three-wavelength selection switch 208b again, switching is performed so that the eastbound optical transmission path 302 of RingA connected to the eastbound optical transmission path 303 of RingB is connected to the eastbound optical transmission path 304 of RingB. . As a result, the working optical path is reconfigured by the eastbound optical transmission path 302 of Ring A and the eastbound optical transmission path 304 of RingB, and an optical signal can be normally transmitted across both Rings. As described above, even if a transmission failure occurs in both Ring A and Ring B, an optical signal can be normally transmitted from the transmitting end of Ring A to the receiving end of Ring B.

JP 2006-191212 A Special table 2003-515187

  However, in the above conventional optical cross-connect device, when the optical path fails, the connection destination of the optical path is simply switched. Therefore, the optical signal is not connected on the optical transmission line that has been confirmed to be normal until then. There is a problem that sex cannot be confirmed.

  For example, in the example of FIG. 16, when a failure occurs in the westbound optical transmission path 301 of RingA, the optical signal from RingA is not connected to the westbound optical transmission path 304 of RingB. The normality of the road cannot be confirmed. As a result, for example, in RingB, even if the westbound optical transmission line 304 fails before the eastbound optical transmission line 303 fails, it cannot be detected. Even when switching to the circulating optical transmission line 304, the working optical path may not be relieved by RingB. As described above, the conventional optical path connection method using the optical cross-connect device has a problem that the reliability of the redundant optical path deteriorates.

  The present invention has been made in view of the above, and an object thereof is to obtain an optical cross-connect device that can always check the normality of redundant optical paths in a plurality of optical networks.

In order to achieve the above-mentioned object, the present invention connects a plurality of optical networks having at least two optical transmission lines, and includes a plurality of the optical networks to be connected. In an optical cross-connect device that connects two systems of optical paths across a plurality of optical networks interposed therebetween, when m is a natural number of 2 or more, a wavelength multiplexed optical signal input from one optical transmission line is Two or more 1 × m wavelength selective switches that are organized into m combinations of one or more optical signals of arbitrary wavelengths and sent from the corresponding output ports of the m output ports, and the two or more 1 × m wavelength selections Two or more two-branch couplers that are provided for each of the m-1 output ports of each switch and distribute the wavelength multiplexed optical signal output from the corresponding output port into two, and the two or more 1 The same number of m wavelength selective switches as the number of wavelength multiplexed optical signals from the remaining one output port of the corresponding 1 × m wavelength selective switch and two or more wavelength multiplexed optical signals from the two or more two-branch couplers are provided. to delivery the corresponding optical transmission path by choosing a wavelength-multiplexed optical signal having an arbitrary wavelength and a (2m-1) × 1 wavelength selective switch, when the one of the optical path fails, the other The (2m-1) × 1 wavelength selective switch corresponding to the optical transmission path of the optical path receives the wavelength multiplexed optical signal from the optical transmission path of the other optical path, or the two branches. In a state where the output of the coupler is continuously selected, the selection target of the (2m−1) × 1 wavelength selective switch corresponding to the optical transmission line in which the failure has occurred is wavelength-multiplexed from the optical transmission line of the other optical path. the 1 × receiving light signals And switches the output of the output or the two-branch coupler of a wavelength selective switch.

  According to the present invention, when a failure occurs in one optical path and the connection is switched to the other optical path, the switching of the connection is not performed in the other optical path, and the wavelength multiplexed optical signal remains connected. Therefore, the normality confirmation of the optical transmission line can also be performed in parallel. Therefore, the reliability of the redundant optical path can be improved.

  According to the present invention, there is an effect that the reliability of the redundant optical path can be improved.

  Exemplary embodiments of an optical cross-connect device according to the present invention will be explained below in detail with reference to the drawings.

Embodiment 1 FIG.
FIG. 1 is a diagram for explaining a configuration example of a multi-ring network including an optical cross-connect device according to Embodiment 1 of the present invention and working and standby optical paths formed across the rings in a normal state. FIG. 2 is a diagram illustrating a configuration example of the optical cross-connect device illustrated in FIG. In FIG. 1, components that are the same as or equivalent to the components shown in FIG. 14 (conventional example) are given the same reference numerals. Here, the description will focus on the parts related to the first embodiment.

In FIG. 1, two optical ring networks A (RingA) and B (RingB) having the same configuration as in FIG. 14 (conventional example) are connected by an optical cross-connect device (OXC) 2a according to the first embodiment. A multi-ring network is shown. Here, as in FIG. 14 (conventional example), the configuration and operation of the optical cross-connect device 2a when the optical add / drop multiplexer 1a on RingA is the transmitting end and the optical add / drop multiplexer 1f on RingB is the receiving end. Will be described.

  As shown in FIG. 2, the optical switch unit included in the optical cross-connect device 2a includes a westbound (West) optical transmission line of RingA and an eastbound (East) optical transmission line, and a westbound (West) optical transmission line of RingB. As a configuration for switching the connection between the eastbound optical transmission line and the eastbound optical transmission line, in RingA and RingB, there is an input / output relationship between the westbound optical transmission line and the eastbound optical transmission line. Although they are opposite to each other, four 1: 3 couplers 201a, 201b, 201c, 201d are provided on the input side and four 3 × 1 on the output side in a one-to-one relationship with each optical transmission line. Wavelength selective switches (3 × 1 WSS) 202a, 202b, 202c, 202d are provided.

  Each of the 1: 3 couplers 201 (a, b, c, d) receives three wavelength-multiplexed optical signals from one input port in the 3 × 1 wavelength selective switch 202 (a, b, c, d). To distribute. Each of the 3 × 1 wavelength selective switches 202 (a, b, c, d) selects one of the wavelength multiplexed optical signals from the three input ports and sends it to one output port.

  In the example shown in FIG. 2, the wavelength multiplexed optical signal input from the RingA west optical transmission line is divided into three by a 1: 3 coupler 201 a and 3 × 1 wavelength selective switch 202 (a, c, d). ). The wavelength multiplexed optical signal input from the EastA optical transmission line of Ring A is distributed by the 1: 3 coupler 201b and transmitted to the 3 × 1 wavelength selective switch 202 (b, c, d). Further, the wavelength multiplexed optical signal input from the WestB optical transmission line of RingB is divided into three by the 1: 3 coupler 201c and sent to the 3 × 1 wavelength selective switch 202 (a, b, c). . The wavelength multiplexed optical signal input from the EastB optical transmission line of RingB is distributed into three by the 1: 3 coupler 201d and sent to the 3 × 1 wavelength selective switch 202 (a, b, d).

  The output port of the 3 × 1 wavelength selective switch 202a is connected to the EastA optical transmission path of RingA, and the output port of the 3 × 1 wavelength selective switch 202b is the West optical transmission path of RingA. It is connected to the. Further, the output port of the 3 × 1 wavelength selective switch 202c is connected to the RingB eastward optical transmission line, and the output port of the 3 × 1 wavelength selective switch 202d is the RingB westward optical transmission line. It is connected to the.

  With this configuration, the optical cross-connect device 2a is normally connected to the westward light of the Ring A between the optical add / drop device 1a on the ring A that is the transmitting end and the optical add / drop device 1f on the ring B that is the receiving end. The active optical path (solid line) straddling both Rings by the transmission path 301 and the RingB eastbound optical transmission path 303, and both Rings by the RingA eastbound optical transmission path 302 and the RingB westbound optical transmission path 304 are straddled. A backup optical path (broken line) is formed.

  Specifically, in the optical cross-connect device 2a, a control unit (not shown) controls the 3 × 1 wavelength selective switch 202c to select the output of the 1: 3 coupler 201a, and the 3 × 1 wavelength selective switch 202d has 1 : Control to select the output of the three coupler 201b. As a result, the 3 × 1 wavelength selective switch 202c receives from the 1: 3 coupler 201a the wavelength-division multiplexed optical signal transmitted to the westward optical transmission line 301 of Ring A and receives it from the eastward optical transmission line of RingB. 303 is connected. The 3 × 1 wavelength selective switch 202d receives from the 1: 3 coupler 201b the wavelength-division multiplexed optical signal transmitted to the Ring A eastward optical transmission line 302, and receives it from the RingB westward optical transmission line 304. Connected to.

  Next, the operation when a failure occurs will be described with reference to FIGS. FIG. 3 is a diagram for explaining a recovery operation when a failure occurs in RingA in the multi-ring network shown in FIG. FIG. 4 is a diagram for explaining a recovery operation when a failure occurs in RingB in addition to RingA in the multi-ring network shown in FIG.

  As shown in FIG. 3, when a transmission failure occurs in the Ring A westward optical transmission line 301, the optical cross-connect device 2a performs control (not shown) when an optical signal abnormality detector (not shown) detects an abnormality in the working optical path. The 3 × 1 wavelength selective switch 202d continuously selects the output of the 1: 3 coupler 201b, and the connection between the Ring A eastbound optical transmission line 302 and the RingB westbound optical transmission line 304 is maintained. The selection target of the 3 × 1 wavelength selective switch 202c in which the input from the 1: 3 coupler 201a is interrupted is switched to the output of the 1: 3 coupler 201b.

  As a result, in RingB, in addition to the westward optical transmission line 304, the eastward optical transmission line 302 of RingA is also connected to the eastward optical transmission line 303. The working optical path that crosses both Rings by the circulating optical transmission path 303 is reconfigured so that the optical signal can be normally transmitted. In RingB, the normality of the west-circulating optical transmission path 304 that is the standby optical path is also monitored. Can be done in parallel.

  Next, as shown in FIG. 4, when a transmission failure further occurs in the eastbound optical transmission path 303 of RingB, as described above, the eastbound optical transmission path 302 of RingA and the westbound optical transmission path 304 of RingB, as described above. Are connected and normality has been confirmed, so that the optical transmission paths 302 and 304 can be used as they are as the working optical path. Therefore, the optical cross-connect device 2a does nothing, and the optical add / drop device 1f can receive normally only by switching the selection target to the transponder 102c in the optical add / drop device 1f. Thus, even if a failure occurs in both Ring A and Ring B, an optical signal can be normally transmitted across both Rings.

  As described above, according to the first embodiment, since the optical cross-connect device is configured in the two-stage configuration of the 1: 3 coupler and the 3 × 1 wavelength selective switch, one optical ring network has failed. Even in this state, the other optical ring network can transmit an optical signal to both the working optical path and the standby optical path, and can continue to check the normality of the standby optical path. Therefore, there is no inconvenience that an abnormality in the optical path is detected only after switching to the standby optical path, so that the reliability of the redundant optical path in the multi-ring network can be improved.

Embodiment 2. FIG.
FIG. 5 is a diagram showing a configuration of an optical cross-connect device according to Embodiment 2 of the present invention. The optical cross-connect device 2b according to the second embodiment has a configuration of 1 × in place of the 1: 3 coupler 201 (a, b, c, d) on the input side in the configuration of the optical cross-connect device 2a shown in FIG. A two-wavelength selective switch (1 × 2 WSS) 203 (a, b, c, d) and a 1: 2 coupler 204 (a, b, c, d) are provided.

  The 1 × 2 wavelength selective switch 203a organizes the wavelength multiplexed optical signals input from the WestA optical transmission path of RingA into two sets combining one or more optical signals of arbitrary wavelengths, and outputs them to two sets. The data is transmitted from the port to the 3 × 1 wavelength selective switch 202a and the 1: 2 coupler 204a. The 1: 2 coupler 204a distributes the optical signal from the 1 × 2 wavelength selective switch 203a to the 3 × 1 wavelength selective switches 202c and 202d.

  The 1 × 2 wavelength selective switch 203b organizes the wavelength-multiplexed optical signals input from the EastA optical transmission line of RingA into two sets obtained by combining one or more optical signals of arbitrary wavelengths, and outputs them to two sets. The data is transmitted from the port to the 3 × 1 wavelength selective switch 202b and the 1: 2 coupler 204b. The 1: 2 coupler 204b distributes the optical signal from the 1 × 2 wavelength selective switch 203b to the 3 × 1 wavelength selective switches 202c and 202d.

  The 1 × 2 wavelength selective switch 203c organizes the wavelength-multiplexed optical signals input from the WestB optical transmission path of RingB into two sets obtained by combining one or more optical signals of arbitrary wavelengths, and outputs them to two sets. The data is transmitted from the port to the 3 × 1 wavelength selective switch 202c and the 1: 2 coupler 204c. The 1: 2 coupler 204c distributes the optical signal from the 1 × 2 wavelength selective switch 203c to the 3 × 1 wavelength selective switches 202a and 202b.

  The 1 × 2 wavelength selective switch 203d organizes the wavelength-multiplexed optical signals inputted from the EastB optical transmission line of RingB into two sets obtained by combining one or more optical signals of arbitrary wavelengths, and outputs them to two sets. The data is transmitted from the port to the 3 × 1 wavelength selective switch 202d and the 1: 2 coupler 204d. The 1: 2 coupler 204d distributes the optical signal from the 1 × 2 wavelength selective switch 203d to the 3 × 1 wavelength selective switches 202a and 202b.

  Even if the optical cross-connect device 2b configured in this way is applied in place of the optical cross-connect device 2b in the multi-ring network shown in FIG. 1, the redundant optical path at the time of failure described in the first embodiment Switching can be performed in the same manner, and the reliability of the redundant optical path can be improved.

  In the optical cross-connect device according to the second embodiment, since the input side is configured with a 1 × 2 wavelength selective switch (1 × 2WSS) and a 1: 2 coupler, the light according to the first embodiment configured with a 1: 3 coupler. Switching characteristics with lower loss than cross-connect devices can be realized.

Embodiment 3 FIG.
FIG. 6 is a system diagram showing a configuration of a multi-ring network including an optical cross-connect device according to Embodiment 3 of the present invention. In FIG. 6, a third optical ring network C (RingC) is added to two optical ring networks A (RingA) and B (RingB) having the same configuration as in FIG. A multi-ring network in which a ring network is connected by an optical cross-connect device (OXC) 2c according to the third embodiment is shown.

  On the optical ring network C (RingC), optical add / drop multiplexers 1g, 1h, 1i are arranged. The optical cross-connect device 2c includes ports W and E, which are connected to the westbound and eastbound optical transmission lines of RingA, RingB, and RingC in a one-to-one relationship.

  FIG. 7 is a diagram illustrating a configuration example of the optical cross-connect device illustrated in FIG. As shown in FIG. 7, the optical switch unit included in the optical cross-connect device 2c according to the third embodiment includes a westward (West) optical transmission line and an eastward optical transmission line of RingA, and a westward rotation of RingB. As a configuration for switching the connection between the (West) optical transmission line and the eastward optical transmission line and the WestC optical transmission line and the eastward optical transmission line of RingC, RingA, In Ring B and Ring C, the input / output relationship between the westbound optical transmission path and the eastbound optical transmission path is opposite to each other. However, each optical transmission path has a one-to-one relationship. , Six 1 × 3 wavelength selective switches (1 × 3WSS) 205 (a, b, c, d, e, f) and twelve 1: 2 couplers 206 (a, b, c, d, e) on the input side. , F, g, h, l )) And six 5 × 1 wavelength selective switches (5 × 1 WSS) 207 (a, b, c, d, e, f) are provided on the output side.

  The 1 × 3 wavelength selective switch 205a organizes the wavelength multiplexed optical signals input from the WestA optical transmission line of RingA into three sets combining one or more optical signals of arbitrary wavelengths and outputs them to three sets. The data is transmitted from the port to the 5 × 1 wavelength selective switch 207a, the 1: 2 coupler 206a, and the 1: 2 coupler 206b. The 1: 2 coupler 206a distributes the wavelength multiplexed optical signal from the 1 × 3 wavelength selective switch 205a to the 5 × 1 wavelength selective switches 207c and 207d. The 1: 2 coupler 206b distributes the wavelength multiplexed optical signal from the 1 × 3 wavelength selective switch 205a to the 5 × 1 wavelength selective switches 207e and 207f.

  The 1 × 3 wavelength selective switch 205b organizes the wavelength multiplexed optical signals input from the EastA optical transmission line of RingA into three sets combining one or more optical signals of arbitrary wavelengths, and outputs them to three sets. The data is transmitted from the port to the 5 × 1 wavelength selective switch 207b, the 1: 2 coupler 206c, and the 1: 2 coupler 206d. The 1: 2 coupler 206c distributes the optical signal from the 1 × 3 wavelength selective switch 205b to the 5 × 1 wavelength selective switches 207c and 207d. The 1: 2 coupler 206d distributes the optical signal from the 1 × 3 wavelength selective switch 205b to the 5 × 1 wavelength selective switches 207e and 207f.

  The 1 × 3 wavelength selective switch 205c organizes the wavelength multiplexed optical signals input from the WestB optical transmission line of RingB into three sets of one or more optical signals of arbitrary wavelengths and outputs them to three sets. The data is transmitted from the port to the 5 × 1 wavelength selective switch 207c, the 1: 2 coupler 206e, and the 1: 2 coupler 206f. The 1: 2 coupler 206e distributes the optical signal from the 1 × 3 wavelength selective switch 205c to the 5 × 1 wavelength selective switches 207a and 207b. The 1: 2 coupler 206f distributes the optical signal from the 1 × 3 wavelength selective switch 205c to the 5 × 1 wavelength selective switches 207e and 207f.

  The 1 × 3 wavelength selective switch 205d organizes the wavelength multiplexed optical signals input from the EastB optical transmission line of RingB into three sets combining one or more optical signals of arbitrary wavelengths and outputs them to three sets. The data is transmitted from the port to the 5 × 1 wavelength selective switch 207d, the 1: 2 coupler 206g, and the 1: 2 coupler 206h. The 1: 2 coupler 206g distributes the optical signal from the 1 × 3 wavelength selective switch 205d to the 5 × 1 wavelength selective switches 207a and 207b. The 1: 2 coupler 206h distributes the optical signal from the 1 × 3 wavelength selective switch 205d to the 5 × 1 wavelength selective switches 207e and 207f.

  The 1 × 3 wavelength selective switch 205e organizes the wavelength multiplexed optical signals input from the WestC optical transmission line of RingC into three sets combining one or more optical signals of arbitrary wavelengths, and outputs them to three output ports. To 5 × 1 wavelength selective switch 207e, 1: 2 coupler 206i, and 1: 2 coupler 206j. The 1: 2 coupler 206i distributes the optical signal from the 1 × 3 wavelength selective switch 205e to the 5 × 1 wavelength selective switches 207a and 207b. The 1: 2 coupler 206j distributes the optical signal from the 1 × 3 wavelength selective switch 205e to the 5 × 1 wavelength selective switches 207c and 207d.

  The 1 × 3 wavelength selective switch 205f organizes the wavelength multiplexed optical signals inputted from the EastC optical transmission path of RingC into three sets combining one or more optical signals of arbitrary wavelengths, and outputs them to three sets. The data is transmitted from the port to either the 5 × 1 wavelength selective switch 207f, the 1: 2 coupler 206k, or the 1: 2 coupler 206l. The 1: 2 coupler 206k distributes the optical signal from the 1 × 3 wavelength selective switch 205f to the 5 × 1 wavelength selective switches 207a and 207b. The 1: 2 coupler 206l distributes the optical signal from the 1 × 3 wavelength selective switch 205f to the 5 × 1 wavelength selective switches 207c and 207d.

  The 5 × 1 wavelength selective switch 207a selects one of the optical signals taken from the five input ports and sends it out to the EastA optical transmission line of RingA. The 5 × 1 wavelength selective switch 207b selects one of the optical signals taken from the five input ports and sends it to the west-bound (West) optical transmission line of RingA.

  The 5 × 1 wavelength selective switch 207c selects one of the wavelength multiplexed optical signals received from the five input ports and sends it to the EastB optical transmission line of RingB. The 5 × 1 wavelength selective switch 207d selects one of the wavelength multiplexed optical signals received from the five input ports and sends it to the WestA optical transmission path of RingA.

  The 5 × 1 wavelength selective switch 207e selects one of the wavelength multiplexed optical signals received from the five input ports, and sends it to the EastC optical transmission line of RingC. The 5 × 1 wavelength selective switch 207f selects one of the wavelength multiplexed optical signals received from the five input ports and transmits the selected signal to the WestC optical transmission path of RingC.

  In the multi-ring network shown in FIG. 6 in which three optical ring networks are connected using the optical cross-connect device 2c configured as described above, the redundant optical path switching in the event of a failure described in the first embodiment is similarly performed. The reliability of the redundant optical path can be improved.

In the third embodiment, as can be understood from the configuration compared with the optical cross-connect apparatus 2b shown in the second embodiment, 3 or more optical ring network optical cross-connect device 2b shown in the second embodiment Although the method of extending to the configuration of connecting the optical cross-connect devices shown in the first embodiment is suggested, this suggests a method of extending the optical cross-connect device shown in the first embodiment to a configuration of connecting three or more optical ring networks.

  That is, in the configuration shown in FIG. 2, a 1: 5 coupler is provided on the input side instead of a 1: 3 coupler, and a 5 × 1 WSS is provided on the output side instead of 3 × 1 WSS to connect three optical ring networks. In the multi-ring network, the redundant optical path switching at the time of failure described in the first embodiment can be performed in the same manner, and the reliability of the redundant optical path can be improved.

Embodiment 4 FIG.
FIG. 8 is a system diagram showing a configuration of an optical mesh network including an optical cross-connect device according to Embodiment 4 of the present invention. And has it 8, in the first optical mesh network 81, the optical cross-connect device 2d1,2d2,2d3 of four routes at intersections of a plurality of optical transmission paths is disposed in the second optical mesh network 82, Four-way optical cross-connect devices 2d5, 2d6, and 2d7 are arranged at the intersections of the plurality of optical transmission lines, and both optical mesh networks 81 and 82 are connected via the six-way optical cross-connect device 2e. . The four-way optical cross-connect device 2d4 is arranged at the intersection of the optical transmission paths in a third optical mesh network (not shown).

  In the first optical mesh network 81, the port P2 of the optical cross-connect device 2d1 is connected to the port P1 of the optical cross-connect device 2d2 via the optical transmission line 401, and the port P3 of the optical cross-connect device 2d2 is connected to the optical transmission line. It is connected to the port P2 of the optical cross-connect device 2e via the path 402. The port P4 of the optical cross-connect device 2d1 is connected to the port P1 of the optical cross-connect device 2d3 via the optical transmission line 403, and the port P3 of the optical cross-connect device 2d3 is connected to the optical cross-link via the optical transmission line 404. It is connected to port P5 of the connecting device 2e. The port P3 of the optical cross-connect device 2d1 is connected to the port P1 of the optical cross-connect device 2e via the optical transmission path 405, and the port P4 of the optical cross-connect device 2d2 is optically crossed via the optical transmission path 406. It is connected to the port P2 of the connection device 2d3. The port P4 of the optical cross-connect device 2d3 is connected to the port P1 of the optical cross-connect device 2d4 via the optical transmission path 407.

  The port P1 of the optical cross-connect device 2d1 is connected to an optical transmission line in an adjacent optical mesh network (not shown). Similarly, the port P2 of the optical cross-connect device 2d2 is connected to an optical transmission line in an adjacent optical mesh network (not shown). The optical transmission path 405 between the port P3 of the optical cross-connect device 2d1 and the port P1 of the optical cross-connect device 2e, and between the port P4 of the optical cross-connect device 2d2 and the port P2 of the optical cross-connect device 2d3 Similarly, four-way optical cross-connect devices are also arranged at intersections with the optical transmission path 406, but the illustration is omitted for convenience of explanation.

  In the second optical mesh network 82, the port P2 of the optical cross-connect device 2d7 is connected to the port P3 of the optical cross-connect device 2d5 via the optical transmission line 411, and the port P1 of the optical cross-connect device 2d5 is The optical cross-connect device 2e is connected to the port P3 via the optical transmission line 412. The port P4 of the optical cross-connect device 2d7 is connected to the port P3 of the optical cross-connect device 2d6 via the optical transmission line 413, and the port P1 of the optical cross-connect device 2d6 is connected to the optical cross-connect device via the optical transmission line 414. 2e port P6. The port P1 of the optical cross-connect device 2d7 is connected to the port P4 of the optical cross-connect device 2e via the optical transmission line 415, and the port P4 of the optical cross-connect device 2d5 is connected to the optical cross-link via the optical transmission line 416. It is connected to the port P2 of the connecting device 2d6. The port P4 of the optical cross-connect device 2d6 is connected to the port P3 of the optical cross-connect device 2d4 via the optical transmission line 417.

  The port P3 of the optical cross-connect device 2d7 is connected to an optical transmission line in an adjacent optical mesh network (not shown). Similarly, the port P2 of the optical cross-connect device 2d5 is also connected to an optical transmission line in an adjacent optical mesh network (not shown). The optical transmission path between the port P1 of the optical cross-connect device 2d7 and the port P4 of the optical cross-connect device 2e, and the light between the port P4 of the optical cross-connect device 2d5 and the port P2 of the optical cross-connect device 2d6 Similarly, four-way optical cross-connect devices are also arranged at the intersections with the transmission lines, but the illustration is omitted for convenience of explanation.

  The ports P2 and P4 of the optical cross-connect device 2d4 are connected to optical transmission lines in a third optical mesh network (not shown).

  Each of the four-way optical cross-connect devices 2d (1 to 7) has the same configuration as shown in FIGS. 2 and 5, and the input / output relationship is as shown in FIG. 9, for example. FIG. 9 is a diagram illustrating a configuration example of the four-way optical cross-connect device illustrated in FIG. In FIG. 9, in the configuration shown in FIG. 5, the RingA West port is port 1 (Port1), the RingA East port is Port 2 (Port2), the RingB West port is Port 3 (Port3), and the RingB It is shown that the application can be applied if the east port is port 4 (Port 4).

  Further, the six-way optical cross-connect device 2e has a configuration shown in FIG. 7 or a configuration in which the configuration shown in FIG. 2 is expanded to six routes, and the input / output relationship is, for example, as shown in FIG. As shown. FIG. 10 is a diagram illustrating a configuration example of the six-way optical cross-connect device illustrated in FIG. In FIG. 10, in the configuration shown in FIG. 7, the RingA West port is port 1 (Port 1), the Ring A East port is Port 2 (Port 2), the Ring B West port is Port 3 (Port 3), and the Ring B It is shown that the application can be applied by setting the East port to port 4 (Port 4), the RingC West port to Port 5 (Port 5), and the RingC East port to Port 6 (Port 6).

  Next, an operation for forming a redundant optical path in the optical mesh network shown in FIG. 8 will be described with reference to FIGS. FIG. 11 is a system diagram illustrating the working and standby optical paths formed across the networks in the normal state in the optical mesh network shown in FIG. FIG. 12 is a diagram illustrating a recovery operation when a failure occurs in a redundant optical path formed across the networks illustrated in FIG.

  In FIG. 11, in FIG. 8, the third optical terminal whose transmitting end side exists in the adjacent optical mesh network connected to the port P <b> 1 of the optical cross-connect device 2 d <b> 1 and whose receiving end side is connected to the port P <b> 4 of the optical cross-connect device 2 d <b> 4. It is shown that when present in the mesh network, the working optical path (solid line) and the standby optical path (broken line) in the normal state are formed across the two optical mesh networks 81 and 82. .

  The optical cross-connect device 2d1 sends a wavelength multiplexed optical signal input from the transmission end to the port P1 to the optical transmission line 401 from the port 2 and sends it from the port 3 to the optical transmission line 405. The optical cross-connect device 2d2 sends the wavelength multiplexed optical signal input to the port P1 from the port 3 to the optical transmission line 402.

  The optical cross-connect device 2e sends a wavelength multiplexed optical signal input to the port P2 from the port 4 to the optical transmission line 414, and sends a wavelength multiplexed optical signal input to the port P1 from the port 6 to the optical transmission line 404. To do.

  The optical cross-connect device 2d7 sends the wavelength multiplexed optical signal input to the port P1 from the port 4 to the optical transmission line 413. The optical cross-connect device 2d6 sends the wavelength multiplexed optical signal input to the port 3 from the port 4 to the optical transmission line 417. The optical cross-connect device 2d4 sends the wavelength multiplexed optical signal input to the port P3 from the port 4 to the optical transmission line to which the receiving end is connected.

  The optical cross-connect device 2d3 sends the wavelength multiplexed optical signal input to the port P3 from the port 4 to the optical transmission line 407. The optical cross-connect device 2d6 sends the wavelength multiplexed optical signal input to the port 3 from the port 4 to the optical transmission line 417. The optical cross-connect device 2d4 sends the wavelength multiplexed optical signal input to the port P1 from the port 4 to the optical transmission line to which the receiving end is connected.

  As a result, a working optical path passing through the optical transmission paths 401, 402, 415, 413, and 417 and a standby optical path passing through the optical transmission paths 405, 404, and 407 are formed. In this state, as shown in FIG. 12, when a failure occurs in the optical transmission line 401, the optical cross-connect device 2e connecting the two mesh networks 81 and 82 disconnects the port P2 and the port P4 and simultaneously Port P1 is also connected to port P4. As a result, the working optical path is reconfigured to pass through the optical transmission lines 405, 415, 413, and 417. Since the standby optical path is not changed, transmission of the optical signal can be confirmed.

  As described above, if the optical cross-connect device described in the first to third embodiments is arranged at each intersection of a plurality of optical transmission lines in an optical network in which a plurality of optical mesh networks are connected, the reliability of the redundant optical path is similarly obtained. Can be improved. In short, the optical cross-connect device according to the present invention is generally applicable as a device for connecting a plurality of optical networks having redundant optical paths.

Embodiment 5 FIG.
FIG. 13 is a system diagram illustrating another configuration example of the optical add / drop multiplexer in the multi-ring network shown in FIG. 1 as Embodiment 5 of the present invention. In FIG. 13, the optical add / drop multiplexers 3a, 3b, 3c are arranged in RingA in place of the optical add / drop multiplexers 1a, 1b, 1c, and the ring B is optical in place of the optical add / drop multiplexers 1d, 1e, 1f. Branch / insertion devices 3d, 3e, 3f are arranged. Each optical add / drop device has the same configuration, the transmission system is configured as shown in the optical add / drop device 3a, and the reception system is configured as shown in the optical add / drop device 3f.

  The optical add / drop device 3a includes a single transponder in the optical add / drop device 1a (the transponder 102a is left in the illustrated example), and the adder 105 instead of the adder 101 is connected to the output end of the transponder 102a, the OADM 103a, It is configured to be provided between the input terminal 103b.

  In addition, the optical add / drop device 3f uses a single transponder (in the illustrated example, leaving the transponder 102c) in the optical add / drop device 1f, and replaces the selector 106 in place of the selector 104 with the output terminals of the OADMs 103c and 103d. And the input terminal of the transponder 102c.

  Even if the optical add / drop multiplexer is configured as described above, the optical cross-connect device 2a has a ring A westward optical transmission line between the optical add / drop multiplexer 3a serving as the transmitting end and the optical add / drop multiplexer 3f serving as the receiving end. The active optical path (solid line) that straddles both the ring 301 and the eastbound optical transmission path 303 of RingB, and the both rings that comprise the eastbound optical transmission path 302 of RingA and the westbound optical transmission path 304 of RingB. The standby optical path (broken line) can be formed, and the operation for improving the reliability of the redundant optical path described in the first embodiment can be performed even when a failure occurs.

  As described above, the optical cross-connect device according to the present invention is useful for connecting a plurality of optical networks having redundant optical paths without degrading the reliability of the redundant optical paths.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a system diagram illustrating a configuration example of a multi-ring network including an optical cross-connect device according to Embodiment 1 of the present invention, and active and standby optical paths formed across rings during normal operation. It is a figure which shows the structural example of the optical cross-connect apparatus shown in FIG. It is a figure explaining the recovery operation when a failure occurs in RingA in the multi-ring network shown in FIG. It is a figure explaining the recovery operation | movement when a failure generate | occur | produces also in RingB in addition to RingA in the multi-ring network shown in FIG. It is a figure which shows the structure of the optical cross-connect apparatus by Embodiment 2 of this invention. It is a system diagram which shows the structure of a multi-ring network provided with the optical cross-connect apparatus by Embodiment 3 of this invention. It is a figure which shows the structural example of the optical switch with which the optical cross-connect apparatus shown in FIG. 6 is provided. It is a system diagram which shows the structure of the optical mesh network provided with the optical cross-connect apparatus by Embodiment 4 of this invention. It is a figure which shows the structural example of the four-way optical cross-connect apparatus shown in FIG. It is a figure which shows the structural example of the 6-way optical cross-connect apparatus shown in FIG. FIG. 9 is a system diagram for explaining active and standby optical paths formed across networks in a normal state in the optical mesh network shown in FIG. 8. FIG. 12 is a diagram illustrating a recovery operation when a failure occurs in a redundant optical path formed across the networks illustrated in FIG. 11. FIG. 10 is a system diagram illustrating another configuration example of the optical add / drop multiplexer in the multi-ring network shown in FIG. 1 as Embodiment 5 of the present invention. It is a system diagram explaining a configuration example of a multi-ring network including a conventional optical cross-connect device and working and standby optical paths formed across the rings in a normal state. It is a figure which shows the structural example of the conventional optical cross-connect apparatus shown in FIG. FIG. 15 is a diagram illustrating a recovery operation when a failure occurs in RingA in the multi-ring network illustrated in FIG. 14. FIG. 15 is a diagram illustrating a recovery operation when a failure occurs in RingB in addition to RingA in the multi-ring network shown in FIG. 14.

Explanation of symbols

Ring A, B Optical ring network 1a, 1b, 1c, 1d, 1e, 1f Optical add / drop device 2a, 2b, 2c, 2d1-2d7, 2e Optical cross connect device 3a, 3b, 3c, 3d, 3e, 3f Optical add / drop Equipment 101, 105 Branching device (DIS)
102a, 102b, 102c, 102d Transponders 103a, 103b, 103c, 103d OADM
104,106 selector (SEL)
201a, 201b, 201c, 201d 1: 3 coupler 202a, 202b, 202c, 202d 3 × 1 wavelength selective switch (3 × 1 WSS)
203a, 203b, 203c, 203d 1 × 2 wavelength selective switch (1 × 2 WSS)
204a, 204b, 204c, 204d 1: 2 coupler 205a, 205b, 205c, 205d 1 × 3 wavelength selective switch (1 × 3 WSS)
206a, 206b, 206c, 206d, 206e, 206f, 206g, 206h, 206i, 206j, 206k, 206l 1: 2 coupler 207a, 207b, 207c, 207d 5 × 1 wavelength selective switch (5 × 1WSS)
81,82 Optical mesh network

Claims (3)

Two systems that connect a plurality of optical networks having at least two optical transmission lines and span a plurality of optical networks including a plurality of the optical networks to be connected and interposed between a transmitting end side and a receiving end side In the optical cross-connect device that connects the optical paths of
When m is a natural number of 2 or more,
Wavelength multiplexed optical signals input from one optical transmission line are organized into m sets obtained by combining one or more optical signals of arbitrary wavelengths, and two or more 1 × m signals transmitted from corresponding output ports of m output ports. A wavelength selective switch;
Two or more two-branch couplers provided for each of the m−1 output ports of each of the two or more 1 × m wavelength selective switches and distributing the wavelength multiplexed optical signal output from the corresponding output port into two. ,
The same number as the two or more 1 × m wavelength selective switches, and the wavelength multiplexed optical signal from the remaining one output port of the corresponding 1 × m wavelength selective switch and two or more wavelengths from the two or more two-branch couplers A wavelength-division-multiplexed optical signal of an arbitrary wavelength is selected from the multiplexed optical signals and sent to the corresponding optical transmission line (2m-1) × 1 wavelength selective switch,
When a failure occurs in the one optical path, wavelength multiplexed light is transmitted from the optical transmission path of the other optical path to the (2m-1) × 1 wavelength selective switch corresponding to the optical transmission path of the other optical path. The (2m−1) × 1 wavelength selective switch corresponding to the optical transmission line in which a failure has occurred in a state where the output of the 1 × m wavelength selective switch that receives a signal or the output of the two-branch coupler is continuously selected. The optical cross-connect device is switched to the output of the 1 × m wavelength selective switch that receives a wavelength-multiplexed optical signal from the optical transmission line of the other optical path or the output of the two- branch coupler. When two optical networks having two optical transmission lines are connected, the two or more 1 × m wavelength selective switches are four 1 × 2 wavelength selective switches, and the two or more optical networks are connected. the two branch coupler is a four two-branch coupler, the two or more (2m-1) × 1 wavelength selective switch according to claim 1, characterized in that the four 3 × 1 wavelength selective switch The optical cross-connect device described in 1. When two or more optical networks having two optical transmission paths are connected or two optical networks having three optical transmission paths, the two or more 1 × m wavelengths are connected. The selection switches are six 1 × 3 wavelength selection switches, the two or more two-branch couplers are twelve two-branch couplers, and the two or more (2m−1) × 1 wavelength selection switches are The optical cross-connect device according to claim 1, wherein there are six 5 × 1 wavelength selective switches.

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