JP2815040B2 - Optical switch network - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical switch network used in an optical communication network.

[0002]

2. Description of the Related Art The use of optical communication makes it possible to increase the capacity of a single optical transmission line due to the wide bandwidth of light. However, at a node that passes without being terminated,
Performing photoelectric conversion on all optical signals has disadvantages such as an increase in size of the device and an increase in cost. Therefore, an optical network that switches an optical signal as light has attracted attention. As its function, it is required to use an optical switch to collectively switch a large-capacity optical signal as it is to recover a failure or reconfigure a network. When performing them, the operator must be able to
It is necessary to constantly monitor the optical switch and transmit operation / management / maintenance information to each node.

Conventionally, a configuration shown in FIG. 2 has been generally known as a configuration for monitoring a network and obtaining operation, management, and maintenance information in an optical switch circuit network. In FIG. 2, 201 is a 2 × 2 optical switch, 202 is an optical switch network, 203 and 206 are optical transmission lines connected to other nodes, and optical signals are transmitted from the optical transmission line 203. After being switched by the optical switch 201, the optical transmission path 2
At 06, it is transmitted to another node. 204 is a control circuit, 20
Reference numeral 7 denotes an optical splitter; 205, an optical receiver for obtaining information on operation, management, maintenance, and the like; an optical signal transmitted from another node is partially split by an optical splitter 207; At 205, optical signal monitoring and operation, management, and maintenance information can be obtained.

[0004] By using the above method, network operation / management / maintenance information can be obtained in a node that passes through light.

[0005] When an optical switch that is not optimally driven due to a change with time is used as the 2 × 2 optical switch, the power of the optical signal is observed in order to observe the deterioration state from the optimal driving point. It is necessary to monitor the conditions, etc., and correct to the optimum driving point by control.

It is known that such a request can be realized by using the configuration shown in FIG. Operation /
As in the case of obtaining the management / maintenance information, the optical receiver 205 receives a part of the optical signal, monitors the optical power, sends the information to the control circuit 204, and corrects the optical switch to the optimal driving state. It is possible to

[0007]

By using the conventional technique described above, it is possible to detect information such as operation, management and maintenance in an optical switch network which can be switched as it is while maintaining the light.・ Maintenance can be performed.
Even if a 2 × 2 optical switch whose optimal driving state changes with time is used, the driving state can be optimized by detecting light.

However, according to the conventional configuration, the number of optical splitters must be at least equal to the number of output terminals of the optical switch network, and the mounting volume of the optical splitter increases.
There is a drawback that the mounting volume further increases due to the accompanying increase in optical transmission paths.

SUMMARY OF THE INVENTION The present invention solves the above-mentioned problems, and is capable of acquiring operation / management / maintenance information, monitoring an optical signal and an optical switch, and reducing the mounting volume. Is to provide.

[0010]

According to the first aspect of the present invention, there are provided a plurality of input terminals having m input terminals, n output terminals, an arbitrary number of input terminals, and an arbitrary number of output terminals. A group of a plurality of optical switches, having two input terminals and two output terminals, and arbitrarily changing a distribution ratio of optical output power of the input optical signal to the two output terminals. A second group of n optical switches, n optical receivers, and a controller, each of said m input terminals and m input terminals of some of said first group of optical switches Are connected to each other, a plurality of input terminals and output terminals of some of the first group of optical switches are connected in parallel or in tandem, and 2n output terminals of some of the first group of optical switches are connected to each other. The second group of n optical switches are respectively connected to 2n input terminals of the second group of n optical switches. Two one output terminal of n of the output end of the people and said n output terminals are respectively connected, the second
Among the output terminals of the n optical switches in the group, n output terminals of the second group of optical switches that are not connected to the n output terminals are connected to the n optical receivers, respectively. And said n
Optical receivers and the control device are connected to each other, and it is possible to set so that optical signals are not simultaneously input to different input terminals of the same group of optical switches in the second group. Is obtained.

According to the second aspect of the present invention, in the optical switch network including a plurality of optical switches each having a plurality of input terminals and output terminals and arranged in a matrix, the plurality of optical switches are Each of the last-stage optical switches is connected to each other so that an optical signal is input to only one input terminal, and each of the last-stage optical switches transmits the optical signal input from the one input terminal to its own plurality. Can be distributed at any ratio to the output end of
An optical switch network is obtained, wherein an optical receiver is connected to one of the plurality of output terminals of each of the last-stage optical switches.

According to the third aspect of the present invention, each of the optical switches in the last stage is a 2 × optical switch made of LiNbO _3.
3. The optical switch network according to claim 2, wherein the optical switch network is a two-optical switch.

[0013]

As a second group of optical switches of the optical switch network of the present invention, for example, by changing the drive voltage,
A 2 × 2 optical switch that can arbitrarily set the selection ratio of one input light is used. The input terminal of the 2 × 2 optical switch is A,
B, output terminals C and D. When an optical signal is input to the A input terminal of the 2 × 2 optical switch, 95% optical power and D output terminal are provided at the C output terminal so that information such as operation, management, and maintenance can be obtained at the D output terminal. The switching state can be set such that the optical power of 5% goes to the second position. At this time, if an optical signal is also input to the B input terminal, the optical signal input to the B input terminal is, for example, 5% to the C output terminal and 95% to the D output terminal.
5% from the A input that is output and intended to get at the D output
95% of the optical signal from the B input terminal is cross-talked to the optical signal. Therefore, the D output terminal cannot receive the branched light from the A input terminal. However, in the present invention, since an optical receiver is connected to an optical switch having a configuration in which an optical signal is not simultaneously input to both input terminals, an unselected input optical signal (from the B input terminal). The optical receiver connected to the D output terminal can receive the split light from the A input terminal without receiving crosstalk due to the optical signal). Therefore, 2 × 2
The optical receiver connected to the unused output terminal of the optical switch can always obtain operation / management / maintenance information and monitor the optical switch and the optical signal. The 2 × 2 optical switch originally required to have the switching function is used as an optical branch, and since it is not separately constructed by inserting an optical branch, it is required for an optical branch and an optical branch. The mounting volume can be reduced by the amount of the optical fiber and the optical connector.

[0014]

The present invention will be described below in detail with reference to examples.

FIG. 1 shows a first embodiment of the optical switch network according to the present invention.

In FIG. 1, 100 is a first group of optical switches, 101 is a second group of optical switches, 102 is an optical switch network, and 103 is another node and an input terminal of the optical switch network 102. The connected optical transmission line, 106 is an optical transmission line connected to another node at the output end of the optical switch network 102, and 104 is a control device. Reference numeral 105 denotes an optical receiver for obtaining information on operation, management, maintenance, and the like, and for monitoring optical signals and optical switches. Reference numeral 108 denotes an input terminal of the optical switch network 102, and reference numeral 109 denotes an output terminal of the optical switch network 102. Here, both the first group of optical switches 100 and the second group of optical switches 101 are LiNbO _3.
And a 2.times.2 optical switch having two input terminals and two output terminals.

The optical switch network 102 of the present embodiment includes the above-described first group of optical switches 100, a second group of 2 × 2 optical switches 101, a control device 104, and an optical receiver 105. ing. Input terminal 1 of this optical switch network 102
08 is connected to the optical transmission line 103 and the optical switch network 1
The optical transmission line 106 is connected to the output terminal 109 of the second communication device 02. One of the output terminals of the 2 × 2 optical switch 101 of the second group is connected to the output terminal 109 of the optical switch network 102, and the remaining output terminal of the 2 × 2 optical switch 101 of the second group is connected to an optical terminal. Receiver 105 is connected.

Next, a method for obtaining network operation / management / maintenance information in the optical switch network according to the present embodiment will be described.

It is assumed that an optical signal to be transmitted is a digital signal. At the transmitting node, the optical signal to be transmitted is
In order to transfer network operation / maintenance / control information, it is assumed that micro-modulation is performed in advance on subcarriers on which such information is carried. As the 2 × 2 optical switch of the second group, a LiNbO ₃ optical switch capable of arbitrarily setting the selection ratio of the two input lights by changing the drive voltage is used, so that the 2 × 2 optical switch 101 of the second group is used. Can be set so that, for example, 5% of the light goes to the optical receiver 105 and the remaining light goes to the output terminal 109. Therefore, the receiver 105 can obtain network operation / management / maintenance information by receiving the subcarriers. These pieces of information are transferred to the control device 104 and used for operation, management, and maintenance of the network.

Incidentally, the optical switch network 102 of the present embodiment
Is a non-blocking positive matrix optical switch network, so the input 108 of the optical switch network 102 is
Be sure to use one of the output terminals 109 of the optical switch network 102.
Can be output in correspondence with. In this case, the 2 × 2 optical switch 1 of the second group in the final stage
01 are used as the output terminals of the optical switch network, only one output terminal is used.
An optical signal comes to only one of the two input terminals of the 2 × 2 optical switch 101 in the group (the optical signal is not input to both input terminals). For example, when the input terminal 108-A of the optical switch network 102 is connected to the output terminal 109-1 of the optical switch network 102, the input terminal 108-A is connected to the input terminal of the optical switch 101 connected to the optical output terminal 109-1. Optical signal from input terminal 108-A and input terminal 108
That the optical signal from the input terminal 108-B is simultaneously input means that the optical signal from the input terminal 108-B is lost at the optical switch 101 connected to the optical output terminal 109-1. It can be seen from the fact that it is not output to the output terminal 109 of the network 102. Therefore, by making the input end 108 of the optical switch network 102 always output corresponding to any one of the output ends 109 of the optical switch network 102, the optical receiver 105 can reduce the crosstalk due to the optical signal from a different path. It is possible to always receive operation / management / maintenance information without being affected.

Next, a description will be given of a method for setting the optical switch in the optical switch network of the present embodiment to an optimum driving state.

It is assumed that the used optical switch is an optical switch whose optimum driving voltage changes due to aging, temperature change and the like. By detecting the optical power with the optical receiver 105, the power of the optical signal currently passing through the optical switch can be determined. Therefore, by sending the information to the control device 104, the optical switch (the optical receiver 105 is connected) in the path through which the optical signal passes in response to a change in state of the optical switch due to aging, temperature change, or the like. The operating voltage can be adjusted to an optimum operating voltage by slightly changing the driving voltage of each of the optical switches (except for the optical switch provided) one by one and performing control such that the power of the obtained optical signal is maximized. Output terminal 10
When the optical transmission line 106 connected to the optical transmission line 9 is connected to the next node, the optical transmission line of the next node connected through the optical transmission line 106 passes through the last-stage optical switch. If the method of detecting the optical power and sending the value back to the node being adjusted by means of transferring the operation, management and maintenance information of the network, the drive voltage of the last stage optical switch can be adjusted. It is. When the optical transmission line connected to the output terminal of the optical switch network is connected to the terminal device of the own node, the received optical power is referred to at the terminal point of the own node, so that the last Adjustment of the switch drive voltage is also possible.

The second group of 2 × 2 optical switches 101 in the final stage
Is 2 × 2 which is originally required to have the switching function.
Since it is an optical switch and is not configured by inserting a separate optical branch unlike the conventional one, the mounting volume is reduced by the amount of the optical branch, the optical fiber and the optical connector required for the optical branch. be able to. In addition, the connection of optical components is usually performed using an optical connector, and the number of optical splitters to be mounted is reduced, so that the loss of light due to the use of the optical connector can be reduced by the amount of the omitted optical connector. .

Although the present invention has been described in detail with reference to the embodiments, the present invention is not limited to the embodiments.

For example, in the embodiment, a method of superimposing subcarriers is used as a means for transmitting information such as operation, management, and maintenance. However, an optical signal transmitted at a transmitting node is time-divided.
A time-division area for carrying operation / management / maintenance information is created, time-division multiplexed, and time-division-multiplexed and separated by the optical receiver 105.
The present invention can be applied even if a method for obtaining operation / management / maintenance information is used.

Although a digital signal is used as an optical signal to be transmitted in the embodiment, the present invention can be applied to an analog signal as long as operation / management / maintenance information can be separated from a transmitted optical signal.

Although the branch ratio of the last-stage optical switch 5 is set to 5:95, the present invention can be applied to any ratio within a range allowed by the loss margin of the system.

The output terminal of the 2 × 2 optical switch 101 of the second group of the optical switch network is used for monitoring, operation, management,
Although an optical receiver for obtaining maintenance information is connected, the optical receiver is not limited to the last stage, but has a plurality of output terminals, and arbitrarily changes a distribution ratio of an input optical signal to the plurality of output terminals. Optical switch that can be set so that an optical signal can not be input to different input terminals of the optical switch at the same time. Even if an optical receiver is connected, 2 ×
The present invention can be applied even if an optical switch other than 2 is used.

Also, instead of 101, two input terminals,
By using another optical switch that can set the selection ratio at the output end to an arbitrary ratio, the present invention can be executed without any trouble.

Further, as the first group of optical switches, LiNbO
A 2 × 2 optical switch made using ₃
The present invention can be implemented without any trouble by using other materials and principles having arbitrary input fractions and arbitrary output fractions (such as mechanical optical switches using Pursum) as the group of optical switches.

Further, even if an optical component other than the 2 × 2 optical switch, such as an optical splitter or a laser diode, which is not related to the switch network, is incorporated in the optical switch network,
The present invention can be applied without hindrance.

Further, the present invention can be applied to an optical switch network constituted by combining the optical switch networks of the present invention without any trouble.

[0033]

According to the present invention, there is no need to connect an optical receiver for control or the like via an optical splitter in the optical switch network. Accordingly, the number of optical splitters and the optical fibers and optical connectors associated with the optical splitters in the optical switch network can be reduced, the mounting volume is reduced, and the cost is reduced. In addition, since the number of optical connectors used in the configuration according to the present invention is smaller than that in the related art, the optical loss of the main signal can be reduced by applying the present invention.

[Brief description of the drawings]

FIG. 1 is a diagram showing one embodiment of the present invention.

FIG. 2 is a diagram for explaining a conventional technique.

[Explanation of symbols]

 REFERENCE SIGNS LIST 100 First group optical switch 101 Second group 2 × 2 optical switch 102 m × n optical switch network 103 Optical transmission line 104 Controller 105 Optical receiver 106 Optical transmission line 108 Input end of optical switch network 109 Light Output end of switch network

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int.Cl. ⁶ , DB name) H04Q 3/52-3/52 101

Claims (3)

(57) [Claims] 1. A first group of a plurality of optical switches having m input terminals, n output terminals, an arbitrary number of input terminals and an arbitrary number of output terminals, and two input terminals. And a second output terminal having two output terminals and capable of arbitrarily changing the distribution ratio of optical output power of the input optical signal to the two output terminals.
A group of n optical switches, n optical receivers, and a controller, wherein each of the m input terminals and m input terminals of some of the first group of optical switches are Connected
The input terminals and the output terminals of some of the first group of optical switches are connected in parallel or in tandem, and the 2n output terminals of some of the first group of optical switches and the n of the second group are connected. 2n input terminals of the two optical switches are connected to each other, and one of n output terminals of the two output terminals of each of the n optical switches of the second group and the n output terminals are connected to each other. Are connected to each other,
Of the output terminals of the second group of n optical switches, the n output terminals of the second group of optical switches that are not connected to the n output terminals and the n optical receivers; Are respectively connected, the n optical receivers and the control device are connected,
An optical switch network, characterized in that it is possible to set so that an optical signal is not simultaneously inputted to different input terminals of the same second group of optical switches. 2. An optical switch network including a plurality of optical switches each having a plurality of input terminals and output terminals and arranged in a matrix, wherein the plurality of optical switches are connected to each other in a last stage optical switch. The optical switches are connected to each other so that an optical signal is input to only one input terminal, and each of the optical switches in the final stage is capable of transmitting an optical signal input from the one input terminal to a plurality of output terminals of the optical switch. An optical switch network capable of being distributed at a ratio, wherein an optical receiver is connected to one of a plurality of output terminals of each of the last-stage optical switches. 3. The optical switch of the last stage is composed of LiNb.
_3. The optical switch network according to claim 2, wherein the optical switch network is a 2 * 2 optical switch made using O3.