JP2000278212A - Optical transmission line fault point search system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To search fault points on all optical transmission lines inside a ring with an optical time domain refrectometer(OTDR) device by transmitting an optical signal for fault point search through an optical fiber transmission line inside an optical network while bypassing plural node devices with a branch optical fiber. SOLUTION: On both the input and output sides of node device 1-1 and 1-2, wavelength division multiplexing(WDM) couplers 20-1, 20-2 and 30-1 to 30-4 are respectively inserted as branching means and synthesizing means and the branch ports of the WDM couplers 30-1, 30-3, 30-2 and 30-4 are mutually connected by optical fibers 40-1 and 40-2. Then, the wavelength band of an optical signal outputted from an OTDR device 10 is set different from that of an optical signal outputted from the node device and only the optical signal outputted from the OTDR device 10 can be transmitted while bypassing the node device 1-2. Therefore, since the optical signals outputted from the OTDR device 10 are successively transmitted while bypassing the respective node devices, the fault points on all the transmission lines can be searched by one OTDR device 10.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a search for a fault in an optical transmission line, and more particularly to a fault search system for an optical network including a ring node device.

[0002]

2. Description of the Related Art FIG. 6 shows an SDH (Synchronous Digital Hi
erarchy) shows a block diagram of the ring system. The SDH ring system is composed of each of the ring node devices 1-1 to 1-8 and optical fiber transmission lines 2-1 to 2-8 connecting the ring node devices, and is capable of performing communication between arbitrary ring node devices. is there. In FIG. 6, as an example, the number of ring node
Although the number is shown in the figure, the number of ring node devices is not practically limited. Also, the SDH ring system uses an SDH
Although it is called like this because it uses a frame,
In addition, SONET (Sync
A format such as a hronous optical network frame can also be used. In the following explanation, for convenience, SDH
Although reference is made to ring systems, these are basically independent of the frame format.
FIG. 7 shows the configuration of FIG. 6 in more detail. Here, for simplicity, the ring node devices 1-1 and 1--1
2, 1-3 are illustrated, but the same applies to the configuration between other ring node devices. Generally, a ring node device has four optical terminals. For example, as shown in FIG. 7, the ring node device 1-2 has optical terminals 5-2-1 to 5-2-1.
2-4, which are used for transmitting and receiving optical signals, respectively. In the case of communication using a ring node device,
Generally, there are two flows of the optical signal, clockwise and counterclockwise, which enhance the reliability of the system. As the clockwise signal, for example, the ring node device 1
-1 is output from the optical terminal 5-1-3, transmitted through the optical fiber transmission line 2-1-1, and then input to the optical terminal 5-2-1 of the ring node device 1-2. Received. Further, the optical signal transmitted from the ring node device 1-2 is transmitted to the optical terminal 5-3-1 of the ring node device 1-3 after being transmitted through the optical fiber transmission line 2-2-1 and received. The same applies to counterclockwise signals.

In the above-described SDH ring system, when a failure such as a break occurs in an optical fiber transmission line, a failure point has been conventionally searched for by mainly using the following two methods. . FIG. 8 shows a method of searching for a failure point as a service interruption among the methods conventionally used. For example, if clockwise communication between the ring node devices 1-1 and 1-3 is interrupted, the optical fiber transmission line 2-1-1 or 2-2
-1 may be disconnected. In such a case, first, the optical fiber transmission line 2-1-1 is connected to the optical terminal 5-1.
3 and OTDR (Optica) to the removed optical terminal 6-1.
l A Time Domain Refrectometer (failure point searching device) 10 is connected to transmit a fault point searching optical signal to search for a fault point. If the disconnection of the optical fiber transmission line 2-1-1 is not confirmed, the OTDR device 10 is moved to the place where the ring node device 1-2 is located, and the optical fiber transmission line 2-2 is similarly operated. A task of searching for a fault point of -1 and specifying a fault point is performed. However, in the above-described method, it is necessary to disconnect the optical fiber transmission line and the ring node device, and the optical fiber transmission line that has not actually been disconnected needs to be temporarily disconnected to perform a fault point search operation. In order to avoid such a problem, a method as shown in FIG. 9 has been used. In FIG. 9, for example, a WDM is provided between an optical fiber transmission line 2-1-1 and an optical terminal 5-1-3.
(Wavelength Division Multiplexing)
Insert the coupler 20-1. The WDM coupler generally has a function of multiplexing / demultiplexing optical signals in different wavelength bands. For example, when the wavelength of an optical signal used for communication between the ring node devices 1-1 and 1-2 is light in the 1.3 μm band, OT
The wavelength of the optical signal output from the DR device 10 is 1.55 μm
If the WDM coupler 20-1 has a function of multiplexing the optical signals of the 1.3 μm band and the 1.55 μm band, the communication between the ring node devices 1-1 and 1-2 is cut off. It is possible to perform the work of searching for a fault point in the optical fiber transmission line 2-1-1 without using the above. In addition, a search for a fault point of the optical fiber transmission line 2-2-1 can be performed in the same manner.

[0004]

However, the above two prior arts have the following problems. That is, since the optical signal output from the OTDR device 10 can only search for the optical fiber transmission line connecting the respective ring node devices, the optical fiber transmission line which is considered to have a failure such as breakage is It was necessary to connect the OTDR device 10 to the output of the connected ring node device using any of the methods described above.
Generally, since each ring node device is installed in a different place, every time an optical fiber transmission line breaks or the like occurs,
It is necessary to move the OTDR device 10 and make a connection to perform a fault point search operation, which increases the amount of work. FIG.
If the OTDR device is previously installed in the place where each ring node device is placed by the method described above, it is not necessary to move the OTDR device, but in this case, it is necessary to use a plurality of OTDR devices, and the cost is reduced. Was an issue. Further, recently, the ring node device itself is often installed in a customer building of a communication carrier. In such a case, there are restrictions on entering a customer building, restrictions on the installation space of the OTDR device, and the like.

[0005] The present invention relates to an O-communication system located in a station of a telecommunications carrier.
An object of the present invention is to provide an optical transmission line fault point search system capable of searching for a fault point from a TDR device.

[0006]

In order to solve this problem, an optical transmission line fault point searching system according to the present invention comprises an optical network in which a plurality of node devices are connected in a ring or cascade by an optical fiber transmission line. , The input side and the output side of each of the other node devices except for one or end node device of the plurality of node devices, the same wavelength division multiplex coupler as input side branching means such as wavelength division multiplex coupler Output side combining means are inserted respectively, and further, the branch port of the input side branching means and the branch port of the output side combining means are interconnected by a branch optical fiber, and the one or the end node device An output side combining means is connected to the output side, and a failure point searching device is connected to a branch port of the output side combining means. The wavelength band of the optical signal for use and the wavelength band of each output optical signal of the plurality of node devices are set to be different within the transmission wavelength band of the optical fiber transmission line and the branch optical fiber, and the input side branch is set. The means is configured to select and branch the wavelength band of the optical signal for fault point searching of the fault point searching device from the wavelength band of each output optical signal of the plurality of node devices, and to determine the fault point of the fault point searching device. The search optical signal is irrelevant to the transmission of each output optical signal of the plurality of node devices, bypassing the plurality of node devices by the branch optical fiber, and searching the optical network for a failure point. The transmission is performed via the optical fiber transmission line in the network.

Further, in the optical transmission line fault point searching system according to the present invention, in an optical network in which a plurality of node devices are connected in a ring or cascade by an optical fiber transmission line, one of the plurality of node devices is provided. Alternatively, an input side branching unit and an output side combining unit are respectively inserted on the input side and the output side of each of the other node devices except the end node device, and further, a branch port of the input side branching unit and the output side. The branch port of the combining means is interconnected by a branch optical fiber, the output side of the node device at the end is connected to the output side combining means, and the branch port of the output side combining means is provided with a fault point searching device. The wavelength band of the optical signal for searching for a fault point of the fault point searching device and the wavelength bands of the output optical signals of the plurality of node devices are connected to the optical fiber transmission line and the branch optical fiber. An optical filter for suppressing another wavelength component with respect to the fault point searching optical signal of the fault point searching device is inserted in the branch optical fiber, so as to be different from each other in a transmission wavelength band with the optical fiber, An optical filter for suppressing other wavelength components with respect to the wavelength band of the received optical signal of the node device is inserted in the optical fiber immediately before the optical terminal for reception of the node device, and a fault point of the fault point searching device is inserted. The search optical signal is irrelevant to the transmission of each output optical signal of the plurality of node devices, bypassing the plurality of node devices by the branch optical fiber, and searching the optical network for a failure point. The transmission may be performed via the optical fiber transmission path in the network.

[0008] The present invention has the following features. In the optical transmission line fault point searching system according to the present invention, in an optical network in which a plurality of node devices are connected in a ring (or cascade) by an optical fiber transmission line, WDM couplers are input to both the input and output sides of the node devices. It is inserted as side branching means and output side combining means, and the branch ports of the WDM coupler are connected by an optical fiber. By setting the wavelength band of the optical signal output from the OTDR device (failure point searching device) and the wavelength band of the optical signal output from the node device to be different, only the optical signal output from the OTDR device bypasses the node device. Transmitted. With such a configuration, optical signals output from the OTDR device are transmitted one after another bypassing each node device, so that a single OTDR device can search for a fault point on the entire optical transmission path. Become. By inserting a low-reflectivity wavelength-selective optical element such as an optical fiber grating in the middle of the optical fiber connecting the branch ports of the WDM coupler described above, it is possible to improve the accuracy of searching for a fault point in the optical fiber transmission line. It is possible. In another configuration, by inserting an optical filter immediately before the optical fiber for bypass and the receiving optical terminal of the node device, it is possible to increase the degree of suppression of other wavelength components with respect to the desired optical signal. In the present invention, for convenience of explanation, the node device is SD
Although an H ring node device is assumed, the present invention can be applied regardless of the type of the ring node device. Further, although the case where the optical signal output from the node device to the optical fiber transmission line has one wavelength is described, the configuration of the present invention can be applied as it is even when this is a wavelength multiplexed signal. Further, the present invention is not specifically used for a complete ring transmission line, but can be applied to a transmission line in which node devices are cascaded.

[0009]

(Embodiment 1) FIG. 1 shows Embodiment 1 of an optical transmission line fault point searching system according to the present invention. Here, the wavelength of the optical signal output from the OTDR device 10 and the wavelength of the optical signal output from the ring node device 1-1 are different from each other as in the conventional example shown in FIG. Wavelength band of optical signal to be output = 1.55 μm band, wavelength band of optical signal output from the ring node device = 1.3 μm band)
Is set to In such a case, the WDM coupler 30-1 is inserted as an input-side branching unit immediately before the optical terminal 5-2-1 which is a receiving optical terminal of the ring node device 1-2.
The 1.3 μm band optical signal is demultiplexed in the direction of the optical terminal 5-2-1, and the 1.55 μm band optical signal is divided into the WDM coupler 30-1.
The WDM coupler 30-1 is installed so as to be split in the direction of the optical fiber 40-1 connected to the WDM. With such a configuration, the optical signal output from the OTDR device 10 is transmitted to the optical fiber 40-1, and further, the transmission optical terminal 5-2-3 of the ring node device 1-2.
Is input to one terminal of a WDM coupler 30-3 inserted as an output-side combining means, and then guided to an optical fiber transmission line 2-2-1. On the other hand, the ring node device 1-2
The 1.3 μm band optical signal output from the transmission optical terminal 5-2-3 of FIG. 1 passes through the WDM coupler 30-3 and is input to the optical fiber transmission line 2-2-1.

FIG. 2 is a diagram showing an example of an OTDR trace when a fault point search is performed in such a configuration. OT
The optical signal output from the DR device is transmitted to the optical fiber transmission line 2
After being attenuated by -1-1, the light is slightly attenuated by the WDM coupler 30-1, the optical fiber 40-1, and the WDM coupler 30-3. Thereafter, the OTDR signal is attenuated in the optical fiber transmission line 2-2-1.
A TDR trace is obtained. The same configuration is applied to the ring node devices 1-3 and thereafter, so that the OTDR
It becomes possible to unify the search for the fault points of all the optical fiber transmission lines in the ring from the device 10. In the above description, only the clockwise optical signal is targeted. However, as shown in FIG. 1, the same configuration is applied to the counterclockwise signal, and the optical signal between the ring node devices is counterclockwise. And O
The same effect can be obtained by transmitting the optical signal from the TDR device clockwise.

(Embodiment 2) In the trace of Embodiment 1 shown in FIG. 2, the loss due to the WDM coupler 30-1, the optical fiber 40-1, and the WDM coupler 30-3 is exaggerated for convenience of explanation. Actually, these losses are extremely small, and are about 0.5 to 1 dB as a whole. The length of the optical fiber 40-1 is about several meters at most, and is sufficiently shorter than the length of the optical fiber transmission line 2-1-1 or 2-2-1. Therefore, in the actually observed OTDR trace, the WDM coupler 30-1, the optical fiber 40-1,
The change on the trace due to the WDM coupler 30-3 may be difficult to observe in some cases. In such a case,
Embodiment 2 in which Embodiment 1 is improved to clearly specify the position of the ring node device 1-2 on the OTDR trace.
Is shown in FIG. In the configuration shown in FIG. 3, a wavelength selective optical element having a low reflectance, for example, an optical fiber grating 50-1 having a reflection band in a wavelength band of 1.55 μm and having a reflectance of about 0.1% is connected to an optical fiber 40. Insert at -1. With such a configuration, as shown in FIG. 4, the reflection by the optical fiber grating 50-1 can be clearly observed on the OTDR trace, and the position of the ring node device 1-2 can be clearly specified. Become. The insertion position of the optical fiber grating 50-1 is not necessarily the optical fiber 40-.
1 on the optical fiber transmission line 2-1-1 immediately before the WDM coupler 30-1 or the WDM coupler 3-1.
It may be on the optical fiber transmission line 2-2-1 just after 0-3.

(Embodiment 3) FIG. 5 shows Embodiment 3 of the present invention. The wavelength separation degree of the WDM coupler 30-1 is not sufficient,
For example, 1.3 μm output from the ring node device 1-1
When a part of the m-band optical signal leaks into the optical fiber 40-1, the leaked signal is transmitted through the optical fiber transmission line 2-.
To the ring node device 1-3. In such a case, 1.3
An optical filter 70 for removing only the optical signal in the μm band.
By inserting 1 into the optical fiber 40-1, the above problem can be solved. Further, a part of the optical signal in the 1.55 μm band is connected to the optical terminal
In the case of inputting to 2-1 similarly, 1.55 μm
Optical filter 60-1 for removing only the m-band optical signal
Is inserted just before the optical terminal 5-2-1.
It is possible to avoid the problem caused by the input of the 1.55 μm band optical signal to the ring node device 1-2.
Similarly, by inserting the optical filter 70-2 and the optical filter 60-2 in the counterclockwise transmission path between the ring node devices, the above-described problem can be avoided. In this embodiment, the configuration in which the optical fiber grating is not inserted has been described. However, even when the optical fiber grating is inserted as in the second embodiment, the configuration of this embodiment can be used as it is.

(Embodiment 4) In the above embodiments 1, 2, and 3, the branching means on the input side of each node device is provided with WDM.
Like a coupler, a coupler that selects and branches the wavelength band of the optical signal for fault point search of the fault point searching device 10 from the wavelength band of each output optical signal of the plurality of node devices 1-2,. As a result, the optical signal for searching for a fault point of the fault point searching apparatus 10 is transmitted independently of the transmission of the output optical signals of the plurality of node devices 1-2,.
Is transmitted via the optical fiber transmission line in the optical network to search for a fault point in the optical network, bypassing the plurality of node devices 1-2. However, in the third embodiment shown in FIG. 5, an optical filter 7 for suppressing another wavelength component with respect to the optical signal for fault point search of the fault point search apparatus 10 in the branch optical fiber 40-1.
0-1 is inserted, and each node device 1-2,.
The optical filter 60-1 for suppressing other wavelength components with respect to the wavelength band of the received optical signal of the node device is inserted into the optical fiber immediately before the receiving optical terminal 5-2-1,. Therefore, a branch coupler having no specific wavelength selectivity can be used as the branch coupler 30-1 without using a WDM coupler.

In each of the embodiments, a structure combining a normal optical fiber coupler and an optical filter and a structure using a wavelength division multiplexing optical fiber coupler are used as input side branching means and output side combining means for bypassing each node. However, in addition to the above, the input branching means may be formed by using a device combining an optical circulator and a fiber grating, a device using a dielectric multilayer optical filter, a device using an acousto-optic effect, or a semiconductor device. , Output side synthesizing means.

[0015]

As described above, according to the present invention, the following effects can be expected. With one OTDR device, it is possible to search for a fault point on all optical transmission lines in the ring. By inserting a low-reflectivity wavelength-selective optical element such as an optical fiber grating in the middle of the optical fiber connecting the branch ports of the WDM coupler, it is possible to improve the accuracy of searching for a fault point in the optical fiber transmission line. is there. By inserting an optical filter immediately before the branch optical fiber and the receiving optical terminal of the ring node device, it becomes possible to increase the degree of suppression of other wavelength components with respect to a desired optical signal, and adversely affect communication between ring node devices. Can be avoided.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating a configuration of a first exemplary embodiment of the present invention.

FIG. 2 is a diagram for explaining the operation of the first embodiment in FIG. 1;

FIG. 3 is a block diagram illustrating a configuration of a second exemplary embodiment of the present invention.

FIG. 4 is a diagram for explaining the operation of the second embodiment in FIG. 3;

FIG. 5 is a block diagram illustrating a configuration of a third exemplary embodiment of the present invention.

FIG. 6 is a block diagram showing a configuration of an SDH ring system to which the present invention is applied.

FIG. 7 is a block diagram showing an optical network including a ring node device as an example of a system to which the present invention is applied.

FIG. 8 is a block diagram showing an example of a conventional failure point search method.

FIG. 9 is a block diagram showing another example of a conventional failure point search method.

[Explanation of symbols]

1-1 to 1-8 Ring node device 2-1 to 2-8, 2-1-1, 1-2-2, 2-2
1,2-2-2 optical fiber transmission line 5-1-3,5-1-4,5-2-1 to 5-2-4,5
-3-1, 5-3-2, 6-1, 6-2, 15-1 to 1
5-4 Optical terminal 10 OTDR device 20-1 to 20-4, 30-1 to 30-4 WDM coupler 40-1, 40-2 Optical fiber 50-1, 50-2 Optical fiber grating 60-1, 60- 2,70-1,70-2 Optical filter

Claims (8)

[Claims] In an optical network in which a plurality of node devices are connected in a ring by an optical fiber transmission line, an input side and an output side of each of the other node devices except one of the node devices. The input side branching means and the output side combining means are respectively inserted, and further, the branch port of the input side branching means and the branch port of the output side combining means are interconnected by a branch optical fiber, and the one node Output side combining means is connected to the output side of the device, and a fault point searching device is connected to a branch port of the output side combining means. The wavelength band of the fault point searching optical signal of the fault point searching device and The wavelength bands of the output optical signals of the plurality of node devices are set to be different from each other within the transmission wavelength band of the optical fiber transmission line and the branch optical fiber, The fault point searching device is configured to select and branch a wavelength band of the fault point searching optical signal from the wavelength bands of the output optical signals of the plurality of node devices. The optical signal is bypassed by the branch optical fiber and bypasses the plurality of node devices, regardless of the transmission of each output optical signal of the plurality of node devices, to search for a point of failure in the optical network. The optical transmission line fault point searching system is transmitted through the optical fiber transmission line. 2. In an optical network in which a plurality of node devices are cascaded by an optical fiber transmission line, the node device excluding an end node device connected to an end of the optical network among the plurality of node devices. An input-side branching unit and an output-side combining unit are respectively inserted on the input side and the output side of each node device, and the branch port of the input-side branching unit and the branch port of the output-side combining unit The nodes are interconnected by a fiber, an output side combining means is connected to an output side of the node device at the end, and a failure point searching device is connected to a branch port of the output side combining means. The wavelength band of the fault point searching optical signal and the wavelength band of each output optical signal of the plurality of node devices are different from each other within the transmission wavelength band of the optical fiber transmission line and the branch optical fiber. The input side branching means is configured to select and branch a wavelength band of a fault point searching optical signal of the fault point searching device from a wavelength band of each output optical signal of the plurality of node devices, The optical signal for searching for a fault point of the fault point searching device is configured to bypass the plurality of node devices by the branch optical fiber, regardless of transmission of each output optical signal of the plurality of node devices, and to cause a fault in the optical network. An optical transmission line fault point search system, which is transmitted via the optical fiber transmission line in the optical network for a point search. 3. A low-reflectivity wavelength-selective optical element is inserted into the branch optical fiber, the optical fiber immediately before the input-side branching unit, or the optical fiber immediately after the output-side combining unit. The optical transmission path fault point search system according to claim 1 or 2, wherein: 4. An optical filter for suppressing another wavelength component with respect to a fault point searching optical signal of the fault point searching device, wherein the optical filter is inserted in the branch optical fiber. 4. The optical transmission path fault point search system according to 2 or 3. 5. An optical filter for suppressing another wavelength component with respect to a wavelength band of a received optical signal of the node device is inserted in an optical fiber immediately before a receiving optical terminal of the node device. The optical transmission path fault point search system according to claim 1, 2 or 3. 6. An input-side wavelength division multiplexing coupler is used as said input-side branching means, and an output-side wavelength division multiplexing coupler is used as said output-side combining means. An optical transmission path fault point search system according to any one of the claims. 7. In an optical network in which a plurality of node devices are connected in a ring by an optical fiber transmission line, an input side and an output side of each of the node devices other than one of the plurality of node devices. The input side branching means and the output side combining means are respectively inserted, and further, the branch port of the input side branching means and the branch port of the output side combining means are interconnected by a branch optical fiber, and the one node Output side combining means is connected to the output side of the device, and a fault point searching device is connected to a branch port of the output side combining means. The wavelength band of the fault point searching optical signal of the fault point searching device and The wavelength bands of the output optical signals of the plurality of node devices are set so as to be different from each other within the transmission wavelength band of the optical fiber transmission line and the branch optical fiber. An optical filter for suppressing another wavelength component with respect to the optical signal for searching for a fault point of the fault point searching device is inserted, and the reception of the node device is performed in the optical fiber immediately before the receiving optical terminal of the node device. An optical filter for suppressing other wavelength components with respect to the wavelength band of the optical signal is inserted, and the optical signal for searching for a fault point of the fault point searching device is related to transmission of each output optical signal of the plurality of node devices. Optical transmission, wherein the plurality of node devices are bypassed by the branch optical fiber and transmitted through the optical fiber transmission line in the optical network for searching for a fault point in the optical network. Road failure point search system. 8. In an optical network in which a plurality of node devices are cascaded by an optical fiber transmission line, the node device excluding an end node device connected to an end of the optical network among the plurality of node devices. An input-side branching unit and an output-side combining unit are respectively inserted on the input side and the output side of each node device, and the branch port of the input-side branching unit and the branch port of the output-side combining unit The nodes are interconnected by a fiber, an output side combining means is connected to an output side of the node device at the end, and a failure point searching device is connected to a branch port of the output side combining means. The wavelength band of the fault point searching optical signal and the wavelength band of each output optical signal of the plurality of node devices are different from each other within the transmission wavelength band of the optical fiber transmission line and the branch optical fiber. An optical filter for suppressing another wavelength component with respect to the fault point searching optical signal of the fault point searching device is inserted in the branch optical fiber, and the light immediately before the receiving optical terminal of the node device is inserted. An optical filter for suppressing another wavelength component with respect to the wavelength band of the optical signal received by the node device is inserted into the fiber, and the optical signal for searching for a fault point of the fault point searching device is Irrespective of transmission of each output optical signal, the plurality of node devices are bypassed by the branch optical fiber and transmitted through the optical fiber transmission line in the optical network for searching for a failure point of the optical network. An optical transmission path fault point search system characterized by being performed.