KR102107639B1 - Remote Node Identification System for Optical Fiber Using Optical Time Domain Reflectometer and Device for The Same - Google Patents

Abstract

The optical path remote node identification system according to an embodiment of the present invention includes an optical path domain reflectometer that transmits a measurement optical signal to the optical path and the optical path including the plurality of nodes, and receives the signal to be conveyed. The plurality of nodes carries a first optical coupler which branches a portion of the optical signal from the optical path and an optical signal branched from the first optical coupler through at least two different paths, thereby making a path difference between the conveyed optical signals. And a path difference inducing unit that generates a difference in peak height of the conveyed optical signals, and at least one of the difference between the path difference and the peak height of the conveyed optical signals is set differently in the plurality of nodes. It is.

Description

A remote node identification system for optical fiber using optical time domain reflectometer and device for the same

The present invention relates to an optical path remote node (RN) identification system using an optical time domain reflector that can be checked for each location by measuring a physical characteristic state of the optical path and an element for identification used therein.

The optical communication optical path is connected through a number of remote nodes (RNs) around a central office terminal (COT). The optical path includes an annular network as shown in FIG. 1, a straight network arranged in a straight line from a telephone station, or a star topology arranged radially around one telephone station. There is no limit to the number of remote nodes. In general, as shown in FIG. 1, two optical paths are arranged side by side in one optical network, and one is used as a working line and the other as a protective (back-up) line. In the annular network shown in FIG. 1, communication is possible in both directions. That is, communication can be made either clockwise or counterclockwise.

For the maintenance of such optical paths, the physical state (break, breakage, loss) should be measured and grasped by distance, and an optical time domain reflectometer (OTDR) is used as a means. The measurement result of OTDR is illustrated in FIG. 2. In the lower graph of FIG. 2, the X-axis is a distance, and the Y-axis represents loss information. As can be seen in FIG. 2, the measurement power decreases as the distance increases due to the loss per unit length of the optical fiber, and a stepped or reflected peak appears in the graph due to a loss or reflection factor of a specific portion. When measuring OTDR, it is necessary to identify the remote node module. This is because different functions (operation wavelength, etc.) are assigned to each remote node module, and they are not placed in a certain position of the optical path according to the function. Because it needs to grasp.

When OTDR is used, as shown in FIGS. 3 and 4, physical characteristics of the optical path can be measured. That is, it is possible to grasp the location where the physical abnormality of the optical path occurs, the type of the physical abnormality, and the degree of the physical abnormality, etc. At this time, if the remote node can be clearly identified, the part with physical anomaly can be grasped based on the remote node, which is convenient for managing the optical network.

The technical problem to be solved by the present invention is to provide a system capable of identifying a remote node on an optical path and a device for identifying a remote node used therein.

The optical fiber long-distance node identification system according to an embodiment of the present invention includes an optical time domain reflectometer that transmits a measurement optical signal to the optical path, and a signal that is conveyed to the optical path including a plurality of nodes, The plurality of nodes carries a first optical coupler which branches a portion of the optical signal from the optical path and an optical signal branched from the first optical coupler through at least two different paths, thereby passing a path between the transmitted optical signals. And a path difference inducing unit that generates a difference and generates a difference in peak heights of the conveyed optical signals, wherein at least one of the difference between the path difference and the peak heights of the conveyed optical signals is different from each other. It is set.

A first optical coupler for diverging a portion of an optical signal from an optical path for a device for identifying a far-field node according to an embodiment of the present invention and an optical signal diverged from the first optical coupler by conveying through at least two different paths And a path difference inducing unit generating a path difference between the optical signals carried through the different paths and generating a difference in peak heights of the carried optical signals.

The optical fiber long-distance node identification system according to another embodiment of the present invention includes an optical time domain reflectometer that transmits a measurement optical signal to the optical path including a plurality of nodes, and a signal to be conveyed, The plurality of nodes may include a first optical coupler that branches a portion of the optical signal from the optical path, a second optical coupler that branches a portion of the optical signal from the optical path, and is connected in series with the first optical coupler, the first optical And a first path line that carries the optical signal branched from the coupler through the first path and a second path line that carries the optical signal branched from the second optical coupler through the second path, and The length and the length of the second path are set differently, and the peak heights of the optical signal carried through the first path line and the optical signal carried through the second path line Is different from each other, and at least one of a difference between a peak height of an optical signal carried through the first path line and an optical signal carried through the second path line and a path difference between the first path and the second path Is set differently from the plurality of nodes.

A device for identifying a far-field node according to another embodiment of the present invention is a first optical coupler that branches a portion of an optical signal from the optical path, a portion of the optical signal from the optical path, and connected in series with the first optical coupler A second optical coupler, a first path line that carries the optical signal diverged from the first optical coupler through a first path, and a second path that carries an optical signal diverged from the second optical coupler through a second path. A line, the length of the first path and the length of the second path are set differently, and peaks of the optical signal carried through the first path line and the optical signal carried through the second path line The height difference is different

The optical fiber long-distance node identification system according to another embodiment of the present invention includes an optical time domain reflectometer that transmits a measurement optical signal to the optical path and includes a signal that is carried, and a optical path comprising a plurality of nodes, The plurality of nodes transports a first optical coupler branching a portion of the optical signal from the optical path and an optical signal branched from the first optical coupler through at least three different paths, thereby passing a path between the transmitted optical signals. It includes a path difference inducing unit for generating a difference, and the path difference between the optical signals is set differently in the plurality of nodes.

The device for identifying a far-field node according to another embodiment of the present invention carries a first optical coupler which branches a part of the optical signal from the optical path and an optical signal branched from the first optical coupler through at least three different paths. By doing so, it includes a path difference inducing unit that generates a path difference between the conveyed optical signals.

The optical fiber long-distance node identification system according to another embodiment of the present invention includes an optical time domain reflectometer that transmits a measurement optical signal to the optical path and includes a signal that is conveyed, and includes a plurality of nodes. The plurality of nodes may include a first optical coupler that branches a portion of the optical signal from the optical path, a second optical coupler that branches a portion of the optical signal from the optical path, and is connected in series with the first optical coupler, the first optical A first path line for conveying the optical signal branched from the coupler through the first path, a second path line for conveying the optical signal branched from the second optical coupler through the second path, and a branched from the second optical coupler It includes a third path line for conveying the optical signal through the third path, the length of the first to third path is set differently, the path difference of the first to third path In the plurality of nodes it is set different from each other.

A device for identifying a far-field node according to another embodiment of the present invention is a first optical coupler that branches a part of the optical signal from the optical path, and a part of the optical signal from the optical path and is connected in series with the first optical coupler A second optocoupler,

A first path line that carries the optical signal diverged from the first optical coupler through a first path, a second path line that carries the optical signal diverged from the second optical coupler through a second path, and the second optical line. And a third path line that carries the optical signal branched from the coupler through the third path, and the lengths of the first to third paths are set differently.

Using the optical path remote node identification system and its identification element according to an embodiment of the present invention, it is possible to clearly identify the remote node on the optical path, and it is convenient to grasp and maintain the physical abnormality of the optical path based on this. Do.

1 is a schematic diagram of an annular network optical path.
2 is a view showing an example of a light path measurement using an optical time domain reflectometer.
3 is a view showing a pattern that appears according to each type of physical abnormality when the optical path is measured using an optical time domain reflectometer.
4 is a view showing in more detail a pattern that appears according to each type of physical anomaly when measuring an optical path using an optical time domain reflectometer.
5 is a schematic diagram of an optical path remote node identification system and an element for identification using an optical time domain reflectometer according to an embodiment of the present invention.
6 is a schematic diagram of an element for identification used in a far-field node identification system using an optical time domain reflectometer according to an embodiment of the present invention.
FIG. 7 is a diagram illustrating a method of identifying each remote node in a system for identifying a distant node in an optical path using an optical time domain reflectometer according to an embodiment of the present invention.
FIG. 8 is a diagram illustrating another method of identifying each remote node in a system for identifying a distant node in an optical path using an optical time domain reflectometer according to an embodiment of the present invention.
9 is a schematic diagram of an optical path remote node identification system and an element for identification thereof using an optical time domain reflectometer according to another embodiment of the present invention.
10 is a schematic diagram of an optical path remote node identification system and an element for identification thereof using an optical time domain reflectometer according to another embodiment of the present invention.
11 is a schematic diagram of an optical path remote node identification system and an element for identification using an optical time domain reflectometer according to another embodiment of the present invention.
FIG. 12 is a diagram illustrating a method of identifying each remote node in a system for identifying a distant node in an optical path using an optical time domain reflectometer according to the embodiment of FIG. 11.
13 and 14 is a configuration using an optical switch to perform a clockwise optical signal transmission and a counter-clockwise optical signal transmission in the system for the identification of the far-field node using the optical time domain reflectometer according to the embodiment of FIG. 11 It is a drawing to show.
15 is a schematic diagram of an optical path remote node identification system and an element for identification thereof using an optical time domain reflectometer according to another embodiment of the present invention.
16 is a schematic diagram of an optical path remote node identification system and an element for identification thereof using an optical time domain reflectometer according to another embodiment of the present invention.
17 is a schematic diagram of an optical path remote node identification system and an element for identification using an optical time domain reflectometer according to another embodiment of the present invention.
FIG. 18 is a diagram illustrating one method of identifying each remote node in the optical path remote node identification system using the optical time domain reflectometer according to the embodiment of FIG. 17.
19 is a schematic diagram of an optical path remote node identification system and an element for identification using an optical time domain reflectometer according to another embodiment of the present invention.
20 is a schematic diagram of an optical path remote node identification system and an element for identification thereof using an optical time domain reflectometer according to another embodiment of the present invention.
21 is a schematic diagram of an optical path remote node identification system and an element for identification using an optical time domain reflectometer according to another embodiment of the present invention.
FIG. 22 is a diagram illustrating a method of identifying each remote node in a system for identifying a distant node in an optical path using an optical time domain reflectometer according to the embodiment of FIG. 21.
23 is a schematic diagram of an optical path remote node identification system and an element for identification thereof using an optical time domain reflectometer according to another embodiment of the present invention.
24 is a schematic diagram of an optical path remote node identification system and an element for identification using an optical time domain reflectometer according to another embodiment of the present invention.

Then, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains may easily practice. However, the present invention can be implemented in many different forms and is not limited to the embodiments described herein.

In the drawings, the thickness is enlarged to clearly express the various layers and regions. The same reference numerals are used for similar parts throughout the specification. When a portion of a layer, film, region, plate, or the like is said to be “above” another portion, this includes not only the case “directly above” the other portion but also another portion in between. Conversely, when one part is "just above" another, it means that there is no other part in the middle.

5 is a schematic diagram of an optical path remote node identification system and an element for identification using an optical time domain reflectometer according to an embodiment of the present invention, and FIG. 6 is an optical time domain reflectometer according to an embodiment of the present invention. It is a schematic diagram of the identification element used in the used optical path remote node identification system.

An optical path remote node identification system using an optical time domain reflectometer according to an embodiment of the present invention includes a telephone station (COT) and a plurality of remote node modules (RN # 1, RN # 2, RN # 3 ... RN # N ). Between the Telephone Station (COT) and the Remote Node Module (RN # 1, RN # 2, RN # 3 ... RN # N) and the Remote Node Module (RN # 1, RN # 2, RN # 3 ... RN # N) ) There are two optical paths consisting of a main line and a backup line. Although the telephone station (COT) is illustrated in FIG. 5 as being disposed on the left and right sides, a system for identifying a distant node with a light path using an optical time domain reflectometer according to an embodiment of the present invention may be applied to the annular network of FIG. 1.

In the optical path remote node identification system according to an embodiment of the present invention, an identification element as shown in FIG. 6 is installed at each remote node, and an optical time domain reflectometer is installed at the telephone station (COT).

The identification element includes a first optical coupler 11 and a second optical coupler 12 and a second optical coupler 12 having one end connected to a branch line branched from the optical path in the first optical coupler 11 and the first optical coupler 11. ), The first path line 21 and the second path line 22 connected to the other end of the), and a dummy line 31 inserted as a part of the optical path.

The first optical coupler 11 partially branches the optical signal incident through the optical path and sends it to the second optical coupler 12. 5 and 6, the first optical coupler 11 illustrates the ratio of the optical signal diverging from the optical path as 1% (branch ratio 99: 1), but this ratio can be set differently as necessary. The second optocoupler 12 branches out from the first optocoupler 11 and divides the incident optical signal into two again, and sends it out to the first path line 21 and the second path line 22. Here, the branch ratio (X: Y) between the first path line 21 and the second path line 22 is 10:90, 20:80, 30:70, 40:60, 50:50, 60:40 And so forth. The branch ratio (X: Y) between the first path line 21 and the second path line 22 is a remote node module (RN # 1, RN # 2, RN # 3 ... RN) in which an identification element is disposed. #N) Not very different. In this way, a remote node module (RN # 1, RN # 2, RN # 3) in which an element for identifying the branch ratio (X: Y) between the first path line 21 and the second path line 22 is arranged. .. ################################################################################################################################################################### To ############################################ ## ## ## #> </ RTI> with respect to. ####### ################################> / # Each of the remote node modules RN # 1, RN # 2, RN # 3 ... RN # N) To make things different. . The first path line 21 includes a first dummy line 211 and a first reflective mirror 212, and the second path line 22 includes a second dummy line 221 and a second reflective mirror 222. It includes. The reflected light amount ratios of the reflective mirrors 212 and 222 may also be variously determined as 10:90, 20:80, 30:70, 40:60, 50:50, 60:40, and the like. The reflected light quantity ratios of the two reflective mirrors 212 and 222 may also be determined differently for each remote node module (RN # 1, RN # 2, RN # 3 ... RN # N) in which an element for identification is disposed. It is also possible to change the reflected light ratio of the two reflection mirrors 212 and 222 for each remote node module (RN # 1, RN # 2, RN # 3 ... RN # N) in which an element for identification is disposed. This is to make the difference in height of the pulse peaks carried through 21) and the second path line 22 different for each remote node module (RN # 1, RN # 2, RN # 3 ... RN # N). As a method of adjusting the reflected light amount ratio of the two reflective mirrors 212 and 222, a method of adjusting the reflectance of the reflective mirror itself and disposing different insertion loss elements (not shown) in front of the two reflective mirrors 212 and 222 There is a way. The length of the first dummy line 211 and the length of the second dummy line 221 are set to differ by a predetermined value. The difference between the length of the first dummy line 211 and the length of the second dummy line 221 may also be set differently for each remote node module. The first reflection mirror 212 and the second reflection mirror 222 are designed to reflect light in a predetermined wavelength band. The predetermined wavelength band may be located in an area outside the wavelength band of light used for optical communication. The dummy line 31 inserted as a part of the optical path is added to prevent cross-talk with an actual reflected pulse generated outside the remote node module, and the first reflective mirror (from the branched portion of the first optical coupler 11) It is longer than the length up to 212), and longer than the length from the branched portion of the first optocoupler 11 to the second reflection mirror 222. The dummy line 31 may be omitted in some cases. In this embodiment, the distance difference between the heights of the pulse peaks carried through the first path line 21 and the second path line 22 is determined by the respective remote node modules RN # 1, RN # 2, RN # 3 ... RN. #N), the divergence ratio (X: Y) to the first path line 21 and the second path line 22 of the second optical coupler 12 is different, or the two reflection mirrors 212 , 222) may be different from each other or the two means may be applied together.

With reference to FIGS. 7 and 8, a description will be given of a method of identifying each distant node in the optical path distant node identification system using an optical time domain reflectometer according to an embodiment of the present invention.

When the optical time domain reflectometer installed in the telephone station (COT) transmits an optical pulse for identification (OTDR Pulse), the first optical coupler 11 branches off and transmits it to the second optical coupler 12, The second optical coupler 12 divides the optical pulses into two again and transmits them to the first path line 21 and the second path line 22. The optical pulses incident on the first path line 21 and the second path line 22 are reflected by the first reflection mirror 212 and the second reflection mirror 222, respectively, and the second optical coupler 12 and the first The optical coupler 11 returns to the optical time domain reflectometer. At this time, since there is a difference between the length of the first dummy line 211 and the length of the second dummy line 221, a path difference occurs twice as much as the difference, and between the optical pulses returned to the optical time domain reflectometer. Parallax occurs. In addition, the pulses carried through the first path line 21 and the second path line 22 of the measurement element installed in each of the remote node modules (RN # 1, RN # 2, RN # 3 ... RN # N) Since the height difference of the peaks is set differently, as shown in FIG. 7, the optical pulses reflected and returned from the respective remote node modules RN # 1, RN # 2, RN # 3 ... RN # N are returned. The height difference is different. By examining the aspect of the height difference of the optical pulses, it is possible to distinguish which remote pulses are reflected from the remote node modules RN # 1, RN # 2, RN # 3 ... RN # N.

In addition, as shown in FIG. 8, it is possible to parallelize the difference between the lengths of the first dummy lines 211 and the lengths of the second dummy lines 221 together with different height differences of the optical pulses. If the difference between the length of the first dummy line 211 and the length of the second dummy line 221 is different, each remote node module (RN # 1, RN # 2, RN # 3 ... RN # N) The parallax between the reflected and reflected optical pulses is different. When this is combined with a method of varying the height difference of the optical pulses, a much more distinct combination can be obtained compared to using each method one by one. For example, as illustrated in FIG. 8, the first node module RN # 1 and the second node module RN # 2 have the same path difference (path difference # 1), but different peak height differences appear. The first node module (RN # 1) and the third node module (RN # 3) have the same height difference between the peaks, but the path difference (path difference # 1, path difference # 2) is different. Can be distinguished.

9 is a schematic diagram of an optical path remote node identification system and an element for identification thereof using an optical time domain reflectometer according to another embodiment of the present invention.

The optical path remote node identification system according to the embodiment of FIG. 9 and the element for identification thereof are connected to the first optical coupler 11 and the second optical coupler 12 compared to the identification element according to the embodiment of FIG. 5 Is different. In this embodiment, a branch line comes out from both ends of the first optocoupler 11 and is connected to one end of the second optocoupler 12. The rest of the configuration is almost no different from the identification element according to the embodiment of Fig. 5, and the method of confirming each remote node is the same. However, since branch lines are provided at both ends of the first optical coupler 11, measurement can be performed in any direction of the optical path.

10 is a schematic diagram of an optical path remote node identification system and an element for identification thereof using an optical time domain reflectometer according to another embodiment of the present invention.

The optical path remote node identification system according to the embodiment of FIG. 10 and the element for identification thereof are left and right dummy lines 31 and 32 on the optical paths on both sides of the first optical coupler 11 compared to the identification element according to the embodiment of FIG. 9. ) Is different. The left and right dummy lines 31 and 32 are added to prevent crosstalk with an actual reflection pulse generated outside the remote node module, from the branched portion of the first optocoupler 11 to the first reflection mirror 212. Is longer than the length of the first optocoupler 11 to the second reflection mirror 222.

11 is a schematic diagram of an optical path remote node identification system and an element for identification using an optical time domain reflectometer according to another embodiment of the present invention.

The optical path remote node identification system and the element for identification according to the embodiment of FIG. 11 are compared with the element for identification according to the embodiment of FIG. 10, the second optical coupler is omitted, and both sides of the first optical coupler 11 The difference is that the branched line directly forms the first path line 21 and the second path line 22. In order to induce a difference in peak heights of light carried through the first path 21 and light carried through the second path 22, a method of varying the reflected light amount of the reflection mirrors 212 and 222 connected to each of them is used. do. Adjusting the amount of reflected light of the reflective mirrors 212 and 222 is performed by adjusting the reflectance of the reflective mirror itself or by disposing different insertion loss elements (not shown) in front of the two reflective mirrors 212 and 222.

A method of identifying each remote node using the optical path remote node identification system and the identification element will be described with reference to FIG. 12. FIG. 12 is a diagram illustrating a method of identifying each remote node in a system for identifying a distant node in an optical path using an optical time domain reflectometer according to the embodiment of FIG. 11.

In this embodiment, the optical time domain reflectometer installed in the telephone station (COT) transmits a measurement optical pulse (OTDR Pulse) twice in the east and west and once in the east. First, the measurement optical pulses transmitted from each other are branched from the first optocoupler 11, enter the second path line 22, are reflected by the second reflection mirror 222, and are installed in the telephone station (COT). Return to the optical time domain reflectometer. Next, the measurement optical pulse transmitted from west to east is branched from the first optocoupler 11, enters the first path line 21, is reflected from the first reflection mirror 212, and is installed in the telephone station (COT). Return to the optical time domain reflectometer. When the signals measured twice are synthesized, the height of the optical pulse is different according to the reflected light ratio set for each remote node module (RN # 1, RN # 2, RN # 3 ... RN # N). appear. At this time, if the path difference between the first path line 21 and the second path line is different for each of the far node modules (RN # 1, RN # 2, RN # 3 ... RN # N), the far node module (RN # 1, RN # 2, RN # 3 ... RN # N) can also cause a parallax between optical pulses to appear differently. By examining the height difference and parallax of the optical pulses, it is possible to distinguish which remote pulses are reflected from the remote node modules RN # 1, RN # 2, RN # 3 ... RN # N.

13 and 14 is a configuration using an optical switch to perform a clockwise optical signal transmission and a counter-clockwise optical signal transmission in the system for the identification of the far-field node using the optical time domain reflectometer according to the embodiment of FIG. 11 It is a drawing to show.

Referring to FIGS. 13 and 14, a 2 사용 2 optical switch is used to connect between the ends of the annular network and the laser diode (OTDR LD) and photodiode (Pin-PD) of the optical time domain reflectometer, and between them Parallel or cross-connected measurements can be made from copper to each other and from west to east.

15 is a schematic diagram of an optical path remote node identification system and an element for identification thereof using an optical time domain reflectometer according to another embodiment of the present invention.

The identification element according to the embodiment of FIG. 15 includes a first optical coupler 11 and a second optical coupler 12 which are inserted into the optical path and connected in series, from the optical path in the first optical coupler 11 The branched first path line 21 and the second optical coupler 12 include a second path line 22 branched from the optical path. The first path line 21 is drawn out from an end connected to the second optocoupler 12 of the first optocoupler 11, and the second path line 22 is the first of the second optocoupler 12. It is withdrawn from the end connected to the optocoupler (11). The first path line 21 includes a first dummy line 211 and a first reflective mirror 212, and the second path line 22 includes a second dummy line 221 and a second reflective mirror 222. It includes.

Here, by setting the divergence ratio of the first optocoupler 11 and the divergence ratio of the second optocoupler 12 differently, the height of the pulse conveyed through the first path line 21 and the second path line 22 It can be adjusted so that the height of the pulses conveyed is different from each other. For example, as illustrated in FIG. 15, the first optical coupler 11 has a branching ratio of 99: 1 and the second optical coupler 12 has a branching ratio of 98: 2, and thus the first path line 21 ) And the height of the pulse conveyed through the second path line 22 may be adjusted to be approximately twice as large. The branching ratio of the first optical coupler 11 and the branching ratio of the second optical coupler 12 are set differently for each remote node module (RN # 1, RN # 2, RN # 3 ... RN # N), The difference in height of the pulse peaks carried through the first path line 21 and the second path line 22 is determined for each remote node module (RN # 1, RN # 2, RN # 3 ... RN # N). You can make it different. Alternatively, the reflected light quantity ratios of the two reflective mirrors 212 and 222 may be differently determined for each of the remote node modules (RN # 1, RN # 2, RN # 3 ... RN # N) in which an element for identification is disposed. It is also possible to change the reflected light ratio of the two reflection mirrors 212 and 222 for each remote node module (RN # 1, RN # 2, RN # 3 ... RN # N) in which an element for identification is disposed. This is to make the difference in height of the pulse peaks carried through 21) and the second path line 22 different for each remote node module (RN # 1, RN # 2, RN # 3 ... RN # N). As a method of adjusting the reflected light amount ratio of the two reflective mirrors 212 and 222, there are a method of adjusting the reflectance of the reflective mirror itself and a method of disposing different insertion loss elements in front of the two reflective mirrors 212 and 222.

As described above, a method of making the height of the pulse conveyed through the first path line 21 different from the height of the pulse conveyed through the second path line 22 is as described above, and the branch ratio of the first optocoupler 11. There are a method of setting the divergence ratio of the second optocoupler 12 differently, a method of differently setting the reflected light amount ratio of the two reflection mirrors 212 and 222, and the like, the two methods can be applied together.

The first optical coupler 11 partially branches the optical signal incident from the east to the west (left to right in the figure) through the optical path and sends it to the first path line 21. The second optical coupler 12 partially branches the optical signal incident from the west through the optical path (right to left in the figure) and sends it to the second path line 22. The length of the first dummy line 211 and the length of the second dummy line 221 are set to differ by a predetermined value. The difference between the length of the first dummy line 211 and the length of the second dummy line 221 may be set differently for each remote node module (RN # 1, RN # 2, RN # 3 ... RN # N). have. The first reflection mirror 212 and the second reflection mirror 222 are designed to reflect light in a predetermined wavelength band. This predetermined wavelength band may be located in an area outside the wavelength band of light used for optical communication.

The method of identifying each remote node using the optical path remote node identification system of the structure and the element for identification is similar to that described with reference to FIG. 12 above. That is, the optical time domain reflectometer installed in the telephone station (COT) transmits the measurement optical pulse (OTDR Pulse) twice in the east and west and once in the east. First, the optical pulses for measurement transmitted from each other are branched from the first optical coupler 11 and reflected by the first reflective mirror 212 to return to the optical time domain reflectometer installed in the telephone office (COT). Next, the measurement light pulse transmitted from the west to the east is branched from the second optocoupler 12 and reflected from the second reflection mirror 222 to return to the optical time domain reflectometer installed in the telephone office (COT). When the signals measured twice are synthesized, the height difference of the carrier optical pulses is different for each remote node module (RN # 1, RN # 2, RN # 3 ... RN # N), and the remote node module If the path difference between the first path line 21 and the second path line 22 is set differently for each (RN # 1, RN # 2, RN # 3 ... RN # N), the time difference between the optical pulses is different. appear. By examining the height difference and parallax of the carrier optical pulses, it is possible to distinguish which remote pulses are reflected from the remote node modules RN # 1, RN # 2, RN # 3 ... RN # N.

16 is a schematic diagram of an optical path remote node identification system and an element for identification thereof using an optical time domain reflectometer according to another embodiment of the present invention.

The optical path remote node identification system and the element for identification according to the embodiment of FIG. 16 are compared with the element for identification according to the embodiment of FIG. 15 (the left side of the first optocoupler 11) and the second optocoupler ( The difference is that the left and right dummy lines 31 and 32 are inserted to the west (right) of 12). The left and right dummy lines 31 and 32 are added to prevent crosstalk with an actual reflected pulse generated outside the remote node module, and the lengths of the left and right dummy lines 31 and 32 may be different from each other, but both are first. It is longer than the length from the branched portion of the optocoupler 11 to the first reflective mirror 212, and longer than the length from the branched portion of the second optical coupler 12 to the second reflective mirror 222.

17 is a schematic diagram of an optical path remote node identification system and an element for identification using an optical time domain reflectometer according to another embodiment of the present invention.

In the embodiment of FIG. 17, a third path line 23 is added as compared to the optical time domain reflectometer according to the embodiment of FIG. 5. The third path line 23 includes a third dummy line 231 and a third reflective mirror 232, and the path length of the third path line 23 is the first path line 21 and the second path line It is set differently from (22). The difference in path lengths of the first to third path lines 21, 22 and 23 is determined differently for each remote node module RN # 1, RN # 2, RN # 3 ... RN # N. The branching ratio of the second optocoupler 12 may be determined by an equal ratio (approximately 33:33:33) for the three path lines 21, 22, and 23, or by different ratios. This embodiment includes the first to third route lines 21, 22, and 23, but route lines may be further added as necessary.

FIG. 18 is a diagram illustrating one method of identifying each remote node in the optical path remote node identification system using the optical time domain reflectometer according to the embodiment of FIG. 17.

When the optical time domain reflectometer installed in the telephone station (COT) transmits an optical pulse for identification (OTDR Pulse), the first optical coupler 11 branches off and transmits it to the second optical coupler 12, The second optical coupler 12 divides the optical pulses into three again and transmits them to the first path line 21, the second path line 22, and the third path line 23. The optical pulses incident on the first path line 21, the second path line 22 and the third path line 23 are respectively the first reflection mirror 212, the second reflection mirror 222 and the third reflection mirror It is reflected at 232 and returned to the optical time domain reflectometer via the second optocoupler 12 and the first optocoupler 11. At this time, since there is a difference in the lengths of the first to third path lines 21, 22, and 23, a path difference occurs twice as much as the difference, and a parallax occurs between optical pulses returned to the optical time domain reflectometer. do. As shown in FIG. 18, the parallax between optical pulses reflected and returned from each of the remote node modules RN # 1, RN # 2, RN # 3 ... RN # N appears differently. By examining the parallax of these optical pulses, it is possible to distinguish which remote pulses are reflected from the remote node modules (RN # 1, RN # 2, RN # 3 ... RN # N).

19 is a schematic diagram of an optical path remote node identification system and an element for identification using an optical time domain reflectometer according to another embodiment of the present invention.

The optical path remote node identification system according to the embodiment of FIG. 19 and the element for identification thereof are connected to the first optical coupler 11 and the second optical coupler 12 compared to the identification element according to the embodiment of FIG. 17. Is different. In this embodiment, a branch line comes out from both ends of the first optocoupler 11 and is connected to one end of the second optocoupler 12. The rest of the configuration is almost no different from the identification element according to the embodiment of Fig. 17, and the method of confirming each remote node is the same. However, since branch lines are provided at both ends of the first optical coupler 11, measurement can be performed in any direction of the optical path.

20 is a schematic diagram of an optical path remote node identification system and an element for identification thereof using an optical time domain reflectometer according to another embodiment of the present invention.

The optical path remote node identification system according to the embodiment of FIG. 20 and the element for identification thereof are left and right dummy lines 31 and 32 on the optical paths on both sides of the first optical coupler 11 compared to the identification element according to the embodiment of FIG. 19. ) Is different. The left and right dummy lines 31 and 32 are added to prevent crosstalk with an actual reflection pulse generated outside the remote node module, from the branched portion of the first optocoupler 11 to the first reflection mirror 212. Is longer than the length of the first optocoupler 11 to the second reflection mirror 222, and longer than the length of the first optocoupler 11 to the third reflection mirror 232 Is longer than the length of This embodiment includes the first to third route lines 21, 22, and 23, but route lines may be further added as necessary.

21 is a schematic diagram of an optical path remote node identification system and an element for identification using an optical time domain reflectometer according to another embodiment of the present invention.

The optical path far-field node identification system and the element for identification according to the embodiment of FIG. 21 are added with a third path line 23 compared to the element for identification according to the embodiment of FIG. 11. The third path line 23 includes a third dummy line 231 and a third reflective mirror 232, and the path length of the third path line 23 is the first path line 21 and the second path line It is set differently from (22). The difference in path lengths of the first to third path lines 21, 22 and 23 is determined differently for each remote node module RN # 1, RN # 2, RN # 3 ... RN # N. The ratio of the light diverging to the first to third path lines 21, 22, and 23 by the first optocoupler 11 may be set to the same or may be set at different ratios. For example, as illustrated in FIG. 21, the ratio of the first optocouplers 11 branching to the first to third path lines 21, 22, and 23 may be set to 1%, respectively. This embodiment includes the first to third route lines 21, 22, and 23, but route lines may be further added as necessary. For example, a fourth path line may be added to a portion where the first path line 21 is branched.

A method of identifying each distant node using the optical path distant node identification system and its identification element will be described with reference to FIG. 22. FIG. 22 is a diagram illustrating a method of identifying each remote node in a system for identifying a distant node in an optical path using an optical time domain reflectometer according to the embodiment of FIG. 21.

In this embodiment, the optical time domain reflectometer installed in the telephone station (COT) transmits a measurement optical pulse (OTDR Pulse) twice in the east and west and once in the east. First, the measurement optical pulses transmitted from each other are branched from the first optocoupler 11 to enter the second path line 22 and the third path line 23 to enter the second reflection mirror 222 and the third Each is reflected from the reflection mirror 232 to return to the optical time domain reflectometer installed in the telephone office (COT). Next, the measurement optical pulse transmitted from west to east is branched from the first optocoupler 11, enters the first path line 21, is reflected from the first reflection mirror 212, and is installed in the telephone station (COT). Return to the optical time domain reflectometer. When the signals measured twice are synthesized in this way, as shown in FIG. 22, the path difference set for each remote node module (RN # 1, RN # 2, RN # 3 ... RN # N) The parallax between the optical pulses varies according to. By examining this parallax, it is possible to distinguish which remote pulses are reflected from the remote node modules RN # 1, RN # 2, RN # 3 ... RN # N.

23 is a schematic diagram of an optical path remote node identification system and an element for identification thereof using an optical time domain reflectometer according to another embodiment of the present invention.

The optical time domain reflectometer according to the embodiment of FIG. 23 differs from the embodiment of FIG. 15 in that the third path line 23 and the fourth path line 24 are added. The third path line 23 includes a third dummy line 231 and a third reflective mirror 232, and the fourth path line 24 includes a fourth dummy line 241 and a fourth reflective mirror 242. It includes. At this time, the path lengths of the first to fourth path lines 21, 22, 23, and 24 are set differently. . This embodiment includes the first to fourth path lines 21, 22, 23, and 24, but if necessary, additional path lines may be added, and the third path line 23 or the fourth path line ( 24) may be omitted.

24 is a schematic diagram of an optical path remote node identification system and an element for identification using an optical time domain reflectometer according to another embodiment of the present invention.

The optical path far-field node identification system according to the embodiment of FIG. 24 and the element for identification thereof are compared with the element for identification according to the embodiment of FIG. 23 (east) (left) and second optical coupler (1) of the first optical coupler (11) The difference is that the left and right dummy lines 31 and 32 are inserted to the west (right) of 12). The left and right dummy lines 31 and 32 are added to prevent crosstalk with an actual reflected pulse generated outside the remote node module, and the lengths of the left and right dummy lines 31 and 32 may be different, but both are first. It is longer than the length of the fourth to fourth path lines (21, 22, 23, 24). Although the preferred embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and is defined in the following claims. Various modifications and improvements of those skilled in the art using the basic concept of the present invention are also belonging to the scope of the present invention.

11: first optocoupler 12: second optocoupler
21: first route line 22: second route line
23: third route line 24: fourth route line
211, 221, 231, 31: dummy line 212, 222, 232: reflective mirror

Claims (34)

delete delete Optical path including a plurality of nodes and
And an optical time domain reflectometer for transmitting a measurement optical signal to the optical path and receiving a signal to be conveyed,
The plurality of nodes
A first optical coupler which branches a portion of the optical signal from the optical path, and
By passing the optical signal branched from the first optical coupler through at least two different paths, a path difference is generated between the conveyed optical signals, and a path difference that generates a difference in peak heights of the conveyed optical signals. Including the trigger,
At least one of the difference between the path difference and the peak height of the conveyed optical signals is set differently in the plurality of nodes,
The path difference inducing part
A second optical coupler receiving the optical signal branched from the first optical coupler and dividing the signal into two;
A first path line and a second path line respectively receiving the two optical signals output from the second optical coupler, and
The first reflection mirror and the second reflection mirror respectively provided at the ends of the first path line and the second path line
And, the length of the first path line and the second path line are different from each other, and at least one of the divergent ratio of the reflected light amount between the first reflective mirror and the second reflective mirror is different from the second optical coupler,
The path difference inducing unit is configured to divert the optical path from the first end of the first optical coupler to the first branch line which branches a portion of the optical signal flowing in the first direction and the second end opposite to the first end. Further comprising a second branch line for branching a portion of the optical signal flowing in the direction,
The first branch line and the second branch line are both connected to the first end of the second optocoupler, and the first path line and the second path line are opposite ends of the first end of the second optocoupler. Optical system for distant node identification in two stages.
delete In claim 3,
The wavelength band of the light reflected by the first reflection mirror and the second reflection mirror is located in an area outside the wavelength band of light used for optical communication of the optical path,
And a dummy line inserted into the optical path on at least one side of both sides of the first optocoupler, the length of the dummy line being longer than the first path line and longer than the second path line.
delete delete delete A first optical coupler which branches off a portion of the optical signal from the optical path, and
By conveying the optical signal branched from the first optical coupler through at least two different paths, a path difference is generated between the optical signals carried through the different paths, and the peak height of the conveyed optical signals is It includes a path difference inducing unit that causes a difference,
The path difference inducing part
A second optical coupler receiving the optical signal branched from the first optical coupler and dividing the signal into two;
A first path line and a second path line respectively receiving the two optical signals output from the second optical coupler, and
The first reflection mirror and the second reflection mirror respectively provided at the ends of the first path line and the second path line
Including,
The lengths of the first path line and the second path line are different from each other, and at least one of the ratio of the reflected light amount between the first reflective mirror and the second reflective mirror is different from the branch ratio of the second optical coupler,
The path difference inducing unit is configured to divert the optical path from the first end of the first optical coupler to the first branch line which branches a portion of the optical signal flowing in the first direction and the second end opposite to the first end. Further comprising a second branch line for branching a portion of the optical signal flowing in the direction,
The first branch line and the second branch line are both connected to the first end of the second optocoupler, and the first path line and the second path line are opposite ends of the first end of the second optocoupler. A device connected to the 2nd stage for the identification of long-distance nodes. delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete

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