KR101650031B1 - The optical transmission device with bypass function of monitoring signal - Google Patents

Abstract

The present invention relates to an optical transmission apparatus in which a bypass function of a supervisory signal is implemented, and more particularly to a new concept of efficiently monitoring an optical fiber line in operation without installing a separate supervisory filter on the outside.
Conventionally, the optical transmission device disclosed in the prior art has no function of bypassing the supervisory signal, so that the installation space must be secured in order to use a separate supervisory filter or supervisory filter module, and the loss of surveillance light due to the addition of two optical connection points This causes a problem that the monitoring distance is shortened because the monitoring light is sharply reduced.
In order to solve such a problem, according to the present invention, a first and a second monitoring filter are installed on first and second optical transmission / reception modules installed in an optical transmission box and optical fiber cables connected between first and second transmission / And the first and second monitoring filters are connected to each other via a bypass line.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an optical transmission device having a bypass function of a monitoring signal,

The present invention relates to a novel concept of efficiently monitoring an optical fiber line in operation without installing a separate monitoring filter on the outside.

In general, all wired communication networks are being constructed as fiber optic cable, and all industrial infrastructure facilities are connected with optical communication network and various services are provided, so that the damage caused by optical network interference has a serious economic and social impact.

Optical cable, which is the basic infrastructure of optical communication network, is installed in the form of outdoor processing, underground, bridge, direct sales, etc., and its operation environment is very poor and difficult to manage. Related construction in buried area hinders operability of facility and makes preservation management duties of facility difficult.

In addition, the optical cable is deteriorated due to aging, and it is difficult to stably operate due to changes in mechanical characteristics and optical characteristics, and malfunctions are frequently caused by external physical influences. According to the operation and maintenance analysis of the telecommunication operators, optical cable failure is reported to be more than 90%. Therefore, in order to increase the reliability of the optical fiber network and to ensure stable operation of the optical fiber network, it is possible to monitor the optical fiber network automatically and remotely so as to prevent the breakdown due to aging, to promptly track the failure location, It is necessary to introduce systems that control the operation status of the optical line, such as the efficiency of management work.

In consideration of this situation, a surveillance system for monitoring the operation optical fiber line based on the communication link unit section has been introduced. Prior art related to the operation of the optical fiber surveillance system is disclosed in Patent Registration No. 1030109 entitled " A surveillance system for monitoring an operating optical fiber line in a communication service unit in a communication link unit section "

The above-mentioned line-registration invention provides a useful effect for comprehensively monitoring operating optical fibers in the first and second communication link unit sections of a plurality of sections on a continuous line by using a single optical fiber testing apparatus (OTDR) .

In this prior art, an optical transmission apparatus is provided between a plurality of communication link unit sections. The optical transmission apparatus is a series of apparatuses for converting an electrical signal into an optical signal and transmitting the optical signal. .

In order to transmit a supervisory signal to a neighboring communication link unit section in the course of normal optical communication, the optical transmission apparatus itself does not have a function of bypassing a supervisory signal, Should be used.

However, in order to use the surveillance filter or the surveillance filter module, a separate installation space must be secured. Further, since two optical connection points are additionally generated, the surveillance light loss is large. As a result, the surveillance light is sharply reduced, .

In addition, the cost of the filter case for incorporating the surveillance filter and the installation cost of the surveillance filter are excessively required, and the construction cost of the surveillance system is high.

According to an aspect of the present invention, there is provided an optical fiber transmission system including first and second optical transmission / reception modules installed in an optical transmission box and first and second monitoring filters respectively connected to optical fiber cables connected between first and second transmission / And the first and second monitoring filters are connected to each other via a bypass line.

According to the present invention, since a monitoring filter is integrally provided in an optical transmission apparatus, it is possible to monitor an optical fiber line without the inconvenience of installing a separate monitoring filter on the outside, It reduces the amount of loss and provides the effect of greatly extending the monitoring distance.

Further, there is no need to secure a space for installing the monitoring filter, thereby minimizing the installation space and reducing the installation cost of the monitoring filter and the installation cost of the filter case, thereby reducing the construction cost of the monitoring system.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a plan view of an optical transmission apparatus according to a first embodiment of the present invention;
2 is an enlarged cross-sectional view of the main part of the optical transmission apparatus according to the first embodiment of the present invention
3 is a cross-sectional view of a second embodiment optical transmission apparatus to which the present invention is applied
4 is an enlarged cross-sectional view of a main portion of an optical transmission device according to a second embodiment of the present invention
5 is a cross-sectional view of a third embodiment optical transmission apparatus to which the present invention is applied
Fig. 6 is a plan sectional view of the fourth embodiment optical transmission apparatus to which the present invention is applied
Fig. 7 is an enlarged cross-sectional view of the fourth embodiment of the optical transmission device according to the present invention
8 is a plan view of the fifth embodiment optical transmission apparatus to which the present invention is applied

Preferred embodiments for implementing the solution of the problems to be solved by the present invention will be described in more detail.

1 and 2, the optical transmission apparatus includes an optical transmission box 110, first and second optical T / R modules 120 and 120a, An integrated optical transmission apparatus 100 including a pair of first and second optical transmission and reception ports 130 and 130a, a pair of first and second monitoring filters 140 and 140a, and a bypass line 150 As shown in FIG.

Hereinafter, the present invention having the above-described schematic configuration will be described in more detail for facilitating the implementation.

In the integrated optical transmission device 100, first and second optical transmission / reception modules 120 and 120a are installed in an optical transmission box 110 formed of a rectangular openable and closable housing.

The first and second optical transmission / reception modules 120 and 120a include an optical transmitter 121 for converting an electrical signal into an optical signal, an optical fiber cable 122 for transmitting an optical signal, a light amplifying optical signal A coupler 123 and an optical receiver 124 for converting the transmitted optical signal into an electric signal, and the first and second optical T / R modules 120 and 120a are connected to a control unit 125 and the optical fiber cable 122, thereby making it possible to comprehensively control the optical transmission.

A pair of first and second optical transmission and reception ports 130 and 130a for transmitting and receiving a transmission wavelength Tx and a reception wavelength Rx are formed in one side plate 111 of the optical transmission box 110, And fixedly installed.

The first optical T / R module 120 and the first optical T / R port 130 are connected to each other by an optical fiber cable 122a. The second optical T / R module 120a and the second optical T / The first and second monitoring filters 140 and 140a are connected to the optical fiber cable 122a to separate or multiplex the monitoring signals.

A bypass line 150 is connected between the first monitoring filter 140 and the second monitoring filter 140a to bypass the monitoring signal.

In the present invention having such a configuration, the signal wavelength (Tx, Rx) input through the first optical T / R port 130 and the supervisory wavelength λ m are separated from each other by the first supervisory filter 140, 1 optical transmission / reception module 120, normal communication can be performed in one communication link unit interval.

The supervisory wavelength separated by the first supervisory filter 140 is bypassed to the second supervisory filter 140a through the bypass line 150 and inputted through the second optical transceiver module 120a The signal is multiplexed by the second monitoring filter 140a together with the signal wavelength and then transmitted through the second optical transmission / reception port 130a, so that normal communication and monitoring can be performed simultaneously in the communication link unit interval of the other side.

Accordingly, since the first and second monitoring filters 140 and 140a are integrally provided in the integrated optical transmission apparatus 100, it is possible to monitor the optical path without the need of installing a separate monitoring filter on the outside Provides a special effect that can greatly extend the monitoring distance by dramatically reducing the loss of monitoring light by reducing the number of optical connection points caused by using a separate monitoring filter or one monitoring filter module in the construction of the monitoring system as well as providing the monitoring system. do.

In addition, the optical transmission apparatus of the present invention can be implemented as in the second embodiment as shown in FIGS. 2 to 3. Referring to the overall structure of the optical transmission apparatus,

First and second optical transmission / reception modules 220 and 220a installed inside the optical transmission box 210;

A pair of first and second optical transmission and reception ports 230 and 230a installed through one side plate 211 of the optical transmission box 210;

A pair of first and second optical fiber cables 222a and 222b provided on the optical fiber cable 222a connected between the first and second optical T / R modules 220 and 220a and the first and second optical transmission / reception ports 230 and 230a, Monitoring filters 240 and 240a;

A pair of first and second optical adapters 245 and 245a installed through one side plate 211 of the optical transmission box 210;

A pair of bypass lines 250 connected between the first and second monitoring filters 240 and 240a and the first and second optical adapters 245 and 245a;

And an optical jumper cord 260 connected between the first optical adapter 245 and the second optical adapter 245a.

The integrated optical transmission apparatus 200 according to the second embodiment is different from the integrated optical transmission apparatus 200 according to the first embodiment in that the former consists of a pair of bypass lines 250, The second optical adapter 245 (245a) and the optical jumper cord 260 are additionally configured.

In addition, the optical transmission apparatus of the present invention can be implemented as the third embodiment as shown in FIG. 5. Referring to the overall structure of the optical transmission apparatus,

An optical transmission module 320 and a light reception module 320a installed inside the optical transmission box 310;

A pair of optical transmission ports 330 and a light reception port 330a provided through one side plate 311 of the optical transmission box 310;

A pair of first and second surveillance units 321 and 322 installed on the optical fiber cable 322 connected between the optical transmission module 320 and the optical transmission port 330 and the optical reception module 320a and the optical reception port 330a, Filters 340 and 340a;

A pair of first and second optical adapters 345 and 345a installed through one side plate 311 of the optical transmission box 310;

And a pair of bypass lines 350 connected between the first and second monitoring filters 340 and 340a and the first and second optical adapters 345 and 345a, (300) 300a;

A first optical jumper cord 360 connected between the first optical adapters 345 of the separate optical transmission devices 300 and 300a;

And a second optical jumper cord 360a connected between the second optical adapters 345a of the separate optical transmission devices 300 and 300a.

The optical transmission apparatus according to the third embodiment is unique in that a pair of separate optical transmission devices 300 and 300a are integrally connected to each other via first and second optical jumper cords 260 and 260a.

6 to 7, a pair of detachable monitoring filter modules 400a and 400a having a bypass function are mounted on a pair of detachable optical transmission devices 470 and 470a, The present invention can be implemented in a fourth embodiment in which a connection method can be easily connected.

A pair of optical transmission ports 420 and a light reception port 420a provided through one side plate 411 of the monitoring filter box 410;

A pair of first and second optical connectors 430 and 430a installed through the other side plate 412 of the monitoring filter box 410;

A pair of first and second optical fibers 421 and 422 provided on the optical fiber cable 422 connected between the first optical connector 430 and the optical transmission port 420 and the second optical connector 430a and the optical reception port 420a, 2 monitoring filters 440 and 440a;

A pair of first and second optical adapters 445 and 445a installed through one side plate 411 of the monitoring filter box 410;

A pair of detachable monitoring filters 441 and 442 including a pair of bypass lines 450 connected between the first and second monitoring filters 440 and 440a and the first and second optical adapters 445 and 445a, Module 400 (400a);

A first optical jumper cord 460 connected between the first optical adapter 445 of the detachable supervisory filter module 400 (400a);

A second optical jumper cord 460a connected between the second optical adapter 445a of the separate monitoring filter module 400 (400a);

A pair of optical transmission ports 473 and an optical reception port 474 through which the first and second optical connectors 430 and 430a are respectively coupled are installed through one side plate 472 of the optical transmission box 471 And an optical transmission module 475 and a light reception module 476 are installed in the optical transmission box 471. One side of the optical transmission module 475 and the optical reception module 476 is connected to the optical fiber cable 477, And the other side of the optical transmitting module 475 and the optical receiving module 476 is connected to the control unit 478 through an optical fiber cable 477. [ And a pair of detachable optical transmission devices 470 and 470a each having a configuration that is connected to the optical transmission device.

In addition, the optical transmission apparatus of the present invention can be implemented as a fifth embodiment that can be used only for a PTP (Point To Point) communication network as shown in FIG. 8,

An optical transmission module 520 and a light reception module 520a provided inside the optical transmission box 510;

A pair of optical transmission ports 530 and a light receiving port 530a installed through one side plate 511 of the optical transmission box 510;

A pair of first and second surveillance units 520 and 520 installed on the optical fiber cable 522 connected between the optical transmission module 520 and the optical transmission port 530 and the optical reception module 520a and the optical reception port 530a, Filters 540 and 540a;

And a bypass line 550 connected between the first monitoring filter 540 and the second monitoring filter 540a, as shown in FIG.

The optical transmission apparatus according to the fifth embodiment has a technical feature that the first and second monitoring filters 540 and 540a are incorporated in the PTP network integrated optical transmission apparatus 500 and each optical transmission module 520 And an optical receiving module 520a are separately provided and can be used to loop back the monitoring signal at the terminal end.

100, 200: Integrated optical transmission device
110, 210, 310, 471: optical transmission box
120, 220: a first optical T / R module
120a, 220a: a second optical T / R module
122, 122a, 222a, 322, 422, 477: optical fiber cable
130, and 230: a first optical transmission /
130a, 230a: a second optical transmission /
140, 240, 340, 440, 540: first monitoring filter
140a, 240a, 340a, 440a, 540a:
150, 250, 350, 450, 550: Bypass line
245, 345, 445: a first optical adapter
245a, 345a, and 445a:
260: Optical jumper cord
300, 300a, 470, 470a: Separate optical transmission device
320, 475, 520: optical transmission module
320a, 476, and 520a:
330, 420, 530: optical transmission port
330a, 420a, and 530a:
360, 460: first optical jumper cord
360a, 460a: second optical jumper cord
400, 400a: Detachable monitoring filter module
410: Surveillance filter box
430: first optical connector
430a: second optical connector
500: Integrated optical transmission device for PTP network

Claims (6)

delete delete delete An optical transmission module 320 and a light reception module 320a installed inside the optical transmission box 310;
A pair of optical transmission ports 330 and a light reception port 330a provided through one side plate 311 of the optical transmission box 310;
A pair of first and second surveillance units 321 and 322 installed on the optical fiber cable 322 connected between the optical transmission module 320 and the optical transmission port 330 and the optical reception module 320a and the optical reception port 330a, Filters 340 and 340a;
A pair of first and second optical adapters 345 and 345a installed through one side plate 311 of the optical transmission box 310;
And a pair of bypass lines 350 connected between the first and second monitoring filters 340 and 340a and the first and second optical adapters 345 and 345a, (300) 300a;
A first optical jumper cord 360 connected between the first optical adapters 345 of the separate optical transmission devices 300 and 300a;
And a second optical jumper cord (360a) connected between the second optical adapter (345a) of the separate optical transmission device (300) (300a).
A pair of optical transmission ports 420 and a light reception port 420a provided through one side plate 411 of the monitoring filter box 410;
A pair of first and second optical connectors 430 and 430a installed through the other side plate 412 of the monitoring filter box 410;
A pair of first and second optical fibers 421 and 422 provided on the optical fiber cable 422 connected between the first optical connector 430 and the optical transmission port 420 and the second optical connector 430a and the optical reception port 420a, 2 monitoring filters 440 and 440a;
A pair of first and second optical adapters 445 and 445a installed through one side plate 411 of the monitoring filter box 410;
A pair of detachable monitoring filters 441 and 442 including a pair of bypass lines 450 connected between the first and second monitoring filters 440 and 440a and the first and second optical adapters 445 and 445a, Module 400 (400a);
A first optical jumper cord 460 connected between the first optical adapter 445 of the detachable supervisory filter module 400 (400a);
A second optical jumper cord 460a connected between the second optical adapter 445a of the separate monitoring filter module 400 (400a);
A pair of optical transmission ports 473 and an optical reception port 474 through which the first and second optical connectors 430 and 430a are respectively coupled are installed through one side plate 472 of the optical transmission box 471 And an optical transmission module 475 and a light reception module 476 are installed in the optical transmission box 471. One side of the optical transmission module 475 and the optical reception module 476 is connected to the optical fiber cable 477, And the other side of the optical transmitting module 475 and the optical receiving module 476 is connected to the control unit 478 through an optical fiber cable 477. [ And a pair of detachable optical transmission devices 470 and 470a, which are connected to the optical transmission device.
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