KR101598386B1 - Apparatus for Monitoring Multi-Channel Fiber Line - Google Patents

Abstract

The present invention relates to a multi-channel optical line monitoring apparatus, and more particularly, to a multi-channel optical line monitoring apparatus for monitoring a failure of an optical line by providing a plurality of channels for monitoring a plurality of optical lines constituting an optical line, A unit optical module provided for each of the channels so as to receive the reflected light reflected through the optical path and to convert the received reflected light into an electrical signal; A control module for generating a pulse signal for generating the monitoring light and a control signal for selecting the unit optical module, analyzing an electrical signal of the unit optical module according to a signal processing algorithm, and calculating a result of monitoring the light line; And a switching module for transmitting an electrical signal output from the unit optical module of the selected channel to the control module according to a control signal of the control module. Accordingly, the present invention uses a semi-permanent analog electronic switch for switching the optical path between the OTDR and the optical line, so that the lifetime of the device can be extended compared with the conventional optical switch, Maintenance work such as malfunction is not necessary and operation cost can be reduced and long-term operation stability of the optical line monitoring can be secured.

Description

[0001] Apparatus for Monitoring Multi-Channel Fiber Line [0002]

The present invention relates to a multichannel optical line monitoring apparatus, and more particularly, to a multichannel optical line monitoring apparatus capable of overcoming the limitation of a durability life due to a conventional optical switch by using a switching module capable of measuring optical signals alternately by electrical signals And more particularly, to a multichannel optical line monitoring apparatus.

Optical Time Domain Reflectometer (OTDR) is the most commonly used device to monitor the optical path failure. It is used to detect the fresnel reflections at the break point or the optical fiber inside the optical fiber Rayleigh scattering is detected to measure the failure point or loss characteristics of the optical fiber.

1 is a view for explaining a configuration of an optical line monitoring apparatus according to an embodiment of the related art.

1, since the OTDR 10 is an expensive measuring apparatus, the conventional optical line monitoring apparatus does not use a 1: 1 connection between the optical fiber and the OTDR 10, After the switch 20 is connected, a control signal is applied to the optical switch 20 so that the optical signal of the OTDR 10 is transferred to a desired output channel of the optical switch 20.

As a prior art document related to this, Korean Patent No. 10-0952539 discloses a technique for real-time optical cable failure monitoring apparatus and method.

Conventional real-time optical cable failure monitoring devices and methods are based on the N * N intelligent optical switch technology for securing the soundness of the optical cable that forms the basis of the high-speed information communication network with the OTDR technology, And monitor the level of optical transmission and reception of the unused optical cable according to the program of the operating server.

In addition, Korean Patent No. 10-0717928 discloses a technique of a light line monitoring system using a variable optical fiber tester and a monitoring method thereof.

The optical line monitoring system and the monitoring method thereof using a conventional optical fiber tester include a variable OTDR and an optical switch for switching an optical path for each optical line so that a monitoring light having the same wavelength as the wavelength of the optical signal So that the position of the obstacle of the optical line connected to the subscriber side device can be precisely measured and the position can be displayed on the map.

However, the optical switch used in the conventional optical line monitoring apparatus specifies the switching life span of about 10 million times in the manufacturer. Assuming that one OTDR is connected to a 1 * N optical switch and alternate measurement is performed on a channel-by-channel basis once every 10 seconds, the durability of the optical switch may become problematic after about three years. The durability problem of the optical switch is one of the important factors for determining the lifetime of the optical line monitoring device because the switching period can be further shortened in order to detect the failure of the optical line in real time.

As described above, the optical switch used in the conventional optical line monitoring apparatus has a problem in that durability may be caused due to a limited durability life, so that stability in operating the optical line monitoring is degraded, and the replacement cost of the optical switch is periodically consumed have.

Korean Patent No. 10-0952539 "Real-time optical cable failure monitoring device and method" Korean Patent No. 10-0717928 entitled " Optical Line Monitoring System Using Variable Optical Fiber Tester &

The present invention uses a semi-permanent analog electronic switch for switching the optical path between the OTDR and the optical line, so that the lifetime of the device can be extended as compared with the conventional optical switch, thereby overcoming the limit of durability, The present invention provides a multi-channel optical line monitoring apparatus capable of securing long-term operational stability for the optical line monitoring as the maintenance work of the optical line monitoring apparatus becomes unnecessary.

Among the embodiments, a multichannel optical line monitoring apparatus includes a plurality of channels for monitoring a plurality of optical fiber lines constituting an optical line, thereby monitoring a failure of the optical line. In the multichannel optical line monitoring apparatus, A unit optical module provided for each of the channels so as to receive the reflected light reflected through the optical path and to convert the received reflected light into an electrical signal; A control module for generating a pulse signal for generating the monitoring light and a control signal for selecting the unit optical module, analyzing an electrical signal of the unit optical module according to a signal processing algorithm, and calculating a result of monitoring the light line; And a switching module for transmitting an electrical signal output from the unit optical module of the selected channel to the control module according to a control signal of the control module.

The multi-channel optical line monitoring apparatus further includes a data acquisition module connected to the switching module to convert an electrical signal of the unit optical module into a digital electrical signal based on a predetermined sampling rate and transmit the electrical signal to the control module .

Wherein the unit optical module comprises: a pulse generator for generating and outputting a pulse signal having a signal period and a pulse according to the control signal; An optical output unit for continuously outputting surveillance light according to the pulse signal; A coupler for coupling the monitoring light output from the light output unit to the measurement optical core line and receiving reflected light according to characteristics of the measurement optical center line generated by the monitoring light; A light detecting unit receiving the reflected light received by the coupling unit and measuring the light intensity and converting the measured light intensity into an electrical signal; And an amplifying unit for amplifying and outputting an electric signal inputted from the light detecting unit.

The control module may include a timing controller for generating a pulse signal and generating and outputting a control signal for selecting the unit optical module so as to generate a necessary pulse signal by controlling a phase and a time width according to a measurement environment; And a signal processor for receiving a digital signal from the signal conversion module and performing averaging and analysis according to a signal processing algorithm to calculate an optical line monitoring result value.

Among the embodiments, a multi-channel optical line monitoring apparatus includes a plurality of channels for monitoring a plurality of optical fiber lines constituting an optical line, and monitors a failure of the optical line. In the multi-channel optical line monitoring apparatus, A pulse generation module for generating and outputting a pulse signal having a period and a pulse; A monitoring optical system for generating a monitoring light according to the pulse signal to receive the monitoring light from the optical fiber core among a plurality of optical core wires to receive reflected light reflected through the optical fiber cable and convert the reflected light into an electrical signal, ; A control module for generating a pulse signal for generating the monitoring light and a control signal for selecting the unit optical module, analyzing an electrical signal of the unit optical module according to a signal processing algorithm, and calculating a result of monitoring the light line; And a switching module for transmitting an electrical signal output from the unit optical module of the selected channel to the control module according to a control signal of the control module.

The multi-channel optical line monitoring apparatus further includes a data acquisition module connected to the switching module to convert an electrical signal of the unit optical module into a digital electrical signal based on a predetermined sampling rate and transmit the digital signal to the control module .

The unit optical module may include: a light output unit for continuously outputting monitoring light according to the pulse signal; A coupler for coupling the monitoring light output from the light output unit to the measurement optical core line and receiving reflected light according to characteristics of the measurement optical center line generated by the monitoring light; A light detecting unit receiving the reflected light received by the coupling unit and measuring the light intensity and converting the measured light intensity into an electrical signal; And an amplifying unit for amplifying and outputting an electric signal inputted from the light detecting unit.

Wherein the control module comprises: a timing controller for generating a pulse signal and generating and outputting a control signal for selecting the unit optical module so as to generate a required pulse signal by controlling a phase and a time width according to a measurement environment; And a signal processor for receiving a digital signal from the signal conversion module and performing averaging and analysis according to a signal processing algorithm to calculate an optical line monitoring result value.

Among the embodiments, a multi-channel optical line monitoring apparatus includes a plurality of channels for monitoring a plurality of optical fiber lines constituting an optical line, and monitors a failure of the optical line. In the multi-channel optical line monitoring apparatus, A pulse generation module for generating and outputting a pulse signal having a period and a pulse; An optical output module for continuously outputting surveillance light according to the pulse signal; An optical distribution module for distributing and inputting monitoring light output from the optical output module; A unit optical module provided for each of the plurality of optical fiber lines, for each of the plurality of optical fiber lines, for receiving the reflected light reflected by the optical fiber line and converting the received optical signal into an electrical signal; A control module for generating a pulse signal for generating the monitoring light and a control signal for selecting the unit optical module, analyzing an electrical signal of the unit optical module according to a signal processing algorithm, and calculating a result of monitoring the light line; And a switching module for transmitting an electrical signal output from the unit optical module of the selected channel to the control module according to a control signal of the control module.

The multi-channel optical line monitoring apparatus further includes a data acquisition module connected to the switching module to convert an electrical signal of the unit optical module into a digital electrical signal based on a predetermined sampling rate and transmit the electrical signal to the control module .

Wherein the unit optical module comprises: a coupling unit coupling the monitoring light, which is distributed and inputted from the optical distribution module, to the measurement optical core line and receiving reflected light according to the characteristic of the measurement optical center line generated by the monitoring light; A light detecting unit receiving the reflected light received by the coupling unit and measuring the light intensity and converting the measured light intensity into an electrical signal; And an amplifying unit for amplifying and outputting an electric signal inputted from the light detecting unit.

Wherein the control module comprises: a timing controller for generating a pulse signal and generating and outputting a control signal for selecting the unit optical module so as to generate a required pulse signal by controlling a phase and a time width according to a measurement environment; And a signal processor for receiving a digital signal from the signal conversion module and performing averaging and analysis according to a signal processing algorithm to calculate an optical line monitoring result value.

The multichannel optical line monitoring apparatus of the present invention can overcome the limitation of the durability life by extending the lifetime of the device compared with the conventional optical switch by using semi-permanent analog electronic switch for switching the optical path between the OTDR and the optical line It is possible to reduce the operation cost as well as to secure the stability of long-term operation of the optical line monitoring because maintenance work such as switch replacement or switch malfunction is not necessary.

1 is a view for explaining a configuration of an optical line monitoring apparatus according to an embodiment of the related art.
2 is a view for explaining a configuration of a multi-channel optical line monitoring apparatus according to a first embodiment of the present invention.
3 is a view for explaining a configuration of a multi-channel optical line monitoring apparatus according to a second embodiment of the present invention.
4 is a view for explaining a configuration of a multi-channel optical line monitoring apparatus according to a third embodiment of the present invention.

The description of the present invention is merely an example for structural or functional explanation, and the scope of the present invention should not be construed as being limited by the embodiments described in the text. That is, the embodiments are to be construed as being variously embodied and having various forms, so that the scope of the present invention should be understood to include equivalents capable of realizing technical ideas. Also, the purpose or effect of the present invention should not be construed as limiting the scope of the present invention, since it does not mean that a specific embodiment should include all or only such effect.

Meanwhile, the meaning of the terms described in the present invention should be understood as follows.

The terms "first "," second ", and the like are intended to distinguish one element from another, and the scope of the right should not be limited by these terms. For example, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component.

It is to be understood that when an element is referred to as being "connected" to another element, it may be directly connected to the other element, but there may be other elements in between. On the other hand, when an element is referred to as being "directly connected" to another element, it should be understood that there are no other elements in between. On the other hand, other expressions that describe the relationship between components, such as "between" and "between" or "neighboring to" and "directly adjacent to" should be interpreted as well.

It should be understood that the singular " include "or" have "are to be construed as including a stated feature, number, step, operation, component, It is to be understood that the combination is intended to specify that it does not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

All terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined. Commonly used predefined terms should be interpreted to be consistent with the meanings in the context of the related art and can not be interpreted as having ideal or overly formal meaning unless explicitly defined in the present invention.

2 is a view for explaining a configuration of a multi-channel optical line monitoring apparatus according to a first embodiment of the present invention.

2, the multi-channel optical line monitoring apparatus 100 includes a plurality of channels for monitoring a plurality of optical fiber lines constituting the optical line, and monitors a failure of the optical line. The multi-channel optical line monitoring apparatus 100 includes a unit optical module 110, a control module 120 ), A switching module 130, and a data acquisition module 140.

The unit optical module 110 is provided for each channel so that the monitoring light is incident on the measuring optical core among a plurality of optical core lines, receives the reflected light reflected through the optical path, and converts the reflected light into an electrical signal.

The unit optical module 110 includes a pulse generating unit 111, an optical output unit 112, a coupling unit 113, a photodetector 114, and an amplification unit 115.

The pulse generating unit 111 generates a pulse signal having a signal period and a pulse according to a control signal, and outputs the pulse signal to the optical output unit 112.

The optical output unit 112 continuously outputs the monitoring light, which is pulse light, to the coupling unit 113 according to the pulse signal of the pulse generation unit 111. The optical output section 112 can use a laser diode.

The coupling unit 113 receives the monitoring light output from the optical output unit 112 and couples the monitoring light to the measurement optical core line, and receives the reflected light according to the characteristic of the measuring optical center line generated by the monitoring light.

The light detecting unit 114 receives the reflected light received by the coupling unit 113 and measures the light intensity, converts the measured light intensity into an electrical signal, and outputs the electrical signal to the amplifying unit 115.

The amplifying unit 115 amplifies the electric signal input from the optical detecting unit 114 to a waveform suitable for identifying the distorted waveform of the electrical signal and outputs the amplified signal to the switching module 130 do.

The control module 120 generates a control signal for generating a pulse signal for generating the monitoring light and selecting the unit optical module 110 and outputs the electrical signal of the unit optical module 110 selected by the control signal to the signal processing algorithm And then calculates the result of the optical line monitoring. The control module 120 includes a timing controller 121 and a signal processor 122.

The timing controller 121 controls the phase and the time width according to the measurement environment to generate a control signal for generating a pulse signal so that a necessary pulse signal is generated and outputs the control signal to the pulse generator 111, And generates a control signal for selection and outputs it to the switching module 130.

The signal processing unit 122 receives the electrical signals of the unit optical module 110 in a digital form, performs averaging and analysis according to the signal processing algorithm, and calculates the outcome of the optical line monitoring.

The control module 120 may output a setting signal to the data acquisition module 140 to set the initialization of the device, the voltage range, the sampling rate, and the data length, and may include a representation and output of the analyzed data, Storage function can be performed.

The switching module 130 transmits an electrical signal output from the unit optical module 110 of the selected channel to the data acquisition module 140 according to the control signal of the control module 120. The switching module 130 may be an analog electronic switch that performs a switching operation with an electrical signal.

The data acquisition module 140 is connected to the switching module 130 and converts the electrical signal of the unit optical module 110 into an analog / digital signal based on a predetermined sampling rate and transmits the analog signal to the control module 120 as a digital signal. The data acquisition module 140 is located between the control module 120 and the switching module 130, but may be embedded in the control module 120 in some cases.

3 is a view for explaining a configuration of a multi-channel optical line monitoring apparatus according to a second embodiment of the present invention. Hereinafter, the multi-channel optical line monitoring apparatus according to the second embodiment of the present invention will be described with reference to FIG.

Channel optical line monitoring apparatus 200 according to the second embodiment of the present invention includes a pulse generating module 210, a unit optical module 220, a control module 230, a switching module 240, and a data acquisition module 250 ). Accordingly, each unit optical module 220 uses the pulse generation module 210 in common.

That is, the control module 230 outputs a control signal for pulse signal generation to the pulse generation module 210, and the pulse generation module 210 generates a pulse signal having a signal cycle and a pulse according to the control signal, And outputs it to the unit optical module 220.

The unit optical module 220 includes an optical output unit 221, a coupling unit 222, a photodetector unit 223, and an amplification unit 224.

Therefore, the unit optical module 220 generates the monitoring light in the optical output unit 221 according to the pulse signal, and the monitoring light output from the optical output unit 221 in the coupling unit 222 is incident, And receives the reflected light according to the characteristic of the measuring optical center line generated by the monitoring light.

The optical detecting unit 223 receives the reflected light received by the coupling unit 222 and measures the light intensity and converts the measured light intensity into an electrical signal and outputs the electrical signal to the amplifying unit 224. The amplifying unit 224 amplifies the light Amplifies the electrical signal received from the detector 223, and outputs the amplified electrical signal to the switching module 240.

4 is a view for explaining a configuration of a multi-channel optical line monitoring apparatus according to a third embodiment of the present invention. Hereinafter, the multi-channel optical line monitoring apparatus according to the third embodiment of the present invention will be described with reference to FIG.

The multi-channel optical line monitoring apparatus 300 according to the third embodiment of the present invention includes a pulse generating module 310, an optical output module 320, an optical distribution module 330, a unit optical module 340, A switching module 360, and a data acquisition module 370. At this time, the unit optical module 340 provided for each channel includes a coupling portion 341, a light detecting portion 342, and an amplifying portion 343.

The pulse generation module 310 generates a pulse signal having a signal cycle and a pulse according to the control signal of the control module 350 and outputs the pulse signal to the optical output module 320.

The optical output module 320 continuously outputs the monitoring light according to the pulse signal to the optical distribution module. The optical distribution module 330 distributes the monitoring light output from the optical output module 320, And enters the module 340.

Accordingly, in the coupling part 341 of the unit optical module 340, the monitoring light distributed and inputted from the optical distribution module 330 is coupled to the measurement optical core line, and the reflected light according to the characteristic of the measurement optical center line generated by the monitoring light Lt; / RTI >

The optical detection unit 342 receives the reflected light received by the coupling unit 341 and converts the received electrical signal into an electrical signal and outputs the electrical signal to the amplification unit 343. The amplification unit 343 amplifies the electrical signal received from the optical detection unit 342 And outputs the amplified signal to the switching module 360.

Accordingly, the per-channel unit optical module 340 can share the surveillance light using the pulse generation module 310, the optical detection module 320, and the optical distribution module 330.

As described above, in the multi-channel optical line monitoring apparatus according to the first to third embodiments of the present invention, instead of an optical switch for applying a digital control signal, an analog electronic switch and a switching module (130, 240, 360). Accordingly, in the conventional relays based mechanical optical switch, there is a problem in durability during use due to a short lifetime. However, since the switching modules 130, 240 and 360 perform a switching operation with a semi-permanent electrical signal, Can be overcome.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the present invention as defined by the following claims It can be understood that

100, 200, 300: Multi-channel optical line monitoring system
110, 220, 340: unit optical module
120, 230, 350: control module
130, 240, 360: switching module
140, 250, 370: data acquisition module

Claims (12)

A multichannel optical line monitoring apparatus for monitoring a failure of an optical line by providing a plurality of channels for monitoring a plurality of optical fiber lines constituting an optical line,
A unit optical module provided in each of the plurality of optical fiber lines, for each of the plurality of optical fiber cables, for each of the plurality of optical fiber cables to receive the reflected light reflected from the optical fiber line,
A control module for generating a pulse signal for generating the monitoring light and a control signal for selecting the unit optical module, analyzing an electrical signal of the unit optical module according to a signal processing algorithm, and calculating a result of monitoring the light line; And
And a data acquisition module connected to the switching module to convert an electrical signal of the unit optical module into a digital electrical signal based on a predetermined sampling rate and transmit the electrical signal to the control module,
Wherein the unit optical module includes a pulse generator for generating and outputting a pulse signal having a signal period and a pulse according to the control signal.
delete The method according to claim 1,
The unit optical module
An optical output unit for continuously outputting surveillance light according to the pulse signal;
A coupler for coupling the monitoring light output from the light output unit to the measurement optical core line and receiving reflected light according to characteristics of the measurement optical center line generated by the monitoring light;
A light detecting unit receiving the reflected light received by the coupling unit and measuring the light intensity and converting the measured light intensity into an electrical signal; And
And an amplifying unit for amplifying and outputting an electric signal inputted from the light detecting unit.
The method according to claim 1,
The control module includes:
A timing controller for generating a pulse signal and generating and outputting a control signal for selecting the unit optical module so as to generate a necessary pulse signal by controlling a phase and a time width according to a measurement environment; And
And a signal processor for receiving a digital electrical signal from the signal conversion module and performing averaging and analysis according to a signal processing algorithm to calculate an optical line monitoring result value.
A multichannel optical line monitoring apparatus for monitoring a failure of an optical line by providing a plurality of channels for monitoring a plurality of optical fiber lines constituting an optical line,
A pulse generation module for generating and outputting a pulse signal having a signal period and a pulse according to a control signal;
A monitoring optical system for generating a monitoring light according to the pulse signal to receive the monitoring light from the optical fiber core among a plurality of optical core wires to receive reflected light reflected through the optical fiber cable and convert the reflected light into an electrical signal, ;
A control module for generating a pulse signal for generating the monitoring light and a control signal for selecting the unit optical module, analyzing an electrical signal of the unit optical module according to a signal processing algorithm, and calculating a result of monitoring the light line;
A switching module for transmitting an electrical signal output from the unit optical module of the selected channel to the control module according to a control signal of the control module; And
And a data acquisition module connected to the switching module to convert an electrical signal of the unit optical module into a digital electrical signal based on a predetermined sampling rate and transmit the electrical signal to the control module. As a monitoring device.
delete 6. The method of claim 5,
The unit optical module includes:
An optical output unit for continuously outputting surveillance light according to the pulse signal;
A coupler for coupling the monitoring light output from the light output unit to the measurement optical core line and receiving reflected light according to characteristics of the measurement optical center line generated by the monitoring light;
A light detecting unit receiving the reflected light received by the coupling unit and measuring the light intensity and converting the measured light intensity into an electrical signal; And
And an amplifying unit for amplifying and outputting an electric signal inputted from the light detecting unit.
6. The method of claim 5,
The control module includes:
A timing controller for generating a pulse signal and generating and outputting a control signal for selecting the unit optical module so as to generate a necessary pulse signal by controlling a phase and a time width according to a measurement environment; And
And a signal processor for receiving a digital electrical signal from the signal conversion module and performing averaging and analysis according to a signal processing algorithm to calculate an optical line monitoring result value.
A multichannel optical line monitoring apparatus for monitoring a failure of an optical line by providing a plurality of channels for monitoring a plurality of optical fiber lines constituting an optical line,
A pulse generation module for generating and outputting a pulse signal having a signal period and a pulse according to a control signal;
An optical output module for continuously outputting surveillance light according to the pulse signal;
An optical distribution module for distributing and inputting monitoring light output from the optical output module;
A unit optical module provided for each of the plurality of optical fiber lines, for each of the plurality of optical fiber lines, for receiving the reflected light reflected by the optical fiber line and converting the received optical signal into an electrical signal;
A control module for generating a pulse signal for generating the monitoring light and a control signal for selecting the unit optical module, analyzing an electrical signal of the unit optical module according to a signal processing algorithm, and calculating a result of monitoring the light line;
A switching module for transmitting an electrical signal output from the unit optical module of the selected channel to the control module according to a control signal of the control module; And
And a data acquisition module connected to the switching module to convert an electrical signal of the unit optical module into a digital electrical signal based on a predetermined sampling rate and transmit the electrical signal to the control module. As a monitoring device.
delete 10. The method of claim 9,
The unit optical module includes:
A coupler coupling the monitoring light distributed and inputted from the optical distribution module to the measurement optical core line and receiving reflected light according to a characteristic of a measurement optical center line generated by the monitoring light;
A light detecting unit receiving the reflected light received by the coupling unit and measuring the light intensity and converting the measured light intensity into an electrical signal; And
And an amplifying unit for amplifying and outputting an electric signal inputted from the light detecting unit.
10. The method of claim 9,
The control module includes:
A timing controller for generating a pulse signal and generating and outputting a control signal for selecting the unit optical module so as to generate a necessary pulse signal by controlling a phase and a time width according to a measurement environment; And
And a signal processor for receiving a digital electrical signal from the signal conversion module and performing averaging and analysis according to a signal processing algorithm to calculate an optical line monitoring result value.

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