KR20180098718A - Optical time domain reflectometer for divided optical fiber monitering on optical termination box - Google Patents

Abstract

An object of the present invention is to provide an OTDR-based optical line monitoring system. According to the present invention, an optical line diagnosis device including an OTDR is used for real-time monitoring of the state and normality of the optical line. In the event of malfunction, the malfunction analysis content is transmitted to a server via an IOT network and from the server to a worker′s mobile for quick recovery. The present invention relates to an OTDR-based optical line monitoring system including an optical line diagnosis device (100) including a WDM (10) connected to an optical line (400) connecting an optical line starting portion (200) and an optical line terminal portion (300), an abnormality diagnosis unit (20) checking state information of the optical line (400) by analyzing an optical signal of the optical line (400) received through the WDM (10), an abnormal position diagnosis unit (30) discriminating an abnormal section or an abnormal point of the optical line (400) by analyzing reflected light reflected after irradiation of the optical line (400) with light when the state information is abnormality diagnosis information of the optical line (400), and a wireless communication unit (40) transmitting to the outside the state information of the optical line and the abnormal section or abnormal point information; a server (500) monitoring the state of the optical line by receiving the state information of the optical line and the abnormal section or abnormal point information; and a mobile (600) receiving in real time the state of the optical line from the server (500).

Description

[0001] OPTICAL TIME DOMAIN REFLECTOMETER FOR DIVIDED OPTICAL FIBER MONITORING OPTICAL TERMINATION BOX [0002]

The present invention relates to an optical line monitoring system, and more particularly, to a system for centrally controlling an optical line by performing a failure analysis of a plurality of optical cables to be measured and transmitting analysis contents to a server through an IOT network will be.

Recently, a variety of communication devices have been developed and used, the number of Internet users has increased, and data traffic has increased exponentially with the advent of new multimedia services. As a result, the entire network is evolving to send and receive large amounts of data.

In particular, the amount of traffic in the city's internal network is increasing due to the explosion of the Internet, intranet, and extranet in urban areas, and optical communication technology is being used as a technology for traffic reduction due to the surge in data transmission.

As an optical communication technique using an optical fiber, there is a WDM (Wavelength Division Multiplexing) method.

WDM is a system for simultaneously transmitting a plurality of channels through one optical line using light of different wavelengths. In a wavelength division-multiplexing (WDM) optical communication system, And transmits and receives light having different wavelengths.

In order to maintain and repair such a WDM optical transmission system, it is necessary to be able to easily measure a failure section for each channel of an optical path in the field, and an OTDR (Optical Time-Domain Reflectometer) is used as a means for checking the communication state of the optical fiber have,

The OTDR uses a pulse as a signal to cause a pulse of light to enter a fiber under measurement to detect fresnel reflections at a break point or rayleigh scattering in an optical fiber, Or the loss characteristics of the < / RTI >

However, the conventional OTDR is integrated with all the functions of the optical measuring instrument, such as the driving, signal processing and analysis functions, and has limitations in cost reduction, size and weight reduction. In addition, since the meter needs to have an OTDR for each wavelength band, if the wavelength band to be measured is increased, the specifications of the OTDR are increased accordingly, so that the replacement cost of the meter is increased and the size becomes large and is not suitable for portable use .

On the other hand, the optical terminal box is used for connecting, branching and arranging optical fibers, and is usually fixed to a main body or an indoor / outdoor wall, and an optical adapter, a connector and a cable are built in. , Connection protection function and input / output function.

That is, the optical fiber cabinet is one of the subscriber terminal devices that performs the connection and distribution function between the external optical line and the subscriber transmission device. The optical fiber in the optical cable is connected to the optical fiber of the optical fiber cord (or optical splitter) The optical fiber is distributed to the optical network unit, the optical fiber is distributed to the long-haul optical line terminal by optical connection after the remaining optical fibers are distributed.

In the optical terminal box, as described above, a plurality of subscribers are distributed to one optical cable, and each of the distributed optical cables should be monitored in real time for quality assurance.

1. Korean Patent No. 10-0492193 2. Korean Patent No. 10-1587091

The object of the present invention is to provide a system and method for monitoring the status of an optical line in real time using an optical line diagnostic apparatus including an OTDR, The present invention provides an optical line monitoring system using an OTDR.

In order to achieve the above object, an optical line monitoring system using an OTDR according to the present invention includes a WDM 10 connected to a light path 400 connecting a light path starting portion 200 and a light path terminating portion 300, An abnormality diagnosis unit 20 for analyzing the optical signal of the optical path 400 received through the WDM 10 and checking status information of the optical path 400, An abnormal position diagnosis unit 30 for irradiating light to the light path 400 and then analyzing the reflected light reflected from the light path 400 to determine an abnormal region or an abnormal region of the light path 400; And a wireless communication unit (40) for transmitting the abnormal point information to the outside; A server 500 for receiving status information of the optical line and an abnormal section or abnormal point information to monitor the status of the optical line; And a mobile 600 for receiving the state of the optical line from the server 500 in real time.

The abnormality diagnosis unit 20 may include an optical coupler 21 and an optical power meter 22. The abnormal position diagnosis unit 30 may include an OTDR 31 and a control module 32.

The optical coupler 21 transmits part of the input light received from the WDM 10 to the optical power meter 22 and the optical power meter 22 converts the level of the light inputted from the optical coupler 21 And transmits the obtained status information to the control module 32. If the status information is the abnormality diagnosis information of the optical line, the control module 32 transmits the status information of the corresponding optical path through the OTDR 31 It may be to determine a section or an abnormal point.

In addition, the mobile station 600 may transmit the repair information to the server 500 from the server 500 regarding the abnormal section of the optical path or abnormal point information.

At this time, the server 500 may provide the mobile 600 with repair information corresponding to the abnormal section or abnormal point information of the optical path occurring after the repair information.

In addition, the optical line diagnostic apparatus 100 may further include a display unit 60 for displaying whether the optical line is normal or not.

The optical line monitoring system using the OTDR according to the present invention effectively monitors a plurality of subscriber optical lines to provide a stable quality communication service.

In addition, the server obtains normal signal data for each optical line, and status information for each optical line can be confirmed through the IOT network. Thus, the failure analysis can be performed by comparing and analyzing the status information and the normal signal data, It is easy to monitor and maintain the optical line.

In addition, when a fault occurs in the optical line, the optical line can be discriminated without performing the on-site inspection.

1 is a block diagram of an optical line monitoring system using an OTDR according to a preferred embodiment of the present invention;
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an optical line monitoring system using an OTDR, and more particularly,

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention.

Like reference numerals are used for like elements in describing each drawing. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

For example, without departing from the scope of the present invention, 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.

And / or < / RTI > includes any combination of a plurality of related listed items or any of a plurality of related listed items.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, .

On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

Terms such as those defined in commonly used dictionaries are to be interpreted as having a meaning consistent with the contextual meaning of the related art and are to be interpreted as either ideal or overly formal in the sense of the present application Do not.

The optical line monitoring system using the OTDR according to the present invention can provide a stable quality communication service by effectively monitoring a plurality of subscriber optical lines and can include the following configuration.

That is, the WDM 10 connected to the optical line 400 connecting the optical line start part 200 and the optical line termination part 300 analyzes the optical signal of the optical line 400 received through the WDM 10, An error diagnosis unit 20 for checking the status information of the optical path 400 and analyzing the reflected light after irradiating the light path 400 with light if the status information is the abnormality diagnosis information of the optical path 400, An abnormal position diagnosis unit 30 for discriminating an abnormal region or an abnormal region of the optical path 400, a wireless communication unit 40 for transmitting the state information of the optical path and the abnormal region or abnormal point information to the outside, An apparatus 100;

A server 500 for receiving status information of the optical line and an abnormal section or abnormal point information to monitor the status of the optical line; And

And a mobile 600 that receives the state of the optical line from the server 500 in real time.

The abnormality diagnosis unit 20 includes an optical coupler 21 and an optical power meter 22. The abnormality diagnosis unit 30 includes an OTDR 31 and a control module 32, The coupler 21 transmits part of the input light received from the WDM 10 to the optical power meter 22 and the optical power meter 22 measures the level of the light inputted from the optical coupler 21 The control module 32 transmits the status information obtained by comparing with the previously stored light level to the control module 32. If the status information is abnormal diagnosis information of the optical line, It may be to determine the abnormal point.

In addition, the mobile 600 transmits repair information for an abnormal section or abnormal point information of the optical line to the server 500 from the server 500, and the server 500 transmits repair information of the optical line after the repair information And provides repair information of the corresponding optical line to the mobile 600 when the abnormal section or abnormal point information is received.

In addition, the optical line diagnostic apparatus 100 may further include a display unit 60 for indicating whether the optical line is normal or not.

Hereinafter, an optical line monitoring system using an OTDR according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings 1 and 2.

The optical line monitoring system using the OTDR includes the optical line diagnostic apparatus 100, the server 500, and the mobile 600.

The optical path diagnosing apparatus 100 includes a WDM 10 connected to a light path 400 connecting a light path starting portion 200 and a light path terminating portion 300 and a light path 400 An error diagnosis unit 20 for analyzing the optical signal of the optical path 400 to check the status information of the optical path 400, and if the status information is abnormal diagnosis information of the optical path 400, And a wireless communication unit 40 for analyzing the reflected light and transmitting the status information of the optical line and the abnormal section or abnormal point information to the outside.

The optical line start unit 200 may include an optical network unit (ONU) installed on the subscriber side and the optical line termination unit 300 may include an optical line terminal (OLT) located inside the communication company. In addition, the optical line termination 300 may be a photonic box, a central station, a base station, etc., and the examples of the optical line start portion 200 and the optical line termination portion 300 may be reversed.

Point-to-multipoint communication can be performed by the optical splitter or the data multiplexer in the OLT and the ONU. The signal light emitted from the OLT reaches the optical splitter or data multiplexer via the trunk optical line, To the subscriber.

The light ray diagnostic apparatus 100 may be installed at the light end 300 as shown in FIG. 1 to monitor the light path 400 that is drawn into the light end 300 from the light source 200 .

The optical path diagnosis apparatus 100 includes a WDM 10, an abnormality diagnosis unit 20, an abnormal position diagnosis unit 30, and a wireless communication unit 40.

The abnormality diagnosis unit 20 includes an optical coupler 21 and an optical power meter 22. The abnormality diagnosis unit 20 analyzes the optical signal of the optical path 400 received through the WDM 10, Can be checked.

The abnormality diagnosis unit 20 transmits part of the input light received from the WDM 10 to the optical power meter 22 by the optical coupler 21 and the optical power meter 22 is connected to the optical coupler 21 by measuring the level of the light inputted from the light source 21 and comparing it with the light level stored in advance. To this end, the optical power meter 22 measures the optical power sensed through the optical coupler 21 and transmits the measured optical power to the control module 32. The sensor unit 22a converts light energy into electrical energy, And a conversion unit 22b for amplifying the converted electrical energy and transmitting the amplified electrical energy to the control module 32. [ The optical power meter 22 may be a light-current conversion type cathode ray tube, a light-current conversion type semiconductor, and a light-to-heat conversion type depending on the type of sensor. A small Ge photodiode can be used.

The abnormality diagnosis unit 30 includes an OTDR 31 and a control module 32. When the status information indicates abnormality diagnosis information of the optical path 400, the optical path diagnosis unit 30 irradiates the light path 400 with light, The abnormal section or abnormal point of the optical path 400 can be identified.

When it is determined that the status information received through the optical power meter 22 is the abnormality diagnosis information, the abnormality position diagnosis unit 30 determines an abnormal section or an abnormal point of the corresponding optical path through the OTDR 31.

The OTDR 31 performs the same function as a normal OTDR and performs a function of measuring the optical characteristics of the optical path 400 under the control of the control module 32.

The wireless communication unit 40 is an IoT communication module for transmitting the status information of the optical line and the abnormal section or abnormal point information to the outside, and may be, for example, a long range wide area network (LoRa).

The optical line diagnostic apparatus 100 includes a display unit 50 that is connected to the optical line diagnostic apparatus 100 including a function of determining whether the optical line 400 is normal or not, ).

The display unit 50 can identify the presence or absence of the light path 400 in real time in the field.

Meanwhile, the server 500 can monitor the status of the optical line by receiving the status information of the optical line 400 and the abnormal section or abnormal point information, and the mobile 600 can monitor the status of the optical line from the server 500 It can receive in real time.

The server 500 may store normal signal data for the optical path 400. And the control module 32 may transmit the received optical line status information to the server 500. [ Therefore, when a failure occurs in the optical line, the server 500 can perform comparative analysis and can determine whether the optical line is normal or not, so that the optical line can be monitored and managed.

In addition, since the mobile terminal 600 can receive the normal presence / absence from the server 500 in real time, the operator can confirm whether or not the optical path is abnormal without having the OTDR, Can be performed quickly. For example, when an obstacle occurs in one of the optical lines, the server 500 that monitors in real time which optical line is the optical line of the optical line can inform the mobile of the operator. Thus, (500), so that it is possible to promptly carry out the trouble repair work.

In addition, since the means for determining whether the optical path is normal can be replaced by the server 500 in the control module 32, the specification of the OTDR installed in the optical path termination 300 can be lowered, It is possible to reduce the installation cost of the OTDR to be installed in the portable terminal 300.

Hereinafter, the operation of the optical line monitoring system using the OTDR according to the present invention will be described.

The abnormality diagnosis unit 20 analyzes the optical signal of the optical line 400 received through the WDM 10 to check the state information of the optical line 400. [ In other words, it monitors the optical line.

Specifically, the optical coupler 21 transmits part of the input light received from the WDM 10 to the optical power meter 22, and the optical power meter 22 measures the level of the light input from the optical coupler 21 And then observes the optical line by comparing it with a previously stored light level.

When the abnormality diagnosis is confirmed after the optical line monitoring, the abnormality diagnosis information included in the state information of the optical line is transmitted to the abnormality position diagnosis unit 30 in order to acquire the abnormality position information of the optical line, and the OTDR 31 and the control module 32 Analyzes the reflected light after irradiating light to the light path 400 and discriminates an abnormal section or an abnormal point of the light path 400. [

When the abnormal region, that is, the abnormal position information of the optical line is obtained, this information and the optical path state information are transmitted to the server 500 through the wireless communication unit 40, and the server 500 stores the received information, do. At this time, the display unit 50 may be displayed to identify the abnormal ray.

The server 500 monitors the status of the optical line by receiving the status information of the optical line 400 and the abnormal section or abnormal point information and the mobile 600 receives the status of the optical line from the server 500 in real time .

Meanwhile, the mobile station 600 transmits repair information to the server 500 regarding the abnormal section or abnormal point information of the optical line from the server 500, and the server 500 detects the abnormality of the optical path occurring after the repair information It is possible to provide the mobile 600 with repair information of the corresponding optical line when receiving the section or abnormal point information. Here, the repair information may be a repair work type, a repair work time, a repair result, a worker, and the like. In the server 500, when receiving an abnormal section or abnormal point information of the same optical line, To the mobile (600), it is possible to improve the efficiency of the repair work.

It will be apparent to those skilled in the relevant art that various modifications, additions and substitutions are possible, without departing from the spirit and scope of the invention as defined by the appended claims. The appended claims are to be considered as falling within the scope of the following claims.

20: abnormality diagnosis section
30: abnormality position diagnosis section
40:
100: Optical path diagnostics
500: Server
600: Mobile

Claims (4)

A WDM 10 connected to a light path 400 connecting a light path starting portion 200 and a light path terminating portion 300,
An abnormality diagnosis unit 20 for analyzing the optical signal of the optical path 400 received through the WDM 10 and checking status information of the optical path 400,
An abnormal position diagnosis unit for analyzing the reflected light after irradiating light to the light path 400 and determining an abnormal region or an abnormal point of the light path 400 if the state information is abnormal diagnosis information of the light path 400 30),
And a wireless communication unit (40) for transmitting status information of the optical line and an abnormal section or abnormal point information to the outside;
A server 500 for receiving status information of the optical line and an abnormal section or abnormal point information to monitor the status of the optical line; And
A mobile (600) for receiving the state of the optical line from the server (500) in real time;
Optical line monitoring system using OTDR.
The method according to claim 1,
The abnormality diagnosis unit 20 includes an optical coupler 21 and an optical power meter 22,
The abnormal position diagnosis unit 30 includes an OTDR 31 and a control module 32,
The optical coupler 21 transmits part of input light received from the WDM 10 to the optical power meter 22,
The optical power meter 22 measures the level of light input from the optical coupler 21, compares the level of the light with a previously stored light level, and transmits the obtained status information to the control module 32,
Wherein the control module (32) determines an abnormal section or an abnormal point of the optical path through the OTDR (31) if the status information is optical path diagnostic information of the optical path.
The method according to claim 1,
The mobile 600 transmits repair information to the server 500 from the server 500 regarding the abnormal section or abnormal point information of the optical line,
Wherein the server (500) provides repair information of a corresponding optical line to the mobile (600) when receiving an abnormal section or abnormal point information of the optical line occurring after the repair information.
4. The method according to any one of claims 1 to 3,
The light-path diagnosing apparatus 100 includes:
And a display unit (60) for displaying whether the optical line is normal or not.

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