KR20230050859A - Ai applied active fiber optic network management system - Google Patents

Abstract

An active optical fiber management system using artificial intelligence of the present invention, which can reduce a working time and costs, comprises: an enclosure with an RFID tag attached; an optical fiber connected to the enclosure; an optical core cable contrast device identifying a specific optical cable among optical cables in the optical fiber; a fusion device connecting the optical cable of the optical fiber to another optical cable and including a display unit, a sensor unit, and a communication unit; an optical power meter including a short-distance communication unit capable of measuring an optical output at a final RN of the cable fused and connected by the fusion device and transmitting the measured data; a terminal capable of communicating with the enclosure, optical fiber, optical core cable contrast device, fusion device, and optical power meter; and a central server storing all data received from the terminal and storing GIS data and optical fiber data.

Description

Active fiber management system using artificial intelligence {AI APPLIED ACTIVE FIBER OPTIC NETWORK MANAGEMENT SYSTEM}

The present invention relates to an optical fiber management system, and more particularly, to prevent optical fiber errors and losses, to optimize solutions for optical fiber search and management during optical fiber operation, and to automatically obtain the most up-to-date data on the optical fiber It is about an active optical line management system using artificial intelligence to provide optimization solutions for line drawing design and solutions for line errors.

In general, optical cables have lower loss and higher bandwidth than copper wires, and are widely used in high-speed communication networks. However, optical cables have a relatively weak reliability due to low mechanical properties compared to copper wires. That is, the optical cable is easy to cut compared to the copper wire, and communication is impossible when it is bent at a certain angle or more. Therefore, when a failure occurs in an optical cable, operators who have built an optical communication network quickly identify a failure point and put manpower into the failure point to restore the optical cable.

In addition, during the work of finding and connecting the incoming and outgoing cables necessary for the optical line work of the enclosure, it takes a lot of time to find and connect suitable cables from 144 or 288 or 576 optical lines.

On the other hand, a technique for checking whether or not an optical fiber path is faulty through an optical measuring instrument has been disclosed. Specifically, the optical measuring instrument transmits OTDR (OPTICAL TIME DOMAIN REFLECTOMETER) pulses to a plurality of optical termination devices connected to a distribution device, and analyzes a plurality of OTDR pulses reflected from the plurality of optical termination devices and sequentially returned to determine the Analyze for abnormalities.

In addition, 12 or 24 optical cables are divided into one optical fiber unit and a total of 2 to 24 optical fiber units are managed, and the 12 or 24 optical cables in the optical fiber unit have different colors for easy identification.

However, this causes a problem that the operator must check each optical cable one by one, which takes a long time to work.

In addition, even if an optical cable is found and connected, a problem arises in that a line drawing must be manually drawn up to the final installation location, which also causes errors.

In order to solve the above problems, the present invention facilitates work by attaching an RFID tag to an optical cable unit, measures lost data when measuring an optical cable, accumulates data by transmitting to a server, and converts lost data into flow rate. Low-volume data, latecomers can recognize RFID tags through terminals and apps when working on fiber optic lines, check and transmit real-time data on fiber optic lines on site, and use real-time fiber optic data and GIS data to automatically design line drawings It is to provide an active optical line management system using artificial intelligence that provides an optimal line drawing appropriate for the situation, reduces work time and provides a problem solving solution when a problem occurs in the construction of an optical line.

An active optical fiber management system using artificial intelligence of the present invention for achieving the above object includes a body to which an RFID tag is attached; a light path connected to the enclosure; an optical fiber comparator for identifying a specific optical cable among the optical cables of the optical path; a fusion splicer that connects an optical cable of the optical path with another optical cable and includes a display unit, a sensor unit, and a communication unit; an optical power meter including a short-range communication unit capable of measuring optical output at the final RN of the cable spliced by the fusion splicer and transmitting the measured data; A terminal capable of communicating with the enclosure, optical line, optical core comparator, fusion splicer, and optical power meter; and a central server storing all data received from the terminal and storing GIS data and optical line data. there is.

In addition, first, the terminal automatically generates a line drawing using artificial intelligence using the optical fiber data and GIS data of the central server and provides it to the user; In order to obtain a minimum loss value when splicing with a fusion splicer, outputting an optimal fusion splicing environment using artificial intelligence and providing it to the user; Recognizing the RFID tag attached to the enclosure and checking the information on the optical path; Reconfirming whether each optical cable to be fusion-spliced is oblique with an optical fiber line controller and transmitting the optical cable to a terminal; transmitting a loss value generated while fusion-splicing the optical cable to be fusion-spliced with a fusion splicer to a terminal; storing the optical output value and the fusion splicing loss value as data in a central server through a terminal; Based on the automatically generated line drawing, measuring the optical power value with an optical power meter capable of short-range communication in the final RN after all fusion splicing is completed, and transmitting the input optical output value to a terminal using short-range communication; and Receiving the information of the optical cable of the terminal, providing a solution to the user through artificial intelligence when a defect occurs in the optical line, and the solution method using the accumulated data in which the solution to the defect is input; may include.

In order to lower the loss value during fusion splicing with the fusion splicer, in the step of outputting a fusion splicing environment with a low loss value based on artificial intelligence and providing it to the user, at each fusion splicing expected point including the base station cable and the fusion splicing point Checking the RFID tag information of the enclosure through short-range communication of the terminal and checking the optical cable to be fusion-spliced; When the RFID tag information of the enclosure is changed due to each newly fusion-spliced optical cable, the existing optical cable connection information acquired with the RFID tag of the enclosure through short-range communication of the terminal is automatically modified with the newly acquired optical cable information from the optical fiber line comparator. and transmitting the finally changed data to the RFID tag through the terminal and to the central server.

According to these characteristics, the present invention attaches a short-range communicator to a housing or optical fiber unit to facilitate work using an optical cable, optical fiber unit, and enclosure through a terminal and an app, and streamlines data lost after field workers measure optical fiber After that, it is stored on the server to eliminate inefficiency of work that can be consumed by latecomers doing the same work repeatedly for fiber optic work, and by using fiber optic data and GIS data, automatically drawing a line diagram to save work time. has a shortening effect.

In addition, it has the effect of reducing work time and cost by providing a solution to solve when a defect occurs in the optical line construction and optical line.

1 is a configuration diagram of an active optical fiber management system using artificial intelligence according to an embodiment of the present invention.
2 is a flowchart of an active optical fiber management system using artificial intelligence according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily carry out the present invention. However, the present invention may be embodied in many different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Then, with reference to the accompanying drawings, an active optical fiber management system using artificial intelligence according to an embodiment of the present invention will be described.

1 is a configuration diagram of an active optical fiber management system using artificial intelligence according to an embodiment of the present invention, and FIG. 2 is a flowchart of an active optical fiber management system using artificial intelligence according to an embodiment of the present invention. .

1 and 2, the active optical fiber management system using artificial intelligence according to an embodiment of the present invention is an optical core line matcher for identifying a specific optical cable among optical cables in the enclosure 200 and the enclosure 200 ( 300), a fusion splicer 400 for connecting the optical cable of the enclosure 200 and other optical cables, an optical power meter 500 for measuring the optical power of the optical cable fusion-spliced with the fusion splicer 400, and the enclosure 200 , optical core comparator 300, fusion splicer 400, optical power meter 500 and a terminal 10 capable of communication and all data received from the terminal are stored, and the center stores GIS data and optical fiber data. It is configured including the server 100.

The enclosure 200 has an RFID tag attached to enable short-distance communication. The enclosure 200 includes 4 to 8 optical fiber paths, and includes 2 to 24 optical fiber units, and the optical fiber unit includes an optical cable. It consists of groups of 6, 12, 24, etc.

The enclosure 200 uses RFID or NFC to enable short-range communication, but is not limited thereto.

In addition to the enclosure 200, an RFID tag is attached to the optical path and the optical path unit, but is not limited thereto.

The optical fiber comparator 300 has a communication unit capable of short-distance communication, and transmits data input during optical measurement to the terminal 10 using short-range communication.

The optical fiber comparator 300 is characterized in distinguishing the color of each sheath of the optical cable.

The fusion splicer 400 has a communication unit capable of short-distance communication, and can transmit data input during fusion splicing to the terminal 10 using short-range communication. In addition, it has a display unit that can check the loss value of the optical cable that occurs during fusion splicing, and includes a sensor unit that collects field data such as a temperature sensor, humidity sensor, air pressure sensor, and touch sensor in the fusion splicer.

The optical power meter 500 includes a short-range communication unit capable of transmitting data, and transmits the input optical power value to the terminal 10 through wireless communication.

The terminal 10 recognizes the RFID tag of the enclosure 200, collects optical cable connection information data such as enclosure information, optical path information, and optical cable status, location, and connection relationship before work, and transmits the changed data to the RFID tag after work. It can be input, and the changed data is transmitted to the central server (100). In addition, the data received from the optical fiber comparator 300, the data received from the fusion splicer 400, and the data received from the optical power meter 500 are transmitted to the central server 100.

In addition, the terminal 10 can download data from the central server 100 and input the data downloaded from the central server to the RFID tag.

Through this, the central server can manage the work contents of the optical fiber in real time.

Next, with reference to FIG. 2, the system sequence of the active optical fiber management system using artificial intelligence will be described in detail.

First, the terminal 10 automatically generates a line drawing by using artificial intelligence using optical fiber data and GIS data of the central server 100 and provides it to the user (S11).

At this time, artificial intelligence is used to obtain a loss value during fusion splicing with the fusion splicer 400, and a fusion environment with a low loss value is output and provided to the user (S12).

First, the RFID tag information of the enclosure 200 is checked through short-range communication of the terminal 10 at each fusion splicing point including the base station cable and the fusion splicing point, and the optical cable to be spliced is checked (S13).

At this time, it is preferable to use RFID or NFC for short-distance communication, but is not limited thereto.

The optical power value of each of the optical cables to be fusion-spliced is measured by the optical core line comparator 300, and whether or not oblique lines are reconfirmed and transmitted to the terminal 10 (S14).

At this time, the loss value generated while fusion-splicing the optical cable to be spliced with the fusion splicer 400 is transmitted to the terminal (S15), and the optical output value and the fusion splicing loss value are stored as data in the central server through the terminal (S16).

At this time, when the RFID tag information of the enclosure is changed due to each newly fusion-spliced optical cable, the existing optical cable connection information acquired by the RFID tag of the enclosure through short-range communication of the terminal is converted into the optical cable information newly acquired from the optical fiber line matcher 300. correct it automatically

At this time, the optical fiber comparator 300 can distinguish optical cables having different colors, and the terminal app modifies the corresponding optical cable connection information in the optical fiber unit according to the color.

The final changed data is transmitted to the RFID tag and transmitted to the central server.

After all fusion splicing is completed based on the automatically generated line drawing, the optical power value is measured with an optical power meter 500 capable of short-range communication at the final RN (Remote Node), and the input optical output value is transmitted to the terminal 10. (S17).

Finally, the information of each optical cable is transmitted to the terminal 10, and when a defect occurs in the enclosure 200, a solution using artificial intelligence is provided to the user. Data is used (S18).

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements made by those skilled in the art using the basic concept of the present invention defined in the following claims are also included in the scope of the present invention. that fall within the scope of the right.

10: terminal 100: central server
200: enclosure 300: optical fiber collator
400: fusion splicer 500: optical power meter

Claims (3)

Enclosure to which RFID Tag is attached;
a light path connected to the enclosure;
an optical fiber comparator for identifying a specific optical cable among the optical cables in the optical path;
a fusion splicer that connects an optical cable of the optical path with another optical cable and includes a display unit, a sensor unit, and a communication unit;
an optical power meter including a short-range communication unit capable of measuring optical output at the final RN of the cable spliced by the fusion splicer and transmitting the measured data;
A terminal capable of communicating with the enclosure, the optical fiber line, the optical core comparator, the fusion splicer, and the optical power meter; and
An active optical management system using artificial intelligence, characterized in that it comprises a central server storing all data received from the terminal and storing GIS data and optical fiber data. First, the terminal automatically generates a line drawing using artificial intelligence using optical fiber data and GIS data of the central server and provides it to the user;
In order to obtain a minimum loss value when splicing with a fusion splicer, outputting an optimal fusion splicing environment using artificial intelligence and providing it to the user;
Recognizing the RFID tag attached to the enclosure and checking the information on the optical path;
Reconfirming whether or not each optical cable to be fusion-spliced is oblique with an optical fiber line controller and transmitting the same to a terminal;
transmitting a loss value generated while fusion-splicing the optical cable to be fusion-spliced with a fusion splicer to a terminal;
storing the optical output value and the fusion splicing loss value as data in a central server through a terminal;
Measuring the optical power value with an optical power meter capable of short-distance communication in the final RN after all fusion splicing is completed based on the automatically generated line drawing, and transmitting the input optical output value to a terminal using short-range communication; and
Receiving the information of each optical cable to the terminal, providing a solution to the user through artificial intelligence when a defect occurs in the optical line, and using the accumulated data in which the solution to the defect is input; Active optical management system using artificial intelligence, characterized in that. According to claim 2,
In the step of outputting a fusion environment with a low loss value based on artificial intelligence and providing it to the user in order to lower the loss value during fusion splicing with the fusion splicer,
Checking the RFID tag information of the enclosure through short-range communication of the terminal at each expected fusion splicing point, including the base station cable and the fusion splicing point, and checking the optical cable to be fusion spliced;
When the RFID tag information of the enclosure is changed due to each newly fusion-spliced optical cable, the existing optical cable connection information acquired with the RFID tag of the enclosure through short-range communication of the terminal is automatically modified with the newly acquired optical cable information from the optical fiber line comparator. steps; and
An active optical fiber management system using artificial intelligence, characterized in that it further includes; transmitting the final changed data to an RFID tag through a terminal and transmitting to a central server.

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