KR20120140562A - System for monitoring an optical fiber operation using intelligent mini mdf - Google Patents

Abstract

PURPOSE: A light operation monitoring system using a mini MDF(main distribution frame) is provided to rapidly obtain error information in optical communication generated in each BS(base station). CONSTITUTION: An optical communication test apparatus(150) measures an optical communication state of an optical cable which transmits an optical signal from a transmission apparatus of the base station to a lower BS. A mini MDF(210) is installed in the lower BS. The mini MDF receives test light for measuring optical communication from the optical communication test apparatus. The mini MDF inputs test light for measuring the optical communication to a channel line in order to measure the optical communication for the channel line through the optical communication test apparatus. [Reference numerals] (AA,CC,EE) Mini station apparatus of a transmission unit; (BB,DD,FF) Big station apparatus of a reception unit

Description

Optical operation monitoring system using intelligent MIDI MDF {SYSTEM FOR MONITORING AN OPTICAL FIBER OPERATION USING INTELLIGENT MINI MDF}

The present invention relates to an optical operation monitoring system, and in particular, in the optical communication between the upper base station and the lower base station and the service terminal by installing a Mini MDF in the lower base station and controlled by the optical communication test apparatus installed in the upper base station The present invention relates to an optical operation monitoring system using an intelligent Mini MDF that can measure an optical communication failure of a lower base station. Conventional optical monitoring system was equipped with a device control unit, an OTDR, and a fiber selector in a standard rack, but the present invention is a technology for monitoring optical power whether or not in communication with the MDF (Main Distribution Frame) used for optical communication with the fiber selector. Intelligent Mini MDF with integrated Since the intelligent Mini MDF applied to the present invention is interoperable with the existing optical operation monitoring system, it is possible to simplify the configuration of the telephone company connected to the cable from the optical communication device as well as expanding the function of the system.

In recent years, as the communication technology is rapidly developed, a large number of base stations are required to perform communication, and these base stations are connected through an optical cable for high speed communication so that communication is performed.

On the other hand, the base stations performing the optical communication is a trend that is operated by unmanned as the wide area and the centralization phenomenon is accelerated. If a communication failure occurs as the operation of the base station is unmanned, the manager should move directly to the base station and examine the communication equipment to identify the cause of the failure and take necessary measures. However, such a method of diagnosing failures by the manager has a problem that it is difficult to immediately take action when failures occur simultaneously in a geographically dispersed unmanned base station, and it is difficult to identify field equipment, which takes a long time to determine which equipment has a failure.

Recently, an optical time domain refectometer (OTDR), which can measure a communication state, is installed in a base station, and the optical communication operation state can be monitored by remotely controlling the OTDR.

1 shows a configuration diagram of an optical communication operation monitoring apparatus using such a conventional OTDR.

As shown in FIG. 1, the transmitter 11 transmitting and receiving an optical signal from an upper base station 10 transmits an optical signal to a lower base station 20 through an optical cable. The cable is provided with a coupler 13 for coupling an optical signal, which coupler 13 is connected to an OTDR 15 for measuring the optical communication state. The OTDR 15 inputs test light for optical communication measurement to the optical cable connected by the coupler 13, and then checks the amount of reflected light and the location of the failure by checking the amount of reflected light. Done.

On the other hand, the lower base station 20 is provided with a wiring board (MDF; Main Distribution Frame) (MDF) 21 for providing an optical signal transmitted from the upper base station 10 to each service terminal, the lower base station 20 also has an optical communication failure Coupler 23 and OTDR 25 for measuring the presence or absence is installed and operated. The OTDRs 15 and 25 installed in the upper base station 10 and the lower base station 20 transmit the optical communication measurement results to the central control server 30 through the communication network, and the central control server 30 at each base station. It is provided to identify the occurrence of optical communication failure.

The optical communication operation monitoring apparatus having the above configuration has difficulty in real time checking when a specific line has a failure because the OTDR sequentially checks each optical line of the optical cable. Therefore, in the case where it is necessary to check the failure of a specific line through the conventional optical communication operation monitoring device, the OTDR manager should request the inspection of the specific line and receive the result, and the inspection of the specific line is performed. Confirmation and inspection of several tracks are time consuming and cumbersome. In addition, this method of determining whether there is a problem has a problem that it is difficult for the user who requested the failure of the test results performed in the OTDR in detail.

In addition, such a conventional optical communication operation monitoring apparatus has to be installed in each base station OTDR, and must be connected to each communication network to check the optical communication measurement results of this OTDR remotely, the installation and operation is complicated and expensive There was a problem.

In addition, the main function of the wiring board (MDF) installed in the lower base station was simply to connect the optical cable and the optical transmission device by using a jumper cord. Such an optical line operation monitoring system connects any port in the wiring board (MDF) to the OTDR. There was a complicated issue connecting with.

The present invention has been proposed to solve the above-mentioned problems of the prior art, and an object of the present invention is to generate an optical communication failure occurring at each base station in an optical communication through an optical cable between an upper base station, a lower base station, and a service terminal. It is to provide an optical operation monitoring system that can quickly and accurately identify the presence.

In addition, the present invention allows the optical communication test apparatus 150 installed in the lower base station to measure the presence or absence of optical communication failure through the Mini MDF installed in the lower base station without installing the OTDR that was installed and operated independently in the conventional lower base station. It is to provide an optical operation monitoring system.

Optical operation monitoring system according to the present invention for achieving the above object is an optical operation monitoring system for monitoring the failure of the optical communication made through the optical cable between the upper base station and the lower base station and each service terminal, it is installed in the upper base station And an optical communication test device for measuring an optical communication state of an optical cable for transmitting an optical signal from a transmission device of an upper base station to a lower base station; A channel installed in the lower base station, receiving a test light for optical communication measurement from the optical communication test device, and inputting it to a channel line for transmitting an optical signal from a lower base station to a service terminal, and a test light input through the optical communication test device And a Mini MDF that allows optical communication measurements on the track to be performed.

The Mini MDF includes a receiver for receiving an optical signal from an upper base station through an optical cable, a transmitter for connecting an optical signal to a service terminal connected to each channel line with the receiver, and a test light for optical communication measurement from the optical communication test apparatus. And an optical switch for inputting the test light input through the test light input unit to one of the channel lines of the transmission unit.

Here, the Mini MDF is provided with a Tap PD which is installed in the channel line of the transmitter to detect a failure of each channel line by receiving a portion of the optical signal transmitted through each channel line to determine the amount of light. When the Mini MDF detects the failure of the channel line through the Tap PD, the Mini MDF transmits the failed channel line information to the optical communication test device, and the optical communication test device is inputted through the test light input unit to the failed channel line in the Mini MDF. It is desirable to transmit a switching signal to the Mini MDF that controls the light switch to allow light to be incident.

The optical communication test apparatus includes an optical communication measuring unit measuring an optical communication failure by inputting test light into a communication cable or a Mini MD, and controlling the optical switch operation of the Mini MDF to be transmitted through an optical communication measuring unit to test optical input unit of the Mini MDF. MDF switching control unit for controlling the test light input to the input of any one of the plurality of channel lines, a measurement result analysis unit for analyzing and displaying the optical communication measurement results measured by the optical communication measurement unit, and the measurement result analysis It includes a data management unit for registering and managing the data analyzed through the unit in the database.

Meanwhile, the optical operation monitoring system is connected to the optical communication test apparatus through a communication network, and is provided with a central control server for receiving and monitoring the optical communication measurement progress measured and analyzed by the optical communication test apparatus, and connected with the central control server through a communication network. The line monitoring terminal may be provided to receive and display the optical communication measurement progress measured and analyzed by the optical communication test apparatus from the central control server.

In addition, outside the Mini MDF, a QR code including line number information corresponding to each channel is formed. When the central control server receives an optical communication measurement result for a corresponding channel from a mobile terminal that recognizes a QR code formed in the Mini MDF, the central control server provides the mobile terminal with information about the station number and the optical communication measurement result for the corresponding channel. It is preferable. On the other hand, the same QR code formed in the Mini MDF can be printed by printed matter so that it can be stored to be movable can be recognized by the mobile terminal.

In the optical operation monitoring system according to the present invention, a simple configuration and easy expansion of the Mini MDF is installed in the lower base station in place of the OTDR, and it is controlled by the optical communication test apparatus installed in the upper base station so that the optical communication failure can be measured. By doing so, it is possible to quickly and accurately grasp the occurrence of an optical communication failure due to the optical operation, and it is easy to install and maintain the optical operation monitoring system.

That is, in the optical operation monitoring system according to the present invention, only the test device (OTDR) and the optical selector (Fiber Selector) for managing the basic several main routes exist and all the test ports are expanded to the Mini MDF (Fiber Selector). By interlocking with the test equipment of the upper base station remotely, you can test any port. In particular, it monitors in real time whether or not the specific port is communicating through optical power monitoring, and if it is in communication but suddenly detects no signal, it immediately notifies the test apparatus of the upper base station and receives the test command from the test apparatus again to establish the test line. Connect and automatically measure with OTDR to find fault points. In addition, the bar code recognition function is provided to the Mini MDF so that any port can be recognized, and the result of performing the optical property test can be provided to the user. In addition, the present invention is a result of testing through a remote operation monitoring system by remote control by selecting an arbitrary port in front of the Mini MDF through a mobile terminal such as IPAD, deviating from the method that the conventional administrator selected the port to test in the system Received so that you can check with the mobile terminal.

1 is a configuration diagram of an optical communication operation monitoring apparatus using a conventional OTDR;
2 is a block diagram of an optical operation monitoring system according to the present invention,
3 is a connection diagram of the optical communication test device and Mini MDF according to the present invention,
Figure 4 is a block diagram of a control board for controlling the operation of the optical communication test apparatus according to the present invention,
5 is an example of a mobile terminal screen for receiving an optical communication measurement waveform of a corresponding channel through a QR code formed in a receiver and a transmitter channel of the Mini MDF according to the present invention;
Figure 6 is a block diagram of a control board for controlling the operation of the Mini MDF according to the present invention,
7 is a schematic diagram of a mini MDF control board according to the present invention;
8 is a block diagram of a central control server according to the present invention;
9 is a flowchart illustrating a process of monitoring the light operation state through the light operation monitoring system according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram of an optical operation monitoring system according to an embodiment of the present invention.

As shown in FIG. 2, the optical operation monitoring system according to the present invention performs optical communication with a lower base station 200 through an optical cable and measures an optical communication state, and the upper base station 100. ) And a lower base station 200 performing optical communication, a central control server 300 for receiving an optical communication state from the upper base station 100 and monitoring an optical communication state, and the central control server 300. It comprises a line monitoring terminal 400 for the administrator to monitor the state of the optical communication to be grasped.

The upper base station 100 and the lower base station 200 are base stations for relaying optical communication. In an embodiment of the present invention, the base station located at the front end is the upper base station 100, and the base station located at the rear end is the lower base station 200. It is named. The upper base station 100 and the lower base station 200 are connected to each other through optical cables in which a plurality of optical lines are formed, and perform mutual optical communication. Each of the lower base stations 200 corresponding to a service terminal of optical communication is provided. It may be connected to an optical communication device installed in a building or home.

The upper base station 100 includes a transmitter 110 that performs optical communication with the lower base station 200 through an optical cable, and an optical cable that transmits an optical signal from the transmitter 110 to the lower base station 200. Coupler 130 for coupling each optical line, and the optical communication test device 150 is connected to the optical cable through the coupler 130 to measure the optical communication state.

The optical communication test device 150 is an OTDR device for measuring the occurrence and location of the optical communication failure occurs through the optical cable, the optical communication test device 150 is provided with a plurality of channels (ports) lower base station 200 Connected to the Mini MDF (210) located in the performs the function of controlling the operation of the Mini MDF (210). The optical communication test device 150 is connected to the central control server 300 and the line monitoring terminal 400 through a communication network such as a dedicated line or TCP / IP to transmit and receive data.

The lower base station 200 is provided with a Mini MDF (Main Distribution Frame; Wiring Board) 210, which is an optical signal transmitted from the transmitter 110 of the upper base station 100 through a communication cable. It distributes and transmits to the service terminal of the own station. In addition, the Mini MDF (210) is connected to the optical communication test device 150 installed in the upper base station 100, the optical communication by measuring the communication state of the optical line connected to each service terminal under the control of the optical communication test device 150 It performs the function of transmitting to the test device 150. The Mini MDF 210 measures the communication state of the lower base station 200 in place of the OTDR installed in the conventional lower base station 200, the Mini MDF (210) has a simple structure compared to the OTDR production cost Since it is inexpensive, it is possible to reduce the economic cost of installing the OTDR in each lower base station (200).

The central control server 300 remotely controls the operation of the optical communication test apparatus 150 installed in the upper base station 100 and receives the optical communication state measured through the optical communication test apparatus 150 to remotely control the optical communication state. It is a server computer that monitors and manages. The central control server 300 is connected to the optical communication test device 150 of the upper base station 100 through a public network such as TCP / IP or a communication line such as a dedicated line or an optical cable to transmit and receive data.

The line monitoring terminal 400 is connected to the central control server 300 through a communication network, by receiving and monitoring the optical communication status information of each base station identified by the central control server 300, the administrator remotely optical communication status It is a terminal to grasp. In the embodiment of the present invention, the line monitoring terminal 400 may be composed of not only a personal computer (PC) installed and operated at a fixed position, but also a mobile communication terminal such as a laptop, a PDA, a tablet PC, an IPAD, a smartphone, and the like. have.

Figure 3 shows a connection diagram of the optical communication test apparatus and the Mini MDF according to an embodiment of the present invention.

As shown in FIG. 3, the optical communication test apparatus 150 installed in the upper base station 100 is provided with a plurality of communication ports, which are respectively installed in the lower base station 200 through a communication cable. 210 is connected. That is, a plurality of lower base stations 200 are connected to one upper base station 100. Accordingly, the optical communication test apparatus 150 installed in one upper base station 100 has a plurality of lower base stations, respectively, through communication ports. It is connected to the Mini MDF 210 installed in the 200 to perform communication. In addition, the 7-inch monitor is provided on the outside of the optical communication test device 150 so that the communication status that is grasped through the optical communication test device 150 is displayed to the outside so that the administrator can grasp it.

The control board for controlling the operation of the optical communication test device 150 is provided inside the optical communication test device 150, Figure 4 shows a block diagram of a control board for controlling the operation of the optical communication test device.

As shown in FIG. 4, the control board of the optical communication test apparatus 150 controls the switching operation of the optical communication measuring unit 152 and the Mini MDF 210 to measure a communication state by inputting test light into a communication cable. MDF switching control unit 153 for measuring the communication state of the lower base station 200, the measurement result analysis unit 154 for analyzing and displaying the optical communication measurement results measured by the optical communication measurement unit 152 on the screen, and Data interlocking unit 155 for registering and managing the data analyzed through the measurement result analysis unit 154 in the database 157 and the server interlocking unit for interfacing with the central control server 300 connected through a communication network ( 156 is provided.

The optical communication measuring unit 152 is an optical communication measuring device for determining an obstacle by analyzing the amount of reflected light after inputting incident light to each optical line of the optical communication cable as in a typical OTDR, and the MDF switching control unit 153 is It is a device that transmits a switching signal to the Mini MDF (210) installed in the lower base station 200 to set the optical communication measurement channel of the Mini MDF (210) to control the optical communication measurement. The MDF switching control unit 153 transmits a switching signal for setting an optical communication measurement channel of the Mini MDF 210 according to a failure signal transmitted from the Mini MDF 210, and then receives incident light through the optical communication measurement unit 152. Transmission to the Mini MDF 210 to allow optical communication measurements of the corresponding channel.

The measurement result analysis unit 154 is a device for diagnosing a communication failure by analyzing the optical communication waveform measured by the optical communication measurement unit 152. The measurement result analyzed by the measurement result analysis unit 154 is a data management unit. It is registered and managed in the database 157 through 155. On the other hand, the server linkage unit 156 establishes communication with the central control server 300 located remotely, receives the optical communication test device control signal from the central control server 300, and through the measurement result analysis unit 154 The analyzed communication measurement result is transmitted to the central control server 300.

The Mini MDF 210 receives an optical signal transmitted from the upper base station 100 through an optical cable and transmits the optical signal to each service terminal, and an optical communication state between the lower base station 200 and the service terminal device formed through the optical cable. To monitor the function.

As shown in FIG. 3, the Mini MDF 210 includes a receiver 211 for receiving an optical signal of an upper base station 100 transmitted through an optical cable, and a transmitter for transmitting an optical signal to a lower service terminal ( 212, and a plurality of communication channels (ports) are provided in the receiver 211 and the transmitter 212, respectively.

In addition, the Mini MDF 210 is provided with a test light input unit 214 for receiving test light for optical communication measurement transmitted from the optical communication test device 150 of the upper base station 100. The test light inputted to the test light input unit 214 is transmitted to a channel set through an optical switch described later among the plurality of transmission unit 212 channels so that optical communication of the corresponding channel can be measured. Meanwhile, a QR code 213 (Quick Response Code) is formed in each channel of the receiver 211 and the transmitter 212. The QR code 213 includes line number information of the corresponding channel (for example, a base station). Name, optical cable name, core number, communication device ID, transmission / reception classification information, and the like) are registered. Therefore, when the administrator wants to grasp information about a specific channel, when the QR code 213 is recognized through a mobile terminal and the like, the central control server 300 requests information on the channel, the central control server 300. ) Transmits the field number information for the channel and the result of the optical communication measurement to the mobile terminal so that the administrator can grasp the channel information in the field. 5 illustrates an example of a mobile terminal screen for receiving an optical communication measurement waveform of a corresponding channel through a QR code formed in a receiver and a transmitter channel of the Mini MDF. On the other hand, the QR code 213 formed on the Mini MDF 210 may be printed in the same QR code and stored in the office where the manager is located, the manager to the lower base station 200 where the Mini MDF (210) is located. Without moving, the office can recognize the QR code and request information on the channel from the central management server 300 to be provided.

On the other hand, the inside of the Mini MDF (210) is provided with a control board for controlling the operation of the Mini MDF (210), Figure 6 shows a block diagram of a control board for controlling the operation of the Mini MDF, Figure 7 Shows the schematic diagram of the Mini MDF control board.

As shown in FIG. 6 and FIG. 7, the Mini MDF 210 is input through the receiver 211 and transmits an optical signal to each service terminal through the transmitter 212 for each channel (MSPP: Multi-Service Provisioning Platform). At this time, each of the channel lines connecting the receiver 211 and the transmitter 212, the Tap PD receiving a portion of the optical signal (for example, about 5% of the total amount of light) transmitted through the channel line ( 219 are respectively installed, and the Tap PD 219 determines whether the corresponding channel line is disturbed based on the amount of light input. Meanwhile, a WDM coupler 218 is installed for each channel line, spaced apart from the Tap PD 219, and the WDM coupler 218 is connected to the optical switch 217. The optical switch 217 receives the switching information from the optical communication test device 150 and receives the test light transmitted from the optical communication test device 150 through the WDM coupler 218 and the test light input unit 214 installed for each channel line. The switching operation is performed. The operation of the Tap PD 219, the WDM coupler 218, and the optical switch 217 is controlled by the central controller 216.

Mini MDF (210) having the above configuration, the Tap PD (219) first receives a part of the light amount of the optical signal transmitted through each channel line by grasping it to determine whether the failure of each channel line in real time. That is, when the amount of light is input, the Tap PD 219 recognizes that the corresponding channel line is normal. When the amount of light is not input, the Tap PD 219 recognizes that a failure occurs in the corresponding channel line. If it is determined that the channel line has a failure, the central control unit 216 provided in the Mini MDF 210 transmits specific channel line information in which the failure is found to the optical communication test apparatus 150. Accordingly, the optical communication test device 150 transmits switching information for selecting a specific channel line and test light for optical communication measurement to the Mini MDF 210, which is input to the test light input unit 214. By performing a switching operation of connecting the test light to a specific channel line, the optical communication measurement for the corresponding channel line can be made by the optical communication test apparatus 150.

Accordingly, since the optical communication test apparatus 150 performs optical communication measurement on a specific channel line connected according to the switching operation of the Mini MDF 210, it is possible to determine whether there is a failure of the corresponding channel line. There is no need to install OTDR separately at 200.

The central control server 300 is connected to the optical communication test device 150 installed in the upper base station 100 through a communication network to control the operation of the optical communication test device 150, the optical measured by the optical communication test device 150 Communication measurements are provided to manage the overall operation of the fiber cable network.

8 is a block diagram of a central control server according to an exemplary embodiment of the present invention. The central control server 300 includes a GIS view for identifying and managing geographical locations of the optical communication test apparatus 150 and the Mini MDF 210. Topology View control unit 330 for identifying and managing the connection state of the optical cable network connecting the control unit 320, the optical communication test device 150 and the Mini MDF (210) and the service terminal, and facilities of the optical cable network Cable network facility management unit 340 for managing information, cable network operation management unit 350 for managing the operation status, such as whether there is a failure of the optical cable network, and a database in which each line facility and operation data of the optical cable is registered ( 360 and a central control unit 310 for managing the components. Although not shown in FIG. 8, it is obvious that the central control server 300 is provided with an input device, an output device, a communication device, a hardware device, and operating software for driving the same. Do.

The line monitoring terminal 400 is a terminal device connected to the central control server 300 through a communication network to receive and display an optical communication measurement result made through the optical communication test device 150 from the central control server 300. The line monitoring terminal 400 may request the central control server 300 to make an optical communication measurement through the optical communication test apparatus 150 and receive a measurement result. To this end, the line monitoring terminal 400 monitors the remote test controller for remotely requesting the optical communication measurement test to the central control server 300 and the optical communication measurement result transmitted from the central control server 300 on the screen. The state monitoring unit and the optical communication test device 150 emulator for performing an emulation for the optical communication test device 150 installed in the upper base station 100 is provided.

Hereinafter, an operation process of the optical operation monitoring system having the above configuration will be described.

9 is a flowchart illustrating a process of monitoring the light operation state through the light operation monitoring system according to an embodiment of the present invention.

Step S110: First, when the optical operation monitoring system is turned on, the optical communication test apparatus 150 installed in the upper base station 100 is connected to each line of the optical cable through which the optical signal is transmitted from the upper base station 100 to the lower base station 200. It operates with a normal OTDR that performs optical communication measurements.

Steps S120 and S130, on the other hand, the Tap PD 219 of the Mini MDF 210 installed in the lower base station 200 receives a partial amount of light of an optical signal transmitted to each channel line connecting the receiver 211 and the transmitter 212. The amount of light received is measured (S120). If the amount of light to be measured satisfies the reference light amount, it is determined that the corresponding channel line is normally operated. The process of measuring the incident light amount is repeatedly performed until the system is terminated (S130).

Step S140: If the measured incident light quantity does not satisfy the criterion, the channel line determines that a failure has occurred, and the Mini MDF 210 transmits channel line information determined as a failure to the optical communication test device 150, thereby precisely adjusting the channel line information. You will be asked to take an optical communication measurement.

Steps S150 and S160: The optical communication test apparatus 150 transmits the switching information for selecting the corresponding channel line received from the Mini MDF 210 and the test light for optical communication measurement to the Mini MDF 210 (S150). Accordingly, the Mini MDF 210 connects the corresponding channel line and the test light input unit 214 through the optical switch 217 to inject the test light input to the test light input unit 214 into the selected channel line. .

Steps S170 and S180: The optical communication test apparatus 150 performs optical communication measurement on the corresponding channel line by measuring an amount of test light incident and reflected on the channel line connected through the optical switch 217 of the Mini MDF 210. In operation S170, the optical communication measurement result is analyzed, displayed on the screen, and stored in the database 157 (S180).

Steps S190 and S200: On the other hand, the optical communication measurement results analyzed through the optical communication test apparatus 150 are transmitted to the central control server 300 and monitored, and the central control server 300 is provided to the line monitoring terminal 400 if necessary. The optical communication measurement result is transmitted to allow an administrator to check the optical communication measurement result through the line monitoring terminal 400 remotely (S190). This process is repeated until the system is terminated (S200).

Through the above process, the optical communication test apparatus 150 controls the optical switch 217 of the Mini MDF 210 installed in each of the lower base stations 200 and applies the test light to the test light input unit 214 of the Mini MDF 210. And transmits the test light to the channel line connected to the test light incident part 214 according to the control agent of the optical switch 217 of the Mini MDF 210 to perform optical communication measurement on the corresponding channel line. Will be judged.

Meanwhile, in FIG. 9, the presence or absence of failure in each optical communication channel line of the lower base station 200 is measured according to the request of the Mini MDF 210. However, the upper base station 100 or the lower base station 200 Determination of the failure according to the optical communication measurement may be performed at the request of the line monitoring terminal 400 or the central control server 300. In particular, since the QR code 213 is registered in each channel of the Mini MDF (210) registered with the channel number information of the channel, the administrator recognizes the QR code 213 through a mobile terminal, etc. When requesting the communication measurement to the central control server 300, the central control server 300 transmits the optical station measurement information for the corresponding channel and the optical communication measurement results performed through the optical communication test device 150 to the mobile terminal manager The channel information can be obtained from the field or the office.

The optical operation monitoring system according to the present invention is not limited to the above-described embodiment, and the technical scope of the present invention and the equivalent scope of the claims to be described below by those skilled in the art to which the present invention pertains. Of course, various modifications and variations can be made.

100: upper base station 110: transmitter
130: coupler 150: optical communication test device
151: central control unit 152: optical communication measuring unit
153: MDF switching control unit 154: measurement result analysis unit
155: data management unit 156: server interworking unit
157: database 200: lower base station
210: Mini MDF 211: Receiver
212: transmitting unit 213: QR code
214: test light input unit 216: central control unit
217: optical switch 218: WDM coupler
219: Tap PD 300: Central Control Server
310: central control unit 320: GIS View control unit
330: Topology View Control Department 340: Cable Network Facility Management Department
350: cable network operation management unit 360: database
400: track monitoring terminal

Claims (10)

In the optical operation monitoring system for monitoring the failure of the optical communication made through the optical cable between the upper base station and lower base station and each service terminal,
An optical communication test apparatus (150) installed in the upper base station (100) and measuring an optical communication state of an optical cable for transmitting an optical signal from the transmitting apparatus (110) of the upper base station (100) to the lower base station (200);
Is installed in the lower base station 200, receives the test light for optical communication measurement from the optical communication test device 150 and inputs to the channel line for transmitting the optical signal from the lower base station 200 to the service terminal, the optical communication test And a mini MDF (210) for performing optical communication measurements on the channel line to which test light is input through the device (150). The method of claim 1,
The Mini MDF 210
A receiver 211 receiving an optical signal from an upper base station 100 through the optical cable;
A transmitter 212 connected to the receiver 211 by each channel line and transmitting an optical signal to a service terminal;
A test light input unit 214 for receiving test light for optical communication measurement from the optical communication test device 150;
And an optical switch (217) for inputting the test light input through the test light input unit (214) to any one of the channel lines of the transmitting unit (212). The method of claim 2,
The Mini MDF 210
It is installed on the channel line of the transmitter 212, Tap PD 219 is provided to identify the failure of each channel line by receiving a portion of the optical signal transmitted through each channel line to determine the amount of light, characterized in that it is provided Optical Operation Surveillance System. The method of claim 3,
The Mini MDF 210 transmits the channel line information in which the failure occurs to the optical communication test device 150 when the failure of the channel line is detected through the Tap PD 219,
The optical communication test apparatus 150 may provide a switching signal for controlling the optical switch 217 such that the test light inputted through the test light input unit 214 enters the channel line in which the MDF 210 has failed, and the mini MDF 210. Optical operation monitoring system, characterized in that for transmitting. The method of claim 2,
The optical communication test device 150
Optical communication measuring unit 152 for measuring the optical communication failure by inputting the test light to the communication cable or Mini MDF (210),
By controlling the operation of the optical switch 217 of the Mini MDF (210), the test light transmitted through the optical communication measuring unit 152 and input to the test light input unit 214 of the Mini MDF (210) of any of the plurality of channel lines MDF switching control unit 153 for controlling to be input to one line,
A measurement result analyzer 154 analyzing and displaying the optical communication measurement results measured by the optical communication measurement unit 152;
And a data management unit (155) for registering and managing the data analyzed through the measurement result analysis unit (154) in the database (157). 6. The method of claim 5,
The optical operation monitoring system
Optical operation, characterized in that the central control server 300 is connected to the optical communication test device 150 through a communication network, and receives and monitors the optical communication measurement progress measured and analyzed by the optical communication test device 150. Surveillance system. The method according to claim 6,
The optical operation monitoring system
The line monitoring terminal 400 is connected to the central control server 300 through a communication network to receive and display the optical communication measurement progress measured and analyzed by the optical communication test apparatus 150 from the central control server 300. Optical operation monitoring system, characterized in that. The method according to claim 6,
Optical operation monitoring system, characterized in that the outside of the Mini MDF (210) is formed a QR code (213) containing the prefix information corresponding to each channel. The method of claim 8,
When the central control server 300 receives an optical communication measurement result for a corresponding channel from a mobile terminal that recognizes the QR code 213 formed in the Mini MDF 210, the head station information and optical information for the corresponding channel are received. An optical operation monitoring system, characterized by providing a communication measurement result to the mobile terminal. The method of claim 8,
Optical operation monitoring system, characterized in that the same QR code formed on the Mini MDF (210) and the same QR code is printed on the printed material so that it can be stored to be stored.

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