KR100692669B1 - Real-time optical cable management system - Google Patents

Abstract

The present invention provides an optical transmission system including an optical end station that performs signal conversion, fault signal generation, and optical transmission, and an optical distribution box that is connected to the optical end station to perform an optical cable connection, connection site protection, and distribution. A connected real-time optical cable monitoring system, comprising: an optical cable control server connected to the optical end station and an optical cable driven by the optical cable control server, connected to the optical distribution box, and connected to the optical distribution box to perform a failure measurement to measure a measurement waveform. And an optical cable test apparatus for obtaining the measured waveform and providing the measured waveform to the optical cable control server, and a monitoring monitor driven by the optical cable control server to provide a user interface, wherein the optical cable control server is provided to the optical end station at a first cycle time. Optical signal for each optical cable stored in the optical end station by remote access If the transmission and reception level is determined, and it is determined that the optical cable is defective based on the information obtained from the optical station, the optical cable test apparatus is driven to obtain the measurement waveform of the corresponding region where the failure occurs, and to determine whether the failure occurs and the point of failure through the measurement waveform. The present invention relates to a real-time optical cable monitoring system.

Optical transmission device, optical station, wavelength division multiplexing, optical cable, fault monitoring

Description

Real-time optical cable management system

1 is a block diagram of a real-time optical cable monitoring system according to an embodiment of the present invention.

2 is a view showing that the optical cable monitoring system of the present invention collects fault information from the optical end station.

3 is an operational flowchart of a real-time optical cable monitoring system according to an embodiment of the present invention.

The present invention relates to a real-time optical cable monitoring system, in particular, the occurrence of abnormal signs of the optical cable through a change in the transmission and reception level for the optical cable randomly received from the optical end station device on the optical path and the optical end station periodically obtained from the optical end station device The present invention relates to a real-time optical cable monitoring system that monitors an optical cable in real time through an optical cable tester connected to the corresponding optical cable.

In recent years, communication using mobile phones and the Internet has rapidly progressed toward transmitting still pictures and moving pictures beyond the level of exchanging voice or text data. As a result, the demand for high-speed information and communication technology is increasing exponentially. As a result, communication demand is rapidly expanding in all fields of society, and the transmission speed of communication networks and the spread of optical cable communication networks are rapidly progressing to meet them.

Due to the wide and diverse track site, optical cable lines may deteriorate due to environmental factors over time.In the case of cables buried around roads or rivers, vibrations caused by traffic or changes in geology Micro bands can occur and cause failures. In addition, the accident of cutting the optical cable by road construction, excavation, etc., the wear, refraction, deformation of the optical cable due to the deformation of the terrain and geology can be the cause of the accident. These effects can not only affect the volume of calls, but also paralyze the city.

Therefore, it is necessary to continuously monitor and manage the failure of the optical fiber cable to prevent accidents caused by the optical fiber cable failure.

Due to these demands, the management and monitoring of the optical fiber cable and the restoration thereof have been made. In other words, the current monitoring and recovery of the optical cable detects and reports the failure of the optical fiber cable in the system that performs the optical transmission, the maintenance personnel uses the Optical Time Domain Refectometer (OTDR) meter to find and repair the optical cable breakage point. The OTDR meter tells you how many meters from the meter the optical cable is broken.

However, the conventional method has a problem that it takes a lot of time to find the point of failure because the maintenance personnel must be dispatched to the site to determine the point of failure in the optical cable and must identify the point of failure using the OTDR meter. In addition, in the conventional method, the recovery operation is performed only when the optical cable failure is detected by the optical transmission system. That is, the failure of the optical cable can be known only when the failure condition defined by the optical transmission system occurs. Therefore, there is a problem that no action can be taken when the optical cable is slightly damaged, or when the optical transmission system does not detect or fail to detect an optical cable failure.

Therefore, the present invention is to solve the conventional problems, it is possible to determine whether the failure of the optical cable and the point of failure even if you do not go to the field, and even if the optical station does not generate a failure signal or the failure monitoring for the optical cable The purpose is to make it possible.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings. In the following description of the present invention, detailed descriptions of related well-known functions or configurations will be omitted when it is determined that they may unnecessarily obscure the subject matter of the present invention. Terms to be described later are terms defined in consideration of functions in the present invention, and may be changed according to intentions or customs of users or operators. Therefore, the definition should be made based on the contents throughout the specification.

1 is a block diagram of a real-time optical cable monitoring system according to an embodiment of the present invention. As shown in Figure 1, the real-time optical cable monitoring system 100 of the present invention is an optical cable control server 110, the optical cable control server 110 connected to the optical end station device (hereinafter referred to as 'optical end station') 210 in a network And an optical cable test apparatus 120 connected to one or more optical distribution boxes 220 and a monitoring monitor 130 connected to the optical cable control server 110.

Prior to describing the configuration of the present invention, the optical end station 210 and the optical distribution box 220 of the configuration of the optical transmission system to which the present invention is applied will be briefly described.

The optical end station 210 is equipped with a standardized network management protocol (CORBA: Common Object Request Broker Architecture, TL1, SNMP, etc.) and is a conventional optical end station apparatus installed at the end of the optical transmission path when constructing an optical transmission system. That is, the optical end station 210 converts an electrical signal into an optical signal during data transmission, converts a received optical signal into an electrical signal, and transmits the optical signal to an optical cable. The optical end station 210 checks the transmission signal level and the reception signal level of the transmitted optical signal and generates a failure signal when the difference between the currently recognized transmission level and the previous (or reference) transmission level exceeds the threshold. Performs self-diagnosis to identify faults and generates fault signals such as generating a fault signal.

Optical end station 210 varies depending on the transmission speed, and supports signal multiplexing in the case of ultra-high speed large capacity products. In general, optical methods for multiplexing optical signals include Optical Time Division Multiplexing (OTDM), Wavelength Division Multiplexing (WDM), and Dense Wavelength Division Multiplexing (DWDM). Dual DWDM is called high-density wavelength division multiplexing. Like WDM, it is a technique of multiplexing multiple optical signals into a single signal, which is more advanced than WDM. Among the multiplexing technologies, the DWDM method is the most advanced technology. Therefore, in the case of the ultra-high speed optical communication network, the optical end station 210 will perform the optical transmission in the DWDM method.

Optical distribution box 220 is an enclosure having functions of connection, connection area protection and distribution of the optical cable, and is connected to the optical end station 210 through the optical cable and also connected to the optical distribution box of the remote location, to achieve the object of the present invention For the optical cable test device 120 is connected.

Returning to the configuration description of the present invention, the optical cable control server 110 collects and analyzes the status information of the optical cable and performs the overall operation such as finding and informing the failure point of the optical cable.

The optical cable control server 110 collects state information of the optical cable in two ways and another method shown in FIG. The first is a conventional method, and receives a failure signal provided by the connected optical end station 210 spontaneously. At this time, the fault signal of the optical end station 210 is randomly generated when an error occurs in the optical transmission system.

The second collects the transmission level in the optical cable managed by the optical end station 210 after remotely logging in and connecting to the optical end station 210 every first predetermined period. The second time is performed even if a failure signal does not occur in the optical end station 210. Gwangdan station 210 determines the failure with a certain margin (margin) when determining the failure. That is, the optical end station 210 does not generate a fault signal if the signal detected for fault determination is within the margin width. Therefore, the optical cable control server 110 may detect the abnormal signal within the margin width of the optical end station 210 in the second collection operation.

The third is to test the optical cable line connected to the optical distribution box by driving the optical cable test device 120 every second predetermined period and collects the test results. The third collection operation is performed separately from the first and second collection operations. Therefore, even if the failure is not detected due to the failure of the optical end station 21 or the optical distribution box 220, the optical cable failure can be detected by the third collection operation. In general, since one optical cable test apparatus is responsible for the plurality of optical distribution boxes 220, the optical cable test apparatus sequentially tests the optical cable lines connected to the optical distribution box and collects the results.

In the above, the time of the first schedule period and the second schedule period is arbitrarily determined by the operator, it is preferable to make the second schedule period longer than the first schedule period. On the other hand, the optical cable control server 110 processes the three collection operations in parallel.

When the optical cable control server 110 obtains the state information of the optical cable by the above three collection operations, it analyzes it. That is, when the failure signal is received from the optical end station 210 through the first collection operation, the optical cable control server 110 determines whether the received failure signal is a failure signal related to the optical cable. When the optical cable control server 110 collects the transmit / receive level for each optical cable through the second collecting operation, it compares the collected transmit / receive level with a previous or / and reference transmit / receive level to determine whether there is a change in the transmit / receive level.

The optical cable control server 110, if it is determined that the failure signal received from the optical end station 210 is a failure signal related to the optical cable or there is a change in the transmission / reception level, the optical cable test device 120 is driven to find a failure point and monitor the monitor 130. To inform them of the fact.

The optical cable test apparatus 120 is driven by the optical cable control server 110. The optical cable tester 120 determines whether an optical cable is abnormal by using the OTDR measurement method.

The OTDR measurement method is a method of analyzing a signal form in which time is incident on the optical fiber and reflected light and scattered light of the optical pulse is returned. Backscatter or reflected light generated in the optical fiber is returned to the time difference with respect to the optical fiber length from the incident point to the measurement point. Therefore, according to the OTDR measurement method, the fault location of the optical cable can be determined using a method of obtaining the length of the optical fiber from the delay time and the propagation speed of the optical fiber to the position where backscattering or reflected light occurs.

The monitoring monitor 130 is controlled by the optical cable control server 110 and provides a PC-based client GUI (Graphic User Interface) environment for monitoring a real-time optical cable failure situation.

Hereinafter, an operation description of an optical cable monitoring system according to an exemplary embodiment of the present invention will be described with reference to FIG. 1 along with FIG. 3. 3 is an operation flowchart of a real-time optical cable monitoring system according to an embodiment of the present invention.

As shown in FIG. 3, the optical fiber monitoring system 100 performs a collection operation for three optical cable state information in parallel. First, the first acquisition operation described above and the operation (A) according to the above, if the optical end station 210 detects the abnormality of the optical transmission system generates a failure signal and transmits to the optical cable control server 110.

When the optical cable control server 110 receives a failure signal from the optical end station 210 (301), it analyzes the failure code included in the received failure signal to determine whether the received failure signal is a signal for the optical cable failure (302). ).

As a result of the determination, if the failure signal is an optical cable failure signal, the optical cable control server 110 obtains information on the optical cable section in which the failure occurred from the received failure signal and tests the optical cable in the corresponding section (303).

However, prior to this, the optical cable control server 110 checks previously stored construction site information to check whether construction is in progress in the optical cable section to test the optical cable (304).

If construction is in progress in the corresponding optical cable section (305), the optical cable control server 110 determines that the optical cable failure has occurred by the construction and terminates the processing of the currently received optical cable failure signal. However, when the optical cable control server 110 determines that there is no construction in progress in the corresponding optical cable section (305), the optical cable section information to be tested by the optical cable test apparatus 120 in charge of the optical cable section to instruct the driving.

The optical cable test apparatus 120 is driven under the control of the optical cable control server 110, and the OTDR measurement is performed by introducing a test light source into the optical distribution box 220 located in the corresponding optical cable section and connected thereto (306). The optical cable test apparatus 120 obtains a measurement waveform through the OTDR measurement and provides it to the optical cable control server 110.

The optical cable control server 110 analyzes the measurement waveform obtained from the optical cable test apparatus 120 to identify the point where the abnormal waveform is generated, that is, the point where the failure occurs, and the point where the identified failure occurs is optically distributed (220). It is calculated whether it is located at a distance of about 308.

Then, the optical cable control server 110 displays the information or / and the measurement waveform thus calculated on the monitoring monitor 130 to inform the operator (309).

Here, the optical cable control server 110 is connected to the network and functions as a computer, and thus not only notifies a failure through the monitoring monitor 130, but also generates an alarm sound, alerts the terminal or server of a remote site. In addition, a notification operation such as an SMS or a set voice may be notified to the mobile terminal or the wired terminal. The optical cable control server 110 may display the optical cable section and the point of occurrence of the failure as GIS information.

The second collection operation and thus operation B will be described below.

Apart from the first operation, when the set period is the optical cable control server 110 is remotely logged in to the optical end station 210 and connected (310).

When the optical cable control server 110 is connected to the optical end station 210, the transmission and reception level information for each optical cable connected to the optical end station 210 is stored in the corresponding memory of the optical end station 210 (S311).

 The optical cable control server 110 compares the read / receive level for each optical cable with a previous transmit / receive level or a set reference value, and grasps the optical cable or / and change value at which the transmit / receive level is changed (312).

Here, the optical cable control server 110 determines whether to perform the optical cable measurement event by analyzing the optical cable or / and the change value of the transmission and reception level is changed (313). That is, the optical cable control server 110 determines that the measurement event is the target of the optical cable having the set change value larger than the threshold even if the change value is greater than or within the margin of the optical end station 210. On the other hand, the present invention can be made to perform the optical cable test for all the optical cable of the transmission level is changed regardless of the change value.

When the optical cable control server 110 determines that it is an optical cable measurement event, the optical cable test apparatus 120 is driven for the optical cable test. As described above, the optical cable control server 110 determines whether the optical cable is under construction in the corresponding optical cable section (S305). If not under construction, the optical cable control server 110 performs steps 306, 307, 308, and 309 as described above to find a point of failure and notify the operator.

Finally, when looking at the third collection operation and the operation (C), the optical cable control server 110 drives the optical cable test apparatus 120 when the cycle is set separately from the first and second collection operation and the operation accordingly. In step 306, measurement of the optical cable is started, the measurement waveform is obtained, and the measurement waveform is analyzed to determine whether there is a point where an abnormal waveform occurs in the measurement waveform (307). If there is no abnormal waveform among the measurement waveforms, it is determined that the optical cable is normal, and if there is an abnormal waveform, the failure point is identified from the point where the abnormal waveform has occurred (308). The operator is then notified of the identified obstacle point (309).

On the other hand, the data of the measurement waveform for the optical cable periodically obtained from the optical cable testing device 120 is continuously accumulated in the optical cable control server 110, the operator changes the characteristics of the optical cable through the history management of the accumulated measurement waveform It can manage the life expectancy of the optical cable.

The technical spirit of the present invention has been described above with reference to the accompanying drawings, but this is by way of example only and not intended to limit the present invention. In addition, it is obvious that any person skilled in the art can make various modifications and imitations without departing from the scope of the technical idea of the present invention.

The present invention determines the failure through the transmission and reception level, and determine whether the failure occurs and the point of failure using the wavelength of the region where the failure occurred, to quickly determine whether the optical cable failure occurs and the point where the failure occurred in real time to the operator Because it can be notified, it is possible to solve the time waste, such as going to the field, and to check the optical cable failure periodically without checking the optical cable failure in the optical end station, it can find and notify the optical cable failure that the optical end station does not detect, the optical cable test By separately measuring the state of the fiber, the device obtains the effect of statistically managing the change of the state of the fiber.

Claims (5)

A real-time optical cable connected to an optical transmission system including an optical end station for signal conversion, a signal generation, and an optical transmission; an optical distribution box connected to the optical end station to perform connection, connection site protection, and distribution; In the surveillance system, An optical cable control server connected to the optical end station; An optical cable test apparatus driven by the optical cable control server, connected to the optical distribution box, performing an error measurement on the optical cable connected to the optical distribution box, obtaining a measurement waveform, and providing the measurement waveform to the optical cable control server; And It includes a surveillance monitor driven by the optical cable control server to provide a user interface, The optical cable control server remotely accesses the optical end station every first period to obtain a transmission / reception level of the optical signal for each optical cable stored in the optical end station, and if it is determined that the optical cable has failed through the information obtained from the optical end station, Real-time optical cable monitoring system, characterized in that the drive to obtain the measurement waveform of the region where the failure occurs and to determine whether the failure occurs and the point of failure through the measurement waveform. The method of claim 1, The optical cable control server drives the optical cable test apparatus every second cycle to measure the state of each optical cable to identify at least one of failure occurrence and failure point. The method according to claim 1 or 2, Determining whether the optical cable control server is a failure through the transmission and reception level for the corresponding optical cable obtained from the optical end station, after comparing the obtained transmission and reception level with a previous value or a reference value, if the transmission and reception level changes, it is determined that the optical cable failure. Real-time optical cable monitoring system, characterized in that. The method according to claim 1 or 2, The optical cable control server determines whether a failure occurs through the transmission / reception level for the corresponding optical cable obtained from the optical end station, after comparing the obtained transmission / reception level with a previous value or a reference value, the transmission / reception level is changed, and the change value is set. Real-time optical cable monitoring system, characterized in that it is determined that the optical cable failure is greater than the threshold value. The method of claim 4, wherein The optical cable test apparatus is a real-time optical cable monitoring system, characterized in that for measuring the failure of the optical cable using the OTDR (Optical Time Domain Reflectometer) measuring method.

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