KR20110077749A - Intelligent monitoring system for optical path - Google Patents

Abstract

PURPOSE: An intelligent monitoring line system is provided to watch over whether an abnormality of a line independently. CONSTITUTION: A remote monitoring apparatus comprises a receiver(21), a critical value DB(22), a calculation unit(23) and an alarm unit(24). A receiver receives an optical power value that is transmitted from a transmission unit of a optical signal measure system. The critical value DB stores the critical value about the optical power value that exceeds a normal range. The calculation unit decides whether the abnormality of the line by mutually comparing the critical value saved in the critical value DB with the optical power value received in receiver. The alarm unit informs the abnormality of the line to administrator in case the abnormality of the line is decided.

Description

INTELLIGENT MONITORING SYSTEM FOR OPTICAL PATH}

The present invention relates to an intelligent line monitoring system, and more particularly, unlike an optical fiber tester (OTDR), which is a relatively expensive device that monitors a line through a feedback signal reflected and installed on a carrier for transmitting an optical signal. An optical signal measuring device connected to an optical splitter for distributing optical signals to a plurality of subscribers as end terminals and receiving a part of the optical signal to calculate an optical power value, and thresholding the optical power value calculated by the optical signal measuring device at a remote location By providing a remote monitoring device that can determine whether there is a line abnormality against the value DB and notify the administrator, it can independently monitor the line abnormality without affecting the system and data transmission of the service provider, and the optical fiber tester Compared to the OTDR, the manager can effectively judge the abnormality of the track even with relatively inexpensive equipment. The present invention relates to an intelligent line monitoring system that can prevent and quickly recover from a communication failure by notifying a user of the problem.

The current communication system is shifting from the conventional coaxial cable method to the optical communication method using an optical fiber due to the rapid growth of the FTTH high-speed communication network for services such as IPTV and VoIP.

Therefore, the quality reliability of the optical fiber becomes more important now, and there is a demand for a system capable of preventing communication failures in advance and recovering quickly in the event of a failure.

In Japan, for example, the rate of optical service failures is about twice as high as that of coaxial cable services. In view of this, the optical network is judged to have an abnormality in the optical network line in order to guarantee the quality of communication to subscribers. We can see that it's time for a more capable line-monitoring system.

On the other hand, optical fiber network lines established between the service provider side and the subscriber side inevitably cause optical path loss due to various factors such as physical and chemical factors.

That is, as shown in Figs. 4 to 5, the loss of the optical path is due to excessive tension due to poor pipe, loss change due to water penetration in the manhole, in-pipe side pressure due to road construction, cable aging, ground subsidence, vibration, etc. It is caused by several complex factors.

As a method for recognizing an optical communication network failure due to the optical path loss, a method of installing an optical time domain reflectometer (OTDR) may be used on a carrier.

The optical fiber tester (OTDR) is a light pulse incident on the optical fiber, and analyzes the distance distribution of the amount of light reflected and returned from each point in the fiber length direction to lose the optical fiber, the distance to the connection point and the connection loss, the amount of reflection from the connection point, Refers to a mechanism for measuring the distance to the break point when the fiber breaks.

6 illustrates a basic principle of monitoring an optical path in an optical fiber tester (OTDR) according to the prior art. Referring to the drawings, an optical signal from an LD (Laser Diode) is returned by Rayleigh, Raman scattering and Fresnel reflection (feedback). Signal) is received as a PD (photo diode) and represented as a time (or distance) axis and a magnitude axis of the signal as shown in FIG.

However, the optical fiber tester (OTDR) is an expensive device and has a limitation in constructing a device capable of monitoring all the circuits provided by the telecommunications carrier. The structure is complicated in the way of determining the abnormality of the circuit through the signal, and there is a problem that the equipment should be concentrated in the service provider side system and a separate signal for monitoring may affect the data transmission.

The present invention has been made to solve the problems of the prior art as described above, an object of the present invention is installed at the end of the optical path to receive a portion of the optical signal, calculate the optical power value from the received optical signal, and calculate By comparing the optical power value with the threshold DB, it is possible to monitor the abnormality of the line independently without affecting the operator's system and data transmission by constructing a system that can notify the administrator by determining the abnormality of the line. In addition, the present invention provides an intelligent line monitoring system that can effectively prevent communication failures and quickly recover by informing a manager by effectively determining whether there is an abnormality in a line even as a relatively inexpensive equipment compared to an optical fiber tester (OTDR).

In order to achieve the above object, the intelligent line monitoring system according to the present invention monitors an abnormality of an optical communication network line for distributing an optical signal transmitted from a telecommunications operator through an optical path in an optical distributor and transmitting the optical signal to a plurality of subscribers, respectively. An optical signal input unit connected to the optical splitter, the optical signal input unit for receiving a part of an optical signal transmitted from the carrier side to each of the plurality of subscribers and transmitting the rest to the plurality of subscribers. An optical signal measuring device including a micom unit for calculating an optical power value from the optical signal input to the signal input unit, and a transmitter for transmitting the optical power value calculated by the microcomputer unit; A receiver installed at a remote location, the receiver capable of receiving an optical power value transmitted from a transmitter of the optical signal measuring apparatus, a threshold DB storing a threshold value for an optical power value exceeding a normal range, and received by the receiver Comprising a comparison of the optical power value and the threshold stored in the threshold DB and the operation unit for determining the presence or absence of a line abnormality, and the remote monitoring device is provided with an alarm unit for notifying the administrator when the line abnormality is determined by the operation unit; It is characterized by.

In addition, the intelligent line monitoring system according to the present invention, the optical signal input unit, a plurality of photodiodes for converting the received optical signal into an electrical signal, and the electrical signal converted in each photodiode respectively converted into a digital signal And a multiplexer for single outputting each digital signal converted by the AD converter.

In addition, in the intelligent line monitoring system according to the present invention, the threshold DB is divided into an upper limit threshold value and a lower limit threshold value, wherein the upper limit threshold value and the lower limit threshold value are respectively set to have a predetermined range. The optical power value received by the receiving unit is characterized in that it is determined as a line check request if it falls within the range of the upper limit threshold value or the lower limit threshold value of the threshold DB.

In addition, the intelligent line monitoring system according to the present invention is characterized in that the threshold DB is calibrated based on the optical power value received by the receiver immediately after the initial installation or maintenance of the optical communication network line.

By the above configuration, the intelligent line monitoring system according to the present invention can independently monitor the abnormality of the line without affecting the service provider side system and data transmission, and is relatively inexpensive compared to the optical fiber tester (OTDR). As equipment, it is effective to effectively detect the abnormality of the line and notify the administrator to prevent and quickly recover the communication obstacles.In particular, it is necessary to determine the line inspection request in case of the occurrence of the failure even if it is not the failure of the optical communication network line. Therefore, the communication failure can be prevented in advance, and the threshold value is calibrated based on the optical power value immediately after the initial installation or maintenance of the optical communication network line, so that it can be widely applied to systems with different environments.

Hereinafter, an intelligent line monitoring system according to the present invention will be described in detail with reference to the embodiment shown in the drawings.

1 is a block diagram of an intelligent line monitoring system according to an embodiment of the present invention, Figures 2 and 3 is an exemplary view of a display of a remote monitoring system according to an embodiment of the present invention.

Referring to the drawings, an intelligent line monitoring system according to an embodiment of the present invention distributes an optical signal transmitted from a carrier side (A) through an optical path in an optical splitter (B) to deliver each to a plurality of subscriber sides (C). An optical signal measuring apparatus 10 and a remote monitoring apparatus 20 are configured as a system for monitoring an abnormality of an optical communication network line.

The optical signal measuring device 10 is connected to the optical splitter B for distributing optical signals to the plurality of subscriber sides C, which are ends of the optical path, and includes an optical signal input unit 11, a microcomputer unit 12, And a transmitter 13, an input / output unit 14, an I / O interface 15, and a power module 16.

The optical signal input unit 11 includes a photodiode 111, an AD converter 112, and a multiplexer 113 in which a part of the optical signal transmitted from the communication service provider A is input. do.

The photodiode 111 is provided in plural and partly receives an optical signal transmitted from the telecommunication service provider side A to the plurality of subscriber sides C, and the other part is transmitted to the plurality of subscriber sides C. However, it is a configuration that converts the received optical signal into an electrical signal.

In one embodiment of the present invention, 16 photodiodes 111 are provided so that one optical signal measuring apparatus 10 can simultaneously operate 16 channels as shown in the drawing, and is transmitted from a carrier. Only 5% of the optical signal, which is a part of the optical signal 100%, is input, and the remaining 95% of the optical signal is configured to be transmitted to the plurality of subscriber side C as it is.

The AD converter 112 is configured to convert the electrical signals converted by the respective photodiodes 111 into digital signals.

The multiplexer 113 is configured to single output each digital signal converted by the AD converter 112 to the microcomputer 12.

The micom unit 12 calculates an optical power value from the optical signal input to the optical signal input unit 11. In the exemplary embodiment of the present invention, the optical signal is electrically transmitted through the photodiode 111. The digital signal is converted into a signal, and is converted into a digital signal through the AD converter 112, and the optical power value is calculated for each channel by receiving a single output digital signal through the multiplexer 113.

Since the optical power value calculated by the microcomputer 12 is simply calculated by a program programmed in the microcomputer 12 from the input digital signal, detailed description thereof will be omitted.

The transmitting unit 13 is configured to transmit the optical power value calculated by the microcomputer 13 to the remote monitoring apparatus 20. The RS232 port or the TCP / IP port via the I / O interface 15 as a medium. It will be connected to the receiver 21 of the remote monitoring device 20 by using.

The input / output unit 14 checks the connection state of the optical signal measuring apparatus 10 through an LED block, checks the optical power value calculated by the microcomputer 12 through an LCD, and the like. It is a configuration that can input a set value, etc. through the I / O interface 15 as a medium is connected to the microcomputer 12, the power module 16 is a power supply to the optical signal measuring device 10 It is a configuration to supply.

Unlike the conventional optical fiber tester (OTDR), due to the configuration of the optical signal measuring device 10 is connected to the optical splitter (B) and receives a portion of the optical signal to calculate the optical power value (A) system and data It is possible to monitor the abnormality of the track independently without affecting the transmission.

The remote monitoring device 20 is connected to the optical signal measuring device 10 and configured to monitor the presence or absence of a line abnormality at a remote location with a receiving unit 21, a threshold DB 22, a calculating unit 23 and And an alarm unit 24 and a display unit 25.

That is, the remote monitoring device 20 may be installed in the communication service provider side A located at a remote location as a terminal device such as a PC, but in the case of an apartment, the MDF room or management where the optical distributor B is located. It may be installed in an office or the like.

The receiving unit 21 is configured to receive the optical power value transmitted from the transmitting unit 13 of the optical signal measuring apparatus 10, and transmits the received optical power value to the calculating unit 23.

The threshold DB 22 is a configuration in which a threshold for an optical power value exceeding a normal range is stored, and is divided into an upper limit threshold and a lower limit threshold, and the upper limit threshold and the lower limit threshold are in a predetermined range. Is automatically calibrated by programming on the basis of the optical power value received by the receiver 21 immediately after the initial installation or maintenance of the optical network line, as shown in FIG. It is calibrated by

That is, the threshold value DB 22 may prevent the communication failure in advance by determining that the upper limit threshold value and the lower limit threshold value have a predetermined range so that the calculation unit 23 determines not only a line fault but also a line check request. By being able to calibrate, even if the construction environment of the optical communication line is different, it is possible to monitor the abnormality of the circuit based on the reference value immediately after the initial installation or repair of the optical communication line.

The calculating part 23 compares the optical power value received by the receiving part 21 with the upper limit threshold value and the lower limit threshold value stored in the threshold DB 22 to determine whether there is a line abnormality.

That is, the calculation unit 23 determines that the line is normal when the optical power value received by the receiver 21 is between the upper limit threshold and the lower limit threshold stored in the threshold DB 22, and the receiver 21 If the optical power value received as the optical power value exceeds the upper limit threshold stored in the threshold value DB 22 or less than the lower limit threshold, the line abnormality is determined, the optical power value received by the receiver 21 In the case of the upper limit threshold value or the lower limit threshold value stored in the threshold DB 22, the circuit check request is determined.

The alarm unit 24 is configured to notify the administrator when a line abnormality or a line check request is determined by the operation unit 23 to display a warning message of the display unit 25 with an alarm sound, or more aggressively. You can also configure it to send an alert SMS to the administrator.

Due to the configuration of the remote monitoring device 20 as described above, it is possible to effectively determine whether there is an abnormality in the line and notify the manager to prevent and promptly recover a communication failure, and even if there is a failure of the optical communication line, a failure sign occurs. In this case, it is possible to prevent communication failure in advance by judging the line inspection request, and the threshold value is calibrated based on the optical power value immediately after the initial installation or repair of the optical communication network line. The line monitoring system can be widely applied.

The intelligent line monitoring system described above and shown in the drawings is only one embodiment for implementing the present invention, and should not be construed as limiting the technical idea of the present invention. The scope of protection of the present invention is defined only by the matters set forth in the claims below, and the embodiments which have been improved and changed without departing from the gist of the present invention will be apparent to those skilled in the art. It will be said to belong to the protection scope of the present invention.

1 is a block diagram of an intelligent line monitoring system according to an embodiment of the present invention

2 and 3 are exemplary views of a display of a remote monitoring system according to an embodiment of the present invention.

4 and 5 are explanatory diagrams for the optical network system and the optical fiber loss factor

6 and 7 are reference diagrams of a line monitoring system using an optical fiber tester (OTDR) according to the prior art.

<Short description of the major reference symbols>

10 Optical Signal Measuring Device

     11 Optical signal input unit

     12 Micombu

     13 Transmitter

     14 I / O part

20 Remote Monitoring Device

     21 receiver

     22 Threshold DB

     23 calculator

     24 alarm

     25 Display

Claims (4)

In the line monitoring system for monitoring the abnormality of the optical communication network line for distributing the optical signal transmitted from the telecommunications provider side through the optical path in the optical splitter to each of the subscribers, An optical signal input unit connected to the optical splitter, wherein an optical signal input unit receives a part of an optical signal transmitted from the telecommunication service provider side to the plurality of subscriber sides, and transfers the rest to the plurality of subscriber sides, and an optical signal input to the optical signal input unit An optical signal measuring device including a micom unit configured to calculate an optical power value at a second transmission unit, and a transmitter configured to transmit the optical power value calculated at the microcomputer unit; A receiver installed at a remote location, the receiver capable of receiving an optical power value transmitted from a transmitter of the optical signal measuring apparatus, a threshold DB storing a threshold value for an optical power value exceeding a normal range, and received by the receiver Comprising an optical power value and the threshold value stored in the threshold DB and a calculation unit for determining whether there is a line abnormality, and the remote monitoring device is provided with an alarm unit for notifying the administrator when the line abnormality is determined by the operation unit; Intelligent line monitoring system, characterized in that The method of claim 1, The optical signal input unit includes a plurality of photodiodes for converting the received optical signal into an electrical signal, an AD converter for converting the electrical signals converted from the respective photodiodes into digital signals, and a conversion in the AD converter. Intelligent line monitoring system comprising a multiplexer for outputting each of the digital signals. The method according to claim 1 or 2, The threshold DB is divided into an upper limit threshold and a lower limit threshold, wherein the upper limit threshold and the lower limit threshold are each set to have a predetermined range, The operation unit, if the optical power value received by the receiving unit falls within the range of the upper limit threshold value or the lower limit threshold value of the threshold DB, intelligent circuit monitoring system, characterized in that the judging request . The method of claim 3, And the threshold DB is calibrated based on the optical power value received by the receiver immediately after the initial installation or maintenance of the optical communication network line.

Images