KR20040039509A - Monitoring system of optical communication network - Google Patents

Abstract

PURPOSE: A system for monitoring an optical communication network is provided to efficiently monitor a fault in an optical communication network and to swiftly catch a fault point in case that a fault occurs. CONSTITUTION: A system for monitoring an optical communication network comprises a test signal transmitter(100), a test signal receiver(200), an optical switch(400), an OTDR(500), and a management module(300). The test signal transmitter(100) receives the status information of the second optical communication equipment(21) or the environmental information of a remote communication station, loads it on the second optical signal, and transmits it through the first optical line(31). The test signal receiver(200) receives the second optical signal from the first optical line(31) and extracts the status information of the second optical communication equipment(21) and the line loss information of the remote communication station and an optical line. The optical switch(400) is installed so as to be connected with the second optical line(32). The OTDR(500), installed so as to be connected or disconnected with the second optical line(32), uses a different wavelength from the first and second optical signals. The management module(300), installed so as to be connected to the test signal receiver(200), the optical switch(400), and the OTDR(500), receives the line loss information, extracted from the test signal receiver(200), and controls the operations of the optical switch(400) and the OTDR(500).

Description

Monitoring system of optical communication network

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical communication network monitoring system, and more particularly, to an optical communication network monitoring system capable of finding obstacles such as optical communication equipment and finding bending portions or cutting portions of optical paths.

As the demand for high traffic data and high communication speed increases, the spread of optical communication networks is increasing. Optical communication network is a medium capable of transmitting a large amount of data at high speed, and is recognized as the ultimate alternative to the wired communication network. As such, as the proportion of optical communication networks using optical paths increases, the obstacles of optical communication networks may cause serious problems economically and socially compared to existing communication networks. Therefore, by diagnosing the obstacles of the optical network and monitoring the failure efficiently, it is possible to prevent service interruption due to the failure of the optical network, and to quickly identify and recover the point of failure when the optical network fails. It is a very important key to increase the reliability of the network.

However, conventionally, there is no monitoring means capable of immediately grasping the point of failure and the contents of the failure, for example, the line handicapped power supply or the device handicapped in the light beam section, in particular, the subscriber network section.

Accordingly, the present invention has been made in an effort to provide an optical communication network monitoring system for diagnosing obstacles of an optical communication network, efficiently monitoring failures, and quickly identifying a failure point when an error occurs in an optical communication network.

1 to 3 are diagrams for describing an optical communication network monitoring system according to embodiments of the present invention.

According to an embodiment of the present invention for achieving the above technical problem, the first optical communication equipment 11 installed in the base communication station, the second optical communication equipment 21 installed respectively in the remote communication station, and the first optical communication equipment and A monitoring system for monitoring an optical communication network comprising a first optical path 31 connecting the second optical communication equipment and transmitting a first optical signal carrying traffic information includes: status information of the second optical communication equipment 21 and And / or receives environmental information of the remote communication station, and is loaded on the second optical signal λ ₂ having a wavelength different from that of the first optical signal λ ₁ on which the traffic information is carried, through the first optical path 31. A test signal transmitter 100 for transmitting; It is connected to the first optical path 31 by a second optical path 32, receives the second optical signal λ ₂ from the first optical path 31, the status information of the second optical communication equipment A test signal receiver 200 for extracting line loss information of the remote communication station and the optical path; An optical switch 400 installed to be connected to the second optical path 32; It is installed to be connected to or short-circuited with the second optical path 32 by the operation of the optical switch 400, and the wavelength λ ₃ different from the first optical signal λ ₁ and the second optical signal λ ₂ . OTDR 500 using; It is installed to be connected to the test signal receiver 200, the optical switch 400 and the OTDR 500, respectively, the line loss information extracted from the test signal receiver 200 receives the OTDR (500) and the optical It characterized in that it comprises a management module 300 for controlling the operation of the switch 400.

In this case, when a plurality of optical communication networks including the first optical communication device 11, the second optical communication device 21, and the first optical path 31 are formed, the test signal transmitter 100 and the second A plurality of optical paths 32 and test signal receivers 200 are provided in a one-to-one correspondence with the optical communication network; The management module 300, the optical switch 400 and the OTDR 500 are integrated to be used so that the management module 300 is connected to the test signal receivers 200, respectively, the optical switch 400 is Any one selected from the second optical lines 32 under the control of the management module 300 and installed to connect each of the OTDR 500 and the second optical lines 32 in a 1xN type and the OTDR It is characterized in that it is operated to connect the 500.

According to another embodiment of the present invention for achieving the above technical problem, a plurality of first optical communication equipment 11 installed in a base communication station, a plurality of second optical communication equipment 21 installed in a remote communication station, and the first The monitoring system for monitoring an optical communication network comprising a plurality of first optical paths 31, 31 ', 32 "connecting the optical communication equipment and the second optical communication equipment one-to-one and transmitting a first optical signal containing traffic information. The first optical signal λ provided to correspond to the second optical communication equipment 21 in a one-to-one manner, receiving state information of each second optical communication equipment and environmental information of the remote communication station, and carrying the traffic information. A test signal transmitter (100) which is carried in each of the first optical paths (31, 31 ', 31 ") on a second optical signal [lambda] ₂ having a wavelength different from ₁ ); A plurality of second optical paths (32, 32 ', 32 ") connected one-to-one with said first optical paths (31, 31', 31"); A test signal receiver configured to receive the second optical signal from the first optical lines 31, 31 ′, and 31 ″, respectively, and to extract the state information of the second communication equipment, the remote communication station, and the line loss information of the optical lines; 200); One side is connected to each of the second optical paths 32, 32 ′, 32 ″ and the other side is connected to the test signal receiver 200 by a third optical path 33, wherein the second optical paths 32 32 ', 32') and 1xN optical switch 400 'periodically connecting the test signal receiver 200; The OTDR 500 is connected to the third optical path 33 by a coupler 43 and uses a wavelength λ ₃ different from the first optical signal λ ₁ and the second optical signal λ ₂ . and; The management module 300 is installed to be connected to the test signal receiver 200 and the OTDR 500, respectively, and receives the line loss information extracted from the test signal receiver 200 to control the operation of the OTDR 500. It is characterized by including a).

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

1 is a schematic diagram illustrating an optical communication network monitoring system according to a first embodiment of the present invention, Figure 2a is a block diagram illustrating a test signal transmitter in the optical communication network monitoring system according to Figure 1, Figure 2b 1 is a block diagram illustrating a test signal receiver in the optical network monitoring system according to FIG. 1, FIG. 2C is a block diagram illustrating a management module in the optical network monitoring system according to FIG. 1, and FIG. 3 is a second embodiment of the present invention. A schematic diagram illustrating an optical communication network monitoring system according to an example.

Example 1

Referring to FIG. 1, the optical communication network to be monitored includes at least one remote communication station located at least one to several tens of kilometers away from one base communication station. And a monitoring system of an optical communication network includes a test signal transmitter 100, a test signal receiver 200, a management module 300, an optical switch 400, and an optical time domain reflectometer (OTDR ). 500 and optical paths connecting them respectively.

The equipment installed in the telecommunication station or the base communication station may differ depending on whether the communication network to which the communication station belongs is a wired communication network or a mobile communication network, and may also vary depending on the function of the communication station. However, the telecommunication station and the base station have at least optical communication equipments 11 and 21, such as optical repeaters or optical end stations, for transmitting and receiving traffic information to each other in an optical communication method, and a 2-way wavelength division multiplexer for transmitting optical signals in both directions (2). It is common for basic optical communications equipment such as -way wavelength division multiplexer (WDM) (12, 22) to be installed. In particular, although not shown in the remote communication station, commercial power equipment, rectifier rectifying commercial power to DC power to supply power to various equipment in the country, battery or uninterruptible power supply to supply emergency power in case of commercial power failure ( Power supplies such as UPS) are installed. Since the remote communication station is generally operated in an unmanned manner, in order to provide stable operating conditions of various communication equipment, power supply equipment, and other facilities in the communication station, for example, a thermo-hygrostat, a cooling fan, a leak sensor, a fire sensor, and a door sensor. It is common to have more facilities installed.

As such, the first optical path 31 connecting the base communication station and the remote communication station, the various communication equipments 21 and 22, the power supply equipment, and other environmental equipment in the remote communication station may fail in normal communication. Monitoring of these potential failures is necessary because they can have large and small negative impacts. The status information or environmental information, which is such a failure factor and is to be monitored, may be expressed as either a digital input (DI) or an analog input signal (AI) according to its characteristics.

Examples of digital input signals include an alarm signal indicating whether a rectifier or UPS equipment has failed, a signal indicating whether a commercial power supply has failed, a signal indicating whether a door is opened or closed, a signal indicating a state of various switches, or an optical communication equipment. Signals indicating whether a failure of various equipment installed therein, and the like, and the like, these are all digital values in that they are represented by two-state value, such as On (On) or Off (Off). Multiple relays are employed to secure the digital input signals, and each relay has an electrical connection with the checkpoint of each equipment to be monitored in the Telecommunication Station. For example, when a failure occurs in the commercial power supply, and a state in which commercial power is not supplied, a relay connected thereto operates to be provided to the control unit 120 of the test signal transmitter 100 described below as one of the digital input signals. If you have built-in relay among devices, you can use the built-in relay.

On the other hand, examples of analog input signals include physical quantities such as voltage and current of commercial power supplies, output current and output voltage of rectifiers, RF power, output of optical communication equipment, temperature and humidity in communication stations, and the like. In the above example, the digital or analog input signal is merely exemplary and may include information to be added or excluded according to the conditions of the telecommunication station.

The digital and analog type status information and environmental information that can be secured by such a telecommunication station are transmitted to the test signal transmitter 100 of the telecommunication station through the contact unit 23 that provides a signal contact point, thereby transmitting the first optical path 31. ), It is used as basic information for monitoring the optical communication equipment (21, 22) and environment of the remote telecommunication station.

One test signal transmitter 100 is installed for each telecommunication station, and the test signal receiver 200 is installed in a common base communication station that manages the telecommunication station so as to correspond one-to-one with each test signal transmitter 100.

Referring to FIG. 2A in conjunction with FIG. 1, the test signal transmitter 100 may transmit various signals including the above-described state information and environment information transmitted through the contact unit 23 to a specific wavelength λ _1. ) Is made into an optical signal (hereinafter referred to as a second optical signal) having a wavelength λ ₂ different from that of the optical signal (hereinafter referred to as a first optical signal), and multiplexed with a first optical signal carrying traffic information. It transmits to a base station through the 1st optical path 31.

The test signal transmitter 100 includes an input unit 110, a controller 120, and a second optical signal generator 130, and is connected to the first optical path 31 by the first WDM coupler 41. . The input unit 110 receives the state information and / or the environmental information that the contact unit 23 obtains from various equipments or environmental monitoring sensors of a remote communication station and provides them in the form of digital input signals and analog input signals, and receives them as digital data. It converts and provides a role. The input unit 110 includes a digital input unit and an analog input unit separately. The digital input unit includes a DI input terminal to which a digital input signal is applied and a DI interface for interfacing the digital input signal input through the digital input signal into a signal that can be read by the controller. The analog input unit is composed of an AI input terminal to which the analog input signal is applied and an A / D converter converting the analog input signal into a digital signal. The controller 120 includes a CPU, a memory, and a clock generator. The CPU of the controller 120 buffers the digital data provided from the DI interface and the A / D converter, respectively, into the memory, extracts the data buffered in the memory, and loads the data into the test signal DO. In addition, the controller 120 needs to install software necessary for such data processing. The second optical signal generator 130 receives the test signal DO output from the controller 120 and generates and outputs a second optical signal corresponding to the data value. To this end, the second optical signal generator 130 receives the laser diode outputting the optical signal corresponding to the driving signal and the test signal DO provided by the controller 120 as an input signal and receives the corresponding driving signal as the laser diode. It is configured to include a driving circuit provided to. The second optical signal generated by the second optical signal generator 130 should have a wavelength λ ₂ whose wavelength is different from the wavelength λ ₁ of the first optical signal. This allows the test signal receiver 200 to extract only the second optical signal λ ₂ from the multiplexed optical signal of the first optical signal λ ₁ and the second optical signal λ ₂ by using a wavelength difference. For sake. The second optical signal λ ₂ generated by the second optical signal generator 130 is transmitted to the first WDM coupler 41. The first WDM coupler 41 is the first optical signal λ ₁ generated by the first optical communication equipment 21 installed in the remote telecommunication company and the second optical signal λ output by the second optical signal generator 130. ₂ ) is multiplexed and transmitted to the base communication station through the first optical line 31. The test signal transmitter 100 may further include a power module and a battery, so that the test signal transmitter may be driven by a commercial power source, but the second optical signal may be sent to the base communication station even when the commercial power supply fails and is not normally supplied. . In addition, the test signal transmitter 100 may be manufactured as an independent module by embedding each component described above in a case. In this case, it further comprises an LED and an LED driver, and the controller 120 is configured to provide a signal indicating whether the normal operation of each component to the LED driver 450 according to the value of the digital input signal and the analog input signal.

Referring to FIG. 2B in conjunction with FIG. 1, the second optical path 32 is formed by the second WDM coupler 42 through which the first optical signal λ ₁ and the second optical signal λ ₂ are flowed. It is connected to the first optical path 31, the test signal receiver 200 is connected to the second optical path (32). The second WDM coupler 42 uses the first optical signal using a wavelength difference from the multiplexed optical signal of the first optical signal λ ₁ and the second optical signal λ ₂ transmitted through the first optical path 31. The signal λ ₁ is sent to the base station, and the second optical signal λ ₂ is extracted and sent to the test signal receiver 200. The test signal receiver 200 receives only the second optical signal λ ₂ and converts it into an electrical signal, and converts the analog input signal AI and the digital input signal transmitted from the transmitter from the converted electrical signal, that is, the various devices of the remote communication station. Extract data of status information and / or environmental information. In addition, by measuring the output strength of the electrical signal to extract the line loss information of the first optical path (31). The extracted information is transmitted to the management module 300 through the communication unit.

The test signal receiver 200 includes an optical-electric signal converter 210, an A / D converter 220, a controller 230, and a communication unit 240. The second optical signal λ ₂ extracted from the second WDM coupler 42 is provided to the optical-electrical signal converter 210, and the first optical signal passes through the 2-way WDM 12 to the first optical communication equipment ( 11) is delivered. The optical-electric signal converter 210 receives the second optical signal λ ₂ and converts it into an analog electrical signal corresponding thereto. The optical-electric signal conversion unit 210 may be configured using, for example, a photodiode and a conversion circuit coupled thereto for such signal conversion. According to this configuration, the second optical signal is an analog electric signal having a size of 4 to 20 mA. Is converted to. The analog electric signal is sampled through the A / D converter 220 and converted into a digital signal corresponding to the level. The controller 230 receives a digital signal from the A / D converter 220 and outputs the state information and the output information of the second optical signal λ ₂ necessary to calculate the line loss data of the optical path therefrom. And / or extracts and buffers the environment information into a memory and outputs the buffered data. The controller 230 includes a CPU, a memory, and a clock generator. In addition, the controller 230 is installed with software for the necessary data processing. The communication unit 240 interfaces the communication between the management module 300 and the control unit 230 through a management network such as X25, TCP, ASYNC, or the like. The test signal receiver 200 further includes a power module and a battery as in the case of the test signal transmitter 100, and may be manufactured as an independent module by embedding the various components described above in a case, and further include an LED and an LED driver. Can be.

Referring to FIG. 2C in conjunction with FIG. 1, the management module 300 stores optical information (dB) information of the monitored first optical path 31 while storing and managing information received from the test signal receiver 200 in a database. The first optical path 31 is used to determine whether the current state is normal or abnormal. The optical power (dB) value obtained by the test signal receiver 200 is a total of reflecting the connection loss at each contact point, the loss by the WDM coupler, and the transmission loss by the optical paths 31 and 32 at a specific point in time. Transmission loss. Here, the connection loss excluding the transmission loss by the optical path 31 is information that can be secured in advance by calculation or measurement based on the characteristics of each equipment. Therefore, the loss remaining after subtracting the connection loss from the optical power (dB) value obtained by the test signal receiver 200 (that is, the total transmission loss) is the optical path, in particular, the transmission actually induced by the first optical path 31 at a specific point in time. It is a loss. When the actual transmission loss of the first optical path 31 exceeds the allowable limit, the management module 300 outputs an operation signal for operating the optical switch 400 and the OTDR 500 to output the optical path, in particular, the first optical beam. Find the bending or cutting part of the furnace (31).

The management module 300 is a control unit 320 and each communication unit 311, 312, 313, 314 capable of communicating with the test signal receiver 200, the optical switch 400, the OTDR 500 and the central monitoring station, respectively. It includes. The controller 320 includes a CPU, a memory, and a clock generator. The CPU of the control unit 320 buffers the digital data provided through the communication unit 311 connected to the test signal receiver 200 in the memory and extracts the data buffered in the memory to allow the actual transmission loss of the optical path. In case of exceeding the OTDR 500 and the optical switch 400 serves to output the operation signal for operating.

The optical switch 400 is connected to the first optical path 31 and the OTDR (operated by the operation signal of the management module 300) connected to the first optical path 31 of which the actual transmission loss exceeds the allowable limit. 500) to connect or short-circuit. A third WDM coupler 43 is installed at the contact point of the optical switch 400 and the second optical path 32.

The OTDR 500 is operated by an operation signal of the management module 300, and is connected to the second optical path 32 through the second optical path 32 connected by the optical switch 400. The bending part or the cutting part of 31) is found. At this time, the OTDR 500 uses an optical signal having a wavelength λ ₃ different from that of the first optical signal λ ₁ and the second optical signal λ ₁ .

The test signal transmitter 100, the test signal receiver 200, and the management module 300 are described as an example and are not necessarily limited thereto. In particular, their respective controls 120, 230, 320 vary in their choice with regard to how they can be configured. For example, a device such as a microcomputer or a programmable logic controller (PLC) in which devices such as a CPU, a memory, and a clock generator are all integrated may be utilized.

Subsequently, the operation of the monitoring system for the optical communication network according to the present embodiment will be described.

When the state information and environmental information of the remote telecommunication station are input to the test signal transmitter 100, the information is made of a second optical signal having a wavelength different from that of the first optical signal on which the traffic information is carried, and the traffic information is loaded. It is multiplexed with one optical signal and transmitted via a first optical path 31 used for communication between a remote communication station and a base communication station. Then, the test signal receiver 200 connected to the first optical path 31 by the second optical path 32 extracts only the second optical signal, and then extracts data of status information and / or environmental information of the remote communication station. And, by measuring the output strength of the electrical signal to extract the line loss information of the first optical path 31, and transmits the extracted information to the management module 300 through the communication unit 240. The management module 300 transmits the received data to the central monitoring station so that the transmitted data can be monitored. If the actual transmission loss of the first optical line 31 exceeds the allowable limit, the OTDR 500 and the optical fiber are automatically transmitted. Outputs an operation signal for operating the switch 400. According to the operation signal generated from the management module 300, the OTDR 500 finds the bending part or the cutting part of the first optical path 31 through the optical switch 400. Then, if an element that causes a failure in the communication equipment (21, 22) is found from the data monitored by the central monitoring station, the technician or the like is dispatched to the remote communication station to take immediate action.

Meanwhile, referring back to FIG. 1, in general, a plurality of optical communication networks including one optical communication device of a base communication station, one optical communication device of a remote communication station, and a first optical path connecting them with one base communication station are formed. In this case, a test signal transmitter, a second optical path and a test signal receiver are connected to each first optical path. However, the management module and the OTDR are integrated and provided as one, and the optical switch is installed with a 1xN type to connect the OTDR with the first optical path exceeding the allowable transmission loss among the first optical paths by the operation signal of the management module 300. I will let you.

Example 2

The optical network monitoring system according to the present embodiment has the biggest difference from the first embodiment in that only one test signal receiver is integrally used. Therefore, only the connection relationship between the test signal receiver, the management module, the optical switch, and the OTDR and the configuration of the optical switch and the management module are different from those in the first embodiment, and otherwise, the repeated description is omitted.

Referring to FIG. 3, an optical communication network including an optical communication device 21 of a base communication station, an optical communication device 11 of a remote communication station, and first optical paths 31, 31 ′, 31 ″ connecting them with respect to one base communication station. A plurality of these are formed, and the test signal transmitter 100 and the second optical paths 32, 32 ', and 32 "are respectively connected to each of the first optical paths 31, 31', and 31".

The optical switch 400 'is a 1xN type in which one side is connected to each of the second optical paths 32, 32' and 32 ″ and the other side is connected to the test signal receiver 200 by the third optical path 33. As a result, each of the second optical paths 32, 32 ′, 32 ″ is periodically connected to the test signal receiver 200. That is, the optical switch 400 ′ does not connect each of the second optical paths 32, 32 ′, and 32 ″ and the test signal receiver 200 by control, and sequentially, but periodically, each of the second optical paths ( 32, 32 ', 32 ") and the test signal receiver 200 are programmed to be connected. Therefore, when the second optical signal transmitted from each test signal transmitter 200 is sequentially received by the test signal receiver 200 via the optical switch 400 ', the test signal from the second optical signals sequentially received. The receiver 200 extracts status information and / or environmental information of each telecommunication station and line loss information of each first optical path (31, 31 ', 31 ″), and extracts the extracted information through the communication unit. It sequentially transmits to the management module 300 '.

The management module 300 ′ buffers the digital data provided through the communication unit connected to the test signal receiver 200 in the memory, and simultaneously extracts the data buffered in the memory, thereby extracting the first optical paths 31, 31 ′, and 31. If the actual transmission loss of ″) exceeds the allowable limit, it outputs an operation signal for operating the OTDR 500. The management module 300 'according to the present embodiment eliminates the need for a communication unit with the optical switch 400' in the management module 300 according to the first embodiment, and does not require the control of the optical switch 400 '. .

The OTDR 500 is connected to the third optical line 33 connecting the optical switch and the test signal receiver 200 by the WDM coupler 43, and is operated by the operation signal of the management module 300 ′. When the operation signal of the management module 300 ′ is input to the OTDR 500, bending or cutting through the respective second optical paths 32, 32 ′, and 32 ″, which are sequentially connected by the optical switch 400. The first optical path 31 having the uneven area and its position are found.

As described above, according to the optical communication network monitoring system of the present invention, by efficiently diagnosing and monitoring the obstacles of the optical communication equipment of the remote communication station, it is possible to immediately find the obstacles because it does not take time to move.

In addition, it is possible to immediately identify the handicapped person on the track, the handicapped person of the power source or device. Therefore, when the cause of failure is a failure of the power supply, the failure can be solved within the battery backup time without interruption of communication.

Furthermore, not only can the bending part or the cutting part of the optical path be quickly and easily found, but also the light output (dB) is measured steadily in the usual way, thereby preventing an obstacle or an accident in advance.

Therefore, the service interruption due to the failure of the optical communication network is prevented in advance, and the optical communication network can be quickly restored, thereby increasing the reliability of the optical communication network.

The present invention is not limited to the above embodiments, and it is apparent that many modifications are possible by those skilled in the art within the technical spirit of the present invention.

Claims (6)

The first optical communication device 11, which is installed in the base communication station, the second optical communication device 21 installed in the remote telecommunication station, respectively, and the first optical link carrying the traffic information by connecting the first optical communication device and the second optical communication device. In the monitoring system for monitoring an optical communication network comprising a first optical path 31 through which a call is transmitted, The second optical signal λ ₂ having a wavelength different from the first optical signal λ ₁ on which the traffic information is received by receiving state information of the second optical communication device 21 and / or environmental information of the remote communication station. A test signal transmitter (100) mounted on the first optical path (31) for transmission; It is connected to the first optical path 31 by a second optical path 32, receives the second optical signal λ ₂ from the first optical path 31, the status information of the second optical communication equipment A test signal receiver 200 for extracting line loss information of the remote communication station and the optical path; An optical switch 400 installed to be connected to the second optical path 32; It is installed to be connected to or short-circuited with the second optical path 32 by the operation of the optical switch 400, and the wavelength λ ₃ different from the first optical signal λ ₁ and the second optical signal λ ₂ . OTDR 500 using; It is installed to be connected to the test signal receiver 200, the optical switch 400 and the OTDR 500, respectively, the line loss information extracted from the test signal receiver 200 receives the OTDR (500) and the optical Optical network monitoring system comprising a management module 300 for controlling the operation of the switch (400). According to claim 1, If the plurality of optical communication network comprising the first optical communication equipment 11, the second optical communication equipment 21 and the first optical path 31 is formed, The test signal transmitter (100), the second optical path (32) and the test signal receiver (200) are provided in plural numbers so as to correspond one-to-one with the optical communication network; The management module 300, the optical switch 400 and the OTDR 500 are integrated to be used so that the management module 300 is connected to the test signal receivers 200, respectively, the optical switch 400 is Any one selected from the second optical paths 32 and the OTDR under the control of the management module 300 and installed to connect each of the OTDR 500 and the second optical paths 32 in a 1xN type. Optical network monitoring system, characterized in that it is operated to connect 500. A plurality of first optical communication equipments 11 installed at a base communication station, a plurality of second optical communication equipments 21 installed at a remote telecommunication station, and the first optical communication equipment and the second optical communication equipments in a one-to-one manner, and traffic information. In the monitoring system for monitoring an optical communication network comprising a plurality of first optical paths (31, 31 ', 32 ") to which the first optical signal carrying the The first optical signal λ ₁ is installed to correspond to the second optical communication equipment 21 in a one-to-one manner and receives state information of each second optical communication equipment and environment information of the remote communication station, and includes the traffic information. A respective test signal transmitter (100) mounted on a second optical signal (λ ₂ ) having a wavelength different from) and transmitted through each of the first optical paths (31, 31 ', 31 "); A plurality of second optical paths (32, 32 ', 32 ") connected one-to-one with said first optical paths (31, 31', 31"); A test signal receiver configured to receive the second optical signal from the first optical lines 31, 31 ′, and 31 ″, respectively, and to extract the state information of the second communication equipment, the remote communication station, and the line loss information of the optical lines; 200); One side is connected to each of the second optical paths 32, 32 ′, 32 ″ and the other side is connected to the test signal receiver 200 by a third optical path 33, wherein the second optical paths 32 32 ', 32') and 1xN optical switch 400 'periodically connecting the test signal receiver 200; The OTDR 500 is connected to the third optical path 33 by a coupler 43 and uses a wavelength λ ₃ different from the first optical signal λ ₁ and the second optical signal λ ₂ . and; The management module 300 is installed to be connected to the test signal receiver 200 and the OTDR 500, respectively, and receives the line loss information extracted from the test signal receiver 200 to control the operation of the OTDR 500. Optical network monitoring system including '). 4. The test signal transmitter 100 according to any one of claims 1 to 3, wherein: An input unit 110 which receives the state information and / or the environment information of the remote communication station and converts the digital information into digital data; A controller 120 for buffering the digital data provided from the input unit 110 to a memory, extracting data buffered in the memory, and outputting the extracted data to a test signal; And a second optical signal generator 130 for receiving the test signal output from the controller 120 and outputting the second optical signal λ ₂ corresponding thereto. . The optical-electric signal converter of claim 1, wherein the test signal receiver 200 receives the second optical signal λ ₂ and converts it into an analog electrical signal corresponding to the second optical signal λ ₂ . 210; An A / D converter 220 for converting the analog electric signal output from the optical-electric signal converter 210 into a digital signal; Extracting the output information of the second optical signal and the state information and / or the environmental information required to receive the digital signal from the A / D converter 220 and calculate the line loss data of the optical path therefrom. And a controller 230 for buffering the memory and outputting the buffered data. According to any one of claims 1 to 3, wherein the management module (300, 300 ') is: respectively capable of communicating with the test signal receiver 200, optical switch 400 and OTDR (500), respectively. Communication units (311, 312, 313, 314); The OTDR 500 or the optical switch 400 is buffered when the digital data provided by the test signal receiver 200 is buffered in a memory and the data buffered in the memory is extracted to exceed the allowable limit of the optical path. And a control unit for outputting an operation signal to operate.