KR200396306Y1 - System for watching optic fiber using testing wave length - Google Patents

Abstract

The present invention relates to a system for monitoring a light path, and in particular, a wavelength different from a wavelength for data transmission and reception to a light path used by a specific transmission device, and a separate testing wavelength for monitoring the presence or absence of the light path and loss of the light path. Testing can be used to test the optical path without adversely affecting the transmission and reception of data, and to show the optical signal strength of the receiver in real time to the operator through the FND or the GUI, enabling fast optical status and maintenance. The present invention relates to a light beam surveillance system using a.

The constituent means constituting the optical path monitoring system using the testing light wavelength of the present invention is to generate a testing light wavelength signal of a predetermined wavelength, and perform a multiplexing with the optical wavelength signal transmitted from the optical transmission equipment on the transmitting side to transmit through the optical cable. And separating the testing optical wavelength signal from the multiplexed optical wavelength signal transmitted through the optical cable to display the intensity of the testing optical wavelength signal on the corresponding display device, and the optical wavelength signal transmitted from the optical transmission equipment after the separation is transferred to another optical transmission equipment. And an NMS unit for receiving the information on the receiving line monitor and transmitting the information about the testing light wavelength signal separated from the receiving line monitor, and storing and analyzing the information in a predetermined database.

Description

Optical monitoring system using testing light wavelengths {SYSTEM FOR WATCHING OPTIC FIBER USING TESTING WAVE LENGTH}

The present invention relates to a system for monitoring a light path, and in particular, a wavelength different from a wavelength for data transmission and reception to a light path used by a specific transmission device, and a separate testing wavelength for monitoring the presence or absence of the light path and loss of the light path. Testing can be used to test the optical path without adversely affecting the transmission and reception of data, and to show the optical signal strength of the receiver in real time to the operator through the FND or the GUI, enabling fast optical status and maintenance. The present invention relates to a light beam surveillance system using a.

In general, as the backbone network becomes faster due to the development of optical communication, the damage caused by the failure of the optical fiber has a serious economic and social impact.

Therefore, in order to increase the reliability of the transmission network, an optical line monitoring device that can measure the point of failure and loss change of the optical path is essential. By measuring the loss change of the optical path, it is possible to prevent the failure caused by the optical path deterioration.

1 is a block diagram showing an example of a conventional optical path monitoring apparatus, which is used to measure an optical path having a short relay distance.

Referring to FIG. 1, a conventional optical line monitoring apparatus includes an optical core selector capable of selecting an optical signal to be measured from among a plurality of optical fibers in an optical signal and a time-domain optical reflectance measuring device 16 from a transmitter 11 of a transmission system. The monitoring signal coming out through 15 is combined by a Wave Division Multiplexing (WDM) optocoupler 13 and is incident on the optical path 14. At this time, the optical signal is transmitted to the receiver 12 of the transmission system via the optical path 14, and the monitoring signal guided to the receiver 12 of the transmission system is transmitted to the receiver 12 of the transmission system by the optical filter 18. This prevents deterioration of transmission characteristics.

On the other hand, the supervisory signal guided by the scattering in the optical fiber to the transmission unit 11 of the transmission system is transmitted by the WDM optical coupler 13 to the time domain light reflection wave measurement device 16, and the time domain light reflection wave measurement device ( Analyze the fault location and the loss of the optical path by measuring the monitoring signal transmitted from 16).

The controller 17 controls the time domain light reflecting wave measurement apparatus 16 and the optical line selector 15.

However, although the conventional optical path monitoring device as described above can be used to measure the optical path 14 having a relatively short relay distance, the optical path monitoring device compensates for the attenuation of the optical signal generated in the optical fiber to increase the relay distance in a long distance transmission system. It is not possible to monitor the light path 14 provided with an optical amplifier (denoted by reference numeral 23 in FIG. 2).

This is because the optical amplifier 23 prevents performance degradation of the transmission system by the amplified spontaneous emission (ASE) generated by the optical amplifier 23, and the scattered light in the optical signal is the optical amplifier 23 or This is because an optical passive element called an isolator (indicated by 25 and 26 in FIG. 2) is placed on both sides to prevent transmission to the transmission unit 11 of the transmission system.

However, since the isolators 25 and 26 are optical passive elements having a function of passing light in one direction but blocking the light in the opposite direction, the monitoring signal from the time domain light reflecting wave measurement device 16 is an isolator ( 25, 26) but never return.

Therefore, the conventional optical path monitoring device does not measure the optical path 14 after the isolators 25 and 26, so there is a problem in that the optical path 23 is not monitored. In addition, there is a problem in that the power of the OTDR monitoring signal cannot measure the long-distance optical path 14 of several hundred kilometers due to the attenuation of the optical path 14.

FIG. 2 is a block diagram of an optical path monitoring apparatus in a long distance transmission system in which a conventional optical amplifier is added, and used to monitor the optical path 14 in a long distance transmission system in which an optical amplifier 23 is added.

The optical path monitoring device in a long-distance transmission system to which a conventional optical amplifier is added is a conventional optical path monitoring device, which includes an optical amplifier for amplifying a monitoring signal for amplifying a monitoring signal from the time domain light reflecting wave measuring device 16. 24) is further provided.

Referring to the optical path monitoring apparatus in a long-distance transmission system to which the conventional optical amplifier is added with reference to Figure 2, the optical signal and the monitoring signal is separated by the WDM optical coupler 21, the optical signal is an optical with an isolator 25 The signal is transmitted to the amplifier 23, and the monitoring signal is transmitted to the monitoring signal amplification optical amplifier 24 without the isolator 25, and is transmitted to the monitoring signal amplification optical amplifier 24.

Thereafter, the optical signal amplified by the optical amplifier 23 transmitted through the isolator 26 and the monitoring signal amplified by the optical amplifier 24 for amplifying the supervisory signal are combined by the WDM optical coupler 22 to provide an optical path 14. Is delivered.

On the other hand, the optical signal reflected by the scattering in the optical path 14 is returned to the optical amplifier 23 having the isolator 26 by the WDM optical coupler 22, and the optical signal has the isolator 26 It does not proceed to the transmitter 11 of the transmission system.

On the other hand, the reflected supervisory signal enters the optical amplifier 24 for amplifying the supervisory signal without the isolator 26, so it is amplified and directed toward the transmitting unit 11 of the transmission system. The WDM optical coupler 13 measures the time-domain optical reflection wave. Delivered to device 16.

Accordingly, the time-domain light reflection wave measuring apparatus 16 may measure the point of failure and the loss of the optical path 16 from the transmitted monitoring signal.

However, the optical path monitoring apparatus in the long-distance transmission system to which the conventional optical amplifier as described above generates a natural emission light (ASE) amplified by the optical amplifier for monitoring signal amplification 24, and lowers the optical transmission characteristics, Since a separate optical signal amplifier 24 for amplifying the surveillance signal for amplifying the surveillance signal has to be provided, there is a problem of increasing the construction cost of the system.

In addition, a separate power supply must be supplied to the optical amplifier 24 for amplifying the supervisory signal, and a pumping laser diode (LD) is included for amplifying the supervisory signal, so that the entire power supply device or the pumping LD is broken. There is a problem that causes the system failure to reduce the reliability of the system.

The present invention was devised to solve the above problems of the prior art, and multiplexes and transmits a predetermined optical wavelength signal for data transmitted from an optical transmission device and a testing optical wavelength signal for testing a line state, and at the receiving side, By separating the multiplexed optical signal and detecting the testing optical wavelength signal to check the power intensity, the optical fiber line monitoring using the testing optical wavelength signal that can easily check the state of the optical path in the absence of the loss of data transmitted from the optical transmission equipment To provide a system for that purpose.

In order to solve the above technical problem, the constituent means constituting the optical path monitoring system using the testing optical wavelength proposed by the present invention generates a testing optical wavelength signal of a predetermined wavelength and multiplexes the optical wavelength signal transmitted from the optical transmission equipment on the transmission side. A transmission line monitor for performing transmission through the optical cable, and separating the testing optical wavelength signal from the multiplexed optical wavelength signal transmitted through the optical cable to display the intensity of the testing optical wavelength signal on the corresponding display device, and after transmitting the optical transmission signal The optical wavelength signal transmitted from the equipment includes a receiving line monitor transmitting to another optical transmission device, and an NMS unit for receiving information about the testing optical wavelength signal separated from the receiving line monitoring, storing and analyzing the information in a predetermined database. Characteristic It shall be.

In addition, the transmission line monitor, the CWDM for generating a testing wavelength wavelength signal of a predetermined wavelength band, and the CWDM for performing a wavelength division multiplexing of the testing optical wavelength signal and the optical wavelength signal transmitted from the optical transmission equipment through the optical cable A multiplexer, a driver for driving the testing wavelength generator, a power supply for supplying power to each element of the transmission line monitor, and a display unit for displaying a power supply state of the power supply unit. .

The receiving side line monitor may further include: a CWDM demultiplexer that separates an optical signal received through the optical cable into an optical wavelength signal transmitted from a transmission device and the testing optical wavelength signal, a testing wavelength receiver that receives the separated testing optical wavelength signal; And a driving unit for driving the testing wavelength receiver, a control and display unit for controlling the testing optical wavelength signal received by the testing wavelength receiver to display optical power on a predetermined display device, and powering each element of the receiving line monitor. Characterized in that comprises a power supply for supplying.

The wavelength of the testing light wavelength signal is in the range of 1580 nm to 1600 nm, and the wavelength of the light wavelength signal of the transmission equipment is in the range of 1310 nm or 1550 nm, and in particular, the wavelength of the testing light wavelength signal is preferably 1590 nm. Do.

The control and display unit may further include an A / D converter for converting the power of the received testing light wavelength signal into a digital signal.

In addition, the power of the testing light wavelength signal converted by the A / D converter provided in the control and display unit is displayed on the display device, the display device is characterized in that the FND (Flexible Numeric Display) LED.

Hereinafter, with reference to the accompanying drawings will be described in detail the operation and preferred embodiment of the optical path monitoring system using the testing light wavelength of the present invention consisting of the above configuration means.

As shown in FIG. 3, in the optical path monitoring system using the testing light wavelength of the present invention, the transmitting side 100 and the receiving side 200 are connected by an optical cable.

The transmitting side 100 transmits an optical wavelength signal having a predetermined wavelength and an optical wavelength signal carrying data to be transmitted by the transmitting side optical transmission equipment 110 and the transmission side optical transmission equipment 110 and a predetermined wavelength having a predetermined wavelength. The transmission side preference monitor 120 transmits through the optical cable by multiplexing (multiplexing).

In addition, the receiving side 200 receives the multiplexed optical signal, and transmits the optical wavelength signal transmitted from the optical transmission equipment 110 of the transmitting side 100 and the testing optical wavelength signal generated by the transmitting side line monitor 120. It is composed of a receiving side line monitor 210 for displaying the intensity of the testing light wavelength signal to the display device (not shown) separately and the optical transmission equipment 220 of the receiving side 200 receiving the separated light wavelength signal.

On the other hand, the receiving side line monitor 210 of the receiving side 200 is connected to the network to receive the information on the testing light wavelength signal separated from the receiving line line monitor 210, to store and analyze in a predetermined database NMS (Network Management System) 300 is included in the configuration of the optical path monitoring system using the testing light wavelength.

An internal block diagram of the transmission line monitor 120 is shown in FIG. 4.

As shown in FIG. 4, the transmitter side line monitor 120 includes a testing wavelength generator 127, a CWDM multiplexer 129, a driver 125, a power supply 121, and a display 123. Consists of including.

The testing wavelength generator 127 performs an operation of generating a testing light wavelength signal of a predetermined wavelength band. That is, a predetermined testing signal used to check the state of the light path is generated to have a predetermined power and wavelength. The wavelength of the testing light wavelength signal uses a wavelength different from that used by ordinary optical transmission equipment for data transmission and reception.

For example, since the normal optical transmission equipment uses a wavelength of 1310 nm or 1550 nm for data transmission and reception, the wavelength of the testing light wavelength signal used in the present invention uses a wavelength in the range of 1580 nm to 1600 nm, Preferably, a wavelength of 1590 nm is used.

The testing optical wavelength signal generated by the testing wavelength generator 127 is transmitted to a CWDM (Coarse Wavelength Division Multiplexing) multiplexer 129. Then, the CWDM multiplexer 129 transmits the optical wavelength signal of the wavelength band of 1310 nm or 1550 nm transmitted by the optical transmission device 110 and the testing optical wavelength signal by wavelength division multiplexing (CWDM) to transmit the optical wavelength signal.

In order to drive the testing wavelength generator 127, a driver 125 comprising a predetermined circuit is provided, and a transmission line monitor such as the CWDM multiplexer 129, the testing wavelength generator 127, and the driver 125 is provided. A power supply 121 for supplying power to each device is provided, and a display unit 123 showing a power supply state of the power supply 121 is required.

Meanwhile, an internal block diagram of the receiving side line monitor 120 for receiving the multiplexed optical signal transmitted from the transmitting side line monitor 120 is shown in FIG. 5.

As shown in FIG. 5, the receiving line monitor 120 includes a CWDM demultiplexer 219, a testing wavelength receiver 217, a driver 215, a control and display unit 213, and a power supply unit 211. consist of.

The CWDM demultiplexer 219 receives the optical signal received through the optical cable to perform demultiplexing. That is, demultiplexing the received optical signal to perform the operation of separating the optical wavelength signal transmitted from the transmission equipment and the testing optical wavelength signal generated by the transmission line monitor 120.

The optical wavelength signal transmitted from the transmission equipment separated by the CWDM demultiplexer 219 is transmitted to the other optical transmission equipment 220 connected to the receiving side 200, and the testing optical wavelength signal is transmitted to the testing wavelength receiver 217. .

The testing light wavelength signal received by the testing wavelength receiver 217 is transmitted to the control and display unit 213. The power of the testing light wavelength signal is displayed on a predetermined display device (not shown) by a predetermined control device.

Since the signal transmitted from the testing wavelength receiver 217 is in an analog form, the control and display unit 213 may display an A / D converter to display a power of the testing light wavelength signal on a predetermined display device (not shown). (Not shown) to convert to a digital signal.

The power of the testing light wavelength signal changed by the A / D converter (not shown) included in the control and display unit 213 is displayed on the display device (not shown). The display device (not shown) is preferably a FND (Flexible Numeric Display) LED.

The receiving line monitor 210 includes a driver 215 for driving the testing wavelength receiver 217, and each element (control and display unit 213, testing wavelength) of the receiving line monitor 210. A power supply unit 211 is provided to supply power to the receiver 217 and the CWDM demultiplexer 219.

Meanwhile, the plurality of receiving side line monitors 210 illustrated in FIG. 3 are connected to each other in a network, and are connected to the receiving side line monitors 210 in a network and received from the receiving side line monitor 210. The NMS unit 300 is provided to store and analyze information on the optical wavelength signal.

The stored information not only indicates whether the optical paths are abnormal for each section, but also the optical paths for each time zone. Therefore, when the operator wants to utilize the light path state as data, the state of the light path by section or time zone can be confirmed by driving execution software such as an Excel file.

By using the information on the testing light wavelength signal stored in the NMS unit 300, the operator can check the state of the optical cable to ensure the stability of the line.

In addition, the NMS unit further includes an alarm device that sounds a buzzer when it is determined that there is an abnormality in the optical path by analyzing the received test light wavelength signal, thereby warning the surrounding operators in case of an abnormality in the optical path, and quickly recovering the optical path. To be made.

If it is determined that there is an abnormality in the optical path, the NMS unit transmits the optical fiber abnormality in a short message to the operator using an SMS service. Therefore, the operator can recognize the abnormal condition of the optical path in real time, and can quickly cope with a problem in the optical path.

According to the optical path monitoring system using the testing light wavelength of the present invention having the above configuration and operation and preferred embodiments, the transmitting side multiplexes and transmits the optical wavelength signal for the data transmitted from the optical transmission equipment and a separate testing optical wavelength signal. On the receiving side, the multiplexed optical signal is demultiplexed to detect the testing optical wavelength signal, so that the state of the optical path can be easily confirmed without damaging the data transmitted from the optical transmission equipment.

In addition, by displaying the power strength of the testing light wavelength signal on the display device, the operator can check the state of the light path in real time, there is an advantage that facilitates the maintenance of the optical line.

1 is a configuration diagram of a conventional optical path monitoring device.

2 is a configuration diagram of another conventional optical path monitoring device.

3 is an overall block diagram of an optical path monitoring system using the testing light wavelength of the present invention.

4 is a block diagram of a transmission line monitor that is one component of the present invention.

5 is a block diagram of a receiving line monitor that is one component of the present invention.

Explanation of symbols on main parts of drawing

100: transmitting side 110: optical transmission equipment

120: transmission line monitoring unit 121: power supply unit

123: display unit 125: driving unit

127: testing wavelength generator 129: CWDM multiplexer

200: receiving side 210: transmitting line monitoring device

211: power supply unit 213: control and display unit

215: drive unit 217: testing wavelength receiver

219: CWDM Demultiplexer 220: Optical Transmission Equipment

300: NMS part

Claims (9)

In the optical fiber surveillance system, A transmission line monitor for generating a testing optical wavelength signal of a predetermined wavelength band and performing multiplexing with the optical wavelength signal transmitted from the optical transmission equipment on the transmission side to transmit the optical wavelength signal through an optical cable; Separating the testing optical wavelength signal from the multiplexed optical wavelength signal transmitted through the optical cable to display the intensity of the testing optical wavelength signal on the display device, and the optical wavelength signal transmitted from the optical transmission equipment after the separation is transmitted to another optical transmission equipment A receiving line monitor; And an NMS unit configured to receive information about the testing light wavelength signal separated from the receiving line monitor and store and analyze the information in a predetermined database. The line transmitter of claim 1, A testing wavelength generator for generating a testing optical wavelength signal of a predetermined wavelength band, a CWDM multiplexer for wavelength division multiplexing the optical wavelength signal transmitted from the testing optical wavelength signal and the optical transmission equipment and transmitting the optical wavelength signal through an optical cable, and generating the testing wavelength And a driving unit for driving the unit, a power supply unit for supplying power to each element of the transmission line monitor, and a display unit for displaying a power supply state of the power supply unit. The method of claim 1, wherein the receiving line monitor, A CWDM demultiplexer for separating the optical signal received through the optical cable into an optical wavelength signal transmitted from a transmission device and the testing optical wavelength signal, a testing wavelength receiver for receiving the separated testing optical wavelength signal, and a driver for driving the testing wavelength receiver. And a control and display unit for controlling the testing optical wavelength signal received by the testing wavelength receiver to display optical power on a predetermined display device, and a power supply unit for supplying power to each element of the receiving line monitor. Light line monitoring system using the testing light wavelength, characterized in that. The method according to claim 2 or 3, The wavelength of the testing light wavelength signal ranges from 1580 nm to 1600 nm, and the wavelength of the light wavelength signal of the transmission equipment is in the range of 1310 nm or 1550 nm. The method according to claim 4, And a wavelength of the testing light wavelength signal is 1590 nm. The method according to claim 3, And the control and display unit further comprises an A / D converter for converting the power of the received testing optical wavelength signal into a digital signal. The method according to claim 6, The power of the testing light wavelength signal converted by the A / D converter provided in the control and display unit is displayed on the display device, and the display device is a FND (Flexible Numeric Display) LED. Surveillance system. The method according to claim 1, And the NMS unit further comprises an alarm device which sounds a buzzer when it is determined that there is an abnormality in the optical path by analyzing the received optical wavelength signal. The method according to claim 8, And when the NMS unit determines that there is an abnormality in the optical path, the optical fiber monitoring system using a testing optical wavelength, characterized in that the SMS message is transmitted to the operator using a SMS service.