KR100264973B1 - Ray monitoring device in optical transmission system including optical amplifier - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to an optical path monitoring apparatus in an optical transmission system including an optical amplifier.

2. The technical problem to be solved by the invention

In the present invention, a long-range optical transmission system including an optical amplifier amplifies a monitoring signal without a separate optical amplifier, thereby measuring a failure point and a loss of an ultra-high-speed long-range optical transmission path by using a time-domain optical reflection measuring apparatus (OTDR). It is intended to provide a light monitoring device for improving reliability.

3. Summary of Solution to Invention

The present invention includes a first separation unit for separating the optical signal and the monitoring signal reflected back according to the wavelength; A first blocking unit for blocking an optical signal; An amplifier for amplifying the surveillance signal separated by the first separator; A second separator for separating the amplified natural emission light and the monitoring signal output from the amplifier; A second blocking unit for blocking the amplified natural emission light separated by the second separating unit; And an analyzing unit for analyzing a failure position and a loss of the optical path by measuring the monitoring signal provided from the second separating unit.

4. Important uses of the invention

The present invention is used for optical path measurement of a long distance transmission system including an optical amplifier.

Description

Ray monitoring device in optical transmission system including optical amplifier

The present invention relates to an optical path monitoring device capable of measuring a fault point and a loss of a high speed long distance optical transmission line by using an optical time domain reflectometry (OTDR) in a long distance optical transmission system including an optical amplifier (EDFA). will be.

In general, as the backbone network becomes faster due to the development of optical communication, the damage caused by the failure of the optical path 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 line is essential. The optical line monitoring device promptly informs the point of failure in the event of an optical line failure, thereby enabling rapid failure recovery. 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 configuration diagram of a conventional optical path monitoring device, which is used to measure an optical path having a short relay distance.

Referring to FIG. 1, a conventional optical path 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 from a transmitter 11 of a transmission system and a time domain optical reflective wave measurement apparatus 16. The supervisory signal coming out through 15 is combined by a wavelength division multiplexing (WDM) optocoupler 13 and is incident to 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 by the optical filter 18 to the receiver 12 of the transmission system. This prevents deterioration of the transmission characteristics since it cannot enter.

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, it 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 impossible to monitor the optical path 14 provided with the optical amplifier (23 of FIG. 2 to be described later).

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 (25, 26 of FIG. 2 to be described later) 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 km 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 is 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 in order to amplify 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 monitoring signal for amplifying the monitoring 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 has been made to solve the above problems, in the long-distance optical transmission system including an optical amplifier, the ultra-high-speed long-distance optical transmission to the time domain optical reflectance measuring device (OTDR) by amplifying the monitoring signal without having a separate optical amplifier The purpose of the present invention is to provide an optical line monitoring device for improving the reliability of the system by measuring the point and loss of the furnace.

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

2 is a block diagram of an optical path monitoring apparatus in a long distance transmission system to which a conventional optical amplifier is added.

3 is an exemplary view illustrating a configuration of an optical path monitoring apparatus according to an embodiment of the present invention.

4 is an exemplary configuration diagram of a light beam monitoring apparatus according to another embodiment of the present invention.

5 is a signal analysis waveform diagram of a time domain light reflection measurement apparatus (OTDR) measured in accordance with an embodiment of the present invention.

* Explanation of symbols for the main parts of the drawings

11: transmission system receiver 12: transmission system receiver

13,21,22,31,32,33,34: WDM optocoupler 14: optical path

15: optical fiber selector 16: time domain optical reflective wave measuring device (OTDR)

17 controller 18 light filter

23: optical amplifier (EDFA) 24: optical amplifier for monitoring signal amplification (EDFA)

25,26: isolator 41,42: optical circulator

43,44: fiber grating 45,46: blocking part

The present invention for achieving the above object, in the optical path monitoring apparatus for measuring the state of the optical path applied to a long-range optical transmission system including an optical amplifier, the optical signal reflected by the scattering of the optical path according to the wavelength and returned First separating means for separating the monitoring signal from the control unit; First blocking means for blocking the optical signal; Amplifying means for amplifying the monitoring signal separated by the first separating means; Second separating means for separating the amplified natural emission light and the monitoring signal outputted from the amplifying means; Second blocking means for blocking said amplified spontaneous emission light separated by said second separating means; And analyzing means for measuring the monitoring signal provided from the second separating means to analyze the failure position and the loss of the optical path.

The apparatus may further include combining means for combining the optical signal and the monitoring signal so that the optical signal and the monitoring signal can be amplified by the amplifying means.

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

3 is a diagram illustrating a configuration of an optical path monitoring apparatus according to an embodiment of the present invention.

According to a preferred embodiment of the present invention, the optical path monitoring apparatus measures a signal reflected by scattering of the optical path 14 in order to measure the condition of the optical path 14 in a long distance optical transmission system. Separated by the WDM coupler (33, 34) for separating the optical signal and the monitoring signal reflected by the scattering of the optical path, the isolator 26 for blocking the reflected optical signal, and the WDM coupler (33, 34) An optical amplifier 23 for amplifying the reflected monitoring signal, amplified natural emission light ASE output from the optical amplifier 23, WDM couplers 31 and 32 for separating the monitoring signal, and a WDM coupler 31 Isolator 25 for blocking the amplified spontaneous emission light separated by the < RTI ID = 0.0 > 32, < / RTI > and time domain light for analyzing the fault location and loss of the optical path by measuring the monitoring signal provided by the WDM coupler 31, 32. Reflective wave measuring device (OTDR).

The optical path monitoring device according to an embodiment of the present invention is provided at both ends of the isolators 25 and 26 to prevent the monitoring signal from passing through the isolators 25 and 26 linked to the front and rear ends of the optical amplifier 23 in the long distance transmission system. Each of the WDM optocouplers 31 to 34 is provided.

Referring to the optical path monitoring apparatus in the long-distance optical transmission system according to an embodiment of the present invention with reference to FIG. 3, the optical signal and the monitoring signal to guide the optical path 14 isolator interlocked to the front end of the optical amplifier 23 (25) Separated according to the wavelength by the WDM optocoupler 31 at the front end, the optical signal passes through the isolator 25 and the supervisory signal does not go through the isolator 25, but the WDM optocoupler 32 behind the isolator 25. Are combined and amplified in the optical amplifier 23.

The amplified optical signal and the supervisory signal are separated by the WDM optical coupler 33 at the front end of the isolator 26 linked to the rear end of the optical amplifier 23, and then again the WDM optical coupler 34 at the rear end of the isolator 26. Are combined in the light path 14.

On the other hand, the optical signal and the supervisory signal reflected by the scattering of the optical path 14 are separated by the WDM optical coupler 34 at the rear end of the isolator 26 according to the wavelength, and the reflected supervisory signal is the isolator 26. However, the optical signal is blocked because it passes through the isolator 26.

Subsequently, the monitoring signal is amplified by the optical amplifier 23. At this time, the natural emission light ASE amplified by the optical amplifier 23 and the amplified monitoring signal are output, and according to the wavelength, the WDM optical coupler at the rear of the isolator 25 is used. Separated by 32), the amplified supervisory signal does not pass through the isolator 25, but the amplified natural emission light passes through the isolator 25 and is blocked.

Next, the amplified supervisory signal goes to the transmitter 11 of the transmission system through the WDM optocoupler 31 in front of the isolator 25 and is transmitted to the time domain light reflecting wave measurement device 16 by the WDM optocoupler 13. do.

Therefore, when analyzing the monitoring signal received by the time-domain light reflecting wave measurement device 16, it is possible to measure the point of failure and loss of the optical path 14, the analysis result is shown in FIG.

4 is an exemplary configuration diagram of a light beam monitoring apparatus according to another embodiment of the present invention.

According to another preferred embodiment of the present invention, the optical path monitoring apparatus measures a signal reflected by scattering of the optical path 14 in order to measure the condition of the optical path 14 in a long distance optical transmission system. An optical circulator 42 and an optical fiber grating 44 for separating the optical signal and the monitoring signal reflected by scattering of the optical path, and a blocking unit 46 for blocking the optical signal passing through the optical fiber grating 44; And an optical amplifier 23 for amplifying the monitoring signal reflected by the optical fiber grating 44, and an optical circulator 41 for separating the amplified natural emission light ASE outputted from the optical amplifier 23 and the monitoring signal. ) And the optical fiber grating 43, the blocking unit 45 for blocking the amplified natural emission light passing through the optical fiber grating 43, and the monitoring signal provided from the optical circulator 41 to measure the obstacle of the optical path Analyzing location and loss And a time-domain light reflecting wave measurement device (OTDR).

According to another embodiment of the present invention, the optical path monitoring device blocks an optical signal reflected from the optical path 14 and an amplified natural emission light ASE generated from the optical amplifier 23 in a long-distance transmission system, Only the optical circulators 41 and 42 and the monitoring signal are amplified by the optical amplifier 23 and transmitted to the time domain optical reflectivity measuring device 16 so that the failure point and the loss of the optical path 14 can be analyzed. Optical fiber gratings 43 and 44 for reflecting.

The optical path monitoring device according to the embodiment of the present invention as described above can amplify the monitoring signal without having a separate monitoring signal amplification optical amplifier (24 of FIG. 2) can reduce the cost when building the system By using only optical passive elements such as WDM optocouplers 31 to 34, the reliability of the system can be improved.

Referring to the optical path monitoring device in the long-distance optical transmission system according to another embodiment of the present invention with reference to FIG. 4, the optical signal and the monitoring signal that guides the optical path 14 is an optical circulator (before the optical amplifier 23) ( 41 is delivered to the optical amplifier 23 and amplified in the optical amplifier 23.

Thereafter, the amplified optical signal and the monitoring signal are transmitted to the optical path 14 by the optical circulator 42 behind the optical amplifier 23.

On the other hand, the optical signal and the monitoring signal reflected by the scattering of the optical path 14 is returned to the port with the optical fiber grating 44 by the optical circulator 42, wherein the monitoring signal is the optical fiber grating 44 ) Is reflected by the optical waveguide 42 and transmitted to the optical amplifier 23 by the optical circulator 42, and the optical signal passes through the optical fiber grating 44 as it is and is blocked by the blocking unit 46. Here, the blocking unit 46 blocks the optical signal transmitted to the optical amplifier 23 by bending the end of the optical fiber after the optical fiber grating 44.

Thereafter, the monitoring signal reflected by the optical fiber grating 44 is amplified by the optical amplifier 23. At this time, the natural emission light ASE amplified by the optical amplifier 23 and the amplified monitoring signal are output to the optical circulator. 41) proceeds to the port where the fiber grating 43 is located.

Next, the amplified supervisory signal is reflected by the optical fiber grating 44, and then goes back to the transmitting unit 11 of the transmission system through the optical circulator 41, and then the time-domain optical reflection wave measuring device by the WDM optical coupler 13 ( 16).

Therefore, when analyzing the monitoring signal received by the time-domain light reflecting wave measurement device 16, it is possible to measure the point of failure and loss of the optical path 14, the analysis result is shown in FIG.

On the other hand, the amplified natural emission light ASE generated by the optical amplifier 23 and lowering the light transmission characteristics is passed through the optical fiber grating 43 by the optical circulator 41 as it is by the blocking unit 45. Is blocked. Here, the blocking unit 45 blocks the amplified natural emission light ASE by bending the end of the optical fiber after the optical fiber grating 43.

The optical path monitoring device according to the embodiment of the present invention as described above can amplify the monitoring signal without having a separate monitoring signal amplification optical amplifier (24 of FIG. 2) can reduce the cost when building the system The reliability of the system can be improved by using only optical passive elements such as optical circulators 41 and 42 and optical fiber gratings 43 and 44.

5 is a signal analysis waveform diagram of a time-domain optical reflectivity measurement apparatus (OTDR) measured according to an embodiment of the present invention, in which "a" is an amplification point by the optical amplifier 23, and "b" is an optical path. Each end of (14) is shown.

Referring to FIG. 5, there is a point where the power of the monitoring signal decreases and then increases, because the power of the monitoring signal increases in the optical amplifier 23. In addition, the amplified spontaneous emission light ASE generated in the optical amplifier 23 and affecting the transmission system is blocked by the isolator 25 through the WDM optical coupler 32 of FIG. 3, or the optical fiber grating of FIG. 4. Blocked by the blocking portion 45 through 43.

The present invention described above is capable of various substitutions, modifications, and changes without departing from the spirit of the present invention for those skilled in the art to which the present invention pertains, and the above-described embodiments and accompanying It is not limited to the drawing.

The present invention as described above, it is possible to amplify the monitoring signal without having a separate optical signal amplifier for monitoring signal amplification can reduce the cost when constructing the system, it is possible to immediately know the point of failure and loss in the event of optical fiber failure By enabling rapid recovery, it is possible to shorten the service downtime, prevent the failure in advance and solve the problem of the optical fiber without service interruption, thereby improving the reliability of the transmission system.

Claims (6)

An optical path monitoring device for measuring a state of an optical path applied to an optical transmission system including an optical amplifier, First separation means for separating an optical signal and a monitoring signal reflected and returned by scattering of the optical path according to a wavelength; First blocking means for blocking the optical signal; Amplifying means for amplifying the monitoring signal separated by the first separating means; Second separation means for separating the amplified natural emission light output from the amplification means and the monitoring signal; Second blocking means for blocking said amplified spontaneous emission light separated by said second separating means; And Analyzing means for analyzing the position and loss of the optical path by measuring the monitoring signal provided from the second separating means Ray monitoring device comprising a. The method of claim 1, Combining means for combining the optical signal and the monitoring signal so that the optical signal and the monitoring signal can be amplified by the amplifying means in the forward direction of the optical signal and the monitoring signal; Ray monitoring device further comprising a. The method according to claim 1 or 2, The first and second separation means, Wavelength Division Multiplexing (WDM) optocouplers for separating the optical signal, the amplified natural emission light (ASE) and the monitoring signal according to a wavelength Ray monitoring device comprising a. The method of claim 3, wherein The first and second blocking means, Light path monitoring device, characterized in that the isolator. The method according to claim 1 or 2, The first and second separation means, Optical circulator and optical fiber grating for advancing the optical signal and the amplified spontaneous emission light in one direction only and enabling the bidirectional propagation of the monitoring signal Ray monitoring device comprising a. The method of claim 5, The first and second blocking means, Bending the optical fiber end of the optical fiber grating to block the optical signal and the amplified natural emission light (ASE).