KR20200094401A - System and method for identificating path of optical line using acoustic wave - Google Patents

Abstract

Provided is a path identification system of an optical line which comprises: a sound wave generating device for generating a sound wave in an arbitrary manhole; a sound wave measuring device connected to a target optical line, inputting a plurality of pulse signals to the target optical line, and collecting a plurality of response data generated in a region including the target optical line; and a path identification device for determining whether the response data related to the sound wave exists among the plurality of response data by using a frequency component of the plurality of response data and determining the arbitrary manhole as a path of the target optical line when response data related to the sound wave is present.

Description

System and method for path identification of optical line using sound waves{SYSTEM AND METHOD FOR IDENTIFICATING PATH OF OPTICAL LINE USING ACOUSTIC WAVE}

The present invention relates to a technique for identifying a path of an optical line using sound waves.

Several optical lines are inherent in one pipeline, and each optical line includes several optical cores. Even if it is an optical line number in the same optical line, the route and distance information of the optical line are different. On the other hand, once the optical line is laid, the route may be extended through an optical connection according to the user's demand. A number of optical lines have been extended according to the explosive wired and wireless Internet demand, and accordingly, the necessity of a technique for identifying the optical line route It has emerged. Through this optical line path identification technology, it is possible to efficiently manage and utilize the optical infrastructure buried underground.

Furthermore, it is necessary to identify the path of a specific optical line in order to efficiently manage and maintain a pre-built optical line. To this end, conventionally, a method in which a person directly generates a physical change on the surface of an optical line was used. In this method, in the case of an optical line buried underground, there is a need for a person to enter the manhole directly. Depending on the condition of the manhole, the working environment may not be easy and may take a lot of time. In addition, when a physical factor is directly applied to the optical line, damage or disconnection of the optical line may occur.

For reference, the existing method for identifying the optical line is a method of measuring the loss change of the optical line using an optical time domain reflectometer (OTDR) after artificially generating the optical loss in the optical line to be identified. A method of discriminating the optical line was used by applying the vibration signal directly to the surface and discriminating the presence or absence of the vibration signal.

The problem to be solved by the present invention is to provide a technique for identifying a path of an optical line laid underground by generating sound waves from the ground and measuring it in a manhole in which the optical line is built.

The path identification system of an optical line according to an embodiment of the present invention is connected to a sound wave generating device that generates sound waves in an arbitrary manhole, a target optical line, and inputs a plurality of pulse signals to the target optical line, thereby allowing the target light A sound wave measuring apparatus for collecting a plurality of response data generated in an area including a line, and determining whether there is response data related to the sound wave among the plurality of response data using a frequency component of the plurality of response data, And a path identification device that determines the arbitrary manhole as a path of the target optical line when response data related to the sound wave is present.

The path identification device generates frequency component data of the plurality of response data, respectively, and determines whether response data related to the sound wave is present using an amplitude value of the frequency component data.

The path identification device generates a frequency component data by performing a Fourier transform on the plurality of response data.

The path identification device respectively determines at least one frequency component satisfying a preset frequency band on the frequency component data for each frequency component data, and the frequency component having a maximum amplitude value among the at least one frequency component is the frequency. It is determined for each component data, and response data related to frequency component data having the maximum value among frequency components having the maximum amplitude value is determined as response data related to the sound wave.

The preset frequency band is a frequency band of the sound wave.

The method for identifying the path of the optical line by the system for identifying the path of the optical line according to an embodiment of the present invention includes generating sound waves in an arbitrary manhole, and inputting a plurality of pulse signals to the target optical line, thereby targeting the target optical line Collecting a plurality of response data generated in the region including, and using the amplitude value of the frequency component of each response data to determine whether the response data associated with the sound wave among the plurality of response data, and the sound wave And determining the arbitrary manhole as a path of the target optical line when response data related to the exist.

Determining whether there is response data related to the sound wave includes generating frequency component data of the plurality of response data, respectively, and determining whether response data related to the sound wave exists using the amplitude value of the frequency component data. Steps.

In the generating of the frequency component data, the frequency component data is generated by performing a Fourier transform on the plurality of response data.

Determining whether there is response data related to the sound wave is determining at least one frequency component that satisfies a preset frequency band on the frequency component data for each of the frequency component data, and a maximum of the at least one frequency component. Determining frequency components having an amplitude value for each of the frequency component data, and determining response data related to frequency component data having a maximum value among frequency components having the maximum amplitude value as response data related to the sound wave. do.

The preset frequency band is a frequency band of the sound wave.

According to the present invention, resources can be efficiently managed and operated by accurately identifying the infrastructure for the optical line.

In addition, according to the present invention, unlike the conventional method for identifying the path of an optical line, it is not necessary to enter the manhole directly to the manhole in order to artificially generate optical loss in the optical line or to identify the path of the optical line. It can be drastically lowered.

In addition, according to the present invention, multiple optical lines can be simultaneously identified using a single sound wave measuring device, so it is more efficient than a device for identifying a path of an existing optical line, and a long distance with a single measurement channel compared to a conventional measurement channel. Measurement is possible and cost reduction is possible.

In addition, according to the present invention, it can be a fundamental technology for more efficiently managing and operating the configuration of the future optical line that is expected to become more complicated.

1 is a diagram illustrating an environment in which a path identification system of an optical line is implemented according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating a method in which a sound wave measurement device collects response data for optical pulse signals using a single channel.
FIG. 3 is a diagram illustrating a method in which a path identification device generates frequency component data of a plurality of response data and analyzes amplitude values of the frequency component data.
FIG. 4 is a diagram for explaining a method for a path identification device to determine response data related to sound waves among a plurality of response data.
5 is a diagram for explaining a method of verifying a determined location of a manhole by a path identification device.
6 is a diagram illustrating an environment in which a path identification system of an optical line is implemented according to another embodiment of the present invention.
7 is a diagram for explaining a method of collecting response data for optical pulse signals using a plurality of channels by a sound wave measuring apparatus.
8 is a view for explaining a method for identifying an optical line buried in an arbitrary manhole in a path identification system of the optical line according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains may easily practice. However, the present invention can be implemented in many different forms and is not limited to the embodiments described herein. In addition, in order to clearly describe the present invention in the drawings, parts irrelevant to the description are omitted, and like reference numerals are assigned to similar parts throughout the specification.

Throughout the specification, when a part “includes” a certain component, it means that the component may further include other components, not to exclude other components, unless otherwise stated. In addition, terms such as “…unit”, “…group”, and “module” described in the specification mean a unit that processes at least one function or operation, which may be implemented by hardware or software or a combination of hardware and software. have.

1 is a diagram illustrating an environment in which a path identification system of an optical line is implemented according to an embodiment of the present invention.

Referring to FIG. 1, the optical line 20 is buried through a plurality of manholes 10. Specifically, the optical line 20 is constructed through underground burial as a manhole-oriented laying method. On the other hand, the underground connection enclosures are connected to each main network through the optical line 20, and the connection enclosures for the main network, distribution, and FTTH (for subscribers) are separated according to each facility location.

Meanwhile, in the present specification, the optical line 20 is a concept that collectively refers to an optical cable and an optical core that are generally used.

The path identification system 1000 of the optical line includes a sound wave generation device 100, a sound wave measurement device 200, and a path identification device 300.

The sound wave generating device 100 generates sound waves in any of the plurality of manholes 10 forming the optical line 20.

For example, the sound wave generating apparatus 100 may generate sound waves in a manhole located third of the plurality of manholes 10. That is, the sound wave generating apparatus 100 applies sound waves, which are physical signals, to any manhole built on the ground without directly applying light loss to the optical line 20 or generating vibration. In this case, sound waves are transmitted to the optical line 20 passing through the manhole where the sound waves are generated.

Meanwhile, the sound wave generating apparatus 100 may be configured as a speaker, and a separate amplifier may be further added.

The sound wave measuring device 200 is connected to an optical line estimated to pass an arbitrary manhole. For example, in the above example, the sound wave measuring device 200 may be connected to the optical line 20 estimated to pass through the third manhole where the sound wave is generated.

In addition, the sound wave measuring apparatus 200 outputs a plurality of pulse signals every predetermined period to collect a plurality of response data generated in an area including the optical line 20. In this case, the area including the optical line 20 means an area covering the length of the optical line 20 to be identified.

Specifically, the sound wave measuring device 200 applies a light pulse signal to the optical line 20 using a light source, and response data that is an interference result of the backscattered light while the incident light pulse progresses through the optical line 20 By measuring them, the distribution of sound waves according to the distance of the optical line 20 is measured in real time. In this case, since the response data includes location information where each response data is generated, the sound wave measuring apparatus 200 may collect the response data and the location information on which each response data is collected.

For example, referring to FIG. 2, when a single first channel is operated, the sound wave measuring device 200 periodically transmits a plurality of light pulse signals to the optical line 20 through the first channel for a predetermined time period. Applied and may collect response data for each of a plurality of optical pulse signals.

In addition, the sound wave measuring apparatus 200 uses the measurement time (pre-set time), measurement speed (sampling frequency), and the optical line measurement length of the channel for the collected response data to a plurality of response data collected in a single channel. You can create a data matrix for

In this case, the data matrix means a reflected sound wave signal by optical pulses arranged for each measurement time, and by processing the signal, it is possible to analyze the time or frequency at which a specific sound wave occurred.

Meanwhile, the sound wave measuring apparatus 200 may be a distributed acoustic sensor (DAS). The distributed sound wave measuring apparatus can detect an optical signal reflected by Rayleigh scattering by injecting an optical pulse into the optical fiber.

The path identification device 300 determines whether there is response data related to sound waves among the plurality of response data using the frequency component of the plurality of response data, and when there is response data related to sound waves, a random manhole targets the optical line Decide by the path of.

Hereinafter, a method for determining the path of the optical line by the path identification device 300 will be described with reference to FIGS. 3 and 4.

FIG. 3 is a diagram for explaining a method in which the path identification device generates frequency component data of a plurality of response data and analyzes amplitude values of the frequency component data, and FIG. 4 shows a path identification apparatus having sound waves and a plurality of response data It is a diagram for explaining a method for determining related response data.

Referring to FIG. 3, the path identification device 300 performs Fourier transform on a plurality of response data to generate frequency component data, respectively.

For example, the path identification device 300 performs Fast Fourier transform (FFT) on each of the plurality of response data to transmit frequency component data, which is a response in the frequency domain, to each response data. Can generate The generated frequency component data represents the frequency characteristics of the corresponding response data and, as shown in FIG. 3, represents the amplitude value for frequency, that is, the signal strength.

Then, the path identification device 300 determines at least one frequency component satisfying a preset frequency band on the frequency component data for each frequency component data.

For example, in FIG. 3, the path identification device 300 may determine at least one frequency component included in a band having a lower limit of f ₁ and an upper limit of f ₂ on frequency component data for each frequency component data. In this case, the preset frequency bands f ₁ to f ₂ may be frequency bands of sound waves generated by the sound wave generator 100 in an arbitrary manhole.

Thereafter, the path identification device 300 determines a frequency component having a maximum amplitude value among at least one frequency component for each frequency component data.

For example, in FIG. 3, the path identification device 300 may determine a frequency component having a maximum amplitude value among frequency components in the f ₁ to f ₂ frequency bands. The path identification device 300 may determine the corresponding process for each frequency component data.

Referring to FIG. 4, the path identification device 300 determines response data related to frequency component data having a maximum value among frequency components having a maximum amplitude value as response data related to sound waves, and response data related to sound waves are collected The point is determined by the location of any manhole.

For example, in FIG. 4, the path identification device 300 sorts frequency components having a maximum amplitude value in each frequency component data according to a distance, and frequency components having a maximum value among frequency components arranged according to a distance. Can decide. To this end, the path identification device 300 may receive position information on response data corresponding to each frequency component data from the sound wave measurement device 200.

Thereafter, the path identification device 300 may determine frequency component data including a frequency component having a maximum value, and determine response data corresponding to the determined frequency component data as response data related to sound waves.

That is, since the preset frequency band corresponds to the frequency band of the sound wave, the frequency components corresponding to the preset frequency band in each frequency component data of a plurality of response data are related to the response data generated by the sound wave, and among these, the maximum Response data related to a frequency component having a value may be treated as response data collected at a point where a sound wave occurs. Through this, the path identification device 300 may determine the position of any manhole where sound waves are generated as the position of the point at which response data related to the frequency component having the maximum value is collected, in which case the position of any manhole It can be determined by the path of the optical line.

If there is no response data having frequency components corresponding to the frequency band of the sound wave, it may be determined that the position of any manhole that generated the sound wave does not correspond to the path of the optical line to which the sound wave measuring device 200 is connected. Accordingly, the path identification device 300 may determine whether there is response data related to sound waves using the amplitude values of the frequency component data of the plurality of response data, and thereby determine the path of the optical line.

On the other hand, the path identification device 300 analyzes a plurality of response data in the time domain, and verifies the location of the determined manhole.

For example, the path identification device 300 sorts a plurality of response data by measurement time, as shown in FIG. 5, and transforms them by fast Fourier, which is a frequency band corresponding to an artificially generated sound wave as shown in FIG. 3. The maximum amplitude between f ₁ and f ₂ is observed. Through this, the maximum amplitude values for the entire optical line measurement length can be observed as shown in FIG. 4, and it is possible to verify the point where the maximum amplitude value becomes the maximum.

6 is a diagram illustrating an environment in which a path identification system of an optical line is implemented according to another embodiment of the present invention.

In FIG. 6, the same contents as those in FIGS. 1 to 5 are omitted, and description will be mainly focused on parts different from FIGS. 1 to 5.

Referring to FIG. 6, the path identification system 2000 of the optical line includes a sound wave generating device 400, a sound wave measuring device 500 and a path identifying device 600, and the sound wave measuring device 500 includes an optical switch ( 510).

The optical switch 510 causes the sound wave measuring device 500 to independently output a plurality of pulse signals from each channel through a plurality of channels 511 to 513, thereby allowing a plurality of optical lines 40, 60, and 80. It should be able to identify the path of the synchronously.

In this case, the sound wave measuring apparatus 500 sequentially generates sound waves in the channel order, respectively, in the manholes 30, 50, 70, and 90 estimated to construct the plurality of optical lines 40, 60, and 80, respectively. Response data is collected sequentially in the order of channels.

For example, in FIG. 7, the sound wave measuring apparatus 500 outputs an optical pulse signal from the first channel 511 and collects response data for the output optical pulse signal. After the response data for the first channel 511 is collected, the sound wave measuring device 500 collects the response data for the second channel 512 in the same way, and thereafter the response data for the third channel 513 To collect. After collecting response data for the first channel 511 to the third channel 513 once, the sound wave measuring apparatus 500 re-collects the response data for the first channel 511. That is, the sound wave measuring apparatus 500 collects response data for all channels once and then returns to the first channel again and repeats the same process.

Thereafter, the sound wave measuring apparatus 500 generates a data matrix using response data collected from each channel of the first channel 511 to the third channel 513.

In addition, the path identification device 600 identifies the path of the plurality of optical lines 40, 60, and 80 by performing the same process on a channel basis. For example, the path identification device 600 uses the plurality of channels 511 to 513 to sound waves in the fourth manhole 90, which is estimated to have passed through a plurality of optical lines 40, 60, and 80 in common. If the fourth manhole 90 is not detected only in the second channel 512, but the second channel 512, a sound wave generating device in the second manhole 50, which is a manhole before the fourth manhole 90, ( 100) It is possible to identify the optical line that has changed its path by generating a sound wave and measuring it in such a way that it is detected. As described above, the present invention can identify an optical line by using not only an arbitrary manhole but also all of the manholes near an arbitrary manhole as a reference entity.

Meanwhile, in FIG. 7, the sound wave measuring apparatus 500 is illustrated as using three channels, but this is only an example, and a plurality of optical lines can be independently identified using a plurality of channels.

8 is a view for explaining a method for identifying an optical line buried in an arbitrary manhole in a path identification system of the optical line according to an embodiment of the present invention.

8, the path identification system 1000 of the optical line generates sound waves in an arbitrary manhole (S100).

The path identification system 1000 of the optical line inputs a plurality of pulse signals to the optical line 20 embedded in an arbitrary manhole, and collects a plurality of response data generated in the region including the optical line 20 ( S110).

The path identification system 1000 of the optical line determines whether there is response data related to sound waves among a plurality of response data using the amplitude value of the frequency component of each response data, and if response data related to sound waves exists, any The manhole is determined by the path of the optical line.

Specifically, the path identification system 1000 of the optical line performs a Fourier transform on a plurality of response data to generate frequency component data, respectively (S120).

The path identification system 1000 of the optical line determines at least one frequency component satisfying a preset frequency band on the frequency component data for each frequency component data (S130). In this case, the preset frequency band may be a frequency band of sound waves.

The path identification system 1000 of the optical line determines a frequency component having a maximum amplitude value among at least one frequency component for each frequency component data (S140).

The path identification system 1000 of the optical line determines response data related to frequency component data having a maximum value among frequency components having a maximum amplitude value as response data related to sound waves (S150).

The path identification system 1000 of the optical line determines a point at which response data related to sound waves are collected as a location of an arbitrary manhole (S160).

The path identification system 1000 of the optical line determines the path of the optical line 20 using an arbitrary manhole position (S170).

According to the present invention, resources can be efficiently managed and operated by accurately identifying the infrastructure for the optical line.

In addition, according to the present invention, unlike the conventional method for identifying the path of an optical line, it is not necessary to enter the manhole directly to the manhole in order to artificially generate optical loss in the optical line or to identify the path of the optical line. It can be drastically lowered.

In addition, according to the present invention, multiple optical lines can be simultaneously identified using a single sound wave measuring device, so it is more efficient than a device for identifying a path of an existing optical line, and a long distance with a single measurement channel compared to a conventional measurement channel. Measurement is possible and cost reduction is possible.

In addition, according to the present invention, it can be a fundamental technology for more efficiently managing and operating the configuration of the future optical line that is expected to become more complicated.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concept of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

Claims (10)

A path identification system for an optical line,
A sound wave generating device that generates sound waves in an arbitrary manhole,
A sound wave measuring device that is connected to a target optical line and inputs a plurality of pulse signals to the target optical line to collect a plurality of response data generated in an area including the target optical line, and
The frequency component of the plurality of response data is used to determine whether response data related to the sound wave is present among the plurality of response data, and when response data related to the sound wave is present, the arbitrary manhole of the target optical line Path identification device to determine by path
Path identification system of the optical line comprising a. In claim 1,
The path identification device
A path identification system for an optical line that generates frequency component data of the plurality of response data, respectively, and determines whether response data related to the sound wave is present using an amplitude value of the frequency component data. In claim 2,
The path identification device
A path identification system of an optical line that generates the frequency component data by performing Fourier transform on the plurality of response data. In claim 2,
The path identification device
At least one frequency component that satisfies a preset frequency band on the frequency component data is determined for each of the frequency component data, and a frequency component having a maximum amplitude value among the at least one frequency component is determined for each of the frequency component data. , A path identification system of an optical line that determines response data related to frequency component data having a maximum value among frequency components having a maximum amplitude value as response data related to the sound wave. In claim 4,
The preset frequency band
Path identification system of the optical line that is the frequency band of the sound wave. A method for a path identification system of an optical line to identify the path of the optical line,
Generating sound waves in an arbitrary manhole,
Inputting a plurality of pulse signals to a target optical line, collecting a plurality of response data generated in an area including the target optical line, and
It is determined whether response data related to the sound wave is present among the plurality of response data by using the amplitude value of the frequency component of each response data, and when the response data related to the sound wave is present, the arbitrary manhole is applied to the target optical line. To decide by the path of
Path identification method comprising a. In claim 6,
Determining whether there is response data related to the sound wave is
Generating frequency component data of each of the plurality of response data, and
Determining whether response data related to the sound wave exists using the amplitude value of the frequency component data
Path identification method comprising a. In claim 7,
Each step of generating the frequency component data
A path identification method for generating the frequency component data by performing a Fourier transform on the plurality of response data. In claim 7,
Determining whether there is response data related to the sound wave is
Determining at least one frequency component satisfying a preset frequency band on the frequency component data for each frequency component data,
Determining a frequency component having a maximum amplitude value among the at least one frequency component for each frequency component data, and
Determining response data related to frequency component data having a maximum value among frequency components having the maximum amplitude value as response data related to the sound wave
Path identification method comprising a. In claim 9,
The preset frequency band
Path identification method that is the frequency band of the sound wave.

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