KR101638316B1 - Optical Fiber Information Management System of Optical Network - Google Patents

Abstract

A line information management system according to the present invention includes: an OTDR (20) that is situated on one side of an optical communication line and includes a first mode for monitoring a disorder of the optical communication line and a second mode for generating line information, and a line information reading unit (30) that acquires the decoded line information from a radiation field of an optical core on an opposite side corresponding to the one side of the optical communication line, and the OTDR (20) generates an optical signal that is obtained by encoding the line information to provide the generated optical signal to each optical core in the second mode. According to the present invention, an operation may be performed without a support of a network managing center to identify line information of a core when an optical line is managed so that an operation efficiency can be improved, and the line information can be read without interrupting optical transmission equipment that is being managed.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

The present invention relates to a line information management system for an optical communication network, and more particularly, to a line information management system for reading and managing line information such as a line number in an optical communication network.

The optical fiber, which is a signal transmission medium of optical communication, is generally cabled in a single hard protective cloth in the form of bundles (144 cores, 288 cores, etc.) in the form of tens or hundreds of single core wires, Or an imaginary transmission line.

The fiber optic cable starts from the point of the installation section and is constructed in various forms such as point-to-point (P2P), annular, branch, etc. through connection and branching to a plurality of input end points.

In the installation section, the fiber optic cable is connected to the optical fiber connector at the end of each core wire when the optical cable reaches the incoming company through underground processing, and one at the side of the optical adapter for optical connector connection in the OFD (Optical Fiber Distribution) It is called optical fiber cluster.

If the optical connector connected to the optical transmission equipment is connected from the OFD to the other optical adapter of the other side, the optical core of the optical transmission equipment is connected to the optical core of the optical transmission equipment through the optical input core. Since a plurality of optical adapters are installed in the OFD, each optical adapter is numbered sequentially from 1, and this number is the number of the line (line number), and the manager of the optical transmission network uses the number And intermediate points and end points.

However, if an error occurs in the line number management due to the twist of the line as shown in FIG. 1, a communication failure occurs. Therefore, the line number information should be managed as important line management information.

On the other hand, a large-scale optical cable network such as a mobile communication optical transmission network frequently performs maintenance work on a light beam due to a communication failure.

When the operator wants to check the number of the optical core, the following method is usually used. This is a method in which a worker at a work site calls the network operation center to make an intentional communication failure to the optical core and confirms whether the optical communication equipment connected to the failed optical core actually occurs at the network operation center. The identification work is based on human cognitive sensation.

However, there is a problem that efficiency is inferior in that the operation can be performed only when the network operation center is required to support it. [0011] Second, there is a problem in that a temporary obstacle of the optical transmission network (called ' Third, there is a problem that the possibility of error due to human error is very high because the work based on human cognition takes the majority of the entire work. .

The recognition of the problems and problems of the prior art is not obvious to a person having ordinary skill in the art, so that the inventive step of the present invention should not be judged based on the recognition based on such recognition I will reveal.

It is an object of the present invention to provide a line information management system for an optical network having high workability, such that work can be performed without the need of a network operation center.

It is another object of the present invention to provide a line information management system for an optical communication network capable of reading line information without a line of optical transmission network.

It is another object of the present invention to provide a line information management system for an optical communication network capable of reducing human error and error occurrence possibility.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not restrictive of the invention, unless further departing from the spirit and scope of the invention as defined by the appended claims. It will be possible.

A line information management system according to an aspect of the present invention includes a first device for generating optical signals including encoded line information at one side of an optical communication line and providing the optical signals for each optical core, And a line information reading device for obtaining the line information decoded from the radiation field of the core.

In the above-mentioned line information management system, the line information reading device is paired with a smart phone or a portable PC, and the first device transmits a control command from the smart phone or the portable PC paired with the remote line information reading device And operates.

In the above-described line information management system, the first device may include: an MCU for generating a pattern in which the line information is encoded; A laser driving circuit for generating a light modulation current corresponding to the pattern; A laser for generating the optical signal using the optical modulation current; And a communication interface for performing at least the function of receiving the control command.

In the above-described line information management system, the first device is coupled to the operational core wire used by the optical transmission equipment through the optical coupler, and the line information reading device acquires the line information without the step of optical network operation .

The line information management system according to one aspect of the present invention includes an OTDR which is located at one side of an optical communication line and has at least a first mode for monitoring a fault of the optical communication line and a second mode for generating line information; And a line information reading device for obtaining the line information decoded from a radiation field of the optical core on the other side corresponding to one side of the optical communication line, wherein in the second mode, the OTDR is configured such that the line information is encoded And the optical signal is generated for each optical core.

In the above-described line information management system, in the first mode, the OTDR generates and emits optical pulses to the optical communication line, and uses optical pulses reflected from the optical communication line to return at least a fault position Is measured.

In the above-described line information management system, the line information reading device is paired with a smart phone or a portable PC, and the OTDR receives a control command from the smart phone or the portable PC paired with the remote line information reading device, .

In the above-described line information management system, the OTDR is coupled to the operational core line used by the optical transmission equipment through the optical coupler, and the line information reading device acquires the line information without operating the optical communication network .

In the above-described line information management system, the line information includes at least line number information of the optical core or identification information of the optical core.

In the above-described line information management system, the line information may include at least one of a line number, a viewpoint, a stopover point, a section distance, an endpoint, a wavelength of an operating light, a kind of a transmission equipment, a transmission speed, And at least one of them is included.

In the above-described line information management system, when obtaining the line information decoded from the radiation field, bending the optical core to such an extent that the line information can be obtained without causing a failure in the optical transmission system, The guide mechanism is used.

In the above-described line information management system, a smart phone or a portable PC may display all or a part of the obtained line information using the obtained line information, provide it to the management server, update the line information, And performing an error comparison.

In the above-described line information management system, the line information reading device may include: a photodiode for generating a current signal from the radiation field; A current-voltage conversion amplifier for converting the current signal into a voltage signal; A voltage amplifier for amplifying the voltage signal; An ADC for analog-to-digital converting the amplified voltage signal to generate a digital signal; And an MCU decoding the digital signal to restore the line information.

According to an aspect of the present invention, it is possible to perform work without the need of a network operation center in order to check the line information of the core when managing the optical line, so that the work cancellation is high, It is possible to read the line information without the line of the optical transmission equipment being operated.

In addition, according to one aspect of the present invention, there is no need for mutual communication with a network operation center in preparation for a conventional method, so that it is possible to perform single operation of a line worker and there is no need to pull out an optical connector. / There is an effect to prevent the twisting of the screen due to the human error that may occur between the raw clothes.

According to an aspect of the present invention, since measurement results can be transmitted to the Internet using an electronic device, a systematic line information management is performed in comparison with a conventional management method using a one-time work or a handwriting There is an effect that can be.

1 is a diagram illustrating an example of a communication failure situation due to a twisted line.
2 is a diagram illustrating an optical communication network to which a line information management system according to a first embodiment of the present invention is applied.
FIG. 3 is a block diagram illustrating a line information generator 10 according to an embodiment of the present invention. FIG. 3 (A) The module is configured by connecting 1 * N optical switch.
4 is a block diagram showing a line information reading apparatus 30 according to an embodiment of the present invention.
Fig. 5 is a diagram illustrating a situation in which line information is read. Fig. 5 (A) is a diagram illustrating a situation where a plug-in reading is performed. Fig. 5 Fig. 2 is a diagram illustrating a situation in which reading is performed using an information reading device;
6 is a diagram illustrating an optical communication network to which a line information management system according to a second embodiment of the present invention is applied.
7 is a block diagram showing a configuration of an OTDR 20 according to a second embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other features and advantages of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings in which: FIG. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention in the drawings, parts not related to the description are omitted, and similar names and reference numerals are used for similar parts throughout the specification.

2 is a diagram illustrating an optical communication network to which a line information management system according to a first embodiment of the present invention is applied.

The optical transmission equipment 51 and the optical transmission equipment 52 perform optical communication using an optical line and a plurality of OFDs (OFD1 and OFD2) are disposed in the optical line. An optical line management server 61 is provided for managing the optical line, And the database 62 are operated.

The line information management system according to the first embodiment of the present invention may include a line information generator 10 and a line information reader 30 and a smart phone or a portable PC 40. [

The line information generator 10 is an apparatus for generating optical signals including encoded line information at one side of an optical communication line and providing the optical signals for each optical core. The line information generator 10 includes an optical communication device 51, Coupled to the core wire. The optical coupler 71 may be, for example, a WDM (Wavelength Division Multiplexing) filter, a directional optical coupler, or an optical circulator.

The line information includes at least line number information of the optical core or identification information of the optical core. The line information includes at least the line number of the optical core, the identification information, the viewpoint, the intermediate point distance, the end point, the wavelength of the operating light, , Transport hierarchy, and announcements for optical cores.

The line information reading device 30 is a portable device that obtains decoded line information from the radiation field of the optical core on the other side corresponding to one side of the optical communication line, And reads the digital information from the radiation field, which is a field to be read.

The line information reading device 30 can acquire the line information without the 'line' of the optical network operation.

In the absence of bending in the optical fiber, the optical energy is trapped in the core in the form of a Gaussian distribution. On the other hand, when the bending is generated, the wavefront of the Gaussian distribution is distorted and the optical energy is radiated to the side having a large radius of curvature. The line information reading device 30 reads line information encoded from this radiation field into digital information.

Fig. 5 is a diagram illustrating a situation in which line information is read. Fig. 5 (A) is a diagram illustrating a situation where a plug-in reading is performed. Fig. 5 Fig. 2 is a diagram illustrating a situation in which reading is performed using an information reading device;

Assuming that the line information is to be read by the plug-in method as shown in FIG. 5 (A), the optical connector must be plugged into the reading device, which inevitably leads to a drawback of optical communication through the optical core.

On the other hand, in an embodiment of the present invention, the line information reading apparatus 30 reads out the line information composed of digital information from the optical core bent to such an extent that line information can be obtained without causing a fault in the optical transmission system.

As the radius of curvature becomes smaller, the strength of the radiation field increases, and if it is bent excessively, the optical transmission system may be obstructed, but the line worker It is possible to bend to a lesser degree because it is known that the degree of bending which causes an obstacle is experienced. That is, it is possible to apply the bending to the optical core only to the extent that the minimum copying area that can be read occurs and does not cause the failure.

Further, in acquiring the decoded line information from the radiation field, a guide mechanism may be used to guide the optical core to bend to such an extent that line information can be obtained without causing a failure in the optical transmission system.

The guide mechanism may be integrally constructed or separately formed in the line information reading apparatus, and it may be constructed such that an open pipe-shaped mechanism having a predetermined curvature is formed on the top or side surface of the line information reading apparatus, It may be in the form of a ring or bracelet.

2, the smartphone or the portable PC 40 is paired with the line information reading device 30 and communicates with the optical line management server 61 and the line information generator 10 via the wired / wireless communication network, The generating device 10 operates by receiving a control command from a smartphone or a portable PC 40 paired with the remote line information reading device 30. The smartphone or the portable PC 40 is connected to the line information generating device 10 ), Displays all or a part of the line information using the obtained line information, provides the line information to the optical line management server 61, updates the line information, or performs an error comparison .

FIG. 3 is a block diagram illustrating a line information generator 10 according to an embodiment of the present invention. FIG. 3 (A) The module is configured by connecting 1 * N optical switch.

The unit modules of the line information generator 10 or the line information generator 10 are configured to include the communication interface 11, the MCU 12, the laser driver circuit 13, and the laser 14.

The MCU 12 generates a pattern in which the line information is encoded and the laser drive circuit 13 generates and supplies the optical modulation current corresponding to the pattern generated in the MCU 12 to the laser 14, Receives a light modulation current from the laser driving circuit 13 and generates and emits an optical signal using the optical modulation current. The communication interface 11 receives a control command such as start or stop of signal generation from the outside In particular, the control information generated from the line information reading device 30.

The line information generator 10 may be configured to accommodate a plurality of unit modules in an aggregate form to transmit line information to a plurality of optical cores (refer to FIG. 3A) N optical switches may be connected to sequentially process transmission of line information for a plurality of lines (see Fig. 3 (B)).

4 is a block diagram showing a line information reading apparatus 30 according to an embodiment of the present invention.

The line information reading apparatus 30 according to an embodiment of the present invention includes a photodiode 31, a current-voltage conversion amplifier 32, a voltage amplifier 33, an ADC 34, an MCU 35, and a communication interface 36 ).

The photodiode 31 generates a current signal from the radiation field of the optical core and provides it to the current-to-voltage conversion amplifier 31. The current-to-voltage conversion amplifier 32 converts the current signal supplied from the photodiode 31 The voltage amplifier 33 amplifies the voltage signal supplied from the current voltage amplifier 32 and provides the amplified voltage signal to the ADC 34. The ADC 34 amplifies the voltage signal, The MCU 35 decodes the digital signal generated by the ADC 34 to restore the line information and the communication interface 36 is connected to the smartphone or the portable PC 40 ).

Hereinafter, a process of reading and managing line information using the line information management system according to the first embodiment of the present invention will be described.

First, the line information reading apparatus 30 is paired with a smart phone or a portable PC 40, and line information is generated through a wired / wireless communication network using a line information management application installed in a smart phone or a portable PC 40 And transmits the transmission start command to the line information of the corresponding line to the device (10).

Then, the MCU 12 of the line information generator 10 generates a pattern in which the line information is encoded, and the laser driving circuit 13 generates the optical modulation current corresponding to the pattern generated by the MCU 12, The laser 14 is supplied with a light modulation current from the laser driving circuit 13 and generates and emits an optical signal using the optical modulation current. The optical signal to be emitted is encoded with the line information .

The line information may include announcements of the optical core's line number, identification information, viewpoints, waypoints, distance, endpoints, wavelength of the operating light, type of transmission equipment, transmission speed, transmission metrics and optical core.

The line information generating apparatus 10 transmits a confirmation message to the line information reading apparatus that the operation has been started using the communication interface 36. [

Then, the operator forms a radius of curvature within a predetermined range in the optical core to be worked and then approaches the photodiode 31 of the line information reading device 30. [ The radius of curvature within a predetermined range may be the radius of curvature of the optical core that is capable of reading line information without causing interference to the optical transmission system.

The photodiode 31 of the line information reading device 30 generates a current signal from the radiation field of the optical core and provides it to the current-to-voltage conversion amplifier 31, The voltage amplifier 33 amplifies the voltage signal supplied from the current voltage amplifier 32 and provides the amplified voltage signal to the ADC 34. The voltage amplifier 33 amplifies the voltage signal supplied from the current amplifier 31, The ADC 34 converts the amplified voltage signal into an analog signal to generate a digital signal, and the MCU 35 decodes the digital signal generated by the ADC 34 to recover the line information.

When the line information reading apparatus 30 reads the line information, the smart phone or the portable PC 40 paired therewith displays all or part of the line information using the obtained line information, or displays the line information to the light path management server 61 Provides line information to update line information or compare errors.

When the line information generator 10 uses the 1 * N optical switch in the unit module as shown in FIG. 3 (B), when the line information is read from the other optical core, The line information can be outputted to the corresponding optical core.

When the operation is completed, the line information reading device 30 transmits a command to stop the transmission of the line information to the line information generator 10.

6 is a diagram illustrating an optical communication network to which a line information management system according to a second embodiment of the present invention is applied.

In the line information management system according to the second embodiment of the present invention, the function of the line information generator 10 is integrally implemented in the OTDR 20 instead of the line information generator 10 of the first embodiment.

Hereinafter, configurations and operations different from those of the first embodiment of the present invention will be mainly described, and description of the same or similar parts will be omitted.

The OTDR 20 according to the second embodiment of the present invention includes a first mode for monitoring the failure of the optical communication line and a second mode for monitoring the failure of the optical communication line. And a second mode for generating the second mode.

In the first mode, the OTDR 20 generates and emits optical pulses to the optical communication line, measures the obstacle position of at least the optical communication line using the optical pulse reflected from the optical communication line, and returns to the optical communication line. Is the general operation performed by the OTDR 20 of FIG.

In the second mode, the OTDR 20 encodes the line information to generate an included optical signal and provides the optical signal for each optical core.

The OTDR 20 is coupled to the operational core used by the optical transmission equipment through the optical coupler 71, and the line information reading device acquires the line information without operating the optical communication network.

The line information reading device 30 is paired with a smartphone or a portable PC 40 and the OTDR 20 transmits a control command from a smart phone or a portable PC 40 paired with the remote line information reading device 30. [ And operates.

FIG. 7 is a block diagram showing a configuration of an OTDR 20 according to a second embodiment of the present invention. The hardware configuration is the same as or similar to that of a general OTDR.

In the first mode, the MCU 22 of the OTDR 20 generates and supplies an electrical pulse signal to the laser driver 23, which drives the laser 24 in accordance with the pulse signal, 24 are driven by the laser driving unit 12 to generate high-output optical pulses and output them to the optical path via the optical coupler.

The photodiode 25 receives the light reflected by the incident light pulse and returns to the photodiode 25. The current-voltage conversion amplifier 26 converts the current signal from the photodiode 16 into a voltage signal and amplifies the voltage signal. The voltage amplifier 27 amplifies the voltage. The ADC 18 analog-to-digital converts the voltage and provides the voltage to the MCU 22, and the MCU 22 performs functions such as reading the fault position from the reflected light.

In the second mode, the MCU 22 of the OTDR 20 generates an electric signal in which the above-mentioned line information is encoded and included, and provides the electric signal to the laser driver 23. The laser driver 23 drives the laser And the laser 24 is driven by the laser driving unit 23 so that the line information is encoded to generate the included optical signal and output to the optical line via the optical coupler.

As described above, the conventional OTDR is provided with the laser 24, the laser driver 23, the MUC 22, the communication interface 21, and the like in order to monitor the failure, and according to the second embodiment of the present invention, To change the function of the conventional OTDR so as to have a function as a line information generator. According to the second embodiment of the present invention, since the line information reading apparatus 30 is a device used by an operator while the line information generating apparatus uses a general OTDR hardware configuration, An information reading system can be easily implemented.

Hereinafter, a process of reading and managing line information using the line information management system according to the second embodiment of the present invention will be described.

First, the line information reading device 30 is paired with a smartphone or a portable PC 40, and an OTDR 2 (or a smart phone) is connected to the smartphone or the portable PC 40 through a wired / wireless communication network, ) To transmit the command for setting the operation mode to the second mode and the transmission start command for the line information of the line.

Then, the MCU 22 of the OTDR 20 generates a pattern in which the line information is encoded, and the laser driver 23 generates an optical modulation current corresponding to the pattern generated by the MCU 22, The laser 24 is supplied with a light modulation current from the laser driver 23 and generates and outputs an optical signal using the optical modulation current. The optical signal to be emitted is encoded and included in the optical signal.

The line information may include announcements of the optical core's line number, identification information, viewpoints, waypoints, distance, endpoints, wavelength of the operating light, type of transmission equipment, transmission speed, transmission metrics and optical core. Then, the OTDR 20 transmits an acknowledgment message to the line information reading apparatus that the operation is started using the communication interface 21. [

Then, the operator forms a radius of curvature within a predetermined range in the optical core to be worked and then approaches the photodiode 31 of the line information reading device 30. [ The radius of curvature of a predetermined range may be the radius of curvature of the optical core that is capable of reading line information without causing obstruction to the optical transmission system.

The photodiode 31 of the line information reading device 30 generates a current signal from the radiation field of the optical core and provides it to the current-to-voltage conversion amplifier 31, The voltage amplifier 33 amplifies the voltage signal supplied from the current voltage amplifier 32 and provides the amplified voltage signal to the ADC 34. The voltage amplifier 33 amplifies the voltage signal supplied from the current amplifier 31, The ADC 34 converts the amplified voltage signal into an analog signal to generate a digital signal, and the MCU 35 decodes the digital signal generated by the ADC 34 to recover the line information.

When the line information reading apparatus 30 reads the line information, all or part of the line information is displayed by using the line information obtained by using the smart phone or the portable PC 40, Information is provided to update the line information or perform error comparison.

When the OTDR 20 uses a 1 * N optical switch in the unit module, the optical core is transmitted with a command for switching the optical core to output line information to the optical core. .

When the operation is completed, the line information reading device 30 transmits an instruction to stop transmission of the line information to the OTDR 20.

Hereinafter, effects of the invention according to various aspects of the present invention will be described.

In the prior art, after the intended optical connector is directly pulled or bending or bending is applied, intentional trouble is generated, and then the corresponding transmission device is checked to see if a failure has occurred, And this is a serious problem that not only the operation efficiency but also the operational reliability of the transmission network is lowered.

On the other hand, according to one aspect of the present invention, it is possible to perform work without the need of a network operation center in order to confirm the line information of the core when managing the optical line, so that the work cancellation is high. There is an effect that the line information can be read without the step of the optical transmission equipment which is in operation and is not necessary.

In addition, according to one aspect of the present invention, there is no need for mutual communication with a network operation center in preparation for a conventional method, so that it is possible to perform single operation of a line worker and there is no need to pull out an optical connector. / There is an effect to prevent the twisting of the screen due to the human error that may occur between the raw clothes.

According to an aspect of the present invention, since measurement results can be transmitted to the Internet using an electronic device, a systematic line information management can be performed in comparison with a conventional management method using a one-time work or a handwriting There is an effect.

10: Line information generator 20: OTDR
30: Line information reading device 40: Smartphone or portable PC
51, 52: optical transmission device 61: optical line management server
62: Database

Claims (13)

A first device for generating optical signals including at least optical line information of the optical core or identification information of the optical core on one side of the optical communication line and encoding the optical signal and providing the optical signal for each optical core;
And a line information reading device for obtaining the line information decoded from a radiation field of the optical core at the other side corresponding to one side of the optical communication line, the line information being portable by an operator. The method according to claim 1,
The line information reading device is paired with a smart phone or a portable PC,
Wherein the first device is operated by receiving a control command from the smartphone or the portable PC paired with the remote line information reading device,
Wherein the line information management system comprises: The method of claim 2,
The first device comprises:
An MCU for generating a pattern in which the line information is encoded;
A laser driving circuit for generating a light modulation current corresponding to the pattern;
A laser for generating the optical signal using the optical modulation current;
A communication interface for performing at least the function of receiving the control command;
The line information management system comprising: The method according to claim 1,
The first device is coupled to the operating core wire used by the optical transmission equipment through the optical coupler,
The line information reading device may be configured to acquire the line information without operating the optical communication network,
Wherein the line information management system comprises: At least a first mode for measuring a failure position of the optical communication line and a second mode for generating line information including at least optical line information of the optical line or identification information of the optical line, OTDR;
And a line information reading device for obtaining the line information decoded from the radiation field of the optical core at the other side corresponding to one side of the optical communication line,
Wherein the OTDR in the second mode generates an optical signal including the encoded line information,
Wherein the line information management system comprises: The method of claim 5,
In the first mode,
And generating an optical pulse from the optical communication line and outputting the optical pulse; and measuring a fault position of at least the optical communication line using optical pulses reflected from the optical communication line,
Wherein the line information management system comprises: The method of claim 5,
The line information reading device is paired with a smart phone or a portable PC,
Wherein the OTDR is operated by receiving a control command from the smartphone or the portable PC paired with the remote line information reading device,
Wherein the line information management system comprises: The method of claim 5,
The OTDR is coupled to the operating core wire used by the optical transmission equipment through the optical coupler,
The line information reading device may be configured to acquire the line information without operating the optical communication network,
Wherein the line information management system comprises: delete The method according to claim 1 or 5,
Wherein the line information further includes at least one of a viewpoint of the optical core, a stopping point, a section distance, an end point, a wavelength of an operation light, a type of a transmission equipment, a transmission speed,
Wherein the line information management system comprises: The method according to claim 1 or 5,
In obtaining the line information decoded from the radiation field,
Which uses a guide mechanism for guiding the optical core to bend to such an extent that the line information can be obtained without causing a failure in the optical transmission system,
Wherein the line information management system comprises: The method according to claim 2 or 7,
In the smart phone or the portable PC,
Performing at least one or more operations of displaying all or a part of the obtained line information using the obtained line information, providing the line information to a management server, updating line information, or performing an error comparison,
Wherein the line information management system comprises: The method according to claim 1 or 5,
The line information reading device includes:
A photodiode for generating a current signal from the radiation field;
A current-voltage conversion amplifier for converting the current signal into a voltage signal;
A voltage amplifier for amplifying the voltage signal;
An ADC for analog-to-digital converting the amplified voltage signal to generate a digital signal;
And an MCU decoding the digital signal to restore the line information.
Wherein the line information management system comprises:

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