KR20110038317A - Optical line termination, optical network terminal and passive optical network - Google Patents

Abstract

PURPOSE: An OLT(Optical Line Termination), an ONT(Optical Network Terminal), and a PON(Passive Optical Network) are provided to rapidly grasp the cause of a problem when a communication error happened in the PON. CONSTITUTION: A photo receiver(210) receives an optical signal from a plurality of ONTs. A state display device(230) receives an electric signal which shows the intensity of the optical signal from the photo receiver. If the intensity of the optical signal is within the predetermined range, the state display device displays the intensity state of the optical signal as a normal state. If the optical signal is not within the predetermined range, the state display displays the intensity state of the optical signal as an error state.

Description

Optical Line Termination, Optical Network Terminal and Passive Optical Network

The disclosed technology relates to optical line terminations, optical network terminations and passive optical networks.

Recently, as an optical subscriber network technology for efficiently providing various multimedia contents, it is easily applied to FTTH (Fiber To The Home), FTTN (Fiber To The Neighborhood), FTTP (Fiber To The Premise), FTTC (Fiber To The Curb) Many passive optical networks (PON) technologies are available.

The PON is constructed by connecting one optical line terminal (OLT) to a plurality of optical network terminals (ONTs) through a splitter. When the OLT and the ONT receive the optical signal through the optical cable, the OLT and the ONT convert the received optical signal into an electrical signal. At this time, in order for normal optical communication or link connection between the OLT and the ONT to be made, the received optical signal must be within a certain optical reception sensitivity, and the remaining communication modules should operate normally.

The technical problem to be solved by the disclosed technology is to provide an optical line terminal device, an optical network termination device and a passive optical network.

A first aspect of the disclosed technology to achieve the above technical problem is an optical receiver for receiving an optical signal from a plurality of optical network termination devices; And receiving an electrical signal indicating the intensity of the optical signal from the optical receiver, and displaying the intensity state of the optical signal in a normal state when the intensity of the optical signal is within a preset range, or in an error state when out of the range. It provides an optical line terminal device including a status display unit.

A second aspect of the disclosed technology to achieve the above technical problem is an optical transceiver; And a status display unit configured to receive an electrical signal indicating the intensity of the optical signal received by the optical transceiver and display the intensity state of the optical signal.

A third aspect of the disclosed technology to achieve the above technical problem is a passive optical network in which an optical line terminal device and a plurality of optical network termination devices are connected to each other, the optical line terminal device, the plurality of optical network termination devices An optical receiver configured to receive a first optical signal from the sensors; And a first state display unit configured to receive an electrical signal representing the intensity of the first optical signal from the optical receiver, and to display an intensity state of the first optical signal, wherein the optical network terminator is an optical transceiver. ; And a second state display unit displaying an intensity state of the second optical signal received by the optical transceiver.

Embodiments of the disclosed technology can have the effect of including the following advantages. However, the embodiments of the disclosed technology are not meant to include all of them, and thus the scope of the disclosed technology should not be understood as being limited thereto.

According to one embodiment of the disclosed technology, when a communication error occurs on a passive optical network, it is possible to quickly determine the cause of the problem. Since the optical network termination device and the optical line terminal device visually display a weak reception sensitivity of the optical signal through the LED, the user can recognize this in advance and prevent the communication error from occurring. In addition, the optical line terminal device may display the reception sensitivity for each connected optical network terminal device or for each optical network terminal device group. Therefore, the user may determine that the optical network terminal device or the optical line terminal device is defective, but the failure rate may be prevented from increasing, and the management cost may be reduced by solving the problem quickly and economically.

In addition, according to the disclosed technology, since the optical line terminal device automatically transmits an alarm message to the terminal of the administrator when the reception sensitivity is weak, there is an advantage that it is possible to quickly cope with a problem even if the administrator does not see the LED. The optical fiber terminator transmits an alarm message to the optical line terminal device when the reception sensitivity is weak so that the problem can be solved quickly.

The description of the disclosed technique is merely an example for structural or functional explanation and the scope of the disclosed technology should not be construed as being limited by the embodiments described in the text. That is, the embodiments may be variously modified and may have various forms, and thus the scope of the disclosed technology should be understood to include equivalents capable of realizing the technical idea.

On the other hand, the meaning of the terms described in the present application should be understood as follows.

The terms " first ", " second ", and the like are used to distinguish one element from another and should not be limited by these terms. For example, the first component may be named a second component, and similarly, the second component may also be named a first component.

When a component is referred to as being "connected" to another component, it should be understood that there may be other components in between, although it may be directly connected to the other component. On the other hand, when an element is referred to as being "directly connected" to another element, it should be understood that there are no other elements in between. On the other hand, other expressions describing the relationship between the components, such as "between" and "immediately between" or "neighboring to" and "directly neighboring", should be interpreted as well.

Singular expressions should be understood to include plural expressions unless the context clearly indicates otherwise, and terms such as "include" or "have" refer to features, numbers, steps, operations, components, parts, or parts thereof described. It is to be understood that the combination is intended to be present, but not to exclude in advance the possibility of the presence or addition of one or more other features or numbers, steps, operations, components, parts or combinations thereof.

Each step may occur differently from the stated order unless the context clearly dictates the specific order. That is, each step may occur in the same order as specified, may be performed substantially simultaneously, or may be performed in the reverse order.

All terms used herein have the same meaning as commonly understood by one of ordinary skill in the art unless otherwise defined. Terms defined in commonly used dictionaries should be interpreted to be consistent with meaning in the context of the relevant art and can not be construed as having ideal or overly formal meaning unless expressly defined in the present application.

1 is a view for explaining a passive optical network (PON). PON (100) is an optical subscriber construction method that provides a fiber-based high-speed service to businesses or homes, using a splitter 130 to the optical cable to allow one OLT 110 to connect several ONT (120) That's the way. PON 100 is connected to other networks and service node interface (service node interface) (OLT 110) to start the PON, the splitter 130 for branching the optical fiber from the OLT into several strands of optical fiber, and The ONT 120 is made of. Each of the ONTs is connected to at least one subscriber station via a user network interface.

The PON 100 includes a TDM (A) -PON using a time division multiplexing scheme and a WDM (A) -PON using a wavelength division multiplexing scheme. Time division multiplexing includes ATM-PON based on Asynchronous Transfer Mode (ATM), (G) E-PON based on Ethernet, and G-PON using common frame protocol.

When the optical module of the OLT 110 and the ONT 120 receives an optical signal through an optical cable, the optical module converts the received optical signal into an electrical signal. In this case, when a certain amount of optical signals are not received, the optical module may malfunction, thus causing a broken link or a problem in data transmission. However, the conventional OLT only displays the link information between the OLT and the ONT as link ON / OFF for each OLT port, and the link information for each ONT is not displayed, and it is difficult to distinguish the ONT failure. In addition, since the conventional OLT does not display the intensity information of the received optical signal, it is difficult for the user to recognize the problem only when the link is turned off, so that it is difficult to take precautions before the problem occurs.

In addition, in the case of the conventional ONT, the reception sensitivity of the optical signal received from the OLT was confirmed only by the CLI (Command Line Interface) through the main CPU in the ONT. Therefore, it was difficult for the user to find the cause of the problem when the phenomenon of not receiving the ONT link when the optical reception sensitivity was weak due to the defect of the optical cable.

2A is a block diagram illustrating an optical line terminal device according to an embodiment of the disclosed technology. In the conventional optical line terminal device, when the optical signal is not converted into an electrical signal normally, the sensitivity of the optical signal received due to a problem on the optical cable is out of a certain range, or the optical line terminal device may not convert properly. It could not be confirmed easily. The optical line terminal 110 according to the disclosed technology is to visually express the intensity of the received optical signal, so that it is easy to identify the problem, it is possible to respond quickly to the problem. Referring to FIG. 2A, an optical line terminal device 110 according to the disclosed technology includes an optical receiver 210, a storage 220, a status display 230, and an alarm 240.

The optical line terminal 110 may further include an optical transmission module (not shown) and a PON chip module (not shown) according to an embodiment. The optical transmission module is a module for transmitting an optical signal to the plurality of optical network terminators 120. The optical transmission module includes a laser diode for outputting an optical signal and a laser driver for driving a laser diode according to an optical transmission active signal. can do. According to an implementation example, the optical transmission module may be implemented as one module, such as the optical receiver 210. The PON chip module provides data and an optical activity signal to be transmitted to the optical transmission module, or receives and processes data from which the optical signal received at the optical receiver 210 is photoelectrically converted from the optical receiver 210, and is provided with an optical line terminal device. The module 110 controls the overall operation. In some embodiments, some or all of the status display unit 230, the storage unit 220, or the alarm unit 240 may be implemented in the PON chip module.

The optical receiver 210 receives an optical signal from the plurality of optical network terminators 120. Since the plurality of optical network terminators 120 transmit an optical signal in a wavelength or time slot allocated to the optical network terminal device 120 according to the WDM method or the TDM method, the optical line terminal device 110 receives the optical signal received by the optical receiver 210. May determine which optical network termination device 120 has received. According to an embodiment, the optical receiver 210 may be implemented as a photo diode that receives an optical signal and converts it into an electrical signal and an amplifier that amplifies the converted electrical signal.

The light receiver 210 may provide the amplified electric signal to the storage 220 or the status display 230. Alternatively, the optical receiver 210 may provide an SD (Signal Detect) signal to the storage 220 or the status display 230. The SD signal is a signal indicating the detection state of the optical signal when an optical signal of a predetermined level or more is received from the optical network terminator.

The storage unit 220 stores an initial intensity value of the optical signal received by the optical receiver 210. For example, the storage unit 220 is an optical network termination device corresponding to the signal strength when the first optical signal is received from each optical network termination device 120 after power is applied to the optical line terminal device 110 ( 120 may be stored as an initial intensity value. The initial intensity value is classified and stored for each optical network terminator 120. The initial intensity value may be provided directly from the light receiving unit 210 or may be provided from the status display unit 230 according to an embodiment.

The status display unit 230 receives an electric signal (electrically amplified and amplified photoelectric signal, or SD signal) indicating the intensity of the optical signal received from the optical receiver 210, and the intensity of the optical signal is set in a range (hereinafter, Display the intensity state of the optical signal to a normal state if the range is within the normal range and to an error state if the range is out of the range. The normal range means a section that is greater than or equal to the first boundary value and less than or equal to the second boundary value (first boundary value <second boundary value), and the case within the normal range means that the intensity of the optical signal is greater than or equal to the first boundary value, It means the case below the 2nd boundary value. On the contrary, the case outside the normal range means a case where the intensity of the optical signal is less than the first boundary value or exceeds the second boundary value.

For example, the status display unit 230 receives the electric signal amplified by the light receiving unit 210, and compares it with the normal range, and displays the intensity state in the normal state if it is within the normal range, and in the error state outside the normal range. can do. As another example, the status display unit 230 receives the SD signal from the light receiving unit 210, and is in a normal state when the SD signal is enabled, and in an error state when the SD signal is disabled. The intensity status can be displayed. The SD signal may be activated when the optical signal has a voltage higher than a predetermined level (eg, 200 mV). The normal range may be predetermined by the device developer or the like according to specifications or requirements of the optical module, the optical cable, and the like.

As another example, the normal range may again be divided into a first normal range and a second normal range. For example, the first normal range may be an optimal optical signal intensity range determined by the developer or the like. The second normal range is a range in which electrical signal conversion is normally performed out of the first normal range, and may be a light intensity range requiring attention as an intermediate state between a normal state and an error state. In this case, if the optical signal strength is within the first normal range, the "normal state" is outside the first normal range, but is within the second normal range, "attention state", and if the optical signal strength is outside the second normal range, the "error state". The intensity status can be displayed.

2B is a view for explaining the first and second normal ranges. For example, referring to FIG. 2B, the first normal range means a section that is greater than or equal to the third boundary value and less than or equal to the fourth boundary value (first boundary value <third boundary value <fourth boundary value <second boundary value). The case within the first normal range means that the intensity of the optical signal is greater than or equal to the third boundary value and less than or equal to the fourth boundary value (normal state). The second normal range means a section that is greater than or equal to the first boundary value and less than or equal to the second boundary value. When the second normal range is out of the first normal range but within the second normal range, the intensity of the optical signal is greater than or equal to the first boundary value. It means that it is less than 3 boundary value, or it exceeds 4th boundary value and is below 2nd boundary value (attention state). An error range outside the normal range means a case where the intensity of the optical signal is less than the first boundary value or exceeds the second boundary value (error state).

According to another exemplary embodiment, the state display unit 230 may determine the intensity state to be displayed based on the difference between the initial intensity value stored in the storage unit 220 and the intensity value of the optical signal. For example, when the difference exceeds a predetermined first threshold value, the intensity state may be displayed as an error state, and when the difference is less than or equal to the first threshold value, the intensity state may be a normal state. In another example, the difference is an error state when the first threshold is exceeded, and when the difference is less than or equal to the first threshold and exceeds the second threshold (first threshold value> second threshold value), a "caution state". In the case of "below or below the second threshold value," the intensity state may be displayed in the "normal state".

According to an exemplary embodiment, the status display unit 230 may classify and display the intensity state of the optical signal for each optical network terminator 120 that transmits the optical signal. The status display unit 230 includes a plurality of display devices, and maps each of the optical network termination devices to the display device. Each display device displays the intensity status of the mapped fiber termination device. For example, the status display unit 230 maps the first optical network terminator to the first display device and the second optical network terminator to the second display device, and then sets the intensity state of the first optical network terminator. The intensity of the second optical network terminator may be displayed on the first display device on the second display device.

According to another exemplary embodiment, the plurality of optical network terminators may be classified into a plurality of optical network terminator groups, and the status display unit 230 may include an optical network terminator that transmits an optical signal in an intensity state of the optical signal. It can be displayed separately by group of fiber termination devices. Fiber terminator groups may, for example, be divided by region.

According to an exemplary embodiment, the status display unit 230 may display the intensity state of the optical fiber terminator group if any one of the optical signal strengths received from the optical network terminators belonging to the optical network terminator group is out of a preset range. It can be displayed as an error condition. For example, the first to fourth optical network terminators may be classified into a first group, and the fifth to eighth optical network terminators may be classified into a second group. The second group displays the intensity state on the second display device. In this case, when all of the first to fourth optical network terminators are in a normal state, the first display device displays a normal state, and when any one of the first to fourth optical network terminators is in an error state, the first display device is displayed. Displays the error status. In another embodiment, the status display unit 230 may average the intensity of the optical signal received from the optical termination device belonging to the optical termination device group and display the intensity state based on this.

The alarm unit 240 transmits an alarm message indicating that there is an error in the optical signal to the terminal of the manager when the state of the intensity of the optical signal is outside the preset range. The message transmitted to the manager's terminal (PC, mobile phone, etc.) may be transmitted in the form of email, SMS, MMS.

3 is a block diagram illustrating the state display unit of FIG. 2A. Referring to FIG. 3, the status display unit 230 includes an LED module 310 and an LED controller 320. The LED module 310 includes more than the number of light emitting diodes (LEDs) 312, 314, 316, and 318 of the plurality of optical network termination devices. The LED controller 320 maps each of the plurality of optical network termination devices to a corresponding LED, and then displays the intensity state for each of the optical network termination devices that transmit the optical signal and displays the corresponding LEDs. For example, after mapping the first optical network terminator to the first LED 312 and the second optical network terminator to the second LED 314, the intensity of the optical signal received from the first optical network terminator. The state may be displayed on the first LED 312 and the intensity state of the optical signal received from the second optical network terminator on the second LED 314.

Each intensity state displayed on the LED may be displayed in different colors or different emission frequencies. For example, the normal state may be displayed in green, the attention state in yellow, and the error state in red. Alternatively, the steady state may be displayed at a light emission frequency of 1 Hz, and the error state may be displayed at a light emission frequency of 5 Hz.

As described above, the status display unit 230 displays the intensity status for each optical terminal device or each optical network device group. The intensity state may include two or three or more states, and different colors or different emission frequencies may be used to distinguish the intensity states. By displaying the received optical signal strength, the optical line terminal 110 makes it easy for a user to recognize the state of the strength and facilitates the identification and coping of a problem. In addition, by subdividing the intensity state, it is possible to display not only the normal state but also the attention state, thereby preventing the problem of optical signal transmission error.

4A is a block diagram illustrating an optical network terminator according to an embodiment of the disclosed technology. The optical network terminator 120 according to the disclosed technology causes the optical network terminator 120 to display the state of the intensity of the received optical signal so that the optical signal does not normally convert into an electrical signal. It is easy to see if the problem. Referring to FIG. 4A, the optical network terminator 120 includes an optical transceiver 410, a storage 420, a status display 430, and an alarm 440.

The optical transceiver 410 receives an optical signal from the optical line terminal device 110 or transmits an optical signal to the optical line terminal device 110. According to an embodiment, the optical transmission / reception unit 410 may receive an optical signal and an optical transmission module including a laser diode that outputs an optical signal and a laser driver that drives the laser diode according to an optical transmission active signal. The photodiode may be implemented as an optical receiving module including a photo diode converting an electrical signal and an amplifier amplifying the converted electrical signal. The optical transceiver 410 provides the amplified electric signal or the SD signal to the storage 420 or the status display 430.

The storage unit 420 stores the initial intensity value of the optical signal received by the optical transceiver 410. The storage unit 420 may store the intensity of the optical signal received from the optical line terminal 110 for the first time after power is applied to the optical network terminator 120 as an initial intensity value. The initial intensity value may be provided from the optical transceiver 410 or may be provided from the status display unit 430, according to an embodiment.

The status display unit 430 receives an electric signal (amplified electric signal or SD signal) indicating the intensity of the optical signal received by the optical transceiver 410 from the optical transceiver 410 and displays the intensity state of the optical signal. do. For example, the status display unit 430 receives the electrical signal amplified by the optical transceiver 410, and compares it with the normal range set by the designer, etc., within the normal range to the normal state, if outside the normal range error The status can be displayed as the status. As another example, the status display unit 430 receives the SD signal from the optical transceiver 410, and is in a normal state when the SD signal is enabled, and an error when the SD signal is disabled. You can also display the intensity status as a status.

As another example, the intensity state displayed by the state display unit 430 may include a first state (normal state) in which the intensity of the amplified electric signal is within a first threshold range, and the first threshold range. A second state (attention state) that is out of the second threshold range and a third state (error state) that is in a state outside the second threshold range may be included. The first threshold range and the second threshold range are preset by a developer or the like according to the specifications or requirements of the optical network termination devices 120, and the second threshold range is a larger range including the first threshold range.

4B is a diagram for explaining the first and second threshold ranges. For example, referring to FIG. 4B, the first threshold range means a section that is greater than or equal to the third threshold value and less than or equal to the fourth threshold value. When the first threshold range is less than the third threshold value, the intensity of the optical signal is greater than or equal to the third threshold value. , It means the case below 4th threshold value (normal state). The second threshold range means a section that is greater than or equal to the first threshold value and less than or equal to the second threshold value. The second threshold range is outside the first threshold range but is within the second threshold range, wherein the intensity of the optical signal is greater than or equal to the first threshold value. It means that it is less than 3 boundary value, or it exceeds 4th boundary value and is below 2nd boundary value (attention state). The error range outside the second threshold range means a case where the intensity of the optical signal is less than the first boundary value or exceeds the second boundary value (error state). (First boundary value <third boundary value <fourth boundary value <second boundary value)

As another example, the status display unit 430 may display a relative intensity state by comparing the initial intensity value stored in the storage unit 420 with the intensity value of the optical signal received from the optical transceiver 410. The relative intensity state is, for example, a first state (normal state) in which a difference between an initial intensity value and an intensity value of a received optical signal is smaller than a preset first value, and the difference is greater than the first value and greater than the first value. It may include a second state (attention state) that is smaller than the second value preset as a value, and a third state (error state) whose difference is greater than or equal to the second value.

The status display unit 430 may include an LED according to an embodiment, and display the intensity state through the LED. In this case, each intensity state displayed on the LED may be displayed in different colors or different emission frequencies.

The alarm unit 440 transmits an alarm message indicating that there is an error in the optical signal when the intensity state is an error state to the optical line terminal device 110 through the optical transceiver unit 410. The optical line terminal 110 may transmit the alarm message to the terminal of the manager of the device in response to receiving the alarm message. Messages sent to the manager may be sent in the form of email, SMS, MMS.

5 is a block diagram illustrating a passive optical network according to an embodiment of the disclosed technology. Referring to FIG. 5, the passive optical network 500 is constructed by connecting an optical line terminal device 510 and a plurality of optical network terminators 520. The passive optical network constructed by connecting the optical line terminal device 110 of FIG. 2A and the optical network termination device 120 of FIG. 4A corresponds to the embodiment of the passive optical network 500 of FIG. 5, and thus, FIGS. 2A to 4A. The part described in is also applied to this embodiment as it is.

The optical line terminal device 510 includes an optical receiver 511, a storage 512, a status display 513, and an alarm 514. The optical receiver 511 receives the first optical signal from the plurality of optical network terminators 520. The first storage unit 512 stores the initial intensity value of the first optical signal received by the light receiver 511.

The first state display unit 513 receives an electrical signal indicating the intensity of the first optical signal from the light receiver 511 and displays the intensity state of the first optical signal. For example, the first state display unit 513 compares the electric signal provided from the light receiving unit 511 with a threshold value of a preset normal range to be in a normal state if it is within the normal range, and in an error state if it is out of the normal range. Can be displayed. As another example, the first state display unit 513 compares the initial intensity value stored in the first storage unit 512 with the intensity value of the first optical signal, and if the difference is within the normal range, the first state display unit 513 returns to the normal state, out of the normal range. As a surface error state, you can display the relative intensity state. As another example, the plurality of optical network terminators 520 may be classified into a plurality of optical network terminator groups, and the first state display unit 513 may transmit the first optical signal to the intensity state. The device 520 may be classified and displayed according to the optical network termination device group.

According to an exemplary embodiment, the first state display unit 513 may include an LED module 515 and a plurality of optical network termination devices including LEDs (Light Emitting Diodes) of the plurality of optical network termination devices 520. After mapping to the corresponding LED, it may include an LED control unit 516 for displaying the intensity state by the optical network terminal for transmitting the optical signal to the corresponding LED. According to another embodiment, the LED module 515 includes as many LEDs as the number of optical network termination group, and the LED controller 516 maps each optical network termination group to each LED, The intensity status can be displayed on the corresponding LED for each group of fiber termination devices.

When the intensity state of the first optical signal is out of a preset range, the first alarm unit 514 transmits an alarm message indicating that there is an abnormality in the first optical signal to the terminal of the manager.

The optical network terminator 520 includes an optical transceiver 521, a second storage unit 522, a second status display unit 523, and a second alarm unit 524. The optical transceiver 521 receives an optical signal from the optical line terminal device 510 or transmits an optical signal to the optical line terminal device 510. The second storage unit 522 stores the initial intensity value of the second optical signal.

The second state display unit 523 displays the intensity state of the second optical signal received by the optical transceiver 521. For example, the second state display unit 523 may display the steady state, error state, or intensity state by comparing the second optical signal with a preset boundary value of the normal range. As another example, the second state display unit 523 may display a relative intensity state by comparing the initial intensity value stored in the second storage unit 522 with the intensity value of the second optical signal.

 When the intensity state of the second optical signal is outside the preset range, the second alarm unit 524 transmits an alarm message indicating that there is an error in the second optical signal through the optical transceiver unit 521 to the optical line terminal device 510. ).

The disclosed method and apparatus have been described with reference to the embodiments shown in the drawings for ease of understanding, but these are merely exemplary, and various modifications and equivalent other embodiments are possible to those skilled in the art. Will understand. Therefore, the true technical protection scope of the disclosed technology should be defined by the appended claims.

1 is a view for explaining a passive optical network.

2A is a block diagram illustrating an optical line terminal device according to an embodiment of the disclosed technology.

2B is a view for explaining the first and second normal ranges.

3 is a block diagram illustrating the state display unit of FIG. 2A.

4A is a block diagram illustrating an optical network terminator according to an embodiment of the disclosed technology.

4B is a diagram for explaining the first and second threshold ranges.

5 is a block diagram illustrating a passive optical network according to an embodiment of the disclosed technology.

Claims (19)

An optical receiver for receiving an optical signal from a plurality of optical network termination devices; And Receiving an electrical signal indicating the intensity of the optical signal from the optical receiver, and displaying the intensity state of the optical signal in a normal state when the intensity of the optical signal is within a preset range and in an error state when out of the range; Optical line terminal device including a status display. The method of claim 1, wherein the status display unit, The optical line terminal device for displaying the intensity status by dividing the optical network terminal device by the optical signal. The method of claim 2, wherein the status display unit, A plurality of light emitting diodes corresponding to the plurality of optical network termination devices; And And a light emitting diode controller configured to display the intensity state of the light emitting diodes corresponding to the optical network terminators that have transmitted the optical signal. The method of claim 1, The plurality of optical network terminators are classified into a plurality of optical network terminator groups, And the status display unit displays the strength status by dividing the intensity status by an optical network terminator group to which the optical network terminator which transmitted the optical signal belongs. The method of claim 4, wherein And the status display unit displays the intensity state in an error state when any one of the intensity of the optical signal received from the optical end device belonging to the optical end device group is out of a preset range. The method of claim 2, The apparatus may further include a storage configured to classify and store an initial intensity value of the optical signal for each optical network terminator for transmitting the optical signal. And the status display unit determines an intensity state to be displayed for each optical network terminator that has transmitted the optical signal based on a difference between the initial intensity value and the intensity value of the optical signal. The method of claim 1, The state display unit displays the intensity state through a plurality of light emitting diodes (LEDs), And each intensity state displayed on the LED is displayed in different colors or different emission frequencies. The method of claim 1, And an alarm unit for transmitting an alarm message indicating that there is an abnormality in the optical signal to the terminal of the manager when the intensity state is out of a preset range. Optical transceiver; And And a status display unit configured to receive an electric signal representing the intensity of the optical signal received by the optical transceiver and display the intensity state of the optical signal. 10. The method of claim 9, The intensity state is a first state in which the intensity of the optical signal is within a preset first threshold range, and the intensity of the optical signal is out of the first threshold range and is greater than the first threshold range. And a third state in which the intensity of the optical signal is out of the second threshold range and a third state within a second preset threshold range. 10. The method of claim 9, Further comprising a storage unit for storing the initial intensity value of the optical signal, And the state display unit displays a relative intensity state by comparing the initial intensity value with the intensity value of the optical signal. The method of claim 11, The relative intensity state is a first state in which a difference between the initial intensity value and the intensity value of the optical signal is smaller than a preset first value, and the difference is previously set to a value greater than or equal to the first value and greater than the first value. And a third state in which the difference is greater than or equal to the second value. 10. The method of claim 9, The status display unit displays the intensity status through an LED (Light Emitting Diode), Each intensity state displayed on the LED is an optical network termination device that is displayed in a different color or different emission frequency. 10. The method of claim 9, And an alarm unit for transmitting an alarm message indicating that there is an abnormality in the optical signal to the optical line terminal device when the intensity state is out of a preset range. In a passive optical network in which an optical line terminal device and a plurality of optical network termination devices are connected and constructed, The optical line terminal device, An optical receiver configured to receive a first optical signal from the plurality of optical network termination devices; And A first state display unit which receives an electrical signal representing the intensity of the first optical signal from the optical receiver and displays an intensity state of the first optical signal, The optical network termination device, Optical transceiver; And Passive optical network including a second status display for displaying the intensity of the second optical signal received by the optical transceiver. The method of claim 15, wherein the first status display unit LEDs (Light Emitting Diodes) of the number of the plurality of optical network termination devices; And A passive optical network including an LED controller for mapping each of the plurality of optical network termination devices to a corresponding LED, and then displaying the intensity state for each optical network termination device that transmits the optical signal and displaying the information on the corresponding LED. . The method of claim 15, The plurality of optical network terminators are classified into a plurality of optical network terminator groups, And the first status display unit classifies and displays the intensity status for each optical network terminator group to which the optical network terminator having transmitted the first optical signal belongs. The method of claim 15, The optical line terminal device further comprises a first storage unit for storing the initial intensity value of the first optical signal, The optical network terminator further includes a second storage unit for storing an initial intensity value of the second optical signal, The first state display unit displays a relative intensity state by comparing an initial intensity value stored in the first storage unit with an intensity value of the first optical signal, And the second state display unit displays a relative intensity state by comparing an initial intensity value stored in the second storage unit with an intensity value of the second optical signal. The method of claim 15, The optical line terminal device may further include a first alarm unit configured to transmit an alarm message indicating that there is an abnormality in the first optical signal to the terminal of the manager when the intensity state of the first optical signal is outside a preset range. , The optical network terminator transmits an alarm message indicating that there is an abnormality in the second optical signal to the optical line terminal device when the intensity state of the second optical signal is out of a preset range. The passive optical network further includes a second alarm unit.

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