KR101325858B1 - Apparatus and method for adaptive optical power controlling, optical communication system and for the same - Google Patents

Abstract

The present invention relates to an apparatus and method capable of adaptively adjusting optical power, and an optical communication system therefor. The optical power adjusting device of the present invention collects light surveillance information when an optical signal is input and controls the light source output using the light surveillance information.

Description

APPARATUS AND METHOD FOR ADAPTIVE OPTICAL POWER CONTROLLING, OPTICAL COMMUNICATION SYSTEM AND FOR THE SAME

The present invention relates to the field of optical communication, and more particularly, to an apparatus and method capable of adaptively adjusting optical power, and an optical communication system therefor.

An optical communication system using a wavelength division multiplexing access (WDMA) is a method of transmitting and receiving optical signals of different wavelengths output from a plurality of optical transceivers through a single optical fiber using a wavelength division multiplexing device. The wavelength division multiple access can transmit a large amount of data at the same time, thereby increasing the bandwidth between the transmission intervals, and the rental cost of the optical line by transmitting data using one optical fiber instead of using multiple optical fibers And there is an advantage to save the maintenance cost.

In the conventional wavelength division multiplexing connection, the wavelength is fixed for each connection port according to the number of connection ports of the wavelength division multiplexing device composed of an optical thin film filter (TFF) or an arrayed waveguide grating (AWG). Since a large number of optical transceivers are required, a system operator has difficulty in securing and storing a plurality of optical transceivers having fixed wavelengths for each access port in accordance with system expansion or increase in subscribers.

In order to solve this problem, Korea Patent Registration No. 10-0325687 and "Light source for wavelength-division multiplex optical communication using a Fabry-Perot laser diode immersed in injected non-coherent light" using a seed light source and U.S. Patent Publication No. 2003007207 entitled "Optical Signal Transmitter" describes wavelength independent multiplexing (colorless or color free) that automatically determines the optical output wavelength of an optical transceiver at a wavelength assigned to a connection port of an optical transceiver and a wavelength division multiplexing device. A formal connection has been proposed. According to this proposal, non-coherent broadband light is passed through an optical thin film filter or an arrayed waveguide diffraction grating, and then injected into a Fabric-Perot Laser Diode (FP LD), Semiconductor Optical Amplifier (SOA), or Reflective Semiconductor Optical Amplifier (RSAA). In this case, the same optical signal wavelength as the assigned wavelength is outputted according to the connection port of the wavelength division multiplexing device.

Wavelength-independent wavelength division multiplex optical communication system has a plurality of optics in which the output light of the seed light source of the optical line terminal (OLT) located in the central office (CO) is located at a remote node (RN). Passes through a pass band allocated for each connection port of a wavelength division multiplexing device including a thin film filter (TFF) or an arrayed waveguide grating (AWG). The seed light source passing through the access port of the wavelength division multiplexing device is injected into a wavelength independent optical transceiver composed of a light source of FP LD, SOA or RSOA located in an optical network terminal (ONT). Since the optical signal corresponding to the wavelength of the connection port of the wavelength division multiplexing device is output, the wavelength division multiplexing device can be easily compared with the conventional method using an optical transceiver having a fixed wavelength for each connection port of the wavelength division multiplexing device. Regardless of the access port, a wavelength division multiple access optical communication system can be implemented using one optical transceiver.

As described above, in order to implement an optical communication system using a wavelength independent optical transceiver, a seed light source having a light output over a wide wavelength band should be used. In this case, there is a problem that human eyes or skin are exposed to the seed light source by cutting the optical line or detaching the optical connector. In the case of a wavelength division multiple optical communication system using a wavelength independent optical transceiver and a seed light source, the eyes or skin of the seed light source and the light sources of the multiple optical transceivers are multiplexed by cutting the optical line or separating the optical connector. There is a problem that is exposed.

In order to solve this problem, Korean Patent Registration No. 10-0720632 entitled "Automatic Line Blocking Device and Method in WDM-PON System" filed by the present inventors discloses an optical loss alarm detected by an optical receiving unit of an optical line terminator (OLT). A method of controlling the light output of an optical transmitter of a seed light source and an optical line terminator using a Loss of Signal (LOS) is proposed. According to this proposal, it is assumed that the light source of the optical transceiver of the subscriber unit (ONT, ONU) is always turned on, and the seed light source and the optical of the optical transceiver located at the optical line terminator when cutting the optical line or disconnecting the optical connector are assumed. The output was controlled. Therefore, when cutting the optical line or disconnecting the optical connector, the light output of the seed light source and the multiplexed optical transceiver in the downward direction is reduced to maintain a safe level of light output that does not become a problem even when exposed to human eyes or skin. However, the upward multiplexed optical signal transmitted from multiple optical subscriber end devices (ONT, ONU) to the optical line termination device (OLT) is exposed to human eyes or skin when cutting the optical wire or disconnecting the optical connector. There is a problem.

The present invention relates to the field of optical communication, and provides an apparatus and method for adaptively adjusting optical power, and an optical communication system therefor.

The optical power adjusting device of the present invention comprises: an optical reception monitoring unit for collecting optical monitoring information when an optical signal is input; And a light transmission control unit controlling a light source output using the light monitoring information.

In addition, the optical communication system of the present invention includes the optical power adjusting device according to any one of claims 1 to 3, wherein the optical subscriber end device, the optical transceiver including the optical subscriber end device, optical line termination The optical power adjusting device is included in either the device or the optical line termination device including the optical amplifier.

In addition, the optical power adjusting method of the present invention comprises the steps of: a) collecting optical surveillance information when an optical signal is input; And b) controlling the light source output using the light monitoring information.

According to the present invention, it is possible to prevent human eyes or skin from being exposed to a high power light source when cutting the optical line and detaching the optical connector in the optical communication system.

1 is an exemplary view showing a wavelength division multiplex passive optical subscriber network system using a seed light source according to an embodiment of the present invention.
2 is an exemplary view showing the structure of an optical transceiver of an optical subscriber termination device according to an embodiment of the present invention.
3 is an exemplary view showing a structure of an optical subscriber termination device according to an embodiment of the present invention.
4 is a functional block diagram of an optical line termination device according to an embodiment of the present invention.
5 is a functional block diagram of an optical line termination device including an optical amplifier according to an embodiment of the present invention.
6 is a flow chart showing the procedure of the automatic optical power adjustment method according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, well-known functions or constructions will not be described in detail if they obscure the subject matter of the present invention.

One embodiment of an optical communication system using a seed light source is a wavelength division multiplexing passive optical network (WDM-PON) system.

The wavelength division multiplexing passive optical subscriber network consists of an optical line terminal (OLT), an optical distribution network (ODN) and an optical subscriber station (ONT: Optical Network Terminal). It is composed.

The optical line termination device is located in a central base station (CO) and is composed of a plurality of optical transceivers, a wavelength division multiplexing device, a seed light source, and a seed light source combining device.

The optical distribution network consists of passive wavelength division multiplexing devices that do not require power supply, and are connected to optical line termination devices and optical subscriber termination devices through optical fibers, respectively. In the optical distribution network, a place where a passive wavelength division multiplexer connected to an optical line termination device and an optical subscriber end device is located is called a remote node (RN).

The optical subscriber end device is located in the subscriber's premises or in a local area and includes an optical transceiver.

A seed light source is a broadband light source (BLS) that has light output over a wide wavelength band, and is a light emitting diode (LED), an optical fiber amplifier or super light emitting diode (ASE) that outputs amplified spontaneous emission (ASE). Wide band light sources with a continuous spectrum of light over a wide wavelength band, such as diodes (SLDs) or multiple optical thin film filters (TFFs) or arrayed waveguides (AWG) A light source having a light spectrum having a line width equal to or smaller than a pass band of an optical filter, such as a grating, has a discontinuous light spectrum that matches a wavelength interval of the optical filter over a wide wavelength band.

The optical transceiver is a wavelength independent optical transceiver whose wavelength is determined according to the injected seed light source, and an F-P LD, an RSOA, an SOA, or an external cavity laser (ECL) is used as the light source of the optical transceiver.

1 is an exemplary view showing a wavelength division multiplexing passive optical network (WDM-PON) system using a seed light source according to an exemplary embodiment of the present invention. Optical line termination unit (OLT) 110 located at central base station (CO), multiple optical subscriber end units (ONT, ONU) 130 located in subscriber area, remote branch (RN) 120 of optical distribution network ), An optical fiber L20 connecting the optical line termination device 110 and the remote branch 120, and an optical fiber L30 connecting the plurality of optical subscriber termination devices 130 and the remote branch 120. .

The optical line termination device 110 located in the central base station CO includes a plurality of optical transceivers 111, 112, 113, a wavelength division multiplexer 114, a seed light source 115, 116, and a seed light source combiner 117. The plurality of optical subscriber end devices (ONT, ONU) 130 located in the area includes optical transceivers 131, 132, 133 for each optical subscriber end device, and the remote branch 120 of the optical distribution network is a wavelength division multiplexer 121. It consists of.

The seed light sources 115 and 116 included in the optical line terminator 110 are configured to transmit the optical transceivers 111, 112 and 113 of the optical line terminator 110 and the plurality of optical subscriber terminators 130 through the wavelength division multiplexers 114 and 121. It is injected into the transceivers 131, 132, and 133, respectively.

At this time, the optical fiber L20 between the optical line termination device 110 and the remote branch 120 is cut or the wavelength division multiplexer of the optical line termination device 110 and the remote branch 120 is cut. When the optical connector connected to the optical fiber (L20) between the 121 is separated from the optical line termination device 110 or the wavelength division multiplexer 121 of the remote point 120, the remote point from the optical line termination device 110 The multiplexed optical signal of the optical signals output from the optical transceivers 111, 112, and 113 injected upward through the wavelength division multiplexer 114 by the upward seed light source 116 downward in the direction of the wavelength division multiplexer 121 at 120. Downward seed light sources 115 to be injected into the optical transceivers 131, 132, 133 of the plurality of optical subscriber termination devices 130 are output. In addition, from the wavelength division multiplexer 121 of the remote branch 120 toward the optical line termination unit 110, multiplexing of optical signals output from the optical transceivers 131, 132, and 133 of the plurality of optical subscriber termination units 130 is performed. Optical signals are output.

2 is an exemplary view showing the structure of an optical transceiver of an optical subscriber end device according to an embodiment of the present invention.

Referring to FIG. 2, the optical transceiver 220 of the optical subscriber end device includes a transmitter optical sub-assembly (TOSA) 221, a receiver optical sub-assembly (ROSA) 222, and a laser diode driver (LD). 223, a limiting amplifier 224, a clock data recovery (CDR) 225, an optical transmission control unit 226, and an optical reception monitoring unit 227, which may not be included in some embodiments. have.

The optical reception monitoring unit 227 collects optical surveillance information (LOS; Loss of Lock, or optical reception power) when the optical signal is transmitted and input from the optical transceiver of the optical line termination device. When the optical transmission control unit 226 determines that a normal optical signal is received from the optical transceiver of the optical line termination device with the collected optical monitoring information, the optical transmission control unit 226 controls the LD driver 223 of the optical transceiver 220 of the optical subscriber terminal device. If the collected optical monitoring information is determined to be abnormal, and control the LD driver 223 of the optical transceiver 220 of the optical subscriber terminal device to prevent the light source from operating, and to the optical subscriber terminal device The LD driver 223 of the optical transceiver 220 prevents the light source from operating even when the power is supplied and initialized. In addition, the light transmission control unit 226 generates an alarm for the light monitoring information when the light monitoring information is abnormal.

3 is an exemplary view showing the structure of an optical subscriber termination device according to an embodiment of the present invention.

Referring to FIG. 3, the optical subscriber end device 300 includes a physical transceiver chip 323 that matches an optical transceiver 321, an optical transmission controller 322, an optical reception monitor 324, and an optical transceiver. It includes. The optical reception monitoring unit 324 collects optical monitoring information (Link status information from LOS, LOL, optical reception power or physical layer chip) when an optical signal is transmitted and input from the optical transceiver of the optical line termination device. When the optical transmission control unit 322 determines that the normal optical signal is received from the optical transceiver of the optical line termination device with the collected optical surveillance information, the optical transceiver 321 controls the optical transceiver 321 to output the optical signal. When it is determined to be abnormal, the light source output of the optical transceiver 321 is blocked, and the light source output of the optical transceiver 321 is blocked even when the power is supplied to the optical subscriber end device and initialized. In addition, the light transmission control unit 322 generates an alarm for the light monitoring information when the light monitoring information is abnormal.

4 is a functional block diagram of an optical line termination device according to an embodiment of the present invention.

Referring to FIG. 4, the optical line termination device 400 includes a plurality of optical transceivers 401, 402, and 403, an optical transmission control unit 404, an optical reception monitoring unit 406, a physical layer chip (PHY Chip) 405, and automatic optical transmission. An automatic optical power reduction (APR) control unit 407, an upward seed light source control unit 408, and a downward seed light source control unit 409 are included. The optical transmission control unit 404 outputs the optical signals of one or more optical transceivers 401, 402, 403 by the setting of the operator. The optical reception monitoring unit 406 collects optical surveillance information when an optical signal is transmitted from one or more optical transceivers of the optical subscriber end device. The automatic optical power control control unit 407 is configured to transmit and receive the optical transceivers 401, 402, 403 and the up and down light sources through the light transmission control unit 404 and the up and down seed light source controllers 408 and 409 when the optical line terminator is initialized by power supply. Blocking the output of the optical signal or using the optical monitoring information collected from the optical reception monitoring unit 406 and determining that a normal optical signal is received from one or more optical transceivers of the optical subscriber station, the up and down seed light source controllers 408 and 409. By controlling the up and down seed light source of the normal output (Pwr_B) through. If the light surveillance information collected from the light reception monitoring unit 406 is abnormal, the output of the up and down seed light sources continues to be output with the threshold value Pwr_A through the up and down seed light source controllers 408 and 409. do. When the up and down seed light source controllers 408 and 409 output the optical signals of one or more optical transceivers 401, 402 and 403 by the operator setting by the automatic optical power control controller 407, the output of the up and down seed light sources is terminated by the optical subscriber. It is injected into the optical transceiver of the device to control the optical transceiver of the optical subscriber end device to the optical output of the minimum threshold value Pwr_A for normal operation. In addition, the up and down seed light source control unit 408, 409 is the optical monitoring information collected by the light reception monitoring unit 406 by the automatic optical power control control unit 407 is a normal optical signal from one or more optical transceivers of the optical subscriber end device If it is determined that the reception is received, the automatic optical power control control unit 407 controls the up and down seed light source to be a normal output (Pwr_B). The automatic optical power control control unit 407 in the optical line termination device 400 generates an alarm for the optical monitoring information of the corresponding optical transceiver according to the optical monitoring information collected by the optical reception monitoring unit 406, and the up and down seeds. When the output of the light source is out of the normal range, an alarm is also generated for the up and down seed light sources.

5 is a functional block diagram of an optical line termination device including an optical amplifier according to an embodiment of the present invention.

Referring to FIG. 5, the optical line termination apparatus 500 includes a plurality of optical transceivers 501, 502, 503, an optical transmission control unit 504, an optical reception monitoring unit 506, a physical layer chip (PHY Chip) 505, and automatic optical light. An automatic optical power reduction (APR) control unit 507, an upstream seed light source control unit 508, a downside seed light source control unit 509, an uplink optical amplifier control unit 510, and a downlink optical amplifier control unit 511 are included. The optical transmission control unit 504 outputs the optical signals of one or more optical transceivers 501, 502, 503 by the setting of the operator. The optical reception monitoring unit 506 collects optical monitoring information (Link state information from LOS, LOL, optical reception power, or physical layer chip) when an optical signal is transmitted from one or more optical transceivers of the optical subscriber end device. . The automatic optical power control control unit 507 is configured through the optical transmission control unit 504, the up and down seed light source controllers 508 and 509, and the up and down optical amplifier controllers 510 and 511 when the optical line terminator is initialized by power supply. Blocking the output of the optical transceivers 501, 502, 503 and the up and down light sources, or having the optical monitoring information collected from the optical reception monitor 506 and determining that a normal optical signal has been received from one or more optical transceivers of the optical subscriber end device. The up and down seed light source controllers 508 and 509 or the up and down seed light source controllers 510 and 511 are controlled to output the up and down light sources of the normal output Pwr_B or the up and down seed light source controllers 508 and 509 and the up and down light beams. The amplifier controllers 510 and 511 control the up and down light sources of the normal output Pwr_B to be output. If the light monitoring information collected from the light reception monitoring unit 506 is abnormal, the output of the up and down seed light sources continues through the up and down seed light source controllers 508 and 509 or the up and down optical amplifier controllers 510 and 511. The output of the up and down light sources continues to be output with the threshold value Pwr_A through the control of outputting with the threshold value Pwr_A or simultaneously through the up and down seed light source controllers 508 and 509 and the up and down optical amplifier controllers 510 and 511. To control. The up and down seed light source controllers 508 and 509 output the up and down seed light sources for the optical subscriber when an optical signal of one or more optical transceivers 501, 502, 503 is output by the automatic optical power control controller 507 by an operator setting. The optical transceiver is injected into the optical transceiver to control the optical output of the minimum threshold value Pwr_A to which the optical subscriber optical transceiver can operate normally. Also, the up and down seed light source controllers 508 and 509 may include one or more optical transceivers of the optical subscriber terminal device, in which optical monitoring information collected by the optical reception monitoring unit 506 is transmitted by the automatic optical power control control unit 507. If it is determined that the received from the automatic optical power control control unit 507 controls the up and down seed light source to the normal output (Pwr_B). The up and down optical amplifier controllers 510 and 511 output the up and down seed light sources when the optical signals of one or more optical transceivers 501, 502 and 503 are output by the automatic optical power control controller 507 by an operator setting. It is injected into the optical subscriber optical transceiver to control the light output of the minimum threshold value (Pwr_A) that can operate normally. In addition, the up and down optical amplifier control unit (510, 511) is the optical monitoring information collected by the optical reception monitoring unit 506 by the automatic optical power control control unit 507 the normal optical signal is one or more optical transceivers of the optical subscriber terminal device If the determination is received from the automatic optical power control control unit 507 controls the up and down seed light source to be a normal output (Pwr_B). In the optical line termination device 500, the automatic optical power control control unit 507 generates an alarm for the optical monitoring information of the corresponding optical transceiver according to the optical monitoring information collected by the optical reception monitoring unit 506, and the up and down seeds. When the output of the light source is out of the normal range, an alarm is also generated for the up and down seed light sources.

In FIG. 5, the up and down seed light source controllers 508 and 509 and the up and down optical amplifier controllers 510 and 511 are simultaneously controlled or simultaneously controlled for the normal output Pwr_B and the minimum threshold value Pwr_A of the up and down seed light sources. Only the down seed light source controllers 508 and 509 may be controlled, or only the up and down optical amplifier controllers 510 and 511 may be controlled.

6 is a flow chart showing the procedure of the automatic optical power adjustment method according to an embodiment of the present invention.

Referring to FIG. 6, the optical line termination unit (OLT) prohibits the output of the optical transceiver light source and the up and down seed light sources simultaneously with the power supply, and the optical subscriber end devices (ONT, ONU) also output the optical transceiver light source at the same time as the power supply. Prohibit (S601). The optical line termination device (OLT) checks whether there is a subscriber service port set by the operator (S602), and outputs the up and down seed light sources to the threshold value Pwr_A at the optical line termination device (OLT), The light source of the optical transceiver set by the controller is output. The optical subscriber end device (ONT, ONU) prohibits the output of the light source of the optical transceiver (S605), and the optical monitoring information (LOS, LOL, optical reception power or link state) collected by the optical subscriber end device (ONT, ONU) is suppressed. It is determined whether it is normal or abnormal (S606). If the optical monitoring information collected by the optical subscriber end devices ONT and ONU is normal, the light source of the optical transceiver in the optical subscriber end device is output (S608). If the optical monitoring information collected by the optical subscriber end devices (ONT, ONU) is abnormal (S603), one or more optical transceivers among the optical monitoring information collected by the optical reception monitoring unit of the optical line termination device (OLT) It is determined whether the light monitoring information is normal (S607). Up and down seed light sources when normal optical monitoring information (LOS, LOL, optical receiving power or link status) is collected from one or more optical transceivers among optical monitoring information collected by the optical reception terminator of the optical line termination device (OLT) Outputs to the normal output (Pwr_B) (S609), and generates an alarm for the optical monitoring information of the abnormal optical transceiver from the optical monitoring information collected by the optical reception monitoring unit of the optical line termination device (OLT) (S604). The automatic optical power control control unit in the optical line termination device (OLT) checks whether the output of the up and down seed light source is stable in the normal range (S610). In the optical line termination device (OLT), the automatic optical power control control unit generates an alarm for the up and down seed light sources when the output of the up and down seed light sources is outside the normal range (S611).

In the step S605 of setting the up and down seed light sources to the threshold Pwr_A in the optical line termination device OLT, the outputs of the up and down seed light sources are injected into the optical subscriber optical transceiver so that the optical subscriber optical transceiver is normal. It is to make the light output of the minimum threshold value Pwr_A which can be operated.

In the step S609 of setting the up and down seed light sources to the normal output Pwr_B in the optical line termination device OLT, the output of the up and down seed light sources may be set from the threshold value Pwr_A to the normal output Pwr_B. Steps may be set to allow the normal output Pwr_B to be output gradually, or may be set to output the normal output Pwr_B at the threshold value Pwr_A.

The step S605 of setting the up and down seed light sources to the threshold Pwr_A and the step of setting the up and down seed light sources to the normal output Pwr_B in the optical line termination device OLT are up and down. Even when the optical amplifier is included, the output of the up and down seed light sources is controlled through the control of the up and down seed light sources or the up and down optical amplifiers, or the up and down seed light sources and the up and down optical amplifiers are simultaneously controlled. Adjusting the output of the seed light source.

While the above methods have been described through specific embodiments, the methods may also be implemented as computer readable code on a computer readable recording medium. A computer-readable recording medium includes all kinds of recording apparatuses in which data that can be read by a computer system is stored. Examples of the computer-readable recording medium include a ROM, a RAM, a CD-ROM, a magnetic tape, a floppy disk, an optical data storage device, and the like, and may be implemented in the form of a carrier wave (for example, transmission over the Internet) . In addition, the computer-readable recording medium may be distributed over network-connected computer systems so that computer readable codes can be stored and executed in a distributed manner. In addition, functional programs, codes, and code segments for implementing the above embodiments can be easily deduced by programmers of the present invention.

Although the present invention has been described in connection with some embodiments thereof, it should be understood that various changes and modifications may be made therein without departing from the spirit and scope of the invention as understood by those skilled in the art. something to do. It is also contemplated that such variations and modifications are within the scope of the claims appended hereto.

110: optical line terminator 111, 112, 113: optical transceiver
114, 121: wavelength division multiplexer 115, 116: seed light source
117: seed light source coupling device 120: remote point
130: optical subscriber end device 131, 132, 133: optical transceiver
L20, L30: Optical Fiber

Claims (17)

An optical power adjusting device of an optical subscriber termination device,
An optical reception monitoring unit collecting optical monitoring information when an optical signal is input; And
Including a light transmission control unit for controlling the light source output using the light monitoring information,
It is provided in the optical transceiver of the optical subscriber end device,
And the optical transmission controller controls the optical transceiver to have a light output of a minimum threshold value at which the optical transceiver can operate normally. The method of claim 1,
The optical transmission control unit,
When the power supply is initialized, the optical power control device to block the light source output when the optical line cut or the optical connector is disconnected. The method of claim 1,
The optical monitoring information,
An optical power control device comprising Loss of Signal (LOS), Loss of Lock (LOL), Optical Receive Power, or Link status information. As an optical communication system,
Claims 1 to 3 including the optical power adjusting device of any one of:
And the optical power adjusting device in the optical transceiver of the optical subscriber termination device. 5. The method of claim 4,
A seed light source for forming broadband light;
A filtering unit for filtering broadband light formed by the seed light source;
At least one optical transceiver to which the output optical signal of the filtering unit is input; And
And an optical fiber termination device including the optical power adjusting device. The method of claim 5,
The seed light source,
Passage of broadband light sources or optical filters with a continuous light spectrum over a broad wavelength band, such as light emitting diodes, optical amplifiers that output amplified spontaneous emission, or super luminescent diodes And a broadband light source having a discontinuous light spectrum in which the light spectrum of a line width equal to or less than a passband matches the wavelength spacing of the optical filter over a wide wavelength band. The method of claim 5,
Wherein the filtering unit comprises:
An optical communication system comprising an optical thin film filter (TFF) or an arrayed waveguide grating. The method of claim 5,
The at least one optical transceiver,
An optical communication system comprising a Fabric-Perot Laser Diode (FP LD), a Reflective Semiconductor Optical Amplifier (RSOA), a Semiconductor Optical Amplifier (SOA), or an External Cavity Laser (ECL). The method of claim 5,
The optical fiber terminal device,
And shut off outputs of the at least one optical transceiver and the seed light source when initialized by a power supply. The method of claim 5,
If it is determined that a normal optical signal is received by at least one optical transceiver by using the optical monitoring information, the seed light source is controlled to have a normal output, and when it is determined that abnormal optical signals are received by all optical transceivers, the seed light source is minimum. And control to have an output. The method of claim 10,
Alerting the at least one optical transceiver when an optical signal outside the normal range is received by the at least one optical transceiver using the optical monitoring information, and alerting the seed light source when the output of the seed light source is out of the normal range. Generating an optical communication system. The method of claim 10,
And controlling an output of the seed light source by setting a predetermined step between the normal output and the minimum output. The method of claim 5,
And the optical fiber termination device comprises an optical amplifier. delete As an optical power adjusting method,
a) in the optical power adjusting device provided in the optical transceiver of the optical subscriber end device, collecting optical monitoring information when an optical signal is input; And
b) In the optical power adjusting device provided in the optical transceiver of the optical subscriber end device, the optical signal is input in the upward direction so that the optical signal is output at the minimum threshold value that the optical transceiver can operate normally by using the optical monitoring information. And controlling the light source output of the optical power. 16. The method of claim 15,
The step b)
And interrupting the light source output when a power supply, optical line cut, or optical connector is disconnected. 16. The method of claim 15,
The optical monitoring information,
A method of adjusting optical power, including Loss of Signal (LOS), Loss of Lock (LOL), Optical Receive Power, or Link status information.

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