KR20220071925A - Optical communication device and method for setting wavelength thereof - Google Patents

Abstract

Disclosed is an optical communication device to automatically set a wavelength for an optical signal without a manager's visit. According to one aspect of the present invention, the optical communication device comprises: a first multiplexer including a first transmit port and a second transmit port; a transmission wavelength analyzer analyzing first transmission light to recognize a first transmission wavelength corresponding to the first transmission light and analyzing second transmission light to recognize a second transmission wavelength corresponding to the second transmission light; and a controller generating a first control signal for allowing the first transmission port to pass light corresponding to the first transmission wavelength and allowing the second transmission port to pass light corresponding to the second transmission wavelength and outputting the first control signal to the first multiplexer. According to the first control signal, the first multiplexer performs control to allow the first transmission port to correspond to the first transmission wavelength and performs control to allow the second transmission port to correspond to the second transmission wavelength.

Description

Optical communication device and its wavelength setting method

The present disclosure relates to an optical communication device and a wavelength setting method thereof, and more particularly, to an optical communication device capable of automatically setting a wavelength for communication channel connection between optical communication devices and a wavelength setting method thereof. .

Passive Optical Network (hereinafter referred to as 'PON') has become the core of FTTH environment implementation and Giga-bit Ethernet implementation. PON is an optical line terminal (OLT) on the side of the central office, a remote node (RN) for sharing one feeder optical cable among multiple subscribers, and an optical network termination on the subscriber side device (Optical Network Terminal, ONT) or optical network unit (Optical Network Unit, ONU). The optical cable may be respectively connected to the optical transceiver of the OLT and the optical transceiver of the ONT or ONU to connect the OLT and the ONT/ONU. Here, the optical transceiver is for transmitting and receiving an optical signal through a connected optical cable, and may be an optical transmission/reception module such as a gigabit interface converter (GBIC) or a small form-factor pluggable (SFP).

The separation distance between OLT and ONT/ONU is usually several [km] to several tens [km]. Therefore, it is very cumbersome and time consuming for an administrator to visit the site and set the wavelengths of optical signals that can be communicated between OLT and ONT/ONU.

Korean Patent Publication No. 10-2016-0043655

In order to solve the above problems, the present disclosure is to provide a method for automatically setting the wavelength of an optical signal between optical communication devices without an administrator's visit, and an optical communication device in which the method is implemented.

According to an aspect of the present disclosure, a first multiplexer including a first transmission port and a second transmission port analyzes the first transmission light to recognize a first transmission wavelength corresponding to the first transmission light, and a second transmission A transmission wavelength analyzer that analyzes light and recognizes a second transmission wavelength corresponding to the second transmission light, and the first transmission port passes the light corresponding to the first transmission wavelength, and the second transmission port and a controller for generating a first control signal for passing light corresponding to a second transmission wavelength and outputting the first control signal to the first multiplexer, wherein the first multiplexer receives the first control signal Accordingly, there is disclosed an optical communication device that controls the first transmission port to correspond to the first transmission wavelength and controls the second transmission port to correspond to the second transmission wavelength.

According to an exemplary embodiment, the transmission wavelength analyzer, a first partial transmission light to which a portion of the first transmission light is coupled and input, and a second partial transmission light to which a part of the second transmission light is coupled and input The first transmission wavelength and the second transmission wavelength may be recognized by receiving and analyzing the received first partial transmission light and the received second partial transmission light.

According to an exemplary embodiment, the first transmission light includes first transmission wavelength information, the second transmission light includes second transmission wavelength information, and the transmission wavelength analyzer includes the inputted first partial transmission light. The first transmission wavelength is recognized by analyzing at least a part of the first transmission wavelength information included in the The transmission wavelength can be recognized.

According to an exemplary embodiment, the first transmission wavelength information and the second transmission wavelength information may correspond to an Auxiliary Management and Control Channel (AMCC).

According to an exemplary embodiment, the first multiplexer may include Wavelength Selective Switches (WSS), and may control the WSS to correspond to the first control signal.

According to an exemplary embodiment, the optical communication device further includes a reply wavelength analyzer for recognizing a first reply wavelength corresponding to the first reply light and recognizing a second reply wavelength corresponding to the second reply light; , the controller generates a second control signal for allowing the first receiving port to pass the light corresponding to the first return wavelength and allowing the second receiving port to pass the light corresponding to the second return wavelength, and the second A control signal is output to the first multiplexer, and the first multiplexer includes the first reception port and the second reception port, and the first reception port is adjusted to the first transmission wavelength according to the second control signal. It is possible to control correspondingly, and to control the second receiving port to correspond to the second reply wavelength.

According to an exemplary embodiment, the reply wavelength analyzer recognizes the first reply wavelength by analyzing the first partial reply light input by coupling a part of the first reply light, and a part of the second reply light is coupled The second reply wavelength may be recognized by analyzing the ringed second partial reply light.

According to an exemplary embodiment, the first reply light includes first reply wavelength information, the second reply light includes second reply wavelength information, and the first reply wavelength information is at the first reply wavelength. and information on the first transmission wavelength, the second return wavelength information includes information on the second return wavelength and information on the second transmission wavelength, and the return wavelength analyzer The first reply wavelength is recognized by analyzing the first reply wavelength information through the first partial reply light, and the second reply wavelength is recognized by analyzing the second reply wavelength information through the second partial reply light. can

According to an exemplary embodiment, each of the first reply wavelength information and the second reply wavelength information may correspond to an auxiliary management and control channel (AMCC).

According to an exemplary embodiment, the optical wavelength setting device further includes a second multiplexer that separates a portion of the input reply light into a first partial reply light and a second partial reply light and outputs it to the reply wavelength analyzer; The reply light is an optical signal received from the outside in response to transmission of the transmit light, a part of the reply light is input to the first multiplexer, the other part of the reply light is input to the second multiplexer, and the transmit light is The optical signal of the first transmission port and the second transmission port may be combined to be an optical signal transmitted to the outside from the first multiplexer.

According to an aspect of the present disclosure, a first transmission wavelength corresponding to the first transmission light is recognized by analyzing a first transmission light, and a second transmission wavelength corresponding to the second transmission light is analyzed by analyzing a second transmission light recognizing; generating, by a first transmission port, light corresponding to the first transmission wavelength, and a second transmission port, generating a first control signal for passing light corresponding to the second transmission wavelength; outputting the generated first control signal to a first multiplexer including the first transmission port and the second transmission port; and controlling the first transmission port to correspond to the first transmission wavelength and controlling the second transmission port to correspond to the second transmission wavelength according to the first control signal. A setting method is disclosed.

According to an aspect of the present disclosure, by analyzing the first transmission light and the second transmission light output from the first optical communication device, the first transmission wavelength corresponding to the first transmission light and the second transmission light corresponding to the first transmission light a transmission wavelength analyzer for recognizing a second transmission wavelength; and a first control signal for allowing the first transmission port of the first multiplexer to pass the light corresponding to the first transmission wavelength, and the second transmission port of the first multiplexer to pass the light corresponding to the second transmission wavelength Disclosed is an apparatus for setting an optical wavelength including a controller for generating and outputting a generated first control signal to the first multiplexer.

The optical communication device according to embodiments of the present disclosure may automatically set a wavelength for a communicable optical signal without a visit of an administrator.

In order to more fully understand the drawings recited in the Detailed Description of the present disclosure, a brief description of each drawing is provided.
1 is a configuration diagram of an optical communication system according to an embodiment of the present disclosure.
2 is a block diagram of an optical communication device according to an embodiment of the present disclosure.
3 is a configuration diagram of an optical module and an optical wavelength setting apparatus according to an embodiment of the present disclosure.
4 is a flowchart of an operation of automatically setting an optical wavelength according to an embodiment of the present disclosure.

Since the technical spirit of the present disclosure may have various changes and may have various embodiments, specific embodiments will be illustrated in the drawings and described in detail. However, this is not intended to limit the technical spirit of the present disclosure to specific embodiments, and it should be understood to include all changes, equivalents or substitutes included in the scope of the technical spirit of the present disclosure.

In describing the technical idea of the present disclosure, if it is determined that the detailed description of the related known technology may unnecessarily obscure the spirit of the present disclosure, the detailed description thereof will be omitted. In addition, numbers (eg, first, second, etc.) used in the description of the present application are merely identification symbols for distinguishing one component from other components.

Also, in this application, when it is referred to as “connected” or “connected” to another component, the component may be directly connected to or directly connected to the other component, but in particular the opposite is true. Unless there is a description to be used, it will be understood that it may be connected or connected through another element in the middle.

In addition, terms such as "~ unit", "~ group", "~ character", etc. described herein mean a unit for processing at least one function or operation, which is a processor, a microprocessor, Microcontroller, CPU (Central Processing Unit), GPU (Graphics Processing Unit), APU (Accelerate Processor Unit), DSP (Digital Signal Processor), ASIC (Application Specific Integrated Circuit), FPGA (Field Programmable Gate Array) It may be implemented in hardware such as, software, or a combination of hardware and software.

In addition, it is intended to clarify that the classification of the constituent parts in the present application is merely a classification for each main function that each constituent unit is responsible for. That is, two or more components to be described below may be combined into one component, or one component may be divided into two or more for each more subdivided function. In addition, each of the constituent units to be described below may additionally perform some or all of the functions of other constituent units in addition to the main function it is responsible for. Of course, it can also be performed by being dedicated to it.

The optical communication system according to the embodiments of the present disclosure is located in a remote location from each other and is configured with optical communication devices that transmit and receive optical signals through corresponding optical communication modules (optical transceivers) to various optical communication networks based on WDM-PON. can be applied

For example, the optical communication system may configure an optical transport network that is a sub-network constituting a fronthaul segment of a radio access network architecture. However, the present disclosure is not limited thereto, and the technical spirit of the present disclosure may be applied to a midhaul segment and a backhaul segment of the radio access network architecture. As another example, the optical communication system may be applied to an optical subscriber network. As another example, the optical communication system may be applied to a distributed antenna system (DAS) for resolving a shadow area of a base station.

Hereinafter, for convenience of description, a case in which the optical communication system constitutes the fronthaul segment of the above-described radio access network architecture, a digital unit or a baseband unit at the central office side ) and an optical communication device (eg, COT) connected to a remote unit (Remote Unit) or a remote radio head (Remote Radio Head) connected to a system including an optical communication device (eg, RT) Examples will be mainly described.

Hereinafter, various embodiments according to the spirit of the present disclosure will be described in detail in turn.

1 is a configuration diagram of an optical communication system according to an embodiment of the present disclosure.

Referring to FIG. 1 , an optical communication system 100 according to an embodiment of the present disclosure may include a first optical communication device 120 and a second optical communication device 130 . In FIG. 1 , only one second optical communication device 130 is illustrated for convenience of description, but the technical spirit of the present disclosure is not limited thereto.

The first optical communication device 120 may be located on the first site side, and may include at least one optical transceiver 1200 . The second optical communication device 130 may be located at a second site spaced a predetermined distance from the first site, and may include at least one optical transceiver 1300 . The first optical communication device 120 and the second optical communication device 130 may be communicatively connected through respective optical transceivers 1200 and 1300 and optical cables connecting them.

In some embodiments, the optical communication system 100 may be applied to an optical subscriber network. In this case, the first optical communication device 120 may be an optical line terminal (OLT) on the side of the central office. In addition, the second optical communication device 130 may be any one of a remote device (Remote Terminal, RT), a subscriber-side optical network terminal (Optical Network Terminal, ONT), and an optical network unit (Optical Network Unit).

In another embodiment, the optical communication system 100 may be applied to a fronthaul transmission network of a distributed base station. In this case, the first optical communication device 120 may be a digital unit (Digital Unit, DU) or a baseband unit (BaseBand Unit, BBU) full-side termination device on the side of the central office. In addition, the second optical communication device 130 may be a remote unit (RU) or a remote radio head (RRH).

In another embodiment, the optical communication system 100 may be applied to a distributed antenna system (DAS) for resolving a shadow area of a base station. In this case, the first optical communication device 120 may be a headend unit, and the second optical communication device 130 may be an extension unit or a remote unit.

As described above, the optical communication system 100 according to the technical spirit of the present disclosure can be applied to various optical communication networks implemented with optical communication devices that are located at remote locations from each other and transmit and receive optical signals through corresponding optical transceivers.

Hereinafter, the 'optical wavelength automatic setting operation' between the first optical communication device 120 and the second optical communication device 130 in the optical communication system 100 according to an embodiment of the present disclosure will be described in detail with reference to FIGS. 2 to 4 . explained as

2 is a block diagram of an optical communication device according to an embodiment of the present disclosure. It should be noted that FIG. 2 shows the main part of the optical transceiver included in the optical communication device in more detail on the assumption that the optical communication system 100 of FIG. 1 is applied to WDM-PON. Also, a solid arrow shown in FIG. 2 may indicate a movement path of payload data, and a dotted arrow may indicate a movement path of auxiliary management data (eg, AMCC data).

Referring to FIG. 2 , among a plurality of optical communication devices constituting the optical communication system 100 according to an embodiment of the present disclosure, a first optical communication device 120 is a first main controller (MCU) 210 , a first It may include a memory 215 and n first optical transceivers 1200 - 1 to 1200 - n (where n is a natural number equal to or greater than 2).

The n first optical transceivers 1200 - 1 to 1200 - n may include a first sub control unit 220 , a first transmitter 230 , and a first receiver 250 , respectively. The n first optical transceivers 1200 to 1200-n are connected to a first multiplexer (MUX) 240 to transmit an optical signal to or from the first mux 240 . An optical signal of a corresponding wavelength band may be received.

In addition, among the plurality of optical communication devices constituting the optical communication system 100 according to an embodiment of the present disclosure, each of the n second optical communication devices 130-1 to 130-n is a second optical transceiver 1300 . , a second main controller (MCU) 290 , and a second memory 295 .

Each of the n second optical transceivers 1300 may include a second sub control unit 280 , a second receiver 270 , and a second transmitter 275 . The n second optical transceivers 1300 may be connected to a second MUX 260 to transmit an optical signal to the second MUX 260 or receive an optical signal from the second MUX 260 . .

According to an embodiment, the first mux 240 on the side of the first optical communication device 120 may be a separate device distinct from the first optical communication device 120 or may have a configuration provided inside the first optical communication device 120 . . Further, the second mux 260 may also be a device separate from the n second optical communication devices 130-1 to 130-n, but it is composed of a plurality of n second optical communication devices 130-1 to 130-n. -n) may be provided inside each. In this case, the n second optical communication devices 130 - 1 to 130 - n may each include a plurality of optical transceivers.

According to an embodiment, the first optical communication device 120 , the first mux 240 , and the second mux 260 may be connected in a ring topology. Also, according to an embodiment, a plurality of sub-muxes may be connected to the second mux 260 , and the second optical communication devices 130-1 to 130-n are connected to the sub-muxes to form a tree topology. You may.

First, the first MCU 210 may be configured to generally control the operation of the first optical communication device 120 . The first MCU 210 may be connected to an external device such as a server or a network monitoring system (NMS) to transmit/receive information and data necessary for the operation of the first optical communication device 120 .

The first memory 215 is a space in which program commands and various types of information necessary for the operation of the first optical communication device 12 are stored, and may include a data storage medium such as a magnetic disk or a solid state drive (SSD).

The first auxiliary controller 220 is configured to be wired or wirelessly connected to the first MCU 210 , and may manage and control the first optical transceiver 1200 - 1 . The first auxiliary controller 220 may process payload data transmission/reception and control management (wavelength setting/control, communication status monitoring, etc.) between the first optical transceiver 1200-1 and the second optical transceiver 1300-1. have. Here, the first auxiliary controller 220 is an active component of the first optical transceiver 1200 - 1 , and a low-speed first auxiliary management through an auxiliary management and control channel together with high-speed payload data. It may be a generic term for a processor that performs various control and processing for data transmission, a memory in which firmware is stored, and the like.

The first auxiliary controller 220 may transmit the first auxiliary management data to the second optical transceiver 1300-1 according to various methods.

For example, the first auxiliary controller 220 may simultaneously transmit the first auxiliary management data and the payload data to the second optical transceiver 1300-1 through a baseband intensity over-modulation method. . As another example, the first auxiliary controller 220 may transmit the first auxiliary management data and the payload data to the second optical transceiver 1300-1 by overlapping the first auxiliary management data through an RF pilot tone method. .

The baseband intensity modulation scheme is a technique of stacking the first auxiliary management data on top of the payload data, and the RF pilot tone scheme is a technology of overlapping the ASK or FSK-modulated first auxiliary management data with the payload data. A transmission rate of the first auxiliary management data may be different from a transmission rate of the payload data. For example, the frequency of the first auxiliary management data may be a number [kHz], and the frequency of the payload data may be several tens to hundreds [MHz]. Since the first auxiliary management data transmission/reception method, such as the baseband intensity modulation method and the RF pilot tone method, has already been disclosed, a detailed description thereof will be omitted.

In particular, the first auxiliary controller 220 may generate the first transmission wavelength information when the first test light signal is transmitted. Here, the first test optical signal is a preset 'test information' generated as an optical signal of a first transmission wavelength, and the first transmission wavelength information is auxiliary management data generated by the first auxiliary controller 220, Information on the length of the transmission wavelength may be included. That is, the first auxiliary controller 220 may generate information on the wavelength of the first test light signal as the first auxiliary management data (hereinafter, first auxiliary management data corresponding to the wavelength of the first test light signal). is called 'first transmission wavelength information'). The first transmission wavelength information may be information generated to correspond to the AMCC by the first auxiliary controller 220 . Also, the first auxiliary controller 220 may output the generated first transmission wavelength information to the first transmitter 230 .

The first transmitter 230 is configured to convert the input payload data and/or the first auxiliary management data into an optical signal. The first transmitter 230 may include a Transmitter Optical Sub-Assemblies (TOSA) made of a laser diode, a laser diode driving circuitry (LDD), a biasing circuitry, and the like. Payload data input to the first transmitter 230 may be input through the LDD. In particular, the first transmitter 230 may generate the first transmission light. The first transmit light may include a first test light signal and a first transmit wavelength light signal. The first test optical signal may be obtained by converting test information into an optical signal by the first transmitter 230 . The first transmission wavelength optical signal may be converted by the first transmitter 230 by converting the first transmission wavelength information into an optical signal. The first test optical signal and the optical signal with the first transmission wavelength may be combined into the first transmission light, but may be transmitted to the outside through mutually different channels and wavelengths. This is because the first transmission wavelength optical signal is an optical signal corresponding to AMCC.

The first transmitter 230 may output the first transmission light to the first mux 240 .

The first mux 240 multiplexes (MUXING or Multiplexing) the optical signal input from the first transmitter 230, transmits it through an optical cable, and demultiplexes signals received from the optical cable (DeMUXING or Demultiplexing). Also, the first mux 240 may include wavelength selective switches, that is, Wavelength Selective Switches (WSS). Accordingly, when the control signal is received, the first mux 240 may control the wavelength of each switch of the WSS to correspond to the control signal (this will be described later with reference to FIG. 3 ).

The first receiver 250 separates the input optical signal demultiplexed by the first 'mux 240 into payload data and second auxiliary management data (the definition of the second auxiliary management data will be described later) and corresponds to each. It can be output in the following configuration. In particular, the first receiver 250 may output the second auxiliary management data to the first auxiliary controller 220 . The first receiver 250 may include a photo diode, a Receiver Optical Sub-Assemblies (ROSA) including a Trans-Impedance Amplifier (TIA), a Post Amplifier, and the like.

In the above, the configuration of the first optical transceiver 1200 - 1 among the n first optical transceivers 1200 - 1 to 1200 - n has been described. Since the configuration of the remaining first optical transceivers 1200-2 to 1200-n is substantially the same as that of the first optical transceiver 1200-1, a description thereof will be omitted.

The second sub control unit 280 of the second optical transceiver 1300-1 may be configured to generally control the operation of the second optical transceiver 1300-1.

The second auxiliary controller 280 includes information for transmission/reception of payload data between the first optical transceiver 1200-1 and the second optical transceiver 1300-1 and control management (wavelength setting, communication status monitoring, etc.) , referred to as second auxiliary management data) can be managed. The second auxiliary controller 280 may transmit the payload data and the second auxiliary management data to the first optical transceiver 1200 - 1 according to various methods. Like the first auxiliary controller 220 , the second auxiliary controller 280 may transmit the second auxiliary management data to the first optical transceiver 1200 - 1 through various methods without affecting the payload data. The second auxiliary controller 280 is an active component of the second optical transceiver 1300-1, and collectively refers to a processor that processes and controls information that can be transmitted and received through the auxiliary control management channel, a memory in which firmware, etc. are stored. It can be a term.

The second receiver 270 may have a configuration corresponding to the first receiver 250 , and the second transmitter 275 may have a configuration corresponding to the first transmitter 230 .

The payload data and the second auxiliary management data transmitted to the first optical transceiver 1200 - 1 through the second transmitter 275 and the second mux 260 may be converted and multiplexed into an optical signal. An optical signal received from the first optical transceiver 1200 - 1 through the second mux 260 and the second receiver 270 may be demultiplexed and converted into an electrical signal.

Each of the second MCU 290 and the second memory 295 has a configuration similar to that of the first MCU 210 and the first memory 215 , and a redundant description thereof will be omitted.

In the above, the overall function of each component of the first and second optical transceivers 1200 - 1 and 130 - 1 has been described. Hereinafter, an automatic wavelength setting operation for setting a communication channel between the n first optical transceivers 1200-1 to 1200-n and the n second optical transceivers 1300 with reference to FIGS. 3 and 4 will be described in detail. explained as

3 is a configuration diagram of an optical module and an optical wavelength setting apparatus according to an embodiment of the present disclosure. A solid arrow shown in FIG. 3 may indicate a movement path of payload data, and a dotted arrow may indicate a movement path of auxiliary management data (eg, AMCC data).

Referring to FIG. 3 , each of the n first optical transceivers, that is, a 1-1 optical transceiver 310 - 1 to 1-n th optical transceiver 310 - n may be connected to a first mux 240 .

The 1-1 transmitter 230-1 of the 1-1 optical transceiver 310-1 may be connected to the first transmission port P11 of the first mux 240, and the 1-1 receiver 250- 1) may be connected to the first reception port P12 of the first mux 240 . The 1-2 th transmitter 230 - 2 of the 1-2 th optical transceiver 310 - 2 may be connected to the second transmission port P21 of the first mux 240 , and the 1-2 th receiver 250 - 2) may be connected to the second reception port P22 of the first mux 240 . Similarly, the 1-n-th transmitter 230-n of the 1-n-th optical transceiver 310-n may be connected to the n-th transmission port Pn1 of the first mux 240 , and the 1-n-th receiver 250 . -n) may be connected to the n-th reception port Pn2 of the first mux 240 .

The first transmission port P11 of the 1-1 transmitter 230-1 and the first mux 240 may be connected by a wire (eg, an optical cable), and the first transmission coupler 330-1 is connected to the optical cable. ) can be formed. The first transmit coupler 330 - 1 may couple the first transmit light output from the first transmitter 230 - 1 and output it to a downstream wavelength analyzer ( 340 ). That is, the first partial transmission light is an optical signal separated from the first transmission light by the first transmission coupler 330 - 1 , and may be input to the transmission wavelength analyzer 340 .

The second transmitter 230 - 2 and the second transmission port P21 of the first mux 240 may be connected by wire (eg, an optical cable), and the second transmission coupler 330 - 2 is connected to the optical cable. ) can be formed. The second transmit coupler 330 - 2 may couple the second transmit light output from the second transmitter 230 - 2 and output it to the transmit wavelength analyzer 340 . That is, the second partial transmission light is an optical signal separated from the second transmission light by the second transmission coupler 330 - 2 and may be input to the transmission wavelength analyzer 340 .

Similarly, the 1-n-th transmitter 230-n and the n-th transmission port Pn1 of the first mux 240 may be connected by wire (eg, an optical cable), and the n-th transmission coupler 330 is connected to the optical cable. -n) may be formed. The n-th transmission coupler 330-n may couple the n-th transmission light output from the n-th transmitter 230-n and output the n-th partial transmission light to the transmission wavelength analyzer 340 . That is, the n-th partial transmission light is an optical signal separated from the n-th transmission light by the n-th transmission coupler 330 - n , and may be input to the transmission wavelength analyzer 340 .

The transmission wavelength analyzer 340 may receive the first partial transmission light to the nth partial transmission light. Since the first partial transmission light is a part of the first transmission light, it may include a part of the first test optical signal and a part of the first transmission wavelength optical signal. Therefore, the transmission wavelength analyzer 340 separates the first partial transmission light into a part of the first test optical signal and a part of the first transmission wavelength optical signal, and then analyzes the first transmission wavelength optical signal to recognize the first transmission wavelength. can In addition, the transmission wavelength analyzer 340 separates the second partial transmission light into a part of the second test optical signal and a part of the second transmission wavelength optical signal, and then analyzes the second transmission wavelength optical signal to recognize the second transmission wavelength can do. In the same way, the transmission wavelength analyzer 340 separates the nth partial transmission light into a part of the nth test optical signal and a part of the nth transmission wavelength optical signal, and then analyzes the nth transmission wavelength optical signal to obtain the nth transmission wavelength can be recognized

As described above, the first to nth transmission wavelength optical signals may correspond to AMCC. Accordingly, the transmit wavelength analyzer 340 may be configured to analyze the AMCC signal. Also, the transmit wavelength analyzer 340 may output information on the first to nth transmit wavelengths to the WSS controller 350 .

The WSS controller 350 may generate a first control signal using information on the first to nth transmission wavelengths. For example, the WSS controller 350 allows the first transmission port P11 to pass the signal of the first transmission wavelength, and the second transmission port P21 to allow the signal of the second transmission wavelength to pass, The n-th transmission port Pn1 may generate a first control signal allowing the signal of the n-th transmission wavelength to pass therethrough. That is, the first control signal may be a signal for controlling individual filters of the transmission ports P11 to Pn1 corresponding to each of the first to nth transmission lights.

The WSS controller 350 may output the first control signal to the first mux 240 .

The first mux 240 may include Wavelength Selective Switches (WSS), and may control the WSS according to the first control signal. For example, a switch for selecting a wavelength may be formed in each transmit port and a receive port of the first mux 240 , and the first mux 240 is configured to be connected to each transmit port and receive port according to the first control signal. Individual switches formed can be controlled. That is, the first mux 240 may control the 1-1 switch corresponding to the first transmission port P11 to correspond to the first transmission wavelength. Also, the first mux 240 may control the 2-1 switch corresponding to the second transmission port P21 to correspond to the second transmission wavelength. Similarly, the first mux 240 may control the n-1 th switch corresponding to the n th transmission port Pn1 to correspond to the n th transmission wavelength.

Accordingly, the first transmission port P11 may output only the optical signal corresponding to the first transmission wavelength, and the second transmission port P21 may output only the optical signal corresponding to the second transmission wavelength, and the nth transmission port P21 may output only the optical signal corresponding to the second transmission wavelength. The transmission port P11 may output only an optical signal corresponding to the n-th transmission wavelength.

In addition, the first mux 240 multiplexes the optical signals output from the first transmission port P11 to the n-th transmission port Pn1 to generate 'multiplexed transmission light', and transmits the multiplexed transmission light to the second mux through the optical cable. 260 may be transmitted.

When the multiplexed transmission light is received, the second mux 260 may demultiplex it and output it to each of the n second optical transceivers 320-1 to 320-n. For example, the second mux 260 may refer to a part of the first transmission light included in the multiplexed transmission light (the rest of the first transmission light except for the first partial transmission light, hereinafter the part received by the second mux 260 '). The first transmission light ') may be output to the 2-1-th optical transceiver 320-1 corresponding to the first transmission light. In addition, the second mux 260 may output the second transmission light included in the multiplexed transmission light to the 2-2 optical transceiver 320 - 2 corresponding to the second transmission light. Similarly, the second mux 260 may output the nth transmission light included in the multiplexed transmission light to the 2-nth optical transceiver 320 - n corresponding to the nth transmission light.

The 2-1 receiver 270-1 of the 2-1 optical transceiver 320-1 may receive the first transmission light. In the 2-1 receiver 270-1, the first test optical signal of the first transmission light and the optical signal of the first transmission wavelength may be separated, and the first optical signal of the transmission wavelength is transmitted to the 2-1 auxiliary controller 280. It can be output (Wavelength Data Out).

The 2-1 auxiliary controller 280 may recognize the first transmission wavelength by analyzing the optical signal of the first transmission wavelength. Also, when the first reply light is transmitted in response to the reception of the first transmit light, the 2-1 auxiliary controller 280 may generate the first reply wavelength information. Here, the first reply light is an optical signal set to be transmitted when the first transmission light is received, and includes preset test information (which may be irrelevant to information corresponding to the first test light signal) . It can be included as payload data. For example, when the first transmission light is received, the second-first optical transceiver 320-1 may generate a first reply light and output it to the second mux 260 . In this case, the 2-1 th transmitter 275-1 may generate preset test information as the first reply test optical signal, and the 2-1 th auxiliary controller 280 determines the wavelength of the first reply test optical signal. Information can be generated as the first auxiliary management data (hereinafter, the wavelength of the first return test optical signal is referred to as a 'first return wavelength', and the first auxiliary management data corresponding to the first return wavelength is referred to as a "first return"). Wavelength information'). The first reply wavelength information may be information generated to correspond to the AMCC by the 2-1 auxiliary controller 280 .

Also, the 2-1 auxiliary controller 280 may include information on the first transmission wavelength in the first reply wavelength information. Accordingly, the first return wavelength information may include information on both the wavelength of the first test optical signal and the wavelength of the first return test optical signal. In addition, the second-first auxiliary controller 280 may output the generated first reply wavelength information to the second-first transmitter 275-1.

The 2-1 th transmitter 275 - 1 may generate the first reply light by using the input test information and the first reply wavelength information. Since this may be similar to the operation of the 1-1 transmitter 230-1 generating the first transmission light, a detailed description thereof will be omitted. Also, the 2-1 th transmitter 275 - 1 may output the first reply light to the second mux 260 .

In the same way, the 2-2nd transmitter 275-2 may generate the second reply light and output it to the second mux 260, and the 2-nth transmitter 275-n generates the nth reply light. to output to the second mux 260 . Here, each of the first to nth reply lights includes a first to nth test light signal and a first to nth reply light signal, and the first to nth reply light signals are auxiliary signals. It may correspond to AMCC as management information.

The second mux 260 may generate a multiplexed reply light by multiplexing the first to nth reply lights, and may transmit the multiplexed reply light to the first mux 240 through an optical cable.

In this case, a reply coupler 360 may be formed between the first mux 240 and the second mux 260 . The reply coupler 360 may couple a part of the multiplex reply light and output it to the third mux 370 . That is, the 'partially multiplexed reply light' may be input to the third mux 270 as an optical signal separated from the multiplexed reply light by the reply coupler 360 .

The third mux 370 may demultiplex the partially multiplexed reply light and output it to the reply wavelength analyzer (Upstream Wavelength Analyzer, 380). For example, the third mux 370 may demultiplex the partially multiplexed reply light to separate the first partial reply light to the nth partial reply light, and divide the first partial reply light to the nth partial reply light with a reply wavelength It can be output to the analyzer 380 .

The reply wavelength analyzer 380 may receive the first partial reply light to the nth partial reply light. Since the first partial return light is a part of the first return light, it may include a part of the first return wavelength optical signal. Accordingly, the reply wavelength analyzer 380 can recognize the first reply wavelength by separating a part of the first reply wavelength optical signal from the first partial reply light, and then analyze the first reply wavelength optical signal. In addition, the reply wavelength analyzer 380 may separate a part of the second reply wavelength optical signal from the second partial reply light, and then analyze the second reply wavelength optical signal to recognize the second reply wavelength. In the same way, the reply wavelength analyzer 380 may recognize the nth reply wavelength by separating a part of the nth reply wavelength optical signal from the nth partial reply light and analyze the nth reply wavelength optical signal.

As described above, the first to the nth return wavelength optical signal may correspond to AMCC. Accordingly, the reply wavelength analyzer 380 may be configured to analyze the AMCC signal. Also, the reply wavelength analyzer 380 may output information about the first reply wavelength to the nth reply wavelength to the WSS controller 350 .

The WSS controller 350 may generate a second control signal by using information on the first to nth reply wavelengths. For example, the WSS controller 350 causes the first reply port P12 to pass the signal of the first reply wavelength, and the second reply port P22 to pass the signal of the second reply wavelength, A second control signal that allows the nth reply port Pn2 to pass the signal of the nth reply wavelength may be generated. That is, the second control signal may be a signal for controlling individual filters of the reply ports P12 to Pn2 corresponding to each of the first to nth reply lights.

The WSS controller 350 may output the second control signal to the first mux 240 .

The first mux 240 may control the WSS according to the second control signal. For example, the first mux 240 may control an individual switch formed in each reception port according to the second control signal. That is, the first mux 240 may control the 1-2 switches corresponding to the first reply port P12 to correspond to the first reply wavelength. Also, the first mux 240 may control the 2-2 switch corresponding to the second reply port P22 to correspond to the second reply wavelength. Similarly, the first mux 240 may control the n-2 th switch corresponding to the n-th reply port Pn2 to correspond to the n-th reply wavelength.

Accordingly, the first reply port P12 can output only the optical signal corresponding to the first reply wavelength, and the second reply port P22 can output only the optical signal corresponding to the second reply wavelength, and the nth reply port P22 can output only the optical signal corresponding to the second reply wavelength The reply port P12 may output only an optical signal corresponding to the nth reply wavelength.

In addition, the first mux 240 demultiplexes a portion of the multiplexed reply light input through the optical cable (that is, a portion of the multiplexed reply light except for the partially multiplexed reply light) to the n first optical transceivers 310-1 to 310- n) can be printed individually.

4 is a flowchart of an operation of automatically setting an optical wavelength according to an embodiment of the present disclosure.

FIG. 4 shows operations of each component (transmission wavelength analyzer, WSS controller, return wavelength analyzer, and third mux) of the optical wavelength setting device 390 described with reference to FIG. 3 reconstructed over time. Referring to FIG. 4 , the automatic optical wavelength setting operation of the optical wavelength setting device 390 may be more easily understood.

Referring to FIG. 4 , the first optical communication device 120 generates a first transmission light to an nth transmission light including any one of the first transmission wavelength information to the nth transmission wavelength information ( S410 ), and the generated second transmission light ( S410 ). The first transmission light to the nth transmission light may be transmitted to the second optical communication device 130 (S420).

As described above, each of the n first optical transceivers 1200 - 1 to 1200 - n included in the first optical communication device may generate transmission light including transmission wavelength information. The first mux 240 connected to the first optical transceivers 1200-1 to 1200-n receives and multiplexes the first transmission light to the n-th transmission light, and multiplexes the multiplexed transmission light with the second mux through an optical cable. 260) can be transmitted.

The second optical communication device 130 receives the corresponding m-th transmission light among the first to n-th transmission lights transmitted from the first optical communication device, and information on the m-th transmission wavelength included in the received m-th transmission light. can be read (S450) (m is a natural number less than or equal to n).

The second mux 260 may receive and demultiplex the multiplexed transmission light. The second optical communication device 130 may receive an m-th transmission light corresponding to the demultiplexed first transmission light to the n-th transmission light, and read m-th transmission wavelength information included in the received m-th transmission light. .

The second optical communication device 130 generates a p-th reply light including the read m-th transmission wavelength information and the p-th reply wavelength information, and transmits the generated p-th reply light to the first optical communication through the second mux 260 . It can be transmitted to the device 120 (S460). The second mux 260 may multiplex the reply light provided from each of the plurality of second optical communication devices and transmit the multiplexed light to the first mux 240 . The first mux 240 may demultiplex the received reply light.

The first optical communication device 120 analyzes the transmission wavelength information and the return wavelength information included in each of the reply beams received from the second optical communication device, and controls the WSS according to the control signal generated based on the analysis result (S470). ), it is possible to set the optical wavelength between the optical communication devices (S480).

As described above, in the optical communication system 100 according to an embodiment of the present disclosure, even if a plurality of tunable optical modules are included, optical signals of wavelengths corresponding to these optical modules can be automatically set without an administrator's visit.

Although the above has been described with reference to the preferred embodiment of the present disclosure, those of ordinary skill in the art will describe the technical aspects of the present disclosure within the scope not departing from the spirit and scope of the present disclosure described in the claims below. It will be appreciated that various modifications and variations of the teachings may be made.

100: optical communication system
120: first optical communication device
130: second optical communication device

Claims (20)

a first multiplexer including a first transmission port and a second transmission port;
a transmission wavelength analyzer that analyzes the first transmission light to recognize a first transmission wavelength corresponding to the first transmission light, and analyzes the second transmission light to recognize a second transmission wavelength corresponding to the second transmission light; and
The first transmission port transmits the light corresponding to the first transmission wavelength, and the second transmission port generates a first control signal for passing the light corresponding to the second transmission wavelength, and the first control a controller outputting a signal to the first multiplexer;
including,
The first multiplexer controls the first transmission port to correspond to the first transmission wavelength according to the first control signal, and controls the second transmission port to correspond to the second transmission wavelength. .
According to claim 1,
The transmit wavelength analyzer,
A portion of the first transmission light is coupled to receive a first partial transmission light, and a second partial transmission light coupled with a portion of the second transmission light is received;
An optical communication device for recognizing the first transmission wavelength and the second transmission wavelength by analyzing the received first partial transmission light and the second partial transmission light.
3. The method of claim 2,
The first transmission light includes first transmission wavelength information,
The second transmission light includes second transmission wavelength information,
The transmit wavelength analyzer,
Recognizing the first transmission wavelength by analyzing at least a part of the first transmission wavelength information included in the input first partial transmission light,
An optical communication device for recognizing the second transmission wavelength by analyzing at least a part of second transmission wavelength information included in the input second partial transmission light.
4. The method of claim 3,
and the first transmission wavelength information and the second transmission wavelength information correspond to an Auxiliary Management and Control Channel (AMCC).
According to claim 1,
The first multiplexer includes Wavelength Selective Switches (WSS), and controls the WSS to correspond to the first control signal.
According to claim 1,
a reply wavelength analyzer for recognizing a first reply wavelength corresponding to the first reply light and recognizing a second reply wavelength corresponding to the second reply light;
further comprising,
The controller generates a second control signal for allowing the first receiving port to pass the light corresponding to the first return wavelength and allowing the second receiving port to pass the light corresponding to the second return wavelength, and the generated second outputting a control signal to the first multiplexer;
The first multiplexer includes the first reception port and the second reception port, and according to the second control signal, controls the first reception port to correspond to the first return wavelength, and the second reception port and controlling to correspond to the second return wavelength.
7. The method of claim 6,
The reply wavelength analyzer,
A part of the first reply light is coupled to analyze the input first partial reply light to recognize the first reply wavelength;
The optical communication device of claim 1, wherein a portion of the second reply light is coupled to analyze the input second partial reply light to recognize the second reply wavelength.
8. The method of claim 7,
The first reply light includes first reply wavelength information,
The second reply light includes second reply wavelength information,
The first reply wavelength information includes information on the first reply wavelength and information on the first transmission wavelength,
The second reply wavelength information includes information on the second reply wavelength and information on the second transmission wavelength,
The reply wavelength analyzer,
Recognizing the first reply wavelength by analyzing the first reply wavelength information through the first partial reply light,
and recognizing the second reply wavelength by analyzing the second' reply wavelength information through the second partial reply light.
9. The method of claim 8,
and each of the first reply wavelength information and the second reply wavelength information corresponds to an Auxiliary Management and Control Channel (AMCC).
8. The method of claim 7,
a second multiplexer that separates a part of the input reply light into a first partial reply light and a second partial reply light and outputs it to the reply wavelength analyzer;
further comprising,
The reply light is an optical signal received from the outside in response to transmission of the transmit light, and a part of the reply light is input to the first multiplexer, and the other part of the reply light is input to the second multiplexer,
The transmission light is an optical signal transmitted from the first multiplexer to the outside by combining optical signals of the first transmission port and the second transmission port.
A method for setting a wavelength of an optical communication device, the method comprising:
recognizing a first transmission wavelength corresponding to the first transmission light by analyzing the first transmission light, and recognizing a second transmission wavelength corresponding to the second transmission light by analyzing the second transmission light;
generating, by a first transmission port, light corresponding to the first transmission wavelength, and by a second transmission port, a first control signal for passing light corresponding to the second transmission wavelength;
outputting the generated first control signal to a first multiplexer including the first transmission port and the second transmission port; and
and controlling the first transmission port to correspond to the first transmission wavelength according to the first control signal, and controlling the second transmission port to correspond to the second transmission wavelength. How to set up.
12. The method of claim 11,
The first transmission light includes first transmission wavelength information, and the second transmission light includes second transmission wavelength information,
Recognizing the first transmission wavelength and the second transmission wavelength,
receiving a first partial transmission light coupled with a portion of the first transmission light and a second partial transmission light with a portion of the second transmission light coupled thereto; and
At least a part of the first transmission wavelength information included in the received first partial transmission light and at least a part of the second transmission wavelength information included in the second partial transmission light are analyzed to determine the first transmission wavelength and the second transmission wavelength A method of setting a wavelength of an optical communication device, comprising the step of recognizing.
13. The method of claim 12,
and the first transmission wavelength information and the second transmission wavelength information correspond to AMCC.
12. The method of claim 11,
recognizing a first reply wavelength corresponding to the first reply light provided from the outside in response to the transmission of the first transmit light; and
In order for the first reception port included in the first multiplexer to pass the light corresponding to the first return wavelength, the method further comprising the step of controlling the first reception port to correspond to the first return wavelength, optical communication How to set the wavelength of the device.
15. The method of claim 14,
The first reply light includes first reply wavelength information,
Recognizing the first reply wavelength comprises:
and recognizing the first reply wavelength by analyzing at least a part of the first reply wavelength information included in the input first partial reply light by coupling a part of the first reply light; How to set up.
16. The method of claim 15,
recognizing a second reply wavelength corresponding to a second reply light provided from the outside in response to transmission of the second transmit light; and
In order for the second reception port included in the first multiplexer to pass the light corresponding to the second return wavelength, the method further comprising the step of controlling the second reception port to correspond to the second return wavelength, optical communication How to set the wavelength of the device.
17. The method of claim 16,
The second reply light includes second reply wavelength information,
Recognizing the second reply wavelength comprises:
and recognizing the second reply wavelength by analyzing at least a part of the second reply wavelength information included in the input second partial reply light by coupling a part of the second reply light. How to set up.
18. The method of claim 17,
Each of the first reply wavelength information and the second reply wavelength information corresponds to AMCC.
analyzing the first transmission light and the second transmission light output from the first optical communication device to recognize a first transmission wavelength corresponding to the first transmission light and a second transmission wavelength corresponding to the second transmission light transmission wavelength analyzer; and
The first transmission port of the first multiplexer transmits the light corresponding to the first transmission wavelength, and the second transmission port of the first multiplexer receives a first control signal for passing the light corresponding to the second transmission wavelength and a controller for generating and outputting the generated first control signal to the first multiplexer.
20. The method of claim 19,
receiving a first reply light transmitted from a second optical communication device in response to the reception of the first transmission light and a second reply light transmitted from a third optical communication device in response to the reception of the second transmission light; Further comprising a reply wavelength analyzer for recognizing a first reply wavelength corresponding to the first reply light and recognizing a second reply wavelength corresponding to the received second reply light,
The controller is
A second control signal for allowing the first receiving port of the first multiplexer to pass the light corresponding to the first return wavelength, and the second receiving port of the first multiplexer to pass the light corresponding to the second return wavelength and outputting the generated second control signal to the first multiplexer, an optical wavelength setting device.

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