KR20220134294A - Optical communication system with automatic channel setting function and optical communication module provided therein - Google Patents

Abstract

When a first optical communication module transmits a first transmission optical signal comprising the information regarding a first channel at every first preset time, the present invention is configured so that a second optical communication module transmits the information regarding the first channel to the first optical communication module. According to the present invention, even if the first optical communication module does not know its transmission channel connected to a first multiplexer/demultiplexer, the second optical communication module can automatically set its transmission channel through a second transmission optical signal comprising the information regarding the transmitted first channel.

Description

An optical communication system having an automatic channel setting function and an optical communication module provided therein

The present invention relates to an optical communication system having an automatic channel setting function and an optical communication module provided therein.

A wavelength division multiplexing (WDM) optical communication system that communicates information about a plurality of channels having different wavelengths through a single optical fiber is mainly used in current high-speed communication networks. Such an optical communication system requires an optical communication module capable of transmitting and receiving an optical signal corresponding to each channel of a multiplexer/demultiplexer in order to transmit information about several dozen channels through one optical fiber.

For smooth data communication between local and remote, set the channel of the optical signal transmitted by the optical communication module (i.e., wavelength setting) so that the optical signal transmitted by the optical communication module passes through the channel of the multiplexer/demultiplexer. Should be. For this purpose, conventionally, the installer of the optical communication system connects the optical communication module to the multiplexer/demultiplexer and then manually sets the transmission channel of the optical communication module. However, when the optical communication system is installed in this way, the difficulty of installation, maintenance and repair of the optical communication system increases, thereby increasing the cost, and the system construction time is also long.

In order to solve this problem, in Patent Document 1, when the first optoelectronic module receives a Loss Of Signal (LOS) indicator from the second optoelectronic module, the first optoelectronic module is the signal loss indicator. In response to receiving, transmit an optical signal relating to one of the plurality of wavelength channels toward the second optoelectronic module, and if the signal loss indicator persists, the first optoelectronic module tunes the transmitter to tune the transmitter to one of the plurality of wavelength channels Transmission of optical signals on different wavelength channels is disclosed. According to Patent Document 1, since the channel setting of the first optoelectronic module is configured to be made through signal loss, if there is no data exchanged between the first optoelectronic module and the second optoelectronic module, the channel setting of the optoelectronic module is properly made. difficult. In addition, since Patent Document 1 only shows that the first optoelectronic module scans an optical signal to know its own transmission channel while the transmission channel of the second optoelectronic module is fixed, the first optoelectronic module and the second When the optoelectronic module does not know its own transmission channel, it is difficult to apply.

Next, in Patent Document 2, the first optical transceiver first sets its own channel to a specific channel and then performs FSK (Frequency Shift Keying) communication with the second optical transceiver. If the FSK communication is not performed, the first optical transceiver The transceiver is configured to set its channel to another channel. According to Patent Document 2, since the first optical transceiver must individually check whether communication with the second optical transceiver is performed for each set channel, it takes a relatively long time to set the channel of the optical transceiver.

US Patent Publication No. US9692547 (2017.06.27.) Korean Patent Publication No. 1884393 (2018.07.26.)

The present invention has been prepared to solve the above problems, and an object of the present invention is to provide a method for automatically setting a transmission channel of an optical communication module.

Another object of the present invention is to provide a method for quickly and conveniently performing maintenance and repair as well as initial installation of an optical communication system.

In order to achieve the above object, the optical communication system according to the present invention includes a first optical communication module including a first transmitter, a first receiver, and a first controller that is connected to the first transmitter and the first receiver in communication with the first receiver. ; a first multiplexer/demultiplexer disposed outside the first optical communication module and having a plurality of first channels connectable to the first transmitter and the first receiver; a second optical communication module including a second transmitter, a second receiver, and a second controller communicatively connected to the second transmitter and the second receiver; a second multiplexer/demultiplexer disposed outside the second optical communication module and having a plurality of second channels connectable to the second transmitter and the second receiver; and an optical fiber for communicatively connecting the first multiplexer/demultiplexer and the second multiplexer/demultiplexer, wherein the first control unit includes the first transmitter, the plurality of first channels at every first preset time. transmit a first transmission optical signal including information on a first channel, which is information about any one channel, to the second optical communication module, and the second control unit includes information on the first channel When the first transmit optical signal is received by the second receiver, the second transmitter transmits a second transmit optical signal including information on the first channel to the first optical communication module, wherein the first controller comprises: When the second transmission optical signal including information on the first channel is received by the first receiver, the transmission channel of the first transmitter may be set as the first channel.

In addition, the second control unit, wherein the second transmission unit transmits the second transmission optical signal including information about a second channel, which is information about any one of the plurality of second channels, every second preset time to transmit to a first optical communication module, wherein the first control unit receives the second transmission optical signal including information about the second channel by the first receiving unit, the first transmitting unit relates to the second channel When the first transmit optical signal including information is transmitted to the second optical communication module, the second control unit receives the first transmit optical signal including information on the second channel by the second receiver , a transmission channel of the second transmitter may be set as the second channel.

In addition, the first control unit is, if the second transmission optical signal including the information on the second channel is not received by the first receiving unit, the first transmitting unit is transmitted at the first preset time interval. The transmission optical signal may include information indicating that the second transmission optical signal including information on the second channel has not been received.

In addition, the second control unit is, if the first transmission optical signal including the information on the first channel is not received by the second receiving unit, the second transmitting unit transmits the second at every second preset time. The transmission optical signal may include information indicating that the first transmission optical signal including information on the first channel has not been received.

In addition, the first control unit is, when the second transmission optical signal is not received by the first receiving unit until a predetermined time elapses from the time when the first transmission unit starts transmitting the first transmission optical signal, The first transmission unit may stop the operation of transmitting the first transmission optical signal.

In addition, the second control unit is configured to cause the second transmission unit to transmit the second transmission optical signal only after the first transmission optical signal including the information on the first channel is received by the second reception unit can

In addition, when the first transmission optical signal including information on the first channel is received by the second receiver, the second control unit may be configured to use a pre-stored channel convention and information about the first channel to obtain the second signal. You can set the transmission channel of the transmitter.

In addition, in the optical communication system according to the present invention, the first optical communication module processes the first transmission optical signal transmitted from the first transmission unit as a first Auxiliary Management and Control Channel (AMCC) signal under the control of the first control unit. and a first AMCC signal processing unit, wherein the second optical communication module processes a second transmission optical signal transmitted from the second transmission unit as a second AMCC signal under the control of the second control unit. It may further include a signal processing unit.

Meanwhile, in order to achieve the above object, the optical communication module (the above-described 'first optical communication module') according to an embodiment of the present invention transmits a transmission optical signal (the above-described 'first transmission optical signal'). a transmitter ('first transmitter' described above); a receiving unit (the above-mentioned 'first receiving unit') for receiving an external transmission optical signal (the above-described 'second transmission optical signal') transmitted from an external optical communication module ('second optical communication module'); and a control unit (the above-described 'first control unit') communicatively connected to the transmitting unit and the receiving unit, wherein the control unit includes the transmitting optical signal including information on the first channel at every preset time. to the external optical communication module, and when the external transmission optical signal including information about the first channel from the external optical communication module is received by the receiver, the transmission channel of the transmitter may be set as the first channel .

In addition, the control unit, when the external transmission optical signal including information about the second channel is received from the external optical communication module, the transmission unit transmits the optical transmission signal including information about the second channel It can be transmitted to an external optical communication module.

In addition, when the external transmission optical signal including the information on the second channel is not received by the receiver, the control unit may include: Information indicating that the external transmission optical signal including information has not been received may be included.

In addition, the control unit may perform an operation in which the transmitter transmits the transmit optical signal if the external transmit optical signal is not received by the receiver until a predetermined time elapses from the time when the transmitter starts transmitting the transmit optical signal can be made to stop.

In addition, the optical communication module according to an embodiment of the present invention may further include an AMCC signal processing unit that processes the transmission optical signal transmitted from the transmission unit as an AMCC signal under the control of the control unit.

Meanwhile, in order to achieve the above object, the optical communication module (the above-described 'second optical communication module') according to another embodiment of the present invention transmits a transmission optical signal (the above-described 'second transmission optical signal'). a transmitter ('second transmitter' described above); a receiving unit (ie, the above-described 'second receiving unit') for receiving an external transmission optical signal (ie, the above-described 'first transmission optical signal') transmitted from an external optical communication module (ie, the above-described 'first optical communication module'); and a control unit (the 'second control unit' described above) communicatively connected to the transmitting unit and the receiving unit, wherein the control unit transmits the external transmission optical signal including information about the first channel from the external optical communication module. When received by the receiver, the transmitter may transmit the transmit optical signal including information about the first channel to the external optical communication module.

In addition, the control unit causes the transmitter to transmit the transmit optical signal including information on the second channel at a preset time, and the external transmit optical signal including information on the first channel is received by the receiver Only after this is achieved, the transmitter may allow the transmitter to transmit the transmit optical signal.

In addition, when the external transmission optical signal including information about the first channel is received from the external optical communication module, the control unit may include a pre-stored channel protocol and information about the first channel by using the information about the first channel. You can set the transmission channel.

In addition, the optical communication module according to another embodiment of the present invention may further include an AMCC signal processing unit that processes the transmission optical signal transmitted from the transmission unit as an AMCC signal under the control of the control unit.

In the present invention, when the first optical communication module transmits (ie, scans) the first transmission optical signal including information on the first channel at every first preset time, the second optical communication module sends the first optical communication module to the first optical communication module. It is configured to convey information about the first channel. According to this, even if the first optical communication module does not know its own transmission channel connected to the first multiplexer/demultiplexer, the first optical communication module transmits its own transmission channel through the second transmission optical signal including information on the first channel transmitted by the second optical communication module. The transmission channel can be set.

In addition, in the present invention, as long as the second optical communication module transmits (ie, scans) the second transmission optical signal including information on the second channel at every second preset time, the first optical communication module performs the second optical communication module is configured to deliver information about the second channel to According to this, even if the second optical communication module does not know its own transmission channel connected to the second multiplexer/demultiplexer, the second optical communication module transmits its own transmission channel through the first optical communication signal including information on the second channel transmitted by the first optical communication module. The transmission channel can be set.

In addition, in the present invention, the first optical communication module (or the second optical communication module) determines whether there is a loss of signal (LOS) in the data transmitted from the second optical communication module (or the first optical communication module). It is not necessary to individually check for each setting channel or to check whether the first optical communication module (or the second optical communication module) communicates with the second optical communication module (or the first optical communication module) for each setting channel. When the first optical communication module (or the second optical communication module) transmits (ie, scans) the transmission optical signal including the channel information at every preset time, the second optical communication module (or the first optical communication module) It is configured to transmit information about the transmission channel of the first optical communication module (or the second optical communication module). Accordingly, it is possible to set the transmission channel of the first optical communication module (or the second optical communication module) quickly and conveniently compared to the prior art.

Furthermore, the present invention includes a first AMCC signal processing unit for the first optical communication module to process the first transmission optical signal as a first AMCC signal, and the second optical communication module to process the second transmission optical signal as a second AMCC signal and a second AMCC signal processing unit. According to this, if the AMCC communication link is not disconnected between the first optical communication module and the second optical communication module, even if there is no data directly exchanged between the first optical communication module and the second optical communication module, the first optical communication module and the second optical communication module It is possible to set the transmission channel. Accordingly, it is possible to quickly and conveniently perform maintenance and repair as well as initial installation of the optical communication system.

1 is a diagram schematically illustrating an optical communication system and an optical communication module provided therein according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating an optical signal through which a first optical communication module and a second optical communication module communicate when the optical communication system of FIG. 1 operates in a bidirectional automatic channel setting mode.
FIG. 3 is a diagram illustrating a case in which a first optical communication module is in an on state and a second optical communication module is in an off state in the optical communication system of FIG. 1 .
FIG. 4 is a diagram illustrating a state in which the second optical communication module transmits the second transmission optical signal only after receiving the first transmission optical signal transmitted from the first optical communication module in the optical communication system of FIG. 1 .
FIG. 5 is a diagram illustrating an optical signal through which a first optical communication module and a second optical communication module communicate when the optical communication system of FIG. 1 operates in a one-way automatic channel setting mode.

Hereinafter, an optical communication system having an automatic channel setting function and an optical communication module provided therein according to the present invention will be described in detail with reference to the accompanying drawings. The accompanying drawings are provided as examples in order to sufficiently convey the spirit of the present invention to those skilled in the art, and the present invention is not limited to the drawings presented below and may be embodied in other forms. As used herein, the term '... The 'unit' means a unit for processing one function or operation, which may be implemented as hardware or software, or a combination of hardware and software.

1 is a diagram schematically illustrating an optical communication system and an optical communication module provided therein according to an embodiment of the present invention.

1, an optical communication system 1000 according to an embodiment of the present invention includes a first optical communication module 100, a first multiplexer/demultiplexer 200, a second optical communication module 300, and a second multiplexer. / may include a demultiplexer 400 and an optical fiber 500 .

The first optical communication module 100 includes a first transmission unit 110 for transmitting a first transmission optical signal and an external transmission optical signal (eg, an external optical communication module 300 ) transmitted from an external optical communication module (eg, the second optical communication module 300 ). For example, it may include a first receiver 120 for receiving a second transmit optical signal), and a first controller 130 communicatively connected to the first transmitter 110 and the first receiver 120 . An algorithm for automatic channel setting may be pre-stored in the first control unit 130 .

In addition, the first optical communication module 100 processes the first transmission optical signal transmitted from the first transmission unit 110 as a first AMCC signal under the control of the first control unit 130 , and in the first reception unit 120 , It may include a first AMCC signal processing unit 140 that processes the received external transmission optical signal (eg, the second transmission optical signal) as a second AMCC signal.

Here, the first AMCC signal means a signal including data transmitted by the first optical communication module 100 to perform status monitoring or function control of the second optical communication module 300 . The first AMCC signal is transmitted through a subchannel (ie, AMCC) formed in the traffic data transmitted by the first transmitter 110 . The first AMCC signal monitors the state of the second optical communication module 300 (transmission optical power, reception optical power, temperature of the second optical communication module, driving current and driving voltage of a laser diode provided in the second optical communication module, etc.) or , can be used to control the function of the second optical communication module 300 (change of the transmission channel, on/off control of the laser diode provided in the second optical communication module, etc.), and furthermore, of the second optical communication module 300 It may be used to determine information (model name of the second optical communication module, IDENTIFICATION information of the second optical communication module, etc.).

In addition, the second AMCC signal is data that the first optical communication module 100 receives from the external optical communication module 300 , and the external optical communication module 300 monitors the state of the first optical communication module 100 or controls a function, etc. It means a signal including data to be transmitted to perform The second AMCC signal is transmitted through a subchannel (ie, AMCC) formed in the traffic data transmitted by the second transmitter 310 . The second AMCC signal monitors the state of the first optical communication module 100 (transmission optical power, reception optical power, temperature of the first optical communication module, driving current and driving voltage of the laser diode provided in the first optical communication module, etc.) or , can be used to control the function of the first optical communication module 100 (change of a transmission channel, on/off control of a laser diode provided in the first optical communication module, etc.), and furthermore, of the first optical communication module 100 It may be used to determine information (model name of the first optical communication module, IDENTIFICATION information of the first optical communication module, etc.).

In the present invention, when the first optical communication module 100 operates as a principal, the second optical communication module 300 becomes an external optical communication module, and the second transmission optical signal transmitted by the second optical communication module 300 is externally transmitted. becomes an optical signal.

In addition, in the present invention, when the second optical communication module 300 operates as a subject, the first optical communication module 100 becomes an external optical communication module, and the first transmission optical signal transmitted by the first optical communication module 100 is It becomes an external transmission optical signal.

The first optical communication module 100 is connected to the first manager system 10 to receive data to be transmitted to the second optical communication module 300 from the first manager system 10 , and the second optical communication module 300 ) may transmit data received from the first manager system 10 . In addition, the first optical communication module 100 may send and receive management and control information from the first manager system 10 , and may receive power required for the operation of the first optical communication module 100 . When the first optical communication module 100 receives power from the first manager system 10 , the first optical communication module 100 automatically sets its own transmission channel as described below.

When the first optical communication module 100 does not include the first AMCC signal processing unit 140 , the first transmission optical signal transmitted from the first transmission unit 110 and the external transmission light received from the first reception unit 120 . The signal (eg, the second transmission optical signal) is controlled by the first control unit 130 . In this case, the first transmit optical signal and the second transmit optical signal are to be transmitted and received integrally with data exchanged between the first optical communication module 100 and the second optical communication module 300 under the control of the first control unit 130 . can

On the other hand, when the first optical communication module 100 includes the first AMCC signal processing unit 140 , the first transmission optical signal transmitted from the first transmission unit 110 and the external received from the first reception unit 120 are The transmission optical signal (eg, the second transmission optical signal) is processed as an AMCC signal by the first AMCC signal processing unit 140 . In this case, the first transmit optical signal and the second transmit optical signal are transmitted/received separately from data exchanged between the first optical communication module 100 and the second optical communication module 300 , that is, transmitted/received through a subchannel (AMCC). can be As shown in FIG. 1 , the first AMCC signal processing unit 140 may be configured separately from the first control unit 130 , but is provided in the form of firmware in the first control unit 130 , so that it is integrated with the first control unit 130 . may consist of

The first multiplexer/demultiplexer 200 may be disposed outside the first optical communication module 100 . A plurality of first channels 210 connectable to the first transmitter 110 and the first receiver 120 are provided on one side of the first multiplexer/demultiplexer 200, and the first multiplexer/demultiplexer 200 is provided. A first connection port 220 connectable to one side of the optical fiber 500 is provided at the other side of the optical fiber 500 . Wavelengths that can pass through each of the first channels 210 provided in the first multiplexer/demultiplexer 200 may be different.

The second optical communication module 300 includes a second transmission unit 310 for transmitting a second transmission optical signal, and an external transmission optical signal (eg, the first optical communication module 100) transmitted from the external optical communication module (eg, the first optical communication module 100). For example, it may include a second receiver 320 for receiving the first transmission optical signal), and a second controller 330 communicatively connected to the second transmitter 310 and the second receiver 320 . An algorithm for automatic channel setting may be previously stored in the second control unit 330 .

In addition, the second optical communication module 300 processes the second transmission optical signal transmitted from the second transmission unit 310 as a second AMCC signal under the control of the second control unit 330 , and in the second reception unit 320 . It may include a second AMCC signal processing unit 340 that processes the received external transmission optical signal (eg, the first transmission optical signal) as the first AMCC signal.

The second optical communication module 300 is connected to the second manager system 30 to receive data to be transmitted to the first optical communication module 100 from the second manager system 30 , and the first optical communication module 100 ) may transmit data received from the second manager system 30 . In addition, the second optical communication module 300 may send and receive management and control information from the second manager system 30 , and may receive power required for the operation of the second optical communication module 300 . When the second optical communication module 300 receives power from the second manager system 30 , the second optical communication module 300 automatically sets its own transmission channel as described below.

When the second optical communication module 300 does not include the second AMCC signal processing unit 340 , the second transmission optical signal transmitted from the second transmission unit 310 and the external transmission light received from the second reception unit 320 . The signal (eg, the first transmission optical signal) is controlled by the second control unit 330 . In this case, the first transmit optical signal and the second transmit optical signal are to be transmitted and received integrally with data exchanged between the first optical communication module 100 and the second optical communication module 300 under the control of the second control unit 330 . can

On the other hand, when the second optical communication module 300 includes the second AMCC signal processing unit 340 , the second transmission optical signal transmitted by the second transmission unit 310 and the external received by the second reception unit 320 are The transmission optical signal (eg, the first transmission optical signal) is processed as an AMCC signal by the second AMCC signal processing unit 340 . In this case, the first transmit optical signal and the second transmit optical signal are transmitted/received separately from data exchanged between the first optical communication module 100 and the second optical communication module 300 , that is, transmitted/received through a subchannel (AMCC). can be As shown in FIG. 1 , the second AMCC signal processing unit 340 may be configured separately from the second control unit 330 , but by being provided in the form of firmware in the second control unit 330 , it is integrated with the second control unit 330 . may consist of

The second multiplexer/demultiplexer 400 may be disposed outside the second optical communication module 300 . A plurality of second channels 410 connectable to a second transmitter 310 and a second receiver 320 are provided on one side of the second multiplexer/demultiplexer 400, and the second multiplexer/demultiplexer 400 is provided. A second connection port 420 connectable to the other side of the optical fiber 500 is provided on the other side of the optical fiber 500 . Wavelengths that can pass through each second channel 410 provided in the second multiplexer/demultiplexer 400 may be different.

One side of the optical fiber 500 is connected to the first connection port 220 provided on the other side of the first multiplexer/demultiplexer 200 , and the other side of the optical fiber 500 is the other side of the second multiplexer/demultiplexer 400 . It is connected to the second connection port 420 provided in the. The optical fiber 500 is communicatively connected to the first multiplexer/demultiplexer 200 and the second multiplexer/demultiplexer 400, and accordingly, the first optical communication module 100 and the second optical communication module 300 transmit data between each other. and AMCC signals.

FIG. 2 is a diagram illustrating an optical signal through which a first optical communication module and a second optical communication module communicate when the optical communication system of FIG. 1 operates in a bidirectional automatic channel setting mode. Hereinafter, a state when the optical communication system 1000 shown in FIG. 1 operates in a bidirectional automatic channel setting mode will be described with reference to FIG. 2 .

In the bidirectional automatic channel setting mode shown in FIG. 2 , the first transmitter 110 of the first optical communication module 100 transmits a first transmission for a plurality of first channels 210 provided in the first multiplexer/demultiplexer 200 . The scan is performed as an optical signal, and the second transmitter 310 of the second optical communication module 300 is also scanned as a second transmit optical signal for a plurality of second channels 410 provided in the second multiplexer/demultiplexer 400 . is the mode to

FIG. 2 shows that the first transmitter 110 of the first optical communication module 100 is connected to channel 3 of the first multiplexer/demultiplexer 200, and the first receiver 120 connects to the first multiplexer/demultiplexer 200. ) connected to channel 23 is shown as an example. In addition, FIG. 2 shows that the second transmitter 310 of the second optical communication module 300 is connected to channel 23 of the second multiplexer/demultiplexer 400, and the second receiver 320 is connected to the second multiplexer/demultiplexer 400. A state connected to channel 3 of 400 is shown as an example.

The first controller 130 causes the first transmitter 110 to scan the plurality of first channels 210 provided in the first multiplexer/demultiplexer 200 . For example, the first transmitter 110 transmits, under the control of the first controller 130, information (0x01) on the first channel provided in the first multiplexer/demultiplexer 200 at a specific time t ₁ second. The included first transmission optical signal may be transmitted to the second optical communication module 300 . Also, under the control of the first controller 130 , the first transmitter 110 includes the first channel 2 information (0x02) of the first multiplexer/demultiplexer 200 at t ₁ +1 second. The transmission optical signal may be transmitted to the second optical communication module 300 . In addition, under the control of the first controller 130 , the first transmitter 110 includes the first channel 3 information (0x03) of the first multiplexer/demultiplexer 200 at t ₁ +2 seconds. The transmission optical signal may be transmitted to the second optical communication module 300 .

As such, the first control unit 130 controls the first multiplexer/demultiplexer 200 for each first preset time (t ₁ second, t ₁ +1 second, t ₁ +2 second, etc.) A first transmission optical signal including information about a first channel (0x01, 0x02, 0x03, etc.) that is information about any one of the plurality of first channels 210 provided in the second optical communication module 300 to send

Here, among the information about the first channel (0x01, 0x02, 0x03, etc.), the information about the first channel (0x03) may relate to a wavelength that can pass through the first channel 210 . In addition, in the present invention, the first preset time is not limited to the above example, and the user of the first optical communication module 100 may set it arbitrarily in the first control unit 130 .

In addition, in the present invention, the first control unit 130, in principle, the first receiving unit 120 from the second transmitting unit 310 of the second optical communication module 300, the second transmission optical signal including information about the first channel irrespective of whether or not has been received, the first transmission unit 110 may transmit the first transmission optical signal including the information on the first channel at every first preset time. Conventionally, after the first optical communication module arbitrarily sets its own channel, waits for information about the channel to be transmitted from the second optical communication module, and if the information on the channel is not transmitted, the channel is changed through the method of changing the arbitrarily set channel. was set.

In contrast, in the present invention, instead of waiting for the first optical communication module 100 to transmit channel information from the second optical communication module 300 , the first transmitting unit 110 transmits the information to the first channel at every first preset time. The second optical communication module 300 is configured to transmit the information about the first channel to the first optical communication module 100 as long as the first transmission optical signal including the information is transmitted. According to the present invention, the first optical communication module 100 transmits its own transmission channel through the second transmission optical signal including information on the first channel transmitted by the second optical communication module 300 compared to the prior art. You can set it up more quickly.

Referring to FIG. 2 , among the plurality of first transmission optical signals transmitted by the first transmission unit 110 , the first transmission optical signal including information (0x03) on the third channel of the first multiplexer/demultiplexer 200 only is received by the second receiver 320 of the second optical communication module 300 through channel 3 of the second multiplexer/demultiplexer 400 . In this case, the second control unit 330 knows that the reception channel of the second optical communication module 300 is channel 3 and that the transmission channel of the first optical communication module 100 is channel 3. Accordingly, the second control unit 330 may set the receiving channel of the second receiving unit 320 as the third channel of the second multiplexer/demultiplexer 400 . Also, as described later, the second controller 330 may notify the first controller 130 that the transmission channel of the first optical communication module 100 is the third channel of the first multiplexer/demultiplexer 200 .

In the same manner, the second controller 330 causes the second transmitter 310 to scan the plurality of second channels 410 provided in the second multiplexer/demultiplexer 400 . For example, the second transmitter 310 transmits, under the control of the second controller 330 , information (0x04) on channel 4 provided in the second multiplexer/demultiplexer 400 at a specific time t ₂ seconds. The included second transmission optical signal may be transmitted to the first optical communication module 100 . Also, under the control of the second controller 330 , the second transmitter 310 includes the second information (0x05) about the channel 5 of the second multiplexer/demultiplexer 400 at t ₂ +1 second. The transmission optical signal may be transmitted to the first optical communication module 100 . In addition, under the control of the second controller 330 , the second transmitter 310 includes information (0x16) on channel 22 of the second multiplexer/demultiplexer 400 at t ₂ +18 seconds. The transmission optical signal may be transmitted to the first optical communication module 100 . Also, under the control of the second controller 330 , the second transmitter 310 includes information (0x17) on the 23rd channel of the second multiplexer/demultiplexer 400 at t ₂ +19 seconds. The transmission optical signal may be transmitted to the first optical communication module 100 .

In this way, the second control unit 330 controls the second transmitter 310 every second preset time (t ₂ seconds, t ₂ +1 seconds, …, t ₂ +18 seconds, t ₂ +19 seconds, etc.) 2 A second including information about a second channel (0x04, 0x05, ..., 0x16, 0x17, etc.) Transmits an optical signal.

Here, the information (0x17) on the second channel of any one of the information on the second channel (0x04, 0x05, ..., 0x16, 0x17, etc.) relates to a wavelength that can pass through the second channel 410 can In addition, in the present invention, the second preset time is not limited to the above example, and the user of the second optical communication module 300 may set it arbitrarily in the second control unit 330 .

In addition, in the present invention, in principle, the second control unit 330 is a first transmission optical signal in which the second reception unit 320 includes information about the second channel from the first transmission unit 110 of the first optical communication module 100 . irrespective of whether or not has been received, the second transmission unit 310 may transmit the second transmission optical signal including information on the second channel at every second preset time. As described above, in the related art, after the second optical communication module arbitrarily sets its own channel, it waits for information about the channel to be transmitted from the first optical communication module, and if the information on the channel is not transmitted, the arbitrarily set channel is changed. The channel was set through the method.

In contrast, in the present invention, instead of waiting for the second optical communication module 300 to transmit channel information from the first optical communication module 100 , the second transmitter 310 sends the second channel to the second channel every second preset time. The first optical communication module 100 is configured to transmit information about the second channel to the second optical communication module 300 as long as the second transmission optical signal including the information is transmitted. According to the present invention, the second optical communication module 300 transmits its own transmission channel through the first transmission optical signal including information on the second channel transmitted by the first optical communication module 300 compared to the prior art. You can set it up more quickly.

Referring to FIG. 2 , among a plurality of second transmission optical signals transmitted by the second transmission unit 310 , a second transmission optical signal including information (0x17) on channel 23 of the second multiplexer/demultiplexer 400 . only is received by the first receiver 120 of the first optical communication module 100 through channel 23 of the first multiplexer/demultiplexer 200 . In this case, the first control unit 130 knows that the reception channel of the first optical communication module 100 is channel 23 and that the transmission channel of the second optical communication module 300 is channel 23 . Accordingly, the first control unit 130 may set the receiving channel of the first receiving unit 120 as the 23rd channel of the first multiplexer/demultiplexer 200 . Also, the first control unit 130 may inform the second control unit 330 that the transmission channel of the second optical communication module 300 is channel 23 of the second multiplexer/demultiplexer 400 , as will be described later.

Meanwhile, the first control unit 130 determines whether the second transmission optical signal including information (0x17) on the second channel 410 of the second multiplexer/demultiplexer 400 has been received by the first reception unit 120 . It can be monitored in real time.

As a result of the real-time monitoring by the first control unit 130, when the second transmission optical signal including the information (0x17) on the second channel is received by the first reception unit 120 , the first control unit 130 controls the first By allowing the transmission unit 110 to transmit the first transmission optical signal including the information (0x17) on the second channel, the second control unit 330 can set the transmission channel of the second optical communication module 300 . .

When the first transmission unit 110 transmits a first transmission optical signal including information on the second channel (0x17) under the control of the first controller 130, information on the second channel (0x17) ) is received by the second receiver 320 through channel 3 of the first multiplexer/demultiplexer 200 and channel 3 of the second multiplexer/demultiplexer 400 . As such, when the first transmission optical signal including the information on the second channel (0x17) is received by the second receiving unit 320 , the second control unit 330 sets the transmission channel of the second transmitting unit 310 to the second transmission channel. It is set as a channel (that is, channel 23 of the second multiplexer/demultiplexer 400).

On the other hand, as a result of monitoring in real time by the first control unit 130 , if the second transmission optical signal including the information about the second channel (0x17) is not received by the first receiving unit 120 , or any second transmission If the optical signal is also not received by the first receiver 120, the first controller 130 responds to the first transmit optical signal transmitted by the first transmitter 110 at the first preset time, the second channel. Information indicating that the second transmission optical signal including the information has not been received may be included.

Accordingly, in the above example, when the first transmission unit 110 transmits the first transmission optical signal including the information (0x01) on the first channel of the first multiplexer/demultiplexer 200, the first channel Information (0xFF) indicating that the information (0x17) on the second channel has not been received may be included in the first transmission optical signal including information (0x01) on the second channel. In addition, when the first transmitter 110 transmits the first transmission optical signal including the information (0x02) on the second channel of the first multiplexer/demultiplexer 200, the information on the second channel (0x02) ) may include information (0xFF) indicating that the information (0x17) regarding the second channel has not been received. In addition, when the first transmitter 110 transmits the first transmission optical signal including the information (0x03) on the third channel of the first multiplexer/demultiplexer 200, the information on the third channel (0x03) ) may include information (0xFF) indicating that the information (0x17) regarding the second channel has not been received.

As described above, among the first transmission optical signals transmitted by the first transmission unit 110, the first transmission optical signal including the information (0x03) on the third channel of the first multiplexer/demultiplexer 200 is 2 is received by the second receiver 320 of the optical communication module 300 . At this time, when the first transmission optical signal including the information on the third channel (0x03) includes information (0xFF) indicating that the information on the second channel (0x17) is not received, the second control unit 330 can clearly recognize that the second transmit optical signal transmitted through the second transmitter 310 has not yet passed through the second channel 410 of the second multiplexer/demultiplexer 400, and accordingly It is possible to postpone the transmission channel setting of the second optical communication module 300 to a later time. As a result, when the first transmission optical signal includes information (0xFF) indicating that the information (0x17) on the second channel has not been received, the transmission channel setting of the second optical communication module 300 is Accuracy can be improved.

Meanwhile, the second control unit 330 determines whether the first transmission optical signal including information (0x03) on the first channel 210 of the first multiplexer/demultiplexer 200 has been received by the second reception unit 320 . It can be monitored in real time.

As a result of the real-time monitoring by the second control unit 330 , when the first transmission optical signal including the information (0x03) on the first channel is received by the second reception unit 320 , the second control unit 330 controls the second By allowing the transmission unit 310 to transmit the second transmission optical signal including the information (0x03) on the first channel, the first control unit 130 can set the transmission channel of the first optical communication module 100 . .

When the second transmission unit 310 transmits a second transmission optical signal including information on the first channel (0x03) under the control of the second control unit 330 , information on the first channel (0x03) ) is received by the first receiver 120 through channel 23 of the second multiplexer/demultiplexer 400 and channel 23 of the first multiplexer/demultiplexer 200 . As such, when the second transmission optical signal including the information on the first channel (0x03) is received by the first receiving unit 120 , the first control unit 130 sets the transmission channel of the first transmitting unit 110 to the first transmission channel. It is set as a channel (that is, channel 3 of the first multiplexer/demultiplexer 200).

The first control unit 130 sets the transmission channel of the first transmission unit 110 to the first channel (ie, channel 3 of the first multiplexer/demultiplexer 200), and as described above, the second control unit ( When the 330 sets the transmission channel of the second transmitter 310 to the second channel (ie, channel 23 of the second multiplexer/demultiplexer 400), the first optical communication module 100 and the second optical communication A link is established between modules 300 .

When a link is established between the first optical communication module 100 and the second optical communication module 300 , the first optical communication module 100 and the second optical communication module 300 respectively stop the channel scan operation. Instead, the first transmitting unit 110 of the first optical communication module 100 and the second transmitting unit 310 of the second optical communication module 300 transmit a communication check command, respectively, and the first of the first optical communication module 100 The receiver 120 and the second receiver 320 of the second optical communication module receive the communication check command, respectively. The first control unit 130 checks whether there is an abnormality in the transmission/reception channel through the communication check command received from the first receiving unit 120 , and the second control unit 330 checks the communication check command received from the second receiving unit 320 . Through this, it is checked whether there is an abnormality in the transmission/reception channel, and if there is no abnormality as a result of checking by the first control unit 130 and the second control unit 330, the channel setting is terminated.

As a result of the real-time monitoring by the second control unit 330 , if the first transmission optical signal including the information about the first channel (0x03) is not received by the second reception unit 320 , or no first transmission optical signal If not received by the second receiver 320, the second controller 330 includes the information about the first channel in the second transmit optical signal that the second transmitter 310 transmits every second preset time. information indicating that the first transmission optical signal has not been received may be included.

Accordingly, in the above example, when the second transmitter 310 transmits the second transmit optical signal including information (0x04) on the fourth channel of the second multiplexer/demultiplexer 400, the fourth channel Information (0xFF) indicating that the information (0x03) on the first channel has not been received may be included in the second transmission optical signal including information (0x04) on . In addition, when the second transmission unit 310 transmits the second transmission optical signal including the information (0x05) on the 5th channel of the second multiplexer/demultiplexer 400, the information on the 5th channel (0x05) ) may include information (0xFF) indicating that the information (0x03) regarding the first channel has not been received.

As described above, among the second transmission optical signals transmitted by the second transmission unit 310 , the second transmission optical signal including information (0x17) on channel 23 of the second multiplexer/demultiplexer 400 is 1 is received by the first receiver 120 of the optical communication module 100 . At this time, when the second transmission optical signal including the information on the 23rd channel (0x17) includes information (0xFF) indicating that the information on the first channel (0x03) is not received, the first The control unit 130 can clearly recognize that the first transmission optical signal transmitted through the first transmission unit 110 has not yet passed through the first channel 210 of the first multiplexer/demultiplexer 200, and thus Accordingly, the setting of the transmission channel of the first optical communication module 100 can be delayed until later. As a result, when the second transmission optical signal includes information (0xFF) indicating that the information (0x03) on the first channel has not been received, the transmission channel setting of the first optical communication module 100 is Accuracy can be improved.

FIG. 3 is a diagram illustrating a case in which a first optical communication module is in an on state and a second optical communication module is in an off state in the optical communication system of FIG. 1 . More specifically, in FIG. 3 , the first optical communication module 100 is a state in which power is supplied from the first manager system 10 (ie, an on state), whereas the second optical communication module 300 is a second manager system It is a diagram illustrating a state in which power is not supplied from ( 30 ) (ie, an off state) or is not installed in the second manager system ( 30 ).

When the first optical communication module 100 receives power supply from the first manager system 10 , as described above, the first control unit 130 performs the first multiplexing/ The demultiplexer 200 transmits a first transmission optical signal including information about a first channel, which is information about any one of the plurality of first channels 210 provided in the demultiplexer 200 .

Specifically, the first transmission unit 110 sequentially from channel 1 to the max channel (eg, channel 40) under the control of the first control unit 130, or channel 1 to the max channel (eg, channel No. 40). , channel 40) randomly, the first transmission optical signal including information on each channel may be transmitted. Furthermore, under the control of the first controller 130 , the first transmission unit 110 may repeat the transmission of the first transmission optical signal from the first channel to the max channel 10 times. However, at this time, since the second optical communication module 300 is in an off state or not mounted in the second manager system 30 , the second receiver 320 cannot receive the information about the first channel, and accordingly The second transmitter 310 may not transmit the information about the first channel to the first receiver 120 .

That is, the first optical communication module 100 may repeatedly perform a scan operation on the plurality of first channels 210 to set its own transmission channel. However, when the second optical communication module 300 is in the off state or is not mounted in the second manager system 30 , the first optical communication module 100 cannot set its own transmission channel and is unnecessary It's just wasting power.

Accordingly, the first control unit 130 may control the first transmission unit 110 if the second transmission optical signal is not received by the first receiving unit 120 even when a predetermined time has elapsed from the time when the first transmission unit 110 starts to transmit the first transmission optical signal. , the first transmission unit 110 may stop the operation of transmitting the first transmission optical signal.

Specifically, when the second transmission optical signal received by the first receiving unit 120 does not exist when the predetermined time has elapsed, the first control unit 130 controls to stop the transmission operation of the first transmission optical signal. The command may be transmitted to the first transmitter 110 . Here, the predetermined time is a reference time for the first transmission unit 110 to stop the transmission operation of the first transmission optical signal, and may be preset in the first control unit 130 . When the first control unit 130 transmits the control command to the first transmission unit 110 , the first transmission unit 110 changes from the channel scan mode to the low power mode and stops the transmission operation of the first transmission optical signal. Accordingly, since unnecessary channel scan operation in the first transmitter 110 can be prevented, power consumption generated in the first optical communication module 100 can be reduced compared to the case of FIG. 2 .

Alternatively, the second optical communication module 300 may be in a state in which power is supplied from the second manager system 30 (ie, an on state), whereas the first optical communication module 100 may be in the first manager system 10 . .

When the second optical communication module 300 receives power supply from the second manager system 30 , as described above, the second control unit 330 causes the second transmitter 310 to perform a second multiplexing/ The demultiplexer 400 transmits a second transmission optical signal including information about a second channel, which is information about any one of the plurality of second channels 410 provided in the demultiplexer 400 .

Specifically, the second transmitter 310 sequentially from channel 1 to the max channel (eg, channel 40) under the control of the second control unit 330, or channel 1 to the max channel (eg, channel 40). , channel 40) randomly, the second transmission optical signal including information on each channel may be transmitted. Furthermore, under the control of the second control unit 330 , the second transmission unit 310 may repeat the transmission of the second transmission optical signal from the first channel to the max channel 10 times. However, at this time, since the first optical communication module 100 is in an off state or not mounted on the first manager system 10 , the first receiver 120 cannot receive the information about the second channel, and accordingly The first transmitter 110 may not transmit the information about the second channel to the second receiver 320 .

That is, the second optical communication module 300 may repeatedly perform a scan operation on the plurality of second channels 410 to set its own transmission channel. However, when the first optical communication module 100 is in the off state or is not mounted in the first manager system 10 , the second optical communication module 300 cannot set its own transmission channel and is unnecessary It's just wasting power.

Accordingly, the second control unit 330 may control the second transmission unit 310 if the first transmission optical signal is not received by the second reception unit 320 even when a predetermined time elapses from the time when the second transmission unit 310 starts to transmit the second transmission optical signal. , the second transmission unit 310 may stop the operation of transmitting the second transmission optical signal.

Specifically, when the first transmission optical signal received by the second receiving unit 320 does not exist when the predetermined time has elapsed, the second control unit 330 controls to stop the transmission operation of the second transmission optical signal. The command may be transmitted to the second transmitter 310 . Here, the predetermined time is a reference time for the second transmission unit 310 to stop the transmission operation of the second transmission optical signal, and may be preset in the second control unit 330 . When the second control unit 330 transmits the control command to the second transmission unit 310 , the second transmission unit 310 stops the transmission operation of the second transmission optical signal while changing from the channel scan mode to the low power mode. Accordingly, since unnecessary channel scan operation in the second transmitter 310 can be prevented, power consumption generated in the second optical communication module 300 can be reduced compared to the case of FIG. 2 .

FIG. 4 is a diagram illustrating a state in which the second optical communication module transmits the second transmission optical signal only after receiving the first transmission optical signal transmitted from the first optical communication module in the optical communication system of FIG. 1 .

As described above with respect to FIG. 2 , the first control unit 130 controls the first transmission unit 110 from among the plurality of first channels 210 provided in the first multiplexer/demultiplexer 200 for each first preset time. A first transmission optical signal including information about a first channel, which is information about one channel, is transmitted. In addition, the second control unit 330 is information about any one of the plurality of second channels 410 provided in the second multiplexer/demultiplexer 400 at every second preset time by the second transmitter 310 . A second transmission optical signal including information about the second channel is transmitted.

However, according to FIG. 4 , the second control unit 330 receives the first transmission optical signal including the information on the first channel by the second reception unit 320 (ie, the first multiplexer/demultiplexer 200 ). Only after information on channel 3 is 0x03), the second transmitter 310 controls to transmit the second transmit optical signal.

As shown in FIG. 2 , when the second optical communication module 300 receives power from the second manager system 30 (ie, in an on state), the second control unit 330 sends the second control unit 330 to the second receiver 320 . Regardless of whether the first transmission optical signal is received, the second transmission unit 310 may be controlled so that the second transmission unit 310 transmits the second transmission optical signal every second preset time.

However, as shown in FIG. 4 , the second control unit 330 controls the second transmission unit 310 only when the first transmission optical signal is received by the second reception unit 320 , and the second transmission unit 310 operates the second When the transmission optical signal is transmitted, the power consumption generated in the second optical communication module 300 can be reduced compared to the case of FIG. 2 . At this time, the second transmitter 310 is in the low power mode before the first transmit optical signal is received by the second receiver 320, and is changed to the channel scan mode when the first transmit optical signal is received by the second receiver 320. The second transmission optical signal is transmitted every second preset time.

Meanwhile, in the first control unit 130 , the first transmission unit 110 transmits the first transmission optical signal only after the second transmission optical signal including the information on the second channel is received by the first reception unit 120 . It can also be controlled to transmit.

As shown in FIG. 2 , when the first optical communication module 100 receives power from the first manager system 10 (that is, in the on state), the first control unit 130 sends 2 Regardless of whether the transmission optical signal is received, the first transmission unit 110 may be controlled so that the first transmission unit 110 transmits the first transmission optical signal.

However, the first control unit 130 controls the first transmission unit 110 only when the second transmission optical signal is received by the first reception unit 120 , and the first transmission unit 110 transmits the first transmission optical signal. In this case, it is possible to reduce power consumption generated in the first optical communication module 100 compared to the case of FIG. 2 . At this time, the first transmission unit 110 is in the low power mode before the second transmission optical signal is received by the first reception unit 120 , and is switched to the channel scan mode when the second transmission optical signal is received by the first reception unit 120 . One transmission optical signal is transmitted every first preset time.

FIG. 5 is a diagram illustrating an optical signal through which a first optical communication module and a second optical communication module communicate when the optical communication system of FIG. 1 operates in a one-way automatic channel setting mode. Hereinafter, a state when the optical communication system 1000 shown in FIG. 1 operates in a one-way automatic channel setting mode will be described with reference to FIG. 5 .

The unidirectional automatic channel setting mode shown in FIG. 5 differs from the bidirectional automatic channel setting mode shown in FIG. 2 , in which only the first transmitter 110 of the first optical communication module 100 is provided in the first multiplexer/demultiplexer 200 . Scans the first channel 210 as a first transmit optical signal, and the second transmitter 310 of the second optical communication module 300 includes a plurality of second channels provided in the second multiplexer/demultiplexer 400 . It is a mode that does not scan for 410 .

5 shows that the first transmitter 110 of the first optical communication module 100 is connected to the third channel of the first multiplexer/demultiplexer 200, and the first receiver 120 is connected to the first multiplexer/demultiplexer 200. ) is connected to channel 4 by way of example. 5 shows that the second transmitter 310 of the second optical communication module 300 is connected to channel 4 of the second multiplexer/demultiplexer 400, and the second receiver 320 is connected to the second multiplexer/demultiplexer 400. A state connected to channel 3 of 400 is shown as an example.

As described above with respect to FIG. 2 , even in the unidirectional automatic channel setting mode shown in FIG. 5 , the first control unit 130 includes a plurality of first transmission units 110 provided in the first multiplexer/demultiplexer 200 . A scan is performed for the channel 210 . For example, the first transmitter 110 transmits, under the control of the first controller 130, information (0x01) on the first channel provided in the first multiplexer/demultiplexer 200 at a specific time t ₁ second. The included first transmission optical signal may be transmitted to the second optical communication module 300 . Also, under the control of the first controller 130 , the first transmitter 110 includes the first channel 2 information (0x02) of the first multiplexer/demultiplexer 200 at t ₁ +1 second. The transmission optical signal may be transmitted to the second optical communication module 300 . In addition, under the control of the first controller 130 , the first transmitter 110 includes the first channel 3 information (0x03) of the first multiplexer/demultiplexer 200 at t ₁ +2 seconds. The transmission optical signal may be transmitted to the second optical communication module 300 .

As such, the first control unit 130 controls the first multiplexer/demultiplexer 200 for each first preset time (t ₁ second, t ₁ +1 second, t ₁ +2 second, etc.) A first transmission optical signal including information about a first channel (0x01, 0x02, 0x03, etc.) that is information about any one of the plurality of first channels 210 provided in the second optical communication module 300 to send

Here, among the information about the first channel (0x01, 0x02, 0x03, etc.), the information about the first channel (0x03) may relate to a wavelength that can pass through the first channel 210 . In addition, in the present invention, the first preset time is not limited to the above example, and the user of the first optical communication module 100 may set it arbitrarily in the first control unit 130 .

Referring to FIG. 5 , among the plurality of first transmission optical signals transmitted by the first transmission unit 110 , the first transmission optical signal including information (0x03) on the third channel of the first multiplexer/demultiplexer 200 (0x03) only is received by the second receiver 320 through channel 3 of the second multiplexer/demultiplexer 400 . In this case, the second control unit 330 knows that the reception channel of the second optical communication module 300 is channel 3 and that the transmission channel of the first optical communication module 100 is channel 3. Accordingly, the second control unit 330 may set the receiving channel of the second receiving unit 320 as the third channel of the second multiplexer/demultiplexer 400 . Also, as described later, the second controller 330 may notify the first controller 130 that the transmission channel of the first optical communication module 100 is the third channel of the first multiplexer/demultiplexer 200 .

The second control unit 330 determines in real time whether the first transmission optical signal including the information (0x03) on the first channel 210 of the first multiplexer/demultiplexer 200 has been received by the second reception unit 320 . can be monitored.

As a result of monitoring by the second control unit 320 in real time, when the first transmission optical signal including information (0x03) on the first channel 210 is received by the second reception unit 320 , the second control unit 320 . may set the transmission channel of the second transmitter 310 by using a pre-stored channel rule and information on the first channel.

For example, when the second control unit 320 knows the transmission channel of the first optical communication module 100 , the second optical communication module 300 adds a channel to the transmission channel of the first optical communication module 100 plus one channel. ) may be pre-stored in a channel protocol to set as a transmission channel of Accordingly, when the first transmission optical signal including the information (0x03) on the first channel 210 is received by the second reception unit 320 , the second control unit 320 controls the first optical communication module 100 of the first optical communication module 100 . It is recognized that the transmission channel is the 3rd channel, and at the same time, it is recognized that the 4th channel, which is a channel obtained by adding the 1st channel to the 3rd channel, is the transmission channel of the second optical communication module 300 . In this case, the second control unit 320 sets the transmission channel of the second transmission unit 310 as channel 4, so that the second transmission unit 310 provides a plurality of second channels provided in the second multiplexer/demultiplexer 400 . In 410, an optical signal having a wavelength corresponding to channel 4 may be transmitted as a second transmission optical signal.

In addition, as a result of the real-time monitoring by the second control unit 320, when the first transmission optical signal including the information (0x03) on the first channel 210 is received by the second reception unit 320, the second control unit ( 320 allows the second transmission unit 310 to transmit the first transmission optical signal including the information (0x03) on the first channel 210, so that the first control unit 130 controls the first optical communication module 100 Allows you to set the transmission channel of

When the second transmission unit 310 transmits a second transmission optical signal including information on the first channel (0x03) under the control of the second control unit 330 , information on the first channel (0x03) ) is received by the first receiver 120 through channel 4 of the second multiplexer/demultiplexer 400 and channel 4 of the first multiplexer/demultiplexer 200 . As such, when the second transmission optical signal including the information on the first channel (0x03) is received by the first receiving unit 120 , the first control unit 130 sets the transmission channel of the first transmitting unit 110 to the first transmission channel. It is set as a channel (that is, channel 3 of the first multiplexer/demultiplexer 200).

The first control unit 130 sets the transmission channel of the first transmission unit 110 to the first channel (ie, channel 3 of the first multiplexer/demultiplexer 200), and as described above, the second control unit ( When the 330 sets the transmission channel of the second transmitter 310 to the second channel (ie, channel 4 of the second multiplexer/demultiplexer 400), the first optical communication module 100 and the second optical communication A link is established between modules 300 .

When a link is established between the first optical communication module 100 and the second optical communication module 300 , the first optical communication module 100 stops the channel scan operation. Instead, the first transmitting unit 110 of the first optical communication module 100 and the second transmitting unit 310 of the second optical communication module 300 transmit a communication check command, respectively, and the first of the first optical communication module 100 The receiver 120 and the second receiver 320 of the second optical communication module receive the communication check command, respectively. The first control unit 130 checks whether there is an abnormality in the transmission/reception channel through the communication check command received from the first receiving unit 120 , and the second control unit 330 checks the communication check command received from the second receiving unit 320 . Through this, it is checked whether there is an abnormality in the transmission/reception channel, and if there is no abnormality as a result of checking by the first control unit 130 and the second control unit 330, the channel setting is terminated.

In the two-way automatic channel setting mode according to FIG. 2 , as a result of real-time monitoring by the second control unit 330 , the first transmission optical signal including the information (0x03) on the first channel is transmitted to the second receiving unit 320 . If not received, the second control unit 330 may not receive the first transmission optical signal including information about the first channel in the second transmission optical signal transmitted by the second transmission unit 310 every second preset time. It was explained that it could include information to the effect that it did not. However, since the unidirectional automatic channel setting mode according to FIG. 5 is a mode in which the second transmitter 310 does not scan the plurality of second channels 410 provided in the second multiplexer/demultiplexer 400, the first It is not necessary to include information to the effect that the first transmission optical signal including information about one channel has not been received in the second transmission optical signal.

In comparison with the bidirectional automatic channel setting mode according to FIG. 2 , according to the one-way automatic channel setting mode according to FIG. 5 , the second optical communication module 300 does not necessarily perform a channel scan operation by the second transmitter 310 . Since the transmission channel of the 310 can be set, power consumption generated in the second optical communication module 300 can be reduced compared to the case of FIG. 2 , and the transmission channel of the second transmitter 310 is also more rapidly can be set.

As described above, although the present invention has been described with reference to the limited embodiments and drawings, the present invention is not limited to the above embodiments, which are various modifications and Transformation is possible. Accordingly, the technical spirit of the present invention should be understood only by the claims, and all equivalents or equivalent modifications thereof will fall within the scope of the technical spirit of the present invention.

10: first manager system 30: second manager system
100: first optical communication module 110: first transmitter
120: first receiving unit 130: first control unit
140: first AMCC signal processing unit 200: first multiplexer/demultiplexer
210: first channel 220: first access port
300: second optical communication module 310: second transmitter
320: second receiving unit 330: second control unit
340: second AMCC signal processing unit 400: second multiplexer/demultiplexer
410: second channel 420: second access port
500: optical fiber 1000: optical communication system

Claims (17)

a first optical communication module including a first transmitter, a first receiver, and a first controller communicatively connected to the first transmitter and the first receiver;
a first multiplexer/demultiplexer disposed outside the first optical communication module and having a plurality of first channels connectable to the first transmitter and the first receiver;
a second optical communication module including a second transmitter, a second receiver, and a second controller communicatively connected to the second transmitter and the second receiver;
a second multiplexer/demultiplexer disposed outside the second optical communication module and having a plurality of second channels connectable to the second transmitter and the second receiver; and
and an optical fiber communicatively connecting the first multiplexer/demultiplexer and the second multiplexer/demultiplexer,
The first control unit, wherein the first transmission unit transmits a first transmission optical signal including information about a first channel, which is information about any one of the plurality of first channels, at a first preset time, the first transmission optical signal including information on the second optical communication to send to the module,
The second control unit may include, when the first transmission optical signal including information on the first channel is received by the second receiver, a second transmission optical signal by the second transmission unit including information on the first channel to transmit to the first optical communication module,
The first control unit is configured to set a transmission channel of the first transmission unit to the first channel when the second transmission optical signal including information about the first channel is received by the first reception unit system.
According to claim 1,
The second control unit, wherein the second transmission unit transmits the second transmission optical signal including information about a second channel, which is information about any one of the plurality of second channels, every second preset time to the first to transmit to the optical communication module,
The first control unit may include, when the second transmission optical signal including information on the second channel is received by the first receiver, the first transmission unit includes the first transmission light including information on the second channel to transmit a signal to the second optical communication module,
The second control unit sets the transmission channel of the second transmission unit as the second channel when the first transmission optical signal including information about the second channel is received by the second reception unit. system.
3. The method of claim 2,
The first control unit,
If the second transmission optical signal including information on the second channel is not received by the first receiver,
In the first transmission optical signal transmitted by the first transmission unit at the first preset time interval, information to the effect that the second transmission optical signal including information on the second channel is not received is included. optical communication system.
3. The method of claim 2,
The second control unit,
If the first transmit optical signal including information on the first channel is not received by the second receiver,
In the second transmission optical signal transmitted by the second transmission unit every second preset time, information indicating that the first transmission optical signal including information on the first channel has not been received is included. optical communication system.
According to claim 1,
The first control unit,
If the second transmit optical signal is not received by the first receiver until a predetermined time elapses from the time when the first transmitter starts transmitting the first transmit optical signal,
The optical communication system according to claim 1, wherein the first transmitter stops the operation of transmitting the first transmit optical signal.
3. The method of claim 2,
The second control unit,
and the second transmission unit transmits the second transmission optical signal only after the first transmission optical signal including the information on the first channel is received by the second reception unit.
According to claim 1,
The second control unit,
When the first transmission optical signal including information on the first channel is received by the second receiver, setting a transmission channel of the second transmitter using a pre-stored channel convention and information on the first channel Characterized by an optical communication system.
According to claim 1,
The first optical communication module further comprises a first AMCC signal processing unit for processing the first transmission optical signal transmitted from the first transmission unit as a first Auxiliary Management and Control Channel (AMCC) signal under the control of the first control unit, ,
The second optical communication module further includes a second AMCC signal processing unit that processes the second transmission optical signal transmitted from the second transmission unit as a second AMCC signal under the control of the second control unit.
a transmission unit for transmitting a transmission optical signal;
a receiver for receiving an external transmission optical signal transmitted from an external optical communication module; and
and a control unit communicatively connected to the transmitting unit and the receiving unit,
The control unit is
The transmitting unit transmits the transmission optical signal including information on the first channel to the external optical communication module every preset time, and the external transmission optical signal including information on the first channel from the external optical communication module When received by the receiver, the optical communication module, characterized in that for setting the transmission channel of the transmitter to the first channel.
10. The method of claim 9,
The control unit is
When the external transmission optical signal including information on the second channel is received from the external optical communication module, the transmitter transmits the transmission optical signal including information on the second channel to the external optical communication module Optical communication module, characterized in that.
11. The method of claim 10,
The control unit is
If the external transmission optical signal including information on the second channel is not received by the receiver,
and information indicating that the external transmission optical signal including information on the second channel has not been received is included in the transmission optical signal transmitted by the transmission unit at the predetermined time interval.
10. The method of claim 9,
The control unit is
If the external transmission optical signal is not received by the receiver until a predetermined time elapses from the time when the transmitter starts transmitting the optical signal,
The optical communication module, characterized in that the transmission unit stops the operation of transmitting the transmission optical signal.
10. The method of claim 9,
The optical communication module further comprising an AMCC signal processing unit for processing the transmission optical signal transmitted from the transmission unit as an AMCC signal under the control of the control unit.
a transmission unit for transmitting a transmission optical signal;
a receiver for receiving an external transmission optical signal transmitted from an external optical communication module; and
and a control unit communicatively connected to the transmitting unit and the receiving unit,
The control unit is
When the external transmission optical signal including information about the first channel is received from the external optical communication module, the transmitter transmits the transmission optical signal including information about the first channel to the external optical communication module Optical communication module, characterized in that.
15. The method of claim 14,
The control unit is
The transmitting unit transmits the transmit optical signal including information on the second channel every preset time,
The optical communication module according to claim 1, wherein the transmitter transmits the transmit optical signal only after the external transmit optical signal including the information on the first channel is received by the receiver.
15. The method of claim 14,
The control unit is
When the external transmission optical signal including information about the first channel is received from the external optical communication module, the transmission channel of the transmitter is set by using a pre-stored channel convention and information about the first channel Optical communication module characterized.
15. The method of claim 14,
The optical communication module further comprising an AMCC signal processing unit for processing the transmission optical signal transmitted from the transmission unit as an AMCC signal under the control of the control unit.

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