KR20140123712A - Apparatus for optical communication, protection switching method of the same - Google Patents

Abstract

An optical communication apparatus is mounted to a first node among a plurality of nodes in a linear multicast network where the nodes are connected to each other linearly. The optical communication apparatus includes: a first extraction passage module which extracts at least a portion of a first operating signal, and passes a signal to retransmit in the first operating signal; a second extraction passage module which extracts at least a portion of an inputted first preliminary signal, and passes a signal to retransmit in the first preliminary signal; and a first optical switch which selects one of the first and second extraction passage modules, and outputs a signal extracted by the selected extraction passage module, wherein the first operating signal and the first preliminary signal are signals that are separated and transmitted from a second node adjacent to the first node.

Description

FIELD OF THE INVENTION [0001] The present invention relates to an optical communication apparatus,

The present invention relates to an optical communication device and a protection switching method thereof.

Referring to FIG. 1, a ring add-drop multiplex (ADM) network is the same as a 1 + 1 optical channel protection switch in a point-to-point network structure. The ring ADM network uses two rings divided into operating ring and preliminary ring. The ring ADM network performs unidirectional protection switching at the receiving end. Therefore, the ring ADM network uses a protection switching method in which a signal transmitted from a preliminary ring in the opposite direction is received when a failure occurs in one operating ring. Among the uniform route method and the diverse route method, which is a traffic signal operating method, the ring ADM network transmits a traffic signal in a diverse path mode.

However, in a linear multicasting network, since a node is linearly connected unlike a ring ADM network, a protection switching method suitable for a linear multicasting network is required.

An object of the present invention is to provide an optical communication device and a protection switching method therefor.

An optical communication apparatus mounted on a first node among a plurality of nodes in a linear multicast network in which a plurality of nodes are linearly connected according to an embodiment of the present invention is characterized by extracting at least some of the input first operating signals, A second extraction module that extracts at least some of the input first preliminary signals and passes a signal to be retransmitted among the first preliminary signals, And a first optical switch for selecting one of the first extraction pass module and the second extraction pass module and outputting a signal extracted from the selected extraction pass module, wherein the first operation signal and the first preliminary signal are And is a signal transmitted separately from a second node which is a neighbor node of the first node.

And a demultiplexer for demultiplexing the signal output from the first optical switch.

The optical communication apparatus includes a third extraction module for extracting at least some of the input second operating signals and for passing a signal to be retransmitted among the second operational signals, A fourth extraction module for passing a signal to be retransmitted among the second preliminary signals and a third extraction module for selecting one of the third extraction module and the fourth extraction module and outputting a signal extracted from the selected extraction module And the second operation signal and the second preliminary signal may be a signal transmitted separately from a third node which is a neighbor node of the first node.

The optical communication apparatus may further include an optical coupler for coupling the signal output from the first optical switch and the signal output from the second optical switch, and a demultiplexer for demultiplexing the signal output from the optical coupler.

The optical communication device includes a multiplexer for receiving at least one signal, a first optical coupler for separating the signal output from the multiplexer into a plurality of identical signals, a first optical coupler for separating the first signal separated from the first optical coupler, A second optocoupler coupling the signal passed in the pass module and a third optocoupler coupling the second signal separated from the first optocoupler and the signal passed in the second optocoupler module .

The optical communication device includes a third extraction module for extracting at least some of the input second operating signals and for passing a signal to be retransmitted among the second operating signals, A fourth opto-coupler for coupling signals passed by the third pass-through module, a fourth pass-through module for extracting at least some of the input second preliminary signals and for passing a signal to be retransmitted among the second preliminary signals, Further comprising a fifth optical coupler for coupling a fourth signal separated by the first optical coupler and a signal passed by the fourth extracting and passing module, wherein the second operation signal and the second preliminary signal are transmitted to the first node And may be a signal transmitted separately from a third node which is a neighbor node.

Each of the first extraction module and the second extraction module may extract an input signal to be separated into an overall signal, a channel, or a signal to be transmitted to the first optical switch.

In a linear multicast network in which a plurality of nodes are linearly connected according to another embodiment of the present invention, a protection switching method for an optical communication device mounted on a first one of the plurality of nodes, Extracting at least some of the input first preliminary signals as a second extracted signal, and selecting any one of the first extracted signal and the second extracted signal, Wherein the first operation signal and the first preliminary signal are signals transmitted separately from a second node which is a neighbor node of the first node.

The outputting of the first output signal may select a normal extraction signal when any one of the first extraction signal and the second extraction signal is abnormal.

The step of outputting as the first output signal may select the second extracted signal when the operating signal line transmitting the first operating signal has a fault.

The protection switching method may further include demultiplexing the first output signal.

The protection switching method includes the steps of extracting at least some of the input second operating signals as a third extraction signal, extracting at least some of the input second preliminary signals as a fourth extraction signal, Signal and the fourth extracted signal and outputting the selected extracted signal as a second output signal, wherein the second operation signal and the second preliminary signal are transmitted to a neighboring node May be a signal transmitted separately from the third node.

The protection switching method may further comprise combining the first output signal and the second output signal, and demultiplexing the combined signal.

According to the embodiment of the present invention, it is possible to efficiently configure a method for protecting and switching optical signals in a linear multicast network, thereby reducing capex and oppexes.

According to the embodiment of the present invention, since the optical path is doubled and used stably, a desired wavelength can be stably extracted and used. According to the embodiment of the present invention, the extraction node extracts the partial or total optical signal of the operation signal and the preliminary signal, and can use the extracted optical signal by using the switch as needed. According to the embodiment of the present invention, the coupling signal can be divided using the optical coupler and inserted into the working line and the spare line. According to the embodiment of the present invention, it is possible to pass a signal intact in the form of an optical signal without electro-optical conversion, and to block a signal sent from a front node using a blocking filter. Therefore, according to the embodiment of the present invention, the system structure is simple, and the multicast optical signal can be protected and switched.

According to the embodiment of the present invention, the service provided by the region through the insertion / extraction node can be served to other regions. By using the protection switching method according to the embodiment of the present invention, the optical signal received from the linear node can be stably operated, and the optical signal sent from all other nodes can be usefully used.

1 is a view for explaining a ring-type insertion extraction multiplex.
2 is a block diagram of a linear multicasting network according to an embodiment of the present invention.
3 is a flowchart of a signal input method according to an embodiment of the present invention.
4 is a flowchart of a protection switching method according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Throughout the specification, when an element is referred to as "comprising ", it means that it can include other elements as well, without excluding other elements unless specifically stated otherwise.

Now, an optical communication device according to an embodiment of the present invention and a protection switching method thereof will be described in detail with reference to the drawings.

2 is a block diagram of a linear multicasting network according to an embodiment of the present invention.

Referring to FIG. 2, the linear multicasting network 10 multicasts a multi-wavelength optical signal. Here, multicasting is a method of transmitting information from one input node to a plurality of destination nodes.

At this time, the linear multicasting network 10 is capable of inputting and outputting from all the nodes 100, 200, 300, 400, and 500 so as to enable bidirectional multicasting. However, the embodiment of the present invention will be described as including three transfer nodes 200, 300, and 400 between two input / output nodes 100 and 500 for convenience. Here, the transfer node is not limited to three, and one or more transfer nodes may be included.

The linear multicasting network 10 transmits the same signal to the working signal (W) line and the protection signal (P) line. Accordingly, the linear multicasting network 10 can select either the working signal line W or the spare signal line P to output a signal. Therefore, when a fault occurs in any one of the lines, for example, the operating signal line, the linear multicasting network 10 performs protection switching to the spare signal line instead of the operating signal line. In this way, the linear multicasting network 10 can reliably output a signal even if a failure occurs.

The input / output nodes 100 and 500 are nodes for inputting and outputting a multi-wavelength optical signal.

The forwarding nodes 200, 300, and 400 forward the multi-wavelength optical signal to the next node. Also, the transfer nodes 200, 300, and 400 can input new optical signals and output the transmitted signals. The transfer nodes 200, 300, and 400 transmit multi-wavelength optical signals in both directions.

Here, the first I / O node 100 and the first transfer node 200, the second transfer node 300 and the third transfer node 400, the third transfer node 400 and the second I / And transmits and receives a multi-wavelength optical signal through an optical transmission line (not shown).

The specific configuration of each node is as follows.

The optical communication device of the first input / output node 100 includes a multiplexer (MUX) 101, an optical coupler 103, an operating amplifier (optical amplifier) 105, And a signal amplifier 107.

The multiplexer 101 receives a plurality of signals having different wavelengths and outputs a multi-wavelength optical signal. The optical coupler 103 separates a signal output from the multiplexer 101 into an operation signal and a preliminary signal and transmits the separated signal to the amplifiers 105 and 107. The amplifiers 105 and 107 amplify the input signal and output the amplified signal to the first transmission node 200.

The optical communication apparatus of the first input / output node 100 includes a demultiplexer (DEMUX) 111, an optical switch 113, an operational signal amplifier 115 and a preliminary signal amplifier 117 ). The amplifiers 115 and 117 amplify the signals transmitted from the first transmission node 200 and transmit the amplified signals to the optical switch 113. The optical switch 113 selects either the operating signal line or the spare signal line and transmits the selected signal to the demultiplexer 111. The demultiplexer 111 demultiplexes a plurality of multi-wavelength optical signals transmitted from the optical switch 113 into different channels according to wavelengths and outputs the multi-wavelength optical signals.

The optical communication device of the first forwarding node 200 includes an optical amplifier 201, a drop and continue module 203, an optical coupler 205, , And an optical amplifier (207). The optical communication device of the first transmission node 200 includes an optical amplifier 211, an extraction pass module 213, an optical coupler 215, an optical amplifier 217, . The first forwarding node 200 includes an optical amplifier 221, an extracting pass-through module 223, an optical coupler 225, and an optical amplifier 227 to transmit an operation signal to the first input / output node 100 . The optical communication device of the first transmission node 200 includes an optical amplifier 231, an extraction pass-through module 233, an optical coupler 235, an optical amplifier 237, . The optical communication device of the first transmission node 200 includes a multiplexer 241 and an optical coupler 243 for signal input. The optical communication device of the first transmission node 200 includes optical switches 251 and 253, an optocoupler 255 and a demultiplexer 257 for signal output.

Each of the optical amplifiers 201, 207, 211, 217, 221, 227, 231, 237 amplifies and outputs an input signal. The optical amplifier can compensate for the reduced signal in extracting / passing and channel combining optical signal channels, and compensating for the reduced signal in long distance transmission.

The extraction pass-through modules 203, 213, 223 and 233 separate the multi-wavelength optical signals output from the corresponding optical amplifiers 201, 211, 221 and 231 on a per-channel, .

The optical switch 251 selects one of the operation signal and the preliminary signal extracted from the extraction pass modules 203 and 213 and transmits the selected signal to the optical coupler 255. The optical switch 253 selects one of the operation signal and the preliminary signal extracted from the extraction pass modules 223 and 233 and transmits the selected signal to the optical coupler 255. The optical coupler 255 combines the output signals of the optical switch 251 and the optical switch 253 and outputs the combined signal to the demultiplexer 257. The demultiplexer 257 demultiplexes the multi-wavelength optical signals output from the optical coupler 255 into different channels according to wavelengths and outputs the multi-wavelength optical signals.

The multiplexer 241 receives a plurality of wavelengths and outputs a multi-wavelength optical signal. The optical coupler 243 branches the multi-wavelength optical signal output from the multiplexer 241 to the optical couplers 205, 215, 225, and 235. Each of the optical couplers 205, 215, 225, and 235 combines a signal transmitted from the corresponding extraction pass module 203, 213, 223, or 233 and a signal transmitted from the optical coupler 243.

With this configuration, the first forwarding node 200 can forward or output signals transmitted from the first input / output node 100 and the second forwarding node 300 to the next node. The first forwarding node 200 may forward the signal input from the first forwarding node 200 to the first input / output node 100 and the second forwarding node 300. The first transmission node 200 can perform protection switching by selecting the operation signal and the preliminary signal using the optical switches 251 and 253. [

The second forwarding node 300 includes the same node configuration as the first forwarding node 200. The optical communication device of the second transmission node 300 includes an optical amplifier 301, an extraction pass module 303, an optical coupler 305, an optical amplifier 307, . The optical communication device of the second transmission node 300 includes an optical amplifier 311, an extraction pass module 313, an optical coupler 315, an optical amplifier 317, . The optical communication device of the second transmission node 300 includes an optical amplifier 321, an extraction pass-through module 323, an optical coupler 325, an optical amplifier 327, . The optical communication device of the second transmission node 300 includes an optical amplifier 331, an extraction pass module 333, an optical coupler 335, an optical amplifier 337, . The optical communication device of the second transmission node 300 includes a multiplexer 341 and an optical coupler 343 for signal input. The second forwarding node 300 includes optical switches 351 and 353, an optocoupler 355 and a demultiplexer 357 for signal output.

With this configuration, the second forwarding node 300 can forward or output signals transmitted from the first forwarding node 200 and the third forwarding node 400 to the next node. The second forwarding node 300 may forward the signals input from the second forwarding node 300 to the first forwarding node 200 and the third forwarding node 400. The second transmission node 300 can perform protection switching by selecting the operation signal and the preliminary signal using the optical switches 351 and 353. [

The third forwarding node 400 includes the same node configuration as the first forwarding node 200. The optical communication device of the third transmission node 400 includes an optical amplifier 401, an extraction pass module 403, an optical coupler 405, an optical amplifier 407, . The optical communication device of the third transmission node 400 includes an optical amplifier 411, an extraction pass module 413, an optical coupler 415, an optical amplifier 417, . The optical communication device of the third transmission node 400 includes an optical amplifier 421, an extraction pass-through module 423, an optical coupler 425, an optical amplifier 427, . The optical communication device of the third transmission node 400 includes an optical amplifier 431, an extraction pass-through module 433, an optical coupler 435, an optical amplifier 437, . The optical communication device of the third transmitting node 400 includes a multiplexer 441 and an optical coupler 443 for signal input. The optical communication device of the third transmitting node 400 includes optical switches 451 and 453, an optical coupler 455 and a demultiplexer 457 for signal output.

With this configuration, the third forwarding node 400 can forward or output signals transmitted from the second forwarding node 300 and the second input / output node 500 to the next node. The third transfer node 400 may transfer the signal input from the third transfer node 400 to the second transfer node 300 and the second input / output node 500. The third transmitting node 400 can perform protection switching by selecting the operation signal and the preliminary signal using the optical switches 451 and 453. [

The second input / output node 500 includes the same node configuration as the first input / output node 100. The optical communication device of the second input / output node 500 includes a multiplexer 501, an optical coupler 503, an operation signal amplifier 505, and a preliminary signal amplifier 507 related to signal input.

 The optical communication device of the second input / output node 500 includes a demultiplexer 511, an optical switch 513, an operation signal amplifier 515, and a preliminary signal amplifier 517 related to signal output.

As described above, the forwarding nodes 200, 300, and 400 can multicast optical signals in both directions. The transfer nodes 200, 300, and 400 are connected to the multi-wavelengths received from the neighbor nodes using the extraction pass modules 203, 213, 223, 233, 303, 313, 323, 333, 403, 413, 423, And extracts and passes the optical signal. At this time, the extraction pass modules 203, 213, 223, 233, 303, 313, 323, 333, 403, 413, 423 and 433 can perform overall signal separation, band separation, and channel separation. The pass-through modules 203, 213, 223, 233, 303, 313, 323, 333, 403, 413, 423 and 433 can pass or extract only a specific band of optical signals using a band pass filter . In other words, each forwarding node extracts the optical signal by each channel and band according to the position of the demultiplexer, switch and filter, and sends the optical signal to the node of the lower network or the node of the other network, if necessary, have.

The forwarding nodes 200-400 can input a new signal to the linear multicasting network 10 using the multiplexers 241, 341 and 441 and the optical couplers 243, 343 and 443.

The forwarding nodes 200-400 are connected to the forwarding node 200-400 using the optical switches 251,253, 351,353, 451,453, optocouplers 255,355, 455 and demultiplexers 257,357, And a protection signal can be selected. Therefore, the linear multicast network 10 transmits the operation signal and the preliminary signal, and can select one of the operation signal and the preliminary signal according to the state of the line, and perform protection switching. Therefore, the linear multicast network 10 operates stably even if the line fails.

Conventional linear network nodes require as many transmitters as the number of channels received at the node to retransmit. However, the linear multicast network 10 does not send all the received channels again, but only the necessary channels can be sent using the transmitter. That is, the linear multicast network 10 can transmit only necessary channels to the neighboring node directly or by using a transmitter without using a transmitter for the entire number of extracted channels.

The linear multicasting network 10 may also be useful for broadcasting an optical signal. Also, the proposed protection switching method can be applied not only to OTS (line part) protection switching, but also to OCH (channel) protection switching and OMS (multi center) protection switching depending on the network configuration method.

Next, the operation of the optical communication device mounted on the transfer nodes 200-400 will be described. The operation of the forwarding node 200 will be briefly described.

3 is a flowchart of a signal input method according to an embodiment of the present invention.

Referring to FIG. 3, the forwarding node 200 receives a signal to be transmitted to the linear multicasting network 10 (S110). At this time, the transfer node 200 receives a signal from the multiplexer 241.

The forwarding node 200 separates the input signal into a plurality of input signals (S120). The forwarding node 200 separates the output signal of the multiplexer 241 into a plurality of identical signals using an optical coupler 243.

The transfer node 200 transfers each of the separated input signals to the operation signal line and the preliminary signal line (S130).

The forwarding node 200 filters the pass-through signal to be retransmitted to the next node among the signals transmitted from the previous node by using the extraction pass-through modules 203, 213, 223, and 233 of the operational signal line and the preliminary signal line (S140) .

The transfer node 200 combines the pass signal and the input signal using the optical couplers 205, 215, 225, and 235 of each line, and outputs the combined signal (S150).

4 is a flowchart of a protection switching method according to an embodiment of the present invention.

4, the forwarding node 200 extracts signals to be output from the signals transmitted from the previous node by using the extraction pass-through modules 203, 213, 223, and 233 of the respective operation signal lines and the preliminary signal line S210).

The forwarding node 200 selects one of the operation signal and the preliminary signal extracted from the extraction pass-through modules 223 and 233 (S220). The forwarding node 200 selects using the optical switches 251 and 253. For example, the forwarding node 200 may select a spare signal line when a failure occurs in the operating signal line. Thereby, the transfer node 200 performs the protection switching to the spare signal line. Particularly, when a fault occurs in a certain line, for example, a working signal line, there may be a problem in the signal extracted from the extraction passing module 223. Then, the transfer node 200 can use the optical switch 251 to select the signal extracted from the extraction pass module 233 of the preliminary signal line, and perform protection switching.

The forwarding node 200 combines all extracted signals selected by the optical switches 251 and 253 using the optical coupler 255 (S230).

The forwarding node 200 demultiplexes the combined extracted signal using the demultiplexer 257 (S240).

As described above, according to the embodiment of the present invention, since the optical path is doubled and used stably, a desired wavelength can be stably extracted and used. According to the embodiment of the present invention, the extraction node extracts the partial or total optical signal of the operation signal and the preliminary signal, and can use the extracted optical signal by using the switch as needed. According to the embodiment of the present invention, the coupling signal can be divided using the optical coupler and inserted into the working line and the spare line. According to the embodiment of the present invention, it is possible to pass a signal intact in the form of an optical signal without electro-optical conversion, and to block a signal sent from a front node using a blocking filter. Therefore, according to the embodiment of the present invention, the system structure is simple, and the multicast optical signal can be protected and switched.

According to the embodiment of the present invention, the service provided by the region through the insertion / extraction node can be served to other regions. By using the protection switching method according to the embodiment of the present invention, the optical signal received from the linear node can be stably operated, and the optical signal sent from all other nodes can be usefully used.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

Claims (13)

1. An optical communication device mounted on a first one of the plurality of nodes in a linear multicast network in which a plurality of nodes are linearly connected,
A first extraction module for extracting at least some of the inputted first operation signals and for passing a signal to be retransmitted among the first operation signals,
A second extraction module for extracting at least some of the input first preliminary signals and for passing a signal to be retransmitted among the first preliminary signals,
And a first optical switch for selecting one of the first extraction module and the second extraction module and outputting a signal extracted from the selected extraction module,
Wherein the first operation signal and the first preliminary signal are signals separated from a second node which is a neighbor node of the first node. The method of claim 1,
A demultiplexer for demultiplexing a signal output from the first optical switch,
Further comprising: The method of claim 1,
A third extraction module for extracting at least some of the inputted second operation signals and for passing a signal to be retransmitted among the second operation signals,
A fourth extraction module that extracts at least some of the input second preliminary signals and passes a signal to be retransmitted among the second preliminary signals,
Further comprising a second optical switch for selecting any one of the third extraction module and the fourth extraction module and outputting a signal extracted from the selected extraction module,
Wherein the second operation signal and the second preliminary signal are signals separated from a third node which is a neighbor node of the first node. 4. The method of claim 3,
An optical coupler for coupling a signal output from the first optical switch and a signal output from the second optical switch, and
A demultiplexer for demultiplexing a signal output from the optical coupler,
Further comprising: The method of claim 1,
A multiplexer for receiving at least one signal,
A first optical coupler for separating signals output from the multiplexer into a plurality of identical signals,
A second optical coupler coupling the first signal separated from the first optical coupler and the signal passed through the first extracting module,
A third optical coupler for coupling a second signal separated by the first optical coupler and a signal passed by the second extraction pass module,
Further comprising: The method of claim 5,
A third extraction module for extracting at least some of the inputted second operation signals and for passing a signal to be retransmitted among the second operation signals,
A fourth optical coupler for coupling a third signal separated by the first optical coupler and a signal passed by the third extraction module,
A fourth extraction module that extracts at least some of the input second preliminary signals and passes a signal to be retransmitted among the second preliminary signals,
Further comprising a fifth optical coupler for coupling a fourth signal separated by the first optical coupler and a signal passed by the fourth extraction pass module,
Wherein the second operation signal and the second preliminary signal are signals separated from a third node which is a neighbor node of the first node. The method of claim 1,
Each of the first extraction module and the second extraction module
And separates the input signal into a total signal, a channel-by-channel signal, or a band-by-band signal, and extracts a signal to be transmitted to the first optical switch. A method for protecting an optical communication device mounted on a first one of a plurality of nodes in a linear multicast network in which a plurality of nodes are linearly connected,
Extracting at least some of the input first operating signals as a first extracted signal,
Extracting at least some of the input first preliminary signals as a second extracted signal, and
Selecting one of the first extraction signal and the second extraction signal and outputting the selected extraction signal as a first output signal,
Wherein the first operation signal and the first preliminary signal are signals transmitted separately from a second node which is a neighbor node of the first node. 9. The method of claim 8,
The step of outputting as the first output signal
And selecting a normal extraction signal when any one of the first extraction signal and the second extraction signal is abnormal. 9. The method of claim 8,
The step of outputting as the first output signal
And the second extraction signal is selected when the operation signal line transmitting the first operation signal has a fault. 9. The method of claim 8,
Demultiplexing the first output signal
Further comprising the steps of: 9. The method of claim 8,
Extracting at least some of the input second operating signals as a third extracted signal,
Extracting at least some of the input second preliminary signals as a fourth extracted signal, and
Selecting one of the third extracted signal and the fourth extracted signal and outputting the selected extracted signal as a second output signal,
Wherein the second operation signal and the second preliminary signal are signals transmitted separately from a third node which is a neighbor node of the first node. The method of claim 12,
Combining the first output signal and the second output signal, and
Demultiplexing the combined signal
Further comprising the steps of:

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