KR100557143B1 - Optical channel path supervisory and correction apparatus and method for transparent potical cross-connect - Google Patents

Abstract

In the all-optical OXC of the wavelength division multiplexing optical network, the present invention relates to a unit of subframes and timeslots according to the order of input optical signals inputted to the all-optical OXC from input ports having a predetermined number of generated optical signals. A path monitoring information generation unit for delaying the output signal as a motion path monitoring information optical signal, wavelength demultiplexers for demultiplexing the input optical signals and outputting a second predetermined number, and the demultiplexing optical signals; Optical couplers for coupling the movement path monitoring information optical signal in a one-to-one correspondence, optical switches for switching and outputting the combined optical signals according to previously input switching information, and optical signals output from the optical switches And multiplexing the output signals to output ports having a first predetermined number and outputting the optical signals output from the wavelength multiplexers. A path monitoring information detection unit for detecting the moving path monitoring information optical signal and converting the detected optical signal into an electric signal, and detecting the corresponding subframe and time slot position information from the converted electric signal to generate the moving path monitoring information; And a path monitoring controller for correcting a path in which an abnormality occurs by comparing the frame and timeslot position information with the previously input switching information.

All-optical OXC, Wavelength Path Monitoring / Modification

Description

OPTICAL CHANNEL PATH SUPERVISORY AND CORRECTION APPARATUS AND METHOD FOR TRANSPARENT POTICAL CROSS-CONNECT}             

1 is a view showing the configuration of an optical signal path monitoring apparatus for OXC according to the prior art

2 is a view showing the configuration of an optical signal path monitoring and control device for OXC according to a first embodiment of the present invention

3 to 4 is an example showing the detailed configuration of the main optical delay module in the optical signal path monitoring and control device for OXC of FIG.

FIG. 5 is a diagram illustrating a detailed configuration of a sub optical delay module in the main optical delay module of FIG. 3.

6 is a diagram illustrating a detailed configuration of a subframe and timeslot detector in the optical signal path monitoring and control device for OXC of FIG.

7 is a view showing a time frame used in the optical signal path monitoring and control device for OXC of FIG.

FIG. 8 is a diagram illustrating an output example of main optical delay lines in the main optical delay module of FIG. 3.

FIG. 9 is a diagram showing an example of output from sub optical delay lines in the sub optical delay module of FIG. 4; FIG.

FIG. 10 is an example of a time frame input to a subframe and timeslot detection unit in the OXC optical signal path monitoring and control device of FIG.

11 is a view showing the configuration of an optical signal path monitoring and control device for OXC according to a second embodiment of the present invention

12 is a diagram illustrating a detailed configuration of a subframe and timeslot detector in the optical signal path monitoring and control device for OXC of FIG.

The present invention relates to an all-optical optical cross-connect (OXC) in a wavelength division multiplexing optical network, and more particularly, to an apparatus and a method for path monitoring and modification of wavelength channels in an all-optical optical cross-connect (OXC).

Current subscribers use hundreds of kb / s to several Mb / s over optical networks using Asymmetric Digital Subscriber Line (ADSL), cable modem, dial up model, and Ethernet. I'm using a data service. However, a bandwidth of at least 100 Mb / s is required to provide subscribers with high-capacity video services, VOD (Video On Demend), high-speed Internet, and broadcast services in optical communication systems. Accordingly, many countries around the world are constructing high-capacity optical communication networks using OXC having a capacity of several Tb / s together with a high-speed, high-capacity dense wavelength division multiplexing (DWDM) optical transmission system. Until now, OXC using optical / electric / optical conversion is mainly used, but transparent OXC, which does not undergo optical / electric / optic conversion, is expected to be used within the next 2-3 years. The wavelength channels input from the all-optical OXC are output to the destination port through an optical switch or the like according to the preset wavelength routing information. At this time, it is necessary to check whether the input wavelength channels are correctly switched according to preset OXC wavelength routing information. This is called optical signal path monitoring in OXC.

1 is a view showing the configuration of the optical signal path monitoring apparatus for OXC according to the prior art.

Referring to FIG. 1, the optical signal path monitoring apparatus for OXC according to the related art recognizes an input port number by combining a specific frequency of f1 to each input port and uses an ASE wavelength of EDFA (Erbium Doped Fiber Amplifier) of the input unit. Recognize the input wavelength number. For example, if an ASE wavelength of λ _n + FSR modulated at a frequency of F2 is detected at output 1, this means that the λ _n optical signal at input 2 is switched to output 1. By calculating the path of the input wavelengths through the detected ASE wavelength component and the frequency component of f _i through the above process, and comparing them with predetermined routing / switching information, it is possible to check whether the input wavelength signals are correctly switched and to find an error. If it modifies the path of the optical signal by controlling the optical switch.

In order to monitor the path of the wavelength signal in the manner described above, there must be as many ASE wavelength channels as the number of wavelength channels at the input W. However, current WDM optical transmission systems use both EDFA amplification bands to transmit optical signals, for example 32 and 64 channels. It is not possible to use a separate ASE wavelength channel for path monitoring of the wavelength channel as in the OXC wavelength path monitoring apparatus according to the prior art. In the prior art, n · N (n is the number of wavelengths, N is the number of input and output) optical fiber gratings are required, and n · N path monitoring optical receivers are required for the frequency detector. Therefore, there is a problem that the price of the wavelength path monitoring device increases significantly. In addition, expensive tunable filters should be used to detect ASE wavelengths. Therefore, the prior art has a big limitation in using in actual OXC system.

It is another object of the present invention to provide a path monitoring signal generation unit for detecting an input port and a wavelength number through subframe and time slot detection in an all-optical OXC in order to detect an input port and a wavelength number through one frame instead of an expensive FPF. The present invention provides a wavelength path monitoring / modification apparatus and method which reduces the manufacturing cost by using a transmitter and an optical delay module.

It is still another object of the present invention to implement a path monitoring signal generator in an all-optical OXC using a single data pattern generator instead of an expensive FPF in the path monitoring and modification of an optical wavelength signal. An apparatus and method are provided.

In accordance with the above object, the present invention provides an all-optical OXC of a wavelength division multiplexing optical communication network, in which a predetermined generated optical signal is input to the all-optical OXC from input ports having a first predetermined number. A path monitoring information generation unit for delaying in units of subframes and timeslots and outputting the motion path monitoring information optical signal; wavelength demultiplexers for demultiplexing the input optical signals and outputting a second predetermined number; Optical couplers for coupling the multiplexed optical signals and the movement path monitoring information optical signal in a one-to-one correspondence, optical switches for switching and outputting the combined optical signals according to previously input switching information, and the optical switch Wavelength multiplexers for multiplexing the optical signals outputted from the plurality of signals and outputting them to output ports having a first predetermined number; A path monitoring information detection unit for detecting the movement path monitoring information optical signal from the output optical signals and converting the same into an electric signal, and generating the movement path monitoring information by detecting the corresponding sub-frame and time slot position information from the converted electric signal; And a path monitoring controller for correcting a path in which an abnormality occurs by comparing the generated subframe and time slot position information with the previously input switching information.

In still another aspect, there is provided a method for monitoring / modifying an optical signal path in an all-optical OXC of a wavelength division multiplexing optical network, wherein the predetermined optical signal is inputted from an input port having a first predetermined number. A first process of outputting the motion path monitoring information optical signal by delaying the sub-frame and the time slot unit; and a second process of demultiplexing the input optical signals and outputting a second predetermined number, A third process of combining optical signals and the movement path monitoring information optical signal in a one-to-one correspondence, a fourth process of optically switching the combined signal according to previously input switching information, and multiplexing the optically switched signals A fifth process of outputting the first predetermined number of optical signals, detecting a movement path monitoring information optical signal from the multiplexed optical signals, and converting the optical signal into an electrical signal; And a sixth process of detecting the corresponding subframe and time slot position information from the converted electrical signal to generate movement path monitoring information, comparing the generated movement path monitoring information with previously input path switching information, and then According to the result is characterized in that the seventh process of modifying the path.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that the same elements in the figures are represented by the same numerals wherever possible. In addition, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

2 is a view showing the configuration of an optical signal path monitoring and control device for OXC according to a first embodiment of the present invention.

Referring to FIG. 2, the apparatus for monitoring and controlling the optical signal path for the OXC according to the first embodiment of the present invention includes a path monitoring information generator, first to Nth wavelength demultiplexers 30, and optical couplers 40. , Optical switches 50, wavelength multiplexers 60, a path monitoring information detector, and a path monitoring controller.

The path monitoring information generator generates the wavelength path monitoring information. Wherein the path monitoring information generating unit to a single laser diode 110, the light modulation frequency f ₁ having the wavelength λ _P for the frequency generator 100, the light modulation of the generated frequency f ₁ to generate the frequency f ₁ a predetermined time It consists of a main optical delay module 120 for delaying.

3 to 4 are exemplary views showing the detailed configuration of the main optical delay module 120 in the optical signal path monitoring and control device for OXC of FIG.

Referring to FIG. 3, the main optical delay module 120 is configured as follows.

First, referring to FIG. 3, the main optical delay module 120 according to the first embodiment includes an optical amplifier 121, an optical coupler 123, main optical delay lines 125, and first to Nth sub optical delay modules. Field 127.

The optical amplifier 120 amplifies the optical signal input from the laser diode (110). The optical coupler 123 separates and outputs the optically modulated frequency amplified from the optical amplifier 121 and input. The main optical fiber delay lines 125 delay and output frequencies separated from the optical coupler 123 at intervals of a predetermined subframe unit, respectively, in order. The first to N-th sub-delay modules 127 delay and output frequencies input from the optical fiber delay lines 125 in sub-frame units, respectively, in intervals of timeslots.

Meanwhile, the main optical delay module 120 may be implemented as follows according to the second embodiment. Referring to FIG. 4, the main optical delay module 220 according to the second embodiment includes an optical coupler 221, main optical fiber delay lines 223, optical amplifiers 225, and first to Nth sub optical delay modules. Field 227.

The optical coupler 221 separates and outputs the optically modulated frequency from the optical signal input from the laser diode 110. The main optical fiber delay lines 223 delay and output the frequencies separated by the optical coupler 221 at intervals of a predetermined subframe unit, respectively, in order. The optical amplifiers 225 amplify the optical signals output by being delayed by the sub-frame interval from the main optical fiber delay lines 223. The first to N th sub-delay modules 227 delay and output the optical signals amplified from the optical amplifiers 225 at intervals of timeslots, respectively.

5 is a diagram illustrating a detailed configuration of the sub-light delay module 127.

Referring to FIG. 5, the sub optical delay module 127 includes an optocoupler 128 and sub optical fiber delay lines 129. The optocoupler 128 separates and outputs frequencies that are input by being delayed in units of subframes from the main optical fiber delay lines 125. The sub-fiber delay lines 129 delay and output the frequencies separated by the optocoupler 128 by a timeslot interval in order. At this time, the frequencies delayed by the timeslot intervals output from the sub-fiber delay lines 129 are path monitoring information.

The first to Nth wavelength demultiplexers 30 demultiplex the inputs 1 to N, respectively. The optocouplers 40 combine the outputs of the wavelength demultiplexers 30 with the path monitoring information generated by the path monitoring information generator. The optical switches 50 switch the optical signal coupled at the optical couplers 40 according to preset switching information. Each of the wavelength multiplexers 60 receives a signal transmitted from the optical switches 50 and multiplexes the signal.

The path monitoring information detector detects path monitoring information from the multiplexed signal input from the wavelength self-weighting devices 60. The path monitoring information detector includes an optical circulator 70, an optical receiver 80, an optical fiber grating (reflective filter) 90, and a subframe and timeslot detector 150. The optical circulators 70 detect the path monitoring wavelength λ _P from the data combined with the path monitoring information output from the wavelength multiplexers 60. The optical receivers 80 convert the path monitoring wavelength λ _P detected by the optical circulators 70 into an electrical signal. The optical fiber gratings 90 generate output 1 to output N. The subframe and timeslot detector 150 detects the subframe and timeslot in the electrical signal input from the optical receivers 80.

6 is a diagram illustrating a detailed configuration of the subframe and timeslot detector 150. Referring to FIG. 6, the subframe and timeslot detector 150 detects a frequency component received from the optical receivers 80 to identify an input port, and a bandpass filter column 152, subframes and timeslot detectors. 154, an OXC switching information generator 156 for generating the optical signal path of the input data in the form of a table using the detected subframe and timeslot information.

The path monitoring controller receives the path monitoring information, that is, the optical signal path table of the input data from the subframe and the timeslot detector 150, monitors the optical signal path in the OXC, and generates an error generated when an error occurs in the optical signal path. Correct it. The path monitoring controller includes a switch controller 130, a comparator 140, and a switching table 160. The switching table 160 stores predetermined switching / routing information. The comparator 140 compares the path monitoring information input from the subframe and the timeslot detector 150, that is, the optical signal path table of the input data and the switching / routing information predetermined in the switching table 160. The comparator 14 indicates that an incorrect switching, that is, a path error, occurs in the OXC when the comparison results in the difference between the path monitoring information and the predetermined switching / routing information. The switch controller 130 controls the switching of the optical switches 50 to correct the path of the optical signal when an incorrect switching occurs.

As described above, the optical signal path monitoring apparatus for the OXC according to the first embodiment of the present invention uses a time frame divided into a main frame, a sub frame, and a time slot, and monitors and modifies the moving path of the optical signal in a time slot unit. do.

7 is a view showing a time frame used in the optical signal path monitoring and control device for OXC according to the first embodiment of the present invention.

Referring to FIG. 7, the main frame T _MF is composed of N subframes T _SF , and each sub frame T _SF is composed of n timeslots TS1 to TSn. At this time, the sub frame number indicates the input port number. For example, if the f ₁ frequency is located in the subframe 1 section, it means that it is an optical signal input to input port 1, and if the frequency f ₁ is located in the sub frame 2 section, it means that it is an optical signal input to input port 2 do. If the frequency f ₁ is located in the subframe N section, this means that the optical signal is input to the N input port. In addition, the timeslot number in each subframe means a wavelength number. For example, if the frequency f ₁ is located in the first timeslot in the subframe, the wavelength of the input optical signal is λ ₁ , and if the frequency f ₁ is located in the second timeslot in the subframe, the wavelength of the input optical signal This means that λ ₂ . When the frequency f ₁ is located at the n th time slot in the subframe, the wavelength of the input optical signal is λ _n . Therefore, when the frequency f ₁ is located in the first timeslot in the first subframe, it means that the wavelength of the optical signal input to the first input terminal is λ ₁ . That is, when the frequency f ₁ is located in the n th time slot in the N th subframe, it means that the wavelength of the optical signal input to the N input terminal is λ _n .

 8 is a diagram illustrating an output example of the main photo delay lines 125 of the main photo delay module 120. FIG. 9 is a diagram illustrating an output example of sub-light delay lines 129 of the sub-light delay module 127.

Hereinafter, an operation of monitoring the movement path of the optical signal by using the time frame configured as described above by the OXC optical signal path monitoring apparatus according to the first embodiment of the present invention will be described in detail with reference to FIGS. 2 to 9.

Referring to FIG. 2, the frequency generator 100 generates an input frequency f ₁ . The generated frequency component is modulated into an optical signal in the laser diode 110 with a λ _p wavelength. The modulated optical signal is delayed in the main optical delay module 120.

Referring to FIG. 3, which shows a detailed configuration of the main optical delay module 120, the modulated optical signal is amplified by the optical amplifier 121, separated into N through the optical coupler 123, and the main optical delay lines ( 125) Delayed output in order.

Referring to FIG. 8 showing an example of output from the main optical delay lines 125, the first optical signal is delayed 7a without delay, the second optical signal is delayed by T _MF / N 7b, and the Nth optical The signal is delayed by [N-1 / N] T _MF (7c) and placed in each time slot and output. Where T _MF represents the length of time of the main frame. As described above, the optical signals delayed and output from the main optical delay lines 125 are input to the first to Nth sub optical delay modules 127.

Referring to FIG. 5, which shows a detailed configuration of the sub optical delay module 127, optical signals delayed and input from the main optical delay lines 125 are divided into N through optical couplers 128 and sub optical delays. The delay is output once again in order while passing through the lines 129.

Referring to FIG. 9, which shows an example of output from the sub optical delay lines 129, a first optical signal delayed from the main optical delay lines 125 and input is placed in a first timeslot in each subframe without delay. do. The second optical signal delayed from the main optical delay lines 125 is delayed by T _SF / n and positioned in a second timeslot in each subframe. The last n th optical signal, which is delayed from the main optical delay lines 125 and input, is delayed by [(n-1) / n] T _SF and positioned in the n th time slot in each subframe. Where T _SF represents the length of time of the subframe.

The optical signals for path monitoring which are delayed in the manner described above and located in each timeslot in each subframe are combined with the wavelength components input to the OXC through the optical coupler 40. That is, the path monitoring optical signal located in the i th timeslot in the j th subframe is coupled through the optical coupler 40 with the λ _i wavelength input to the j th input port of the OXC. The path monitoring wavelength of λ _P combined with the optical signal is switched by the optical switch 50 to each output in accordance with predetermined switching information.

The switched optical signal and the path monitoring wavelength of λ _p are combined in the wavelength multiplexer 60 and then input to a path monitoring wavelength detector consisting of an optical circulator 70 and an optical fiber grating 90. The optical circulator 70 detects the lambda _P wavelength, and the optical fiber grating 90 outputs data. The optical receiver 80 converts the λ _P wavelength detected by the optical circulator 70 into an electrical signal and outputs the electrical signal.

The path monitoring signal converted into the electrical signal is input to the subframe and the timeslot detector 150. The subframe and timeslot detector 150 detects subframes and timeslots of the input path monitoring signal. The detected subframe and timeslot information indicates input port and wavelength information of the output optical signal.

Referring to FIG. 6, which shows a detailed configuration of the subframe and timeslot detector 150, a signal input to the subframe and timeslot detector 150 is input to the band pass filter train 152 for frequency detection. Detecting the frequency information in the band pass filter column 152 can find the input port information of the optical signal. The frequency components detected in the band pass filter column 152 are input to the subframe and timeslot position detectors 154, and the subframe and timeslot position detectors 154 are subframes and timeslots from the input frequency components. To detect the position information. The OXC switching table generator 156 is used to generate an input / output table of the wavelength signals switched in the all-optical OXC using the subframe and time slot position information detected as described above.

10 illustrates an example of a time frame input to the subframe and the timeslot detector 150. In FIG. 10, a path monitoring signal is located in a first time slot in a first subframe, an nth time slot in a first subframe, and a second time slot in an Nth subframe in a time frame input to the subframe and the timeslot detector 150. An example is shown.

When a path monitoring signal as shown in FIG. 10 is detected from the sub-frame and timeslot detector 150, the OXC switching table generator 156 outputs N times an optical signal having a wavelength of λ ₁ and λ _n at the input port _1. Generates information that the optical signal at wavelength λ ₂ is switched to output ₂ at the input port.

The switching table generated by the OXC switching table generator 156 through the above-described process is compared with the wavelength signal switching table 160 predetermined in the comparator 140. In this case, if the actual switching information and the predetermined switching information are different, it means that an incorrect switching has occurred in the OXC. Therefore, the optical switch connection change signal is transmitted to the optical switch controller 130 in order to correct them. The optical switch controller 130 controls the optical switches 50 to modify the switching state of the wavelength signals.

Through the above process, the switching path of the optical signal input into the OXC can be identified, and the path in which the abnormality occurs can be modified and controlled.

11 is a view showing the configuration of the optical signal path monitoring and control device for OXC according to the second embodiment of the present invention, Figure 12 is a sub-frame and in the optical signal path monitoring and control device for OXC according to the second embodiment It is a figure which shows the detailed structure of a timeslot detection part.

As shown in FIG. 2, in the first embodiment, one frequency generator 100 generating a frequency f ₁ is used to generate path monitoring information. However, the frequency f ₁ only indicates the presence or absence of a signal and does not affect the input port detection or the wavelength detection. Accordingly, as shown in FIG. 11, in the second embodiment, the input data pattern generator 300 having a specific data pattern is used instead of the frequency generator 100 to generate the path monitoring information. The input data pattern generator 300 distinguishes input ports by using a predetermined bit. For example, when there is an input 1, an input 2, an input 3, and an input 4, the input data pattern generator 300 is' 00 ',' 01 ',' 10 ',' The data pattern of 11 'can be used to distinguish. In addition to the above-described method, the data pattern may be provided in various ways. The input data pattern generated by the input data pattern generator 300 is detected by the subframe and timeslot detector 350 as shown in FIG. 12.

Meanwhile, as shown in FIG. 6, the subframe and timeslot detector 150 according to the first embodiment of the present invention includes a band pass filter sequence 152 for frequency detection in detecting the subframe and timeslot. However, in the second embodiment of the present invention, since the input data pattern generator 300 is used to generate the path monitoring information, it is not necessary to detect the frequency when detecting the subframe and the timeslot. Accordingly, as shown in FIG. 12, the subframe and timeslot detector 350 according to the second embodiment of the present invention may be implemented without a band pass filter for frequency detection.

In the above description of the present invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be defined by the described embodiments, but should be determined by the equivalent of claims and claims.

As described above, the wavelength path monitoring / modification apparatus and method in the all-optical OXC of the present invention can detect and correct an optical signal switching error occurring in the all-optical OXC. The present invention can significantly lower the manufacturing cost of the optical signal path monitoring apparatus by significantly reducing the number of optical receivers and optical fiber gratings without using expensive tunable filters unlike conventional OXC devices. In addition, the path monitoring signal generator is implemented using a single optical transmitter and a data pattern generator, and wavelength information is detected using a time slot, thereby simplifying the monitoring of the signal path, and thus can be effectively utilized in an optical communication network. .

Claims (11)

In all-optical OXC of wavelength division multiplexing optical network, Path monitoring outputting a predetermined generated optical signal as a sub-frame and time slot unit according to the order of input optical signals inputted to the all-optical OXC from input ports having a first predetermined number and outputting them as movement path monitoring information optical signals. An information generator, Wavelength demultiplexers for demultiplexing the input optical signals and outputting a second predetermined number; Optical couplers for coupling the demultiplexed optical signals and the movement path monitoring information optical signal in a one-to-one correspondence; Optical switches for switching and outputting the combined optical signals according to previously input switching information; Wavelength multiplexers for multiplexing the optical signals output from the optical switches and outputting them to output ports having a first predetermined number; The movement path monitoring information optical signal is detected from the optical signals output from the wavelength multiplexers and converted into an electrical signal, and the movement path monitoring information is generated by detecting the corresponding subframe and time slot position information from the converted electrical signal. A route monitoring information detection unit; And a path monitoring control unit for correcting a path in which an abnormality occurs by comparing the detected subframe and time slot position information with the previously input switching information. The method of claim 1, wherein the path monitoring information generation unit, One frequency generator for generating a predetermined frequency, An optical transmitter for optically modulating the frequency generated by the frequency generator; And a main optical delay module for delaying the optical signal generated by the optical transmitter in subframes and timeslots according to the order of the input optical signal input to the all-optical OXC and outputting the optical signal as a movement path monitoring information optical signal. Wavelength Path Monitoring and Correction Device in an All-optical OXC. The method of claim 1, wherein the path monitoring information generation unit, One data pattern generator for generating predetermined bit data to identify a path of predetermined input optical signals; An optical transmitter for optically modulating the bit data generated by the data pattern generator to generate a predetermined optical signal; And a main optical delay module configured to delay the predetermined optical signal generated by the optical transmitter in subframe and time slot units according to the order of the input optical signal input to the all-optical OXC and output the movement path monitoring information. Wavelength path monitoring and correction device in all-optical OXC. The method of claim 1, wherein the path monitoring information detection unit, Optical circulators for advancing the optical signals output from the wavelength multiplexers in an output direction and for advancing the movement path monitoring information optical signal reflected from the output direction to the optical sensors; Reflection filters for reflecting the movement path monitoring information optical signal among the signals output from the optical circulators and outputting the optical signal to the optical circulators; The photodetectors for converting the movement path monitoring information optical signal into an electrical signal; And a subframe and timeslot detector for detecting the corresponding subframe and timeslot position information from the converted electrical signal to generate path monitoring information. The method according to any one of claims 2 and 3, wherein The main optical delay module, An optical amplifier for amplifying and outputting an optical signal generated from the optical transmitter; An optical coupler for demultiplexing the optical signal amplified and output from the optical amplifier by a first predetermined number; Main optical fiber delay lines for delaying and outputting the demultiplexed optical signal by the optical coupler by subframe intervals according to the order of input ports into which the demultiplexed optical signal is input; A sub-optic which demultiplexes the optical signal delayed by the sub-frame interval from the main optical fiber delay lines by a second predetermined number and delays and outputs the demultiplexed optical signal by the time slot interval in the order of the output signal of the wavelength demultiplexer Wavelength path monitoring and correction apparatus in an all-optical OXC, comprising delay modules. The method of claim 5, The sub optical delay module, An optical coupler for demultiplexing an optical signal input by being delayed by subframes from the main optical fiber delay lines by a second predetermined number; And sub-fiber delay lines for delaying and outputting the optical signal demultiplexed from the optical coupler by a time slot interval in the order of the output signal of the wavelength demultiplexer. The method of claim 4, wherein the subframe and timeslot detector, A band pass filter column for outputting only an electric signal corresponding to a corresponding frequency in the electric signal converted from the light sensor; Subframe and timeslot detectors for detecting position information of subframes and timeslots in the electrical signal outputted from the bandpass filter string; And an OXC switching information generator for generating the detected frequency subframe and timeslot position information into a switching table. The method of claim 1, wherein the path monitoring control unit, A switching table storing pre-input switching information; A comparator for comparing the path monitoring information detected from the path monitoring information detection unit with the optical signal switching information previously input to the switching table; And a switch controller for modifying a switching path when the path monitoring information and the optical signal switching information previously input to the switching table are different from each other. A method for monitoring and modifying an optical signal path in an all-optical OXC of a wavelength division multiplexing optical network, A first process of delaying a predetermined optical signal in units of subframes and timeslots according to the order of input optical signals input from input ports having a first predetermined number and outputting the predetermined optical signal as a movement path monitoring information optical signal; A second process of demultiplexing the input optical signals and outputting a second predetermined number; A third process of combining the demultiplexed input optical signals and the movement path monitoring information optical signal in a one-to-one correspondence; A fourth process of optically switching the combined signal according to previously input switching information; A fifth process of multiplexing the optically switched signals and outputting the first predetermined number of optical signals; A sixth process of detecting the movement path monitoring information optical signal from the multiplexed optical signals and converting the same into an electrical signal, and generating the movement path monitoring information by detecting corresponding subframe and time slot position information from the converted electrical signal; , And a seventh process of comparing the generated movement path monitoring information with previously inputted path switching information and correcting the path according to the result. A method for monitoring and modifying an optical signal path in an all-optical OXC of a wavelength division multiplexing optical network, A first process of delaying predetermined bit data in subframe and time slot units according to the order of input optical signals inputted from input ports having a first predetermined number and outputting the predetermined bit data as a movement path monitoring information optical signal; A second process of demultiplexing the input optical signals and outputting a second predetermined number; A third process of combining the demultiplexed input optical signals and the movement path monitoring information optical signal in a one-to-one correspondence; A fourth process of optically switching the combined signal according to previously input switching information; A fifth process of multiplexing the optically switched signals and outputting the first predetermined number of optical signals; A sixth process of detecting the moving path monitoring information optical signal from the multiplexed optical signals and converting the detected moving path monitoring information optical signal into an electric signal, and generating the moving path monitoring information by detecting corresponding subframe and time slot position information from the converted electric signal; and, And a seventh process of comparing the generated movement path monitoring information with previously inputted path switching information and correcting the path according to the result. The method of claim 7, Wherein the detected subframe position information indicates an input port and the time slot position information indicates an optical signal wavelength.

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