KR100520650B1 - Optical channel path supervisory and correction apparatus for transparent potical cross-connect - Google Patents

Abstract

The present invention relates to a wavelength path monitoring / modification apparatus of an all-optical OXC of a wavelength division multiplexing optical communication network having a variable wavelength conversion function. A plurality of inputs for converting the predetermined number of wavelengths and outputting the converted wavelength, and outputted from each of the input units using information generated in the predetermined number n of frequencies and information stored in a preset switching table. A path monitoring information generation unit for generating and outputting a path monitoring signal for selecting one wavelength for path monitoring among a predetermined number of conversion wavelengths; and a predetermined number n of conversion wavelengths output from each of the input units And a plurality of optocouplers, a plurality of wavelength multiplexers, and the optocoupler to one-to-one correspondence with the path monitoring signals output from the path monitoring information generator; A plurality of optical switches corresponding to each of the plurality of plugs and switching a predetermined number (n) of signals input from the corresponding optical coupler to each of the wavelength multiplexers using information stored in a preset switching table; A path monitoring information detector for detecting a path monitoring signal from each of the optical signals output from each of the wavelength multiplexers, converting the path monitoring signal into an electric signal, and detecting current switching information of the optical signals input to the OXC based on the electric signal; And a path monitoring controller configured to store the preset switching table, compare the current switching information detected by the path monitoring information detection unit with the switching table, determine whether a path abnormality occurs, and correct the path where the path abnormality occurred. It features.

Description

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

The present invention relates to an all-optical optical cross-connect (OXC) in a wavelength division multiplexed optical communication network, and more particularly, to an apparatus 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 the ASE wavelength of λ _n + FSR modulated with the frequency of F2 is detected at output 1, this means that the λ _n optical signal is switched to output 1 at input 2. 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.

However, the conventional optical signal path monitoring / modifying device as described above is applicable to the OXC which does not have a wavelength tunable function, but is not applicable to the OXC having a tunable tunable function. This is because the OXC having a tunable function converts an input wavelength to another wavelength because a conventional optical signal path monitoring / modifying device can detect the converted wavelength but cannot detect the input wavelength before conversion. However, in order to implement a dynamic optical communication network, an OXC capable of varying the wavelength of optical signals is necessary. Accordingly, in the all-optical communication network, an optical signal path monitoring / modifying device applicable to OXC having a variable wavelength is required.

Accordingly, an object of the present invention is to provide an optical signal path monitoring / modification apparatus and method capable of correcting a path of an optical signal when an error occurs by inspecting an optical signal path even in an OXC having a tunable wavelength conversion function.

 Another object of the present invention is to find out the wavelength and input port of the input optical signal through the subframe and time slot in which the predetermined frequency and the predetermined frequency are located in the OXC having the wavelength tunable conversion function, and to check the switching path of the input optical signal to detect an error. It is an object of the present invention to provide an optical signal path monitoring / modification apparatus and method capable of modifying an optical signal path when generated.

According to the above object, the present invention provides a wavelength path monitoring / modification apparatus of an all-optical OXC of a wavelength division multiplexing optical communication network having a variable wavelength conversion function, and receives a multiplexed signal of predetermined (n) different wavelengths. By using a plurality of input units for converting a predetermined number (n) of demultiplexed and then outputting a converted wavelength by demultiplexing, and using information generated in a predetermined number (n) of frequencies generated and a preset switching table A path monitoring information generation unit for generating and outputting a path monitoring signal for selecting one wavelength for path monitoring among the n conversion wavelengths output from each of the input units, and a predetermined number output from each of the input units; a plurality of optocouplers and a plurality of wavelengths for one-to-one correspondence of the conversion wavelengths of (n) and the path monitoring signals output from the path monitoring information generator; A plurality of switches for switching the predetermined number (n) signals inputted from the corresponding optical coupler to each of the wavelength multiplexers using the firearms and the information stored in a predetermined switching table corresponding to each one of the optocouplers. Detecting a path monitoring signal from each of the optical switches and the optical signals output from each of the wavelength multiplexers, converting the path monitoring signal into an electrical signal, and detecting current switching information of the optical signals inputted to the OXC based on the electrical signal. A path storing the path monitoring information detection unit and the preset switching table, comparing the current switching information detected by the path monitoring information detection unit with the switching table to determine whether a path abnormality has occurred, and then correcting the path where the path abnormality has occurred And a monitoring control unit.

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 the optical signal path monitoring and control device for OXC according to an embodiment of the present invention.

Referring to FIG. 2, in the OXC optical signal path monitoring and control device according to an embodiment of the present invention, the path monitoring information generation unit 30, the input unit 50, the optical couplers 55, and the optical switches 60 are provided. And a wavelength multiplexer 65, a path monitoring information detector 70, and a path monitoring controller 90.

The path monitoring information generator 30 generates the wavelength path monitoring information. The path monitoring information generator 30 includes frequency generators 32, a combiner 34, an optical modulator (laser diode) 36, a first optical splitter 38, and a first optical retarder 40. , First light selectors 42, light retardation modules 44, and second light selectors 46.

The frequency generators 32 generate frequencies of the frequencies f _{1 to} f _n , respectively. The frequency combiner 34 combines the frequencies f _{1 to} f _n generated by the frequency generators 32 and outputs the combined frequency f _i . The laser diode 36 has a wavelength λ _P and modulates and outputs an input frequency f _i . The first optical splitter 38 splits the frequencies of the light modulated f _i and outputs them as optical signals of 1 to n. The first optical retarders 40 delay and output optical signals of 1 to n by 0 to (n-1) time slot intervals, respectively. For example, the first optical retarders 40 output the first optical signal without delay, delay the second optical signal by one time slot interval, and output the nth optical signal by the time slot of (n-1). Output by delaying the interval. The first light selectors 42 select and output only a specific light signal (a frequency present in the first subframe) among the light signals output from the first light delay units 40. The optical delay modules 44 delay and output a specific optical signal output from the first optical selectors 42 by a sub frame interval.

3 is a diagram showing the detailed configuration of the optical delay module 44-1 in the optical signal path monitoring and control device for OXC of FIG.

Referring to FIG. 3, the optical delay module 44-1 includes a second optical splitter 2 and second optical retarders 4. The second optical splitter 2 splits a specific optical signal output from the first optical selectors 42 and outputs it as optical signals of 1 to N. The second optical retarders 4 delay and output 1 to N optical signals separated by the second optical splitter 2 by 0 to (N-1) subframe intervals, respectively. For example, the second optical retarders 40 output the first optical signal without delay, delay the second optical signal by one subframe interval, and output the Nth optical signal by subframe of (N-1). Output by delaying the interval.

The second optical selectors 48 select and output only a specific optical signal (a corresponding frequency present in a corresponding subframe) according to preset switching information among optical signals output from the optical delay modules 44. In this case, the specific optical signals output from the second optical selectors 48 are path monitoring information.

Meanwhile, the input unit 50 receives a predetermined multiplexed signal of different wavelengths n, demultiplexes the signal, and converts the demultiplexed wavelengths n to output the converted wavelength. The input unit 50 includes first to Nth wavelength demultiplexers 52-1 to 52 -N, variable wavelength converters 54-1 to 54 -N, optical couplers 55, and optical switches ( 60, wavelength multiplexers 65.

The first to N-th wavelength demultiplexers 52-1 to 52-N demultiplex input 1 to input N, respectively, and output the input wavelengths of λ ₁ to λ _n . The variable wavelength converters 54-1 to 54 -N convert input wavelengths of λ ₁ to λ _n outputted from the wavelength demultiplexers 52 to different wavelengths. The optocouplers 54 combine the converted wavelengths output from the variable wavelength converters 54-1 to 54 -N with the path monitoring information generated by the path monitoring information generator 30. The optical switches 60 switch the optical signal coupled at the optical couplers 54 according to preset switching information. The wavelength multiplexers 65 receive the signals transmitted from the optical switches 60, respectively, and multiplex and output the signals.

The path monitoring information detector 70 detects the path monitoring information from the multiplexed optical signals output from the wavelength multiplexers 65. The path monitoring information detection unit 70 includes optical circulators 72, optical detectors 74, reflective filters (optical fiber gratings) 76, an input port, and a frequency detector 78.

The optical circulators 72 advance the optical signal output from the wavelength multiplexers 65 to the reflection filter 76 and output the optical signal reflected from the reflection filter 76 to the light sensor 74. . The reflection filters 76 reflect the path monitoring wavelength λ _P corresponding to the path monitoring information among the optical signals output from the optical circulators 72 and generate outputs 1 to N. The light detectors 74 convert the path monitoring wavelength λ _P output from the light circulators 72 into an electric signal. Input port and frequency detector 78 detects subframes and wavelengths and time slots in electrical signals input from photodetectors 74.

4 is a diagram illustrating a detailed configuration of the input port and the frequency detector.

4, the input port and frequency detector 78 includes electrical signal splitters 78-1, bandpass filter string 78-2, subframe and wavelength detectors 78-3, and timeslots. Detectors 78-4, OXC switching table generator 78-5.

The electric signal splitters 78-1 separate the electric signal converted by the light detector 74 by wavelength. The bandpass filter train 78-2 detects a frequency component of f _{i in} the separated signals for each wavelength. The subframe and wavelength detectors 78-3 detect a wavelength corresponding to the frequency of each f _i detected in the bandpass filter sequence 78-2, and detect the sub frame in which the frequency of each f _i is located. Time slot detectors 78-4 detect the input wavelength before being converted in variable wavelength converter 54. The OXC switching table generator 78-4 generates a path of an input optical signal in the form of a table using the detected wavelength, subframe, and time slot information.

The path monitoring controller 90 receives the path monitoring information, that is, the path table of the input optical signal from the input port and the frequency detector 78, monitors the optical signal path in the OXC, and an error generated when an error occurs in the optical signal path. Modify The path monitoring controller 90 includes a switch controller 92, a comparator 94, and a switching table 96. The switching table 96 stores predetermined switching / routing information. The comparator 94 compares the path monitoring information input from the input port and the frequency detector 78, that is, the predetermined switching / routing information to the switching table 96 and the path table of the input optical signal. The comparator 94 indicates that an incorrect switching, that is, a path error, occurs in the OXC when the path monitoring information and the predetermined switching / routing information differ from each other. The switch controller 92 corrects the path of the optical signal by controlling the switching of the optical switches 60 when erroneous switching occurs.

5 is a view showing a time frame used in the optical signal path monitoring and control device for OXC having the variable wavelength converter. Referring to FIG. 5, the time frame is composed of main frames. 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.

An optical signal path monitoring apparatus for an OXC having a variable wavelength converter according to an embodiment of the present invention monitors a path of an input optical signal through a path monitoring signal using a time frame as described above, and when a path error occurs, Correct the path of the optical signal.

 FIG. 6 is a diagram illustrating an example of outputting a path monitoring signal in an OXC optical signal path monitoring and control device having a variable wavelength converter according to an exemplary embodiment of the present invention. Show signal output example.

Referring to FIG. 6, a subframe represents an input port. For example, subframe 1 represents the first input port, subframe 2 represents the second input port, and subframe N represents the Nth input port. In addition, the frequency of f _i located in each subframe represents λ _i wavelength. For example, the f ₁ frequency represents lambda ₁ wavelength, the f ₂ frequency represents lambda ₂ wavelength, and the f _i frequency represents lambda _i wavelength. For example, if the f ₂ frequency is located in the subframe 1 section, the subframe 1 means the input port 1 and the f ₂ frequency represents the λ ₂ wavelength, which means that the λ ₂ wavelength is 1 at the input port 1 It means that it is switched to the output. When the f ₃ frequency is located in the subframe 2 section, the subframe 2 means the input port 2, and the f ₃ frequency represents the λ ₃ wavelength, which means that the λ ₃ wavelength is output from the input port 2 to the 1 output. It means that it is switched. In addition, when the f ₇ frequency is located in the subframe N section, the subframe N means the N input port, and the f ₇ frequency represents the λ ₇ wavelength, which means that the λ ₇ wavelength is outputted once at the N input port. It means that it is switched to. Where λ ₂ , λ ₃ ,... ,? ₇ wavelengths are the conversion wavelengths converted in the variable wavelength converters 54-1 to 54-N. In the path monitoring method as described above, the switching path of the input port and the conversion wavelength can be known by the subframe and the wavelength, but the input wavelength (the wavelength before the conversion) input to the input port is unknown. However, in order to perform path monitoring in an OXC equipped with a variable wavelength converter, the wavelength information before conversion must also be known. Therefore, the path monitoring and control apparatus for OXC having a variable wavelength converter according to an exemplary embodiment of the present invention is configured to detect and convert in which subframe and in which time slot the frequency of f _i is located at a specific output. Find the previous input wavelength information. For example, the OXC path monitoring and control device having a variable wavelength converter according to the present invention has a conversion wavelength λ input to the x th input port when a frequency f _i is located in a y th time slot within an x th subframe at a specific output. The switching path of _i is found and the input wavelength λ _k before conversion of λ _i . K is obtained by the following equation.

k = j-i + 1, j ≥ i

k = j-i + 1 + n where j <i

Where k is the wavelength number before conversion, i is the detected path monitoring frequency number, j is the time slot number where the path monitoring frequency is located, and n is the number of wavelengths. When the wavelength before the conversion from the path monitoring signal is obtained using Equation 1, it is shown in Table 1 below. Table 1 below shows the pre-conversion wavelengths obtained when the number of input wavelengths is 16.

Referring to Table 1, for example, when the input port number x is 1, the converted wavelength (switching wavelength) number i is 2, and the time slot number j is 2, j = i, so that the wavelength number k before conversion j-i + 1 = 2-2 + 1 = 1, and the wavelength before conversion is determined by lambda ₁ . When the number x of the input port is 2, the converted wavelength (switching wavelength) number i is 3, and the time slot number j is 1, j <i, the wavelength number before conversion k = j-i + 1 + n = 1-3 + 1 + 16 = 15, and the wavelength before conversion is determined by λ ₁₅ . In addition, when the input port number x is 16, the converted wavelength (switching wavelength) number i is 7, and the time slot number j is 16, j> i, so the wavelength number before conversion k = j-i + 1 = 16- 7 + 1 = 10, and the wavelength before conversion is determined by λ ₁₀ .

As described above, the OXC path monitoring and control device having a variable wavelength converter according to an embodiment of the present invention detects a wavelength corresponding to the frequency of f _i in the path monitoring signal of the output terminal, and the frequency of f _i It detects which time slot is located in the subframe to detect which wavelength is input from which input port and which output port is switched, and what is the input wavelength (the wavelength before conversion).

FIG. 7 is a diagram illustrating an example of a path monitoring signal input to the laser diode 36 of FIG. 2, and FIG. 8 is a diagram of an example of a path monitoring signal delayed by a time slot unit in the delay module 44 of FIG. 2. Drawing. FIG. 9 is a diagram illustrating an example of a path monitoring signal output from the first optical selectors 42 of FIG. 2, and FIG. 10 is a view of a path monitoring signal combined with input wavelengths of each input port of FIG. 2. An example is shown. FIG. 11 is a diagram illustrating an example of an optical signal path monitoring signal detected at each output of the OXC in FIG. 2.

2 to 11, the path monitoring and control apparatus for the OXC according to the present invention detects which wavelength is input from which input port and is switched to which output port, and what is the input (before conversion) wavelength to input the optical signal The operation of monitoring and controlling the path of the system will be described in detail.

Referring to FIG. 2, the frequency generators 32 generate one frequency per subframe of the frequencies f _{1 to} f _n , respectively. The generated frequencies f _{1 to} f _n are combined at a frequency of f _i in the frequency combiner 34. In this case, the frequency combiner 34 combines the frequencies of f _{1 to} f _n generated by the frequency generators 32 to generate a signal as shown in FIG. 7. In FIG. 7, frequencies of f _{1 to} f _n are located in each time slot. The combined frequencies of f _{1 to} f _n are modulated into an optical signal in a laser diode 36 having a wavelength λ _P. The modulated optical signal is separated into first to nth optical signals in the first optical splitter 38. The separated first to nth optical signals are respectively delayed by 0 to (n-1) time slot intervals through the first optical retarders 40, respectively. That is, as shown in FIG. 8, the first optical signal is not delayed, and the second optical signal has one (2-1 = 1) time slot intervals (T _TS / n, T _TS: sub frame length, n: Number of wavelengths). The n th optical signal is delayed by (n-1) time slot intervals [(n-1) / n] T _TS . As shown in FIG. 8, the delayed optical signals are input to the first light selectors 42. As shown in FIG. 8, the delayed optical signals pass through the first optical selectors 42 and only a specific optical signal (the optical signal located in the first subframe) is output. For example, referring to FIG. 9, FIG. 9A illustrates an example in which only optical signals located in subframe 1 of the delayed optical signals illustrated in FIG. 8 are output. 9B shows an example in which only optical signals located in subframe 2 among the delayed optical signals shown in FIG. 8 are output. In addition, FIG. 9C shows an example in which only optical signals positioned in subframe 3 are output from the delayed optical signals shown in FIG. 8.

Optical signals located in a specific subframe output from the first optical selectors 42 are input to the optical delay modules 44, respectively. Referring to FIG. 4, which shows a detailed configuration of the optical delay module 44-1, the specific optical signal output from the first optical selectors 42 is transmitted through the second optical splitter 2 to the first to Nth. Are separated into optical signals. The first to Nth optical signals separated from the second optical splitter 2 are delayed by the 0 to (N-1) subframe intervals through the second optical retarders 4, respectively. For example, as shown in FIG. 10A, the first optical signal of the optical signals separated from the second optical splitter 2 is not delayed through the second optical retarders 4. And as shown in (b) of FIG. 10, the first optical signal of the optical signals separated from the second optical splitter 2 is one (2-1 = 1) through the second optical retarders 4. Delayed by) subframe intervals (T _SF / N, T _SF: sub frame length). As shown in (c) of FIG. 10, the Nth optical signal of the optical signals separated from the second optical splitter 2 is (N-1) subs through the second optical retarders 4. Delayed by the frame interval [(N-1) / N] T _SF . As described above, the optical signals delayed by the sub-frame intervals through the second optical retarders 4 are input to each of the second optical selectors 48. The optical signals input to each of the second optical selectors 48 are selected by an optical signal of a particular f _i according to the OXC switching state and connected to the respective input wavelengths. In the embodiment of the present invention, it is assumed that the switching connection state is determined as shown in Table 2 below.

At each input port of the OXC, an optical signal having a wavelength of λ _{1 to} λ _n is inputted, and the optical signals are switched to output ports defined in Table 2 above. However, when the input optical signals are directly switched to the output ports, collisions between the same wavelengths may occur. The OXC thus converts the wavelength of the incoming optical signal to another wavelength to switch to the corresponding output ports to avoid collisions between wavelengths. Table 2 shows an input / output switching table when an input wavelength of an optical signal inputted through input ports 1 to N is converted into a corresponding conversion wavelength and output to a predetermined output port. Referring to Table 2, λ ₁ of the input wavelengths of the optical signal input to the input port 1 is outputted to the output port 2 without wavelength conversion, λ of the input wavelengths of the optical signal input to the input port 1 ₂ is wavelength-converted to λ _n-1 and outputted to output port 1. Among the input wavelengths of the optical signal input to the first input port, λ _n is wavelength-converted to λ ₃ and output to the N port. In addition, as shown in Table 2, the input wavelengths of the optical signals inputted through the input ports 2 to N are converted to the wavelength and output to the predetermined output port.

The second optical selectors 46 of the path monitoring information generating unit 30 switch only specific optical signals (path monitoring signals) according to the input / output switching table of Table 2 to change the wavelength converters 54-1 to 54. -N) combines with the conversion wavelengths output.

More specifically, as shown in Table 2, since the respective output wavelengths of the variable wavelength converters 54-1 of the input port ₁ are λ _1, λ _n-1 , and λ ₃ , the second light selectors 46 are used. The first light selector 46-1-1 of the first light selector block 46-1 selects the frequency f ₁ of the path monitoring signals shown in FIG. 9B. The second optical selector 46-1-2 selects the frequency f _n-1 of the path monitoring signals shown in FIG. 9B, and the Nth optical selector 46-1-N selects FIG. 9. A frequency f ₃ is selected from the path monitoring signals shown in (b) of FIG.

The output wavelengths of the variable wavelength converters 54-2 of the second input port are λ _n, λ ₁ ,. , λ _2, so that the first light selector 46-2-1 of the second light selector block 46-2 of the second light selectors 46 is one of the path monitoring signals shown in FIG. 9C. f _n Select frequency. The second light selector 46-2-2 selects the frequency f ₁ of the path monitoring signals shown in FIG. 9C, and the N-th light selector 46-2-N selects the frequency of FIG. Select the f ₂ frequency among the path monitoring signals shown in c).

In addition, the output wavelengths of the variable wavelength converters 54-N of the N input port are λ _2, λ _n ,. , λ _1, so that the first light selector 46-n-1 of the nth light selector block 46-n of the second light selectors 46 is one of the path monitoring signals shown in FIG. 9D. f ₂ Select the frequency. The second light selector 46-n-2 selects the frequency f _n among the path monitoring signals shown in FIG. 9D, and the N-th light selector 46-nN selects FIG. 9D. The frequency f ₁ is selected from the path monitoring signals shown in FIG.

As described above, the path monitoring signal selected by each of the second optical selectors 46 is as shown in FIG. 10. FIG. 10A illustrates a path monitoring signal output from the first light selector block 46-1 of the second light selectors 46. 10B illustrates a path monitoring signal output from the second light selector block 46-2 of the second light selectors 46. 10C illustrates a path monitoring signal output from the nth light selector block 46-n of the second light selectors 46.

The path monitoring signals shown in FIG. 10A are combined with the optical signals output from the variable wavelength converter 54-1 of the input port 1 through the optical couplers 55, and FIG. 10B. The path monitoring signals shown in FIG. 2 are combined with the optical signals output from the variable wavelength converter 54-2 of port 2 through the optical couplers 55. The path monitoring signals illustrated in FIG. 10C are combined with the optical signals output from the variable wavelength converter 54 -N of port N through the optical couplers 55. As described above, the path monitoring signals having the λ _p wavelength combined with the input optical signals are switched to each output through the optical switches 60 according to the switching information as shown in Table 2. The switched optical signals and the path monitoring signals having a wavelength of λ _p are multiplexed in the wavelength multiplexers 60 and then input to the optical circulators 72. The optical circulators 72 advance the optical signal output from the wavelength multiplexers 65 to the reflection filter 76 and output the optical signal reflected from the reflection filter 76 to the light sensor 74. . The reflection filters 76 reflect the path monitoring wavelength λ _P corresponding to the path monitoring information among the optical signals output from the optical circulators 72 and generate outputs 1 to N. The light detectors 74 convert the path monitoring wavelength λ _P reflected from the reflection filters 76 into an electric signal. The electrical signal converted from the light detectors 74 is as shown in FIG. 11, the output 1, the frequencies of f _n-1 is detected in the n-th time slot in the subframe 1, and the frequency of f _n detected at the n-th time slot in sub-frame 2 n-th in the subframe N A frequency of f ₁ is detected in the timeslot. In output 2, the frequency of f ₁ is detected in the first timeslot in subframe _1, the frequency of f ₂ is detected in the first timeslot in subframe _{2 and} the frequency of f _{n in} the first timeslot in subframe N. Is detected. In output N, the frequency of f ₃ is detected in the second timeslot in subframe _1, the frequency of f ₁ is detected in the second timeslot in subframe _{2 and} the frequency of f _{2 in} the _second timeslot in subframe N. Is detected.

The path monitoring signal detected in FIG. 11 is input to an input port and a frequency detector 78. Signals input to the input port and the frequency detector 78 are separated into n through the electrical signal splitters 78-1, as shown in FIG. 4, and then input to the bandpass filter string 78-2. do. The bandpass filter sequence 78-2 detects a frequency component of f _{i in} the separated signals for each wavelength, and the detected frequency components of f _i are input to the sub-frame and the wavelength detectors 78-3. The subframe and wavelength detectors 78-3 detect the wavelength corresponding to the frequency of each f _i output from the bandpass filter sequence 78-2, and detect the subframe in which the frequency of each f _i is located. . In this case, the wavelength corresponding to the frequency of f _i represents the wavelength number of the switched optical signals, and the sub frame number where the frequency of each f _i is located represents the input port. After the input port and the wavelength are identified through the frequency detection of the subframe and f _i as described above, the path monitoring signal is input to the timeslot detectors 78-3. The timeslot detectors 78-3 identify the wavelength number before the input optical signals are wavelength converted in the variable wavelength converters 54-1 to 54-N using Equation 1 described above. The OXC switching table generator 78-4 generates a switching table between the input optical OXC input and output ports using the detected wavelength, subframe, and time slot information as shown in Table 3 below.

The switching table generated as shown in Table 3 is compared with the switching table 96, for example, Table 2, which was previously determined through the comparator 94. At this time, the comparator 94 transmits an optical switch connection change signal to the switch controller 92 in order to correct the error because an incorrect switching occurs in the OXC when the actual switching information and the predetermined switching information are different. The switch controller 92 controls the optical switches 60 to modify the switching state of the optical signals. The switch controller 92 also controls the variable wavelength converters 54-1 to 54 -N of the OXC input stage and the first and second light selectors 42 and 46 in the path monitoring information generator 30. .

12 is a diagram illustrating a path monitoring signal generator according to a second embodiment in the OXC optical signal path monitoring and control device of FIG. 2. Referring to FIG. 12, unlike the path monitoring signal generator 30 of FIG. 2, the path monitoring signal generator 120 according to the second embodiment of the present invention may be output to the output parts of the first optical delay units 40. Instead of using the first light selectors 42, 1xn optical splitters 110 are used instead of the delay modules 44. As a result, the configuration of the path monitoring signal generator 120 may be simplified.

13 is a view for explaining the operation of the path monitoring signal generator 120 according to the second embodiment of the present invention. FIG. 13 illustrates a path monitoring signal input to the first light selector block 112-1 of the light selectors 112 of FIG. 12. The first optical selector block 112-1 detects a desired frequency of f _i according to a predetermined switching table among the path monitoring signals input. Referring to Table 1, the first optical selector block 112-1 detects a frequency of f ₁ in sub frame 1 among the path monitoring signals input, detects a frequency of f _n-1 in sub frame 2, The frequency of f ₃ in subframe N is detected. The frequencies detected from the first optical selector block 112-1 generate an optical signal path monitoring signal as shown in FIG. 10A. Meanwhile, the optical signal path monitoring signal generation method as described above is applied to the second optical selector block 112-2 and the third switch block 112-3 as it is.

As described above, the present invention relates to an optical signal path monitoring / modification apparatus for an all-optical OXC, and unlike the conventional method, an OXC having a tunable wavelength conversion function checks an optical signal path to correct an optical signal path when an error occurs. To be able. That is, the present invention detects the wavelength and the input port of the input optical signal through the subframe and time slot in which the predetermined frequency and the predetermined frequency are located in the OXC having a wavelength tunable conversion function, and then checks the switching path of the input optical signal and generates an error. In this case, an optical signal path monitoring / modifying device capable of modifying an optical signal path may be provided. Therefore, the optical signal path monitoring / modification apparatus in the OXC having the wavelength variable conversion function of the present invention can be utilized very efficiently when a dynamic all-optical communication network is constructed in the future.

1 is a view showing the configuration of the optical signal path monitoring and control device for OXC according to the prior art showing the configuration of the optical signal path monitoring device

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

3 is a view showing a detailed configuration of a delay module in the optical signal path monitoring and control device for OXC of FIG.

4 is a diagram illustrating a detailed configuration of an input port and a frequency detector in the optical signal path monitoring and control device for the OXC of FIG.

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

6 is a diagram illustrating an example of outputting a path monitoring signal in the optical signal path monitoring and control device for OXC of FIG.

7 is a diagram illustrating an example of a path monitoring signal input to a laser diode in FIG. 2;

FIG. 8 is a diagram illustrating an example of a path monitoring signal delayed in units of timeslots in the delay module of FIG. 2.

FIG. 9 is a diagram illustrating an example of a path monitoring signal output from an on / off switch of FIG. 2; FIG.

FIG. 10 is a diagram illustrating an example of a path monitoring signal combined with input wavelengths of each input port of FIG. 2. FIG.

FIG. 11 is a diagram illustrating an example of an optical signal path monitoring signal detected at each output in FIG. 2; FIG.

FIG. 12 is a diagram illustrating a path monitoring signal generator according to a second embodiment in the OXC optical signal path monitoring and control device of FIG. 2;

13 is a view for explaining the operation of the path monitoring signal generator according to a second embodiment of the present invention;

Claims (8)

A wavelength path monitoring / modification apparatus of an all-optical optical cross-connect (OXC) of a wavelength division multiplexing optical communication network having a variable wavelength conversion function, A plurality of input units configured to receive a predetermined multiplexed signal of a predetermined number n of different wavelengths, demultiplex the received multiplexed signal, and convert the demultiplexed predetermined n wavelengths to output a converted wavelength; Path monitoring that selects one wavelength for path monitoring from among the n conversion wavelengths output from each of the input units by using the self-generated frequency n and information stored in a preset switching table. A path monitoring information generation unit generating and outputting a signal; A plurality of optocouplers for coupling a predetermined number of conversion wavelengths output from each of the input units and the path monitoring signals output from the path monitoring information generator in a one-to-one correspondence; Multiple wavelength multiplexers, A plurality of optical switches corresponding to each of the optical couplers and switching a predetermined number (n) of signals input from the corresponding optical couplers to each of the wavelength multiplexers using information stored in a preset switching table; , A path monitoring information detector for detecting a path monitoring signal from each of the optical signals output from each of the wavelength multiplexers, converting the path monitoring signal into an electric signal, and detecting current switching information of the optical signals input to the OXC based on the electric signal; , And a path monitoring controller configured to store the preset switching table, compare the current switching information detected by the path monitoring information detection unit with the switching table, determine whether a path abnormality occurs, and correct the path where the path abnormality occurred. Featuring wavelength path monitoring / correction in all-optical OXCs. The method of claim 1, wherein the input unit, A wavelength demultiplexer configured to receive and demultiplex a predetermined multiplexed signal of different wavelengths n;  And variable wavelength converters for converting the demultiplexed predetermined wavelengths (n) and outputting the converted wavelengths, respectively. The method of claim 1, wherein the path monitoring information generation unit, Frequency generators for generating a predetermined number of frequencies; A combiner for combining the generated frequencies into a frequency signal modulated in a time division manner; An optical modulator for optically modulating the combined frequencies; A splitter for splitting an optical signal output from the optical modulator by a predetermined number (n); Optical delayers for delaying each of the divided optical signals by different timeslot intervals according to the order of the input optical signals; First optical selectors for selecting and outputting only optical signals positioned in a first subframe with respect to the optical signals output from the optical delay unit; A delay module for dividing the optical signals output from the first optical selectors into predetermined N optical signals and delaying each of the optical signals in sub-frame interval units; Wavelength path monitoring in the all-optical OXC comprising second optical selectors for selecting only specific optical signals and outputting them as path monitoring signals according to information stored in a preset switching table for the optical signals output from the delay module. / Fixation device. The method of claim 1, wherein the path monitoring information detection unit, Reflection filters for reflecting an optical signal corresponding to the path monitoring signal among the optical signals output from the wavelength multiplexers; Optical circulators for passing the optical signals output from the wavelength multiplexers to the reflective filters and detecting a path monitoring signal reflected from the reflective filters; Optical detectors for converting the detected path monitoring signal into an electrical signal; And a subframe and frequency detector for detecting the current switching information of the optical signals inputted to the OXC by detecting the subframe, the wavelength information and the timeslot information in the converted electrical signal. / Fixation device. The method of claim 1, wherein the route monitoring information control unit, A switching table for storing switching information input in advance; A comparator for comparing current switching information detected from the path monitoring information detector with information stored in the switching table; And a switch controller for modifying a switching path when the current switching information and the information stored in the switching table are different as a result of the comparison. The method of claim 4, wherein the sub-frame and the frequency detector, Optical splitters for splitting the electrical signal converted by the optical detector for each wavelength, Bandpass filter strings for detecting and outputting a path monitoring frequency component from each of the divided signals for each wavelength; Wavelength and subframe detectors for detecting wavelength information of each path monitoring frequency output from the bandpass filter sequences, and detecting subframe information in which each path monitoring frequency is located; Timeslot detectors for detecting timeslot information in which each path monitoring frequency output from the bandpass filter sequences is located; And a switching table generator for obtaining wavelength information of an input optical signal by using the wavelength and subframe information and time slot information, and obtaining and tabulating the switching path information of the input optical signal. Fix device. The method of claim 6, The wavelength information of the path monitoring frequency is a conversion wavelength number for identifying conversion wavelengths output from the input units, and the subframe information is an input port number for identifying an input port for inputting a multiplex signal to the input unit. Wavelength path monitoring / correction apparatus in the all-optical OXC, characterized in that the wavelength information of the input optical signal is the input wavelength number. The method of claim 7, wherein An input wavelength number input to the input unit is a wavelength path monitoring / correction device in the all-optical OXC, characterized in that obtained by the following equation (2). k = j-i + 1, j ≥ i k = j-i + 1 + n where j <i k is the input wavelength number input to the input unit i is the path monitoring frequency number detected in the bandpass filter sequence j is a time slot number where the path monitoring frequency is located n is the number of input wavelengths input to the input unit