JP3926162B2 - Wavelength multiplex transmission equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a wavelength division multiplex transmission device, and in particular, groups a plurality of wavelengths into i (i is an integer of 2 or more) wavelength bands, performs band dispersion compensation for each of these wavelength bands, and then performs wavelength bands. The present invention relates to a wavelength division multiplex transmission apparatus that multiplexes and transmits transmission.
[0002]
[Prior art]
An example of such a conventional wavelength division multiplexing transmission apparatus will be described with reference to a block diagram shown in FIG. In FIG. 8, a group of optical signals λ1-1 to λ1-j having j different wavelengths input from the outside are input to the wavelength multiplexer 3-1 and multiplexed into the optical signals in the first wavelength band. . The optical signals λ2-1 to λ2-k having different wavelengths input from the outside are input to the wavelength multiplexing unit 3-2 and multiplexed into the optical signal of the second wavelength band. The optical signals λi-1 to λi-n having n different wavelengths inputted from the outside are inputted to the wavelength multiplexing unit 3-i and multiplexed into the optical signals in the i-th wavelength band.
[0003]
FIG. 9 shows the relationship between the first to i-th wavelength bands and the wavelengths constituting them.
[0004]
The optical multiplexed signals converted from the first to i-th wavelength bands by these wavelength multiplexing units 3-1 to 3-i are input to the band dispersion compensation units 4-1 to 4-i, respectively, for each wavelength band. Dispersion compensation is performed. Each output after dispersion compensation is multiplexed by the band multiplexing unit 10 and led to an optical transmission line (not shown) as a wavelength multiplexed optical signal.
[0005]
The wavelength multiplexing unit 3-1 includes optical compensators 311-1 to 311-j that perform dispersion compensation on the input optical signals λ1-1 to λ1-j in advance, and optical signals from the dispersion compensator 311-1 during normal operation. When the optical signal from the dispersion compensator 311-1 disappears, the pseudo optical signal having the wavelength λ1-1 input from the pseudo optical signal generation unit 20 is selected and output p (p: positive integer) Optical signal selectors 312-1 arranged every other wavelength, optical amplifiers 313-1 to 313-j for compensating for the insertion loss of the dispersion compensator and varying the output power in units of each wavelength at the device output; , And an optical multiplexer 310 that wavelength-multiplexes j optical signals input from the optical amplifiers 313-1 to 313-j into one optical signal and outputs the optical signal. The other wavelength multiplexing units 3-2 to 3-i have the same configuration as the wavelength multiplexing unit 3-1.
[0006]
The band dispersion compensation unit 4-1 includes an optical amplifier 42-1 that amplifies only an optical signal in a predetermined band to a predetermined level with respect to the optical signal output from the wavelength multiplexing unit 3-1, and the optical amplifier 42-1. A band dispersion compensator 43-1 for compensating the dispersion of the output optical signal, and an optical amplifier 44 for amplifying only an optical signal in a predetermined band to a predetermined level in order to compensate for an insertion loss of the band dispersion compensator 43-1. -1. The other band dispersion compensation units 4-2 to 4-i have the same configuration.
[0007]
The band multiplex unit 10, in order to prevent the optical SNR from being deteriorated by ASE light (amplified spontaneous emission light) when i optical signals are wavelength-multiplexed by the optical coupler 13, the band dispersion compensator 4-1 ..., 4-i, optical bandpass filters 12-1 to 12-i that pass only optical signals in a predetermined band, and i input from the optical bandpass filters 12-1 to 12-i. 9 and an optical amplifier 14 that amplifies the optical signals in all the wavelength bands of FIG. 9 to a predetermined level in order to compensate for the insertion loss due to the optical bandpass filter and the optical multiplexer. And a single dispersion compensator 15 that compensates for the dispersion of the zero dispersion wavelength of the transmission line, and an optical amplifier 16 that compensates for the insertion loss of the single dispersion compensator 15 and amplifies it to a predetermined level. .
[0008]
As shown in FIG. 10, the pseudo optical signal generator 20 creates and outputs q (q: positive integer) types of pseudo signals for the first wavelength band (1) and outputs them. The pseudo optical signal generating unit 20-1 for the wavelength band 1 composed of 1 to 201-q, and similarly, r (r: positive integer) types of pseudo signals are generated and output for the second wavelength band (2). Wavelength band 2 pseudo optical signal generating unit 20-2 and wavelength band i pseudo optical signal for generating and outputting s (s: positive integer) types of pseudo signals for the i th wavelength band i. It consists of generating part 20-i.
[0009]
The simulated optical signal output from the simulated optical signal generation unit 20 is used to reduce fluctuations in the total power level output from the apparatus and the power level for each wavelength. In order to be inserted via the optical signal selector in the wavelength multiplexing unit, as an example, even when only the wavelength band 1 is used among the wavelength bands divided into i, the wavelengths in other wavelength bands Multiplexers 3-2 to 3 -i and band dispersion compensators 4-2 to 4-i for other wavelength bands are also required.
[0010]
The optical signal selectors 312-1 to 3i2-1 and the like are assumed to be controlled in a selected state by a control circuit (not shown).
[0011]
[Problems to be solved by the invention]
Therefore, the conventional wavelength division multiplexing apparatus shown in FIG. 8 can be expanded in the in-service state, but all blocks are required even when the number of wavelengths used in the initial stage is small. There are disadvantages that the price is high and a large floor area is required to install all the blocks.
[0012]
The object of the present invention is to reduce the initial introduction price and reduce the installation floor area of the apparatus when the number of wavelengths used in the initial stage is small, and the wavelengths that can be added in the in-service state in the future. It is to provide a multiplex transmission apparatus.
[0013]
[Means for Solving the Problems]
A wavelength division multiplexing transmission apparatus according to the present invention dispersion-compensates a plurality of wavelength multiplexing means each for multiplexing a plurality of input optical signal groups having different wavelengths into one wavelength band, and each wavelength band output of these wavelength multiplexing means. A wavelength division multiplex transmission apparatus including a plurality of band dispersion compensating means and a band multiplexing means for multiplexing and transmitting each wavelength band output of the plurality of band dispersion compensating means, each of the plurality of wavelength bands In response to the above, pseudo optical signal generating means for generating one or a plurality of predetermined pseudo wavelength signals included in these corresponding wavelength bands and a pseudo multiplexed signal obtained by multiplexing these pseudo wavelength signals; in each input of the plurality of wavelength multiplexing means, and the optical signal selection means for outputting the input optical signal corresponding to said pseudo wavelength signal generated from said pseudo optical signal generating means selectively, wherein High bandwidth At a plurality of respective join the club means, characterized in that it includes an optical signal switching means for outputting the switching between the pseudo-multiplexed signal corresponding thereto and each of the wavelength bands output.
[0014]
When there is an unused wavelength band among the plurality of wavelength bands, the optical signal switching means corresponding to the unused wavelength band is controlled to be switched to the pseudo multiplexed signal from the pseudo optical signal generating means. It is characterized by that. Further, when the input optical signal corresponding to the pseudo wavelength signal disappears, the optical signal selection means corresponding to the lost input optical signal is switched to the pseudo wavelength signal. Each of the plurality of wavelength multiplexing means includes a chromatic dispersion compensator that dispersion-compensates each wavelength signal of the input optical signal group, and each of the optical signal selection means includes the chromatic dispersion compensator. It is provided in the output stage.
[0015]
Another wavelength multiplexing transmission apparatus according to the present invention distributes a plurality of wavelength multiplexing means each for multiplexing a plurality of input optical signal groups having different wavelengths into one wavelength band, and each wavelength band output of these wavelength multiplexing means. A wavelength division multiplexing transmission apparatus comprising: a plurality of band dispersion compensating means for compensating; and a band multiplexing means for multiplexing and transmitting each wavelength band output of the plurality of band dispersion compensating means, wherein the plurality of wavelength bands Corresponding to each of the above, a pseudo optical signal generating means for generating a pseudo multiplex signal in which one or a plurality of types of pseudo wavelength signals included in these corresponding wavelength bands are multiplexed, and the band dispersion compensating means in each join the club of switching the pseudo optical signal insertion means for inserting the pseudo multiplexed signal, at a plurality of respective join the club of the band multiplexing means, and said pseudo-multiplexed signal corresponding thereto and each of the wavelength bands output Characterized in that it includes an optical signal switching means for outputting Te.
[0016]
When there is an unused wavelength band among the plurality of wavelength bands, the optical signal switching means corresponding to the unused wavelength band is controlled to be switched to the pseudo multiplexed signal from the pseudo optical signal generating means. It is characterized by that.
[0017]
The operation of the present invention will be described. A plurality of wavelength optical signals are grouped into i wavelength bands, and the wavelength is used in the order of using all the optical signals of wavelengths within a certain wavelength band. Even if the number of wavelengths used is changed in a wavelength multiplex transmission device that is defined so that i wavelength bands are sequentially used, such as using an optical signal in the optical signal, it is output from the device. A pseudo optical signal that is used to reduce fluctuations in the total power level and the power level per wavelength is inserted. When such a quasi-optical signal insertion type wavelength division multiplexing transmission apparatus is introduced, even when the number of wavelengths used at the initial stage is small, wavelength multiplexing units and band dispersion corresponding to i (that is, all) wavelength bands are used. What is necessary to eliminate the fluctuation of the total power level of the device output by providing a compensation unit is simulated in the input unit of each wavelength band in the band multiplexing unit that multiplexes all the optical signals of i wavelength bands. By inserting the optical signal, it is only necessary to provide only the wavelength multiplexing unit and the band dispersion compensation unit corresponding to the wavelength band to be used.
[0018]
Therefore, when the number of wavelengths used at the initial stage is small, the initial introduction price is low, the floor area to be installed is small, and the number of wavelengths in the in-service state can be increased in the future.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram of an embodiment of the present invention, and the same parts as those in FIG. In FIG. 1, only the points different from the conventional block of FIG. 8 will be described. In the present embodiment, the optical signal switches 11-1 to 11-i are connected to the respective wavelength band input units of the band multiplexing unit 10 (that is, the output units of the band dispersion compensation units 4-1 to 4-i). It is provided for wavelength bands. Each of the optical signal switchers 11-1 to 11-i selectively switches between the output of each band dispersion compensator 4-1 to 4-i and the pseudo wavelength signal generated from the pseudo optical signal generator 20. is there.
[0020]
The configuration of the simulated optical signal generation unit 20 is shown in FIG. Referring to FIG. 4, the pseudo optical signal generation unit 20 includes pseudo optical signal generation blocks 20-1 to 20-i corresponding to the first to i-th wavelength bands, respectively. The block 20-1 generates pseudo optical signal generators 201-1 to 201-q that generate and output q types of pseudo optical signals, and outputs of these pseudo optical signal generators 201-1 to 201-q. Each of the two branches, one wavelength multiplexing unit 3-1 is also output to the optical signal selector, the other one is q optical couplers 211-1 to 211-q to be output to the optical multiplexer 213, An optical multiplexer 213 that wavelength-multiplexes q types of pseudo optical signals input from these q optical couplers, and an optical signal switch 11 of the band multiplexer 10 after adjusting the combined optical signal to a predetermined level. And an optical amplifier 214 that outputs to -1.
[0021]
Similarly, the block 20-2 for the second wavelength band includes pseudo optical signal generators 202-1 to 202-r that generate and output r types of pseudo optical signals, and these pseudo optical signal generators 202. -1 to 202-r, each of which has two branches, one is directly output to the optical signal selector of the wavelength multiplexing unit 3-2, and the other is r optical couplers output to the optical multiplexer 223 221-1 to 221-r, an optical multiplexer 223 that wavelength-multiplexes r types of pseudo optical signals input from the r optical couplers, and a combined optical signal that is adjusted to a predetermined level. And an optical amplifier 224 that outputs to the optical signal unit switch 11-2 of the multiplexing unit 10.
[0022]
Similarly, the block 20-i for the i-th wavelength band includes pseudo optical signal generators 20i-1 to 20i-s that generate and output S types of pseudo optical signals, and these pseudo optical signal generators 20i. The outputs of -1 to 20i-s are branched into two, one is directly output to the optical signal selector of the wavelength multiplexing unit 3-i, and the other is s optical couplers output to the optical multiplexer 2i3 2i1-1 to 2i1-s, an optical multiplexer 2i3 that wavelength-multiplexes s types of pseudo optical signals input from these s optical couplers, and a combined optical signal that is adjusted to a predetermined level. And an optical amplifier 2 i 4 that outputs to the optical signal switching unit 11-i of the multiplexing unit 10.
[0023]
2 and 3 show two examples of the optical signal switch 11-1 in FIG. 1, and the other optical signal switches 11-2 to 11-i have the same configuration. The example of FIG. 2 uses a 2 × 1 optical switch that is switched without interruption, and the example of FIG. 3 is configured by two optical attenuators a and b and an optical coupler c.
[0024]
In the example of FIG. 3, when an optical signal from the input B is derived instead of the optical signal from the input A, an optical attenuator is used so that the optical power level at the output C is always the same. The reduction amount of a is gradually increased, and at the same time, the attenuation amount of the optical attenuator b is gradually reduced. Conversely, when the optical signal from the input A is derived instead of the optical signal from the input B to the output C, the attenuation of the optical attenuator a so that the optical power level at the output C is always the same. The amount is gradually decreased, and at the same time, the amount of attenuation of the optical attenuator b is controlled to gradually increase.
[0025]
Other configurations are the same as those of the conventional example of FIG. The internal configurations of the dispersion compensator, optical amplifier, optical multiplexer, and the like in FIG. 1 are well known to those skilled in the art and are not directly related to the present invention, and thus detailed description thereof will be omitted. In addition, the receiving device is not directly related to the present invention, and thus the description thereof is also omitted.
[0026]
In the configuration of FIG. 1 described above, for example, the case where only the first wavelength band among the wavelength bands grouped into i is used will be described. The optical signal from the compensation unit 4-1 is selected, and the other optical signal switches 11-2 to 11-i are the pseudo optical signals from the pseudo optical signal generation unit 20 (by the optical multiplexer 213 shown in FIG. 4). Control is performed by a control unit (not shown) so as to select (pseudo multiplexed signal).
[0027]
For the second to i-th wavelength bands, the wavelength multiplexing units 3-2 to 3-i and the band dispersion compensation units 4-2 to 4-i are not required, the initial introduction price is reduced, and the apparatus is installed. The floor space for the can be reduced. When the second wavelength band is used as the system is expanded, only the wavelength multiplexing unit 3-2 and the band dispersion compensation unit 4-2 are added and output from the band dispersion compensation unit 4-2. After confirming that the optical signal level of the second wavelength band is a predetermined level, the optical signal switch 11-2 in the band multiplexer 10 is changed from the pseudo multiplexed signal from the pseudo optical signal generator 20 to the band dispersion compensator. Control to switch to the optical signal from 4-2. By doing so, it is possible to increase the wavelength without affecting the first wavelength band in the in-service state.
[0028]
FIG. 5 is a block diagram of another embodiment of the present invention, in which an orthogonal polarization multiplexing method is used as the wavelength multiplexing method. The wavelength multiplexing unit 3-1 when this orthogonal polarization multiplexing method is employed will be described with reference to FIG.
[0029]
The example of FIG. 5 shows an example in which the optical signal selectors are arranged at odd wavelength numbers every other wavelength. The wavelength multiplexing unit 3-1 includes an odd array polarization multiplexing unit 30-1, an even array polarization multiplexing unit 30-2, and a polarization orthogonal multiplexer 30-3. The odd array polarization multiplexing unit 30-1 includes a plurality of optical signal selectors 312-1 312-3,..., 312- (j-1) and a plurality of optical amplifiers 313-1, 313-3,. 313- (j-1) and a polarization maintaining optical multiplexer 30-1. The even-order polarization multiplexing unit 30-2 includes a plurality of optical amplifiers 313-2, 313-4,..., 313-j and a polarization maintaining optical multiplexer 310-2.
[0030]
The optical signals of odd array wavelengths λ1-1, λ1-3,..., Λ1− (j−1) input from the outside to the odd array polarization multiplexing unit 30-1 are held in a constant polarization direction. Polarization maintaining optical multiplexers that are input in a state and pass through polarization maintaining optical signal selectors 312-1 to 312- (j-1) and polarization maintaining optical amplifiers 313-1 to 313- (j-1). Polarization maintaining multiplexing is performed at 310-1. The optical signals of the even array wavelengths λ1-2, λ1-4,..., Λ1-i input from the outside to the even array polarization multiplexing unit 30-2 are orthogonal to the polarization of the optical signal of the odd array wavelength. And is polarization-maintained and multiplexed by the polarization-maintaining optical multiplexer 310-2 via the polarization-maintaining optical amplifiers 313-2 to 313-j.
[0031]
The multiplexed optical signal of the odd array polarization multiplexer 30-1 output from the polarization maintaining optical multiplexer 310-1 and the even array polarization multiplexer 30-2 output from the polarization maintaining optical multiplexer 310-2. The multiplexed optical signal is multiplexed by the polarization orthogonal multiplexer 30-3 while keeping the polarizations orthogonal to each other.
[0032]
The configuration of FIG. 5 is that of the wavelength multiplexing unit 3-1 for the first wavelength band, but the same configuration is also adopted for the second to i-th wavelength bands. The configuration of the subsequent stage of each of these wavelength multiplexing units is the same as that of the band dispersion compensation unit and band multiplexing unit of FIG.
[0033]
FIG. 6 is a block diagram of still another embodiment of the present invention, and the same parts as those in FIG. The present embodiment is an example in the case where the pseudo optical signal is inserted by the band dispersion compensation unit when the wavelength band is in use. In FIG. 6, only the parts different from FIG. 1 will be described. 6, the optical signal selectors 312-1 to 3i2-1 provided in the wavelength multiplexing units 3-1 to 3-i in FIG. 1 are omitted, and the band dispersion compensation units 4-1 to 4-i are omitted. In the input part, pseudo optical signal inserters 41-2 to 41-i are added.
[0034]
In this case, each of the optical amplifiers 42-1 to 42-i has a predetermined band in order to compensate for the insertion loss between the optical multiplexer and the pseudo optical signal inserter in the wavelength multiplexing units 3-1 to 3-i. Only the optical signal is amplified to a predetermined level.
[0035]
Each of these pseudo optical signal inserters 41-2 to 41-i receives a pseudo optical signal from the pseudo optical signal generation unit 20 with respect to the optical signal in the wavelength band that is the output of each of the wavelength multiplexing units 3-1 to 3-i. An optical signal is inserted so that the optical signal level input to the optical amplifiers 42-1 to 42-i is constant even if the number of wavelengths used for service within a certain wavelength band is different. This is for inserting the pseudo optical signal into the original optical signal.
[0036]
FIG. 7 is a diagram illustrating an example of the pseudo optical signal generation unit 20 in FIG. 6, and parts equivalent to those in FIG. 4 are denoted by the same reference numerals. In FIG. 7, the optical couplers 211-1 to 211 for the optical signals of the pseudo optical signal generators 201-1 to 201 -q, which describe the block 20-1 corresponding to the first wavelength band with respect to parts different from FIG. 4. Each of the branch outputs by −q is adjusted to a predetermined level by optical amplifiers 215-1 to 215-q, and multiplexed (multiplexed) by optical multiplexer 216. The pseudo multiplexed signal by the optical multiplexer 216 becomes an insertion signal in the pseudo signal inserter 41-1 in FIG.
[0037]
The other configuration is the same as that of the block 20-1 in FIG. Also, the blocks 20-2 to 20-i corresponding to other wavelength bands have the same configuration as the block 20-1 described above, and therefore their description will be omitted.
[0038]
Also in the present embodiment, optical signal switchers 11-1 to 11-i are provided at the input unit of the band multiplexer 10, and pseudo-multiplexed signals are supplied by this optical signal switcher for unused wavelength bands. Therefore, it is clear that there is an effect equivalent to that of the first embodiment.
[0039]
【The invention's effect】
As described above, according to the present invention, the pseudo optical signal is inserted at the input section of each wavelength band in the band multiplexing section that multiplexes all the optical signals of a plurality of wavelength bands. Since only the corresponding wavelength multiplexing unit and band dispersion compensation unit need be provided, when the number of wavelengths used at the initial stage is small, there is an effect that the initial introduction price is reduced and the apparatus installation area is also reduced. . In addition, there is an effect that the number of wavelengths in the in-service state can be easily increased in the future.
[Brief description of the drawings]
FIG. 1 is a block diagram of an embodiment of the present invention.
FIG. 2 is a diagram illustrating an example of the optical signal switching device in FIG. 1;
FIG. 3 is a diagram showing another example of the optical signal switch in FIG. 1;
4 is a diagram illustrating an example of a pseudo optical signal generation unit in FIG. 1; FIG.
FIG. 5 is a partial block diagram of another embodiment of the present invention.
FIG. 6 is a partial block diagram of still another embodiment of the present invention.
7 is a diagram illustrating an example of a pseudo optical signal generation unit in FIG. 6;
FIG. 8 is a block diagram illustrating a conventional example.
FIG. 9 is a diagram illustrating an example in which a plurality of wavelengths are grouped into i wavelength bands.
10 is a diagram illustrating an example of a pseudo optical signal generation unit in FIG. 8. FIG.
[Explanation of symbols]
3-1 to 3-i Wavelength multiplexing unit 4-1 to 4-i Band dispersion compensation unit 10 Band multiplexing unit 11-1 to 11-i Optical signal switch 13, 310, 320, 3i0 Optical multiplexer 20 Pseudo optical signal Generation units 312-1, 322-1, 3i2-1 optical signal selectors 41-1, 41-2, 41-i pseudo optical signal inserter

Claims (6)

A plurality of wavelength multiplexing means each for multiplexing a plurality of input optical signal groups of different wavelengths into one wavelength band;
A plurality of band dispersion compensation means for dispersion compensating each wavelength band output of these wavelength multiplexing means;
A wavelength division multiplexing transmission device including a band multiplexing unit for multiplexing and transmitting each wavelength band output of the plurality of band dispersion compensation units,
Corresponding to each of the plurality of wavelength bands, one or a plurality of predetermined pseudo wavelength signals included in the corresponding wavelength bands and a pseudo multiplexed signal obtained by multiplexing these pseudo wavelength signals are generated. Pseudo optical signal generating means for
An optical signal selection means for selectively outputting the pseudo wavelength signal generated from the pseudo optical signal generation means and an input optical signal corresponding thereto at each input section of the plurality of wavelength multiplexing means;
Optical signal switching means for switching and outputting each of the wavelength band outputs and the corresponding pseudo multiplexed signal at each of a plurality of input portions of the band multiplexing means ,
A wavelength division multiplexing transmission apparatus comprising: When there is an unused wavelength band among the plurality of wavelength bands, the optical signal switching unit corresponding to the unused wavelength band is controlled to be switched to the pseudo multiplexed signal from the pseudo optical signal generating unit. The wavelength division multiplexing transmission apparatus according to claim 1. 3. The optical signal selection unit corresponding to the lost input optical signal is switched to the pseudo wavelength signal when the input optical signal corresponding to the pseudo wavelength signal disappears. The wavelength division multiplexing transmission apparatus described. Each of the plurality of wavelength multiplexing means has a chromatic dispersion compensator for dispersion compensating each wavelength signal of the input optical signal group, and each of the optical signal selection means is an output of the chromatic dispersion compensator. The wavelength division multiplexing transmission device according to claim 1, wherein the wavelength division multiplexing transmission device is provided in a stage. A plurality of wavelength multiplexing means each for multiplexing a plurality of input optical signal groups of different wavelengths into one wavelength band;
A plurality of band dispersion compensation means for dispersion compensating each wavelength band output of these wavelength multiplexing means;
A wavelength division multiplexing transmission device including a band multiplexing unit for multiplexing and transmitting each wavelength band output of the plurality of band dispersion compensation units,
In correspondence with each of the plurality of wavelength bands, pseudo optical signal generating means for generating a pseudo multiplexed signal that is included in these corresponding wavelength bands and that multiplexes one or more types of pseudo wavelength signals, and
Pseudo optical signal inserting means for inserting the pseudo multiplexed signal at each input portion of the band dispersion compensating means;
Optical signal switching means for switching and outputting each of the wavelength band outputs and the corresponding pseudo multiplexed signal at each of a plurality of input portions of the band multiplexing means ,
A wavelength division multiplexing transmission apparatus comprising: When there is an unused wavelength band among the plurality of wavelength bands, the optical signal switching unit corresponding to the unused wavelength band is controlled to be switched to the pseudo multiplexed signal from the pseudo optical signal generating unit. The wavelength division multiplexing transmission apparatus according to claim 5.

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