CN1482814A - Full optical wavelength route cross module - Google Patents
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- CN1482814A CN1482814A CNA031283772A CN03128377A CN1482814A CN 1482814 A CN1482814 A CN 1482814A CN A031283772 A CNA031283772 A CN A031283772A CN 03128377 A CN03128377 A CN 03128377A CN 1482814 A CN1482814 A CN 1482814A
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Abstract
A total optical wavelength route intersecting module comprising an Er-doped fiber preliminary amplifier, de-multiplexer, optical space switch matrix, multiplexer or wave combiner, Er-doped fiber power amplifier, each of the L line output of the de-multiplexer is connected to the L optical space matrix input ends, the signal output end having the same wave length of the N de-multiplexer is connected to the same optical space matrix input ends, each of which is connected to the M multiplexers or wave combiners, the output ends of the L different optical space switch matrix are connected to each of the input end of the same multiplexer or the wave combiner. The module by the invention can not only realize the dynamic optical wavelength interchange, but also reduce the cost and technology difficulty.
Description
Technical field
The invention belongs to optical communication field, particularly realize the optical cross connect parts of light exchange, optical routing.
Background technology
Present stage, the empty wavelength channel route of realization Wavelength reuse in all-optical network must be used optical transponder unit and optical switch.Use at present the more light electro-optical type wavelength shifter that has, its defective is to have destroyed the form transparency of communication channel, and cuts along with the increasing of wavelength channel, and existing network node electronic equipment processing speed does not catch up with, and forms electronic bottleneck; On this external existing technology 0 level, the integrated scale of optical switch is limited.Therefore, Electronics Letters, 20
ThMarch 2003 Vol.39 No.6 have proposed optical cross-connect as shown in Figure 3, and it is made up of Er-doped fiber preamplifier 1, demodulation multiplexer 2, single mode connection optical fiber 3, multiplexer or wave multiplexer 5, Er-doped fiber power amplifier 8, the clog-free optical space switch matrix 9 of extensive integrated port number, all band continuously adjustable wavelength shifter 10.In general, this optical cross-connect is feasible for minority leading-edge fields such as space flight, aviation, universe explorations, and be used in the popular optical communication fields such as apparatus for network node neither appropriate also unnecessary, because all band continuously adjustable wavelength shifter 10 needs the big and expensive high accuracy tunable laser source of technical difficulty, this is unfavorable for promoting the use of in apparatus for network node; And be subjected to its structural limitations, if adopt the ripe full photofixation wavelength shifter of technical merit, can not realize dynamic wavelength exchange again; In addition, although adopted the clog-free optical space switch matrix 9 of extensive integrated port number, for will realize dense wave division multipurpose wavelength route in all-optical network, its integrated scale still dislikes not enough; In addition, do not have the wavelength modular character, poor expandability.The clog-free optical space switch matrix 9 of extensive integrated port number and all band continuously adjustable wavelength shifter 10, these 2 is present technological difficulties, the commercialization of these two devices also will be done more work.
Summary of the invention
The invention provides a kind of all-optical wave-length route Cross module, be difficult to realize and the limited problem of the integrated scale of optical switch to solve all band continuously adjustable LASER Light Source that exists in the prior art, reach the dynamic wavelength exchange, be implemented in the empty wavelength channel route that the all-optical network medium wavelength is reused.
A kind of all-optical wave-length route Cross module of the present invention, comprise N Er-doped fiber preamplifier, a N demodulation multiplexer, a M multiplexer or wave multiplexer, a M Er-doped fiber power amplifier, each road input optical fibre connects Er-doped fiber preamplifier, demodulation multiplexer successively in the input optical fibre of N road, M multiplexer or wave multiplexer connect the Er-doped fiber power amplifier separately, the latter connects output optical fibre and forms the output of M road, it is characterized in that:
(1) described each demodulation multiplexer L road output connects L optical space switch matrix input respectively, and N the identical signal output part of demodulation multiplexer wavelength is connected to same each input of optical space switch matrix;
(2) output of each optical space switch matrix is connected respectively to M multiplexer or wave multiplexer, is connected to same multiplexer or each input of wave multiplexer from the output of the individual different optical space switch matrixes of L;
Wavelength division multiplexing wavelength signals in every input optical fibre link is λ
1, λ
2..., λ
L, L is the wavelength signals number, is natural number; Above-mentioned N represents input optical fibre link number, and M represents output optical fibre link number, is natural number.
Described all-optical wave-length route Cross module, when needs were used to carry out wavelength Conversion, it was further characterized in that:
(1) it comprises that also the input and output port number average is wavelength Conversion selective light space switching matrix and L * J fixed wave length transducer of L * J, the corresponding λ of wherein every J fixed wave length transducer
1, λ
2..., λ
LIn a wavelength, a corresponding L wavelength altogether;
(2) wherein wavelength Conversion selective light space switching matrix input and output port number average is L * J, and the input port number of L optical space switch matrix respectively is that N+J, output port number respectively are M+J;
(3) input of the J of each optical space switch matrix output connection wavelength Conversion selective light space switching matrix, the every J of output of wavelength Conversion selective light space switching matrix is one group, connects J fixed wave length transducer of wavelength to be converted, the optical space switch matrix input of corresponding wavelength successively;
Above-mentioned J represents the fixed wave length transducer number that output valve is identical, 1≤J≤N.
Described all-optical wave-length route Cross module, being connected of described each demodulation multiplexer and optical space switch matrix, each optical space switch matrix and being connected of multiplexer or wave multiplexer can pass through monomode fiber.
The present invention compared with prior art has following major advantage:
One. provide a kind of, can realize the optional dynamic light wavelength exchange of wavelength shifter, lowered technical difficulty by commercial clog-free full optical space switch switching matrix and the discrete wavelength transducer that full photofixation wavelength shifter is combined into.
They are two years old. and use combining of fixed wave length transducer and optical switch matrix cheaply, reach the close performance of all band continuously adjustable wavelength shifter, and the port scale of the optical switch that uses can be very not big.
They are three years old. and the number of wavelengths that increases in the link does not need to change overall optical cross-connect agent structure, and extensibility is strong, can realize making all-optical wave-length router cheaply.
Therefore, help in apparatus for network node, promoting the use of.
Description of drawings
Fig. 1 is an all-optical wave-length route Cross module schematic diagram of the present invention.
Fig. 2 is the all-optical wave-length route Cross module structural representation that the present invention needs wavelength shifter.
Fig. 3 is a kind of structural representation of common optical cross-connect.
Fig. 4 is the performance curve of the present invention and optical cross-connect shown in Figure 3.
Embodiment
The invention will be further described below in conjunction with embodiment and accompanying drawing.
A kind of all-optical wave-length route Cross module of the present invention, its structure be as shown in Figure 1: comprise Er-doped fiber preamplifier 1, demodulation multiplexer 2, optical space switch matrix 4, multiplexer or wave multiplexer 5, Er-doped fiber power amplifier 8.The all-optical wave-length route Cross module that can be used for wavelength Conversion shown in Figure 2 also comprises wavelength Conversion selective light space switching matrix 6 and fixed wave length transducer 7.Connect optical fiber 3 by single mode, demodulation multiplexer 2, optical space switch matrix 4 and multiplexer or wave multiplexer 5 are connected successively, and optical space switch matrix 4, wavelength Conversion selective light space switching matrix 6, fixed wave length transducer 7 are connected successively with 4.
Above-mentioned Er-doped fiber preamplifier 1, demodulation multiplexer 2, optical space switch matrix 4, multiplexer or wave multiplexer 5, fixed wave length transducer 7, Er-doped fiber power amplifier 8 can have several, and its number is equal to or is not equal to.Optical space switch matrix 4 and wavelength Conversion selective light space switching matrix 6 can adopt OMM 115-320*1-0-4-* range of models product produced in USA, also can adopt other type product.Fixed wave length transducer 7, the ALCATEL1901ICM type product that can adopt France to produce also can adopt other type product.
Among Fig. 1, Fig. 2, Fig. 3: A
1, A
2A
NRepresent one group of input optical fibre (expression signal input part) that comes from different links, each optical fiber comprises optical wavelength division multiplexed signal.B
1, B
2B
MRepresent one group of optical fiber (expression signal output part) that leaves this cross-connect, every optical fiber carries the optical wavelength division multiplexed signal that reconfigures.N, M are natural numbers, represent input optical fibre link number, output optical fibre link number respectively, and it can equate or be unequal.
Among Fig. 4: curve 1 and the all-optical wave-length route Cross module of curve 2 difference corresponding diagram 2 and the performance curve of optical cross-connect shown in Figure 3.Article two, the corresponding input of curve, output optical fibre link number are N=M=16, and the wavelength-division multiplex signals number that comprises in every input, the output optical fibre link is L=32, and under this condition, transverse axis represents to connect occupancy, and vertical pivot is represented blocking probability.Connect occupancy less than 50 percent situation under, blocking performance shows that all-optical wave-length route Cross module of the present invention can satisfy frequent situation lower network and block running status less than 50 percent.
Operation principle of the present invention is:
Wavelength division multiplexing wavelength signals number in every optical fiber link is λ
1, λ
2..., λ
L, in several or all, so the wavelength signals number in each optical fiber link can equate or unequal that the maximum number of the different wavelength division multiplexing wavelength signals in all optical fiber links is L, L is a natural number.From different input optical fibre link A
1, A
2A
NOne group of wavelength-division multiplex signals (Fig. 1 left end), enter corresponding optical demultiplexer 2 (DEMUX) later on by Er-doped fiber preamplifier 1 (EDFA, quantity is N) compensation signal attenuation separately, the number of optical demultiplexer 2 is N, from each optical fiber link A
1, A
2A
NIdentical wavelength signals (the λ that middle demultiplexing comes out
1, λ
2..., λ
L) marshalling (sign of lambda is represented different wavelength signals in conjunction with subscript), the identical λ that is of wavelength signals
iThe wavelength signals of (i is the natural number from 1 to L) is input to same clog-free optical space switch matrix 4 by monomode fiber 3 connections, the corresponding input of 4 left ends among Fig. 1, the corresponding output of right-hand member, it is N+J that the optical fiber link number N that its input port number equals to import adds J, it is M+J that the optical fiber link number M that its output port number equals to export adds J, and J is from one of natural number of 1 to N; The configured number of this optical switch matrix 4 is that the maximum wavelength that system uses is counted L in the whole all-optical wave-length route Cross module.Under the effect of the electric controller of wavelength routing algorithm, the light signal λ of any one input port
iCan be by clog-free optical space switch matrix 4 assignment exchange to any output port, the light signal λ that obtains from clog-free optical space switch matrix 4 each output port
iWavelength Conversion just is connected to a wavelength Conversion selective light space switching matrix 6 if desired, (the corresponding input of 6 right-hand members among Fig. 2, the corresponding output of its left end, its input and output port number equates and is that L * J) (right-hand member is an input among Fig. 2 with a plurality of fixed wave length transducers 7, left end is an output, the number of the wavelength shifter that output valve is identical is J, and the number of the wavelength shifter group that output valve is different is L) input of the discrete type wavelength shifter formed, this moment original optical wavelength signal λ
iIn information be converted to λ by fixed wave length transducer 7
kCan exchange to the carrier wavelength lambda of appointment
k(k is not equal to i, the mutual conversion between the expression different wave length, identical wavelength can not be changed mutually) on, realize the wavelength exchange, the wavelength signals λ after the conversion
kIt is identical with this wavelength and be λ to be re-entered input again
k Optical switch matrix 4, to reselect route; If wavelength signals λ
iDo not need wavelength Conversion just by clog-free optical space switch matrix 4 according to the routing rule assignment exchange to those output ports of 4 that is connected with multiplexer or wave multiplexer 5, be connected to the input port of multiplexer or wave multiplexer 5 then by monomode fiber, its connection is can not have to surpass one and be connected to multiplexer or wave multiplexer 5 from same clog-free optical space switch matrix 4 output ports, that is to say that the monomode fiber that is connected with multiplexer or wave multiplexer 5 inputs can only come from different clog-free optical space switch matrix 4 outputs.The input port number of multiplexer or wave multiplexer 5 is L, and the multiplexer of required configuration or wave multiplexer 5 numbers are M (M is a natural number, and is generally equal with N, also can be unequal) in the module.Should be all to output to the multiplexing or wave multiplexer of corresponding multiplexer later on respectively through the optical wavelength signal of routing and close ripple, be sent to optical fiber link (B by Er-doped fiber power amplifier 8 (quantity is M) then by equal power
1, B
2..., B
M), transmit optical wavelength signal to next stage optical routing node (wherein can comprise and be same as all-optical wave-length route Cross module of the present invention).
In brief, the wavelength signals in the Networks of Fiber Communications is by the present invention, and the optical wavelength signal of input link port can select to exchange to output optical fibre link port arbitrarily arbitrarily, and can realize the wavelength exchange by the assignment requirement.Illustrate N=M=8, L=16, during J=1, the number of Er-doped fiber preamplifier 1 required for the present invention is 8, type is that the number of 1 * 8 demodulation multiplexer 2 is 8, the number of optical space switch matrix 4 is 16 (its input/output port is N+1=9), the number of wavelength Conversion selective light space switching matrix 6 is 1 (its input/output port is 8), the number of fixed wave length transducer 7 is 8, type is that the number of 8 * 1 multiplexers or wave multiplexer 5 is 8, and Er-doped fiber power amplifier 8 numbers are 8.
Claims (3)
1. all-optical wave-length route Cross module, comprise N Er-doped fiber preamplifier, a N demodulation multiplexer, a M multiplexer or wave multiplexer, a M Er-doped fiber power amplifier, each road input optical fibre connects Er-doped fiber preamplifier, demodulation multiplexer successively in the input optical fibre of N road, M multiplexer or wave multiplexer connect the Er-doped fiber power amplifier separately, the latter connects output optical fibre and forms the output of M road, it is characterized in that:
(1) described each demodulation multiplexer L road output connects L optical space switch matrix input respectively, and N the identical signal output part of demodulation multiplexer wavelength is connected to same each input of optical space switch matrix;
(2) output of each optical space switch matrix is connected respectively to M multiplexer or wave multiplexer, is connected to same multiplexer or each input of wave multiplexer from the output of the individual different optical space switch matrixes of L;
Wavelength division multiplexing wavelength signals in every input optical fibre link is λ
1, λ
2..., λ
L, L is the wavelength signals number, is natural number; Above-mentioned N represents input optical fibre link number, and M represents output optical fibre link number, is natural number.
2. all-optical wave-length route Cross module as claimed in claim 1 is characterized in that:
(1) it comprises that also the input and output port number average is wavelength Conversion selective light space switching matrix and L * J fixed wave length transducer of L * J, the corresponding λ of wherein every J fixed wave length transducer
1, λ
2..., λ
LIn a wavelength, a corresponding L wavelength altogether;
(2) wherein wavelength Conversion selective light space switching matrix input and output port number average is L * J, and the input port number of L optical space switch matrix respectively is that N+J, output port number respectively are M+J;
(3) input of the J of each optical space switch matrix output connection wavelength Conversion selective light space switching matrix, the every J of output of wavelength Conversion selective light space switching matrix is one group, connects J fixed wave length transducer of wavelength to be converted, the optical space switch matrix input of corresponding wavelength successively;
Above-mentioned J represents the fixed wave length transducer number that output valve is identical, 1≤J≤N.
3. all-optical wave-length route Cross module as claimed in claim 1 or 2 is characterized in that being connected of described each demodulation multiplexer and optical space switch matrix, each optical space switch matrix pass through monomode fiber with being connected of multiplexer or wave multiplexer.
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CNB031283772A CN1255995C (en) | 2003-07-24 | 2003-07-24 | Full optical wavelength route cross module |
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CNB031283772A CN1255995C (en) | 2003-07-24 | 2003-07-24 | Full optical wavelength route cross module |
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CN1255995C CN1255995C (en) | 2006-05-10 |
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Cited By (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101193329B (en) * | 2006-11-29 | 2010-07-21 | 株式会社日立制作所 | Optical switch and optical crossconnect apparatus |
CN101547381B (en) * | 2009-05-08 | 2011-08-24 | 北京科技大学 | Multicast RWA method with signal power attenuation limit in all-optical network |
CN101304294B (en) * | 2008-06-24 | 2011-09-21 | 中兴通讯股份有限公司 | Non-obstruction optical network apparatus as well as optical network node end-to-end service non-obstruction decussation method |
CN102318364A (en) * | 2011-07-29 | 2012-01-11 | 华为技术有限公司 | Optical switching device and signal exchange system |
WO2015066830A1 (en) * | 2013-11-05 | 2015-05-14 | 华为技术有限公司 | Wavelength routing device |
CN108061937A (en) * | 2017-12-22 | 2018-05-22 | 中国科学院半导体研究所 | A kind of multimode optical switching structure for link switching |
WO2019034016A1 (en) * | 2017-08-15 | 2019-02-21 | Huawei Technologies Co., Ltd. | All-optical networks based on switchable wavelength connects (swcs) |
CN116320845A (en) * | 2023-05-24 | 2023-06-23 | 之江实验室 | Flattened data exchange method and system based on optical switch |
-
2003
- 2003-07-24 CN CNB031283772A patent/CN1255995C/en not_active Expired - Fee Related
Cited By (10)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101193329B (en) * | 2006-11-29 | 2010-07-21 | 株式会社日立制作所 | Optical switch and optical crossconnect apparatus |
CN101304294B (en) * | 2008-06-24 | 2011-09-21 | 中兴通讯股份有限公司 | Non-obstruction optical network apparatus as well as optical network node end-to-end service non-obstruction decussation method |
CN101547381B (en) * | 2009-05-08 | 2011-08-24 | 北京科技大学 | Multicast RWA method with signal power attenuation limit in all-optical network |
CN102318364A (en) * | 2011-07-29 | 2012-01-11 | 华为技术有限公司 | Optical switching device and signal exchange system |
WO2015066830A1 (en) * | 2013-11-05 | 2015-05-14 | 华为技术有限公司 | Wavelength routing device |
WO2019034016A1 (en) * | 2017-08-15 | 2019-02-21 | Huawei Technologies Co., Ltd. | All-optical networks based on switchable wavelength connects (swcs) |
US10645473B2 (en) | 2017-08-15 | 2020-05-05 | Futurewei Technologies, Inc. | All-optical networks based on switchable wavelength connects (SWCs) |
CN108061937A (en) * | 2017-12-22 | 2018-05-22 | 中国科学院半导体研究所 | A kind of multimode optical switching structure for link switching |
CN116320845A (en) * | 2023-05-24 | 2023-06-23 | 之江实验室 | Flattened data exchange method and system based on optical switch |
CN116320845B (en) * | 2023-05-24 | 2023-08-15 | 之江实验室 | Flattened data exchange method and system based on optical switch |
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