CN101056265A - Address-control-based optical channel selection device - Google Patents
Address-control-based optical channel selection device Download PDFInfo
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- CN101056265A CN101056265A CNA200710099597XA CN200710099597A CN101056265A CN 101056265 A CN101056265 A CN 101056265A CN A200710099597X A CNA200710099597X A CN A200710099597XA CN 200710099597 A CN200710099597 A CN 200710099597A CN 101056265 A CN101056265 A CN 101056265A
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- GNSKLFRGEWLPPA-ZSJDYOACSA-M potassium;dideuterio phosphate Chemical compound [K+].[2H]OP([O-])(=O)O[2H] GNSKLFRGEWLPPA-ZSJDYOACSA-M 0.000 claims description 3
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Abstract
The invention relates to the optical channel selection device based on the address control and belongs to the technical area of the optical channel selection, its features are as follows: optical division device which divides the optical packets into two channels; the photoelectrical conversion device converts one channel of the optical packet outputted by the optical division device into the telegraph and corresponding clock signals; channel selection logic control module extracts the address from the received telegraph and generates the control signals of all optical channels according to the address mapping relation of this device; the photoelectrical synchronization device receives another channel of optical packet of the optical division device and synchronizes the optical packet with the control signals entering into the optical channel via controlling the length of the optical fiber; the optical channel selection module is controlled by the control signals generated by the channel selection control module, when this address does not belong to the port of the current channel, the optical signals is refracted to other sites, otherwise, the optical signals smoothly pass. The invention can save the carrier wavelength resources, avoid the data error, is simple in structure and quick in channel selection.
Description
Technical field
The present invention relates to optical channel selection device, and be particularly related to route system based on internet protocol IP.
Background technology
In Internet, the network in various countries and area couples together by router, and router is the nucleus equipment of whole Internet.In recent years, along with appearance and the application in Internet of speech, graphic service, the traffic carrying capacity of Internet is with exponential rate increase, and this has proposed new requirement to the existing network bandwidth.
Current core router operation principle is: at first the light message signals is converted to telegram literary composition signal, by searching local routing table, telegram literary composition signal is carried out routing, by the switching fabric in the router telegram literary composition signal is distributed to different output ports after finishing routing, be the light message signals by electrooptic conversion module with telegram literary composition conversion of signals at last, pass to the next stage router, perhaps directly receive by oneself.This process need is changed through twice photoelectricity, electric light, the complicated internal memory operation and the exchange of exchanging array, and the speed that message is transmitted will be subjected to many-sided restriction.Therefore need a kind of optical routing device, reduce the expense of photoelectricity, electric light conversion as far as possible, reduction even elimination repeating process are transmitted message and are more prone to the dependence of internal memory and exchanging array.
The existing data exchange structure of not sharing the same light can provide the three kinds of light solution that have of fast data packet exchange.First kind of scheme is the scheme of utilizing broadcasting and selecting switching technology; Second kind of scheme is based on the scheme of multi-protocols wavelength exchange (MPLms) technology; The third scheme utilizes optical tech to substitute electronic switching system (ESS).But first kind and second kind of scheme all are based on the wavelength address carries out route, current broadcast and select exchange directly each port migration not to be WDM output/input, and also wavelength resource is limited, can't satisfy the quantitative requirement of IP address.The restriction of optics has greatly limited the application of light exchange in facilities management in the third scheme.Therefore need a kind of optical routing device, transmit not directly relatedly, be not limited with carrier wavelength.
Summary of the invention
The invention provides a kind of structure of novel optical channel selection device, propose electro optic effect, realize the light routing of light message information by crystal.
The invention is characterized in that the optical channel selection device based on address control is characterized in that, overall light-dividing device 1, photoelectricity switching and clock extraction element 2, routing Logic control module 3, photoelectric synchronous device 4, optical channel selection device 5, wherein:
Light-dividing device 1 is a semi-transparent mirror that partly returns, and the light message is divided into two-way through behind this light-dividing device 1, one the tunnel enters each photoelectric synchronous device 4, another road enters opto-electronic conversion and clock extraction element 2, and described smooth message as beginning flag, is its address code and clean symbol by a delimiter subsequently;
Opto-electronic conversion and clock extraction element 2, contain the optical-electrical converter 6 of serial connection successively, preamplifier 7, main amplifier 8, equalizer 9, decision device 10, decoding, descrambling, coding circuit 14, Chuan Jie peak detector 12 and AGC amplifier 12 successively, and clock recovery circuitry 13, the output of described equalizer 9 is when the input with described decision device 10 links to each other, also with the input of the extensive circuit 13 of clock, the input of peak detector 12 links to each other, the output while and the described decoding of described clock recovery circuitry 13, descrambling, the input of coding circuit 14 links to each other, the output of described AGC amplifier 11 links to each other with the input of main amplifier 8; Described clock recovery circuitry 13 contains: the decision circuit 16 of serial connection and sign indicating number form the decision device 10 of circuit composition 17 successively, the clock recovery circuitry 13 that Chuan Jie clamper shaping 18 successively, Nonlinear Processing 19, tuning amplification 20, amplitude limit 21, shaping 22 and phase-shift circuit 23 are formed, wherein non-linear processing circuit 19 can adopt not gate of RC differential circuit serial connection to realize, phase-shift circuit 23 forms circuit 17 output phase shift signals to decision circuit 16 and sign indicating number; And the equalizer that links to each other with the input of decision device and shaping circuit respectively of output; Described opto-electronic conversion and clock extraction element 2 are converted to telegram literary composition and corresponding clock signals to the light message, and output to routing Logic control module 3;
Routing Logic control module 3 is combined into by address extraction circuit and Combinational Logic Control signal generating circuit serial connection, wherein:
The address extraction circuit contains: four bit address produce circuit, message delimits clock generation circuit and message is delimited control signal generation circuit, wherein:
Four bit address produce circuit, the d type flip flops of serial connection and 4 d type flip flops that the Q output * * that is connected to described each d type flip flop produces 4 bit address are formed successively by 4, the message flow of being made up of single bit data stream data and clock signal thereof is input to 4 the 1st d type flip flop inputs in the d type flip flop that is connected in series successively, to produce to the clock cycle 4 bit address one by one
With 01111110 be delimiter message boundary clock generation circuit by 8 successively d type flip flop and inputs of serial connection be connected the 2nd---6 input AND circuit of the 7th d type flip flop Q output are combined into, resetting of described single bit data stream data and another control message boundary is input to 8 inputs of the d type flip flop of serial connection successively with clock signal, when whenever detecting delimiter 01111110,6 inputs just produce the clock signal of a message boundary with door;
Described message is delimited control signal generation circuit, contain: 4 d type flip flops that are connected in series successively, and last d type flip flop output connects the reset circuit that inverter is formed, a D holds the D reset flip-flop of set all the time and is connected in two of its output and imports the demarcation control signal generation circuit that AND circuit are formed, the output signal of described 6 inputs and door and described clock signal are sent into the input as reset circuit, and the D reset flip-flop clock end that a described D holds set all the time is sent in the output of this reset circuit, and the input of this D reset flip-flop is connected to described one two input and door, its another be input as described clock signal, this two input then is sent to described four bit address as resetting of described control message boundary with clock signal with the output of door and is produced the clock end in mutual 4 d type flip flops that are connected in series in the circuit;
The Combinational Logic Control waveshaping circuit is by different logical designs, the hypothesis channel selection device has 4 ports in this device, the light message has 4 bit address, the distribution of removing other 14 addresses of 0000 and 1111 is as follows: address 0001,0100,0101,1010 mapped port 0, address 0010,0111,1000 are mapped to port one, address 0011,1001,1011,1100 are mapped to port 2, address 0110,1101,1110 are mapped to port 3, Combinational Logic Control signal shape circuit comprises: 4 inputs respectively with 4 bit address add0---the not gate that add3 links to each other, 4 groups of totally 12 inputs 4 input nand gates that link to each other with the output of 4 bit address signals or its corresponding not gate; And 4 with door, each links to each other with the output of described a certain group of NAND gate with the input of door, output is 5 control signal of corresponding light route selection module; When the light message address belonged to corresponding light route selection module 5 and points to ports, passing to these light route selection module 5 control signals was 0, otherwise is 1;
The mapping of 4 destination address signals in the signal of telecommunication message flow that described routing Logic control module 3 extracts by described channel selection device is with control signal control0---and one among the control3 passes to each light route selection module 5;
Photoelectric synchronous device 4 is an optical fiber, its length l=c
0T/n, wherein c
0Be the light velocity in the vacuum, t is described control signal time-delay, and n is the refractive index of carrier wave in fiber medium;
Light route selection module 5, it is by the polarizer 24, DKDP luminescent crystal 25, it is the potassium dideuterium phosphate crystal, form with birefringece crystal 26, the polarizer 24 makes the laser that is loaded with the light message information become single polarization, and DKDP crystal 25 is making alive not externally, be that control signal is when being ' 0 ', keep isotropism, incident light direction of vibration by DKDP crystal 25 time is constant, promptly is parallel to the o optical vibration direction of birefringece crystal 26, signal passes through smoothly, when the outside adds voltage V
0, when promptly control signal was output as ' 1 ', incident light was parallel to the e light polarization direction of birefringece crystal 26 by 90 ° of DKDP crystal 25 rear polarizer direction deflections, reflects during by it, departs from original route, can not pass through light path.
The invention has the advantages that: have nothing to do with the carrier wavelength of light message, overcome the problem of inadequate resource; Less demanding to optics; Produce control signal by address information and directly control each routing passage, avoided losing and make mistakes in the data handling procedure, improved routing speed.
Description of drawings
Fig. 1 is the coded system of light message information among the present invention.Comprise delimiter, address code, payload.
Fig. 2 is the optical channel selection device structural representation that the present invention is based on address control.
As shown in Figure 2, optical channel selection device is mainly by light-dividing device 1, opto-electronic conversion and clock extraction element 2, and routing Logic control module 3, photoelectric synchronous device 4 and light route selection module 5 are formed.
Fig. 3 is opto-electronic conversion of the present invention and clock extracting apparatus structural representation.
As shown in Figure 3, opto-electronic conversion and clock extracting apparatus be by photoelectric detector 6, preamplifier 7, and main amplifier 8, equalizer 9, decision device 10, AGC amplifier 11, peak detector 12, clock recovery circuitry 13 and decoding descrambling coding circuit 14 are formed.
Fig. 4 is a clock extracting apparatus structural representation of the present invention.
As shown in Figure 4, clock extracting apparatus is by decision circuit 16, and sign indicating number forms circuit 17, clamper shaping circuit 18, and non-linear processing circuit 19, tuning amplification circuit 20, amplitude limiter circuit 21, shaping circuit 22 and phase-shift circuit 23 form.
A kind of realization that Fig. 5 extracts the address part circuit for routing Logic control module of the present invention, this circuit is applicable to 4 bit address, according to the difference of address size in the light message, this circuit can have different realizations.
Fig. 6 is a kind of realization of control signal generative circuit of the present invention, this circuit is applicable to that the hypothesis channel selection device has 4 ports, the light message has 4 bit address, the distribution of removing other 14 addresses of 0000 and 1111 is as follows: address 0001,0100,0101,1010 mapped port 0, address 0010,0111,1000 is mapped to port one, and address 0011,1001,1011,1100 is mapped to port 2, and address 0110,1101,1110 is mapped to port 3.Among the figure: add0---add3 is 4 bit address from low to high, and control0---control3 is the control signal of 4 ports producing, and when the light message address belonged to corresponding path and points to port, this path control signal was 0, otherwise is 1.
Fig. 7 is a light route selection module structural representation of the present invention.
As shown in Figure 7, the light route selection module is by the polarizer 24, and DKDP (potassium dideuterium phosphate crystal) 25 and birefringece crystal 26 are formed.
Fig. 8 realizes for a kind of hardware of photoelectric detector 6 in opto-electronic conversion of the present invention and the clock extraction element 2 and preamplifier.
Fig. 9 is a kind of realization of light-dividing device of the present invention, use be semi-transparent semi-reflecting lens.
Figure 10 is the routing process schematic diagram of the light message after the beam split of the present invention.
Embodiment
Be described in detail below in conjunction with the specific implementation of accompanying drawing technical solution of the present invention.
The present invention is based on coded system as shown in Figure 1.As beginning flag, its destination address at message foremost by a delimiter for each light message.
As shown in Figure 2, optical channel selection device is mainly by light-dividing device 1, opto-electronic conversion and clock extraction element 2, routing Logic control module 3, photoelectric synchronous device 4 and light route selection module 5.Light signal enters channel selection device through light-dividing device 1, is divided into two-way, and one the tunnel enters each photoelectric synchronous device 4, and another road enters opto-electronic conversion and clock extraction element 2.Opto-electronic conversion and clock extraction element 2 are converted to the signal of telecommunication and corresponding clock with light signal, and signal is given to routing Logic control module 3.Routing Logic control module 3 extracts the destination address of message in the electric signal streams, and the map addresses generation control signal according to channel selection device passes to each light route selection module 5.At this moment, another road light signal arrives each light route selection module 5 through photoelectric synchronous device 4 with control signal.Each path adds or cancels external electrical field according to control signal in the light route selection module 5 to passage, when light message destination address belongs to the port that this path leads to, not to DKDP crystal 25 extra electric fields, light signal is passed through smoothly, otherwise to DKDP crystal 25 extra electric fields, the lightray propagation direction is deflected, thus the light signal in the filtering Ben Feiben path.
Each parts of optical channel selection device of the present invention can adopt prior art.
Light-dividing device 1 adopts semi-transparent semi-reflecting lens among Fig. 2.As shown in Figure 9.
Photoelectric conversion module 2 adopts classical as shown in Figure 3 circuit among Fig. 2.This circuit is by photoelectric detector 6, preamplifier 7, and main amplifier 8, equalizer 9, decision device 10, AGC amplifier 11, peak detector 12, clock recovery circuitry 13 and decoding descrambling coding circuit 14 are formed.Photoelectric detector 6 adopts classical as shown in Figure 8 PIN-PET circuit with preamplifier 7.Main amplifier 8 adopts integrated amplifier.Clock recovery circuitry adopts structural circuit as shown in Figure 4.
Routing Logic control module 3 comprises that the extraction address module of sequential logic and combinational logic generate the control signal module among Fig. 2.4 extraction address circuits such as Fig. 5: be input as single bit data stream data and clock signal clock thereof, the light message is a delimiter with 01111110, address bit is 4, The data step-by-step filling mode, i.e. 01111110 boundary that appears at message, transmitting terminal finds that when transmitting messages literary composition occurring continuous 51 in the data adds one 0 automatically, receiving terminal receive 5 continuous 1 o'clock, be 0 as next bit, then ignore this 0, as next bit is 1, then shows it is the beginning of another message.As Fig. 5 circuit after detecting 01111110, again through 4 clock cycle, delivery outlet add0, add1, add2, add3 will export correct address, 4 all after dates occur up to next 01111110.
Photoelectric synchronous device 4 can adopt the mode of fiber lengths in the control module and environment thereof to realize among Fig. 2.Postpone to be t that the refractive index of carrier wave in fiber medium is n if control signal produces, the light velocity is c in the vacuum
0, then required fiber lengths is l=c
0T/n..
Among Fig. 2 light route selection module structure as shown in Figure 7, it is by the polarizer 24, DKDP crystal 25 and birefringece crystal 26 are formed.The phenomenon that crystal refractive index distributes and changes under External Electrical Field is called electro optic effect.The anisotropy that crystal refractive index distributes be by the atom and molecule that constitutes crystal arrange and between them interactional anisotropy cause.If the effect of external electric field is even as big as influencing this arrangement or when interacting, must making crystal that inherent variation takes place.This variation shows as on macroscopic view: just exist the crystal of natural birefringence to produce additional birefringence originally; Sometimes also can make isotropic body (producing anisotropy) such as the DKDP crystal.The polarizer 24 makes the laser that is loaded with the light message information become single polarization.DKDP crystal 25 externally not making alive be control signal when being ' 0 ', keep isotropism, incident light direction of vibration by DKDP crystal 25 time is constant, promptly is parallel to the o optical vibration direction of birefringece crystal 26, signal passes through smoothly, shown in solid line among Fig. 7.When the outside adds voltage V
0Be control signal when being output as ' 1 ', incident light is parallel to the e light polarization direction of birefringece crystal 26 by 90 ° of DKDP crystal rear polarizer direction deflections, reflects during by it, departs from original route, can not pass through light path, as shown in phantom in Figure 7.
Above-mentioned smooth route selection module example as shown in figure 10, three light message white fritters belong to three different light pathes respectively among the figure, the laser beam irradiation that is loaded with 3 messages is to all light pathes, control signal is controlled the digital deflection device in each light path, the laser of non-path is redirect to beyond the path, the light message signals that only remaining destination address is this path.
The present invention is by the co-ordination of above-mentioned module, reaches the light message is distributed on the destination channel, and can not appear at the purpose of non-target path.Simultaneously, whole process only relates to the process of an opto-electronic conversion, the memory read-write that needs when not relating to electrical communication and and exchange loop afterwards, greatly reduce message and transmit the restriction that is subjected to.Make the raising of forwarding rate more feasible.
Claims (1)
1, based on the optical channel selection device of address control, it is characterized in that, overall light-dividing device (1), photoelectricity switching and clock extraction element (2), routing Logic control module (3), photoelectric synchronous device (4), optical channel selection device (5), wherein:
Light-dividing device (1) is a semi-transparent mirror that partly returns, behind light message this light-dividing device of process (1), be divided into two-way, one the tunnel enters each photoelectric synchronous device (4), another road enters opto-electronic conversion and clock extraction element (2), described smooth message as beginning flag, is its address code and clean symbol by a delimiter subsequently;
Opto-electronic conversion and clock extraction element (2), contain the optical-electrical converter (6) of serial connection successively, preamplifier (7), main amplifier (8), equalizer (9), decision device (10), decoding, descrambling, coding circuit (14), Chuan Jie peak detector (12) and AGC amplifier (12) successively, and clock recovery circuitry (13), the output of described equalizer (9) is when the input with described decision device (10) links to each other, also with the input of the extensive circuit of clock (13), the input of peak detector (12) links to each other, the output while and the described decoding of described clock recovery circuitry (13), descrambling, the input of coding circuit (14) links to each other, the output of described AGC amplifier (11) links to each other with the input of main amplifier (8); Described clock recovery circuitry (13) contains: Chuan Jie decision circuit (16) and sign indicating number form the decision device (10) that circuit is formed (17) successively, the clock recovery circuitry (13) that Chuan Jie clamper shaping (18) successively, Nonlinear Processing (19), tuning amplification (20), amplitude limit (21), shaping (22) and phase-shift circuit (23) are formed, wherein non-linear processing circuit (19) can adopt not gate of RC differential circuit serial connection to realize, phase-shift circuit (23) forms circuit (17) output phase shift signal to decision circuit (16) and sign indicating number; And the equalizer that links to each other with the input of decision device and shaping circuit respectively of output; Described opto-electronic conversion and clock extraction element (2) are converted to telegram literary composition and corresponding clock signals to the light message, and output to routing Logic control module (3);
Routing Logic control module (3) is combined into by address extraction circuit and Combinational Logic Control signal generating circuit serial connection, wherein:
The address extraction circuit contains: four bit address produce circuit, message delimits clock generation circuit and message is delimited control signal generation circuit, wherein:
Four bit address produce circuit, the d type flip flops of serial connection and 4 d type flip flops that the Q output * * that is connected to described each d type flip flop produces 4 bit address are formed successively by 4, the message flow of being made up of single bit data stream data and clock signal thereof is input to 4 the 1st d type flip flop inputs in the d type flip flop that is connected in series successively, to produce to the clock cycle 4 bit address one by one
With 01111110 be delimiter message boundary clock generation circuit by 8 successively d type flip flop and inputs of serial connection be connected the 2nd---6 input AND circuit of the 7th d type flip flop Q output are combined into, resetting of described single bit data stream data and another control message boundary is input to 8 inputs of the d type flip flop of serial connection successively with clock signal, when whenever detecting delimiter 01111110,6 inputs just produce the clock signal of a message boundary with door;
Described message is delimited control signal generation circuit, contain: 4 d type flip flops that are connected in series successively, and last d type flip flop output connects the reset circuit that inverter is formed, a D holds the D reset flip-flop of set all the time and is connected in two of its output and imports the demarcation control signal generation circuit that AND circuit are formed, the output signal of described 6 inputs and door and described clock signal are sent into the input as reset circuit, and the D reset flip-flop clock end that a described D holds set all the time is sent in the output of this reset circuit, and the input of this D reset flip-flop is connected to described one two input and door, its another be input as described clock signal, this two input then is sent to described four bit address as resetting of described control message boundary with clock signal with the output of door and is produced the clock end in mutual 4 d type flip flops that are connected in series in the circuit;
The Combinational Logic Control waveshaping circuit is by different logical designs, the hypothesis channel selection device has 4 ports in this device, the light message has 4 bit address, the distribution of removing other 14 addresses of 0000 and 1111 is as follows: address 0001,0100,0101,1010 mapped port 0, address 0010,0111,1000 are mapped to port one, address 0011,1001,1011,1100 are mapped to port 2, address 0110,1101,1110 are mapped to port 3, Combinational Logic Control signal shape circuit comprises: 4 inputs respectively with 4 bit address add0---the not gate that add3 links to each other, 4 groups of totally 12 inputs 4 input nand gates that link to each other with the output of 4 bit address signals or its corresponding not gate; And 4 and door, each links to each other with the output of described a certain group of NAND gate with the input of door, and output is the control signal of (5) of corresponding light route selection module; When the light message address belonged to corresponding light route selection module (5) sensing port, passing to this light route selection module (5) control signal was 0, otherwise is 1;
The mapping of 4 destination address signals in the signal of telecommunication message flow that described routing Logic control module (3) extracts by described channel selection device is with control signal control0---and one among the control3 passes to each light route selection module (5);
Photoelectric synchronous device (4) is an optical fiber, its length l=c
0T/n, wherein c
0Be the light velocity in the vacuum, t is described control signal time-delay, and n is the refractive index of carrier wave in fiber medium;
Light route selection module (5), it is by the polarizer (24), DKDP luminescent crystal (25), it is the potassium dideuterium phosphate crystal, and birefringece crystal (26) forms, and the polarizer (24) makes the laser that is loaded with the light message information become single polarization, and DKDP crystal (25) is making alive not externally, be that control signal is when being ' 0 ', keep isotropism, incident light direction of vibration by DKDP crystal (25) time is constant, promptly is parallel to the o optical vibration direction of birefringece crystal (26), signal passes through smoothly, when the outside adds voltage V
0, when promptly control signal was output as ' 1 ', incident light was parallel to the e light polarization direction of birefringece crystal (26) by 90 ° of DKDP crystal (25) rear polarizer direction deflections, reflects during by it, departs from original route, can not pass through light path.
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|---|---|---|---|
| CNB200710099597XA CN100521656C (en) | 2007-05-25 | 2007-05-25 | Address-control-based optical channel selection device |
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| CNB200710099597XA CN100521656C (en) | 2007-05-25 | 2007-05-25 | Address-control-based optical channel selection device |
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| CN100521656C CN100521656C (en) | 2009-07-29 |
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Cited By (3)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| WO2013110243A1 (en) * | 2012-01-27 | 2013-08-01 | Huawei Technologies Co., Ltd. | Spectral encoding of an optical label or destination |
| WO2014090158A1 (en) * | 2012-12-11 | 2014-06-19 | Huawei Technologies Co., Ltd. | System and method for multi-wavelength encoding |
| CN107689827A (en) * | 2017-07-12 | 2018-02-13 | 北京空间飞行器总体设计部 | A kind of remote sensing satellite high speed load data optical fiber coffret |
-
2007
- 2007-05-25 CN CNB200710099597XA patent/CN100521656C/en not_active Expired - Fee Related
Cited By (7)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| WO2013110243A1 (en) * | 2012-01-27 | 2013-08-01 | Huawei Technologies Co., Ltd. | Spectral encoding of an optical label or destination |
| US9054827B2 (en) | 2012-01-27 | 2015-06-09 | Futurewei Technologies, Inc. | Optical switching device using spectral trigger |
| US9136969B2 (en) | 2012-01-27 | 2015-09-15 | Futurewei Technologies, Inc. | Spectral encoding of an optical label or destination |
| US9178644B2 (en) | 2012-01-27 | 2015-11-03 | Futurewei Technologies, Inc. | Spectral encoding of an optical label or destination |
| WO2014090158A1 (en) * | 2012-12-11 | 2014-06-19 | Huawei Technologies Co., Ltd. | System and method for multi-wavelength encoding |
| US9628878B2 (en) | 2012-12-11 | 2017-04-18 | Huawei Technologies Co., Ltd. | System and method for multi-wavelength encoding |
| CN107689827A (en) * | 2017-07-12 | 2018-02-13 | 北京空间飞行器总体设计部 | A kind of remote sensing satellite high speed load data optical fiber coffret |
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| Publication number | Publication date |
|---|---|
| CN100521656C (en) | 2009-07-29 |
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