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CN1462126A - Parallel multichunnel wavelength locking device - Google Patents

Parallel multichunnel wavelength locking device Download PDF

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Publication number
CN1462126A
CN1462126A CN02113097A CN02113097A CN1462126A CN 1462126 A CN1462126 A CN 1462126A CN 02113097 A CN02113097 A CN 02113097A CN 02113097 A CN02113097 A CN 02113097A CN 1462126 A CN1462126 A CN 1462126A
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optical fiber
wavelength
output
distributed feedback
fiber collimator
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CN100391139C (en
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谢建平
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University of Science and Technology of China USTC
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University of Science and Technology of China USTC
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  • Semiconductor Lasers (AREA)

Abstract

A parallel multi-channel wavelength locking device for the DFB laser in DWDM optical communication system is disclosed. The wavelength locking beam of each DFB laser is coupled to an optical fibre coupler, whose output is connected to binary-array CCD photoelectric detector directly and via optical collimator array and standard FP. The output of said photoelectric detector is connected to relative differentiator and the differentiator is then connected to the relative temp controller of each DFB laser for loking its wavelength.

Description

Parallel multichunnel wavelength locking device
Technical field:
The present invention relates to use the optical fiber telecommunications system that close wavelength-division multiplex technology constitutes, especially relate to the employed wavelength locker of laser (or claiming Wavelength stabilized device) in the system.
Background technology:
In the present optical fiber telecommunications system, can be in an optical fiber simultaneously with the light wave transmissions information of several or dozens of different wave length, be called dense wave division multipurpose (being called for short DWDM) technology.It can satisfy the requirement of modern society to the transmission of big capacity information.International Telecommunications Union (ITU) has stipulated that the wavelength spacing in the optical fiber communication of DWDM is respectively 0.8nm and 0.4nm, and corresponding channel separation is respectively 100GHz and 50GHz.This just requires the optical wavelength on each channel that the higher stable degree must be arranged, and promptly must adopt high-precision locking or stabilization technique to each wavelength.Light source in the optical fiber telecommunications system all is distributed feedback semiconductor laser (an abbreviation Distributed Feedback Laser), it has advantages such as small-sized, that working stability is reliable, spectral line is narrow, the life-span is long, but its emitted laser wavelength can drift about because of temperature change, and this temperature wavelength shift generally is about 0.2nm/ ℃.
At present the technology that the dfb semiconductor laser is carried out wavelength locking mainly is: (etalon multi-wavelength lock-in techniques sees reference Fabry-pool sieve (abbreviation FP) document: Ed Miskovic, " Wavelength lockers keep lasers inline ", Photonics Spectra, in February, 1999, P104).Existing FP multi-wavelength lock-in techniques is that the output beam with each Distributed Feedback Laser is coupled out on a small quantity with fiber coupler that the light wave of (as 2%) is used for wavelength locking, and remaining most laser is used for the communication of optical fiber arterial highway.This Shu Guangzai that each Distributed Feedback Laser is used for wavelength locking leads to the fiber coupler of terminal after lumping together with the series-parallel fiber couplers of some levels.The output of this terminal fiber coupler has two optical fiber end: an optical fiber end outputs to FP, and each wavelength utilizes a transmission peaks in the transmittance graph of multi-peaks structure of FP etalon to lock, and the light that sees through FP is transformed into signal of telecommunication V by a photoelectric detector 1, as a reference signal in the calculus of differences; Another optical fiber end outputs to another photoelectric detector, and the signal of telecommunication of its output is as another reference signal V in the calculus of differences 2For can be from differential signal (Δ V=V 1-V 2) in to identify be the wavelength of which Distributed Feedback Laser, must do by a small margin the injection current of each Distributed Feedback Laser, (crest of for example modulated injection current-trough difference is 2~3% of an average injection current for the modulation of low frequency, frequency is 200Hz): (promptly adopt conventional time-division multiplex technology) at times successively by electronic switch each Distributed Feedback Laser is carried out the injection current modulation, and then differential signal made Filtering Processing (frequency filtering is a modulating frequency, as 200Hz).Owing on a certain period, have only a Distributed Feedback Laser modulated, therefore have only the differential signal on this Distributed Feedback Laser wavelength to exist after the filtering, and should go up the differential signal of other not modulated Distributed Feedback Laser wavelength the period all because of having only DC component all by elimination.Differential signal amplifies the back through amplifier and the pairing Distributed Feedback Laser of this wavelength is carried out adjustment by the electronic switch gating, by thermostat and make wavelength locking on definite wavelength value thus.When laser output wavelength during just at desirable value, differential signal is zero, and it is existing temperature-resistant that thermostat is kept laser, and then its wavelength just remains unchanged.If laser wavelength elongated (or shortening), at this moment will diminish (or become big) by the luminous intensity behind the FP, and not constant by the luminous intensity of FP, then differential signal will become negative value (or on the occasion of), the wavelength departure value is big more, and the negative value of differential signal (or on the occasion of) amplitude is big more.At this moment differential signal will be indicated corresponding thermostat cooling (or intensification), and the amplitude of cooling (or intensification) is determined by negative (or just) amplitude of differential signal, the laser wavelength that departs from out is turned back to again on the necessary wavelength value.
Existing this injection current modulation and time-multiplexed multi-wavelength lock-in techniques have three shortcomings: the one, the Distributed Feedback Laser injection current is modulated, this modulation signal also must enter in the communication of optical fiber arterial highway, taken certain bandwidth resources in each channel, this is undesirable in the optical fiber communication; The 2nd, carry out in the process of current-modulation successively in timesharing, the modulating time of each laser can reduce with the increase of the number of active lanes of wavelength locking (for example during 8 wavelength locking, this modulating time is about 1/16 second, and during 16 wavelength locking, this modulating time is about 1/32 second).The too short meeting of modulating time makes the validity and the reliability decrease of this wavelength locking, so the difficult locking that is used for the dozens of wavelength of this technology; The 3rd, the output of each Distributed Feedback Laser all will be passed through the series-parallel fiber couplers of some levels, and (and coupler progression can increase with the increase of number of lasers, for example during 8 wavelength locking, coupler progression is 4 grades, and during 16 wavelength locking, coupler progression is 5 grades) could arrive FP and photoelectric detector.Wherein the splitting ratio of first order fiber coupler is 2: 98, thereafter the splitting ratio of every grade of fiber coupler is 1: 1, like this, only having an appointment in the output intensity of every Distributed Feedback Laser when 8 wavelength locking 0.25% is used for wavelength locking, then is about 0.125% when 16 wavelength locking; If take into account loss (being generally 1db) of each fiber coupler self and the loss of FP again, then luminous intensity will be more weak.The generally about 10mW of Distributed Feedback Laser power has only 10 μ W magnitudes so can enter the luminous intensity of FP.This has brought bigger difficulty to Photoelectric Detection.Therefore, the practical application of dense wave division multipurpose optical fiber telecommunications system is restricted.
Summary of the invention:
The object of the present invention is to provide a kind of can directly distinguish differential signal and need not injection current modulation and time-multiplexed parallel multichunnel wavelength locking device.
Technical solution of the present invention is as follows:
Contain 1: 1 fiber coupler in the wavelength locker, the FP etalon, photoelectric detector and difference engine, thermostat etc., the input of 1: 1 fiber coupler links to each other with wavelength-locked beam output from each Distributed Feedback Laser, the output of photoelectric detector then leads to the respective input of difference engine, difference engine is connected on the corresponding thermostat of each Distributed Feedback Laser, it is characterized in that between fiber coupler and the difference engine by preceding, back optical fiber collimator, FP etalon and two line array CCD photoelectric detectors are formed, output one end of fiber coupler links to each other with the input of preceding optical fiber collimator, the other end is directly aimed at a row photosensitive unit of two line array CCD photoelectric detectors, the output of back optical fiber collimator is then aimed at another row photosensitive unit of two line array CCD photoelectric detectors, before, each optical fiber collimator of back is arranged mutually parallel into array, before, the vertical FP etalon of placing is preceding between the back optical fiber collimator, each respective axes of back optical fiber collimator coincides.
That is to say, the present invention proposes the be arranged in parallel wavelength locker of the designed uniqueness of the technology of structuring the formation of a kind of utilization: from wavelength every Distributed Feedback Laser to be locked, be coupled out and be used for the light beam that wavelength locking is communicated by letter with the arterial highway, wherein be used for connecing 1: 1 fiber coupler that is used to produce differential signal behind the light beam of wavelength locking.Optical fiber collimator array, other end optical fiber then directly connected two line array CCD photoelectric detectors (wherein CCD is the abbreviation of electric charge accumulation device) before one end optical fiber of coupler output connected.The quantity of optical fiber collimator is corresponding with the quantity of Distributed Feedback Laser, they are arranged mutually parallel into array (can be equidistantly to arrange or the unequal-interval arrangement, as long as promptly can be that any array form is arranged conveniently), and former and later two identical optical fiber collimator arrays will be set simultaneously, and the FP etalon just is placed between the forward and backward optical fiber collimator array also vertical with it.Like this, each collimated laser beam of preceding optical fiber collimator array output just impinges perpendicularly on the FP etalon, each light beam has own certain wavelengths, take the transmission peaks of FP separately, these wavelength are arranged in order by adjacent spacing 0.8nm (or 0.4nm), and back optical fiber collimator array is then accepted the optical signal transmissive through the corresponding wavelength separately of FP.Output optical fibre with the back optical fiber collimator forms a line, is connected on the two line array CCD photoelectric detectors and an aligning row photosensitive unit wherein then, the direct output optical fibre of 1: 1 optical fiber coupler also forms a line, is connected on the two line array CCD photoelectric detectors and aligning another row photosensitive unit wherein, makes two the optical fiber end points (being each end points of optical fiber collimator and 1: 1 optical fiber coupler) from same Distributed Feedback Laser aim at two photosensitive units of the same sequence number on the different linear arrays of CCD respectively.This signal of telecommunication to photosensitive unit output enters difference engine, obtained differential signal (signal of telecommunication being entered separately difference engine) with corresponding this of every Distributed Feedback Laser, positive and negative and amplitude according to differential signal can be carried out adjustment to this Distributed Feedback Laser by the semiconductor temperature-control device, makes its wavelength locking (promptly stable) on necessary wavelength.The wave length shift of every Distributed Feedback Laser detects and temperature control all has closed loop of one's own.Therefore present technique need not be modulated the injection current of Distributed Feedback Laser, need not carry out filtering to differential signal, also need not carry out timesharing to many Distributed Feedback Lasers and detect successively and control.
Employing multi-channel optical fibre collimater array that the present invention proposes and the shared FP etalon of two line array CCD photoelectric detector arrays are a kind of brand-new technology with the structure that realizes the multi-channel wavelength locking.1. it changed fully the available technology adopting time division multiplexing carry out the multi-wavelength locking according to the time serial technology path, be that wave length shift to the multichannel Distributed Feedback Laser carries out that all the period of time is detected and the wavelength locking of all the period of time, effectively and reliably than the detection at times of prior art and locking.2. it does not need the injection current of each road Distributed Feedback Laser is modulated, and undesirable modulation signal can not occur in the arterial highway of therefore communicating by letter, and the bandwidth resources of busy channel have not been avoided this significant drawbacks in the prior art fully.3. it does not need multistage series-parallel fiber coupler (to have only the one-level coupler itself for lock of the present invention yet, has only the two-stage coupler between from the Distributed Feedback Laser to the photoelectric detector altogether), thereby, make that the luminous intensity enter FP is the several times to 10 times of prior art, this has brought bigger convenience to Photoelectric Detection.4. the photosensitive unit of employed fiber coupler, optical fiber collimator, photoelectric detector, difference engine, thermostat etc. are the matured product of prior art in the structure, and various device all uses a plurality of single-pieces of same model, therefore are convenient to industrialization.
Description of drawings:
Accompanying drawing 1, lock structure of the present invention and signal transmission schematic diagram.
The structural representation of accompanying drawing 2, FP etalon.
The array structure schematic diagram of accompanying drawing 3, optical fiber collimator.
The array structure schematic diagram of accompanying drawing 4, two line array CCD photoelectric detectors.
Embodiment:
Below in conjunction with drawings and Examples the present invention is described in detail.
The present invention can implement with structure shown in Figure 1.Among the figure, 1 is that (its quantity is decided according to the actual needs of optical fiber telecommunications system, for example 40, promptly forms 40 passages simultaneously for the Distributed Feedback Laser of several same model.In the drawings respectively with 1.1,1.2 ..., 1.40 represent that promptly 1.i just represents i laser.Other duplicate devices also adopts same expression mode, below no longer explains), their wavelength is successively at a distance of to about 0.8nm (or about 0.4nm), and this provides (for example CQU915/1840, the product of JDS Uniphase company) by production firm; The 2nd, be used to distinguish the fiber coupler of wavelength locking and arterial highway communication beam, make by prior art, splitting ratio all is 2: 98, their each optical fiber dead end is (luminous intensity is 98%) towards the optical fiber communication arterial highway, and another fiber-optic output (luminous intensity is 2%) just is connected to the input of 1: 1 fiber coupler 3 that is used to produce differential signal; Output optical fibre one end of each in this fiber coupler (being 3.i) leads in the preceding optical fiber collimator array 4, links to each other with the input of each optical fiber collimator (being 4.i), become collimated light beam by separately optical fiber collimator, pass each self-corresponding optical fiber collimator (being 6.i) in the back optical fiber collimator array 6 that reaches offside behind the FP etalon 5; Each output of back optical fiber collimator array 6 and another fiber-optic output of fiber coupler 3 form a line, aim at each self-corresponding photosensitive unit row in the two line array CCD photoelectric detector arrays 7 respectively; These photosensitive units become light signal into the signal of telecommunication, two photosensitive units (being 7.i and 7.i ') of same sequence number are to detect the light wave that comes from same Distributed Feedback Laser in its two row, and one is to detect light signal, another light signal that is optical fiber collimator array exit point after detection comes from (promptly by formed light signal behind the FP) that directly comes from the fiber coupler exit point; The some of output have just formed two signals of telecommunication in the calculus of differences, have entered difference engine 8 (for the conventional electrical technology) separately the signal of telecommunication from two line array CCD photoelectric detector arrays 7; Each Distributed Feedback Laser is corresponding to a difference engine (being 8.i), the differential signal of its output leads to thermostat 9 (being the inner set semiconductor temperature-control device of every Distributed Feedback Laser product) separately, and this Distributed Feedback Laser is carried out adjustment (being the existing temperature control technology of semiconductor laser).
The FP etalon is made of (for example K9 optical glass) the 10 parallel placements of two optical crystal chips that (depth of parallelism≤5 "), centre have ULE fused quartz (ULE7971, coefficient of expansion α=3.5 * 10 -8/ spacing block 11 (see figure 2)s of k) making.Flatness≤the λ of each side/10.Grind by the processing of conventional optical technology and can satisfy these requirements.With (for example: WD-1001 high performance structures AB glue solidifying glue, Condar chemical experimental factory, Shanghai product, down with) two plates and two spacing blocks are bonded to integral body (make the depth of parallelism≤5 ") between each side, just become and have highly thermally-stabilised (0 ℃~70 ℃), high-precision FP etalon.It is 60%~70% deielectric-coating that the medial surface that two plates is parallel to each other is coated with reflectivity, and lateral surface then is coated with the anti-reflection film (being existing conventional optical coating technology) of residual reflectivity R≤0.2%, and the printing opacity centre wavelength of two films is 1550nm, bandwidth 〉=40nm.The thickness d of spacing block (being the spacing of the parallel medial surface of two plates) is specific design load, and it chooses Δ λ=0.8nm or Δ λ=0.4nm that the transmission peaks place wavelength spacing that must make it meets the ITU regulation, and its computing formula is: d = λ 0 2 2 Δλ ,
With 40 paths, Δ λ=0.8nm, message center wavelength X 0=1550mn is an example, and the thickness that calculating can get spacing block is d=1.502mm.The wavelength value that can get each transmission peaks place of FP etalon thus is respectively λ i=1 550.052nm ± 0.8nm * i, (i=0, ± 1 ..., ± 20).
In the optical fiber collimator array, each optical fiber collimator adopts existing product (product of for example Chinese Foochow Casix company, be of a size of φ 1.8mm * 9mm), they are installed in the array hole 13 of U type metal pedestal shown in Figure 3 (for example indium steel seat) 12 both sides (be 4 * 10 equidistant array), form before and after two arrays 4 and 6.The FP etalon just is placed on (being in the U type groove of indium steel seat) between forward and backward two arrays, with solidifying glue the bottom surface of FP is bonded in the U type groove plate upper surface place of indium steel seat, and the axis in the parallel surface of FP and array hole is perpendicular.Each optical fiber collimator has the dew end of 1mm in the both sides, hole, glue is bonding with itself and hole wall with solidifying.Each axially bored line parallels that (depth of parallelism≤5 "), the dead in line of indium steel seat both sides corresponding aperture (amount of staggering≤20 μ m) can be satisfied these requirements with the processing of conventional Digit Control Machine Tool.
Two line array CCD photoelectric detector arrays are seen Fig. 4: the output optical fibre end 14 of 1: 1 fiber coupler 3 preface is successively formed a line, the output optical fibre end 15 of back optical fiber collimator array forms a line in regular turn, this two row optical fiber end is lined up two alignments, by the plastic mould pressing moulding of routine, constitute optical fiber end two linear arrays 16, the row between line-spacing between its optical fiber end and two alignments are apart from the arrangement size decision by the photosensitive unit on the two selected line array CCD elements 17.The two line array CCD elements that these optical fiber end two linear arrays are conformed to selected size (for example shore pine company product, model PDAS1024) with curing gluing fusing (routine techniques), can become two line array CCD photoelectric detector arrays.Draw the output of suitable lead 18 from each photosensitive unit, it is linked to each other with the respective input of each difference engine, promptly enter separately difference engine corresponding to the signal of telecommunication of each Distributed Feedback Laser as two line array CCD photoelectric detectors.
In sum, the present invention can realize the locking of parallel multi-channel optical maser wavelength.Blocked optical maser wavelength is that equally spaced pectination distributes, and each wavelength is a carrier wave on the channel.Be utilized as if 90% of the 100GHz bandwidth resources of wishing each channel, then require wave length shift≤5GHz on each channel, promptly optical maser wavelength locking precision should be≤0.04nm, at this moment can generation information not disturb between the adjacent channel; If wish that 95% of 100GHz bandwidth is utilized, then wavelength locking precision should be≤0.02nm.These specification requirements utilize technology of the present invention to reach.

Claims (1)

1, a kind of parallel multichunnel wavelength locking device, wherein contain 1: 1 fiber coupler, the FP etalon, photoelectric detector and difference engine, thermostat etc., 1: 1 fiber coupler (3) input link to each other with wavelength-locked beam output from each Distributed Feedback Laser (1), the respective input that the output of photoelectric detector (7) then leads to difference engine (8), difference engine is connected on the corresponding thermostat of each Distributed Feedback Laser (9), it is characterized in that between fiber coupler and the difference engine by optical fiber collimator (4,6), FP etalon (5) and two line array CCD photoelectric detectors (7) are formed, output one end of fiber coupler links to each other with the input of preceding optical fiber collimator (4), the other end is directly aimed at a row photosensitive unit of two line array CCD photoelectric detectors, the output of back optical fiber collimator (6) is then aimed at another row photosensitive unit of two line array CCD photoelectric detectors, before, each optical fiber collimator of back is arranged mutually parallel into array, before, the vertical FP etalon of placing is preceding between the back optical fiber collimator, each respective axes of back optical fiber collimator coincides.
CNB021130973A 2002-05-30 2002-05-30 Parallel multichunnel wavelength locking device Expired - Fee Related CN100391139C (en)

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Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102158662A (en) * 2011-04-15 2011-08-17 中国科学院长春光学精密机械与物理研究所 Image data transmission circuit of satellite-borne high-resolution CCD (Charge Coupled Device) camera
CN102780529A (en) * 2012-07-13 2012-11-14 青岛海信宽带多媒体技术有限公司 Passive optical network and optical line terminal optical module thereof
CN105470808A (en) * 2016-01-11 2016-04-06 深圳新飞通光电子技术有限公司 Tunable laser system with multi-optical-path output
CN105514781A (en) * 2016-01-11 2016-04-20 深圳新飞通光电子技术有限公司 Wavelength locking device
CN107346989A (en) * 2016-05-06 2017-11-14 福州高意通讯有限公司 A kind of multi-channel laser wavelength dependence monitor and monitoring method
CN108507686A (en) * 2018-02-02 2018-09-07 北京科益虹源光电技术有限公司 A kind of temperature drift feedback method and device that laser center wavelength measures

Family Cites Families (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JP2687557B2 (en) * 1989-03-17 1997-12-08 横河電機株式会社 Frequency stabilized semiconductor laser device
JP4000195B2 (en) * 1994-08-19 2007-10-31 ライカ ゲオジステームス アクチエンゲゼルシャフト Stabilized multi-frequency light source device for generation of combined light wavelength and method for generation of combined light wavelength
US6516010B1 (en) * 1999-07-13 2003-02-04 Agere Systems, Inc. Method and apparatus for active numeric temperature compensation of an etalon in a wavelength stabilized laser

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102158662A (en) * 2011-04-15 2011-08-17 中国科学院长春光学精密机械与物理研究所 Image data transmission circuit of satellite-borne high-resolution CCD (Charge Coupled Device) camera
CN102780529A (en) * 2012-07-13 2012-11-14 青岛海信宽带多媒体技术有限公司 Passive optical network and optical line terminal optical module thereof
CN105470808A (en) * 2016-01-11 2016-04-06 深圳新飞通光电子技术有限公司 Tunable laser system with multi-optical-path output
CN105514781A (en) * 2016-01-11 2016-04-20 深圳新飞通光电子技术有限公司 Wavelength locking device
CN107346989A (en) * 2016-05-06 2017-11-14 福州高意通讯有限公司 A kind of multi-channel laser wavelength dependence monitor and monitoring method
CN107346989B (en) * 2016-05-06 2019-10-29 福州高意通讯有限公司 A kind of multi-channel laser wavelength dependence monitor and monitoring method
CN108507686A (en) * 2018-02-02 2018-09-07 北京科益虹源光电技术有限公司 A kind of temperature drift feedback method and device that laser center wavelength measures
CN108507686B (en) * 2018-02-02 2019-09-27 北京科益虹源光电技术有限公司 A kind of the temperature drift feedback method and device of laser center wavelength measurement

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