CN1334473A - Method for regulating parallelism of raster pair - Google Patents
Method for regulating parallelism of raster pair Download PDFInfo
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- CN1334473A CN1334473A CN 01126556 CN01126556A CN1334473A CN 1334473 A CN1334473 A CN 1334473A CN 01126556 CN01126556 CN 01126556 CN 01126556 A CN01126556 A CN 01126556A CN 1334473 A CN1334473 A CN 1334473A
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Abstract
A method for regulating the parallelism of raster pair is based on the dispersion characteristics of raster to the light beams with different wavelengthes. Two laser devices are used to emit two laser beams with different wavelengthes. Said laser beams are gathered into one and then fined. The fine beam is emitted onto the first raster to generate two diffracted beams, and then onto the second raster to also generate two diffracted beams, which are reflected back to a graduated ruler via said two rasters. The distance between two light spots can be used to regulate said parallelism. If said distance does not change for far field and near field, two rasters are fully parallel. Its advantages are simple regulation steps, high precision and high reliability.
Description
Technical field:
The present invention is a kind of about adjusting the parallel method of grating pair, mainly is applicable to and adjusts two positions that grating is parallel to each other.
Background technology:
Superpower in ultrashort (femtosecond magnitude) (greater than 10
12Watt) in the generation of Laser process, need be with a pair of grating compress that is parallel to each other, the depth of parallelism of accurately adjusting grating pair to the waveform quality that guarantees output optical pulse, improve peak power and have great significance.Formerly in the technology, Edward Miesak and Raluca Negres are at article " Alignment Procedure for a Dual Grating Pulse Compressor " (Optic andPhotonics News, 1998, vol.9, No.8, a kind of method of adjustment is provided the insert between the P36-37), and light path arrangement as shown in Figure 1.Method of adjustment and step are: beam of laser is incided on the half-reflecting half mirror 1, incide on first catoptron 3 through passing aperture 2 after the reflection, regulate first catoptron 3 and make laser gki be mapped to the center O of first grating 4
1On, adjust first grating 4 then and make its diffracted beam drop on the center O of second grating 6
2On.2. second catoptron 5 is put into the B position, the attitude of regulating it makes penetrates the laser beam of coming from first catoptron 3 and returns (whether to pass the foundation of aperture 2 as judgement) along former road.3. keep the attitude of second catoptron 5 constant, move to the C point, second catoptron 5 returns beam reflection to second grating 6, regulates second grating 6, make light beam return (whether to pass aperture 2) along former road as the foundation of judging, so just can judge two gratings 4 with 6 parallel.
In the above-mentioned technology formerly, the step of adjustment is all a lot of with the optical element that relates to, and error is inevitable also many, and the parallel accuracy of two gratings is difficult to guarantee.
Summary of the invention:
The present invention adjusts the parallel method of grating pair, is the dispersion characteristics of utilizing grating pair different wave length light beam, selects two bundle different wave length λ for use
1≠ λ
2Laser beam adjust.The layout of its light path as shown in Figure 2.Concrete set-up procedure is:<1〉at first select for use generation two to restraint different wave length λ
1≠ λ
2 First laser instrument 7 of laser beam and second laser instrument 8, and make two bundle different wave length λ
1And λ
2Laser beam through being mixed into a branch of co-linear beams OA behind half anti-semi-permeable mirror 1;<2〉above-mentioned co-linear beams OA is mapped on first grating 4 by an aperture 2, produce two bundles, first optical grating diffraction light beam A D and the AE, the first optical grating diffraction light beam A D and AE are incided on second grating 6 produce two bundle second optical grating diffraction light beam DF and EG to be mapped to that back reflection goes back on the catoptron 5, through being mapped on the scale 9 that has scale behind second grating 6 and first grating 4, form two luminous points once more;<3〉mobile scale 9 is observed the variation of spacing when far field and near field of two luminous points on the scale 9.The spacing of two luminous points no change when far field and near field shows that then first grating 4 and second grating 6 are parallel to each other; The spacing of two luminous points changes when far field and near field, and promptly both are unequal, then adjusts first grating 4 and second grating 6 respectively, up in far field and near field the time, till the spacing no change of two luminous points, till promptly two gratings are parallel to each other.
The invention described above is adjusted the parallel method of grating pair, its light path arrangement as shown in Figure 2, concrete set-up procedure as mentioned above: 1. two bundle different wave length λ that at first first laser instrument 7 and second laser instrument 8 sent with half anti-semi-permeable mirror 1
1And λ
2(λ
1≠ λ
2) laser beam mixed be a branch of co-linear beams OA.I.e. first laser instrument, 7 emission wavelength lambda
1Laser beam see through half-reflecting half mirror 1 back and second laser instrument, 8 emission wavelength lambda
2Laser beam two laser after half-reflecting half mirror 1 reflection be combined into a co-linear beams OA.2. aperture 2 is put into light path, make co-linear beams OA through thin as much as possible behind the aperture 2.3. co-linear beams OA incides on first grating 4, because different wave length λ
1And λ
2Diffraction of light angle difference, co-linear beams OA will produce two bundle first optical grating diffraction light beam A D and the AE separately, after they incide second grating, 6 surfaces and go up again diffraction go out corresponding two bundles, second optical grating diffraction light beam DF and the EG.Catoptron 5 reflects back two bundle second optical grating diffraction light beam DF and EG, and once more through second grating 6 and first grating 4, last diffraction goes out two light beam LN and KM, forms two luminous points on scale 9.The scale 9 that 3. will have scale shifts near or moves far, and relatively whether the spacing of two luminous points changes when near field and far field.If the spacing of two luminous points changes with shifting near or move far of scale 9, illustrate that then two light beam LN and KM disperse, be not parallel to each other mutually, show that just two gratings are not parallel.Adjust two gratings 4 and 6 respectively, till two light beam LN and KM are parallel to each other, just can judge that two gratings have been adjusted into this moment to be parallel to each other.
Compare with technology formerly, the present invention has outstanding feature and is: 1. utilize grating to judge being parallel to each other of two gratings for the dispersion characteristics of different wavelengths of light bundle.Formerly be to calibrate grating with beam of laser in the technology, and the present invention calibrates with two bundle different wavelength of laser bundles, it adjusts precision height, good reliability.Light path arrangement as shown in Figure 2, laser beam diffraction four times back and forth between two gratings is separated the different wavelength of laser bundle at last.If two gratings are not parallel, an angle is arranged relatively, will produce angular dispersion.Angular dispersion can make the directional light of two initial parallel bundle different wave lengths become not parallel.2. the element that will adjust among the present invention is few, and then the error of Tiao Zhenging is little.Set-up procedure is easy to memory and grasps simultaneously.Formerly in the technology except must adjusting two gratings, the auxiliary element of need adjusting is many, step is also many, error is big.The present invention only is in course of adjustment and needs to adjust two gratings and get final product, and other auxiliary element is disposable not to be needed to readjust after putting well again, has so just simplified set-up procedure, has reduced error.For example to catoptron 5, formerly at first will be in the technology in the B position with its placement angular setting to perpendicular with laser beam, keep then placing the constant C position that moves to of angle, the track of translation is perpendicular with laser beam.And the present invention arbitrarily places the requirement that has nothing special of the placement angle of catoptron 5 and position, as long as it can satisfy reflection function, and does not need to regulate it in adjustment process subsequently again.
Description of drawings:
Fig. 1 is the parallel light path arrangement synoptic diagram that method adopted of technological adjustment grating pair formerly.
Fig. 2 adjusts the parallel light path arrangement synoptic diagram that method adopted of grating pair for the present invention.
The specific embodiment:
Use light path arrangement as shown in Figure 2. First laser instrument, 7 usefulness be wavelength X1The He-Ne laser of=632.8nm, second laser 8 usefulness be wavelength X2The semiconductor laser of=1060nm. Regulate aperture 2 bore makes light beam as much as possible thin, and this helps to improve precision. Placed angle and the position of speculum 5 do not have Any special requirement is arranged, can arbitrarily place, as long as it is just passable to play reflex. The minimum scale of scale 9 Reach a millimeter magnitude. Block two light beam LN and KM of last outgoing with scale 9, can be at the table of scale 9 See two luminous points on the face, one of them luminous point is that wavelength is λ1He-Ne Lasers, another luminous point is that wavelength is λ2Semiconductor laser. Scale 9 is shifted near and moves far, and relatively the spacing of two luminous points is when near field and far field Whether change, with this as judging whether parallel foundation of two gratings. If the spacing of two luminous points changes, divide Do not adjust two gratings 4 and 6, until spacing is constant.
Claims (1)
1. adjust the parallel method of grating pair for one kind, make light source, adjust first grating (4) and second grating (6) is parallel to each other, it is characterized in that concrete set-up procedure is with laser instrument:
<1〉at first selects generation different wave length (λ for use
1≠ λ
2) first laser instrument (7) and second laser instrument (8) of laser beam, and make two bundle different wavelength of laser bundles be mixed into a branch of co-linear beams (OA) through half anti-semi-permeable mirror (1);
<2〉above-mentioned co-linear beams (OA) is mapped on first grating (4) by an aperture (2), producing the two bundle first optical grating diffraction light beams (AD, AE) incides second grating (6) and goes up and produce the two bundle second optical grating diffraction light beams (DF, EG) and be mapped to catoptron (5) and go up back reflection and go back, be mapped on the scale (9) that has scale through second block of grating (6) and first block of grating (4) once more, form two luminous points;
<3〉mobile scale (9) is observed the spacing of last two luminous points of scale (9) when far field and near field and is changed, and the spacing no change of two luminous points shows that then first grating (4) and second grating (6) are parallel to each other; The spacing of two luminous points changes in far field and near field, then adjusts first grating (4) and second grating (6) respectively, up in far field and near field the time, till the spacing no change of two luminous points.
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CNB011265566A CN1145053C (en) | 2001-08-27 | 2001-08-27 | Method for regulating parallelism of raster pair |
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CNB011265566A CN1145053C (en) | 2001-08-27 | 2001-08-27 | Method for regulating parallelism of raster pair |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103017659A (en) * | 2012-12-29 | 2013-04-03 | 中国科学院长春光学精密机械与物理研究所 | Synchronous tiny potential difference and angular difference detection system for combined laser beam emitting light path |
CN108363217A (en) * | 2018-04-20 | 2018-08-03 | 中国科学院物理研究所 | Method and the application of parallelism of raster pair are adjusted and monitored using automatic leveling laser scale |
CN109217076A (en) * | 2018-10-31 | 2019-01-15 | 中国科学院物理研究所 | Laser adjusting method and corresponding device |
Families Citing this family (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN100401133C (en) * | 2006-09-12 | 2008-07-09 | 中国科学院上海光学精密机械研究所 | Method for regulating parallel raster pair |
-
2001
- 2001-08-27 CN CNB011265566A patent/CN1145053C/en not_active Expired - Fee Related
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103017659A (en) * | 2012-12-29 | 2013-04-03 | 中国科学院长春光学精密机械与物理研究所 | Synchronous tiny potential difference and angular difference detection system for combined laser beam emitting light path |
CN103017659B (en) * | 2012-12-29 | 2015-11-25 | 中国科学院长春光学精密机械与物理研究所 | Swash combiner and launch the small potential difference of light path detection system synchronous with angular difference |
CN108363217A (en) * | 2018-04-20 | 2018-08-03 | 中国科学院物理研究所 | Method and the application of parallelism of raster pair are adjusted and monitored using automatic leveling laser scale |
CN109217076A (en) * | 2018-10-31 | 2019-01-15 | 中国科学院物理研究所 | Laser adjusting method and corresponding device |
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