CN203672491U - Fourier transform spectrometer - Google Patents
Fourier transform spectrometer Download PDFInfo
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- CN203672491U CN203672491U CN201320894368.8U CN201320894368U CN203672491U CN 203672491 U CN203672491 U CN 203672491U CN 201320894368 U CN201320894368 U CN 201320894368U CN 203672491 U CN203672491 U CN 203672491U
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- catoptron
- light
- beam splitter
- fourier transform
- transmitted light
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- 230000003287 optical effect Effects 0.000 claims abstract description 24
- 230000005540 biological transmission Effects 0.000 claims description 10
- 230000033001 locomotion Effects 0.000 claims description 9
- 239000000523 sample Substances 0.000 claims description 6
- 230000003595 spectral effect Effects 0.000 description 4
- 230000000694 effects Effects 0.000 description 3
- 230000010287 polarization Effects 0.000 description 3
- 230000002452 interceptive effect Effects 0.000 description 2
- 229910001632 barium fluoride Inorganic materials 0.000 description 1
- 230000009286 beneficial effect Effects 0.000 description 1
- 239000008358 core component Substances 0.000 description 1
- 230000007812 deficiency Effects 0.000 description 1
- 238000001514 detection method Methods 0.000 description 1
- 239000011521 glass Substances 0.000 description 1
- 238000002329 infrared spectrum Methods 0.000 description 1
- 239000000463 material Substances 0.000 description 1
- 238000000034 method Methods 0.000 description 1
- SBIBMFFZSBJNJF-UHFFFAOYSA-N selenium;zinc Chemical compound [Se]=[Zn] SBIBMFFZSBJNJF-UHFFFAOYSA-N 0.000 description 1
- 238000004904 shortening Methods 0.000 description 1
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Abstract
The utility model relates to a Fourier transform spectrometer. The Fourier transform spectrometer comprises a light source, a collimation unit, a light splitting unit and a detecting unit, lights emitted by the light source is collimated via the collimation unit and incident to a beam splitter, the light splitting unit comprises the beam splitter, a transmitted light refractor, a first reflector, a second reflector and a mobile part, the incident light is divided into two beams by the beam splitter, the split reflected light is reflected back to the beam splitter by the first reflector, the split transmitted light is reflected by the transmitted light refractor and reflected back to the beam splitter by the second reflector, the transmitted light is refracted to the direction of the reflected light by the transmitted light refractor, the mobile part moves the first reflector and/or the second reflector and is used for changing optical path differences, and the lights reflected back via the first reflector and the second reflector are transmitted and reflected via the beam splitter and received by the detecting unit. The Fourier transform spectrometer is advantaged by high resolution, low tolerance requirement, small size, low cost and the like.
Description
Technical field
The utility model relates to a kind of Fourier transform spectrometer.
Background technology
Fourier transform spectrometer adopts Michelson interferometer as core component, its ultimate principle is: in the light beam incident interferometer of collimation, by the motion of index glass in interferometer, obtain the interferogram under different optical path differences, the interferogram obtaining is carried out to Fourier transform and can obtain corresponding spectrogram, thereby realize spectrographic detection.
And traditional Michelson interferometer is to be mainly made up of beam splitter, fixing plane mirror and the scanning reflection mirror of motion, wherein plane mirror and scanning reflection mirror are orthogonal, and the angle of both and beam splitter is 45 degree.Owing to being subject to the polarization effect impact of beam splitter, relatively low by the beam energy of interferometer.
This interferometer is after process beam splitter, and reflected light path and transmitted light path are mutually orthogonal, and this just makes the device of interferometer on reflection and two optical path directions of transmission, extend respectively, has greatly increased the volume of interferometer.
Although can realize dwindling of interferometer volume by shortening light path, but the moving device that gated sweep catoptron moves itself also can occupy two spaces on optical path direction, can not fundamentally solve the bulky problem of interferometer, also just cannot effectively reduce the volume of Fourier transform spectrometer.
Summary of the invention
In order to solve above-mentioned deficiency of the prior art, the utility model provides the Fourier transform spectrometer that a kind of volume is little, cost is low, resolution is high, tolerance is little.
For achieving the above object, the utility model adopts following technical scheme:
A kind of Fourier transform spectrometer, comprising:
Light source and collimation unit, the light that described light source sends incides on beam splitter after collimation unit collimation;
Spectrophotometric unit, described spectrophotometric unit comprises beam splitter, transmitted light refrative mirror, the first catoptron, the second catoptron and moving-member; Incident light is divided into two bundles by described beam splitter, the reflected light after beam splitting by the first catoptron retroeflection to beam splitter, the transmitted light after beam splitting after the reflection of described transmitted light refrative mirror by the second catoptron retroeflection to beam splitter; Described transmitted light is folded to described catoptrical direction by described transmitted light refrative mirror; Described moving-member moves described the first catoptron and/or the second catoptron for changing optical path difference;
Probe unit is detected unit through the light of the first catoptron, the second catoptron retroeflection and receives after described beam splitter transmission, reflection.
As preferably, described transmitted light refrative mirror is plane mirror.
As preferably, described transmitted light refrative mirror is parallel with described beam splitter.
As preferably, described the first catoptron and/or the second catoptron are plane mirror or corner reflector.
Further, when described the first catoptron, the second catoptron are corner reflector, described moving-member rotates mobile described the first catoptron, the second catoptron.
Further, described moving-member comprises balance staff and the first swing arm being connected with balance staff respectively, the second swing arm, and described the first catoptron, the second catoptron are connected with the first swing arm, the second swing arm respectively; Described balance staff drives the first swing arm, the second swing arm to swing, and the first swing arm, the second swing arm drive the first catoptron, the second mirror motion again, change optical path difference.
Further, the light that described light source sends incides on beam splitter with 30 ° of angles after collimation unit collimation.
The utility model compared with prior art has following beneficial effect:
1, volume is little, cost is low
By the transmitted light refrative mirror in transmitted light path, transmitted light is folded in catoptrical direction, because original reflected light light path still has device, transmitted light turns to catoptrical direction can additionally not occupy the space in reflected light direction, the space of spectrometer in transmission direction reduced greatly, dwindled the volume of spectrometer;
By transmitted light is folded in catoptrical direction, can adopt easily an actuating unit to control the movement of the catoptron on reflection and two optical path directions of transmission simultaneously, adopt minimum optical device to realize the object that spectrometer volume reduces thereby realized, reduced cost.
2, high spectral resolution
Under linear motor driving, can obtain the optical path difference of motor shift motion twice; Under swing arm tilting mechanism drives, can realize the optical path difference of approximately 4 times of angle mirrors at optical axis direction move distance, improve the spectral resolution of spectrometer.
3, tolerance is little
Spectrometer of the present utility model uses single refrative mirror to realize light path folding, when utilizing less optical device to dwindle the volume of interferometer, also can select corner reflector to realize light beam retroeflection, has reduced spectrometer optical alignment precision, is convenient to make realize.
4, beam energy utilization factor is high
The utility model adopts the mode of 30 ° of angle oblique incidences, no longer mutually orthogonal through reflected light and the transmitted light of beam splitter beam splitting, can reduce the impact of the polarization effect of being introduced by beam splitter, makes more light by interferometer, and beam energy utilization factor is high.
Accompanying drawing explanation
Fig. 1 is Fourier transform spectrometer structural representation in embodiment 1;
Fig. 2 is Fourier transform spectrometer structural representation in embodiment 2;
Fig. 3 is Fourier transform spectrometer structural representation in embodiment 4.
Embodiment
Embodiment 1
Refer to Fig. 1, a kind of Fourier transform spectrometer, is applied to infrared field, comprises light source 11, collimation unit 12, spectrophotometric unit 201 and probe unit 3.
The light that described light source 11 sends incides on beam splitter 21 after collimation unit 12 collimations; Described light source 11 is infrared light supply, and the collimating mirror of described collimation unit 12 is parabolic mirror;
The present embodiment, the light that described light source 11 sends incides on beam splitter with 30 ° of angles after collimation unit 12 collimations, can reduce the impact of beam splitter polarization effect, makes more beam energy by interferometer be
Described spectrophotometric unit 201 comprises beam splitter 21, transmitted light refrative mirror 23, the first catoptron 221, the second catoptron 241 and moving-member 251;
Incident light is divided into two bundles by described beam splitter 21, the reflected light after beam splitting by the first catoptron 221 retroeflection to beam splitter 21; Transmitted light after beam splitting after 23 reflections of described transmitted light refrative mirror by the second catoptron 241 retroeflection to beam splitter 21; Beam splitter 21 can be ZnSe, the materials such as KBr and BaF2;
Described transmitted light is folded to described catoptrical direction by described transmitted light refrative mirror 23; As long as described transmitted light refrative mirror 23 can be folded to described catoptrical direction by described transmission direction of light, without restriction to its type, as plane mirror, reflector plate etc.Simultaneously also without restriction to the placement direction of transmitted light refrative mirror 23.
Preferably, the transmitted light refrative mirror 23 of the present embodiment is and the plane mirror of described beam splitter 21 parallel placements; Transmitted light after folding is parallel with described catoptrical direction, is convenient to optical path adjusting, facilitates the control of moving-member to catoptron simultaneously.
Described the first catoptron 221 and the second catoptron 241 are used for making light path retroeflection to beam splitter, can be plane mirror or corner reflector.The present embodiment is plane mirror.
In order to change optical path difference, described moving-member 251 moves described the first catoptron 221 or the second catoptron 241 or moves the first catoptron 221 or the second catoptron 241 simultaneously all can; Can adopt linearity or rotating manner to move.The moving-member 251 of the present embodiment is linear motor, mobile described the second catoptron 24, and described the second catoptron 24 makes linear back and forth movement along optical axis place direction and changes optical path difference under linear motor driving.
Described probe unit 3 is infrared detecting unit, comprise and focus on parabolic mirror 31, infrared eye 32 and processing module 33, in this embodiment, infrared eye 32 can be other infrared detectors such as Si-PIN detector, MCT detector, DTGS detector.
Interfering beam focuses on infrared eye 32 light-sensitive surfaces through focusing on parabolic mirror 31, and at infrared eye, 32 places obtain a series of infrared signal intensity levels corresponding with optical path difference; Infrared eye 32 passes to processing module 33 by the infrared interference signal detecting and carries out Fourier transform, thereby obtains corresponding infrared spectrum spectrogram.
Under linear motor driving, can obtain the optical path difference of motor shift motion twice, greatly improve spectral resolution.
By the transmitted light refrative mirror in transmitted light path, transmitted light is folded in catoptrical direction, greatly shortened the light path in transmission direction, the space of spectrometer in transmission direction reduced greatly, dwindled spectrometer volume.
Embodiment 2
Refer to Fig. 2, a kind of Fourier transform spectrometer, different from the Fourier transform spectrometer in embodiment 1:
A kind of Fourier transform spectrometer, different from Fourier transform spectrometer described in embodiment 2:
Moving-member is mobile described the first catoptron also.
Embodiment 4
Refer to Fig. 3, a kind of Fourier transform spectrometer, different from Fourier transform spectrometer described in embodiment 3:
The first catoptron 222 in spectrophotometric unit 20, the second catoptron 242 are corner reflector, and moving-member 252 rotates mobile described the first catoptron 222, the second catoptron 242.
The present embodiment moving-member 252 adopts swing arm structure.
Described moving-member 252 comprises the first swing arm 26, the second swing arm 27 and balance staff 28, and described the first swing arm 26, the second swing arm 27 are connected on balance staff 28, and described the first catoptron 222, the second catoptron 242 are connected with the first swing arm 26, the second swing arm 27 respectively; Described balance staff 28 drives the first swing arm 26, the second swing arm 27 to swing, and the first swing arm 26, the second swing arm 27 drive the first catoptron 222, the second catoptron 242 to move again, and then changes optical path difference.
Under swing arm tilting mechanism drives, can realize the optical path difference of approximately 4 times of corner reflectors at optical axis direction move distance, improve the spectral resolution of spectrometer.
In the needs occasion of the catoptron on mobile reflected light path simultaneously, can adopt an actuating unit to control the movement of the catoptron on reflection and two optical path directions of transmission simultaneously, save the moving-member of originally controlling separately the catoptron on reflected light path, make spectrometer smaller volume, cost step-down.
Above-mentioned embodiment should not be construed as the restriction to the utility model protection domain.Key of the present utility model is: transmitted light is folded to reflected light direction, thereby has saved the space in transmitted light direction, reduced the volume of spectrometer.In the situation that not departing from the utility model spirit, within any type of change that the utility model is made all should fall into protection domain of the present utility model.
Claims (7)
1. a Fourier transform spectrometer, comprising:
Light source and collimation unit, the light that described light source sends incides on beam splitter after collimation unit collimation;
Spectrophotometric unit, described spectrophotometric unit comprises beam splitter, transmitted light refrative mirror, the first catoptron, the second catoptron and moving-member; Incident light is divided into two bundles by described beam splitter, the reflected light after beam splitting by the first catoptron retroeflection to beam splitter, the transmitted light after beam splitting after the reflection of described transmitted light refrative mirror by the second catoptron retroeflection to beam splitter; Described transmitted light is folded to described catoptrical direction by described transmitted light refrative mirror; Described moving-member moves described the first catoptron and/or the second catoptron for changing optical path difference;
Probe unit is detected unit through the light of the first catoptron, the second catoptron retroeflection and receives after described beam splitter transmission, reflection.
2. Fourier transform spectrometer according to claim 1, is characterized in that: described transmitted light refrative mirror is plane mirror.
3. Fourier transform spectrometer according to claim 2, is characterized in that: described transmitted light refrative mirror is parallel with described beam splitter.
4. Fourier transform spectrometer according to claim 1, is characterized in that: described the first catoptron and/or the second catoptron are plane mirror or corner reflector.
5. Fourier transform spectrometer according to claim 4, is characterized in that: when described the first catoptron, the second catoptron are corner reflector, described moving-member rotates mobile described the first catoptron, the second catoptron.
6. Fourier transform spectrometer according to claim 5, it is characterized in that: described moving-member comprises balance staff and be connected to the first swing arm, the second swing arm on balance staff, and described the first catoptron, the second catoptron are connected with the first swing arm, the second swing arm respectively; Described balance staff drives the first swing arm, the second swing arm to swing, and the first swing arm, the second swing arm drive the first catoptron, the second mirror motion again.
7. Fourier transform spectrometer according to claim 1, is characterized in that: the light that described light source sends incides on beam splitter with 30 ° of angles after collimation unit collimation.
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CN201320894368.8U CN203672491U (en) | 2013-12-23 | 2013-12-23 | Fourier transform spectrometer |
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CN201320894368.8U CN203672491U (en) | 2013-12-23 | 2013-12-23 | Fourier transform spectrometer |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN103712691A (en) * | 2013-12-23 | 2014-04-09 | 聚光科技(杭州)股份有限公司 | Fourier transformation spectrograph |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN103712691A (en) * | 2013-12-23 | 2014-04-09 | 聚光科技(杭州)股份有限公司 | Fourier transformation spectrograph |
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