CN201518072U - Multi-focus regulating and controlling system - Google Patents
Multi-focus regulating and controlling system Download PDFInfo
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- CN201518072U CN201518072U CN200920199135XU CN200920199135U CN201518072U CN 201518072 U CN201518072 U CN 201518072U CN 200920199135X U CN200920199135X U CN 200920199135XU CN 200920199135 U CN200920199135 U CN 200920199135U CN 201518072 U CN201518072 U CN 201518072U
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Abstract
The utility model belongs to the technical field of applied optics, and relates to a radial cosine phase type axial multi-focus regulating and controlling system. The whole set system is composed of coherent light source emission components, a light beam diameter adjuster, a radial cosine phase wave front adjuster and an optical focusing component. Emission light beams of the coherent light source emission components are adjusted to demanded diameter through the light beam diameter adjuster and then are focused by the optical focusing component into a focus zone. The radial cosine phase wave front adjuster is used to adjust the front side of incidence light waves to enable the wave-front phase to show radial cosine changes, the focus zone forms multi-focus distribution on light axis after being focused by the optical focusing component, and the multi-focus distance and number can be regulated and controlled by cosine function parameters of the radial cosine phase wave front adjuster. The multi-focus regulating and controlling system is characterized in that multi-focus axial regulation and control are convenient, light energy utilization efficiency is high, the system is terse, and the like.
Description
Technical field:
The utility model belongs to the applied optics technical field, and system is relevant with Focused Optical system focus area light intensity regulating, particularly a kind of multi-focus regulation system.Be mainly used in fields such as Laser Micro-Machining, the little manipulation of optics, optical information storage, light and matter interaction.
Background technology:
In many Focused Optical systems, the focus area light intensity plays important effect.In optical storage system, reduce the focus spot size and can improve the optical information storage density, long depth of focus is easy to the laser servo system works, and axial many focuses then can be applied in the emerging multilayer optical storage technology.In light tweezers field, since Ashkin research and development light tweezers, obtained swift and violent development from the light forceps technique, promoted the big step development in a lot of fields, particularly at life science.For validity, dirigibility and the controllable type that increases light tweezers device, the certain methods such as technology, holographic optical tweezers array and interference fringe pattern that match are suggested, many focus systems are subjected to extensive concern owing to can realize the advantage that a plurality of particles are handled simultaneously.Formerly in the technology, a kind of many focuses of Focused Optical system generating technique in optical tweezer technology field that is applied to is arranged (referring to United States Patent (USP) " Transverseoptical accelerator and generalized optical vortex ", the patent No.: US 7,109,473, B2, patent time D ate of patent:2006 September 19).This many focuses of Focused Optical system generating technique has suitable advantage, but, still come with some shortcomings: 1) in this many focuses of Focused Optical system generating technique the plane of many focus distribution on the plane vertical with systematic optical axis, luminous energy is disperseed, if guarantee suitable light intensity and optical gradient forces that each focus produces, utilization ratio of optical energy is low, and required incident laser light source will have higher Output optical power; 2) the light tweezer of Chan Shenging is powerless for the control of the molecule on the optical axis direction direction; 3) beam propagation exists from axle, has increased the adjusting difficulty, the system architecture complexity.
The utility model content:
Problem to be solved in the utility model has been to overcome the deficiency of above-mentioned technology formerly, and a kind of axial multi-focus regulation system is provided, and it has many focal axis to regulation and control, characteristics such as regulation and control are convenient, utilization ratio of optical energy is high, system is succinct.
Basic design of the present utility model is:
The utility model provides a kind of multi-focus regulation system.Whole system is by coherent source emission element, beam diameter regulator, radially cosine phase wave front modifier, optical focus parts constitute.Coherent source emission element outgoing beam through the beam diameter regulator with the light beam regulation required diameter after, focus on by the optical focus parts and to form focus area.Radially the cosine phase wave front modifier is regulated the incident light wave front, make Wave-front phase be radially varies with cosine, after the focusing of optical focus parts, focus area just forms the many focus distribution on the optical axis, and many focuses spacing and number can be by the radially cosine function parameter regulation and control of cosine phase wave front modifier.System has characteristics such as many focal axis are convenient to regulation and control, utilization ratio of optical energy is high, system is succinct.
Technical solution of the present utility model is as follows:
A kind of multi-focus regulation system, system is by coherent source emission element 1, beam diameter regulator 2, radially cosine phase wave front modifier 3, optical focus parts 4 constitute; Be equipped with beam diameter regulator 2, radially cosine phase wave front modifier 3, optical focus parts 4 on the coherent source emission element 1 outgoing beam direction successively; Radially the control phase on the cosine phase wave front modifier 3 radially presents the cosine function distribution, and the incident beam wavefront surface is carried out phase modulation (PM), and the cosine function parameter is adjustable.
The beam diameter regulator 2 of above-mentioned multi-focus regulation system is the adjustable beam expander optics of beam expander multiplying power.
The beam diameter regulator 2 of above-mentioned multi-focus regulation system can be Galileo type beam expanding lens or Cape Town type beam expanding lens.
The mode of operation of the radially cosine phase wave front modifier 3 of above-mentioned multi-focus regulation system can be transmission-type or two kinds of pattern one of reflection-type.
The radially cosine phase wave front modifier 3 of above-mentioned multi-focus regulation system is programmable phase type spatial light modulator or liquid crystal optics phase control device able to programme or ray machine electricity integrated phase control device one.
When the radially cosine phase wave front modifier 3 of above-mentioned multi-focus regulation system is reflective mode operation, radially be equipped with light beam splitter 6 between cosine phase wave front modifier 3 and the beam diameter regulator 2.
The light beam splitter 6 of above-mentioned multi-focus regulation system and radially be equipped with 1/4th slides between the cosine phase wave front modifier 3,1/4th slide optical axis directions become miter angle with the incident ray polarization direction, and light beam splitter 6 is a polarization spectroscope.Perhaps, the light beam splitter 6 of above-mentioned multi-focus regulation system is near radially being coated with 1/4th slides on the cosine phase wave front modifier 3 one sidelights workplace.
A kind of multi-focus regulation system of the present utility model is structure as mentioned above, the course of work is that coherent source emission element 1 outgoing coherent light beam is through beam diameter regulator 2,2 pairs of light beams of beam diameter regulator expand bundle, expand laser beam behind the bundle through after the cosine phase wave front modifier 3 radially, focus on by optical focus parts 4; Radially the Wave-front phase of the laser beam of 3 pairs of incidents of cosine phase wave front modifier distributes and has carried out the radial distribution adjusting, cosine function changes to make PHASE DISTRIBUTION present radially, after having laser beam that cosine phase radially changes wavefront surface and focusing on, a plurality of focuses of axial distribution have been formed at focus area through optical focus parts 4.
Radially the mode of operation of cosine phase wave front modifier 3 can be transmission-type and two kinds of patterns of reflection-type.Under the reflective-mode working condition, radially be equipped with light beam splitter 6 between cosine phase wave front modifier 3 and the beam diameter regulator 2.Be equipped with beam diameter regulator 2, light beam splitter 6 and cosine phase wave front modifier 3 radially on the coherent source emission element 1 light beam exit direction successively, radially the mode of operation of cosine phase wave front modifier 3 is a reflection-type, light beam irradiates is reflected back toward in cosine phase wave front modifier 3 radially, once more through being equipped with optical focus parts 4 on the light beam splitter 6 back reflection beam directions.The course of work is: coherent source emission element 1 outgoing coherent light beam is through beam diameter regulator 2, expand laser beam behind the bundle through light beam splitter 6 transmissions after by radially cosine phase wave front modifier 3 reflections; Part light was reflected when the light beam of reflected back passed through light beam splitter 6 once more, was focused on by optical focus parts 4; The Wave-front phase of the laser beam of 3 pairs of incidents of radially cosine phase wave front modifier of reflective mode operation distributes and has carried out the radial distribution adjusting, after having laser beam that cosine phase radially changes wavefront surface and focusing on, a plurality of focuses of axial distribution have been formed at focus area through optical focus parts 4.
Efficiency of light energy utilization light beam splitter adopts polarization spectroscope 7 under the reflective mode operation in order to improve, between the radially cosine phase wave front modifier 3 of polarization spectroscope 7 and reflective mode operation, be equipped with 1/4th slides 8, / 4th slides, 8 optical axis directions become miter angle with the incident ray polarization direction, / 4th slides 8 can be independent optical element, also can be for being plated in 1/4th films 8 on the polarization spectroscope 7 close radially cosine phase wave front modifier 3 one side optical surfaces.The course of work is: coherent source emission element 1 outgoing coherent light beam becomes first light beam through beam diameter regulator 2 after laser beam process polarization spectroscope 7 behind the expansion bundle and 8 transmissions of 1/4th slides, by radially cosine phase wave front modifier 3 reflections; The light beam of reflected back is converted into linearly polarized light through 1/4th slides 8 by circularly polarized light once more, the polarization direction with for the first time through polarized lights before 1/4th slides 8 to vertical, so it is very high to be polarized spectroscope 7 reflex time reflectivity, reflected light is focused on by optical focus parts 4; The Wave-front phase of the laser beam of 3 pairs of incidents of radially cosine phase wave front modifier of reflective mode operation distributes and has carried out the radial distribution adjusting, has formed a plurality of focuses of axial distribution at focus area.
Advantage of the present utility model:
1) the axial many focuses of phase type produce and regulation and control, and focus quantity, distribution shape, spacing are all adjustable, and can produce Jiao and move with focus and jump;
2) axially multi-focus regulation is convenient, the reliability height, and dirigibility is strong;
3) incident light utilization ratio of optical energy height;
4) system architecture is simple, and stable performance requires low to mechanical positioning.
Description of drawings:
Fig. 1 is the first embodiment synoptic diagram of the present utility model.
Fig. 2 is a radially cosine phase wave front modifier synoptic diagram of the present utility model.
Fig. 3 is the axial many focus distribution figure of focus area of the present utility model (containing two figure of Fig. 3 A and Fig. 3 B).
Fig. 4 is the second embodiment synoptic diagram of the present utility model.
Fig. 5 is the 3rd an embodiment synoptic diagram of the present utility model.
Embodiment:
First specific embodiment
Fig. 1 is the first embodiment synoptic diagram of the present utility model.A kind of multi-focus regulation system is characterized in that system is by coherent source emission element 1, beam diameter regulator 2, radially cosine phase wave front modifier 3, optical focus parts 4 constitute; Be equipped with beam diameter regulator 2, radially cosine phase wave front modifier 3, optical focus parts 4 on the coherent source emission element 1 outgoing beam direction successively; Radially the control phase on the cosine phase wave front modifier 3 radially presents the cosine function distribution, and the incident beam wavefront surface is carried out phase modulation (PM), and the cosine function parameter is adjustable.
Coherent source emission element 1 is selected carbon dioxide gas laser for use, and beam diameter regulator 2 adopts Galileo type beam expanding lens, and optical focus parts 4 are Nikon flat field apochromatic objective.
A kind of multi-focus regulation system is structure as mentioned above, the course of work is that coherent source emission element 1 outgoing coherent light beam is through beam diameter regulator 2,2 pairs of light beams of beam diameter regulator expand bundle, expand laser beam behind the bundle through after the cosine phase wave front modifier 3 radially, focus on by optical focus parts 4; Radially the Wave-front phase of the laser beam of 3 pairs of incidents of cosine phase wave front modifier distributes and has carried out the radial distribution adjusting, cosine function changes to make PHASE DISTRIBUTION present radially, after having laser beam that cosine phase radially changes wavefront surface and focusing on, a plurality of focuses of axial distribution have been formed at focus area through optical focus parts 4.Fig. 2 is a radially cosine phase wave front modifier synoptic diagram of the present utility model.The axial many focus distribution figure of focus area that Fig. 3 obtains for the utility model, horizontal ordinate is for being the axial coordinate of true origin with the geometrical focus, unit is a wave number.
Second specific embodiment
Fig. 4 is the second embodiment synoptic diagram of the present utility model, and a kind of multi-focus regulation system is reflective mode operation.Under the reflective-mode working condition, radially be equipped with light beam splitter 6 between cosine phase wave front modifier 3 and the beam diameter regulator 2.
Be equipped with beam diameter regulator 2, light beam splitter 6 and cosine phase wave front modifier 3 radially on the coherent source emission element 1 light beam exit direction successively, radially the mode of operation of cosine phase wave front modifier 3 is a reflection-type, light beam irradiates is reflected back toward in cosine phase wave front modifier 3 radially, once more through being equipped with optical focus parts 4 on the light beam splitter 6 back reflection beam directions.
Coherent source emission element 1 is selected carbon dioxide gas laser for use, and beam diameter regulator 2 adopts Galileo type beam expanding lens, and optical focus parts 4 are Nikon flat field apochromatic objective, and 6 fens light pens of light beam splitter are 1: 1.
The course of work is: coherent source emission element 1 outgoing coherent light beam is through beam diameter regulator 2, expand laser beam behind the bundle through light beam splitter 6 transmissions after by radially cosine phase wave front modifier 3 reflections; Part light was reflected when the light beam of reflected back passed through light beam splitter 6 once more, was focused on by optical focus parts 4; The Wave-front phase of the laser beam of 3 pairs of incidents of radially cosine phase wave front modifier of reflective mode operation distributes and has carried out the radial distribution adjusting, after having laser beam that cosine phase radially changes wavefront surface and focusing on, a plurality of focuses of axial distribution have been formed at focus area through optical focus parts 4.A plurality of focus effects that present embodiment produces axial distribution are identical with first embodiment, for example produce the many focuses as Fig. 3 A and Fig. 3 B.
The 3rd specific embodiment
Fig. 5 is the 3rd an embodiment synoptic diagram of the present utility model, on the basis of second embodiment, efficiency of light energy utilization light beam splitter adopts polarization spectroscope 7 under the reflective mode operation in order to improve, between the radially cosine phase wave front modifier 3 of polarization spectroscope 7 and reflective mode operation, be equipped with 1/4th slides 8, / 4th slides, 8 optical axis directions become miter angle with the incident ray polarization direction, and 1/4th slides 8 are independent optical element.
The present embodiment course of work is: coherent source emission element 1 outgoing coherent light beam is through beam diameter regulator 2, become first light beam after laser beam process polarization spectroscope 7 behind the expansion bundle and 8 transmissions of 1/4th slides, by radially cosine phase wave front modifier 3 reflections; The light beam of reflected back is once more through behind 1/4th slides 8, be converted into linearly polarized light by circularly polarized light, the polarization direction with for the first time through polarized lights before 1/4th slides 8 to vertical, so it is very high to be polarized spectroscope 7 reflex time reflectivity, reflected light is by 4 focusing of optical focus parts; The Wave-front phase of the laser beam of 3 pairs of incidents of radially cosine phase wave front modifier of reflective mode operation distributes and has carried out the radial distribution adjusting, a plurality of focuses of axial distribution have been formed at focus area, the a plurality of focus effects that produce axial distribution are identical with preceding two embodiment, for example the many focus distribution situation shown in Fig. 3 A and Fig. 3 B.
Claims (8)
1. multi-focus regulation system is characterized in that: system is by coherent source emission element (1), beam diameter regulator (2), radially cosine phase wave front modifier (3), optical focus parts (4) constitute; Be equipped with beam diameter regulator (2), radially cosine phase wave front modifier (3), optical focus parts (4) on coherent source emission element (1) the outgoing beam direction successively; Radially the control phase on the cosine phase wave front modifier (3) radially presents the cosine function distribution, and the incident beam wavefront surface is carried out phase modulation (PM), and the cosine function parameter is adjustable.
2. a kind of according to claim 1 multi-focus regulation system is characterized in that: beam diameter regulator (2) is the adjustable beam expander optics of beam expander multiplying power.
3. a kind of according to claim 1 multi-focus regulation system is characterized in that: beam diameter regulator (2) is Galileo type beam expanding lens or Cape Town type beam expanding lens.
4. a kind of according to claim 1 multi-focus regulation system is characterized in that: radially the mode of operation of cosine phase wave front modifier (3) is transmission-type or reflection-type pattern.
5. a kind of according to claim 1 multi-focus regulation system is characterized in that: radially cosine phase wave front modifier (3) is programmable phase type spatial light modulator or liquid crystal optics phase control device able to programme or ray machine electricity integrated phase control device one.
6. a kind of according to claim 1 multi-focus regulation system, it is characterized in that: when radially cosine phase wave front modifier (3) is for reflective mode operation, radially be equipped with light beam splitter (6) between cosine phase wave front modifier (3) and the beam diameter regulator (2).
7. a kind of according to claim 1 multi-focus regulation system, it is characterized in that: light beam splitter (6) and radially be equipped with 1/4th slides between the cosine phase wave front modifier (3), / 4th slide optical axis directions become miter angle with the incident ray polarization direction, and light beam splitter (6) is a polarization spectroscope.
8. as a kind of multi-focus regulation system as described in the claim 7, it is characterized in that: light beam splitter (6) is learned on the workplace near cosine phase wave front modifier (3) one sidelights radially and is coated with 1/4th slides.
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| CN200920199135XU CN201518072U (en) | 2009-10-21 | 2009-10-21 | Multi-focus regulating and controlling system |
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| CN200920199135XU CN201518072U (en) | 2009-10-21 | 2009-10-21 | Multi-focus regulating and controlling system |
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Cited By (9)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN102566077A (en) * | 2012-02-10 | 2012-07-11 | 上海理工大学 | Multifocal imaging device and method |
| CN102566055A (en) * | 2012-02-10 | 2012-07-11 | 上海理工大学 | Phase plate multi-focus generation apparatus and generation method thereof |
| CN103424879A (en) * | 2013-06-07 | 2013-12-04 | 上海理工大学 | Focusing optical system based on single object lens |
| CN104785923A (en) * | 2014-01-22 | 2015-07-22 | 深圳市韵腾激光科技有限公司 | Multi-point focusing laser processing device |
| CN106994557A (en) * | 2017-04-20 | 2017-08-01 | 武汉铱科赛科技有限公司 | A kind of dynamic controllable laser-processing system and method for focal position of laser |
| CN107529467A (en) * | 2017-08-21 | 2018-01-02 | 成都莱普科技有限公司 | Silicon-based MEMS wafer multi-focus laser cutting system and cutting method |
| CN111913313A (en) * | 2020-07-20 | 2020-11-10 | 南昌大学 | Parameter-adjustable axial cosine structure light generation device and method |
| CN113741025A (en) * | 2020-05-27 | 2021-12-03 | 山东大学 | Photon flight stabilizing system |
| CN117191714A (en) * | 2023-09-06 | 2023-12-08 | 深圳市凯佳光学科技有限公司 | Single-molecule mechanical testing system and method based on double-optical-trap optical tweezers |
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2009
- 2009-10-21 CN CN200920199135XU patent/CN201518072U/en not_active Expired - Fee Related
Cited By (12)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN102566077A (en) * | 2012-02-10 | 2012-07-11 | 上海理工大学 | Multifocal imaging device and method |
| CN102566055A (en) * | 2012-02-10 | 2012-07-11 | 上海理工大学 | Phase plate multi-focus generation apparatus and generation method thereof |
| CN103424879A (en) * | 2013-06-07 | 2013-12-04 | 上海理工大学 | Focusing optical system based on single object lens |
| CN103424879B (en) * | 2013-06-07 | 2015-09-16 | 上海理工大学 | Based on the Focused Optical system of single object lens |
| CN104785923A (en) * | 2014-01-22 | 2015-07-22 | 深圳市韵腾激光科技有限公司 | Multi-point focusing laser processing device |
| CN106994557A (en) * | 2017-04-20 | 2017-08-01 | 武汉铱科赛科技有限公司 | A kind of dynamic controllable laser-processing system and method for focal position of laser |
| CN106994557B (en) * | 2017-04-20 | 2018-10-19 | 武汉铱科赛科技有限公司 | A kind of laser-processing system and method that focal position of laser dynamic is controllable |
| CN107529467A (en) * | 2017-08-21 | 2018-01-02 | 成都莱普科技有限公司 | Silicon-based MEMS wafer multi-focus laser cutting system and cutting method |
| CN107529467B (en) * | 2017-08-21 | 2019-10-25 | 成都莱普科技有限公司 | Silicon-based MEMS wafer multi-focus laser cutting system and cutting method |
| CN113741025A (en) * | 2020-05-27 | 2021-12-03 | 山东大学 | Photon flight stabilizing system |
| CN111913313A (en) * | 2020-07-20 | 2020-11-10 | 南昌大学 | Parameter-adjustable axial cosine structure light generation device and method |
| CN117191714A (en) * | 2023-09-06 | 2023-12-08 | 深圳市凯佳光学科技有限公司 | Single-molecule mechanical testing system and method based on double-optical-trap optical tweezers |
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