CN207248114U - A kind of white light interference three-dimensional appearance transcriber - Google Patents
A kind of white light interference three-dimensional appearance transcriber Download PDFInfo
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- CN207248114U CN207248114U CN201720490091.0U CN201720490091U CN207248114U CN 207248114 U CN207248114 U CN 207248114U CN 201720490091 U CN201720490091 U CN 201720490091U CN 207248114 U CN207248114 U CN 207248114U
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Abstract
The utility model belongs to the application apparatus field of optical, mechanical and electronic integration, more particularly to a kind of white light interference three-dimensional appearance transcriber, including computer, driving device, the ccd image sensor set gradually, micro- eyepiece, microcobjective, optical compensation plate, beam-splitter and workbench, driving device is used to drive the equidistant displacement linear motion of workbench, the upper surface of optical compensation plate and beam-splitter is compounded with semi-transparent semi-reflecting film, the output terminal of computer is connected to the input terminal of driving device, the output terminal of ccd image sensor is connected to the input terminal of computer, computer is used for by reproducing object under test towards the three-dimensional appearance on the surface of beam-splitter.The utility model beneficial effect:Can the position of the micro- eyepiece of manual adjustment and microcobjective can be realized from the light that reflects on the light and optical compensation plate of object under test surface reflection close to aplanatism in advance, reach zero optical path difference, realize white light interference, it is easy to adjust;Easy to operate, cost of manufacture is relatively low, and economic value is considerable.
Description
Technical Field
The utility model belongs to the application apparatus field of optical-mechanical-electrical integration, concretely relates to three-dimensional appearance reappearance device is interfered to white light.
Background
The surface topography of an object is often obtained by contacting the surface of the object and then reconstructing the three-dimensional topography, which has the disadvantage of leaving scratches on the surface of the object. The method using optical interference is also called non-contact method, but it is rather difficult to realize white light interference, and the commonly used michael grandson interferometer uses 632.8nm red laser emitted by He-Ne laser to measure the change of tiny distance, and various three-dimensional topographers are already available. However, to observe the interference fringes of white light with higher quality, the interference arms of the michelson interferometer must be adjusted to be substantially completely symmetrical, so that the optical path difference of two coherent lights is very small, and the adjustment process needs to be careful and is very difficult to operate.
Disclosure of Invention
The utility model aims at overcoming the defect that prior art exists, provide a can adjust microscopical eyepiece and objective's position by manual work in advance to the light that reflects on realization follow object surface reflection that awaits measuring and the optical compensation board is close aplanatism, reaches zero optical path difference, realizes that the white light interferes, adjusts convenient white light and interferes three-dimensional appearance and reappear the device.
The utility model provides a technical scheme that its technical problem adopted is: the utility model provides a three-dimensional appearance reappearance device of white light interference, which comprises a computer, a drive arrangement, the CCD image sensor who sets gradually along light propagation direction, the microscope eyepiece, the microscope objective, the optical compensation board, beam splitter and the workstation that is used for placing the object that awaits measuring, a drive arrangement is used for driving the workstation and makes the linear motion of equidistance displacement in light propagation direction, optical compensation board and beam splitter all compound the half-transmitting and half-reflecting membrane towards the upper surface of microscope objective, the output of computer is connected to drive arrangement's signal input part, the signal output part of CCD image sensor is connected to the input of computer, the computer is used for through three-dimensional appearance analysis software, reappear the three-dimensional appearance of the object that awaits measuring towards the surface of beam splitter.
The utility model can select two glass plates with equal thickness and the upper surfaces of which are coated with the semi-transparent and semi-reflective film in advance, one glass plate coated with the semi-transparent and semi-reflective film is an optical compensation plate, the other glass plate coated with the semi-transparent and semi-reflective film is a beam splitter, and the microscope eyepiece, the microscope objective, the optical compensation plate and the beam splitter are coaxial; the lower part of the workbench is connected with a driving device, and the driving device is started to enable the workbench to gradually move upwards or downwards at equal intervals. Wherein, the utility model discloses a two glass boards that scribble the semi-transparent semi-reflecting membrane realize that white light interferes, reappear the device of non-transparent object three-dimensional appearance and have not reported yet.
The first path of light directly penetrates through the microscope eyepiece, the microscope objective, the optical compensation plate and the light splitting plate, and returns to the original path after being reflected by the upper surface of the object to be detected, the second path of light is reflected to the optical compensation plate through the light splitting plate, is reflected to the light splitting plate again by the semi-transparent semi-reflective film of the optical compensation plate, is reflected again by the semi-transparent semi-reflective film of the light splitting plate, is converged with the first path of light, is emitted to the CCD image sensor according to the return path of the first path of light, and is vertically scanned to the computer by the CCD image sensor. In addition, the computer sends the instruction every certain time and makes drive arrangement clockwise rotation or anticlockwise rotate and gradually change the workstation position from top to bottom equidistantly, and drive arrangement's drive stroke is certain, and consequently the small displacement that the workstation removed also is definite, thereby the utility model discloses utilize drive arrangement can change the phase place equidistantly, acquire multiple white light interference pattern. In the vertical scanning process of the CCD image sensor, a series of white light interferograms are sequentially obtained, the zero optical path difference position of each pixel point is calculated and positioned through a three-dimensional shape recovery algorithm, and information of corresponding height can be obtained, so that the surface three-dimensional shape of the object to be detected is recovered. The utility model discloses utilize the semi-transparent semi-reflection membrane of optical compensation board and beam splitter upper surface ingeniously, the light that forms to come from the reverberation of the object surface that awaits measuring and optical compensation board reflection back is close aplanatism, reaches zero optical path difference, realizes that white light interferes. The utility model can manually adjust the positions of the microscope eyepiece and the microscope objective in advance to realize that the light reflected from the surface of the object to be measured is close to the aplanatism with the light reflected on the optical compensation plate, thereby achieving zero optical path difference, realizing white light interference and being very convenient for microscope adjustment; the structure is simple, the starting is flexible, and the repeatability is good; simple operation, low manufacturing cost and considerable economic value.
Specifically, the white light interference three-dimensional shape reappearing device further comprises a limiting block, the driving device is a stepping motor, and the limiting block and a base of the driving device are fixed at installation positions; the screw thread connection has the lead screw on the workstation, the central axis parallel arrangement of lead screw and micro objective, and on the lead screw coaxial fixation was in drive arrangement's output pivot, one side of workstation was equipped with and pastes the spacing plane that leans on the stopper. One side of the workbench is closely matched with a limiting plane on the limiting block, and in the lifting process of the lead screw driving workbench, the limiting block limits the rotation of the workbench, so that the workbench can only do lifting motion and does not do rotating motion all the time stably, thereby being convenient for scanning of the CCD image sensor and realizing real imaging.
Furthermore, a fixed metal block is fixed below the workbench, a first threaded hole is formed in the lower portion of the fixed metal block, and the lead screw is connected in the first threaded hole in a threaded mode.
Optionally, the lead screw is connected with the output rotating shaft through the coupler, and the fixing effect is good after connection.
Optionally, the lead screw is equipped with the second screw hole towards drive arrangement's tip, the central axis coincidence of second screw hole and lead screw, second screw hole and output pivot threaded connection, one side of lead screw is equipped with the screw hole of intercommunication second screw hole, and threaded connection has the fixed screw that is used for pressing in output pivot one side in the screw hole, easy to assemble and dismantlement, and fixed effectual rotates the back for a long time, can not produce the error in height.
The device for reproducing the three-dimensional morphology by white light interference further comprises a microscope body, wherein a microscope eyepiece and a microscope objective are arranged in a lens barrel of the microscope body, and an optical compensation plate and a beam splitter are arranged at the lower part of the lens barrel of the microscope body; the microscope lens is simple in structure, is convenient to directly install another lens barrel under the lens barrel of a common microscope body, is convenient to refit and operate, is low in manufacturing cost and has considerable economic value by installing the optical compensation plate and the light splitting plate.
A successful example is based on a microscope ocular and a microscope objective of a common microscope, a loading CCD image sensor is connected with a computer, an optical compensation plate and a beam splitter plate are arranged at the lower part of the microscope objective of the microscope through a lens cone, a white light interference pattern can be obtained only by properly adjusting the distance between the microscope ocular and the microscope objective of the microscope, and a plurality of white light interference patterns can be obtained by slightly moving a workbench up and down through the rotation of a stepping motor.
A (x, y) represents the background light intensity on the pixel point centroid position matrix corresponding to the surface to be measured of the object to be measured, b (x, y) represents the modulation degree of the deformed stripes,the variable function determined by the height h (x, y) of the surface of the object to be measured is represented, and the light intensity distribution of the white light interference pattern collected by the CCD image sensor is
The phase of the interference pattern acquired by each step of the stepping motor is shifted by deltaiLet us orderNamely, it is
Wherein,
to sum up, the utility model discloses utilize the semi-transparent semi-reflecting membrane of optical compensation board and beam splitter upper surface ingeniously, form the reverberation that comes from the object surface that awaits measuring and the light that the optical compensation board reflects back and be close aplanatism, reach zero optical path difference, realize white light and interfere. The stepping motor receives computer instructions, and rotates a certain angle in each step, so that the slight displacement of the movement of the workbench is also determined. The positions of the microscope eyepiece and the microscope objective are manually adjusted to realize that the light reflected from the surface of the object to be measured and the light reflected on the optical compensation plate are close to an aplanatism, so that zero optical path difference is achieved, and white light interference is realized. The phase can be changed at equal intervals by using a stepping motor to obtain multiple white light interference patterns through self-controlAnalysis software or other software (e.g. scanning probe image processing software SPIP)TMEtc.) to reproduce the three-dimensional topography of the object surface. The device has simple structure, flexible starting and good repeatability.
The utility model discloses a white light interferes three-dimensional appearance reappearance device's beneficial effect is: the utility model can manually adjust the positions of the microscope eyepiece and the microscope objective in advance to realize that the light reflected from the surface of the object to be measured is close to the aplanatism with the light reflected on the optical compensation plate, thereby achieving zero optical path difference, realizing white light interference and being very convenient for microscope adjustment; the structure is simple, the starting is flexible, and the repeatability is good; simple operation, low manufacturing cost and considerable economic value.
Drawings
The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.
Fig. 1 is an optical interference schematic diagram of a three-dimensional morphology reproduction device for white light interference according to the present invention;
FIG. 2 is a front view of an optical compensation plate of a three-dimensional topography reproduction device for white light interference according to the present invention;
FIG. 3 is a front view of the light-splitting plate of the three-dimensional shape representation device for white light interference according to the present invention;
FIG. 4 is a schematic full-section view of a worktable of a three-dimensional morphology reproduction device for white light interference according to the present invention;
fig. 5 is a schematic diagram of the connection between the screw of the three-dimensional morphology reappearing device and the output shaft of the driving device according to the present invention.
The CCD image sensor is arranged in the shell, wherein 1, the CCD image sensor is arranged in the shell; 2. a microscope eyepiece; 3. a microscope objective; 4. an optical compensation plate; 5. a light splitting plate; 6. a limiting block; 7. an object to be measured; 8. a workbench, 81, a fixed metal block, 82, a lead screw and 83, a fixed screw; 9. an output shaft; 10. a drive device; 11. a computer; 12. and (3) a semi-permeable and semi-reflective film.
Detailed Description
The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic drawings and illustrate the basic structure of the present invention only in a schematic manner, and thus show only the components related to the present invention.
The embodiment of the present invention shown in fig. 1-5 is a three-dimensional shape reproduction device with white light interference, the device comprises a computer 11, a driving device 10, a CCD image sensor 1, a microscope eyepiece 2, a microscope objective 3, an optical compensation plate 4, a light splitting plate 5 and a workbench 8 for placing an object 7 to be detected, wherein the CCD image sensor 1, the microscope eyepiece 2, the microscope objective 3, the optical compensation plate 4, the light splitting plate 5 and the workbench 8 are sequentially arranged along the light propagation direction, the driving device 10 is used for driving the workbench 8 to make linear motion with equal displacement in the light propagation direction, the upper surfaces, facing the microscope objective 3, of the optical compensation plate 4 and the light splitting plate 5 are both compounded with a semi-transparent semi-reflective film 12, the output end of the computer 11 is connected to the signal input end of the driving device 10, the signal output end of the CCD image sensor 1 is connected to the input end of the computer 11, and the.
In the embodiment, two glass plates with equal thickness and upper surfaces coated with the semi-transparent and semi-reflective films can be selected in advance, one glass plate coated with the semi-transparent and semi-reflective film 12 is an optical compensation plate 4, the other glass plate coated with the semi-transparent and semi-reflective film 12 is a beam splitter plate 5, and the microscope eyepiece 2, the microscope objective 3, the optical compensation plate 4 and the beam splitter plate 5 are coaxial; the lower part of the worktable 8 is connected with a driving device 10, and the driving device 10 is started to move the worktable 8 upwards or downwards step by step at equal intervals. In the embodiment, two glass plates coated with the semitransparent and semi-reflective film 12 are used for realizing white light interference, and no device for reproducing the three-dimensional appearance of the non-transparent object is reported.
As shown in fig. 1, the first path of light directly passes through the microscope eyepiece 2, the microscope objective 3, the optical compensation plate 4 and the beam splitter plate 5, and returns to the original path after being reflected by the upper surface of the object 7 to be measured, the second path of light is reflected to the optical compensation plate 4 through the beam splitter plate 5, and is reflected to the beam splitter plate 5 again by the semi-transparent and semi-reflective film 12 of the optical compensation plate 4, and then is reflected again by the semi-transparent and semi-reflective film 12 of the beam splitter plate 5, and is converged with the first path of light and emitted to the CCD image sensor 1 according to the return path of the first path of light, and is vertically scanned to the computer 11 by the CCD image sensor 1. In addition, the computer 11 sends out instructions at regular intervals to make the driving device 10 rotate clockwise or rotate counterclockwise to change the up-and-down position of the worktable 8 at equal intervals step by step, the driving stroke of the driving device is fixed, so that the micro displacement of the worktable 8 is also determined, and thus the driving device 10 can be used for changing the phase at equal intervals to acquire a plurality of white light interference patterns in the embodiment. In the vertical scanning process of the CCD image sensor 1, a series of white light interferograms are sequentially acquired, the zero optical path difference position of each pixel point is calculated and positioned through a three-dimensional shape recovery algorithm, and information of corresponding height can be obtained, so that the surface three-dimensional shape of the object 7 to be detected is recovered. In this embodiment, the semi-transparent and semi-reflective film 12 on the upper surfaces of the optical compensation plate 4 and the light splitting plate 5 is skillfully used to form an optical path length of the reflected light from the surface of the object to be measured 7 close to the equal optical path length of the light reflected by the optical compensation plate 4, so as to achieve zero optical path length difference and realize white light interference, and the interference schematic diagram is shown in fig. 1. In the embodiment, the positions of the microscope eyepiece 2 and the microscope objective 3 can be manually adjusted in advance, so that the light reflected from the surface of the object 7 to be measured and the light reflected on the optical compensation plate 4 are close to the aplanatism, the zero optical path difference is achieved, the white light interference is realized, and the microscope is very convenient to adjust; the structure is simple, the starting is flexible, and the repeatability is good; simple operation, low manufacturing cost and considerable economic value.
Specifically, the white light interference three-dimensional shape reappearing device further comprises a limiting block 6, the driving device 10 is a stepping motor, and the limiting block 6 and a base of the driving device 10 are fixed at installation positions; the screw rod 82 is connected to the workbench 8 in a threaded mode, the screw rod 82 is parallel to the central axis of the microscope objective 3, the screw rod 82 is coaxially fixed to the output rotating shaft 9 of the driving device 10, and a limiting plane attached to the limiting block 6 is arranged on one side of the workbench 8. One side of workstation 8 and the spacing plane on the stopper 6 closely cooperate, and lead screw 82 drive workstation 8 lift in-process, stopper 6 has restricted workstation 8's rotation, makes workstation 8 can only do elevating movement steadily all the time, and do not do rotary motion, and the CCD image sensor 1 of consequently being convenient for scans, and the formation of image is true.
Furthermore, a fixed metal block 81 is fixed below the workbench 8, a first threaded hole is formed in the lower portion of the fixed metal block 81, and the lead screw 82 is in threaded connection with the first threaded hole, so that the structure is simple, and the installation is convenient.
Optionally, the lead screw 82 is connected with the output rotating shaft 9 through a coupler, and the fixing effect is good after connection.
Optionally, the end of the screw rod 82 facing the driving device 10 is provided with a second threaded hole, the second threaded hole coincides with the central axis of the screw rod 82, the second threaded hole is in threaded connection with the output rotating shaft 9, one side of the screw rod 82 is provided with a screw hole communicated with the second threaded hole, the screw hole is internally in threaded connection with a fixing screw 83 used for being pressed against one side of the output rotating shaft 9, the mounting and the dismounting are convenient, the fixing effect is good, and after the screw rod is rotated for a long time, errors in height cannot be generated.
Specifically, the white light interference three-dimensional morphology reappearing device further comprises a microscope body, the microscope eyepiece 2 and the microscope objective 3 are installed in a lens cone of the microscope body, and the optical compensation plate 4 and the beam splitter plate 5 are installed at the lower part of the lens cone of the microscope body; the microscope lens is simple in structure, is convenient to directly install another lens barrel under the lens barrel of a common microscope body, is convenient to install the optical compensation plate 4 and the light splitting plate 5, is simple to operate, is low in manufacturing cost, and has considerable economic value.
In a successful example, based on a microscope eyepiece 2 and a microscope objective 3 of a common microscope, a loading CCD image sensor 1 is connected with a computer 11, an optical compensation plate 4 and a beam splitter plate 5 are arranged at the lower part of the microscope objective 3 of the microscope through a lens cone, a white light interference pattern can be obtained only by properly adjusting the distance between the microscope eyepiece 2 and the microscope objective 3 of the microscope, and a workbench 8 is slightly moved up and down through the rotation of a stepping motor to obtain a plurality of white light interference patterns.
A (x, y) represents the background light intensity on the pixel point centroid position matrix corresponding to the surface to be measured of the object to be measured 7, b (x, y) represents the modulation degree of the deformed stripes,a variable function determined by the height h (x, y) of the surface of the object 7 to be measured, the light intensity distribution of the white light interference pattern collected by the CCD image sensor 1 is
The phase of the interference pattern acquired by each step of the stepping motor is shifted by deltaiLet us orderNamely, it is
Wherein,
to sum up, in this embodiment, the optical compensation plate 4 and the transflective film 12 on the upper surface of the light splitting plate 5 are skillfully used to form an optical path length of the reflected light from the surface of the object 7 to be measured, which is close to the aplanatism with the light reflected by the optical compensation plate 4, so as to reach zero optical path length difference, and realize white light interference, and the interference schematic diagram is shown in fig. 1, the step motor receives the instruction of the computer 11, and rotates by a certain angle at each step, so that the small displacement of the movement of the worktable 8 is also determined. The positions of the microscope eyepiece 2 and the microscope objective 3 are manually adjusted to realize that the light reflected from the surface of the object 7 to be measured is close to the aplanatism with the light reflected on the optical compensation plate 4, so that zero optical path difference is achieved, and white light interference is realized. The phase can be changed at equal intervals by utilizing a stepping motor, a plurality of white light interference patterns are obtained, and the three-dimensional appearance of the surface of an object is reproduced through self-made analysis software or other software (such as scanning probe image processing software SPIPTM and the like). The device has simple structure, flexible starting and good repeatability.
It should be understood that the above description of the specific embodiments is only for the purpose of explanation and not for the purpose of limitation. Obvious changes or variations caused by the spirit of the present invention are within the scope of the present invention.
Claims (5)
1. A white light interference three-dimensional shape reappearing device is characterized in that: comprises a computer (11), a driving device (10), a CCD image sensor (1), a microscope eyepiece (2), a microscope objective (3), an optical compensation plate (4), a light splitting plate (5) and a workbench (8) for placing an object to be measured (7) which are arranged in sequence along the light propagation direction, the driving device (10) is used for driving the workbench (8) to do linear motion with equidistant displacement in the light propagation direction, the upper surfaces of the optical compensation plate (4) and the light splitting plate (5) facing the microscope objective (3) are both compounded with a semi-transparent and semi-reflective film (12), the output end of the computer (11) is connected to the signal input end of the driving device (10), the signal output end of the CCD image sensor (1) is connected to the input end of a computer (11), the computer (11) is used for reproducing the three-dimensional appearance of the surface, facing the light splitting plate (5), of the object to be detected (7) through three-dimensional appearance analysis software;
the white light interference three-dimensional morphology reappearing device further comprises a microscope body, the microscope eyepiece (2) and the microscope objective (3) are installed in a lens cone of the microscope body, and the optical compensation plate (4) and the light splitting plate (5) are installed on the lower portion of the lens cone of the microscope body.
2. The white light interference three-dimensional shape reproduction device according to claim 1, wherein: the white light interference three-dimensional shape reappearing device further comprises a limiting block (6), the driving device (10) is a stepping motor, and the limiting block (6) and a machine base of the driving device (10) are fixed at installation positions; threaded connection has lead screw (82) on workstation (8), the central axis parallel arrangement of lead screw (82) and micro objective (3), on lead screw (82) coaxial fixation was in output pivot (9) of drive arrangement (10), one side of workstation (8) is equipped with and leans on the spacing plane on stopper (6).
3. The white light interference three-dimensional shape reproduction device according to claim 2, wherein: a fixed metal block (81) is fixed below the workbench (8), a first threaded hole is formed in the lower portion of the fixed metal block (81), and the lead screw (82) is connected into the first threaded hole in a threaded mode.
4. A white light interference three-dimensional topography reproduction apparatus according to claim 2 or 3, characterized in that: the lead screw (82) is connected with the output rotating shaft (9) through a coupler.
5. A white light interference three-dimensional topography reproduction apparatus according to claim 2 or 3, characterized in that: the end part of the screw rod (82) facing the driving device (10) is provided with a second threaded hole, the second threaded hole coincides with the central axis of the screw rod (82), the second threaded hole is in threaded connection with the output rotating shaft (9), one side of the screw rod (82) is provided with a screw hole communicated with the second threaded hole, and the screw hole is internally in threaded connection with a fixing screw (83) pressed against one side of the output rotating shaft (9).
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