JP2004361581A - Method and device of automatic focus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To quickly and precisely focus on an object to be observed. <P>SOLUTION: The distance from a glass substrate 5 is metered with a range finder sensor 7 adjoining an objective lens 4. The objective lens 4 is lowered based on the found distance down to a position which is higher than the surface of the glass substrate 5 within a focal depth of the objective lens 4. Under this condition, automatic focusing is performed with the objective lens 4 so that the focal point of the objective lens 4 is set on the surface of the glass substrate 5. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an autofocus method and an apparatus for adjusting the focus position of an objective lens on a glass substrate surface when observing a glass substrate used for an observation target, for example, a flat panel display (FPD) using a microscope.
[0002]
[Prior art]
In a large-sized observation microscope, a well-known contrast type autofocus is used to adjust a focus position of an objective lens on a glass substrate surface. This autofocus sequentially captures images of the glass substrate while lowering the objective lens from a preset home position toward the glass substrate in a predetermined step, performs image processing on these image data, and detects a peak value of contrast. The Z coordinate position of this peak value is determined as the focus position of the objective lens.
[0003]
Patent Document 1 describes, for example, a technique for performing focusing at the time of inspection of a glass substrate. In this Patent Document 1, a substrate transport unit having a height sensor for detecting a displacement amount of a reference plane on a subject is provided separately from a substrate inspection unit for performing an appearance inspection of the subject, and the subject is inspected by the inspection unit. Detects the amount of displacement of the reference surface on the object before transporting it, and focuses on the object based on the amount of displacement of the reference surface on the object detected by the height sensor when performing an appearance inspection of the object. Perform alignment.
[0004]
[Patent Document 1]
JP 2000-266991 A [0005]
[Problems to be solved by the invention]
However, in order to detect the image data having the highest contrast from a plurality of image data in the contrast type autofocus, it is necessary to capture each image every step movement while moving the objective lens down by the step movement. For this reason, when the distance from the home position of the objective lens to the focus position becomes long, it takes time to process the image data, and it takes time to detect the focus position. In order to shorten the scanning time, when the glass substrate is moved to change the observation position on the glass substrate, the position of the objective lens is fixed at the current position.
[0006]
However, when the focus position is fixed, if the surface accuracy of the stage on which the glass substrate is mounted is low, or if the flatness of the surface of the glass substrate cannot be obtained and distortion occurs, the focus position of the objective lens is changed to the glass position. It may be shifted from the substrate surface. In this case, the focus position of the objective lens of the glass substrate may be shifted below the glass substrate surface. If the autofocus is executed from the downwardly shifted state, the objective lens further descends and scans while descending to the lower limit position without detecting the focus position. When the objective lens reaches the lower limit position, the objective lens starts to scan while moving up, returning to the home position and lowering again, and it takes more time to detect the focus position.
[0007]
On the other hand, in Patent Literature 1, since the substrate transport unit having the height sensor and the substrate inspection unit are separated from each other, the subject transported between the substrate transport unit in which the height sensor is disposed and the substrate inspection unit If the height positions are not the same, even if the displacement amount of the reference surface on the subject is detected with high accuracy in the substrate transport unit, the substrate inspection unit can accurately focus on the subject based on this displacement amount. It becomes difficult. In addition, since the substrate transport unit has a lower surface accuracy than the stage of the substrate inspection unit, it is difficult to accurately focus on the subject in the substrate inspection unit based on the displacement detected by the height sensor. Become.
[0008]
Therefore, an object of the present invention is to provide an autofocus method and an apparatus thereof that can focus on an observation target with high accuracy in a short time.
[0009]
[Means for Solving the Problems]
The present invention measures the distance of the observation target to be observed by the objective lens attached to the microscope main body, and relatively moves the objective lens and the observation target in the optical axis direction based on the measured distance. This is an autofocus method in which autofocus is performed on the objective lens to adjust the focus position of the objective lens to an observation target.
[0010]
According to the present invention, a distance measuring means for measuring a distance of an observation target observed by an objective lens attached to a microscope body, and a distance between the objective lens and the observation target relatively based on the distance measured by the distance measuring means. First focus control means for moving, and in a state in which the distance between the objective lens and the observation target is relatively moved by the first focus control means, auto-focusing on the objective lens is performed to shift the focus to the focus position of the objective lens. This is an autofocus device including a second focus control unit that adjusts an observation target.
[0011]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings.
[0012]
FIG. 1 is a configuration diagram of an autofocus device used for a large observation microscope. The microscope mounting stage 1 is provided with a microscope main body 2 movably in the vertical direction (Z direction).
[0013]
A revolver 3 is rotatably provided below the microscope main body 2. The revolver 3 is provided with a plurality of objective lenses 4 having different magnifications. Below these objective lenses 4, a glass substrate 5 used for a flat panel display (FPD) such as a liquid crystal display is positioned and mounted on a stage 33 at a reference position.
[0014]
At the lower part of the microscope main body 2, an optical distance measuring sensor 7 is selected through rotation of the revolver 3 via a sensor mounting bracket 6 and interferes with the objective lens 4 set on the optical axis P of the microscope main body 2. It is fixed in the position where it does not. It is preferable that the distance measuring sensor 7 is provided in parallel with the objective lens 4 in the vicinity.
[0015]
The measurement reference position of the distance measuring sensor 7 is provided at a preset height position A, for example, corresponding to a home position position which is a reference point of a focus start position of the objective lens 4. The distance measuring sensor 7 irradiates, for example, a laser beam in a direction perpendicular to the surface of the glass substrate 5, receives light reflected from the surface of the glass substrate 5, and adjusts the timing from emission of the laser light to reception of the laser light. The distance to the glass substrate 5 is measured based on the measured distance, and the measured distance signal is output. The distance measuring sensor 7 sequentially measures the distance to the glass substrate 5 every predetermined period, for example, and outputs the measured distance signal.
[0016]
The focus control unit 8 includes a coarse precision focus control unit 9 as a first focus control unit and a high precision focus control unit 10 as a second focus control unit.
[0017]
The coarse focus control unit 9 positions the surface of the glass substrate 5 within the depth of focus of the objective lens 4 based on the measured distance signal from the distance measurement sensor 7 and the focus position of each objective lens 4 and the parallax correction data. Moving the objective lens 4 from the home position, for example, to lower the focus position of the objective lens 4 within the depth of focus of the objective lens 4 and higher than the surface position of the glass substrate 5. A descending distance for positioning is calculated, and a descending signal for descending the microscope main body 2 is sent to the microscope mounting stage 1 according to the descending distance.
[0018]
If the objective lens 4 is moved down by this descending distance, the focus position of the objective lens 4 exists within the depth of focus of the objective lens 4 and higher than the surface position of the glass substrate 5. At this time, the shift amount of the focus position of the objective lens 4 with respect to the surface position of the glass substrate 5 is an offset amount that is adjusted by auto-focusing by the next high-precision focus control unit 10.
[0019]
The descending distance differs depending on the focal length according to the magnification of the objective lens 4 selected by the rotation of the revolver 3.
[0020]
The high-precision focus control unit 10 executes autofocus on the objective lens 4 in a state where the glass substrate 5 is located within the depth of focus of the objective lens 4 to shift the focus position of the objective lens 4 on the surface of the glass substrate 5. Is sent to the microscope mounting stage 1. In this auto focus, scanning is performed while lowering the objective lens 4 from a preset home position toward the glass substrate 5, and images of the glass substrate 5 are sequentially captured through the objective lens 4, and the image data is processed. Then, the height position of the objective lens 4 when the image data having the highest contrast is captured is determined as the focus position.
[0021]
Next, the operation of the apparatus configured as described above will be described with reference to the autofocus flowchart shown in FIG.
[0022]
The microscope main body 2 moves downward from the upper limit position or downward from above to remove backlash and position the objective lens 4 at the home position.
[0023]
In step # 1, the distance measuring sensor 7 irradiates the laser light in a direction perpendicular to the surface of the glass substrate 5, receives the reflected light from the surface of the glass substrate 5, and receives the light from the emission of the laser light. The distance to the glass substrate 5 is measured based on the timing up to and the measured distance signal is output.
[0024]
Next, in step # 2, the coarse precision focus control unit 9 moves the objective lens 4 from the home position based on the input measurement distance signal from the distance measurement sensor 7 and the focus position corresponding to the magnification of the objective lens 4. A descending distance is calculated by moving the objective lens 4 down to a position within the depth of focus of the objective lens 4 and higher than the surface position of the glass substrate 5.
[0025]
Next, in step # 3, the coarse-accuracy focus control unit 9 sends a down signal for lowering the microscope main body 2 according to the calculated down distance to the microscope mounting stage 1. Thereby, the microscope main body 2 is lowered with respect to the microscope mounting stage 1, and the objective lens 4 is lowered from the home position. Then, when the coarse precision focus control unit 9 descends the microscope main body 2 by the descending distance, the lowering of the microscope main body 2 is stopped.
[0026]
As a result, the objective lens 4 is controlled to be within the depth of focus of the objective lens 4 and the focus position of the objective lens 4 to be higher than the surface position of the glass substrate 5.
[0027]
As described above, the coarse focus control unit 9 receives the measurement distance signal from the distance measurement sensor 7 and moves the focus position of the objective lens 4 to a position higher than the surface of the glass substrate 5 within the depth of focus of the objective lens 4. Will be located.
[0028]
Next, in step # 4, the high-precision focus control unit 10 performs autofocus on the objective lens 4 in a state where the focus is always higher than the surface of the glass substrate 5 within the focal depth of the objective lens 4. Then, a movement control signal for adjusting the focus position of the objective lens 4 on the surface of the glass substrate 5 is sent to the microscope mounting stage 1. As a result, the microscope main body 2 moves up and down by the offset of the focus position shifted within the focal depth of the objective lens 4, and the focus position of the objective lens 4 is adjusted on the glass substrate 5.
[0029]
As described above, in the first embodiment, the distance from the glass substrate 5 is measured by the distance measuring sensor 7 adjacent to the objective lens 4, and the objective lens 4 is lowered based on the measured distance. To a position higher than the surface of the glass substrate 5 within the depth of focus of the objective lens 4, and in this state, autofocus is performed on the objective lens 4 to adjust the focus position of the objective lens 4 on the surface of the glass substrate 5. .
[0030]
Thus, the objective lens 4 can be lowered at once without moving the objective lens from the home position as in the related art, and the focus position of the objective lens 4 can be adjusted within the focal depth of the objective lens 4 in a short time.
[0031]
Thereafter, the scanning distance of the autofocus with respect to the objective lens 4 can be shortened because the scanning distance of the autofocus with respect to the objective lens 4 can be shortened because the scanning distance of the offset may be higher than the focus position within the depth of focus of the objective lens 4. it can.
[0032]
As a result, the time for finally adjusting the focus position of the objective lens 4 to the surface of the glass substrate 5 can be greatly reduced.
[0033]
Also, since the autofocus for the objective lens 4 is performed after being positioned at a position higher than the surface of the glass substrate 5 within the depth of focus of the objective lens 4, if the objective lens 4 is lowered by the autofocus, the objective lens 4 The focus position of 4 can be adjusted on the surface of the glass substrate 5, and a stable autofocus operation can be performed without returning the objective lens 4 to the home position and performing autofocus again as in the related art.
[0034]
Further, since the distance measuring sensor 7 is provided adjacent to the objective lens 4, the distance measurement between the distance measuring sensor 7 and the glass substrate 5 and the focusing of the objective lens 4 on the glass substrate 5 are performed on the same substrate stage. This can be performed above and in the vicinity of the field of view of the objective lens 4, and the focusing on the surface of the glass substrate 5 can be performed with high accuracy.
[0035]
Note that the objective lens 4 has a smaller depth of focus at a higher magnification and a larger depth of focus at a lower magnification. However, when the objective lens 4 with a lower magnification is selected, the distance measurement sensor 7 causes a distance between the objective lens 4 and the glass substrate 5. Only by lowering the objective lens 4 based on the distance, the focus position of the objective lens 4 can be adjusted on the surface of the glass substrate 5.
[0036]
Next, a second embodiment of the present invention will be described with reference to the drawings.
[0037]
FIG. 3 is a configuration diagram of an autofocus device used for a large observation microscope. The same parts as those in FIG. 1 are denoted by the same reference numerals, and detailed description thereof will be omitted. At the lower part of the microscope main body 2, a distance measuring sensor irradiating section (light irradiating section) 21 constituting a distance measuring sensor is provided in proximity to the objective lens 4 via a support 20. The distance measuring sensor irradiating unit 21 irradiates a laser beam at a predetermined angle θa with respect to the optical axis Q of the microscope main body 2 (the optical axis of the objective lens 4) and in a direction passing through the focus position of the objective lens 4.
[0038]
A distance measuring sensor light receiving section (light receiving section) 23 constituting a distance measuring sensor is provided in the lower part of the microscope main body 2 via a support 22 in proximity to the objective lens 4. The distance measuring sensor light receiving section 23 is provided at a position facing the distance measuring sensor irradiating section 21 via the optical axis Q of the microscope main body 2, and irradiates a laser beam onto the surface of the glass substrate 5 by the distance measuring sensor irradiating section 21. The reflected light from the surface of the glass substrate 5 at this time is received, and a light receiving position signal indicating the light receiving position is output.
[0039]
The distance measuring sensor irradiating section 21 and the distance measuring sensor light receiving section 23 may be provided at positions where they do not interfere with the objective lens 4, and when the plurality of objective lenses 4 are mounted on the revolver 3 as shown in FIG. May be provided at a position that does not interfere with each objective lens 4 that is moved by the rotation of the revolver 3.
[0040]
As the distance measuring sensor light receiving section 23, for example, as shown in FIG. 4, a line sensor in which a plurality of light receiving elements 23a are arranged in a line is used. When the position of the glass substrate 5 falls below the focus position of the objective lens 4 as shown in the figure, the irradiation position of the laser light emitted from the distance measurement sensor irradiation unit 21 on the surface of the glass substrate 5 changes. The light receiving position of the reflected light from the surface of the glass substrate 5 in the line sensor 23 is displaced in the arrangement direction of each light receiving element 23a of the line sensor 23.
[0041]
Therefore, if the light receiving position (position of the light receiving element) Pa on the line sensor 23 when the surface of the glass substrate 5 is located at the focus position of the objective lens 4 is set in advance, the light receiving position Pa and the focus adjustment are performed. From the shift d from the light receiving position on the line sensor 23 at the time of, the focus shift amount between the focus position of the objective lens 4 and the glass substrate 5 can be obtained.
[0042]
The coarse-accuracy focus control unit 24 receives a light-receiving position signal output from the line sensor 23, and calculates a focus shift amount between the focus position of the objective lens 4 and the glass substrate 5 based on the light-receiving position on the line sensor 23. A descent distance for positioning the focus position within the depth of focus of the objective lens 4 and higher than the surface position of the glass substrate 5 is calculated from the defocus amount, and the descent for lowering the microscope main body 2 according to the descent distance. A signal is sent to the microscope mounting stage 1.
[0043]
Next, the operation of the device configured as described above will be described.
[0044]
As the microscope body 2 moves down, the objective lens 4 moves down from the home position. In this state, the distance measurement sensor irradiating unit 21 irradiates the laser beam at a predetermined angle θa with respect to the optical axis Q of the objective lens 4 and in a direction passing through the focus position of the objective lens 4.
[0045]
The line sensor serving as the distance measuring sensor light receiving unit 23 receives reflected light from the surface of the glass substrate 5 when the laser light is irradiated onto the glass substrate 5 by the distance measuring sensor irradiating unit 21 and indicates the light receiving position. Outputs the light receiving position signal. At this time, the light receiving position of the reflected light from the surface of the glass substrate 5 on the line sensor 23 is displaced in the arrangement direction of each light receiving element 23a as the objective lens 4 is lowered.
[0046]
The coarse-accuracy focus control unit 24 receives a light-receiving position signal output from the line sensor 23, and calculates a focus shift amount between the focus position of the objective lens 4 and the glass substrate 5 based on the light-receiving position on the line sensor 23. From this amount of focus shift, a descent distance for setting the focus position of the objective lens 4 within the depth of focus of the objective lens 4 and higher than the surface position of the glass substrate 5 is calculated, and the microscope main body 2 is lowered according to the descent distance. A descending signal to be transmitted is sent to the microscope mounting stage 1.
[0047]
Next, the coarse-accuracy focus control unit 9 sends a down signal for lowering the microscope main body 2 to the microscope mounting stage 1 according to the calculated descent distance. Thereby, the microscope main body 2 is lowered with respect to the microscope mounting stage 1, and the objective lens 4 is lowered from the home position. Then, when the coarse precision focus control unit 9 descends the microscope main body 2 by the descending distance, the lowering of the microscope main body 2 is stopped.
[0048]
As a result, the objective lens 4 is controlled to be within the depth of focus of the objective lens 4 and the focus position of the objective lens 4 to be higher than the surface position of the glass substrate 5.
[0049]
Next, similarly to the above, the high-precision focus control unit 10 executes the autofocus on the objective lens 4 and sends a movement control signal for adjusting the focus position of the objective lens 4 on the surface of the glass substrate 5 to the microscope mounting stage 1. Therefore, the focus position of the objective lens 4 is adjusted on the glass substrate 5.
[0050]
As described above, in the second embodiment, the distance measurement sensor including the distance measurement sensor irradiation unit 21 and the line sensor 23 is provided in the lower part of the microscope main body 2, and the objective lens is set based on the light receiving position on the line sensor 23. Since the focus position 4 is located within the depth of focus of the objective lens 4 and higher than the surface position of the glass substrate 5, it is needless to say that the same effects as those of the first embodiment can be obtained. On the optical axis Q, the focus position of the objective lens 4 can be positioned within the depth of focus of the objective lens 4 and higher than the surface position of the glass substrate 5. As a result, the focus position of the objective lens 4 can be accurately set on the surface of the glass substrate 5.
[0051]
Next, a third embodiment of the present invention will be described with reference to the drawings.
[0052]
FIG. 5 is a configuration diagram of an autofocus device used for a large observation microscope. The same parts as those in FIG. 1 are denoted by the same reference numerals, and detailed description thereof will be omitted. A distance measuring sensor 30 is built in the microscope main body 2. The distance measuring sensor 30 irradiates the distance measuring laser beam L to the glass substrate 5 through the objective lens 4, receives the reflected light from the glass substrate 5 through the objective lens 4, and sets the glass based on the light receiving timing of the reflected light. The distance from the substrate 5 is determined.
[0053]
A mirror 31 is provided on the optical path of the distance measuring laser beam L output from the distance measuring sensor 30 and on the optical axis Q of the microscope main body 2. The mirror 31 reflects the distance measuring laser light L output from the distance measuring sensor 30 to the objective lens 4 side, and reflects the reflected light from the glass substrate 5 to the distance measuring sensor 30 side. This mirror 31 is arranged on the optical axis Q of the microscope main body 2 when the focus position of the objective lens 4 is adjusted on the surface of the glass substrate 5, and when the glass main body 5 is observed by the microscope main body 2, Retreat from the optical axis Q.
[0054]
Next, the operation of the device configured as described above will be described.
[0055]
In a state where the objective lens 4 is lowered from the home position,
The distance measuring sensor 30 outputs the distance measuring laser light L every predetermined period. The distance measuring laser light L is reflected by a mirror 31 arranged on the optical axis Q of the microscope main body 2, and is irradiated on the surface of the glass substrate 5 through the objective lens 4.
[0056]
The reflected light from the surface of the glass substrate 5 passes through the objective lens 4 again, is reflected by the mirror 31, and returns to the distance measuring sensor 30.
[0057]
The distance measurement sensor 30 measures the distance between the glass substrate 5 based on the timing from when the distance measurement laser light L is emitted to when the reflected light from the glass substrate 5 is received, and outputs a measured distance signal. .
[0058]
Next, the coarse focus control unit 9 lowers the objective lens 4 from the home position based on the measurement distance signal from the distance measurement sensor 30 sequentially input and the focus position corresponding to the magnification of the objective lens 4, A descending distance is calculated to set the focus position of the objective lens 4 higher than the surface position of the glass substrate 5 within the focal depth of the lens 4.
[0059]
Next, the coarse-accuracy focus control unit 9 sends a down signal for lowering the microscope main body 2 to the microscope mounting stage 1 according to the calculated descent distance. Thereby, the microscope main body 2 is lowered with respect to the microscope mounting stage 1, and the objective lens 4 is lowered from the home position. Then, when the coarse precision focus control unit 9 descends the microscope main body 2 by the descending distance, the lowering of the microscope main body 2 is stopped.
[0060]
As a result, the objective lens 4 is controlled to be within the depth of focus of the objective lens 4 and the focus position of the objective lens 4 to be higher than the surface position of the glass substrate 5.
[0061]
Next, similarly to the above, the high-precision focus control unit 10 executes the autofocus on the objective lens 4 and sends a movement control signal for adjusting the focus position of the objective lens 4 on the surface of the glass substrate 5 to the microscope mounting stage 1. Therefore, the focus position of the objective lens 4 is adjusted on the glass substrate 5.
[0062]
As described above, in the third embodiment, it is needless to say that the same effect as in the first embodiment can be obtained, and the focus position of the objective lens 4 can be changed on the optical axis Q of the microscope main body 2 by the objective lens. Since it can be positioned within the depth of focus of 4 and higher than the surface position of the glass substrate 5, the focus position of the objective lens 4 can be accurately set on the surface of the glass substrate 5.
[0063]
Note that the present invention is not limited to the above-described embodiments as they are, and can be embodied by modifying the components without departing from the scope of the invention at the stage of implementation. Various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the above embodiments. For example, some components may be deleted from all the components shown in the embodiment. Further, components of different embodiments may be appropriately combined.
[0064]
For example, in the first to third embodiments, the focus position of the objective lens 4 is located at a position higher than the surface of the glass substrate 5 within the depth of focus of the objective lens 4, and autofocus is performed in this state. Although focusing is performed with high accuracy, the focus position is not limited to this, and the focus position of the objective lens 4 is located at a position lower than the surface of the glass substrate 5 within the depth of focus of the objective lens 4, and in this state, the objective is set by autofocusing. The lens 4 may be raised.
[0065]
【The invention's effect】
As described in detail above, according to the present invention, it is possible to provide an autofocus method and an apparatus thereof that can focus on an observation target in a short time and with high accuracy.
[Brief description of the drawings]
FIG. 1 is a configuration diagram showing a large microscope for observation using an autofocus device according to a first embodiment of the present invention.
FIG. 2 is an autofocus flowchart in the same device.
FIG. 3 is a configuration diagram showing a second embodiment of the autofocus device according to the present invention.
FIG. 4 is a view showing a measuring operation of a distance measuring sensor in the device.
FIG. 5 is a configuration diagram showing a third embodiment of the autofocus device according to the present invention.
[Explanation of symbols]
1: microscope mounting stage, 2: microscope body, 3: revolver, 4: objective lens, 5: glass substrate, 6: sensor mounting bracket, 7: distance measuring sensor, 8: focus control unit, 9: coarse precision focus control unit , 10: high-precision focus control unit, 20, 22: support, 21: distance measurement sensor irradiation unit (light irradiation unit), 23: distance measurement sensor light reception unit (light reception unit), 24: coarse precision focus control unit, 30 : Distance measuring sensor.

Claims (14)

Measure the distance of the object to be observed with the objective lens attached to the microscope body,
The objective lens and the observation target are relatively moved in the optical axis direction based on the measured distance, and in this state, the autofocus is performed on the objective lens to set the focus position of the objective lens on the observation target. An autofocus method characterized by the following: The autofocus method according to claim 1, wherein the objective lens and the observation target are relatively moved in an optical axis direction, and the observation target is moved near the position of the objective lens. The autofocus method according to claim 2, wherein the vicinity of the focus position of the objective lens is within a depth of focus range of the objective lens. Distance measuring means for measuring the distance of the observation target to be observed by the objective lens attached to the microscope body,
First focus control means for relatively moving the distance between the objective lens and the observation target based on the distance measured by the distance measurement means,
In a state where the distance between the objective lens and the observation target is relatively moved by the first focus control unit, autofocus is performed on the objective lens to adjust the observation target to the focus position of the objective lens. Second focus control means;
An autofocus device comprising: The autofocus apparatus according to claim 4, wherein the first focus control unit positions the observation target near a focus position of the objective lens. The autofocus apparatus according to claim 4, wherein the first focus control means positions the observation target within a depth of focus of the objective lens. The first focus control unit calculates a shift amount of the observation target from the focus position of the objective lens based on the distance measured by the distance measurement unit and a focus position of the objective lens. 4. The method according to claim 3, wherein the objective lens and the observation target are relatively moved in the optical axis direction based on the amount of the deviation, and a focus position of the objective lens is located within a depth of focus of the objective lens. An autofocus device according to claim 1. A plurality of the objective lenses are attached to a revolver provided rotatably with respect to the microscope main body,
5. The autofocus according to claim 4, wherein the distance measuring means is provided to the microscope main body via a mounting member, and is provided in parallel with the objective lens selected by rotation of the revolver. apparatus. 5. The auto-focusing device according to claim 4, wherein said distance measuring means is a non-contact type distance measuring sensor. 5. The auto-focusing device according to claim 4, wherein said distance measuring means is an optical distance measuring sensor. 5. The auto-focusing device according to claim 4, wherein the distance measuring means is provided at a predetermined height position with respect to the objective lens. A light irradiating unit that irradiates light at a predetermined angle with respect to an optical axis of the objective lens and in a direction passing through the focus position of the objective lens; and a light irradiating unit that irradiates light. And a light receiving unit for receiving reflected light from the observation object at the time,
The autofocus apparatus according to claim 4, wherein a distance from the observation target is obtained based on a light receiving position of the reflected light from the observation target received by the light receiving unit. 13. The autofocus device according to claim 12, wherein the light receiving unit is a line sensor. The distance measuring means is built in the microscope main body, irradiates light to the observation target through the objective lens, and receives reflected light from the observation target through the objective lens, at a light receiving timing of the reflected light. The autofocus apparatus according to claim 4, wherein a distance from the observation target is obtained based on the distance.

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