JPWO2019244303A1 - Wavefront sensor, wavefront measuring device, and wavefront measuring method - Google Patents

Abstract

The microlens array (3), in which the array direction of the plurality of microlenses is inclined with respect to the scanning direction (11A), is moved in the direction traversing the light flux (2A) toward the image sensor (4) for scanning.

Description

The present invention relates to a wavefront sensor that detects a wavefront.

The Shack-Hartmann wavefront sensor is a sensor that collects and splits a light beam that has passed through an optical system to be measured or a light beam reflected by the optical system to be measured by a microlens array. Based on the above, the transmitted wavefront aberration of the test optical system or the reflected wavefront aberration of the test optical system is measured.

However, since the above-mentioned wavefront sensor cannot acquire information exceeding the number of pixels of the two-dimensional detection element, there is a trade-off relationship between the plane resolution of the wavefront and the tilt resolution.
For example, the finer the pitch of the microlens array and the higher the plane resolution of the wavefront, the smaller the number of pixels per one microlens, so the tilt resolution of the wavefront decreases.

For example, in Patent Document 1, high precision is achieved by shifting the irradiation position of the light beam to the two-dimensional detection element in subpixel units by a liquid crystal provided between the microlens array and the two-dimensional detection element. Optical sensors are described.

JP, 2010-230834, A

The sensor described in Patent Document 1 has a problem that the error component of the liquid crystal cannot be calibrated in real time and the plane resolution of the wavefront cannot be improved.

The present invention solves the above-mentioned problems, and an object thereof is to obtain a wavefront sensor that can improve the plane resolution of the wavefront.

The wavefront sensor according to the present invention includes a lens array, an image sensor, and a linear motion mechanism. The lens array is configured by arranging a plurality of lenses upon which the light flux transmitted or reflected by the test optical system is incident. The image pickup device images a plurality of converging spots on which the light fluxes passing through the plurality of lenses are condensed. The linear motion mechanism scans the lens array by moving the lens array in a direction that traverses the light flux toward the image sensor. In this structure, the arrangement direction of the plurality of lenses is inclined with respect to the moving direction of the lens array.

According to the present invention, the plane resolution of the wavefront is obtained by moving the lens array in which the arrangement direction of the plurality of lenses is inclined with respect to the moving direction of the lens array in the direction crossing the light flux toward the image sensor and scanning. Can be improved.

It is a block diagram which shows the structure of the wavefront measuring device which concerns on Embodiment 1 of this invention. 3 is a flowchart showing a wavefront measuring method according to the first embodiment. FIG. 3 is an explanatory diagram showing an outline of the wavefront measuring method according to the first embodiment. It is explanatory drawing which shows the case where a microlens receives the bite. It is explanatory drawing which shows the outline of the modification of the wavefront measuring device which concerns on Embodiment 1. FIG. 7 is an explanatory diagram showing the relationship between the angle formed by the scanning direction of the microlens array and the arrangement direction of the microlenses in the modified example of the wavefront measuring apparatus according to the first embodiment. It is a block diagram which shows the structure of the wavefront measuring device which concerns on Embodiment 2 of this invention. FIG. 7 is a diagram showing a scanning mechanism of a microlens array in the wavefront sensor according to the second embodiment.

Hereinafter, in order to describe the present invention in more detail, modes for carrying out the present invention will be described with reference to the accompanying drawings.
Embodiment 1.
1 is a block diagram showing the configuration of a wavefront measuring apparatus according to Embodiment 1 of the present invention. The wavefront measuring apparatus shown in FIG. 1 measures the wavefront of the test optical system 2 based on the focused spot image of the light beam 2A detected by the wavefront sensor according to the first embodiment. The light flux 2A is a light flux emitted from the light source 1 and transmitted or reflected by the optical system 2 to be tested. In FIG. 1, the wavefront sensor according to the first embodiment includes a microlens array 3, an image sensor 4, and a linear motion mechanism 11. The wavefront measuring apparatus according to the first embodiment includes a local wavefront inclination calculating unit 21, a wavefront calculating unit 22, a resolution control unit 23, and a device control unit 24, in addition to the wavefront sensor.

The microlens array 3 is a lens array that splits the light flux 2A transmitted or reflected by the optical system 2 to be examined and focuses it on the image sensor 4. The image pickup device 4 picks up an image of the focused spot of the light flux 2A and outputs the picked-up image data to the local wavefront tilt calculator 21. The linear motion mechanism 11 moves the microlens array 3 in a direction traversing the light flux 2A toward the image sensor 4. For example, when the direction perpendicular to the image pickup surface of the image pickup device 4 is the optical axis direction of the light flux 2A, the linear movement mechanism 11 uses the position table 32 input from the resolution control unit 23 to generate the microlens array 3 The microlens array 3 is moved and scanned in the direction in which the lens surface of is orthogonal to the optical axis of the light flux 2A. In the microlens array 3, the arrangement direction of the plurality of microlenses is inclined with respect to the moving direction (scanning direction).

The local wavefront tilt calculator 21 calculates the tilt of the local wavefront of the optical system 2 to be tested for each position in the moving direction of the microlens array 3, based on the imaged data of a plurality of focused spots imaged by the imaging device 4. It is a first calculation unit that does. The plurality of local wavefront tilt data 31 calculated by the local wavefront tilt calculation unit 21 are output to the wavefront calculation unit 22.

The wavefront calculator 22 is a second calculator that calculates the wavefront of the optical system 2 to be measured based on the local wavefront inclination data 31 obtained for each position in the moving direction of the microlens array 3. The resolution control unit 23 creates the position table 32 based on the wavefront data calculated by the wavefront calculation unit 22. The position table 32 is data in which a plurality of positions in the moving direction of the microlens array 3 are set, and is output to the device control unit 24. The device controller 24 controls the linear motion mechanism 11 to move the microlens array 3 for each position set in the position table 32. The device control unit 24 controls the image sensor 4 to capture an image of the focused spot of the light flux 2A.

Next, the operation will be described.
FIG. 2 is a flowchart showing the wavefront measuring method according to the first embodiment.
Before the series of processing shown in FIG. 2 is executed, the light from the light source 1 is incident on the test optical system 2 shown in FIG. 1, and the light flux 2A transmitted or reflected by the test optical system 2 is It is incident on the lens array 3. The linear motion mechanism 11 scans the microlens array 3 in which the arrangement direction of the plurality of microlenses is inclined with respect to the scanning direction in a direction traversing the light flux 2A toward the image sensor 4 (step ST1).

The local wavefront tilt calculator 21 calculates the tilt of the local wavefront of the optical system 2 to be tested for each position in the scanning direction of the microlens array 3, based on the imaged data of the plurality of focused spots imaged by the image pickup device 4. Yes (step ST2). A plurality of local wavefront tilt data 31 for each position of the microlens array 3 in the scanning direction is output to the wavefront calculator 22.

The wavefront calculator 22 inputs a plurality of local wavefront tilt data 31 for each position in the scanning direction of the microlens array 3 from the local wavefront tilt calculator 21 and calculates a wavefront using these local wavefront tilt data 31. (Step ST3).

FIG. 3 is an explanatory diagram showing an outline of the wavefront measuring method according to the first embodiment. In the left view of FIG. 3, the light flux 2A propagates from the front side to the back side of the paper surface. As shown in the left side view of FIG. 3, the microlens array 3 is configured by arranging a plurality of microlenses in a two-dimensional square lattice pattern. The microlens array 3 is moved in the scanning direction 11A indicated by the arrow in FIG. 3 by the linear movement mechanism 11 shown in FIG. The scanning direction 11A is a direction that traverses the light flux 2A propagating from the front side to the back side of the paper surface.

The array direction of the plurality of microlenses in the microlens array 3 is inclined at an angle θ with respect to the scanning direction 11A. In this way, the microlens array 3 is moved in the scanning direction 11A by the linear motion mechanism 11 in a state of being inclined with respect to the scanning direction 11A.
For example, when the tilt angle θ is 45°, the linear movement mechanism 11 moves the microlens array 3 at a constant movement amount, and this movement amount is 1/the pitch size d of the microlenses in the microlens array 3. √2 times. In the example shown in FIG. 3, the inclination angle θ is tan -1 ^3, the microlens array 3 is moved to each predetermined amount of movement by the linear motion mechanism 11, the amount of movement, the micro in the microlens array 3 It is 1/√5 times the pitch size d of the lens.

The condensing spot array 41A shown on the right side of FIG. 3 is an array of condensing spots imaged by the imaging device 4 when the microlens array 3 moves to the first position. The condensing spot array 41B is an array of condensing spots imaged by the imaging element 4 when the microlens array 3 moves from the first position to the second position separated by the movement amount. The condensing spot array 41C is an array of condensing spots imaged by the imaging element 4 when the microlens array 3 moves from the first position to the third position separated by the movement amount. The condensing spot array 41D is an array of condensing spots imaged by the imaging device 4 when the microlens array 3 moves from the first position to the fourth position separated by the above-described movement amount. The condensing spot array 41E is an array of condensing spots imaged by the imaging element 4 when the microlens array 3 moves from the first position to the fifth position separated by the movement amount.

The local wavefront tilt calculation unit 21 calculates the local wavefront tilt data 31 based on the imaging data of the focused spot array 41A, calculates the local wavefront tilt data 31 based on the imaging data of the focused spot array 41B, and focuses the light. The local wavefront tilt data 31 is calculated based on the imaging data of the spot array 41C, the local wavefront tilt data 31 is calculated based on the imaging data of the focused spot array 41D, and the local wavefront tilt data 31 is locally calculated based on the imaging data of the focused spot array 41E. The wavefront tilt data 31 is calculated. The wavefront calculator 22 calculates the wavefront of the optical system 2 to be measured based on the five sets of local wavefront tilt data 31 corresponding to the first to fifth positions. This is equivalent to obtaining a focused spot image with a density of 5 times to calculate the wavefront, and can improve the plane resolution of the wavefront.

An angle θ formed by the arrangement direction of the plurality of microlenses with respect to the scanning direction 11A is tan θ=N (a positive natural number, N=1, 2, 3,... ). As a result, the positions defined by 0, d/(N ² +1) ^1/2 ,..., N ² d/(N ² +1) ^1/2 are set in the position table 32. .. By scanning the microlens array 3 for each position set in the position table 32, the density of N ² +1 times the N ² +1 times of measurement with respect to the plane resolution of the wavefront sensor when the microlens array 3 is not scanned. And the inclination of the local wavefront can be measured at equal intervals, and the plane resolution of the wavefront is improved. In other words, it is possible to calculate even higher-order wavefront aberration components.

Further, by scanning the microlens array 3 until the light beam 2A comes off, the light intensity distribution of the light beam 2A can be directly measured using the image sensor 4. As a result, the wavefront of the test optical system 2 can be accurately aligned, which is useful for inspecting microscopic defects or transmittance of the test optical system 2.

Further, by scanning the microlens array 3 until the light beam 2A comes off and directly measuring the light intensity distribution of the light beam 2A using the image sensor 4, it is possible to confirm that the illuminance distribution in the plurality of microlenses is not uniform. FIG. 4 is an explanatory diagram showing a case where the microlens is subjected to a pitting corrosion. As shown in FIG. 4, when the pupil 2B of the optical system 2 to be measured is circular, if the microlens array 3 is completely removed from the optical axis, light is emitted only to the inside of the pupil 2B of the optical system 2 to be measured. It In the example shown in FIG. 4, among the 16 microlenses included in the microlens array 3, 12 microlenses inside the pupil 2B of the optical system 2 to be tested are uniformly illuminated.

As shown in the diagram on the right side of FIG. 4, in the image formation by the microlenses, a focused spot 42A of approximately a point is obtained by the twelve uniformly illuminated microlenses. On the other hand, the four microlenses whose lens area is out of the pupil 2B of the optical system 2 to be tested have a step difference in illuminance, and a focused spot 42B extending in a direction perpendicular to the step is formed. Since the local inclination of the wavefront is calculated by using the calculation of the center of gravity of the image by each microlens of the microlens array 3, the focused spot 42B in which the image linearly extends causes an error. Therefore, the focused spot 42B is excluded from the wavefront calculation. At the position where the microlens array 3 is moved, the microlenses that are uniformly illuminated are different. The light is uniformly illuminated inside the pupil 2B of the optical system 2 to be measured, and a condensing spot 42C of almost a point is obtained. Therefore, the light is not uniformly illuminated outside a part of the pupil 2B of the optical system 2 to be included in the wavefront calculation. Since it becomes the focused spot 42D, it is excluded from the wavefront calculation. In this way, by moving the microlens array 3 to the position where the microlenses are uniformly illuminated and measuring the wavefront, the accuracy of wavefront measurement is improved.

In the scanning of the microlens array 3, the N+2nd and subsequent measurement points may be added with the scanning amount d(N ² +1) ^1/2 . This makes it possible to measure the inclination of the same local wavefront using light beams that have passed through different microlenses, detect individual differences between microlenses in the microlens array, and calibrate this. For example, the cause of the change in the wavefront of the optical system 2 to be measured measured by the wavefront sensor may be the change in the wavefront of the optical system 2 to be measured with time, as well as the change in the wavefront sensor. Therefore, as described above, by detecting and calibrating the individual difference of the microlens, it is possible to separate the change with time of the wavefront sensor from the factor of the change in the wavefront.

The device control unit 24 controls the linear movement mechanism 11 to move the microlens array 3 at each position set in the position table 32, controls the image pickup device 4, and moves the microlens array 3 (scanning position). The focused spot of the light flux 2A is imaged for each position.
The device control unit 24 may control the linear movement mechanism 11 to continuously scan the microlens array 3 and control the image pickup device 4 to repeatedly pick up an image of a focused spot. At this time, a position sensor (not shown) detects the position of the microlens array 3 that is continuously scanned by the linear motion mechanism 11, and associates the detected position with the image data sequentially imaged by the image sensor 4. The local wavefront tilt calculation unit 21 uses this association data to calculate and interpolate the local wavefront tilt data 31 corresponding to the position that has not been set in the position table 32. The wavefront calculation unit 22 speeds up the wavefront measurement by measuring the wavefront based on the inclination of the local wavefront thus measured at high density.

Note that a second light source (not shown) different from the light source 1 may be used as the position sensor described above. For example, the light flux emitted from the second light source is imaged by the image sensor 4 separately from the light flux from the light source 1. By monitoring the operation of the linear motion mechanism 11 with the light flux emitted from the second light source, the image sensor 4 can detect the scanning amount of the microlens array 3 by the linear motion mechanism 11.

Next, a modification of the wavefront measuring apparatus according to the first embodiment will be described.
FIG. 5 is an explanatory diagram showing an outline of a modified example of the wavefront measuring apparatus according to the first embodiment. The wavefront sensor included in the modification of the wavefront measuring apparatus according to the first embodiment includes a microlens array 3A shown in the left side view of FIG. 5 instead of the microlens array 3 shown in FIG.
The wavefront sensor includes the microlens array 3A, the image pickup device 4, and the linear motion mechanism 11. Further, the wavefront measuring apparatus according to the first embodiment includes a local wavefront inclination calculating unit 21, a wavefront calculating unit 22, a resolution control unit 23, and a device control unit 24, in addition to the above wavefront sensor.
In the left side view of FIG. 5, the light flux 2A propagates from the front side to the back side of the paper surface.

Similar to the microlens array 3 shown in FIG. 3, the microlens array 3A is a lens array that splits the light flux 2A transmitted or reflected by the optical system 2 to be examined and focuses it on the image sensor 4. However, unlike the microlens array 3, the microlens array 3A is configured by arranging a plurality of microlenses each having a regular hexagonal outer shape in a two-dimensional hexagonal lattice. The linear movement mechanism 11 moves the microlens array 3A in a direction that traverses the light flux 2A toward the image pickup element 4. For example, when the direction perpendicular to the image pickup surface of the image pickup device 4 is the optical axis direction of the light flux 2A, the linear movement mechanism 11 uses the position table 32 input from the resolution control unit 23 to determine the microlens array 3A. The microlens array 3A is moved and scanned in the direction in which the lens surface is orthogonal to the optical axis of the light flux 2A. In the microlens array 3A, the arrangement direction of the plurality of microlenses is inclined with respect to the moving direction (scanning direction).

Next, the operation will be described.
The microlens array 3A is moved by the linear movement mechanism 11 in the scanning direction 11A indicated by the arrow in the left side view of FIG. The scanning direction 11A is a direction that traverses the light flux 2A propagating from the front side to the back side of the paper surface.

The array direction of the plurality of microlenses in the microlens array 3A is inclined at an angle θ with respect to the scanning direction 11A. As described above, the microlens array 3A is moved in the scanning direction 11A by the linear motion mechanism 11 while being inclined with respect to the scanning direction 11A.
For example, the tilt angle θ is 30°, the microlens array 3A is moved by the linear movement mechanism 11 at regular intervals, and the amount of movement is 1/√3 times the pitch size d of the microlenses in the microlens array 3A. Is. The condensing spot array 43A shown on the right side of FIG. 5 is an array of condensing spots imaged by the imaging device 4 when the microlens array 3A is moved to the first position. The condensing spot array 43B is an array of condensing spots imaged by the imaging element 4 when the microlens array 3A moves from the first position to the second position separated by the moving amount. The condensing spot array 43C is an array of condensing spots imaged by the imaging element 4 when the microlens array 3A moves to the third position, which is separated from the first position by the moving amount.

The local wavefront tilt calculation unit 21 calculates the local wavefront tilt data 31 based on the imaged data of the focused spot array 43A, calculates the local wavefront tilt data 31 based on the imaged data of the focused spot array 43B, and focuses the light. The local wavefront tilt data 31 is calculated based on the imaged data of the spot array 43C. The wavefront calculator 22 calculates the wavefront of the optical system 2 to be measured based on the three sets of local wavefront tilt data 31 corresponding to the first position, the second position, and the third position. This is equivalent to obtaining a focused spot image with three times the density to calculate the wavefront, and can improve the plane resolution of the wavefront.

The angle θ formed by the arrangement direction of the plurality of microlenses with respect to the scanning direction 11A is tan θ=(N/(N+2))×√3 (N is a positive natural number, N=1, 2, 3,...) To do.
FIG. 6 is an explanatory diagram showing the relationship between the angle θ formed by the scanning direction of the microlens array 3A and the array direction of the microlenses in the modification of the wavefront measuring apparatus according to the first embodiment.
The position table 32 in the modification of the wavefront measuring apparatus according to the first embodiment has 0, d/(N ² +N+1) ^1/2 ,..., (N ² +N)d/(N ² +N+1) ^{1/. The} position defined by each of the ² is set. By scanning the microlens array 3A at each position set in the position table 32, local wavefronts are arranged at a density of N ² +N+1 times the planar resolution of the wavefront sensor when the microlens array 3A is not scanned and at equal intervals. The inclination of can be measured, and the plane resolution of the wavefront can be improved. In other words, it is possible to calculate even higher-order wavefront aberration components.

As described above, in the wavefront sensor according to the first embodiment, the microlens array 3 or 3A in which the array direction of the plurality of microlenses is inclined with respect to the scanning direction 11A crosses the light flux 2A toward the image sensor 4. Move in the direction and scan. As a result, imaging data for each scanning position of the microlens array 3 or 3A can be obtained, so that the plane resolution of the wavefront can be improved without lowering the inclination resolution of the wavefront and the dynamic range.

In the wavefront sensor according to the first embodiment, the microlens array 3 is configured by arranging the microlenses in a two-dimensional square lattice shape, and the arrangement direction of the plurality of microlenses is parallel to the scanning direction of the microlens array 3. The inclination angle θ has a relationship in which tan θ is a positive natural number N of 1 or more. When the pitch size of the microlens is d, the linear motion mechanism 11 has 0, d/(N ² +1) ^1/2 ,..., N ² d/(N ² +1) ^1/2 , respectively. The microlens array 3 is scanned at the defined position. As a result, imaging data having a density of N ² +1 times the planar resolution of the wavefront sensor when the microlens array 3 is not scanned and at equal intervals can be obtained.

In the wavefront sensor according to the first embodiment, the microlens array 3A is configured by arranging the microlenses in a two-dimensional hexagonal lattice shape, and the arrangement direction of the plurality of microlenses is parallel to the moving direction of the microlens array 3A. The inclination angle θ has a relationship of tan θ=(N/(N+2))×√3 for a positive natural number N of 1 or more. When the pitch size of the microlenses of the microlens array 3A is d, the linear motion mechanism 11 sets the microlens array 3A to 0, d/(N ² +N+1) ^1/2 ,..., (N ² +N). The scanning is performed at the position defined by each of d/(N ² +N+1) ^1/2 . As a result, image data having a density N ² +N+1 times as high as the plane resolution of the wavefront sensor when the microlens array 3A is not scanned and at equal intervals can be obtained.

The wavefront measuring apparatus according to the first embodiment includes a local wavefront inclination calculating unit 21 and a wavefront calculating unit 22 in addition to the above-described wavefront sensor. As a result, it is possible to realize a wavefront measuring device in which the plane resolution of the wavefront is improved as compared with the wavefront sensor when the microlens array 3 or 3A is not scanned.

In the wavefront measuring method according to the first embodiment, since the processing shown in FIG. 2 is executed, the plane resolution of the wavefront is improved as compared with the wavefront sensor when the microlens array 3 or 3A is not scanned.

Embodiment 2.
FIG. 7 is a block diagram showing the configuration of the wavefront measuring apparatus according to the second embodiment of the present invention. In FIG. 7, the same components as those in FIG. 1 are designated by the same reference numerals and the description thereof will be omitted. The wavefront measuring apparatus shown in FIG. 7 measures the wavefront of the test optical system 2 based on the focused spot image of the light flux 2A detected by the wavefront sensor according to the second embodiment. The wavefront sensor according to the second embodiment includes a microlens array 3, an image sensor 4, a linear motion mechanism 11, and a rotation mechanism 12. The wavefront measuring apparatus according to the second embodiment includes a local wavefront inclination calculating unit 21, a wavefront calculating unit 22, a resolution control unit 23A, and a device control unit 24A, in addition to the wavefront sensor.

The rotation mechanism 12 is a component that rotates the microlens array 3, and is realized using, for example, any one of a rotation stage, a motor, a goniometer stage, and a tilt stage. By rotating the microlens array 3 by the rotating mechanism 12, the tilt angle θ formed by the arrangement direction of the plurality of microlenses with respect to the moving direction of the microlens array 3 by the linear movement mechanism 11 is changed.

The resolution control unit 23A creates the position angle table 33 based on the wavefront data calculated by the wavefront calculation unit 22. The position angle table 33 is data in which the angle θ of the microlens array 3 and a plurality of positions in the moving direction corresponding thereto are set. The device control unit 24</b>A controls the linear movement mechanism 11 to move the microlens array 3 for each position set in the position angle table 33, controls the rotation mechanism 12, and sets the position angle table 33. The microlens array 3 is rotated to the angle θ. The device control unit 24A controls the image sensor 4 to image the focused spot of the light flux 2A.

Next, the operation will be described.
FIG. 8 is a diagram showing a scanning mechanism of the microlens array 3 in the wavefront sensor according to the second embodiment. The resolution control unit 23A shown in FIG. 7 has an angle θ=tan ⁻¹ N (a positive natural number, N=1, 2, 3,...) And 0, d/(N ² +1) ^1/2 , , N ² d/(N ² +1) ^1/2 and the position angle table 33 in which the positions defined by each are set.

The device control unit 24A controls the rotation mechanism 12 to rotate the microlens array 3 to the angle θ set in the position angle table 33, and in this state, controls the linear motion mechanism 11 to move the position angle table 33. The microlens array 3 is moved for each position set to. At this time, the device control unit 24A controls the imaging element 4 to image the focused spot of the light flux 2A for each moving position of the microlens array 3.
In the wavefront measuring apparatus according to the second embodiment, the larger N is, the higher the plane resolution of the wavefront can be, and the smaller N, the higher the frequency of measurement.

As described above, the wavefront sensor according to the second embodiment rotates by rotating the microlens array 3 to change the tilt angle θ formed by the arrangement direction of the plurality of microlenses with respect to the moving direction of the microlens array 3. The mechanism 12 is provided. By changing the angle θ, it is possible to change the wavefront measurement with high speed but low plane resolution and the wavefront measurement with low speed but high plane resolution. The rotation mechanism 12 may be configured to rotate the microlens array 3A. Even with this configuration, the same effect as described above can be obtained.

The wavefront measuring apparatus according to the second embodiment includes a local wavefront tilt calculating unit 21 and a wavefront calculating unit 22 in addition to the above-described wavefront sensor. As a result, it is possible to realize a wavefront measuring device in which the plane resolution of the wavefront is improved as compared with the wavefront sensor when the microlens array 3 is not scanned.

In the wavefront measuring method according to the second embodiment, by rotating the microlens array 3 and changing the angle θ, it is possible to change between high-speed but low plane-resolution wavefront measurement and low-speed but high plane-resolution wavefront measurement. It is possible.

It should be noted that the present invention is not limited to the above-described embodiments, and within the scope of the present invention, each free combination of the embodiments or modifications or embodiments of each arbitrary component of the embodiments. It is possible to omit arbitrary components in each of the above.

Since the wavefront sensor according to the present invention can improve the plane resolution of the wavefront, it can be used for wavefront measurement of various optical systems.

DESCRIPTION OF SYMBOLS 1 light source, 2 optical system to be examined, 2A light flux, 2B pupil, 3,3A microlens array, 4 imaging device, 11 linear movement mechanism, 11A scanning direction, 12 rotation mechanism, 21 local wavefront tilt calculation unit, 22 wavefront calculation unit , 23, 23A resolution control unit, 24, 24A device control unit, 31 local wavefront tilt data, 32 position table, 33 position angle table, 41A, 41B, 41C, 41D, 41E, 43A, 43B, 43C focused spot array, 42A, 42B, 42C, 42D Focused spots.

The wavefront sensor according to the present invention includes a lens array, an image sensor, and a linear motion mechanism. The lens array is configured by arranging a plurality of lenses upon which the light flux transmitted or reflected by the test optical system is incident. The image pickup device images a plurality of converging spots on which the light fluxes passing through the plurality of lenses are condensed. The linear motion mechanism scans the lens array by moving the lens array in a direction that traverses the light flux toward the image sensor. In this configuration, the arrangement direction of the plurality of lenses is inclined with respect to the moving direction of the lens array, and the image pickup device forms a plurality of converging spots for each scanning position of the lens array moved by the linear movement mechanism. The feature is that the inclination of the local wavefront is measured at equal intervals in a two-dimensional grid by imaging, and the inclination of the same local wavefront is measured using the light flux that has passed through different lenses of the plurality of lenses. And

The wavefront sensor according to the present invention includes a lens array, an image sensor, and a linear motion mechanism. The lens array is configured by arranging a plurality of lenses upon which the light flux transmitted or reflected by the test optical system is incident. The image pickup device images a plurality of converging spots on which the light fluxes passing through the plurality of lenses are condensed. The linear motion mechanism scans the lens array by moving the lens array in a direction that traverses the light flux toward the image sensor. In this configuration, the arranging direction of the plurality of lenses is inclined with respect to the moving direction of the lens array, and the linear motion mechanism is arranged for each moving amount according to the inclination of the arranging direction of the lenses with respect to the moving direction of the lens array. By moving the lens array to perform scanning, and by the imaging element capturing a plurality of focused spots at each scanning position of the lens array moved by the linear motion mechanism, the local wavefront is evenly spaced in a two-dimensional lattice. Is measured, and the inclination of the same local wavefront is measured by using the light beams that have passed through different lenses of the plurality of lenses.

Claims (7)

A light beam transmitted or reflected by the optical system to be tested is incident, and a lens array configured by arranging a plurality of lenses,
An image pickup device for picking up a plurality of focused spots where the light fluxes passing through the plurality of lenses are focused,
A linear movement mechanism that moves and scans the lens array in a direction that traverses the light flux toward the image sensor,
The wavefront sensor, wherein an arrangement direction of the plurality of lenses is inclined with respect to a moving direction of the lens array. The lens array is configured by arranging the lenses in a two-dimensional square lattice pattern,
The inclination angle θ formed by the arrangement direction of the plurality of lenses with respect to the moving direction of the lens array has a relationship that tan θ is a positive natural number N of 1 or more,
When the pitch size of the lenses of the lens array is d, the linear motion mechanism sets the lens array to 0, d/(N ² +1) ^1/2 ,..., N ² d/(N ² The wavefront sensor according to claim 1, wherein scanning is performed at a position defined by each of +1) ^1/2 . The lens array is configured by arranging the lenses in a two-dimensional hexagonal lattice pattern,
The inclination angle θ formed by the arrangement direction of the plurality of lenses with respect to the moving direction of the lens array has a relationship of tan θ=(N/(N+2))×√3 for a positive natural number N of 1 or more,
When the pitch size of the lenses of the lens array is d, the linear motion mechanism sets the lens array to 0, d/(N ² +N+1) ^1/2 ,..., (N ² +N)d/ The wavefront sensor according to claim 1, wherein scanning is performed at a position defined by each of (N ² +N+1) ^1/2 . The wavefront sensor according to claim 1, further comprising a rotation mechanism that changes an inclination angle formed by an arrangement direction of the plurality of lenses with respect to a moving direction of the lens array by rotating the lens array. A wavefront sensor according to any one of claims 1 to 4,
A first calculation unit that calculates the inclination of the local wavefront of the optical system to be tested for each position in the moving direction of the lens array based on a plurality of focused spots imaged by the imaging device;
A wavefront measuring apparatus comprising: a second operation unit that calculates a wavefront of the optical system to be tested based on the inclination of the local wavefront calculated by the first operation unit. A lens array formed by arranging a plurality of lenses into which a light beam transmitted or reflected by a test optical system is incident, and a plurality of focused spots where the light beams passed through the plurality of lenses are focused are imaged. A wavefront measuring method using a wavefront sensor having an image sensor,
A linear motion mechanism, a step of moving the lens array in a state in which the arrangement direction of the plurality of lenses is inclined with respect to the moving direction of the lens array in a direction traversing the light flux toward the image sensor, and scanning;
A step of calculating a tilt of a local wavefront of the optical system to be tested based on a plurality of focused spots imaged by the image pickup device for each position in the moving direction of the lens array;
And a step of calculating a wavefront of the optical system to be tested based on the inclination of the local wavefront calculated by the first calculator. 7. The wavefront according to claim 6, wherein the rotation mechanism includes a step of rotating the lens array to change an inclination angle formed by an arrangement direction of the plurality of lenses with respect to a moving direction of the lens array. Measuring method.

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