KR20150118017A - Exposing apparatus and method for fixing the same - Google Patents

Abstract

Provided is a light exposure device, capable of performing high-accuracy light exposure. A light exposure device comprises: an array element for arranging an optical element in a 2D form; a holder for maintaining the array element; a projection optical system for imaging light through the array element on a photosensitive material; a fixed unit wherein a position with respect to the projection optical system is fixed for the holder to be fixed; a fixture for fixating the holder on the fixed unit; and a concave unit installed on at least one side of the holder and the fixed unit, for maintaining the holder on the fixed unit with adsorption.

Description

TECHNICAL FIELD [0001] The present invention relates to an exposure apparatus,

The present invention relates to, for example, an exposure apparatus used in photolithography, and more particularly, to a projection exposure apparatus which allows a light modulated by a spatial light modulation element to pass through a projection optical system, To an image forming apparatus.

2. Description of the Related Art In recent years, exposure light that passes light modulated by a spatial light modulation element such as a DMD (Digital Mirror Device: registered trademark) or the like through a projection optical system, forms an image on the photosensitive material Device is being proposed. Thus, an exposure apparatus using a spatial light modulation element is referred to as a DI (direct image: cochlear) exposure apparatus.

The exposure head of the DI exposure apparatus includes a spatial light modulator (DMD), a first projection optical system (projection lens), a microlens array (MLA), and a second projection optical system Quot; Such a DI exposure apparatus has a configuration in which light modulated by the DMD is magnified and projected on the MLA by the first projection lens and light having passed through the MLA is projected onto the predetermined light reflection surface by the second projection lens Respectively. Here, the MLA is a lens in which microlenses corresponding to the respective pixel portions of the DMD are arranged in an array in accordance with the positions of the respective pixels of the DMD.

As such a DI exposure apparatus, there is a technique described in, for example, Patent Document 1 or Patent Document 2. These techniques relate to an exposure apparatus having components such as a DMD, a first projection lens, an MLA, and a second projection lens, and the light passing through each pixel portion (mirror) .

Japanese Patent No. 4510429 Japanese Patent Application Laid-Open No. 2005-189403

Incidentally, in the DI exposure apparatus, the DMD replacement frequency is relatively high, and it is necessary to align the DMD mirror and the MLA lens corresponding to the DMD mirror. Also, although the frequency is lower than that of the DMD, it is also necessary to perform alignment of the MLA in order to make the projected image on the optical surface to be in a desired position or direction. After such positioning, it is preferable to fix the position of the DMD or MLA.

However, since high precision is required for alignment, high exposure accuracy can not be realized when an unavoidable positional deviation occurs in an operation (for example, screw tightening) for fixing the position of the DMD or MLA. In Patent Documents 1 and 2, no configuration or method for suppressing such positional displacement and fixing the position of the DMD or MLA is proposed at all.

It is therefore an object of the present invention to provide an exposure apparatus capable of realizing high exposure accuracy. It is another object of the present invention to provide a fixing method applicable to the above exposure apparatus.

According to an aspect of the present invention, there is provided an exposure apparatus comprising: an array element in which optical elements are arranged in a two-dimensional shape; a holder for holding the array element; A projection optical system for projecting the projection optical system on the projection optical system; a fixture fixed to the projection optical system to fix the holder, a fixture for fixing the holder to the fixer, And a recess provided in at least one of the holder and the fixer.

According to such an exposure apparatus, since the holder can be fixed by suction using the concave portion and then fixed by the fixture, the positional deviation of the holder (or the positional shift of the array element) accompanying the fixing operation can be suppressed. As a result, it is possible to realize a high exposure accuracy by an array element aligned with high precision.

In the above exposure apparatus, it is preferable that the array element is a reflection type or a transmission type optical element arranged, and the projection optical system forms a light reflected or transmitted by the array element.

If the array element is of a reflection type or a transmission type, the positional deviation of the array element greatly affects the exposure accuracy of the exposure apparatus through the projection optical system or the like at the rear end, and therefore the exposure accuracy is effectively improved do.

According to another aspect of the present invention, there is provided a fixing method comprising: an array element in which optical elements are arranged in a two-dimensional shape; a holder for holding the array element; A fixing method for fixing a holder to a fixed portion fixed to a position with respect to the projection optical system in an exposure apparatus provided with a projection optical system that forms an image on a material is characterized in that the holder is held by suction to the fixed portion And a second step of fixing the holder held in the first step to the fixed part with a fixture.

According to such a fixing method, it is possible to suppress the positional deviation of the holder (or the positional deviation of the array element) accompanying the fixing operation in the second step, and the high exposure accuracy Can be realized.

In the exposure apparatus and the fixing method of the present invention, positional shift of the holder due to the fixing operation can be suppressed, and high exposure accuracy can be realized.

1 is a schematic configuration diagram showing an exposure apparatus according to the present embodiment.
2 is a view showing a specific configuration of the exposure head.
3A is a cross-sectional view showing a configuration of an MLA.
3B is a plan view showing the configuration of the MLA.
4 is a view showing an image forming area by the exposure head.
5 is a view conceptually showing a method of fixing a projection optical system to a base plate.
6 is a view showing the fixing positions of the DMD holder and the MLA holder.
7 is a cross-sectional view showing an example of a detailed structure of the DMD holder.
8 is a perspective view showing an example of the detailed structure of the DMD holder.
9 is a view showing an example of a jig for adjustment of the DMD holder.
10 is a view showing an example of an arm of the adjustment jig.
11 is a cross-sectional view showing an example of the detailed structure of the MLA holder.
12 is a perspective view showing an example of a detailed structure of the MLA holder.
13 is a view showing an example of an adjusting jig of the upper holder 171. Fig.
14 is a view showing an MLA holder of a modified example.
15 is a diagram showing the relationship between the generation pattern of crosstalk and the adjustment direction.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described with reference to the drawings.

1 is a schematic configuration diagram showing an exposure apparatus of the present embodiment.

The exposure apparatus 1 passes light modulated by a spatial light modulation element through a projection optical system, and forms an image on the photosensitive material (resist) by exposing the image by the light. Since such an exposure apparatus directly forms an image with a spatial light modulation element, a mask (or a reticle) is unnecessary and is called a DI (direct image: cochlear) exposure apparatus.

The exposure apparatus 1 includes an exposure head unit 10, a transfer system 20 for transferring a substrate (workpiece) W to be exposed, an exposure head unit 10 and a transfer system 20 (Not shown). Here, the work W is, for example, a resin-made printed substrate coated with a resist.

The exposure head unit 10 includes a plurality of exposure heads (optical engines) 11 and a light source (not shown). The exposure head 11 incorporates the above-described spatial light modulation element, and is supplied with light from a light source and irradiates light in a predetermined pattern. The plurality of exposure heads 11 are supported by a common base plate 12. The base plate 12 is fixed to a gate type gantry 31 provided so as to extend over the mounting table 30. Each end portion (leg portion) of the gantry 31 is fixed to the side surface of the mounting table 30 have.

Here, the base plate 12 is directly mounted on a horizontal beam portion connecting the two leg portions of the gantry 31. [ A through hole (not shown) through which the exposure head 11 penetrates is formed in the beam portion of the gantry 31. The base plate 12 has both ends End portion of the gantry 31 is fixed to the beam portion of the gantry 31. That is, the base plate 12 is fixed to the gantry 31 in a supported manner in both ends.

The method of fixing the base plate 12 to the gantry 31 can be suitably applied as long as it is a method capable of ensuring rigidity. For example, in the case where the exposure head unit 10 is provided with a frame, and the frame and the gantry 31 are fixed, the base plate 12 is fixed to the frame of the exposure head unit 10 It may be fixed to the gantry 31. In this case, the base plate 12 is fixed to the outer frame at both ends.

The transport system 20 includes a flat plate stage 21 for sucking and holding the workpiece W by vacuum adsorption or the like and two guides 22 extending along the moving direction of the stage 21, And an electromagnet 23 constituting a moving mechanism of the stage 21 as an example.

Here, an example of employing a linear motor stage as the moving mechanism will be described. In this case, in the linear motor stage, a moving body (stage) is floated by air on a planar plate provided with a convex pole of a ferromagnetic body in a lattice shape, and a magnetic force is applied to the moving body, To move the moving object (stage).

The stage 21 is arranged such that the longitudinal direction thereof is directed to the stage moving direction, and is supported so as to be capable of reciprocating in a state of compensating the straightness by the guide 22.

In this specification, the moving direction of the stage 21 is referred to as the X direction, the horizontal direction perpendicular to the X direction is referred to as Y direction, and the vertical direction is referred to as Z direction. The workpiece W is rectangular, and is held on the stage 21 in a posture in which one side is oriented in the X direction and the other side is oriented in the Y direction. In the following description, the X direction is referred to as the longitudinal direction of the work W and the Y direction as the width direction of the work W.

The movement path of the stage 21 is designed to pass directly under the exposure head unit 10 and the transfer system 20 conveys the work W to the irradiation position of the light by each of the exposure heads 11 , And passes the irradiation position. In this passing process, an image pattern formed by each exposure head 11 is exposed to the work W.

Next, the optical configuration of the exposure head 11 will be described.

2 is a view conceptually showing the optical configuration of the exposure head 11. As shown in Fig. 2, the exposure head 11 includes an incident optical system 14, a spatial light modulation element 15, a first projection lens 16, a microlens array (MLA) 17, And a second projection lens 18. As shown in FIG.

The incident optical system 14 causes the output light of the light source 13 to enter the spatial light modulation element 15 and includes an optical fiber 14a, a collimator lens 14b, and a mirror 14c. Here, the light source 13 is a lamp or a laser diode that emits a wavelength such as 405 nm or 365 nm. As the optical fiber 14a, for example, quartz fiber is used.

The output light of the light source 13 is guided by the optical fiber 14a and is incident on the collimator lens 14b. The collimator lens 14b converts the light emitted from the optical fiber 14a and diffused into parallel light It exits. The light having passed through the collimator lens 14b is reflected by the mirror 14c and is incident on the spatial light modulation element 15 at an angle?.

As the spatial light modulation element 15, a digital mirror device (DMD) is used. The DMD is an array element in which, for example, minute mirrors (pixel mirrors) of about 13.68 占 퐉 are arranged in a two-dimensional shape. The number of arrays is, for example, 1024 x 768, and the total size of the spatial light modulator (DMD) 15 is, for example, about 14 mm x 10.5 mm.

The angle of each pixel mirror of the DMD 15 is controlled by a control unit (not shown). The control section outputs a control signal for controlling the angle of each pixel mirror of the DMD 15 so that only the reflected light forming the desired pattern is incident on the first projection lens 16. [

That is, the angle of each pixel mirror of the DMD 15 is selectively controlled according to the pattern of the image to be formed. Specifically, the pixel mirror at a position where light should reach the workpiece W in accordance with a pattern to be formed is formed in such a manner that the angle at which the light reflected by the pixel mirror enters the first projection lens 16 And the other pixel mirrors are controlled at an angle (second angle) at which the light reflected by the pixel mirrors does not enter the first projection lens 16. [

Thus, only the light reflected by the pixel mirror at the first angle reaches the surface of the work W, and the light reflected by the pixel mirror at the second angle does not reach the work W.

The first projection lens 16 is an enlarged projection lens for magnifying an image from the DMD 15 by, for example, 2 to 5 times and projecting it onto the MLA 17. [

The MLA 17 is an optical component (array element) in which a plurality of microscopic lenses (hereinafter referred to as lens elements) 17a are arrayed in a two-dimensional shape, as shown in the sectional view in Fig. 3A and the plan view in Fig. to be. Each lens element 17a corresponds to each pixel mirror of the DMD 15 on a one-to-one basis. That is, each lens element 17a forms an image of one pixel mirror on the surface of the work W.

The second projection lens 18 reduces the light condensed in the form of a spot by the MLA 17 to a magnification of, for example, 1 time (x times) to 1/2 times, A projection lens or a reduction projection lens.

As described above, in the DI exposure apparatus 1, the first projection lens 16 and the second projection lens 18 are provided respectively at the front end (light incidence side) and the rear end (light exit side) of the MLA 17 . The first projection lens 16, the MLA 17 and the second projection lens 18 constitute a projection optical system for the DMD 15. [ The second projection lens 18 constitutes a projection optical system for the MLA 17. [

4 is a perspective view schematically showing an image forming area by the exposure head 11. Fig.

4, the image forming area by each of the exposure heads 11 is represented by a rectangular frame (code E) on the surface of the work W. An image formed by one exposure head 11 is formed in the image formation area E that appears with this frame.

As shown in Fig. 4, the exposure head 11 is provided in two rows in the X direction, and each exposure head 11 of the rear side group with respect to the moving direction of the work W is moved to the respective exposure heads 11 in the Y direction.

By disposing the exposure heads 11 as described above, when the work W is exposed while moving in the X direction, a portion which can not be exposed to the image forming area E by each exposure head 11 of the front group And the image forming area E by the exposure head 11 on the rear side. Then, a desired one pattern is formed by the entire exposure head 11.

In other words, a control unit (not shown) stores digital data (original data) of an image (exposure pattern) to be formed, sends a control signal to the transfer system 20, Is moved at a predetermined speed. At the same time, the control unit sends a control signal to the DMD 15 to control the angle of each pixel mirror at a predetermined timing and sequence so that an exposure pattern based on the original data is formed on the work W.

As a result, the work W coated with the resist passes through the image formation area E and an exposure pattern based on the original data is formed on the work W.

Here, a description will be given of a constitution in which each component of the projection optical system is fixed to the base plate 12. Fig.

5 is a view conceptually showing a method of fixing the projection optical system with respect to the base plate 12. Fig. 5, the illustration of the gantry 31 is omitted.

The base plate 12 is formed with a through hole 12a through which light reflected by the DMD 15 passes.

A microlens array holder (MLA holder) 17b holding the MLA 17 is fixed on the upper surface of the base plate 12 so that the MLA 17 is disposed above the through hole 12a. The MLA holder 17b is screwed to the base plate 12 by a screw 17c.

A first projection lens holder 16a holding the first projection lens 16 is provided on the upper surface of the base plate 12 so that a first projection lens 16 is disposed above the MLA 17. [ ). Here, the first projection lens 16 is held in the first projection lens holder 16a by, for example, screwing. The first projection lens holder 16a is screwed to the base plate 12 by a screw 16b.

An incident optical system 14 is fixed to the upper part of the first projection lens 16 by screw fixing and the DMD holder 15a holding the DMD 15 Is fixed.

A second projection lens holder (not shown) holding the second projection lens 18 is provided on the lower surface of the base plate 12 so that a second projection lens 18 is disposed below the through hole 12a 18a. Here, the second projection lens 18 is held in the second projection lens holder 18a by, for example, screwing. The second projection lens holder 18a is screwed to the base plate 12 by a screw 18b.

As described above, the elements constituting the exposure head 11 are directly or indirectly fixed to the base plate 12, but the incident optical system 14, the first projection lens 16, The DMD 15 and DMD holder 15a and MLA 17 (and MLA holder 17b) are not required to be precisely positioned relative to the DMD 15, so simply aligning the screw and the screw hole And can be fixed by screwing. On the other hand, the MLA 17 (and the MLA holder 17b) needs to be precisely aligned to match a specific angle with respect to the moving direction of the work W, and the DMD 15 (15a), it is necessary to align the MLA 17 with high precision in accordance with the position and angle of the MLA 17. After such high-precision alignment, it is required to fix the alignment accuracy without disturbing the accuracy.

Hereinafter, the concrete fixing method of the DMD 15 (and the DMD holder 15a) and the MLA 17 (and the MLA holder 17b) in the present embodiment will be described in detail.

6 is a view showing the fixing positions of the DMD holder and the MLA holder.

In Fig. 6, the fixing positions of the DMD holder and the MLA holder, which are conceptually shown in Fig. 5, are specifically shown.

The MLA holder 17b is fixed to the base plate 12 in a state that the MLA holder 17b is substantially covered by the first projection lens holder 16a and the adjustment arm as described later in detail is moved from the first projection lens holder 16a Protruding outward.

As described above, the first projection lens holder 16a is screwed to the base plate 12, and the first projection lens 16 is screwed onto the first projection lens holder 16a have. An incidence optical system 14 is screwed onto an upper portion of the first projection lens 16 and a DMD holder 15a is fixed to the upper portion of the incidence optical system 14. [

Fig. 7 is a cross-sectional view showing an example of the detailed structure of the DMD holder, and Fig. 8 is a perspective view showing an example of the detailed structure of the DMD holder.

7, the DMD holder 15a is provided with three pressing metal members 151, 152, and 153 and a base plate 158. As shown in Fig. The DMD 15 as a semiconductor chip is mounted on a substrate 15b and the three pressing members 151, 152 and 153 are integrated by screwing the DMD 15 with the board 15b and screwing them together. The pushing members 151, 152 and 153 thus integrated are fixed to the base plate 158 by screws 156 with a shim (thin plate of stainless steel) 155 for adjusting the tilt interposed therebetween. The padding 155 is sandwiched by a properly selected number such that the reflecting surface of the DMD 15 is parallel to the upper surface of the incident optical system 14 to which the DMD holder 15a is fixed. The direction of the light from the DMD 15 toward the first projection lens 16 is adjusted in the direction parallel to the optical axis of the first projection lens 16 1).

The DMD holder 15a is integrated with the DMD 15 in such a structure to hold the DMD 15 therein. The DMD holder 15a integrated with the DMD 15 is fixed to the upper portion of the incident optical system 14 serving as the fixed portion to the DMD holder 15a. Holes 141 and adsorption joints 142 for vacuum adsorption of the DMD holder 15a are provided on the upper portion of the incidence optical system 14. One end of the hole 141 extends in the shape of a groove along the upper surface opposed to the DMD holder 15a. By the vacuum suction through the hole 141 extending in the groove shape, the DMD holder 15a is incident And is strongly held on the upper side of the optical system 14. In addition, the end of the hole 141 does not need to be in the shape of a groove so long as a sufficient holding force can be obtained, for example, a round hole or the like may be used.

The DMD holder 15a is temporarily held at the upper portion of the incident optical system 14 serving as the defective portion by vacuum suction after the position adjustment with high precision. The adsorption maintenance represented by vacuum adsorption can maintain the DMD holder 15a at the upper portion (fixed portion) of the incident optical system 14 without disturbing the precisely adjusted position of the DMD holder 15a. The thus held DMD holder 15a is firmly fixed to the upper part of the incident optical system 14 by the screw 15c, and then the vacuum adsorption may be released. During the fixing operation by the screw 15c, the DMD holder 15a is held by the vacuum suction, so that the displacement of the DMD holder 15a due to the fixing operation is suppressed. With this fixing method, the DMD holder 15a (and the DMD 15) is precisely and firmly fixed to the fixed portion. In this example, the suction joint 142 and the hole 141 are provided on the receiver side. However, even if the joint 142 and the hole 141 are provided on the DMD holder 15a side, Is obtained equally.

The adjustment of the position of the DMD holder 15a may be performed by adjusting the vertical and horizontal positions and angles in the plane perpendicular to the optical axis of the first projection lens 16 (i.e., the XY plane perpendicular to the Z axis shown in Fig. 1) . Since this position adjustment is precise adjustment, an adjusting jig is used.

Fig. 9 is a view showing an example of an adjusting jig of the DMD holder, and Fig. 10 is a view showing an example of an arm of the adjusting jig.

The adjusting jig 40 is temporarily attached when the position of the DMD holder 15a is adjusted, and is detached after the DMD holder 15a is fixed after the position adjustment.

9 and 10, the adjustment jig 40 includes three arms 41, 42, 43. The first and second arms 41, 42 are arranged in the longitudinal direction of the arm And the third arm 43 moves back and forth in the Y direction within the XY plane. The DMD holder 15a is moved in the X direction by the forward and backward movement of the first and second arms 41 and 42 in the same direction and the DMD holder 15a is moved in the Y direction by the forward and backward movement of the third arm 43, Direction. Further, the DMD holder 15a rotates in the XY plane as the first and second arms 41 and 42 move back and forth in opposite directions. Each arm 41, 42, 43 moves back and forth with high precision according to the operation of the operator, so that the operator can align the DMD holder 15a with a desired position and angle with high accuracy. The desired position and angle are based on the position and angle of the MLA 17.

Next, a specific fixing method of the MLA 17 (and the MLA holder 17b) will be described.

Fig. 11 is a cross-sectional view showing an example of a detailed structure of an MLA holder, and Fig. 12 is a perspective view showing an example of a detailed structure of an MLA holder.

The MLA holder 17b has an upper holder 171 and a lower holder 172 and the upper holder 171 is capable of rotating accurately with respect to the lower holder 172. [ The MLA 17 is integrated with the upper holder 171 by being adhered to the upper holder 171 by an adhesive. The upper holder 171 is provided with an angle adjusting arm 177.

The lower holder 172 is fixed to the base plate 12 with screws 174 with the tilt adjusting shim 173 therebetween. The padding 173 is formed so that the direction of the optical axis of the MLA 17 is parallel to the optical axis of the first projection lens 16 or the optical axis of the second projection lens 18 ), As shown in Fig. The lower holder 172, which is thus tilted and fixed to the base plate 12, is a fixed portion to which the upper holder 171 is fixed. The lower holder 172 is provided with a hole 175 for vacuum adsorption of the upper holder 171 and a joint 176 for adsorption. One end of the hole 175 extends in a groove shape along the upper surface opposed to the upper holder 171. By the vacuum suction through the hole 175 extending in the groove shape, And is strongly held in the holder 172. The holes 175 may also be round holes instead of grooves as long as a sufficient holding force can be obtained.

The upper holder 171 is temporarily held in the lower holder 172 serving as a defective portion by vacuum suction after precise angle adjustment on the XY plane perpendicular to the Z axis shown in Fig. Since this holding is also performed by suction, it is possible to hold the upper holder 171 without disturbing the precisely adjusted angular position. The upper holder 171 thus held is firmly fixed to the lower holder 172 by the screw 17c, and then the vacuum adsorption is released. The upper holder 171 is held by the lower holder 172 by vacuum suction during the fixing work by the screw 17c so that the positional deviation of the upper holder 171 due to the fixing operation The positional deviation due to the force applied to the surface) is suppressed. With this fixing method, the upper holder 171 is fixed to the lower holder 172 accurately and firmly, and furthermore, the MLA 17 is fixed to the base plate 12 accurately and firmly. Although the adsorption joint 176 and the hole 175 are formed on the side of the lower holder 172 serving as the servomechanism in this example as well, the mode in which the joint 176 and the hole 175 are formed on the side of the upper holder 171 It is a matter of course that the action of adsorption is equally obtained.

Since the angle adjustment of the upper holder 171 is also precisely adjusted, an adjusting jig is used.

13 is a view showing an example of an adjusting jig of the upper holder 171. Fig.

The adjustment jig 50 can press the arm 177 of the upper holder 171 with high precision according to the operation of the operator so that the operator can precisely align the upper holder 171 and the MLA 17 with a desired angle . The desired angle is a specific angle based on the moving direction of the work W by the stage 21 shown in Fig.

With respect to the position of the MLA 17 in the XY plane (that is, the position of the lower holder 172), the number of lens elements arranged in the MLA 17 is larger than the number of pixel mirrors arranged in the DMD 15 The positioning accuracy is not required compared with the angle adjustment of the MLA 17. Therefore, when the screw and the screw hole are matched with each other, they are fixed as they are by screwing.

Here, an MLA holder of a modified example that can be employed in place of the MLA holder 17b shown in Figs. 11 and 12 will be described.

Fig. 14 is a view showing an MLA holder of a modified example. Fig.

In the MLA holder 117b of this modified example, fixing stone projections 178 and 179 are provided in the upper holder 171 and the lower holder 172, respectively, and these stone projections 178 and 179 are fixed to each other with an adhesive The upper holder 171 is fixed to the lower holder 172 by being fixed by the upper holder 60. [ The upper holder 171 is firmly fixed with respect to the lower holder 172 even with the adhesive 60. [

In this modified example, the displacement of the upper holder 171 due to, for example, the stress when applying the adhesive 60 is suppressed, and the upper holder 171 is fixed to the lower holder 172 accurately and firmly do.

Thus, the description of the modification example is ended.

Next, positioning of the DMD 15 with reference to the MLA 17 will be described. The position and angle of the DMD holder 15a at the desired position and angle (i.e., the desired position and angle of the DMD 15) of the DMD 15 are adjusted by the adjustment jig 40 as described above, Specifically, the light emitted from each pixel mirror of the DMD 15 is incident on each of the corresponding lens elements of the MLA 17 in accordance with the position and angle of the MLA 17 in the present embodiment, The position and angle of incidence. When the DMD 15 is positioned at a desired position and angle, light emitted from each pixel mirror of the DMD 15 passes through each of the corresponding lens elements and finally reaches a point shape at the light irradiation position of the exposure head 11 . However, if the position and the angle of the DMD 15 deviate from the desired position and angle, an extra light spot called crosstalk is generated and the exposure accuracy is lowered. Thus, the DMD 15 is positioned so that the occurrence of crosstalk is reduced while the state of occurrence of such crosstalk is confirmed by the camera and the monitor.

15 is a diagram showing the relationship between the generation pattern of crosstalk and the adjustment direction.

In Fig. 15, the light spot that is normally focused is indicated by an oblique line, and the light spot of crosstalk is shown in white. 15 shows a pattern 1 in which the X-direction position of the DMD 15 is shifted from a desired position, a pattern 2 in which the Y-direction position of the DMD 15 is shifted from a desired position, A pattern 3 deviating from a desired angle is shown. In any pattern, the DMD 15 is adjusted in position using the adjusting jig shown in Fig. 9 in the direction in which the light spot of the crosstalk toward the normally focused image point approaches as shown by the arrow in the figure.

With such position adjustment, the DMD 15 is precisely aligned with respect to the MLA 17, and high-precision exposure with a small crosstalk is realized.

1: Exposure device 10: Exposure head unit
11: Exposure head 12: Base plate
13: light source 14: incident optical system
15: spatial light modulator (DMD) 15a: DMD holder
155: Vacuum suction hole 16: First projection lens
17: microlens array (MLA) 17a: lens element
17b: MLA holder 17c: screw
18: second projection lens 171: upper holder
172: lower holder 175: hole for vacuum adsorption

Claims (3)

An exposure apparatus for imaging light on a photosensitive material by modulating light from a light source with respect to each pixel,
An array element in which optical elements are arranged in a two-dimensional shape,
A holder for holding the array element;
A projection optical system for imaging the light through the array element on the photosensitive material,
A fixed portion for fixing the holder to the projection optical system,
A fixture for fixing the holder to the fixer;
And a concave portion provided on at least one of the holder and the fixed portion for holding the holder by suction to the fixed portion. The method according to claim 1,
Wherein the array element is a reflection type or a transmission type optical element arranged,
Wherein the projection optical system forms an image of light reflected or transmitted by the array element. An exposure apparatus for modulating light from a light source with respect to each pixel to form an image on a photosensitive material, comprising: an array element in which optical elements are arranged in a two-dimensional shape; a holder for holding the array element; A fixing method for fixing an holder to a fixed support having a fixed position with respect to the projection optical system in an exposure apparatus having a projection optical system that forms an image on a photosensitive material,
A first step of holding the holder on the workpiece by suction,
And a second step of fixing the holder held in the first step to the fixed part with a fixture.

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