JP2014235342A - Exposure drawing apparatus, exposure drawing method and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To control an edge position of an image drawn to a drawing object in a high accuracy manner by a further simple treatment.SOLUTION: A first control data generation part 51 generates first control data that show an on-off state of a micromirror for each of two or more micromirrors based on image data. A virtual micromirror setting part 52 sets a virtual micromirror that forms a virtual drawing point that is virtual at a position different from a drawing point corresponding to the micromirror for the respective micromirrors. A second control data generation part 53 generates second control data that show an on-off state for each frame period of the virtual micromirror. A control data correction part 54 corrects a logical value of each frame period in the first control data by a value obtained by performing a logical arithmetic with a logical value of a corresponding frame period in the corresponding second control data.

Description

  The present invention relates to an exposure drawing apparatus that exposes and draws an image on a drawing target, an exposure drawing method, and a program executed by the exposure drawing apparatus.

  2. Description of the Related Art In recent years, there has been an exposure drawing apparatus that uses a spatial light modulation element such as a digital micromirror device (hereinafter referred to as DMD) to generate a light beam according to input image data and perform exposure drawing on a substrate to be exposed. Are known.

  The DMD is a mirror device in which a large number of micromirrors whose reflection surfaces change in response to a supplied control signal are two-dimensionally arranged on a memory cell matrix, and static electricity generated by charges stored in each memory cell. The angle of the reflecting surface of the micromirror is changed by force. An exposure drawing apparatus having a DMD modulates a light beam from a light source by on / off controlling each of the DMD micromirrors based on image data or the like, and exposes the modulated light beam to an exposed substrate. .

  For example, in Patent Document 1, a plurality of drawing point formation regions for forming drawing points based on drawing point data are moved relative to the substrate, and drawing is performed by a plurality of drawing point formation regions according to the movement. In the drawing method of drawing an image by sequentially forming a point cloud on a substrate, by controlling the drawing state of only a part of the drawing point forming areas among a plurality of drawing point forming areas forming the edge of the image, The position of the edge of the image on the substrate is controlled at a pitch finer than the pitch of the drawing point forming region in the direction orthogonal to the extending direction of the edge, and the position of the edge of the drawing point data and the position of the edge formed on the substrate A drawing method for matching is described.

Japanese Patent No. 4532381

  In the exposure drawing apparatus using the DMD as described above, the resolution of the beam trajectory of the micromirror on the substrate is limited by the pitch of the micromirror in the DMD. Therefore, when exposure drawing is performed based on image data created in advance, the edge of the drawing line on the image data may not match the edge of the drawing line that is actually exposed. For example, when a black matrix in a liquid crystal display is exposed on a substrate, if the edge of the black matrix does not coincide with the actual edge, the aperture ratio of the R, G, and B filter portions cannot be sufficiently secured. Can occur. Although the resolution of the beam trajectory can be improved by changing the optical system, such an optical system is expensive and causes an increase in cost.

  Also, by design, even if the edge of the drawing line on the image data matches the edge of the drawing line that is actually exposed and drawn, shading actually occurs due to the influence of the optical system, etc. In some cases, the edge of the drawing line above does not match the edge of the drawing line that is actually exposed and drawn. In such a case, it is necessary to control the position of the edge of the drawing line that is actually exposed and drawn more finely than the resolution of the beam trajectory.

  The drawing apparatus and the drawing method described in Patent Document 1 described above are for solving such problems, and the position of the edge of the drawing line that is actually exposed and drawn is adjusted by the following procedure. First, the ideal mirror data is thinned. Next, contour mirror data is acquired by calculating XOR (exclusive OR) of the thinned mirror data and ideal mirror data. Next, a thinning process is performed on the contour mirror data at a thinning rate according to the control amount of the edge position, and thinned contour mirror data is acquired. Next, an OR (logical sum) of the thinned contour mirror data and the thinned mirror data is calculated to obtain thinned ideal mirror data.

  According to the method described in Patent Document 1, the position of the edge of the drawing line that is actually exposed and drawn can be controlled more finely than the resolution of the beam trajectory, but the processing is complicated and the processing time is increased. There was a problem.

In particular, in the production of printed circuit boards that require high-speed data transfer, line width control (edge control) is required so as to achieve impedance characteristics as designed. For example, when a signal line having a width w and a thickness t is formed on the surface of a dielectric having a dielectric constant ε _r and a thickness h, the impedance Z _{0 of the} signal line can be expressed by the following equation (1). it can.

Z ₀ = 87 × ln {5.98h / (0.8w + t)} / (ε _r +1.414) ^1/2 (1)

  One method for realizing line width control (edge control) that achieves the impedance characteristics as designed is the plating thickness and line width after finishing through the manufacturing process such as plating, exposure / development, and etching. Based on this measurement, the line width of the design pattern is increased or decreased in advance. In this case, it is desirable to perform correction with a fine correction amount at a high data resolution in order to approach the target line width, but this requires an increase in memory capacity and hardware with a high processing speed, resulting in an increase in cost.

  The present invention has been made in view of the above points, and an exposure drawing apparatus, an exposure drawing method, and a program capable of controlling the position of an edge of an image drawn on a drawing target with a simpler process with high accuracy. The purpose is to provide.

  According to a first aspect of the present invention, an image data acquisition unit that acquires image data indicating an image to be drawn on a drawing target, and the incident light is spatially modulated by turning on and off a plurality of micromirrors to correspond to the image data An exposure head that generates the patterned light and irradiates the drawing target with the pattern light; and a relative position of the drawing target with respect to the exposure head in a state where the exposure head irradiates the pattern target with the pattern light. And a first control data including a plurality of logical values corresponding to the on / off state of each micromirror for each frame period, based on the image data. Based on the first control data generation unit and the first control data, on / off of the plurality of micromirrors is controlled. A virtual micro that sets at least one virtual virtual drawing point at a position different from the drawing point corresponding to the control mirror and at least one of the plurality of micro mirrors to the control unit. A plurality of logical values corresponding to an on / off state for each frame period of the virtual micromirror when drawing a portion corresponding to the virtual drawing point of the image indicated by the image data at the virtual drawing point A second control data generation unit that generates second control data including the virtual micromirror, and a logical value for each frame period in the first control data corresponding to the micromirror in which the virtual micromirror is set. By performing a logical operation with the logical value of the corresponding frame period in the second control data corresponding to Exposure drawing apparatus and a control data correction unit for correcting the obtained value Te is provided.

  According to a second aspect of the present invention, there is provided the exposure drawing apparatus according to the first aspect, wherein the virtual micromirror setting unit sets a plurality of virtual micromirrors for one micromirror that sets a virtual micromirror. Is done.

  According to a third aspect of the present invention, the virtual micromirror setting unit is configured such that the virtual drawing point is drawn on the exposure head by the moving mechanism with the drawing point corresponding to the one micromirror interposed therebetween. An exposure drawing apparatus according to a second aspect is provided in which at least two virtual micromirrors are set with respect to the first micromirror so as to be arranged along a moving direction of a relative position of an object.

  According to a fourth aspect of the present invention, the virtual micromirror setting unit is configured such that the virtual drawing point is drawn on the exposure head by the moving mechanism with a drawing point corresponding to the one micromirror interposed therebetween. An exposure drawing apparatus according to a second aspect is provided in which at least two virtual micromirrors are set for the one micromirror so as to be arranged along a direction intersecting a moving direction of a relative position of an object.

  According to a fifth aspect of the present invention, the virtual micromirror setting unit is configured such that the virtual drawing point is drawn on the exposure head by the moving mechanism with a drawing point corresponding to the one micromirror interposed therebetween. There is provided an exposure drawing apparatus according to a second aspect in which a plurality of virtual micromirrors are set for the one micromirror so as to be arranged along a moving direction of a relative position of an object and a direction orthogonal thereto.

  According to a sixth aspect of the present invention, the apparatus further includes an instruction input unit that receives an instruction input for instructing increase / decrease of a line width of the image drawn by the pattern light, and the control data correction unit is included in the instruction input unit. Each frame period in the first control data corresponding to the micromirror in which the virtual micromirror is set, depending on whether the input instruction indicates an increase in the line width or a decrease in the line width Are corrected by values obtained by calculating a logical sum or logical product with a logical value of a corresponding frame period in the second control data corresponding to the virtual micromirror. An exposure drawing apparatus according to any aspect is provided.

  According to a seventh aspect of the present invention, the instruction input unit further receives an instruction input that instructs a correction amount of a line width of an image drawn by the pattern light, and the virtual micromirror setting unit According to the sixth aspect of setting the virtual micromirror such that the distance between the drawing point corresponding to the micromirror and the virtual drawing point increases as the correction amount of the line width input to the input unit increases. An exposure drawing apparatus is provided.

  According to an eighth aspect of the present invention, in the exposure drawing apparatus according to any one of the first to seventh aspects, the virtual micromirror setting unit sets a plurality of virtual micromirrors for each of the plurality of micromirrors. Provided.

  According to a ninth aspect of the present invention, the virtual micromirror setting unit calculates a distance between a drawing point corresponding to one micromirror that sets a virtual micromirror and the virtual drawing point, and a virtual micromirror. A virtual micromirror is set for each of the first micromirror and the other micromirror so that the distance between the drawing point corresponding to the other micromirror to be set and the virtual drawing point is different. An exposure drawing apparatus according to the above aspect is provided.

  According to a tenth aspect of the present invention, the virtual micromirror setting unit includes a plurality of exposure heads, and the distance between a drawing point corresponding to the micromirror that sets the virtual micromirror and the virtual drawing point is There is provided an exposure drawing apparatus according to any one of the first to eighth aspects, in which virtual micromirrors are set for micromirrors in the plurality of exposure heads so as to differ among exposure heads.

  According to an eleventh aspect of the present invention, the virtual micromirror setting unit includes a plurality of exposure heads, and the virtual micromirror setting unit applies only to a micromirror in a part of the plurality of exposure heads. An exposure drawing apparatus according to any one of the first to tenth aspects of setting the above is provided.

  According to a twelfth aspect of the present invention, pattern light corresponding to image data indicating an image to be drawn on a drawing target is generated by spatially modulating incident light by turning on and off a plurality of micromirrors, and the pattern light is An exposure drawing apparatus comprising: an exposure head that irradiates a drawing target; and a moving mechanism that moves a relative position of the drawing target with respect to the exposure head in a state where the pattern light is irradiated from the exposure head to the drawing target. An exposure drawing method for performing exposure drawing on the drawing object using a plurality of logical values corresponding to an on / off state of each of the plurality of micromirrors for each frame period based on the image data Generating first control data including: on each of the plurality of micromirrors based on the image data And generating first control data including a plurality of logical values corresponding to the on / off state of each micromirror for each frame period, and corresponding to the micromirror for at least one of the plurality of micromirrors A step of setting a virtual micromirror that forms at least one virtual virtual drawing point at a position different from the drawing point to be performed, and a portion corresponding to the virtual drawing point of the image indicated by the image data at the virtual drawing point Generating second control data including a plurality of logical values corresponding to the on / off state of each virtual micromirror for each frame period when drawing the virtual micromirror, and corresponding to the micromirror in which the virtual micromirror is set The logical value for each frame period in the first control data corresponds to the virtual micromirror. A control data correction unit that corrects a value obtained by performing a logical operation with a logical value of a corresponding frame period in the second control data; and the plurality of micromirrors based on the corrected first control data And a step of controlling on / off of the exposure drawing method.

  According to a thirteenth aspect of the present invention, there is provided a computer, wherein the control unit, the first control data generation unit, the virtual micromirror setting unit, the first control data generation unit according to any one of the first to twelfth aspects. There are provided a program for causing two control data generating units and the control data correcting unit to function.

  According to the exposure drawing apparatus, the exposure drawing method, and the program according to the present invention, the position of the edge of the image drawn on the drawing target can be controlled with high accuracy by a simple process.

It is a perspective view which shows the structure of the exposure drawing apparatus 1 which concerns on embodiment of this invention. It is a perspective view which shows the structure of DMD which concerns on embodiment of this invention. 2 is a plan view schematically showing an exit surface of an exposure head 30 according to an embodiment of the present invention. FIG. It is a perspective view which shows the aspect of exposure drawing in the exposure drawing apparatus which concerns on embodiment of this invention. It is a top view which shows the locus | trajectory of the exposure area in the to-be-exposed board | substrate exposed by the exposure drawing apparatus which concerns on embodiment of this invention. It is a functional block diagram which shows the functional structure of the exposure drawing apparatus which concerns on embodiment of this invention. It is a block diagram which shows the more detailed structure of the DMD control data generation part which concerns on embodiment of this invention. FIG. 8A and FIG. 8B are diagrams for explaining the first control data according to the embodiment of the present invention. It is a figure which shows an example of arrangement | positioning of the virtual drawing point which concerns on embodiment of this invention. It is a figure which shows an example of arrangement | positioning of the real micromirror and virtual micromirror which concern on embodiment to this invention. It is a figure which shows the form of 1st control data and 2nd control data. It is a block diagram which shows the hardware constitutions of the control system of the exposure drawing apparatus which concerns on embodiment of this invention. It is a flowchart which shows the flow of a process in the 1st control data generation process program which concerns on embodiment of this invention. It is a flowchart which shows the flow of a process in the correction process program which concerns on embodiment of this invention. FIG. 14A to FIG. 14C are diagrams showing one aspect of correction processing for increasing the line width of the drawing line according to the embodiment of the present invention. FIG. 15A to FIG. 15C are diagrams showing one aspect of correction processing for reducing the line width of the drawing line according to the embodiment of the present invention. It is a figure which shows an example of arrangement | positioning of a virtual drawing point.

  Hereinafter, an exposure drawing apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same or equivalent components and parts are denoted by the same reference numerals.

  FIG. 1 is a perspective view showing a configuration of an exposure drawing apparatus 1 according to an embodiment of the present invention. In the following, the moving direction of the stage 10 is defined as the Y direction, and the direction orthogonal to the Y direction on the horizontal plane is defined as the X direction.

  The exposure drawing apparatus 1 includes a flat stage 10 for fixing the substrate C to be exposed. A suction mechanism (not shown) having a plurality of suction holes for sucking air is provided on the upper surface of the stage 10 in a region where the substrate to be exposed C is placed. The substrate C to be exposed is vacuum-sucked by the suction mechanism and held on the stage 10 while being placed on the upper surface of the stage 10.

  Two guide rails 14 are provided on the upper surface of the base 11 along the Y direction. The stage 10 is supported so as to be movable along the Y direction on the guide rail 14 by a moving mechanism 46 (see FIG. 6) including a motor or the like. The exposed substrate C held on the stage 10 moves to the exposure position as the stage 10 moves, and the exposure unit 16 irradiates the light beam to draw an image such as a circuit pattern on the exposed surface.

  A gate 15 is provided on the upper surface of the base 11 so as to straddle the guide rail 14, and an exposure unit 16 is attached to the gate 15. The exposure unit 16 has a plurality of exposure heads 30 and is fixedly arranged on the moving path of the stage 10. In the present embodiment, the exposure unit 16 includes, for example, ten exposure heads 30 arranged in a matrix of 2 rows and 5 columns. Each of the exposure heads 30 is connected to an optical fiber 18 drawn from the light source unit 17 and a signal cable 20 drawn from the exposure head controller 19.

  A gate 22 is provided on the upper surface of the base 11 so as to straddle the guide rail 14. Two imaging units 23 for photographing the alignment mark of the substrate C to be exposed held on the stage 10 are attached to the gate 22. The photographing unit 23 is a CCD camera or the like having a built-in strobe with a very short light emission time. Each of the imaging units 23 is installed so as to be movable in a direction (X direction) perpendicular to the moving direction (Y direction) of the stage 10. When drawing an image on the substrate C to be exposed, the exposure drawing apparatus 1 measures the position of the alignment mark photographed by the photographing unit 23 and adjusts the drawing position based on the measured position of the alignment mark.

  Each of the exposure heads 30 has a digital micromirror device (DMD) 27 (see FIG. 2) as a reflective spatial light modulation element, and the DMD 27 is controlled by a control signal supplied from the exposure head control unit 19. A light beam emitted from the light source unit 17 is spatially modulated to generate pattern light shaped into a shape corresponding to image data indicating a drawing target image supplied from the outside. Each of the exposure heads 30 emits the generated pattern light from the exit surface of the exposure head 30 and irradiates the substrate C to be exposed. Each of the exposure heads 30 changes the pattern light for each predetermined frame period by driving the DMD 27 in accordance with a control signal supplied from the exposure head control unit 19. Thereby, exposure drawing of the image according to image data is performed to the to-be-exposed board | substrate C which moves along the Y direction with the stage 10. FIG.

  FIG. 2 is a perspective view showing the configuration of the DMD 27. The DMD 27 is configured as a mirror device in which a plurality of micromirrors M are arranged in a lattice pattern. Each of the rectangular micromirrors M is placed on an SRAM cell (memory cell) 28 made of a silicon gate CMOS or the like that temporarily stores on / off information corresponding to image data indicating an image to be drawn on the substrate C to be exposed. It is supported by a column including a hinge and a yoke (not shown). The surface of each micromirror M is made of a highly reflective material such as aluminum and forms a light reflecting surface.

  In the SRAM cell 28, a digital signal corresponding to the on state or the off state of each micromirror M generated based on the image data indicating the image to be drawn is written. The reflective surface of the micromirror M in the on state is tilted with the diagonal line as the rotation axis until one corner portion contacts the landing pad on the SRAM cell 28. On the other hand, the reflective surface of the micromirror M in the off state is tilted with the diagonal line as the rotation axis until the corner facing the one corner contacts the other landing pad.

  The light beam reflected by the micromirror M in the on state is emitted from the exit surface of the exposure head 30 via an optical system (not shown). In this way, pattern light corresponding to the image is generated by controlling the inclination (on / off) of each micromirror M based on the image data indicating the image to be drawn.

  FIG. 3 is a plan view schematically showing the emission surface 30 a of the exposure head 30. From the exit surface 30a of each exposure head 30, a plurality of light beams 31 reflected by each of the micromirrors M that are turned on in the rectangular beam exit area 32 are emitted. As shown in FIG. 3, each exposure head 30 is installed such that a rectangular beam emission area 32 is inclined by a predetermined angle with respect to the moving direction of the stage 10. That is, the arrangement direction of the light beams 31 forming the drawing point is inclined with respect to the moving direction of the stage 10.

  FIG. 4 is a perspective view showing an exposure drawing mode in the exposure drawing apparatus 1 according to the present embodiment. FIG. 5 is a plan view showing the trajectory of the exposure area in the substrate C to be exposed that is exposed by the exposure drawing apparatus 1 according to the present embodiment. As shown in FIGS. 4 and 5, the exposure area 33 formed by the light beam emitted from each exposure head 30 has a rectangular shape inclined with respect to the moving direction (Y direction) of the stage 10. As the stage 10 moves, a plurality of strip-shaped exposed areas 34 corresponding to the plurality of exposure heads 30 are formed on the exposed surface of the substrate C to be exposed.

  The strip-shaped exposed area 34 is formed by a plurality of light beams 31 (see FIG. 3) arranged two-dimensionally on the emission surface 30a of each exposure head 30. Further, by inclining the beam emission area 32 with respect to the moving direction of the stage 10 as described above, the interval between the light beams 31 in the direction (X direction) orthogonal to the moving direction of the stage 10 can be made narrower. High resolution can be achieved. In the exposure drawing apparatus 1 according to the present embodiment, a drawing line having the minimum width in the image data is drawn by a plurality of (for example, three) light beams 31. Note that there may be dots that are not used due to variations in the adjustment of the tilt angle. For example, in FIG. 3, the hatched light beam 31 is not used, and the micromirror corresponding to the light beam 31 is always in the OFF state.

  Also, as shown in FIGS. 4 and 5, each of the strip-shaped exposed areas 34 is in a direction (X direction) orthogonal to the moving direction of the stage 10 so as to partially overlap the adjacent exposed areas 34. Each of the exposure heads 30 in each row arranged along the line is arranged at a predetermined interval in the X direction. For this reason, for example, a portion that cannot be exposed between the exposure area 33A located on the leftmost side of the first row and the exposure area 33C located on the right side thereof is exposed by the exposure area 33B located on the leftmost side of the second row. Is done. Similarly, a portion that cannot be exposed between the exposure area 33B and the exposure area 33D located on the right side of the exposure area 33B is exposed by the exposure area 33C.

  FIG. 6 is a functional block diagram showing a functional configuration of the exposure drawing apparatus 1 according to the embodiment of the present invention. In addition to the stage 10 and the exposure head 30 described above, the exposure drawing apparatus 1 includes a raster conversion processing unit 42, a DMD control data generation unit 50, an exposure head control unit 19, an instruction input unit 60, a moving mechanism 46, and a controller 44. It is out.

  The exposure drawing apparatus 1 acquires vector-format image data representing an image to be drawn on the substrate C to be output, which is output from a data creation apparatus 40 having a CAM (Computer Aided Manufacturing) station. The exposure drawing apparatus 1 generates pattern light according to the image data in the exposure head 30 based on the image data acquired from the data creation apparatus 40 and holds the pattern light on the stage 10 from each of the exposure heads 30. The exposed substrate C is irradiated. Under the control of the controller 44, the pattern light emitted from the exposure head 30 is updated every predetermined frame period so as to be interlocked with the movement of the stage 10 by the moving mechanism 46.

  The vector format image data output from the data creation device 40 is input to the raster conversion processing unit 42. The raster conversion processing unit 42 converts vector-format image data into raster-format image data. The raster conversion processing unit 42 supplies raster format image data to the DMD control data generation unit 50.

  The DMD control data generation unit 50 generates DMD control data for controlling on / off of each micromirror M of the DMD 27 provided in each exposure head 30 based on the raster format image data.

  FIG. 7 is a block diagram showing a more detailed configuration of the DMD control data generation unit 50. The DMD control data generation unit 50 includes a first control data generation unit 51, a virtual micromirror setting unit 52, a second control data generation unit 53, and a control data correction unit 54.

  The first control data generation unit 51 turns on / off these micromirrors M constituting the DMD 27 provided in each exposure head 30 based on the raster format image data supplied from the raster conversion processing unit 42. A process of generating first control data indicating timing is performed.

  The first control data will be described below with reference to FIGS. 8 (a) and 8 (b). Here, when an “F” -shaped image as shown in FIG. 8A is exposed and drawn using a plurality of (for example, 1024 × 1024) micromirrors M provided in a single exposure head 30. Will be described as an example. 8A and 8B, only nine micromirrors M1 to M9 and nine drawing points P1 to P9 corresponding to these are shown as representatives for easy understanding. Has been. In the following description, only the micromirrors M1 to M9 and the corresponding drawing points P1 to P9 are mentioned.

  When exposure drawing is performed, as the stage 10 moves, the drawing points P1 to P9 corresponding to the micromirrors M1 to M9 are on the left side in the drawing with respect to the exposed substrate C as shown in FIG. It moves from the right to the right. As shown in FIG. 3, the arrangement direction of the light beam 31 in the exposure head 30 is inclined with respect to the movement direction of the stage 10, and therefore the arrangement direction of the drawing points P1 to P9 is also the movement direction of the stage 10 (drawing point S1). ~ S9 traveling direction). At each drawing point P1 to P9, a light beam is emitted at a timing according to the arrangement, whereby a desired image can be exposed and drawn.

  When the first control data generating unit 51 receives image data indicating an “F” -shaped image as illustrated in FIG. 8A from the raster conversion processing unit 42, the first control data generating unit 51 corresponds to the drawing points P1 to P9. The on / off timing of the mirrors M1 to M9 is obtained by calculation, and the first control data having a form as shown in FIG. 8B is generated. That is, the first control data is data indicating the on / off state of the micromirrors M1 to M9 for each frame period. In FIG. 8B, the blacked-out portion corresponds to the on state of the micromirror, and the white portion corresponds to the off state of the micromirror. According to the first control data shown in FIG. 8B, for example, the micromirrors M1 and M9 are always driven in the off state over the frame periods F1 to F16, and the micromirror M3 is driven in the on state in the frame period F9. Then, the micromirror M5 is driven to the on state over the frame periods F6 to F10. By turning on / off the micromirrors M1 to M9 at such timing, an “F” -shaped image as shown in FIG. 8A is exposed and drawn. The first control data generation unit 51 turns on / off each micromirror M1 to M9 for each frame period based on the coordinate positions of the micromirrors M1 to M9 stored in advance, the moving speed of the stage 10 and the input image data. The first control data is generated by calculating the state.

  Here, the position of the edge of the drawing line on the image data may not match the position of the edge of the drawing line that is actually exposed and drawn. In the exposure drawing apparatus 1 according to the present embodiment, the mirror control data correction unit 54 corrects the first control data based on the second control data generated by the second control data generation unit 53. It is possible to correct the edge position of the drawing line by increasing or decreasing the line width of the drawing line that is actually exposed and drawn.

  The instruction input unit 60 receives an instruction input for increasing or decreasing the line width of a drawing line to be exposed and drawn from the current state. In addition, the instruction input unit 60 receives an instruction input that instructs the correction amount (increase amount and decrease amount) of the line width of the drawing line. The instruction input unit 60 includes a user interface such as a keyboard, a mouse, and a GUI for receiving the instruction input, and notifies the controller 44 of the received instruction input.

  The contents of the instruction input are notified to the DMD control data generation unit 50 via the controller 44. When the virtual micromirror setting unit 52 is notified from the controller 44 that an instruction input for increasing or decreasing the line width of the drawing line has been received, the micromirror M configuring the DMD 27 provided in each exposure head 30. A virtual micromirror that is a virtual micromirror is set for each of the above. That is, the virtual micromirror setting unit 52 virtually arranges virtual micromirrors with respect to each micromirror M constituting the DMD.

FIG. 9 illustrates an arrangement of drawing points corresponding to any one actual micromirror and virtual drawing points corresponding to the virtual micromirror set by the virtual micromirror setting unit 52. As illustrated in FIG. 9, the virtual micromirror setting unit 52 is configured so that four virtual drawing points P _{V1 to} P _V4 are formed around the drawing point P corresponding to the actual micromirror. Four virtual micromirrors respectively corresponding to the virtual drawing points P _{V1 to} P _V4 are set around. For example, as illustrated in FIG. 9, the virtual micromirror setting unit 52 moves the stage 10 with the drawing points P corresponding to the actual micromirrors between the virtual drawing points P _V2 and P _V4 (Y direction). Virtual virtual mirrors corresponding to the virtual drawing points P _V2 and P _V4 are set so that the virtual drawing points P _V1 and P _V3 are in between the drawing points P corresponding to the existing micromirrors. Virtual micromirrors respectively corresponding to the virtual drawing points P _V1 and P _V3 are set so as to be arranged along the direction (X direction) orthogonal to the moving direction of the stage 10 sandwiched therebetween.

Figure 10 is a micro-mirror _{M R} real responsible for rendering point P shown in FIG. 9, in diagram illustrating the arrangement of the virtual micro-mirror _M V1 _{~M V4} respectively corresponding to the virtual drawing point _P V1 _{to P V4} is there. As shown in FIG. 10, the virtual micromirrors M _{V1 to} M _V4 can be set at positions deviating from the arrangement of the micromirrors constituting the DMD 27.

Further, the virtual micromirror setting unit 52 sets the drawing point P and the virtual drawing points P _{V1 to} P _V4 according to the correction amount (increase or decrease) of the line width of the drawing line input to the instruction input unit 60. The distance L between them is changed. Specifically, the virtual micromirror setting unit 52 increases the distance L between the drawing point P and the virtual drawing points P _{V1 to} P _{V4 as} the line width of the drawing line increases or decreases. As described above, the arrangement of the virtual micromirrors corresponding to the virtual drawing points P _{V1 to} P _V4 is determined. Note that the distance L between the drawing point P and the virtual drawing points P _{V1 to} P _V4 may be the same or different from each other. In the present embodiment, the virtual micromirror setting unit 52 sets virtual micromirrors for all the micromirrors M constituting the DMD 27 provided in each exposure head 30. The virtual micromirror setting unit 52 notifies the second control data generation unit 53 of the set coordinate position of the virtual micromirror.

  The second control data generation unit 53 uses the virtual micromirrors set by the virtual micromirror setting unit 52 and the virtual micromirrors set by the virtual micromirror setting unit based on the raster-format image data. The second control data indicating these on / off timings is generated. That is, the second control data generation unit 53 sets the on / off state for each frame period of the virtual micromirror when drawing the portion corresponding to the virtual drawing point of the image indicated by the image data at the virtual drawing point. Second control data to be shown is generated. That is, the second control data is data indicating on / off timing to be set for the virtual micromirror based on the image data when the virtual micromirror is actually present. Therefore, if the coordinate position of the virtual micromirror (or virtual drawing point) is determined, the second control data can be calculated based on the image data.

  When the control data correction unit 54 is notified from the controller 44 that an instruction input to increase or decrease the line width of the drawing line has been received, the control data correction unit 54 sends the first control data for each micromirror to the micromirror. Correction is performed using the second control data for the virtual micromirror set in the above.

Here, FIG. 11, a first control data generated for the micro-mirror M _R of the real any one, for each of the micro mirrors M virtual four set for _R micromirror M _V1 ~M _V4 It is a figure which shows the form of the produced | generated 2nd control data. The four virtual micromirrors M _{V1 to} M _V4 correspond to the virtual drawing points P _{V1 to} P _V4 shown in FIG. The first control data is a frame period F1, F2, F3, F4, the data element corresponding to the state of the on-off of the micromirror _{M R} of the real each _{··· D 1, D 2, D} 3, D 4, ·・ Includes. That is, the data elements D ₁ to D _4, the logic value indicating a logical value "1" or off indicating the on-state of the micromirror M _R of the real "0" is set by the first control data generating unit 51 The

The second control data includes data elements D _1-1 and D _2-1 corresponding to the on / off states of the virtual micromirrors M _{V1 to} M _V4 for each frame period F1, F2, F3, F4,. _{, D 3-1, D 4-1 ···;} D 1-2, D 2-2, D 3-2, D 4-2 ···; D 1-3, D 2-3, D 3- ₃ , D _4-3 ...; D _1-4 , D _2-4 , D _3-4 , D _4-4 . That is, in the data elements D _{1-1 to} D _4-1 , the logical value “1” indicating the on state of the virtual micromirror M _V1 or the logical value “0” indicating the off state is the second control data generation unit 53. Set by Similarly, data element _{D 1-2 ~D 4-2, D 1-3 ~D} 4-3, the D 1-4 _{to D 4-4,} on virtual micromirror _{M V2, M V3, M V4} The logical value “1” indicating the state or the logical value “0” indicating the off state is set by the second control data generation unit 53.

When the control data correction unit 54 is notified from the controller 44 that the instruction input to increase the line width of the drawing line has been received, the data elements D ₁ , D ₂ , D ₃ , and the like constituting the first control data D ₄ ,... And data elements D _1-1 , D _2-1 , D _3-1 , D _4-1 ... Constituting the second control data; D _1-2 , D _2-2. , D _3-2 , D _4-2 ...; D _1-3 , D _2-3 , D _3-3 , D _4-3 ...; D _1-4 , D _2-4 , D _{3- 4,} the logical sum of the D 4-4 _{· · ·} calculated for each frame period, the data elements of the DMD control data the calculated value indicating the on-off timing of the micromirror M _R after correction. Specifically, the control data correction unit 54, the increase in the line width of the drawing line is indicated, the data elements D ₁ of the frame period F1 in the first control data, the frame period F1 in the second control data data elements _{D 1-1, D 1-2, D 1-3} , and calculates the logical sum of the _{D 1-4.} Control data correction unit 54, the data elements of the micro-mirror M _R a value obtained by such logical OR operation in the frame period F1. Similarly, the control data correction unit 54 obtains values obtained by performing a logical sum operation of each data element in the other frame periods F2, F3, F4,..., Respectively, in the frame periods F2, F3, F4,. the data elements of the micro-mirror _{M R} in .... Control data correcting unit 54 supplies the set of data elements in each frame period of the micro-mirror M _R obtained in this manner, downstream of the exposure head control unit 19 as the DMD control data.

On the other hand, when the control data correction unit 54 is notified from the controller 44 that an instruction input for reducing the line width of the drawing line has been received, the data elements D ₁ , D ₂ , D constituting the first control data are received. ₃ , D ₄ ,... And data elements D _1-1 , D _2-1 , D _3-1 , D _4-1 ... Constituting the second control data; D _1-2 , D _{2 -2} , _D3-2 , _D4-2 ...; _D1-3 , _D2-3 , _D3-3 , _D4-3 ...; _D1-4 , _D2-4 , D _3-4, calculated for each frame period a logical product of the _D 4-4 _{· · ·,} the data elements of the DMD control data indicating the on-off timing of the micromirror M _R after correcting the calculated value. Specifically, the control data correction unit 54, the reduction of the line width of the drawing line is indicated, the data elements D ₁ of the frame period F1 in the first control data, the frame period F1 in the second control data The logical product of the data elements D _1-1 , D _1-2 , D _1-3 , and D _1-4 is calculated. Control data correction unit 54, the data elements of the micro-mirror M _R a value obtained by such logical AND operation in the frame period F1. Similarly, the control data correction unit 54 obtains values obtained by performing a logical product operation of each data element in the other frame periods F2, F3, F4,..., Respectively, in the frame periods F2, F3, F4,. the data elements of the micro-mirror _{M R} in .... The control data correction unit 54 supplies the set of data elements for each frame period thus obtained to the subsequent exposure head control unit 19 as DMD control data.

  As described above, the control data correction unit 54 calculates each data element of the first control data by each logical value obtained by performing a logical operation on the first control data and the second control data for each data element. to correct. The DMD control data generation unit 50 corrects the first control data generated by the first control data generation unit 51 when there is no instruction input for increasing or decreasing the line width of the drawing line. Instead, it is supplied as DMD control data to the exposure head controller 19 at the subsequent stage.

  The exposure head controller 19 controls the DMD 27 provided in each exposure head 30 based on DMD control data indicating the on / off timing of each micromirror M supplied from the DMD control data generator 50 under the control of the controller 44. The on / off of each micromirror M is controlled.

  The controller 44 receives the above-described instruction input from the instruction input unit 60 and supplies control signals to the raster conversion unit 42, the moving mechanism 46, the DMD control data generation unit 50, and the exposure head control unit 19. Overall control of the operation timing and the like.

  In the present embodiment, the raster conversion processing unit 42, the DMD control data generation unit 50, the exposure head control unit 19, and the controller 44 are a CPU 201 and a ROM 202 that stores various programs executed by the CPU 201 as shown in FIG. (Read Only Memory), a RAM (Random Access Memory) 203 that temporarily stores data and the like used for arithmetic processing in the CPU 201, and an HDD 204 that stores various data and the like. Has been.

  FIG. 13 is a flowchart showing the flow of processing in the first control data generation processing program executed when the CPU 201 functioning as the DMD control data generation unit 50 generates the first control data. The first control data generation program is stored in advance in the ROM 202, and is executed, for example, when the user performs a predetermined input operation on the instruction input unit 60 when exposure drawing is started.

  In step S <b> 10, the CPU 201 captures the image data of the drawing target image converted into the raster format into the RAM 203.

In step S11, CPU 201 selects the micro mirror _{M i} for which to generate the first control data. Here, i is an identification number of the micromirror.

In step S12, CPU 201 indicates the coordinate position of the micro mirror _{M i} selected in step S11, based on the image data captured in the RAM203 In step S10, the state of the on-off of each frame period of the micro-mirror _{M i,} First control data having a form as shown in FIG. 8B or FIG. 11 is generated and stored in the HDD 204.

  In step S13, the CPU 201 determines whether or not the value of i, which is the identification number of the micromirror, matches the predetermined value a. If the determination is affirmative, the CPU 201 ends the routine, and if the determination is negative. Shifts the processing to step S14. In the present embodiment, the predetermined value a is equal to the number of micromirrors constituting the DMD 27, but is not limited to this.

  In step S14, the CPU 201 increments the value of i by one and returns the process to step S11. By repeating the processes of steps S11 to S14, the first control data is generated for all the micromirrors M constituting the DMD 27 and stored in the HDD 204.

  Note that when performing exposure drawing on the substrate C to be exposed based on the first control data, the CPU 201 starts moving the stage 10 by supplying a control signal to the moving mechanism 46, and The CPU 201 functions as the exposure head control unit 19, reads the first control data from the HDD 204, and each micromirror of the DMD 27 provided in each exposure head 30 at the on / off timing indicated by the first control data. Control on / off of M. Thereby, pattern light corresponding to the drawing pattern is emitted from each exposure head 30 so as to be linked to the movement of the stage 10, and an image is drawn on the exposed surface of the substrate C to be exposed held on the stage 10.

  FIG. 14 is a flowchart illustrating a processing flow in a correction processing program executed when the CPU 201 functioning as the DMD control data generation unit corrects the line width of the drawing line based on an instruction input to the instruction input unit 60. . The correction processing program is stored in advance in the ROM 202, and is executed, for example, when the user performs a predetermined input operation on the instruction input unit 60. Prior to the execution of the correction processing program, the first control data generation processing program is executed, and the HDD 204 stores the first control data for each micromirror M.

  In step S <b> 20, the CPU 201 stores the content of the instruction input received by the instruction input unit 60 in the RAM 203. Specifically, the CPU 201 stores in the RAM 203 information indicating the increase or decrease of the line width received by the instruction input unit 60 and information indicating the correction amount (increase or decrease amount) of the line width.

In step S21, The CPU 201 selects the micro mirror _{M i} corresponding to the first control data to be corrected processed. Here, i is an identification number of the micromirror.

In step S22, CPU 201, for micro mirror _{M i} selected in step S20, as shown in FIG. 9, the micro-mirror _M 4 single virtual drawing point around the drawing point P corresponding to the _{i P} V1 _{to P V4} is The virtual micromirrors M _{V1 to} M _V4 are set (virtual arrangement) so as to be formed. CPU201 the virtual drawing point _{P V2} and _{P V4} are virtual micromirror _{M V2} and so as to be arranged along the moving direction of the stage 10 in between the drawing point P corresponding to the micromirror _{M i} (Y-direction) sets the M _V4, virtual drawing point P _V1 and P _V3 is, virtual micromirrors so as to be arranged along the direction (X direction) perpendicular to the moving direction of the stage 10 in between the micro mirror M _i M Set _V1 and _MV3 . The CPU 201 increases the distance L between the drawing point P and the virtual drawing points P _{V1 to} P _V4 as the line width correction amount (increase or decrease) stored in the RAM 203 in step S20 increases. Then, the arrangement of the virtual micromirrors M _{V1 to} M _V4 is calculated. The CPU 20 stores the coordinate positions of the virtual micromirrors M _{V1 to} M _V4 set in this way in the RAM 203.

In step S23, CPU 201 based on the image data to be drawn image converted to the coordinate position and raster format of the virtual micro-mirror _M V1 _{~M V4} stored in RAM 203, for each of the virtual micro-mirror _M V1 _{~M V4} Second control data indicating these on / off timings is generated. That is, the CPU 21 draws portions corresponding to the virtual drawing points P _{V1 to} P _V4 of the drawing target image indicated by the image data at the virtual drawing points P _{V1 to} P _V4 corresponding to the virtual micromirrors M _{V1 to} M _V4 , respectively. Second control data indicating the on / off state for each frame period of the virtual micromirrors M _{V1 to} M _V4 is generated. The CPU 201 stores the generated second control data in the HDD 204.

  In step S <b> 24, the CPU 201 determines whether the content of the instruction input received by the instruction input unit 60 is an increase or a decrease in line width. When the content of the instruction input is an increase in the line width, the CPU 201 proceeds to step S25, and when the content of the instruction input is a decrease in the line width, the process proceeds to step S26.

In step S25, the CPU 201 reads the first control data and the second control data from the HDD 204, and as described above, the logical value obtained by the logical sum operation of the first control data and the second control data. by correcting the respective data elements of the first control data for the micro mirror M _i. The CPU 201 stores the first control data corrected in this way in the HDD 204.

In step S26, the CPU 201 reads the first control data and the second control data from the HDD 204, and as described above, the logical value obtained by the logical product operation of the first control data and the second control data. by correcting the respective data elements of the first control data for the micro mirror M _i. The CPU 20 stores the first control data corrected in this way in the HDD 204.

  In step S27, the CPU 201 determines whether or not the value of i, which is the identification number of the micromirror, matches the predetermined value a. If the determination is negative, the process proceeds to step S28, where the positive determination is made. If so, the process proceeds to step S29. In the present embodiment, the predetermined value a is equal to the number of micromirrors constituting the DMD 27, but is not limited to this.

  In step S28, the CPU 201 increments the value of i by one and returns the process to step S21. By repeating the processes of steps S21 to S28, the correction process of the first control data is performed for all the micromirrors constituting the DMD 27.

  In step S <b> 29, the CPU 201 supplies the corrected first control data for each micromirror stored in the HDD 204 to the exposure head controller 19 as DMD control data. The CPU 201 functioning as the exposure head controller 19 controls on / off of each micro mirror of the DMD 27 provided in each exposure head 30 based on the DMD control data. Thereby, a drawing line whose line width is increased or decreased from the beginning is drawn by the exposure head 30.

  FIG. 15A to FIG. 15C are diagrams illustrating one mode of correction processing for increasing the line width of the drawing line.

In the example shown in FIG. 15 (a), if the first control data to be turned on over a frame period F5~F8 the micro-mirror M _R of the real is generated is shown. As in the present embodiment, the virtual drawing point P _V2 and P _V4 along the moving direction (Y direction) of the stage 10 in between the drawing point P corresponding to the micromirror M _R of the existent sequence (FIG. 9 See: Virtual micromirrors M _V2 and M _V4 are set. Here, in order to facilitate understanding, virtual micromirrors corresponding to virtual drawing points P _V1 and P _V2 arranged along the X direction are not considered.

As shown in FIG. 9, on-off timing of the virtual micro-mirror M _V2 to form a forward advancing direction in a virtual drawing point P _V2 drawing point P by the micro-mirror M _R of the real is preceding than the micro mirror M _R . In the example shown in FIG. 15 (a), the virtual on-off timing of the micro-mirror M _V2 is, if you are ahead by one frame period than the micromirrors M _R of the real is shown. On the other hand, as shown in FIG. 9, on-off timing of the virtual micro-mirror M _V4 forming the drawing points P _V4 in the traveling direction behind the drawing point P by the micro-mirror M _R of the real, rather than the micro-mirror M _R delay To do. In the example shown in FIG. 15 (a), the virtual on-off timing of the micro-mirror M _V4 is, if you are delayed by one frame period than the micromirrors M _R of the real is shown.

In this case, when an instruction to increase the line width of the drawing line is given, as described above, the first control data is obtained by the value obtained by the logical sum operation of the first control data and the second control data. Is corrected. That is, in the example shown in FIG. 15 (a), the first control data is corrected so as to be turned on micromirror M _R is over a frame period F4～F9. Thus, since the ON period of the micro-mirror M _R is longer than the pre-correction process, the line width of the drawing line in the moving direction (Y direction) of the stage 10 is increased.

On the other hand, in the example shown in FIG. 15 (b), it shows a case where the first control data to be turned off for the micro-mirror M _R of the real over the entire frame period is generated. In the present embodiment, so that the virtual recording points P _V1 and P _V3 along the direction (X direction) perpendicular to the moving direction of the stage 10 in between the drawing point P corresponding to the micromirror M _R of the existent sequence (See FIG. 9), virtual micromirrors M _V1 and M _V3 are set. Here, in order to facilitate understanding, virtual micromirrors corresponding to the virtual drawing points P _V2 and P _V4 arranged along the moving direction (Y direction) of the stage 10 are not considered.

In the example shown in FIG. 15 (b), to form a virtual drawing point _{P V1} above the writing point P corresponding to the micromirror _{M R} real (see FIG. 9) in the frame period F4~F8 the virtual micro-mirror _{M V1} The case where the 2nd control data which should be made into an ON state over is produced | generated is shown. This means that the drawing lines extending along the moving direction of the stage 10 above the moving locus of the drawing points P by the micro-mirror M _R is present. In this case, when an instruction to increase the line width of the drawing line is given, as described above, the first control data is obtained by the value obtained by the logical sum operation of the first control data and the second control data. Is corrected. That is, in the example shown in FIG. 15 (b), the first control data is corrected so as to be turned on micromirror M _R is over a frame period F4～F8. Accordingly, the line width of the drawing lines extending along the moving direction of the stage 10 above the moving locus of the drawing points P by the micro mirror M _R is increased in the direction (X direction) perpendicular to the moving direction of the stage 10 .

On the other hand, in the example shown in FIG. 15 (c), under the drawing point P corresponding to the micromirror _{M R} of the real form a virtual drawing point _{P V3} (see FIG. 9) frame period for virtual micromirror _{M V3 F4~} The case where the 2nd control data which should be made into an ON state over F8 is shown is shown. This means that the drawing lines extending along the moving direction of the stage 10 under the movement locus of the drawing points P by the micro-mirror M _R is present. In this case, when an instruction to increase the line width of the drawing line is given, as described above, the first control data is obtained by the value obtained by the logical sum operation of the first control data and the second control data. Is corrected. That is, in the example shown in FIG. 15 (c), the first control data is corrected so as to be turned on micromirror M _R is over a frame period F4～F8. Accordingly, the line width of the drawing lines extending along the moving direction of the stage 10 below the movement locus of the drawing point P by the micro mirror M _R is increased in the direction (X direction) perpendicular to the moving direction of the stage 10 .

  FIG. 16A to FIG. 16C are diagrams illustrating one mode of correction processing for reducing the line width of the drawing line.

In the example shown in FIG. 16 (a), if the first control data to be turned on over a frame period F5~F8 the micro-mirror M _R of the real is generated is shown. As in the present embodiment, the virtual drawing point P _V2 and P _V4 along the moving direction (Y direction) of the stage 10 in between the drawing point P corresponding to the micromirror M _R of the existent sequence (FIG. 9 See: Virtual micromirrors M _V2 and M _V4 are set. Here, in order to facilitate understanding, virtual micromirrors corresponding to virtual drawing points P _V1 and P _V2 arranged along the X direction are not considered.

As shown in FIG. 9, on-off timing of the virtual micro-mirror M _V2 to form a forward advancing direction in a virtual drawing point P _V2 drawing point P by the micro-mirror M _R of the real, rather than micro-mirror M _R of the real leading To do. In the example shown in FIG. 16 (a), on-off timing of the virtual micro-mirror M _V2 is, if you are ahead by one frame period than the micromirrors M _R of the real is shown. On the other hand, on-off timing of the virtual micro-mirror M _V4 forming the drawing points P _V4 in the traveling direction behind the drawing point P by the micro-mirror M _R of the real is delayed than the micro-mirror M _R real. In the example shown in FIG. 16 (a), on-off timing of the virtual micro-mirror M _V4 is, if you are delayed by one frame period than the micromirrors M _R of the real is shown.

In this case, when the reduction of the line width of the drawing line is instructed, the first control data is obtained by the value obtained by the logical product operation of the first control data and the second control data as described above. It is corrected. That is, in the example shown in FIG. 16 (a), the first control data to the micro-mirror M _R is only turned on in the frame period F6 and F7 are corrected. Accordingly, the on period of the micro-mirror M _R is shorter than the pre-correction process, the line width of the drawing lines is reduced in the direction of movement of the stage 10 (Y-direction).

Thus, a virtual micro-mirrors corresponding to the virtual drawing point P _V2 and P _V4 are arranged along the moving direction of the stage 10 in between the drawing point P corresponding to the micromirror M _R real (Y-direction) M _V2 and M _V4 contribute to an increase or decrease in the line width of the drawing line in the moving direction (Y direction) of the stage 10. Further, by increasing the distance L between the drawing point P and the virtual drawing point P _V2 and P _V4, large displacement amount of off timing of the micro-mirror M _R of the real and virtual micromirror M _V2 and M _V4 becomes, as a result, while the oN period of the micro-mirror M _R defined by the logical OR operation is longer, since the oN period of the micro-mirror M _R defined by the logical AND operation becomes shorter, the correction amount of the line width of the drawing lines Become bigger.

On the other hand, in the example shown in FIG. 16 (b), when the first control data to be turned on over a frame period F4~F8 the micro-mirror M _R of the real is generated is shown. In the present embodiment, as the drawing point P _V1 and P _V3 along the direction (X direction) perpendicular to the moving direction of the stage 10 in between the drawing point P corresponding to the micromirror M _R of the existent sequence Virtual micromirrors M _V1 and M _V3 are set. Here, in order to facilitate understanding, virtual micromirrors corresponding to the virtual drawing points P _V2 and P _V4 arranged along the moving direction (Y direction) of the stage 10 are not considered.

In the example shown in FIG. 16 (b), above the writing point P corresponding to the micromirror _{M R} of the real form a virtual drawing point _{P V1} (see FIG. 9) in the frame period F4~F8 the virtual micro-mirror _{M V1} over the second control data to be turned on is generated, the off over the entire frame period for virtual micromirror M _V3 forming the draw point P _V3 under the drawing point P corresponding to the micromirror M _R of the real state The case where the 2nd control data which should be taken is generated is shown. It is present drawing line extending along the moving direction of the stage 10 above the moving locus of the drawing points P by the micro-mirror M _R, of draw down of the movement locus of the drawing point P by the micro-mirror M _R is It means not existing. In this case, when the reduction of the line width of the drawing line is instructed, as described above, the first control data is obtained by the value obtained by the logical product operation of the first control data and the second control data. Is corrected. That is, in the example shown in FIG. 16 (b), the first control data is corrected so that the micro-mirror M _R is turned off over the entire frame period. Thus, the direction line width of the drawing lines extending along the movement direction (Y direction) of the stage 10 above the moving locus of the drawing points P corresponding to the micro mirror M _R is, perpendicular to the moving direction of the stage 10 ( In the X direction).

On the other hand, in the example shown in FIG. 16 (c), to form a virtual drawing point P _V1 above the writing point P corresponding to the micromirror M _R real (see FIG. 9) in the entire frame period for a virtual micro-mirror M _V1 second control data to be the oFF state is produced, under the drawing point P corresponding to the micromirror M _R of the real form a virtual drawing point P _V3 (see FIG. 9) for the virtual micromirror M _V3 frame over The case where the 2nd control data which should be made into an ON state over period F4-F8 is shown. It is present drawing line extending along the moving direction of the stage 10 under the moving locus of the drawing points P by the micro-mirror M _R, strokes above the moving locus of the drawing points P by the micro-mirror M _R is It means not existing. In this case, when the reduction of the line width of the drawing line is instructed, as described above, the first control data is obtained by the value obtained by the logical product operation of the first control data and the second control data. Is corrected. That is, in the example shown in FIG. 16 (c), the first control data is corrected so that the micro-mirror M _R is turned off over the entire frame period. Accordingly, the line width of the drawing lines extending along the movement direction (Y direction) of the stage 10 below the movement locus of the drawing point P by the micro-mirror M _R is orthogonal directions (X direction and the moving direction of the stage 10 ).

Thus, corresponding to a virtual drawing point P _V1 and P _V3 are arranged along a direction (X direction) perpendicular to the moving direction of the stage 10 in between the drawing point P corresponding to the micromirror M _R of the real The virtual micromirrors M _V1 and M _V3 that contribute to the increase and decrease of the line width of the drawing line in the direction (X direction) orthogonal to the moving direction of the stage 10. Further, by increasing the distance L between the drawing point P and the virtual drawing point P _V1 and P _V3, the line width of the drawing lines located above or below the movement locus of the drawing point P by the micro-mirror M _R The correction amount becomes larger.

  As is clear from the above description, in the exposure drawing apparatus 1 according to the embodiment of the present invention, the first control data generation unit 51 determines the on / off timing for each micromirror based on the input image data. First control data is generated. The exposure head controller 19 controls the on / off of each micromirror based on the first control data, thereby forming a beam spot at an appropriate timing at each drawing point projected on the substrate C to be exposed. . Thereby, it is possible to perform exposure drawing according to image data. In addition, since the drawing line having the minimum line width in the image data is drawn by a plurality of drawing points corresponding to the plurality of micromirrors, high resolution can be achieved.

According to the exposure drawing apparatus 1 according to the embodiment of the present invention, when the edge position of the drawing line that is actually exposed and drawn does not match the edge position of the drawing line on the image data, the user inputs the instruction input unit 60. From this, it is possible to instruct to increase or decrease the line width of the drawing line. When the increase / decrease of the line width of the drawing line is instructed, the virtual micromirror setting unit 52 sets the virtual micromirrors M _{V1 to} M _V4 for each of the micromirrors constituting the DMD 27. As shown in FIG. 9, the virtual micromirror setting unit 52 arranges virtual drawing points P _V2 and P _V4 along the moving direction (Y direction) of the stage 10 with the drawing point P by the micromirror interposed therebetween. In this way, the virtual micromirrors M _V2 and M _V4 are set as described above, and the virtual drawing points P _V1 and P _V along the direction (X direction) perpendicular to the moving direction of the stage 10 with the drawing point P by the micromirror interposed therebetween. _The virtual micromirrors M _V1 and M _V3 are set so that _V3 is arranged. The second control data generation unit 53 generates second control data that determines the on / off timing of each of the set virtual micromirrors M _{V1 to} M _V4 . The control data correction unit 54 corrects the first control data with a value calculated by a logical operation with the second control data. Thus, according to the exposure drawing apparatus 1 which concerns on embodiment of this invention, it is possible to control the position of the edge of the image drawn on the to-be-exposed board | substrate C with high precision by simpler processing. Moreover, according to the exposure drawing apparatus 1 which concerns on embodiment of this invention, it is possible to correct the line width of a drawing line in a unit smaller than the minimum line width of the drawing line which can be expressed on image data, The edge position can be adjusted with high accuracy.

In the above embodiment, the case where four virtual micromirrors M _{V1 to} M _V4 are set for one micromirror is illustrated, but the number of virtual micromirrors set for one micromirror is appropriately increased or decreased. Is possible. For example, in the case where line width correction is unnecessary in the direction (X direction) orthogonal to the moving direction of the stage 10, the moving direction (Y) of the stage 10 with the drawing point P corresponding to the actual micromirror interposed therebetween It is only necessary to set two virtual micromirrors so that virtual drawing points are arranged along (direction). In the above-described embodiment, as shown in FIG. 9, the virtual drawing point is perpendicular to the moving direction (Y direction) of the stage 10 with the drawing point P corresponding to the actual micromirror interposed therebetween. Although the case where the virtual micromirror is set so that the virtual drawing points are arranged in the direction (X direction) is illustrated, the virtual micromirror is set so that the virtual drawing points are arranged in directions other than the X direction and the Y direction. Also good. For example, four or more virtual micromirrors may be set on the circumference of a circle centered on an actual micromirror.

When the line width correction amount is large, as shown in FIG. 17, a virtual drawing point P _V5 is further provided between the virtual drawing points P _V2 and P _V4 arranged along the Y direction and the drawing point P. And P _V6 are set, and virtual drawing points P _V7 and P _V8 are further provided between the virtual drawing points P _V1 and P _V3 and the drawing point P arranged along the X direction. A virtual micromirror may be set for placement. That is, in the case shown in FIG. 17, the virtual micromirror setting unit sets eight virtual micromirrors corresponding respectively to the virtual drawing points P _{V1 to} P _V8 .

  In the above-described embodiment, the case where virtual micromirrors are set for all the micromirrors constituting the DMD 27 provided in each exposure head 30 has been exemplified. However, only a part of the micromirrors constituting the DMD 27 are virtual micromirrors. It is good also as setting a mirror. For example, among the plurality of micromirrors constituting the DMD 27, when only the edge of the drawing line drawn by the micromirror located on the outer periphery of the DMD 27 does not coincide with the edge of the drawing line on the image data, You may set a virtual micromirror only about the micromirror located. As a result, it is possible to correct the line width of the drawing line drawn by the micromirror located at the outer peripheral portion so as to coincide with the edge of the drawing line on the image data. In addition, when there is a variation in the line width of the drawing line between exposure heads, a virtual micromirror may be set only for a micromirror in a specific exposure head. Thereby, it is possible to suppress the variation in the line width of the drawing line between the exposure heads. In these cases, designation of a micromirror for setting a virtual micromirror may be performed via the instruction input unit 60.

  Moreover, according to the exposure drawing apparatus 1 which concerns on embodiment of this invention, the increase / decrease amount of the line | wire width of a drawing line can be changed by changing the distance L between a real micromirror and a virtual micromirror. Is possible. By varying the distance L between micromirrors in a single exposure head, it is possible to suppress variations in the line width of the drawing lines drawn by the micromirrors provided in the single exposure head. Also good. That is, the virtual micromirror setting unit 52 corresponds to the distance between the drawing point corresponding to one micromirror that sets the virtual micromirror and the virtual drawing point, and other micromirrors that set the virtual micromirror. You may set a virtual micromirror with respect to said 1 micromirror and said other micromirror so that the distance between a drawing point and the said virtual drawing point may differ. Further, the distance L may be varied between exposure heads. If there is a variation in the line width of the drawing line due to variations in the amount of light caused by variations in the optical system between the exposure heads, the above-mentioned variation in the drawing line width can be achieved by varying the line width correction amount between the exposure heads. Can be eliminated. When the distance L is made different between the micromirrors constituting the DMD 27 or between the exposure heads, the distance L for each micromirror may be specified via the instruction input unit 60.

  In the present embodiment, the line width correction is performed by correcting the first control data generated by the first control data generation unit 50. However, the line width correction is performed by the raster conversion processing unit 42. Correction processing for raster-format image data may be used in combination. For example, the line width correction in units of 1 μm may be performed on the raster format image data, and the line width correction of 1 μm or less may be performed on the first control data.

  In the above-described embodiment, the case where the logical value “1” is assigned to the on state of the micromirror and the logical value “0” is assigned to the off state is illustrated. However, the logical value “0” is assigned to the on state of the micromirror. The present invention can also be applied to the case where the logical value “1” is assigned to the assignment or off state. In this case, if the instruction input to the instruction input unit 60 indicates an increase in the line width, the control data correction unit 54 uses the frame in the first control data corresponding to the micromirror in which the virtual micromirror is set. The logical value for each period is corrected by a value obtained by calculating a logical product with the logical value of the corresponding frame period in the second control data corresponding to the virtual micromirror. On the other hand, when the instruction input to the instruction input unit 60 indicates a decrease in line width, the control data correction unit 54 uses the frame period in the first control data corresponding to the micromirror in which the virtual micromirror is set. Each logical value is corrected by a value obtained by calculating a logical sum with the logical value of the corresponding frame period in the second control data corresponding to the virtual micromirror.

DESCRIPTION OF SYMBOLS 1 Exposure drawing apparatus 10 Stage 19 Exposure head control part 27 DMD
30 exposure head 46 moving mechanism 50 DMD control data generation unit 51 first control data generation unit 52 virtual micromirror setting unit 53 second control data generation unit 54 control data correction unit 60 instruction input unit M, M _R micromirror M _V1 ~M _V4 virtual micro mirror P _V1 ~P _V4 virtual drawing point

Claims (13)

An image data acquisition unit for acquiring image data indicating an image to be drawn on the drawing target;
An exposure head that spatially modulates incident light by turning on and off a plurality of micromirrors to generate pattern light corresponding to the image data, and irradiates the drawing target with the pattern light;
A moving mechanism for moving a relative position of the drawing target with respect to the exposure head in a state where the exposure head irradiates the pattern target with the pattern light;
Based on the image data, a first control data generation unit that generates first control data including a plurality of logical values corresponding to the on / off states of the micromirrors for each frame period for each of the plurality of micromirrors. When,
A control unit for controlling on / off of the plurality of micromirrors based on the first control data;
A virtual micromirror setting unit that sets, for at least one of the plurality of micromirrors, a virtual micromirror that forms at least one virtual virtual drawing point at a position different from the drawing point corresponding to the micromirror; ,
A second including a plurality of logical values corresponding to an on / off state of each virtual micromirror for each frame period when a portion corresponding to the virtual drawing point of the image indicated by the image data is drawn at the virtual drawing point; A second control data generation unit for generating control data;
The logical value for each frame period in the first control data corresponding to the micromirror in which the virtual micromirror is set is the logical value of the logical value of the corresponding frame period in the second control data corresponding to the virtual micromirror. A control data correction unit for correcting the value obtained by performing the calculation;
Exposure drawing apparatus.   The exposure drawing apparatus according to claim 1, wherein the virtual micromirror setting unit sets a plurality of virtual micromirrors for one micromirror that sets a virtual micromirror.   The virtual micromirror setting unit arranges the virtual drawing points along a moving direction of a relative position of the drawing target with respect to the exposure head by the moving mechanism with a drawing point corresponding to the one micromirror interposed therebetween. The exposure drawing apparatus according to claim 2, wherein at least two virtual micromirrors are set for the one micromirror.   The virtual micromirror setting unit is configured such that the virtual drawing point intersects the moving direction of the relative position of the drawing target with respect to the exposure head by the moving mechanism with the drawing point corresponding to the one micromirror interposed therebetween. The exposure drawing apparatus according to claim 2, wherein at least two virtual micromirrors are set with respect to the one micromirror so as to be arranged along the line.   The virtual micromirror setting unit is configured such that the virtual drawing point has a drawing point corresponding to the one micromirror and a movement direction of the relative position of the drawing target with respect to the exposure head by the moving mechanism and is orthogonal thereto. The exposure drawing apparatus according to claim 2, wherein a plurality of virtual micromirrors are set for the one micromirror so as to be arranged along a direction in which the first micromirror is arranged. An instruction input unit that receives an instruction input for instructing increase / decrease in the line width of the image drawn by the pattern light;
The control data correction unit is a micromirror in which a virtual micromirror is set depending on whether the instruction input to the instruction input unit indicates an increase in line width or a decrease in line width The logical value for each frame period in the first control data corresponding to is obtained by calculating a logical sum or logical product with the logical value of the corresponding frame period in the second control data corresponding to the virtual micromirror. The exposure drawing apparatus according to any one of claims 1 to 5, wherein the exposure drawing apparatus performs correction based on the obtained value. The instruction input unit further receives an instruction input for instructing a correction amount of a line width of an image drawn by the pattern light,
The virtual micromirror setting unit increases the distance between the drawing point corresponding to the micromirror and the virtual drawing point as the correction amount of the line width input to the instruction input unit increases. The exposure drawing apparatus according to claim 6, wherein a micromirror is set.   The exposure drawing apparatus according to claim 1, wherein the virtual micromirror setting unit sets a plurality of virtual micromirrors for each of the plurality of micromirrors.   The virtual micromirror setting unit includes a distance between a drawing point corresponding to one micromirror that sets a virtual micromirror and the virtual drawing point, and a drawing point corresponding to another micromirror that sets a virtual micromirror. The exposure drawing apparatus according to claim 8, wherein a virtual micromirror is set for each of the first micromirror and the other micromirror so that a distance between the virtual drawing point and the virtual drawing point is different. Including a plurality of exposure heads,
The virtual micromirror setting unit is configured to control the micromirrors in the plurality of exposure heads so that a distance between a drawing point corresponding to the micromirror that sets the virtual micromirror and the virtual drawing point is different between the exposure heads. The exposure drawing apparatus according to any one of claims 1 to 8, wherein a virtual micromirror is set. Including a plurality of exposure heads,
The exposure drawing according to any one of claims 1 to 10, wherein the virtual micromirror setting unit sets a virtual micromirror only for micromirrors in a part of the plurality of exposure heads. apparatus. An exposure head that spatially modulates incident light by turning on and off a plurality of micromirrors to generate pattern light corresponding to image data indicating an image to be drawn on the drawing target, and irradiates the drawing target with the pattern light; and the exposure An exposure drawing device that performs exposure drawing on the drawing target using an exposure drawing device including a moving mechanism that moves a relative position of the drawing target with respect to the exposure head in a state where the pattern light is irradiated from the head to the drawing target. A drawing method,
Generating, based on the image data, first control data including a plurality of logical values corresponding to an on / off state for each frame period of the micromirror for each of the plurality of micromirrors;
Generating, based on the image data, first control data including a plurality of logical values corresponding to an on / off state for each frame period of the micromirror for each of the plurality of micromirrors;
For at least one of the plurality of micromirrors, setting a virtual micromirror that forms at least one virtual virtual drawing point at a position different from the drawing point corresponding to the micromirror;
A second including a plurality of logical values corresponding to an on / off state of each virtual micromirror for each frame period when a portion corresponding to the virtual drawing point of the image indicated by the image data is drawn at the virtual drawing point; Generating control data;
The logical value for each frame period in the first control data corresponding to the micromirror in which the virtual micromirror is set is the logical value of the logical value of the corresponding frame period in the second control data corresponding to the virtual micromirror. A control data correction unit for correcting the value obtained by performing the calculation;
Controlling on / off of the plurality of micromirrors based on the corrected first control data;
Exposure drawing method comprising:   12. The computer in the exposure drawing apparatus according to claim 1, the first control data generation unit, the virtual micromirror setting unit, the second control data generation unit, and the computer A program for functioning as a control data correction unit.