JP2004186513A - Aligner and pattern error detecting method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an aligner and a pattern error detecting method for detecting any error of an exposure pattern exposed on a wafer. <P>SOLUTION: The aligner exposes a desired exposure pattern on a wafer. The aligner includes: a buffer memory for holding exposure data as data of an exposure pattern to be exposed on a wafer; a comparing unit for comparing first exposure data generated from the buffer memory based on a first control signal for exposing a first region with second exposure data generated from the buffer memory based on a second control signal for exposing a second region, to which the same exposure pattern as that of the first region should be exposed; and an error detecting unit for detecting an error of the exposure pattern exposed on the wafer based on the compared result. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an exposure apparatus and a pattern error detection method. In particular, the present invention relates to an exposure apparatus for exposing a desired exposure pattern on a wafer and a pattern error detection method for detecting an error in the exposure pattern exposed on the wafer.
[0002]
[Prior art]
An electron beam exposure apparatus has mechanical parts such as an electron optical lens barrel and a wafer stage, and hardware parts such as a digital control unit and an analog amplifier. is there. Then, in order to expose a wafer with high accuracy in an electron beam exposure apparatus, it is necessary to reliably detect an abnormality in these apparatuses.
[0003]
For example, a buffer memory for temporarily storing exposure data stored on a hard disk, two pattern generators for outputting shot data obtained by dividing the exposure data output from the buffer memory into shot units, and two pattern generators. A first comparing unit that compares the two shot data output by each of them, two pattern correcting units that correct and output the shot data output by each of the two pattern generating units, and each of the two pattern correcting units A second comparing unit that compares the two output shot data, a two exposing unit that performs exposure based on the shot data output by each of the two pattern correcting units, and a pattern that is exposed by the two exposing units. An electron beam exposure apparatus including a third comparison unit that performs the above operation is proposed. The electron beam exposure apparatus detects a data abnormality based on a comparison result by the first comparison section, a comparison result by the second comparison section, and a comparison result by the third comparison section, and specifies a cause of the apparatus abnormality. (For example, refer to Patent Document 1).
[0004]
[Patent Document 1]
JP-A-8-279450
[0005]
[Problems to be solved by the invention]
However, the electron beam exposure apparatus disclosed in Patent Document 1 is based on the premise that exposure data output from the buffer memory is normal. Therefore, in the electron beam exposure apparatus, when the buffer memory is not operating normally and an abnormality occurs in the exposure data output from the buffer memory, the electron beam exposure apparatus cannot detect the abnormality of the data. There is a problem that the cause cannot be specified.
[0006]
Therefore, an object of the present invention is to provide an exposure apparatus and a pattern error detection method that can solve the above-described problems. This object is achieved by a combination of features described in the independent claims. The dependent claims define further advantageous embodiments of the present invention.
[0007]
[Means for Solving the Problems]
That is, according to a first embodiment of the present invention, there is provided an exposure apparatus for exposing a desired exposure pattern on a wafer, comprising: a buffer memory for holding exposure data which is data of an exposure pattern to be exposed on the wafer; Based on the first exposure data output from the buffer memory based on the first control signal for exposing the first region, and the second control signal for exposing the second region where the same exposure pattern as the first region is to be exposed. A comparison unit that compares the second exposure data output from the buffer memory with the data, and an error detection unit that detects an error in the exposure pattern exposed on the wafer based on the comparison result by the comparison unit.
[0008]
The memory further includes a first expected value memory for holding the first exposure data output from the buffer memory, and the comparing unit stores the first exposure data output from the first expected value memory and the second exposure data output from the buffer memory. You may compare. The comparing unit may compare the first exposure data output from the first expected value memory with the second exposure data output from the buffer memory in bit units.
[0009]
A comparison result storage unit that stores, as a comparison result, information indicating whether the first exposure data and the second exposure data are the same in association with the identification information of the second area; The error of the exposure pattern exposed on the wafer may be detected based on the comparison result stored in the storage unit.
[0010]
The comparing unit outputs the first exposure data output from the first expected value memory and the buffer memory based on a third control signal for exposing a third area to be exposed with the same exposure pattern as the first area. The comparison result storage unit stores information indicating whether the first exposure data and the second exposure data are the same, and whether the first exposure data is the same as the third exposure data. Is stored as a comparison result. If the first exposure data and the second exposure data are the same and the first exposure data and the third exposure data are different, the error detection unit If the first exposure data and the second exposure data are different from each other and the first exposure data and the third exposure data are different, it is determined that there is an error in the exposure pattern that has been exposed to the first area. It may be determined that there is.
[0011]
A wafer stage on which the wafer is placed and exposed while moving in a first direction, and then turned back and exposed while moving in a second direction opposite to the first direction, wherein the first expected value memory is When the wafer stage is turned back, the first exposure data output from the buffer memory may be written.
[0012]
The memory further includes a second expected value memory for holding the second exposure data output from the buffer memory, and the comparing unit is configured to expose the second exposure data output from the second expected value memory and the same exposure pattern as the first area. The third exposure data output from the buffer memory may be compared based on a third control signal for exposing the third region to be exposed.
[0013]
When the buffer memory is outputting the first exposure data, the first exposure data is written to the first expected value memory. When the buffer memory is outputting the second exposure data, the first expected value memory is written. A first expected value memory control unit for causing the comparing unit to read the first exposure data and writing the third exposure data to the first expected value memory when the buffer memory is outputting the third exposure data; When the memory is outputting the second exposure data, the second exposure data is written to the second expected value memory, and when the buffer memory is outputting the third exposure data, the comparison is made from the second expected value memory. A second expected value memory control unit that causes the unit to read the second exposure data.
[0014]
According to a second aspect of the present invention, there is provided a pattern error detecting method for detecting an error in an exposure pattern exposed on a wafer, wherein the buffer memory outputs the error based on a first control signal for exposing a first area. An exposure step of exposing the wafer using the first exposure data; and a second step in which the buffer memory outputs based on a second control signal for exposing a second area where the same exposure pattern as the first area is to be exposed. An exposure step of exposing the wafer using the exposure data; a comparison step of comparing the first exposure data with the second exposure data; and detecting an error in an exposure pattern exposed on the wafer based on a comparison result in the comparison step. Error detecting step.
[0015]
According to a third aspect of the present invention, there is provided an exposure apparatus for exposing a desired exposure pattern on a wafer, comprising: a buffer memory for holding exposure data which is data of an exposure pattern to be exposed on the wafer; An expected value data generating unit for generating first expected value data which is an expected value of exposure data to be output by the buffer memory based on a first control signal for performing the first control signal; A comparing unit that compares the first exposure data with the first expected value data generated by the expected value data generating unit; an exposing unit that exposes the wafer based on the first exposure data output by the buffer memory; And an error detection unit for detecting an error in the exposure pattern exposed on the wafer based on the comparison result by
[0016]
The apparatus further includes a first expected value memory holding first expected value data generated by the expected value data generating unit, and the comparing unit includes a first expected value data output from the first expected value memory and a second expected value data output from the buffer memory. One exposure data may be compared.
[0017]
According to a fourth aspect of the present invention, there is further provided a wafer stage on which a wafer is placed, wherein the wafer stage turns in a first direction and then turns to move in a second direction opposite to the first direction. The exposure unit performs a first exposure process while the wafer stage is moving in the first direction, and performs a second exposure process on the first region while the wafer stage is moving in the second direction. The first expected value memory may write the first expected value data between the first exposure process and the second exposure process.
[0018]
The apparatus further includes a wafer stage on which a wafer is placed. The wafer stage is turned in a first direction and then turned back to move in a second direction opposite to the first direction. After performing the first exposure processing while moving in the direction of the second direction, the second exposure processing of the first area is performed while the wafer stage is moving in the second direction. During the first exposure processing, the first expected value data generated by the expected value data generating unit may be written.
[0019]
A second expectation memory for holding second expectation data to be output by the buffer memory based on a second control signal for exposing the second area, wherein the wafer stage moves in the second direction; Further, the exposure unit moves in the first direction. The exposure unit performs the second exposure processing on the first region while the wafer stage is moving in the second direction. During the second exposure processing, the comparison unit performs the third exposure processing of the second area, and during the second exposure processing, outputs the first expected value data output by the first expected value memory and the buffer memory. The second expected value memory may be compared with the first exposure data, and the second expected value memory may write the second expected value data generated by the expected value data generating unit during the second exposure processing.
[0020]
According to a fifth aspect of the present invention, there is provided a pattern error detection method for detecting an error of an exposure pattern exposed on a wafer, wherein a buffer memory outputs an error based on a first control signal for exposing a first area. An expected value data generating step of generating first expected value data that is an expected value of power exposure data; first exposure data output from the buffer memory based on the first control signal; and an expected value data generated step. A comparing step of comparing the first expected value data with the first expected value data; an exposure step of exposing the wafer based on the first exposure data output from the buffer memory; and an exposure pattern exposed on the wafer based on the comparison result in the comparing step. And an error detecting step of detecting the error.
[0021]
Note that the above summary of the present invention does not list all of the necessary features of the present invention, and a sub-combination of these features may also be an invention.
[0022]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, the present invention will be described through embodiments of the present invention. However, the following embodiments do not limit the invention according to the claims, and all of the combinations of the features described in the embodiments are not limited thereto. It is not always essential to the solution of the invention.
[0023]
FIG. 1 shows an example of the configuration of an electron beam exposure apparatus 100 according to one embodiment of the present invention. The electron beam exposure apparatus 100 includes exposure units 150a and 150b for performing a predetermined exposure process on the wafer 64 with an electron beam, and a control system 140 for controlling the operation of each component of the exposure units 150a and 150b. The electron beam exposure apparatus 100 is an example of the exposure apparatus of the present invention. Further, the exposure apparatus of the present invention may be an ion beam exposure apparatus that exposes a wafer with an ion beam.
[0024]
The exposure units 150a and 150b irradiate the electron beam irradiation system 110 that irradiates a predetermined electron beam into the housing 10 and deflect the electron beam irradiated from the electron beam irradiation system 110. A mask projection system 112 for adjusting the image forming position, a focus adjusting lens system 114 for adjusting the image forming position of the electron beam near the wafer 64, and a wafer mounted on the wafer stage 62 for the electron beam passing through the mask 30. An electron optical system including a wafer projection system 116 for deflecting a predetermined area 64 and adjusting the direction and size of an image of a pattern transferred to the wafer 64 is provided.
[0025]
The exposure units 150a and 150b include a mask stage 72 on which the mask 30 having a plurality of blocks each having a pattern to be exposed on the wafer 64 is mounted, a mask stage driving unit 68 for driving the mask stage 72, A stage system including a wafer stage 62 on which a wafer 64 on which a pattern is to be exposed is mounted, and a wafer stage driving unit 70 for driving the wafer stage 62 is provided. Further, the exposure units 150a and 150b have an electron detector 60 that detects electrons scattered from the wafer stage 62 side and converts them into an electric signal corresponding to the amount of scattered electrons for adjusting the electron optical system.
[0026]
The electron beam irradiation system 110 includes a first electron lens 14 that determines a focal position of an electron beam by an electron gun 12 that generates an electron beam, and a slit portion 16 having a rectangular opening (slit) through which the electron beam passes. And Since it takes a predetermined time for the electron gun 12 to generate a stable electron beam, the electron gun 12 may always generate an electron beam during the exposure processing. The slit is preferably formed in accordance with the shape of a block including a predetermined pattern formed on the mask 30. In FIG. 1, the optical axis of the electron beam when the electron beam emitted from the electron beam irradiation system 110 is not deflected by the electron optical system is represented by a chain line A.
[0027]
The mask projection system 112 includes a first deflector 18, a second deflector 22, and a third deflector 26 as a mask deflection system for deflecting an electron beam, and a mask focus system for adjusting the focus of the electron beam. It has a second electron lens 20 and a first blanking electrode 24. The first deflector 18 and the second deflector 22 perform deflection to irradiate a predetermined area on the mask 30 with the electron beam. For example, the predetermined area may be a block having a pattern to be transferred to the wafer 64. As the electron beam passes through the pattern, the cross-sectional shape of the electron beam becomes the same as the pattern. The image of the electron beam passing through the block on which the predetermined pattern is formed is defined as a pattern image. The third deflector 26 deflects the trajectory of the electron beam passing through the first deflector 18 and the second deflector 22 substantially in parallel with the optical axis A. The second electron lens 20 has a function of forming an image of the opening of the slit section 16 on the mask 30 placed on the mask stage 72.
[0028]
The first blanking electrode 24 deflects the electron beam so that the electron beam does not hit a block formed on the mask 30. It is preferable that the first blanking electrode 24 deflects the electron beam so that the electron beam does not hit the mask 30. Since the pattern formed on the mask 30 deteriorates as the electron beam is irradiated, the first blanking electrode 24 deflects the electron beam except when transferring the pattern to the wafer 64. Therefore, deterioration of the mask 30 can be prevented. The focus adjustment lens system 114 has a third electronic lens 28 and a fourth electronic lens 32. The third electronic lens 28 and the fourth electronic lens 32 focus the electron beam on the wafer 64. The wafer projection system 116 includes a fifth electronic lens 40, a sixth electronic lens 46, a seventh electronic lens 50, an eighth electronic lens 52, a ninth electronic lens 66, a fourth deflector 34, a fifth deflector 38, It has a six deflector 42, a main deflector 56, a sub deflector 58, a second blanking electrode 36, and a round aperture unit 48.
[0029]
The pattern image rotates under the influence of the electric field and the magnetic field. The fifth electron lens 40 adjusts the amount of rotation of the pattern image of the electron beam that has passed through a predetermined block of the mask 30. The sixth electronic lens 46 and the seventh electronic lens 50 adjust the reduction ratio of the pattern image transferred to the wafer 64 with respect to the pattern formed on the mask 30. The eighth electronic lens 52 and the ninth electronic lens 66 function as objective lenses. The fourth deflector 34 and the sixth deflector 42 deflect the electron beam in the direction of the optical axis A downstream of the mask 30 in the traveling direction of the electron beam. The fifth deflector 38 deflects the electron beam so as to be substantially parallel to the optical axis A. The main deflector 56 and the sub deflector 58 deflect the electron beam so that a predetermined area on the wafer 64 is irradiated with the electron beam. In the present embodiment, the main deflector 56 is used to deflect the electron beam between subfields including a plurality of areas (shot areas) that can be irradiated with one shot of the electron beam, and the sub deflector 58 is used to deflect the subfield. Is used for deflection between shot areas.
[0030]
The round aperture section 48 has a circular opening (round aperture). The second blanking electrode deflects the electron beam so as to hit the outside of the round aperture. Therefore, the second blanking electrode 36 can prevent the electron beam from traveling downstream from the round aperture section 48 in the traveling direction of the electron beam. Since the electron gun 12 always emits an electron beam during the exposure processing period, the second blanking electrode 36 changes the area of the wafer 64 on which the pattern is exposed when the pattern to be transferred to the wafer 64 is changed. Sometimes, it is desirable to deflect the electron beam so that the electron beam does not travel downstream from the round aperture section 48.
[0031]
The control system 140 includes a common processing unit 160, individual processing units 170a and 300b, and individual control units 120a and 120b. The individual control units 120a and 120b include a deflection control unit 82, a mask stage control unit 84, a blanking electrode control unit 86, an electron lens control unit 88, a reflected electron processing unit 90, and a wafer stage control unit 92. The common processing unit 160 supplies the exposure data stored in the hard disk to the individual processing units 170a and 300b. The individual processing units 170a and 300b supply control data relating to the exposure processing to the control units of the individual control units 120a and 120b based on the exposure data supplied from the common processing unit 160. The deflection control unit 82 includes the first deflector 18, the second deflector 22, the third deflector 26, the fourth deflector 34, the fifth deflector 38, the sixth deflector 42, the main deflector 56, and the sub deflector. Control unit 58. The mask stage control unit 84 controls the mask stage driving unit 68 to move the mask stage 72.
[0032]
The blanking electrode control unit 86 controls the first blanking electrode 24 and the second blanking electrode 36. In the present embodiment, the first blanking electrode 24 and the second blanking electrode 36 are controlled so as to irradiate the wafer 64 with an electron beam during exposure, and to prevent the electron beam from reaching the wafer 64 except during exposure. Is desirable. The electronic lens control unit 88 includes a first electronic lens 14, a second electronic lens 20, a third electronic lens 28, a fourth electronic lens 32, a fifth electronic lens 40, a sixth electronic lens 46, a seventh electronic lens 50, The power supplied to the eighth electronic lens 52 and the ninth electronic lens 66 is controlled. The backscattered electron processing unit 90 detects digital data indicating the amount of electrons based on the electric signal detected by the backscattered electron detection unit 60. The wafer stage control unit 92 causes the wafer stage driving unit 70 to move the wafer stage 62 to a predetermined position.
[0033]
Hereinafter, the operation of the electron beam exposure apparatus 100 will be described. On the mask stage 72, a mask 30 having a plurality of blocks in which a predetermined pattern is formed is mounted, and the mask 30 is fixed at a predetermined position. Exposure processing is performed using ozone gas or O ₂ It may be performed in an oxidizing atmosphere such as a plasma gas. At this time, it is preferable that the surface of the mask 30 is covered with a material that is not oxidized by an oxidizing ozone gas or the like. On the wafer stage 62, a wafer 64 to be subjected to exposure processing is mounted. The wafer stage control unit 92 moves the wafer stage 62 by the wafer stage driving unit 70 so that the region of the wafer 64 to be exposed is located near the optical axis A. Since the electron gun 12 always emits an electron beam during the exposure processing period, a blanking electrode is provided so that the electron beam passing through the opening of the slit portion 16 is not irradiated to the mask 30 and the wafer 64 before the start of the exposure. The control unit 86 controls the first blanking electrode 24 and the second blanking electrode 36. In the mask projection system 112, the electron lens 20 and the deflectors (18, 22, 26) are adjusted so that a block on which a pattern to be transferred to the wafer 64 is formed can be irradiated with an electron beam. In the focus adjustment lens system 114, the electron lenses (28, 32) are adjusted so that the electron beam is focused on the wafer 64. In the wafer projection system 116, the electron lenses (40, 46, 50, 52, 66) and the deflectors (34, 38, 42, 56, 58) can transfer a pattern image to a predetermined area of the wafer 64. Is adjusted as follows.
[0034]
After the mask projection system 112, the focus adjustment lens system 114, and the wafer projection system 116 are adjusted, the blanking electrode control unit 86 stops the deflection of the electron beam by the first blanking electrode 24 and the second blanking electrode 36. I do. As a result, the electron beam is applied to the wafer 64 via the mask 30 as described below. The electron gun 12 generates an electron beam, and the first electron lens 14 adjusts the focal position of the electron beam to irradiate the slit portion 16. Then, the first deflector 18 and the second deflector 22 deflect the electron beam having passed through the opening of the slit portion 16 so as to irradiate a predetermined area of the mask 30 on which a pattern to be transferred is formed. The electron beam that has passed through the opening of the slit 16 has a rectangular cross-sectional shape. The electron beam deflected by the first deflector 18 and the second deflector 22 is deflected by the third deflector 26 so as to be substantially parallel to the optical axis A. The electron beam is adjusted by the second electron lens 20 so that an image of the opening of the slit portion 16 is formed in a predetermined region on the mask 30.
[0035]
The electron beam passing through the pattern formed on the mask 30 is deflected in a direction approaching the optical axis A by the fourth deflector 34 and the sixth deflector 42, and substantially deflected by the fifth deflector 38 to the optical axis A. It is deflected to be parallel. The electron beam is adjusted by the third electron lens 28 and the fourth electron lens 32 so that the image of the pattern formed on the mask 30 is focused on the surface of the wafer 64. Is adjusted, and the sixth electronic lens 46 and the seventh electronic lens 50 adjust the reduction ratio of the pattern image. Then, the electron beam is deflected by the main deflector 56 and the sub deflector 58 so as to irradiate a predetermined shot area on the wafer 64. In the present embodiment, the main deflector 56 deflects the electron beam between subfields including a plurality of shot areas, and the sub deflector 58 deflects the electron beam between shot areas in the subfield. The electron beam deflected to a predetermined shot area is adjusted by the electron lens 52 and the electron lens 66 and is irradiated on the wafer 64. As a result, an image of the pattern formed on the mask 30 is transferred to a predetermined shot area on the wafer 64.
[0036]
After a predetermined exposure time has elapsed, the blanking electrode control unit 86 controls the first blanking electrode 24 and the second blanking electrode 36 so that the electron beam does not irradiate the mask 30 and the wafer 64, and Deflected the beam. By the above process, a pattern formed on the mask 30 is exposed to a predetermined shot area on the wafer 64. In order to expose the pattern formed on the mask 30 to the next shot area, in the mask projection system 112, the electron lens 20 and the deflectors (18, 22, 26) have a block having a pattern to be transferred to the wafer 64. Is adjusted to be able to irradiate an electron beam. In the focus adjustment lens system 114, the electron lenses (28, 32) are adjusted so that the electron beam is focused on the wafer 64. In the wafer projection system 116, the electron lenses (40, 46, 50, 52, 66) and the deflectors (34, 38, 42, 56, 58) can transfer a pattern image to a predetermined area of the wafer 64. Is adjusted as follows.
[0037]
More specifically, the sub deflector 58 adjusts the electric field so that the pattern image generated by the mask projection system 112 is exposed to the next shot area. Thereafter, the pattern is exposed to the shot area in the same manner as described above. After exposing the pattern to all the shot areas where the pattern in the subfield is to be exposed, the main deflector 56 adjusts the magnetic field so that the pattern can be exposed in the next subfield. The electron beam exposure apparatus 100 can expose a desired circuit pattern to the wafer 64 by repeatedly performing this exposure processing.
[0038]
The electron beam exposure apparatus 100, which is an electron beam processing apparatus according to the present invention, may be an electron beam exposure apparatus using a variable rectangle, or may be an electron beam exposure apparatus using a blanking aperture array device. You may. The electron beam exposure apparatus 100 according to the present embodiment includes two individual processing units 170a and 300b, two individual control units 120a and 120b, and two exposure units 150a and 150b. The exposure apparatus may be an electron beam exposure apparatus including three or more individual processing units, individual control units, and three or more exposure units. Further, in the electron beam exposure apparatus 100 according to the present embodiment, the exposure unit 150a and the exposure unit 150b respectively expose different wafers, but the electron beam exposure apparatus according to the present invention has a The wafer may be exposed.
[0039]
FIG. 2 shows an example of a frame area on the wafer 64. The frame region is a region that can be exposed while the wafer stage 62 is moving in a predetermined direction, and is a region that straddles a plurality of chip regions 200. That is, in the frame area, the horizontal width is the maximum amplitude of the main deflector 56, and the vertical width is the width of the area on the wafer 64 where chips are formed. For example, in the electron beam exposure apparatus 100, the exposure unit 150a exposes the frame area 202a while the wafer stage 62 is moving in the first direction (positive y-axis direction). Then, when the exposure of the frame region 202a is completed, the wafer stage 62 moves in the positive direction of the x-axis by the width of the frame region, and then turns back in the second direction (y) opposite to the first direction (positive direction of the y-axis). Start moving in the negative direction). Then, while the wafer stage 62 is moving in the second direction (y-axis negative direction), the exposure unit 150a exposes a frame area 202b adjacent to the frame 202a. When the exposure of the frame area 202b is completed, the wafer stage 62 moves in the positive x-axis direction by the width of the frame area, and then returns to start moving in the first direction (positive y-axis direction). Then, while the wafer stage 62 is moving in the first direction (positive y-axis direction), the exposure unit 150a exposes the frame area 202c adjacent to the frame area 202b. As described above, the electron beam exposure apparatus 100 exposes the entire plurality of chip areas 200 on the wafer 64 by repeating the exposure processing for each frame area. In the present embodiment, it is preferable that the same exposure pattern is formed in the plurality of chip regions 200.
[0040]
FIG. 3 shows an example of a band region on the wafer 64. The band area is an area obtained by dividing the frame area into chips. That is, the width of the band area is the maximum amplitude of the main deflector 56, and the length of the band area is the width of the chip area. For example, the frame 202a includes a band region 204a that is a part of the chip region 200a, a band region 204b that is a part of the chip region 200b, and a band region 204c that is a part of the chip region 200c. In this embodiment, it is preferable that the same exposure pattern is formed in the band regions 204a, 204b, and 204c.
[0041]
FIG. 4 shows an example of the configuration of the control system 140 according to the present embodiment. The common processing unit 160 includes an overall control unit 300, a sequence control unit 302, address counters 304 and 306, a buffer memory (main) 308, a buffer memory (PA) 310, a buffer memory (PD) 312, output buffers 314, 316, and 318, expected value memories 320, 322, and 324, expected value memory control units 326, 328, and 330, comparison units 332, 334, and 336, a comparison result storage unit 337, and an error detection unit 338. The individual processing unit 170a includes a main differential correction unit 340a, a pattern generation unit 342a, and a pattern correction unit 344a. The individual processing unit 170b includes a main differential correction unit 340b, a pattern generation unit 342b, and a pattern correction unit 344b.
[0042]
The general control unit 300 is, for example, an engineering workstation, and controls the electron beam exposure apparatus 100 comprehensively. In the exposure processing, the overall control unit 300 first reads out exposure data, which is data of an exposure pattern to be exposed on the wafer 64, from the hard disk drive, and stores the buffer memory (main) 308, the buffer memory (PA) 310, and the buffer memory ( PD) 312. The buffer memory (main) 308, the buffer memory (PA) 310, and the buffer memory (PD) 312 temporarily hold the exposure data received from the overall control unit 300.
[0043]
Next, the overall control unit 300 sends an exposure start flag to the sequence control unit 302. Upon receiving the exposure start flag, the sequence control unit 302 supplies a predetermined main start address and number information to the address counter 304. The address counter 304 generates a main address based on the main start address and the number information, and supplies the main address to the buffer memory (main) 308 and the buffer memory (PA) 310.
[0044]
The buffer memory (main) 308 outputs main data as exposure data for controlling the main deflector 56 based on the main address received from the address counter 304, and supplies the main data to the main differential correction units 340a and 340b. The main differential correction units 340a and 340b correct main data received from the buffer memory (main) 308 and supply the corrected main data to the individual control units 120a and 120b.
[0045]
The buffer memory (PA) 310 supplies the pattern start address and the number information to the address counter 306 based on the main address received from the address counter 304. The address counter 306 generates a pattern address based on the pattern start address and the number information, and supplies the pattern address to the buffer memory (PD) 312. The buffer memory (PD) 312 outputs pattern data, which is exposure data for controlling the sub deflector 58, based on the pattern address received from the address counter 306, and supplies the pattern data to the pattern generators 342a and 342b. The pattern generation units 342a and 342b generate shot data obtained by dividing the pattern data received from the buffer memory (PD) 312 into shot units and supply the shot data to the pattern correction units 344a and 344b. Then, the pattern correction units 344a and 344b correct the shot data received from the pattern generation units 342a and 342b and supply the shot data to the individual control units 120a and 120b.
[0046]
Each control unit of the individual control units 120a and 120b controls each of the exposure units 150a and 150b based on the main data received from the main differential correction units 340a and 340b and the shot data received from the pattern correction units 344a and 304b. . Then, the exposure units 150a and 150b irradiate the wafer 64 with an electron beam to expose a desired exposure pattern.
[0047]
The expected value memory 320 holds main data output from the buffer memory (main) 308. The output buffer 314 switches whether to supply the main data output from the buffer memory (main) 308 to the expected value memory 320 based on the control of the sequence control unit 302. The expected value memory control unit 326 controls reading and writing (read control / write control) of the expected value memory 320 by supplying a read signal and a write signal based on the control of the sequence control unit 302. The comparing unit 332 compares the main data output from the buffer memory (main) 308 with the main data output from the expected value memory 320 on a bit-by-bit basis. Then, the comparison result storage unit 337 stores the comparison result by the comparison unit 332.
[0048]
The expected value memory 322 holds the pattern start address and the number information output from the buffer memory (PA) 310. The output buffer 316 switches whether to supply the pattern start address and the number information output from the buffer memory (PA) 310 to the expected value memory 322 based on the control of the sequence control unit 302. The expected value memory control unit 328 controls reading and writing (read control / write control) of the expected value memory 322 by supplying a read signal and a write signal based on the control of the sequence control unit 302. The comparison unit 334 compares the pattern start address and the number information output from the buffer memory (PA) 310 with the main data output from the expected value memory 322 on a bit-by-bit basis. Then, the comparison result storage unit 337 stores the comparison result by the comparison unit 334.
[0049]
The expected value memory 324 holds the pattern data output from the buffer memory (PD) 312. The output buffer 318 switches whether to supply the pattern data output from the buffer memory (PD) 312 to the expected value memory 324 based on the control of the sequence control unit 302. The expected value memory control unit 330 controls reading and writing (read control / write control) of the expected value memory 324 by supplying a read signal and a write signal based on the control of the sequence control unit 302. The comparing unit 336 compares the pattern data output from the buffer memory (PD) 312 with the pattern data output from the expected value memory 324 in bit units. Then, the comparison result storage unit 337 stores the comparison result by the comparison unit 336.
[0050]
The error detection unit 338 detects an error of the exposure pattern exposed on the wafer 64 based on the comparison result of the comparison units 332, 334, and 336 stored in the comparison result storage unit 337. The overall control unit 300 stores identification information of a band area where the exposure pattern including the error detected by the error detection unit 338 is exposed.
[0051]
Hereinafter, the operation of the common processing unit 160 shown in FIG. 4, particularly, the pattern error detection method will be specifically described with reference to FIGS. 2 and 3. First, the exposure processing of the frame area 202a shown in FIG. 2 is started. The wafer stage 62 causes the exposure unit 150a to expose the frame region 202a while moving in the first direction (positive y-axis direction). The buffer memory (main) 308 receives a first main address as an example of a control signal for exposing the band area 204a shown in FIG. 3 from the address counter 304, and outputs first main data as an example of exposure data. Then, the data is supplied to the individual control unit 170a. The output buffer 314 supplies the first main data output from the buffer memory (main) 308 to the expected value memory 320. The expected value memory control unit 326 causes the expected value memory 320 to write the first main data when the buffer memory (main) 308 is outputting the first main data. Then, the expected value memory 320 stores the first main data output by the buffer memory (main) 308 based on the first main address.
[0052]
Further, the buffer memory (PA) 310 receives the first main address from the address counter 304, outputs a first pattern start address and first number information, which are examples of exposure data, and supplies them to the address counter 306. Then, the address counter 306 outputs the first pattern address based on the first pattern start address and the first number information, and supplies the first pattern address to the buffer memory (PD) 312. The output buffer 316 supplies the first pattern address output from the address counter 306 to the expected value memory 322. The expected value memory control unit 328 causes the expected value memory 322 to write the first pattern address when the address counter 306 outputs the first pattern address. Then, the expected value memory 322 stores the first pattern address output by the address counter 306 based on the first main address.
[0053]
The buffer memory (PD) 312 receives from the address counter 306 a first pattern address which is an example of a control signal for exposing the band area 204a shown in FIG. And supplies it to the individual control unit 170a. The output buffer 318 supplies the first pattern data output from the buffer memory (PD) 312 to the expected value memory 324. The expected value memory control unit 330 causes the expected value memory 324 to write the first pattern data when the buffer memory (PD) 312 is outputting the first pattern data. Then, the expected value memory 324 stores the first pattern data output by the buffer memory (PD) 312 based on the first pattern address. Then, the exposure unit 150a exposes the band area 204a based on the first main data and the first pattern data supplied to the individual control unit 170a.
[0054]
Next, the buffer memory (main) 308 receives from the address counter 304 a second main address which is an example of a control signal for exposing the band area 204b shown in FIG. The data is output and supplied to the individual control unit 170a. Note that the band area 204b is an area where the same exposure pattern as that of the band area 204a is to be exposed, and the first main address and the second main address are ideally the same. The expected value memory control unit 326 causes the comparison unit 332 to read the first main data from the expected value memory 320 when the buffer memory (main) 308 is outputting the second main data. Then, the comparing unit 332 compares the second main data output from the buffer memory (main) 308 with the first main data output from the expected value memory 320. That is, the comparison unit 332 compares the first main data output from the buffer memory (main) 308 based on the first main address with the second main data output from the buffer memory (main) 308 based on the second main address. Compare. Then, the comparing unit 332 supplies information indicating whether or not the first main data and the second main data are the same to the comparison result storage unit 337 as a comparison result. Then, the comparison result storage unit 337 stores the comparison result acquired from the comparison unit 332 in association with the identification information of the band area 204b, for example, the identification information of the chip area 200b.
[0055]
The buffer memory (PA) 310 receives the second main address from the address counter 304, outputs a second pattern start address and second number information, which are examples of exposure data, and supplies them to the address counter 306. Then, the address counter 306 outputs the second pattern address based on the second pattern start address and the second number information, and supplies the second pattern address to the buffer memory (PD) 312. When the buffer memory (PA) 310 outputs the second pattern start address and the second number information, that is, when the address counter 306 outputs the second pattern address, the expected value memory control unit 328 The comparison unit 334 reads the second pattern address from the value memory 322. Then, the comparing unit 334 compares the second pattern address output from the address counter 306 with the first pattern address output from the expected value memory 322. That is, the comparing unit 334 compares the first pattern address output from the address counter 306 based on the first main address with the second pattern address output from the address counter 306 based on the second main address. Then, the comparison unit 334 supplies information indicating whether or not the first pattern address is the same as the second pattern address to the comparison result storage unit 337 as a comparison result. Then, the comparison result storage unit 337 stores the comparison result acquired from the comparison unit 334 in association with the identification information of the band area 204b.
[0056]
Then, the buffer memory (PD) 312 receives from the address counter 306 a second pattern address which is an example of a control signal for exposing the band area 204b shown in FIG. 3, and a second pattern data which is an example of exposure data. And supplies it to the individual control unit 170a. The expected value memory control unit 330 causes the comparing unit 336 to read the first pattern data from the expected value memory 324 when the buffer memory (PD) 312 is outputting the second pattern address. Then, the comparing unit 336 compares the second pattern data output from the buffer memory (PD) 312 with the first pattern data output from the expected value memory 324. That is, the comparison unit 336 compares the first pattern data output from the buffer memory (PD) 312 based on the first pattern address with the second pattern data output from the buffer memory (PD) 312 based on the second pattern address. Compare. Then, the comparison unit 336 supplies information indicating whether the first pattern data and the second pattern data are the same to the comparison result storage unit 337 as a comparison result. Then, the comparison result storage unit 337 stores the comparison result acquired from the comparison unit 334 in association with the identification information of the band area 204b. Then, the exposure unit 150a exposes the band area 204b based on the second main data and the second pattern data supplied to the individual control unit 170a.
[0057]
Next, the buffer memory (main) 308 receives from the address counter 304 a third main address which is an example of a control signal for exposing the band area 204c shown in FIG. The data is output and supplied to the individual control unit 170a. Note that the band area 204c is an area where the same exposure pattern as that of the band area 204a is to be exposed, and the first main address and the third main address are ideally the same. The expected value memory control unit 326 causes the comparing unit 332 to read the first main data from the expected value memory 320 when the buffer memory (main) 308 is outputting the third main data. Then, the comparing unit 332 compares the third main data output from the buffer memory (main) 308 with the first main data output from the expected value memory 320. That is, the comparing unit 332 compares the first main data output from the buffer memory (main) 308 based on the first main address with the third main data output from the buffer memory (main) 308 based on the third main address. Compare. Then, the comparison unit 332 supplies the comparison result storage unit 337 with a comparison result indicating whether the first main data and the third main data are the same. Then, the comparison result storage unit 337 stores the comparison result acquired from the comparison unit 332 in association with the identification information of the band area 204c, for example, the identification information of the chip area 200c.
[0058]
The buffer memory (PA) 310 receives the third main address from the address counter 304, outputs a third pattern start address and third number information, which are examples of exposure data, and supplies them to the address counter 306. Then, the address counter 306 outputs the first pattern address based on the first pattern start address and the first number information, and supplies the first pattern address to the buffer memory (PD) 312. When the buffer memory (PA) 310 outputs the second pattern start address and the second number information, that is, when the address counter 306 outputs the third pattern address, the expected value memory control unit 328 The comparison unit 334 reads the third pattern address from the value memory 322. Then, the comparing unit 334 compares the third pattern address output from the address counter 306 with the first pattern address output from the expected value memory 322. That is, the comparing unit 334 compares the first pattern address output from the address counter 306 based on the first main address with the third pattern address output from the address counter 306 based on the third main address. Then, the comparing unit 334 supplies information indicating whether the first pattern address is the same as the third pattern address to the comparison result storage unit 337 as a comparison result. Then, the comparison result storage unit 337 stores the comparison result acquired from the comparison unit 334 in association with the identification information of the band area 204c.
[0059]
The buffer memory (PD) 312 receives a third pattern address, which is an example of a control signal for exposing the band area 204c shown in FIG. 3, from the address counter 306, and receives third pattern data, which is an example of exposure data. Is output to the individual control unit 170a. The expected value memory control unit 330 causes the comparing unit 336 to read the first pattern data from the expected value memory 324 when the buffer memory (PD) 312 is outputting the third pattern address. Then, the comparing unit 336 compares the third pattern data output from the buffer memory (PD) 312 with the first pattern data output from the expected value memory 324. That is, the comparison unit 336 compares the first pattern data output from the buffer memory (PD) 312 based on the first pattern address with the third pattern data output from the buffer memory (PD) 312 based on the third pattern address. Compare. Then, the comparison unit 336 supplies information indicating whether the first pattern data and the third pattern data are the same to the comparison result storage unit 337 as a comparison result. Then, the comparison result storage unit 337 stores the comparison result acquired from the comparison unit 334 in association with the identification information of the band area 204c. Then, the exposure unit 150a exposes the band area 204c based on the third main data and the third pattern data supplied to the individual control unit 170c.
[0060]
The error detection unit 338 detects an error in the exposure pattern exposed on the wafer 64 based on the comparison results of the comparison units 332, 334, and 336 stored in the comparison result storage unit 337. If the first main data and the second main data are the same and the first main data and the third main data are different, the error detection unit 338 determines that the first pattern address and the second pattern address are the same. When the first pattern address and the third pattern address are different, or when the first pattern data and the second pattern data are the same and the first pattern data and the third pattern data are different, the band area 204c It is determined that there is an error in the exposed exposure pattern, and the overall control unit 330 is notified. In addition, when the first main data and the second main data are different and the first main data and the third main data are different, the error detection unit 338 determines that the first pattern address and the second pattern address are different and the first When the pattern address and the third pattern address are different, or when the first pattern data and the second pattern data are different and the first pattern data and the third pattern data are different, the exposure pattern exposed to the band area 204a is It is determined that there is an error, and the overall control unit 300 is notified.
[0061]
Next, after the exposure processing of the frame area 202a shown in FIG. 2, the processing proceeds to the exposure processing of the frame area 202b. The wafer stage 62 exposes the frame area 202a to the exposure unit 150a while moving in the first direction (positive y-axis direction), and then turns back to expose a second direction opposite to the first direction (positive y-axis direction). While moving in the direction (negative y-axis direction), the exposure unit 150a exposes the frame area 202b. The expected value memory 320 erases the stored first memory data when the wafer stage 64 returns. Then, the expected value memory 320 reads the main data output by the buffer memory (main) 308 based on the main address for exposing the first band area of the frame area 202b. Then, similarly to the above-described case of the frame region 202a, an error of the exposure pattern of the band region included in the frame region 202b is detected while exposing the frame region 202b.
[0062]
Since the width of the frame area is the maximum amplitude of the main deflector 56, the exposure pattern to be exposed differs for each frame area. Even in such a case, by updating the main data stored in the expected value memory 320 when the wafer stage 62 is turned back, that is, when the frame area to be exposed is changed, the exposure pattern of the band area unit can be changed for each frame. Error detection can be appropriately performed.
[0063]
The error detection process by the error detection unit 338 described above is preferably performed during the exposure process, and may be performed after the exposure process. By performing during the exposure processing, an error in the exposure pattern can be detected without lowering the throughput of the electron beam exposure apparatus 100.
[0064]
According to the electron beam exposure apparatus 100 according to the present embodiment, since an error in the exposure pattern is detected for each band area, a chip having an error in the exposure pattern can be specified. That is, since the specific unit of the abnormal portion can be subdivided, the yield can be improved. In addition, since the data stored in the expected value memory in advance and the data output from the buffer memory are compared, it is possible to detect not only data jumps, data omissions, bit failure errors, but also data order errors. Can be.
[0065]
FIG. 5 shows a first modification of the common processing unit 160 according to the present embodiment. The common processing unit 160 according to this modification includes expected value memories 400, 402, and 404 and selectors 406, 408, and 410 in addition to the components shown in FIG. In this modified example, the same components as those of the common processing unit 160 shown in FIG. 4 are denoted by the same reference numerals, and the components denoted by the same reference numerals except for the portions described below. Functions and operations may be the same.
[0066]
The output buffer 314 switches whether to supply the main data output from the buffer memory (main) 308 to the expected value memory 320 or the expected value memory 400 based on the control of the sequence control unit 302. The expected value memory control unit 326 controls reading and writing of the expected value memory 320 and the expected value memory 400 by supplying a read signal and a write signal based on the control of the sequence control unit 302 (read control / write control). I do. The selector 406 selects one of the main data output from the expected value memory 320 and the main data output from the expected value memory 400 and supplies the selected data to the comparing unit 332. The comparing unit 332 compares the main data output from the buffer memory (main) 308 with the main data output from the expected value memory 320 or 400 on a bit-by-bit basis.
[0067]
Further, the output buffer 316 switches to which of the expected value memory 322 and the expected value memory 402 the pattern address output by the address counter 306 is supplied based on the control of the sequence control unit 302. The expected value memory control unit 328 controls reading and writing of the expected value memory 322 and the expected value memory 402 by supplying a read signal and a write signal based on the control of the sequence control unit 302 (read control / write control). I do. The selector 408 selects one of the pattern address output from the expected value memory 322 and the pattern address output from the expected value memory 402 and supplies the selected address to the comparing unit 334. The comparing unit 334 compares the pattern address output from the address counter 306 with the pattern address output from the expected value memory 322 or 402 in bit units.
[0068]
Further, the output buffer 318 switches to which of the expected value memory 324 and the expected value memory 404 the pattern data output from the buffer memory (PD) 312 is supplied based on the control of the sequence control unit 302. The expected value memory control unit 330 controls reading and writing of the expected value memory 324 and the expected value memory 404 by supplying a read signal and a write signal based on the control of the sequence control unit 302 (read control / write control). I do. The selector 410 selects one of the pattern data output from the expected value memory 324 and the pattern data output from the expected value memory 404 and supplies the selected data to the comparing unit 336. The comparison unit 336 compares the pattern data output from the buffer memory (PD) 312 with the pattern data output from the expected value memory 324 or 404 on a bit-by-bit basis.
[0069]
Hereinafter, the operation of the common processing unit 160 shown in FIG. 5, particularly the pattern error detection method, will be specifically described with reference to FIGS. First, the exposure processing of the frame area 202a shown in FIG. 2 is started. The buffer memory (main) 308 receives a first main address, which is an example of a control signal for exposing the band area 204a shown in FIG. 3, from the address counter 304, outputs the first main data, and outputs the first main data. To supply. At this time, the output buffer 314 supplies the first main data output from the buffer memory (main) 308 to the expected value memory 320. The expected value memory control unit 326 causes the expected value memory 320 to write the first main data when the buffer memory (main) 308 is outputting the first main data. Then, the expected value memory 320 stores the first main data output by the buffer memory (main) 308 based on the first main address.
[0070]
The buffer memory (PA) 310 receives a first main address, which is an example of a control signal for exposing the band area 204a shown in FIG. 3, from the address counter 304, and receives a first pattern start address and first number information. Is output to the address counter 306. Then, the address counter 306 outputs the first pattern address based on the first pattern start address and the first number information, and supplies the first pattern address to the buffer memory (PD) 312. At this time, the output buffer 316 supplies the first pattern address output from the address counter 306 to the expected value memory 322. The expected value memory control unit 328 causes the expected value memory 322 to write the first pattern address when the address counter 306 outputs the first pattern address. Then, the expected value memory 322 stores the first pattern address output by the address counter 306 based on the first main address.
[0071]
The buffer memory (PD) 312 receives a first pattern address, which is an example of a control signal for exposing the band area 204a shown in FIG. 3, from the address counter 306, outputs first pattern data, and performs individual control. To the unit 170a. At this time, the output buffer 318 supplies the first pattern data output from the buffer memory (PD) 312 to the expected value memory 324. The expected value memory control unit 330 causes the expected value memory 324 to write the first pattern data when the buffer memory (PD) 312 is outputting the first pattern data. Then, the expected value memory 324 stores the first pattern data output by the buffer memory (PD) 312 based on the first pattern address. Then, the exposure unit 150a exposes the band area 204a based on the first main data and the first pattern data supplied to the individual control unit 170a.
[0072]
Next, the buffer memory (main) 308 receives a second main address, which is an example of a control signal for exposing the band area 204b shown in FIG. 3, from the address counter 304, outputs second main data, and This is supplied to the control unit 170a. At this time, the output buffer 314 supplies the second main data output from the buffer memory (main) 308 to the expected value memory 400. The expected value memory control unit 326 causes the expected value memory 400 to write the second main data when the buffer memory (main) 308 is outputting the second main data. Then, the expected value memory 400 stores the second main data output by the buffer memory (main) 308 based on the second main address. Further, the expected value memory control unit 326 causes the comparing unit 332 to read the first main data from the expected value memory 320 when the buffer memory (main) 308 is outputting the second main data. Then, the comparing unit 332 compares the second main data output from the buffer memory (main) 308 with the first main data output from the expected value memory 320. That is, the comparison unit 332 compares the first main data output from the buffer memory (main) 308 based on the first main address with the second main data output from the buffer memory (main) 308 based on the second main address. Compare. Then, the comparing unit 332 supplies information indicating whether or not the first main data and the second main data are the same to the comparison result storage unit 337 as a comparison result. Then, the comparison result storage unit 337 stores the comparison result acquired from the comparison unit 334 in association with the identification information of the band area 204b.
[0073]
The buffer memory (PA) 310 receives a second main address, which is an example of a control signal for exposing the band area 204b shown in FIG. 3, from the address counter 304, and receives a second pattern start address and second number information. Is output to the address counter 306. Then, the address counter 306 outputs the second pattern address based on the second pattern start address and the second number information, and supplies the second pattern address to the buffer memory (PD) 312. At this time, the output buffer 316 supplies the second pattern start address and the second number information output from the address counter 306 to the expected value memory 402. The expected value memory control unit 328 causes the expected value memory 402 to write the second pattern address when the address counter 306 outputs the second pattern address. Then, the expected value memory 402 stores the second pattern address output by the address counter 306 based on the second main address. In addition, the expected value memory control unit 328 outputs a signal when the buffer memory (PA) 310 outputs the second pattern start address and the second number information, that is, when the address counter 306 outputs the second pattern address. , Causing the comparison unit 334 to read the first pattern address from the expected value memory 322. Then, the comparing unit 334 compares the second pattern address output from the address counter 306 with the first pattern address output from the expected value memory 322. That is, the comparing unit 334 compares the first pattern address output from the address counter 306 based on the first main address with the second pattern address output from the address counter 306 based on the second main address. Then, the comparison unit 334 supplies information indicating whether or not the first pattern address is the same as the second pattern address to the comparison result storage unit 337 as a comparison result. Then, the comparison result storage unit 337 stores the comparison result acquired from the comparison unit 334 in association with the identification information of the band area 204b.
[0074]
The buffer memory (PD) 312 receives a second pattern address, which is an example of a control signal for exposing the band area 204b shown in FIG. 3, from the address counter 306, outputs second pattern data, and performs individual control. To the unit 170a. At this time, the output buffer 318 supplies the second pattern data output from the buffer memory (PD) 312 to the expected value memory 404. The expected value memory control unit 330 causes the expected value memory 404 to write the second pattern data when the buffer memory (PD) 312 is outputting the second pattern data. Then, the expected value memory 404 stores the second pattern data output by the buffer memory (PD) 312 based on the second pattern address. Further, the expected value memory control unit 330 causes the comparing unit 336 to read the first pattern data from the expected value memory 324 when the buffer memory (PD) 312 is outputting the second pattern address. Then, the comparing unit 336 compares the second pattern data output from the buffer memory (PD) 312 with the first pattern data output from the expected value memory 324. That is, the comparison unit 336 compares the first pattern data output from the buffer memory (PD) 312 based on the first pattern address with the second pattern data output from the buffer memory (PD) 312 based on the second pattern address. Compare. Then, the comparison unit 336 supplies information indicating whether the first pattern data and the second pattern data are the same to the comparison result storage unit 337 as a comparison result. Then, the comparison result storage unit 337 stores the comparison result acquired from the comparison unit 334 in association with the identification information of the band area 204b. Then, the exposure unit 150a exposes the band area 204b based on the second main data and the second pattern data supplied to the individual control unit 170a.
[0075]
Next, the buffer memory (main) 308 receives a third main address, which is an example of a control signal for exposing the band area 204c shown in FIG. 3, from the address counter 304, outputs third main data, and This is supplied to the control unit 170a. At this time, the output buffer 314 supplies the third main data output from the buffer memory (main) 308 to the expected value memory 320. The expected value memory control unit 326 causes the expected value memory 320 to write the third main data when the buffer memory (main) 308 is outputting the third main data. Then, the expected value memory 320 stores the third main data output by the buffer memory (main) 308 based on the third main address. Further, when the buffer memory (main) 308 is outputting the third main data, the expected value memory control unit 326 causes the comparing unit 332 to read the second main data from the expected value memory 400. Then, the comparing unit 332 compares the third main data output from the buffer memory (main) 308 with the second main data output from the expected value memory 400. That is, the comparing unit 332 compares the second main data output by the buffer memory (main) 308 based on the second main address with the third main data output by the buffer memory (main) 308 based on the third main address. Compare. Then, the comparison unit 332 supplies information indicating whether the second main data is the same as the third main data to the comparison result storage unit 337 as a comparison result. Then, the comparison result storage unit 337 stores the comparison result acquired from the comparison unit 334 in association with the identification information of the band area 204c.
[0076]
The buffer memory (PA) 310 receives a third main address, which is an example of a control signal for exposing the band area 204c shown in FIG. 3, from the address counter 304, and receives a third pattern start address and third number information. Is output to the address counter 306. Then, the address counter 306 outputs the third pattern address based on the third pattern start address and the third number information, and supplies the third pattern address to the buffer memory (PD) 312. At this time, the output buffer 316 supplies the third pattern address output from the address counter 306 to the expected value memory 322. The expected value memory control unit 328 causes the expected value memory 322 to write the third pattern address when the address counter 306 is outputting the third pattern address. Then, the expected value memory 322 stores the third pattern address output from the address counter 306 based on the third main address. In addition, the expected value memory control unit 328 outputs a signal when the buffer memory (PA) 310 outputs the third pattern start address and the third number information, that is, when the address counter 306 outputs the third pattern address. , Causing the comparison unit 334 to read the second pattern address from the expected value memory 402. Then, the comparing unit 334 compares the third pattern address output from the address counter 306 with the second pattern address output from the expected value memory 402. That is, the comparing unit 334 compares the second pattern address output from the address counter 306 based on the second main address with the third pattern address output from the address counter 306 based on the third main address. Then, the comparison unit 334 supplies information indicating whether the second pattern address is the same as the third pattern address to the comparison result storage unit 337 as a comparison result. Then, the comparison result storage unit 337 stores the comparison result acquired from the comparison unit 334 in association with the identification information of the band area 204c.
[0077]
The buffer memory (PD) 312 receives a third pattern address, which is an example of a control signal for exposing the band area 204c shown in FIG. 3, from the address counter 306, outputs third pattern data, and performs individual control. To the unit 170a. At this time, the output buffer 318 supplies the third pattern data output from the buffer memory (PD) 312 to the expected value memory 324. The expected value memory control unit 330 causes the expected value memory 324 to write the third pattern data when the buffer memory (PD) 312 is outputting the third pattern data. Then, the expected value memory 324 stores the third pattern data output by the buffer memory (PD) 312 based on the third pattern address. Further, the expected value memory control unit 330 causes the comparing unit 336 to read the second pattern data from the expected value memory 404 when the buffer memory (PD) 312 is outputting the third pattern address. Then, the comparing unit 336 compares the third pattern data output from the buffer memory (PD) 312 with the second pattern data output from the expected value memory 404. That is, the comparison unit 336 compares the second pattern data output from the buffer memory (PD) 312 based on the second pattern address with the third pattern data output from the buffer memory (PD) 312 based on the third pattern address. Compare. Then, the comparison unit 336 supplies information indicating whether or not the second pattern data is the same as the third pattern data to the comparison result storage unit 337 as a comparison result. Then, the comparison result storage unit 337 stores the comparison result acquired from the comparison unit 334 in association with the identification information of the band area 204c. Then, the exposure unit 150a exposes the band area 204c based on the third main data and the third pattern data supplied to the individual control unit 170a.
[0078]
If the first main data and the second main data are the same and the second main data and the third main data are different, the error detection unit 338 determines that the first pattern address and the second pattern address are the same, When the second pattern address is different from the third pattern address, or when the first pattern data and the second pattern data are the same and the second pattern data is different from the third pattern data, the band area 204c is exposed. It is determined that there is an error in the exposure pattern and the overall control unit 330 is notified. In addition, when the first main data and the second main data are different and the second main data and the third main data are different, the error detection unit 338 determines that the first pattern address and the second pattern address are different and the second main data is different. When the pattern address and the third pattern address are different, or when the first pattern data and the second pattern data are different and the second pattern data and the third pattern data are different, the exposure pattern exposed to the band region 204b is It is determined that there is an error, and the overall control unit 300 is notified. When the first main data and the second main data are different and the second main data and the third main data are the same, the error detection unit 338 determines that the first pattern address and the second pattern address are different, When the second pattern address and the third pattern address are the same, or when the first pattern data and the second pattern data are different and the second pattern data and the third pattern data are the same, the band area 204a It is determined that there is an error in the exposed exposure pattern, and the overall control unit 300 is notified.
[0079]
According to the pattern error detection method according to this modification, the exposure data for exposing one band area is compared with the two exposure data for exposing the other two band areas, respectively. Error detection can be performed accurately.
[0080]
FIG. 6 shows a second modification of the common processing unit 160 according to the present embodiment. In this modified example, the same components as those of the common processing unit 160 shown in FIG. 4 are denoted by the same reference numerals, and the components denoted by the same reference numerals except for the portions described below. Functions and operations may be the same.
[0081]
The overall control unit 300 is an example of an expected value data generation unit of the present invention, and based on expected value data, which is an expected value of main data to be output by the buffer memory (main) 308 based on the main address, and based on the main address. The buffer memory (PD) 312 generates expected value data which is an expected value of pattern data to be output by the buffer memory (PD) based on the pattern address and expected value data which is an expected value of the pattern address to be output by the address counter 306. Then, the expected value memories 320, 322, and 324 receive and hold the expected value data generated by the overall control unit 300 via the system bus.
[0082]
The operation of the common processing unit 160 shown in FIG. 6, in particular, the pattern error detection method will be specifically described below with reference to FIGS. First, the overall control unit 300 outputs the first data to be output by the buffer memory (main) 308 based on the first main address which is an example of a control signal for exposing the band area included in the frame area 202a shown in FIG. First main expected value data, which is the expected value of the main data, is generated and supplied to the expected value memory 320. Then, the expected value memory 320 holds the first main expected value data generated by the overall control unit 300. Further, the overall control unit 300 generates first pattern address expected value data which is an expected value of the first pattern address to be output by the address counter 306 based on the first main address, and supplies the first pattern address expected value data to the expected value memory 322. Then, the expected value memory 322 holds the first pattern address expected value data generated by the overall control unit 300. Further, the overall control unit 300 generates first pattern expected value data which is an expected value of the first pattern data to be output from the buffer memory (PD) 312 based on the first pattern address, and supplies the first pattern expected value data to the expected value memory 324. I do. Then, the expected value memory 324 holds the first pattern expected value data generated by the overall control unit 300.
[0083]
Next, the exposure processing of the frame area 202a shown in FIG. 2 is started. The wafer stage 62 moves in the first direction (positive y-axis direction), and the exposure unit 150a exposes the frame area 202a while the wafer stage 62 moves in the first direction (positive y-axis direction). (First exposure process).
[0084]
The buffer memory (main) 308 receives a first main address, which is an example of a control signal for exposing the band area 204a shown in FIG. 3, from the address counter 304, outputs first main data, and outputs the first main data. It is supplied to the individual control unit 170a. The expected value memory control unit 326 causes the comparison unit 332 to read the first main expected value data from the expected value memory 320 when the buffer memory (main) 308 is outputting the first main data. Then, the comparing unit 332 compares the first main data output from the buffer memory (main) 308 with the first main expected value data output from the expected value memory 320. Then, the comparing unit 332 supplies information indicating whether or not the first main data and the first main expected value data are the same to the comparison result storage unit 337 as a comparison result. Then, the comparison result storage unit 337 stores the comparison result acquired from the comparison unit 334 in association with the identification information of the band area 204a.
[0085]
The buffer memory (PA) 310 receives a first main address, which is an example of a control signal for exposing the band area 204a shown in FIG. 3, from the address counter 304, and receives a first pattern start address and first number information. Is output to the address counter 306. Then, the address counter 306 outputs the first pattern address based on the first pattern start address and the first number information, and supplies the first pattern address to the comparison unit 334 and the buffer memory (PD) 312. When the buffer memory (PA) 310 outputs the first pattern start address and the first number information, that is, when the address counter 306 outputs the first pattern address, the expected value memory control unit 328 The comparison unit 334 reads the first pattern address expected value data from the value memory 322. Then, the comparing unit 334 compares the first pattern address output from the address counter 306 with the first pattern address expected value data output from the expected value memory 322. Then, the comparison unit 334 supplies information indicating whether or not the first pattern address and the first pattern address expected value data are the same to the comparison result storage unit 337 as a comparison result. Then, the comparison result storage unit 337 stores the comparison result acquired from the comparison unit 334 in association with the identification information of the band area 204a.
[0086]
The buffer memory (PD) 312 receives a first pattern address, which is an example of a control signal for exposing the band area 204a shown in FIG. 3, from the address counter 306, outputs first pattern data, and outputs the first pattern data. 336 and the individual control unit 170a. Also, the expected value memory control unit 330 causes the comparing unit 336 to read the first pattern expected value data from the expected value memory 324 when the buffer memory (PD) 312 is outputting the first pattern address. Then, the comparing unit 336 compares the first pattern data output from the buffer memory (PD) 312 with the first pattern expected value data output from the expected value memory 324. Then, the comparison unit 336 supplies information indicating whether or not the first pattern data and the first pattern expected value data are the same to the comparison result storage unit 337 as a comparison result. Then, the comparison result storage unit 337 stores the comparison result acquired from the comparison unit 334 in association with the identification information of the band area 204a. Then, the exposure unit 150a exposes the band area 204a based on the second main data and the second pattern data supplied to the individual control unit 170a. The band regions 204b and 204c are exposed while repeating the above comparison process.
[0087]
Next, after the exposure processing of the frame area 202a shown in FIG. 2, the processing proceeds to the exposure processing of the frame area 202b. After moving in the first direction (positive y-axis direction), the wafer stage 62 turns back, moves in the second direction (negative y-axis direction) opposite to the first direction (positive y-axis direction), and performs exposure. The unit 150a exposes the frame area 202b while the wafer stage 62 is moving in the second direction (y-axis negative direction) (second exposure processing).
[0088]
Before the second exposure processing, the overall control unit 300 determines whether the buffer memory (main) 308 is based on a fourth main address which is an example of a control signal for exposing the band area included in the frame area 202b shown in FIG. Fourth main expected value data which is an expected value of fourth main data to be output is generated, and a fourth pattern address expected value which is an expected value of a fourth pattern address to be output by the address counter 306 based on the fourth main address. Value data is generated, and fourth pattern expected value data that is an expected value of the fourth pattern data to be output by the buffer memory (PD) 312 is generated based on the fourth pattern address. Then, between the first exposure process and the second exposure process, the fourth main expected value data is supplied to the expected value memory 320, the fourth pattern address expected value data is supplied to the expected value memory 322, and the fourth pattern The expected value data is supplied to the expected value memory 324. Then, between the first exposure process and the second exposure process, the expected value memories 320, 322, and 324 store the fourth main expected value data, the fourth pattern address expected value data, and the fourth pattern address expected value data generated by the general control unit 300. The fourth pattern expected value data is read. Then, the exposure processing of the frame area 202b is started.
[0089]
FIG. 7 shows a third modification of the common processing unit 160 according to the present embodiment. The common processing unit 160 according to this modification includes expected value memories 400, 402, and 404 and selectors 406, 408, and 410 in addition to the components shown in FIG. In this modification, the same components as those of the common processing unit 160 shown in FIG. 6 are denoted by the same reference numerals, and the components denoted by the same reference numerals except for the portions described below. Functions and operations may be the same.
[0090]
The expected value memories 400, 402, and 404 receive and hold the expected value data generated by the general control unit 300 via the system bus, similarly to the expected value memories 320, 322, and 324.
[0091]
The expected value memory control unit 326 controls reading and writing of the expected value memory 320 and the expected value memory 400 by supplying a read signal and a write signal based on the control of the sequence control unit 302 (read control / write control). I do. The selector 406 selects one of the expected value data output from the expected value memory 320 and the expected value data output from the expected value memory 400 and supplies the selected value to the comparing unit 332. The comparing unit 332 compares the main data output from the buffer memory (main) 308 with the expected value data output from the expected value memory 320 or 400 on a bit-by-bit basis.
[0092]
The expected value memory control unit 328 supplies a read signal and a write signal based on the control of the sequence control unit 302 to control reading and writing of the expected value memory 322 and the expected value memory 402 (read control / write). Control). The selector 408 selects one of the expected value data output from the expected value memory 322 and the expected value data output from the expected value memory 402 and supplies the selected value to the comparing unit 334. The comparing unit 334 compares the pattern address output from the address counter 306 with the expected value data output from the expected value memory 322 or 402 in bit units.
[0093]
The expected value memory control unit 330 controls reading and writing (read control / write) of the expected value memory 324 and the expected value memory 404 by supplying a read signal and a write signal based on the control of the sequence control unit 302. Control). The selector 410 selects one of the expected value data output from the expected value memory 324 and the expected value data output from the expected value memory 404 and supplies the selected value to the comparing unit 336. The comparing unit 336 compares the pattern data output from the buffer memory (PD) 312 with the expected value data output from the expected value memory 324 or 404 on a bit-by-bit basis.
[0094]
Hereinafter, the operation of the common processing unit 160 shown in FIG. 7, particularly, the pattern error detection method will be specifically described with reference to FIGS. 2 and 3. First, the overall control unit 300 outputs the first data to be output by the buffer memory (main) 308 based on the first main address which is an example of a control signal for exposing the band area included in the frame area 202a shown in FIG. First main expected value data, which is the expected value of the main data, is generated and supplied to the expected value memory 320. Then, the expected value memory 320 holds the first main expected value data generated by the overall control unit 300. Further, the overall control unit 300 generates first pattern address expected value data which is an expected value of the first pattern address to be output by the address counter 306 based on the first main address, and supplies the first pattern address expected value data to the expected value memory 322. Then, the expected value memory 322 holds the first pattern address expected value data generated by the overall control unit 300. Further, the overall control unit 300 generates first pattern expected value data which is an expected value of the first pattern data to be output from the buffer memory (PD) 312 based on the first pattern address, and supplies the first pattern expected value data to the expected value memory 324. I do. Then, the expected value memory 324 holds the first pattern expected value data generated by the overall control unit 300.
[0095]
Next, the exposure processing of the frame area 202a shown in FIG. 2 is started. The wafer stage 62 moves in the first direction (positive y-axis direction), and the exposure unit 150a exposes the frame area 202a while the wafer stage 62 moves in the first direction (positive y-axis direction). (First exposure process).
[0096]
The buffer memory (main) 308 receives the first main address from the address counter 304, outputs the first main data, and supplies the first main data to the comparison unit 332 and the individual control unit 170a. The expected value memory control unit 326 causes the comparison unit 332 to read the first main expected value data from the expected value memory 320 when the buffer memory (main) 308 is outputting the first main data. Then, the comparing unit 332 compares the first main data output from the buffer memory (main) 308 with the first main expected value data output from the expected value memory 320. Then, the comparing unit 332 supplies information indicating whether or not the first main data and the first main expected value data are the same to the comparison result storage unit 337 as a comparison result. Then, the comparison result storage unit 337 stores the comparison result acquired from the comparison unit 334 in association with the identification information of the band area 204a.
[0097]
Further, the buffer memory (PA) 310 receives the first main address from the address counter 304, outputs a first pattern start address and first number information, and supplies them to the address counter 306. Then, the address counter 306 outputs the first pattern address based on the first pattern start address and the first number information, and supplies the first pattern address to the comparison unit 334 and the buffer memory (PD) 312. The expected value memory control unit 328 causes the comparing unit 334 to read the first pattern address expected value data from the expected value memory 322 when the address counter 306 outputs the first pattern address. Then, the comparing unit 334 compares the first pattern address output from the address counter 306 with the first pattern address expected value data output from the expected value memory 322. Then, the comparison unit 334 supplies information indicating whether or not the first pattern address and the first pattern address expected value data are the same to the comparison result storage unit 337 as a comparison result. Then, the comparison result storage unit 337 stores the comparison result acquired from the comparison unit 334 in association with the identification information of the band area 204a.
[0098]
Then, the buffer memory (PD) 312 receives the first pattern address from the address counter 306, outputs the first pattern data, and supplies the first pattern data to the comparison unit 336 and the individual control unit 170a. The expected value memory control unit 330 causes the comparing unit 336 to read the first pattern expected value data from the expected value memory 324 when the buffer memory (PD) 312 is outputting the first pattern data. Then, the comparing unit 336 compares the first pattern data output from the buffer memory (PD) 312 with the first pattern expected value data output from the expected value memory 324. Then, the comparison unit 336 supplies information indicating whether or not the first pattern data and the first pattern expected value data are the same to the comparison result storage unit 337 as a comparison result. Then, the comparison result storage unit 337 stores the comparison result acquired from the comparison unit 334 in association with the identification information of the band area 204a. Then, the exposure unit 150a exposes the band area 204a based on the first main data and the first pattern data supplied to the individual control unit 170a. The band regions 204b and 204c are exposed while repeating the above comparison process.
[0099]
Prior to the end of the first exposure processing, the overall control unit 300 controls the buffer memory (main) based on a fourth main address which is an example of a control signal for exposing the band area included in the frame area 202b shown in FIG. 308 generates fourth main expected value data which is the expected value of the fourth main data to be output, and the fourth pattern which is the expected value of the fourth pattern address to be output by the address counter 306 based on the fourth main address. Address expected value data is generated, and buffer pattern (PD) 312 generates fourth pattern expected value data, which is an expected value of the fourth pattern data to be output, based on the fourth pattern address. Then, during the first exposure process, the fourth main expected value data is supplied to the expected value memory 400, the fourth pattern address expected value data is supplied to the expected value memory 402, and the fourth pattern expected value data is supplied to the expected value memory 402. The data is supplied to the memory 404. During the first exposure process, the expected value memories 400, 402, and 404 store the fourth main expected value data, the fourth pattern address expected value data, and the fourth pattern expected value data generated by the general control unit 300. Respectively.
[0100]
Next, after the exposure processing of the frame area 202a shown in FIG. 2, the processing proceeds to the exposure processing of the frame area 202b. After moving in the first direction (positive y-axis direction), the wafer stage 62 turns back, moves in the second direction (negative y-axis direction) opposite to the first direction (positive y-axis direction), and performs exposure. The unit 150a exposes the frame area 202b while the wafer stage 62 is moving in the second direction (y-axis negative direction) (second exposure processing).
[0101]
The buffer memory (main) 308 receives the fourth main address from the address counter 304, outputs fourth main data, and supplies the fourth main data to the comparison unit 332 and the individual control unit 170a. The expected value memory control unit 326 causes the comparing unit 332 to read the fourth main expected value data from the expected value memory 400 when the buffer memory (main) 308 is outputting the fourth main data. Then, the comparing unit 332 compares the fourth main data output from the buffer memory (main) 308 with the fourth main expected value data output from the expected value memory 400. Then, the comparing unit 332 supplies information indicating whether or not the fourth main data is equal to the fourth main expected value data to the comparison result storage unit 337 as a comparison result. Then, the comparison result storage unit 337 stores the comparison result acquired from the comparison unit 334 in association with the band region identification information.
[0102]
Further, the buffer memory (PA) 310 receives the fourth main address from the address counter 304, outputs a fourth pattern start address and fourth number information, and supplies them to the address counter 306. Then, the address counter 306 outputs the first pattern address based on the fourth pattern start address and the fourth number information, and supplies the first pattern address to the comparison unit 334 and the buffer memory (PD) 312. The expected value memory control unit 328 causes the comparing unit 334 to read the fourth pattern address expected value data from the expected value memory 402 when the address counter 306 outputs the fourth pattern address. Then, the comparing unit 334 compares the fourth pattern address output from the address counter 306 with the fourth pattern address expected value data output from the expected value memory 402. Then, the comparison unit 334 supplies information indicating whether or not the fourth pattern address and the fourth pattern address expected value data are the same to the comparison result storage unit 337 as a comparison result. Then, the comparison result storage unit 337 stores the comparison result acquired from the comparison unit 334 in association with the band region identification information.
[0103]
Then, the buffer memory (PD) 312 receives the fourth pattern address from the address counter 306, outputs the fourth pattern data, and supplies the fourth pattern data to the comparison unit 336 and the individual control unit 170a. The expected value memory control unit 330 causes the comparing unit 336 to read the fourth pattern expected value data from the expected value memory 404 when the buffer memory (PD) 312 is outputting the fourth pattern data. Then, the comparing unit 336 compares the fourth pattern data output from the buffer memory (PD) 312 with the fourth pattern expected value data output from the expected value memory 404. Then, the comparison unit 336 supplies information indicating whether or not the fourth pattern data is identical to the fourth pattern expected value data to the comparison result storage unit 337 as a comparison result. Then, the comparison result storage unit 337 stores the comparison result acquired from the comparison unit 334 in association with the band region identification information. Then, the exposure unit 150a exposes the band area based on the fourth main data and the fourth pattern data supplied to the individual control unit 170a. The band region included in the frame region 202b is exposed while repeating the above comparison process.
[0104]
Before the end of the second exposure processing, the overall control unit 300 controls the buffer memory (main) based on a fifth main address which is an example of a control signal for exposing the band area included in the frame area 202c shown in FIG. 308 generates fifth main expected value data which is the expected value of the fifth main data to be output, and the fifth pattern which is the expected value of the fifth pattern address to be output by the address counter 306 based on the fifth main address. Address expected value data is generated, and fifth pattern expected value data that is an expected value of the fifth pattern data to be output by the buffer memory (PD) 312 is generated based on the fifth pattern address. Then, during the second exposure processing, the fifth main expected value data is supplied to the expected value memory 320, the fifth pattern address expected value data is supplied to the expected value memory 322, and the fifth pattern expected value data is supplied to the expected value memory 322. The data is supplied to the memory 324. Then, between the second exposure processing, the expected value memories 320, 322, and 324 store the fifth main expected value data, the fifth pattern address expected value data, and the fifth pattern expected value generated by the general control unit 300. Read each data.
[0105]
Next, after the exposure processing of the frame area 202b shown in FIG. 2, the processing proceeds to the exposure processing of the frame area 202c. After moving in the second direction (negative y-axis direction), the wafer stage 62 is further turned back and moves in the first direction (positive y-axis direction). While moving in the (y-axis positive direction), the frame area 202c is exposed (third exposure processing).
[0106]
In the third exposure process, the common processing unit 160 uses the fifth main expected value data, the fifth pattern address expected value data, and the fifth pattern expected value data stored in the expected value memories 320, 322, and 324, respectively. , The same processing as the first exposure processing is performed.
[0107]
According to the pattern error detection method according to this modification, the expected value memory is duplicated, and data can be read from the expected value memory and written into the expected value memory during the exposure process. An error in the exposure pattern can be detected without lowering the throughput of the exposure apparatus 100.
[0108]
In the present embodiment, the pattern error detection method when the electron beam exposure apparatus 100 exposes the wafer 64 by the OTF exposure method (continuous stage movement method) has been described. The present invention can also be applied to a case where the beam exposure apparatus 100 performs exposure for each chip area 200 of the wafer 64 by the SR exposure method (step and repeat method).
[0109]
As described above, the present invention has been described using the embodiment. However, the technical scope of the present invention is not limited to the scope described in the embodiment. Various changes or improvements can be added to the above embodiment. It is apparent from the description of the appended claims that embodiments with such changes or improvements can be included in the technical scope of the present invention.
[0110]
【The invention's effect】
As is apparent from the above description, according to the present invention, it is possible to provide an exposure apparatus and a pattern error detection method for accurately detecting an error of an exposure pattern exposed on a wafer.
[Brief description of the drawings]
FIG. 1 is a diagram showing an example of a configuration of an electron beam exposure apparatus 100.
FIG. 2 is a diagram showing an example of a frame area on a wafer 64.
FIG. 3 is a diagram illustrating an example of a band region on a wafer 64;
FIG. 4 is a diagram illustrating an example of a configuration of a control system 140.
FIG. 5 is a diagram illustrating a first modification of the common processing unit 160.
FIG. 6 is a diagram illustrating a second modification of the common processing unit 160.
FIG. 7 is a diagram illustrating a third modification of the common processing unit 160.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 ... case, 12 ... electron gun, 14 ... 1st electron lens, 16 ... slit part, 18 ... 1st deflector, 20 ... 2nd electron lens, 22 ... ..The second deflector, 24 ... the first blanking deflector, 26 ... the third deflector, 28 ... the third electron lens, 30 ... the mask, 32 ... the fourth electron lens , 34: fourth deflector, 36: second blanking deflector, 38: fifth deflector, 40: fifth electron lens, 42: sixth deflector, 46 ..The sixth electron lens, 48 ... the round aperture, 50 ... the seventh electron lens, 52 ... the eighth electron lens, 56 ... the main deflector, 58 ... the sub deflector, 60 ... ..Electron detectors, 62 ... wafer stage, 64 ... wafer, 66 ... ninth electron lens, 68 ... mask stay Driving unit 70 Wafer driving unit 72 Mask stage 82 Deflection control unit 84 Mask stage control unit 86 Blanking electrode control unit 88 Electron lens control unit, 90: reflection electron processing unit, 92: wafer stage control unit, 100: electron beam exposure apparatus, 110: electron beam irradiation system, 112: mask projection system, 114: focus adjustment lens system, 116: wafer projection system, 120: individual control unit, 140: control system, 150: exposure unit, 160: common processing unit, 170 ..Individual processing unit, 200: chip area, 202: frame area, 204: band area, 300: general control unit, 302: sequence control unit, 304, 306: address counter 308: buffer memory (main), 310: buffer memory (PA), 312: buffer memory (PD), 314, 316, 318 ... output buffer, 320, 322, 324 ... expectation Value memory, 326, 328, 330 ... expected value memory control unit, 332, 334, 336 ... comparison unit, 337 ... comparison result storage unit, 338 ... error detection unit, 400, 402, 404 ... Expected value memory, 406, 408, 410 ... Selector

Claims (15)

An exposure apparatus for exposing a desired exposure pattern on a wafer,
A buffer memory that holds exposure data that is data of an exposure pattern to be exposed on the wafer,
First exposure data output from the buffer memory based on a first control signal for exposing the first area, and second exposure data for exposing a second area where the same exposure pattern as the first area is to be exposed. A comparing unit that compares the second exposure data output from the buffer memory based on the second control signal;
An exposure apparatus, comprising: an error detection unit that detects an error of an exposure pattern exposed on the wafer based on a comparison result by the comparison unit. A first expectation value memory for holding the first exposure data output by the buffer memory;
2. The exposure apparatus according to claim 1, wherein the comparing unit compares the first exposure data output by the first expected value memory with the second exposure data output by the buffer memory. 3. 3. The device according to claim 2, wherein the comparing unit compares the first exposure data output by the first expected value memory and the second exposure data output by the buffer memory on a bit basis. 4. Exposure equipment. A comparison result storage unit that stores information indicating whether or not the first exposure data is the same as the second exposure data as the comparison result in association with the identification information of the second area;
3. The exposure apparatus according to claim 2, wherein the error detection unit detects an error of an exposure pattern exposed on the wafer based on the comparison result stored in the comparison result storage unit. The comparing unit is configured to perform the first exposure data output by the first expected value memory and a third control signal for exposing a third area to be exposed with the same exposure pattern as the first area. Comparing the third exposure data output by the buffer memory,
The comparison result storage unit stores information indicating whether the first exposure data and the second exposure data are the same, and information indicating whether the first exposure data and the third exposure data are the same. Stored as the comparison result,
When the first exposure data and the second exposure data are the same and the first exposure data and the third exposure data are different, the error detection unit determines whether the exposure pattern has been exposed to the third area. When it is determined that there is an error, and the first exposure data and the second exposure data are different and the first exposure data and the third exposure data are different, an error occurs in the exposure pattern exposed to the first area. 5. The exposure apparatus according to claim 4, wherein it is determined that there is an image. A wafer stage on which the wafer is placed, exposed while moving in the first direction, and then turned back to be exposed while moving in a second direction opposite to the first direction;
3. The exposure apparatus according to claim 2, wherein the first expected value memory writes the first exposure data output from the buffer memory when the wafer stage turns back. A second expected value memory for holding the second exposure data output from the buffer memory;
The comparing unit is configured to determine the second exposure data output from the second expected value memory and a third control signal for exposing a third area to be exposed with the same exposure pattern as the first area. The exposure apparatus according to claim 2, wherein the exposure apparatus compares the third exposure data output from the buffer memory. When the buffer memory is outputting the first exposure data, the first expected value memory is written with the first exposure data, and when the buffer memory is outputting the second exposure data, Causing the comparing section to read the first exposure data from the first expected value memory; and, when the buffer memory is outputting the third exposure data, storing the third exposure data in the first expected value memory. A first expected value memory control unit for writing
When the buffer memory is outputting the second exposure data, the second exposure data is written to the second expected value memory, and when the buffer memory is outputting the third exposure data, The exposure apparatus according to claim 7, further comprising a second expected value memory control unit that causes the comparison unit to read the second exposure data from the second expected value memory. A pattern error detection method for detecting an error of an exposure pattern exposed on a wafer,
An exposure step of exposing the wafer using first exposure data output by a buffer memory based on a first control signal for exposing the first area;
An exposure step of exposing the wafer using second exposure data output from the buffer memory based on a second control signal for exposing a second area where the same exposure pattern as the first area is to be exposed; ,
A comparing step of comparing the first exposure data with the second exposure data;
An error detection step of detecting an error of an exposure pattern exposed on the wafer based on a result of the comparison in the comparison step. An exposure apparatus for exposing a desired exposure pattern on a wafer,
A buffer memory that holds exposure data that is data of an exposure pattern to be exposed on the wafer,
An expected value data generation unit that generates first expected value data that is an expected value of exposure data to be output by the buffer memory based on a first control signal for exposing a first area;
A first exposure data output from the buffer memory based on the first control signal, and a comparing unit that compares the first expected value data generated by the expected value data generating unit;
An exposure unit that exposes the wafer based on the first exposure data output by the buffer memory;
An exposure apparatus, comprising: an error detection unit that detects an error of an exposure pattern exposed on the wafer based on a comparison result by the comparison unit. A first expectation value memory that holds the first expectation value data generated by the expectation value data generation unit;
11. The exposure apparatus according to claim 10, wherein the comparing unit compares the first expected value data output from the first expected value memory with the first exposure data output from the buffer memory. . A wafer stage on which the wafer is mounted;
The wafer stage is turned back after moving in a first direction, moves in a second direction opposite to the first direction,
The exposure unit performs a first exposure process while the wafer stage is moving in the first direction, and performs a first exposure process on the first region while the wafer stage is moving in the second direction. 2 exposure processing,
The exposure apparatus according to claim 11, wherein the first expected value memory writes the first expected value data between the first exposure processing and the second exposure processing. A wafer stage on which the wafer is mounted;
The wafer stage is turned back after moving in a first direction, moves in a second direction opposite to the first direction,
The exposure unit performs a first exposure process while the wafer stage is moving in the first direction, and then performs the first area while the wafer stage is moving in the second direction. Performs the second exposure processing of
12. The exposure apparatus according to claim 11, wherein the first expected value memory writes the first expected value data generated by the expected value data generation unit during the first exposure processing. A second expected value memory that holds second expected value data to be output by the buffer memory based on a second control signal for exposing a second area;
The wafer stage further moves back in the second direction after moving in the second direction, moves in the first direction,
The exposure unit performs the second exposure processing on the first area while the wafer stage is moving in the second direction, and then the wafer stage is moving in the first direction. In the meantime, a third exposure process of the second region is performed,
The comparing unit compares the first expected value data output by the first expected value memory with the first exposure data output by the buffer memory during the second exposure processing,
14. The exposure apparatus according to claim 13, wherein the second expected value memory writes the second expected value data generated by the expected value data generation unit during the second exposure processing. A pattern error detection method for detecting an error of an exposure pattern exposed on a wafer,
An expected value data generating step of generating first expected value data which is an expected value of exposure data to be output by the buffer memory based on a first control signal for exposing the first area;
A comparing step of comparing the first exposure data output by the buffer memory based on the first control signal with the first expected value data generated in the expected value data generating step;
An exposure step of exposing the wafer based on the first exposure data output by the buffer memory;
An error detection step of detecting an error of an exposure pattern exposed on the wafer based on a result of the comparison in the comparison step.

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