Figure data verification apparatus and method therefor

A figure data verification apparatus includes an operation part configured to input design data and writing data converted from the design data and perform an exclusive OR operation between data of a figure included in the design data and data of a figure included in the writing data, a sorting part configured to sort figures produced as a result of the exclusive OR operation to at least one arbitrary-angle figure having at least one angle not being an integral multiple of 45 degrees and to at least one non-arbitrary-angle figure all angles of which are integral multiples of 45 degrees, a first removal part configured to remove a figure of a size smaller than a first allowable error value from the arbitrary-angle figure, and a second removal part configured to remove a figure of a size smaller than a second allowable error value from the non-arbitrary-angle figure.

CROSS-REFERENCE TO RELATED APPLICATION

This application is based upon and claims the benefit of priority from the prior Japanese Patent Application No. 2007-007082 filed on Jan. 16, 2007 in Japan, the entire contents of which are incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a verification apparatus and method for figure data. For example, the present invention relates to a verification apparatus and method for figure data defined by writing data used for electron beam writing.

2. Description of the Related Art

Microlithography technique, which forwards miniaturization of semiconductor devices, is extremely important because only this process performs forming a pattern in semiconductor manufacturing processes. In recent years, with an increase in high integration and large capacity of large-scale integrated circuits (LSI), a circuit line width required for semiconductor elements is becoming narrower and narrower. In order to form desired circuit patterns on these semiconductor devices, a master pattern (also called a mask or a reticle) with high precision is required. Then, since the electron beam technique for writing or “drawing” a figure has excellent resolution essentially, it is used for manufacturing such high precision master patterns.

FIG. 17shows a schematic diagram describing operations of a conventional variable-shaped electron beam (EB) pattern writing apparatus. In the variable-shaped electron beam pattern writing apparatus, writing is performed as follows: A first aperture plate410has an opening or “hole”411in the shape of a rectangle, for example, for shaping an electron beam330. This shape of the rectangular opening may also be a square, a rhombus, a rhomboid, etc. A second aperture plate420has a variable-shaped opening421for shaping the electron beam330having passed through the opening411410into a desired rectangular. The electron beam330that left a charge particle source430and has passed through the opening411is deflected by a deflector. Then, the electron beam330passes through a part of the variable-shaped opening421, and irradiates a target workpiece or “sample”340mounted on a stage that is continuously moving in one predetermined direction (e.g. X-axis direction). In other words, a rectangular shape capable of passing through both the opening411and the variable-shaped opening421is written in a writing region of the target workpiece340. This method of writing or “forming” a given shape by letting beams pass through both the opening411and the variable-shaped opening421is referred to as a “variable shaping” method. The electron beam pattern writing apparatus of variable shaping type is disclosed in articles.

In performing electron beam writing, first a layout of a semiconductor integrated circuit is designed, and layout data (design data) for writing the design is generated. Then, the layout data is converted to generate writing data to be input into an electron beam pattern writing apparatus. Further, the writing data is converted into data of a format to be used in the electron beam pattern writing apparatus to write a pattern.

As a method for verifying whether EB data generated by converting CAD data is in accordance with the original CAD data or not, the following is disclosed in an article which describes an electron beam exposure apparatus. An exclusive OR (XOR) operation, etc. are performed between LSI design data (CAD data) and EB data generated by converting the LSI design data. Then, it is judged based on an output of the XOR operation whether the number of figures is 0 or not. When the number of figures is not 0, it operates so as to efficiently judge whether there was any conversion error at the time of data conversion or not (for example, refer to Japanese Unexamined Patent Publication No. 2001-344302 (JP-A-2001-344302)).

When converting design data into writing data, a figure which cannot be formed by using the shape of a beam forming aperture plate is approximated to a figure in accordance with the shape of the beam forming aperture plate. For example, when a pattern writing apparatus has an aperture of a triangle or a rectangle with an angle of 45 degrees, an arbitrary-angle figure that means a triangle or a rectangle having at least one angle not being an integral multiple of 45 degrees is divided into trapezoids or rectangles with an angle being an integral multiple of 45 degrees. More specifically, the triangle or a rectangle having the diagonal line portion at the angle not being an integral multiple of 45 degrees of the arbitrary-angle figure is divided into trapezoids or rectangles with an angle being an integral multiple of 45 degrees. This dividing is herein called a slit-like dividing or a slit-like division.

FIG. 18shows an example of the design data. CAD data210shown inFIG. 18is mixedly composed of non-arbitrary-angle figures214and215that mean a triangle or a rectangle all angles of which are integral multiples of 45 degrees, a figure group217and an arbitrary-anglefigure 216.

FIG. 19shows an example of the writing data after the conversion. Writing data220shown inFIG. 19is mixedly composed of non-arbitrary-angle figures223,225and228, a figure group227, and a slit-like divided figure group226being a non-arbitrary-angle figure group made by slit-like dividing the arbitrary-angle figure. Thefigure 228is smaller than each figure constituting the figure group226.

An exclusive OR (XOR) operation is performed as data verification after the conversion. If a position, a shape, etc. of a figure in the data do not change before and after the data conversion, the number of figures should become zero as the operation result. Therefore, when no figure is output as the operation result, it can be thought that no conversion error (defect) was generated. However, in the case of actually converting data, it is necessary to perform processing such as approximating an arbitrary-angle figure by a slit-like division, and converting values depending upon a change of an address unit (AU). For this reason, an operation result in a mixed state is output. Concretely, in the operation result, an error portion of the approximated figure (arbitrary-angle figure), a conversion error portion of the address unit (AU), and a conversion error portion (defect portion) which is required to obtain are intermingled. This mixed result is usually displayed on a monitor, etc. to be visually checked by a user. However, when a large number of figures are displayed as the operation result, there is a limit in judging all the figures visually. Furthermore, there is a problem in that such checking takes a lot of time and there may be checking omission.

Accordingly, it has been tried to remove figures smaller than a certain size in order to remove allowable error portions and to reduce the number of figures.FIG. 20shows an example of the operation result. As shown inFIG. 20, figures244and246are illustrated as discrepancy portions having displacement between thefigure 214and the displacedfigure 223. Afigure 228, which does not exist in the design data210but is generated by some sort of defect in the writing data220, is also shown as a discrepancy portion. Moreover, an arbitrary-angle figure group242is shown as a discrepancy portion having displacement between the arbitrary-anglefigure 216and the slit-like divided figure group226. For the sake of brevity, it is assumed herein that no AU error is generated in the conversion. The approximation by slit-like dividing the arbitrary-angle figure is executed so that a figure difference before and after the conversion may be within a predetermined allowable error. Therefore, if a figure at the discrepancy portion of the arbitrary-angle figure outputted as the operation result is within the allowable error, the figure can be disregarded as an error. In order to remove an error portion within the allowable error of the arbitrary-angle figure, figures of the size equal to or smaller than the allowable error are deleted. Such operation result is shown inFIG. 21. According to this method, however, it becomes difficult to find other error figures smaller than the allowable error value of the arbitrary-angle figure. For example, in the case shown inFIG. 21, though thefigure 228is an error figure intrinsically, it is impossible to detect it.

BRIEF SUMMARY OF THE INVENTION

It is an object of the present to provide a verification method for highly precisely verifying a conversion error.

In accordance with one aspect of the present invention, a figure data verification apparatus includes a first sorting part configured to input design data and sort figures included in the design data to at least one arbitrary-angle figure having at least one angle not being an integral multiple of 45 degrees and to at least one non-arbitrary-angle figure all angles of which are integral multiples of 45 degrees, a second sorting part configured to input writing data converted from the design data, and sort figures included in the writing data to at least one first figure corresponding to the at least one arbitrary-angle figure and to at least one second figure corresponding to the at least one non-arbitrary-angle figure, a first operation part configured to perform an exclusive OR operation between data of the arbitrary-angle figure and data of the first figure, a second operation part configured to perform an exclusive OR operation between data of the non-arbitrary-angle figure and data of the second figure, a first removal part configured to remove a figure of a size smaller than a first allowable error value from at least one figure produced as a result of the exclusive OR operation between the data of the arbitrary-angle figure and the data of the first figure, and a second removal part configured to remove a figure of a size smaller than a second allowable error value from at least one figure produced as a result of the exclusive OR operation between the data of the non-arbitrary-angle figure and the data of the second figure.

In accordance with another aspect of the present invention, a figure data verification apparatus includes an operation part configured to input design data and writing data converted from the design data and perform an exclusive OR operation between data of a figure included in the design data and data of a figure included in the writing data, a sorting part configured to sort figures produced as a result of the exclusive OR operation to at least one arbitrary-angle figure having at least one angle not being an integral multiple of 45 degrees and to at least one non-arbitrary-angle figure all angles of which are integral multiples of 45 degrees, a first removal part configured to remove a figure of a size smaller than a first allowable error value from the at least one arbitrary-angle figure, and a second removal part configured to remove a figure of a size smaller than a second allowable error value from the at least one non-arbitrary-angle figure.

Moreover, in accordance with another aspect of the present invention, a figure data verification method includes inputting design data, inputting writing data converted from the design data, sorting figures included in the design data to at least one arbitrary-angle figure having at least one angle not being an integral multiple of 45 degrees and to at least one non-arbitrary-angle figure all angles of which are integral multiples of 45 degrees, sorting figures included in the writing data to at least one first figure corresponding to the at least one arbitrary-angle figure and to at least one second figure corresponding to the at least one non-arbitrary-angle figure, performing an exclusive OR operation between data of the arbitrary-angle figure and data of the first figure, performing an exclusive OR operation between data of the non-arbitrary-angle figure and data of the second figure, removing a figure of a size smaller than a first allowable error value from at least one figure produced as a result of the exclusive OR operation between the data of the arbitrary-angle figure and the data of the first figure, and removing a figure of a size smaller than a second allowable error value from at least one figure produced as a result of the exclusive OR operation between the data of the non-arbitrary-angle figure and the data of the second figure.

Furthermore, in accordance with another aspect of the present invention, a figure data verification method includes inputting design data, inputting writing data converted from the design data, performing an exclusive OR operation between data of a figure included in the design data and data of a figure included in the writing data, sorting figures produced as a result of the exclusive OR operation to at least one arbitrary-angle figure having at least one angle not being an integral multiple of 45 degrees and to at least one non-arbitrary-angle figure all angles of which are integral multiples of 45 degrees, removing a figure of a size smaller than a first allowable error value from the at least one arbitrary-angle figure, and removing a figure of a size smaller than a second allowable error value from the at least one non-arbitrary-angle figure.

DETAILED DESCRIPTION OF THE INVENTION

In the following Embodiments, a structure using an electron ray (electron beam) as an example of a charged particle ray (charged particle beam) will be described. The charged particle ray is not restricted to the electron ray, but may be a beam using other charged particle, such as an ion beam.

FIG. 1is a schematic diagram showing an example of a system configuration described in Embodiment 1. As shown inFIG. 1, a layout of a semiconductor integrated circuit is designed first. Then, CAD data (design data)10used as layout data is generated. The CAD data10is converted in a conversion device20to generate writing data12to be input into an electron beam pattern writing apparatus. The writing data12is converted into input format data of the electron beam pattern writing apparatus which writes a figure pattern onto a target workpiece by using an electron beam. Further, the writing data12is converted to data of a format to be used in the electron beam pattern writing apparatus to write a pattern. A data verification apparatus200verifies whether there is any difference between the CAD data10and the writing data12which is converted from the CAD data. The data verification apparatus200includes a verification part100, a monitor102, and an interface (I/F) circuit104. The verification part100inputs the CAD data10and the writing data12, performs an exclusive OR (XOR) operation, and outputs a result data14to the outside through the I/F circuit104or displays the result data14on the monitor102. It is possible for the user to verify a figure accordance or discordance before and after the conversion by checking the result data14.

FIG. 2is a schematic diagram showing an example of the internal structure of a data verification apparatus described in Embodiment 1. The verification part100inFIG. 2includes a CAD data sorting circuit112(first sorting part), a writing data sorting circuit114(second sorting part), a memory106, an XOR operation circuit122(first operation part), an XOR operation circuit124(second operation part), an error removal circuit132(first removal part), and an error removal circuit134(second removal part).

First, as an input step, the verification part100inputs the CAD data10. Then, the inputted CAD data10is sent to the CAD data sorting circuit112. On the other hand, the verification part100inputs the writing data12which was converted from the CAD data10.

FIG. 3shows an example of figures included in the CAD data according to Embodiment 1. As shown inFIG. 3, an arbitrary-anglefigure 150, meaning a figure having at least one angle not being an integral multiple of 45 degrees, non-arbitrary-angle figures144and146, and a figure group148are mixed in the CAD data10. The arbitrary-angle figure herein means a figure having an angle portion which cannot be formed by using the beam forming aperture plate of the pattern writing apparatus. For example, if the pattern writing apparatus has a beam forming aperture plate which can form angles of 45 degrees and 90 degrees, the arbitrary angle θ is to be other than 45 degrees and 90 degrees, that is 0°<θ<45°, 45°<θ<90°, 90°<θ<135°, 135°<θ<180°, 180°<θ<225°, 225°<θ<270°, 270°<θ<315°, and 315°<θ<360°. Then, the non-arbitrary angle is an integral multiple of 45 degrees that can be formed by the beam forming aperture plate. Moreover, for example, if the pattern writing apparatus has a beam forming aperture plate which can form only an angle of 90 degrees, the arbitrary angle θ is to be other than 90 degrees, that is 0°<θ<90°, 90°<θ<180°, 180°<θ<270°, and 270°<θ<360°. In this case, the non-arbitrary angle is 90 degrees which can be formed by the beam forming aperture plate.

FIG. 4shows an example of figures included in the writing data after the conversion described in Embodiment 1. As shown inFIG. 4, non-arbitrary-angle figures164,166, and167, a figure group168, and a slit-like divided figure group170of non-arbitrary-angle figures made by slit-like dividing the arbitrary-angle figure are mixed in the writing data12. At the time of conversion, a figure with an angle larger than 90 degrees is divided into a combination of trapezoids and/or rectangles with the angles of 40, 90, and 130 degrees according to need.

The inputted writing data12is sent to the writing data sorting circuit114. InFIG. 2, although the data is directly input into each sorting circuit, it may be input through the I/F circuit104.

Next, as a sorting step, the CAD data sorting circuit112sorts the figures included in the CAD data12into at least one arbitrary-angle figure and at least one non-arbitrary-angle figure.FIG. 5shows the non-arbitrary-angle figures included in the CAD data shown inFIG. 3.FIG. 6shows the arbitrary-angle figure included in the CAD data shown inFIG. 3. InFIG. 5, only the non-arbitrary-angle figures included in the CAD data10are left to be defined. That is, only the figures144, and146and the figure group148are defined. The CAD data sorting circuit112creates a file42in which only the non-arbitrary-angle figures are defined, and stores it in the memory106. InFIG. 6, only the arbitrary-anglefigure 150included in the CAD data10is newly defined. The CAD data sorting circuit112creates a file32in which only the arbitrary-anglefigure 150is defined, and stores it in the memory106.

On the other hand, the writing data sorting circuit114sorts the figures included in the writing data12into a figure group (at least one first figure) for the arbitrary-angle figures mentioned above and a figure group (at least one second figure) for the non-arbitrary-angle figure mentioned above.

FIG. 7shows a figure group corresponding to the non-arbitrary-angle figures included in the writing data shown inFIG. 4.FIG. 8shows a slit-like divided figure group corresponding to the arbitrary-angle figure included in the writing data shown inFIG. 4. InFIG. 7, only the figures corresponding to the non-arbitrary-angle figures included in the writing data12are left to be defined. That is, only the figures164,166, and167and the figure group168are defined. The writing data sorting circuit114creates a file44in which only the non-arbitrary-angle figures are defined, and stores it in the memory106. InFIG. 8, only the slit-like divided figure group170corresponding to the arbitrary-angle figure included in the writing data12is newly defined. The writing data sorting circuit114creates a file34in which only the slit-like divided figure group170is defined, and stores it in the memory106.

Next, as an XOR operation step, the XOR operation circuit122reads the data file32of the arbitrary-angle figure, and the data file34of the slit-like divided figure group from the memory106. Then, an XOR operation is performed between the data of the arbitrary-angle figure included in the file32and the data of the slit-like divided figure group included in the file34. On the other hand, the XOR operation circuit124reads the data file42of the non-arbitrary-angle figure, and the data file44of the non-arbitrary angle from the memory106. Then, an XOR operation is performed between the data of the non-arbitrary-angle figure included in the file42and the data of the non-arbitrary angle included in the file44.

As a removal step, the error removal circuit132removes figures of the size smaller than a first allowable error value from the figures produced as a result of the operation between the data of the arbitrary-angle figure and the data of the slit-like divided figure group corresponding to the arbitrary-angle figure data. It is preferable to use an approximation error value of the arbitrary angle portion as the first allowable error value. Since the approximation error value of the arbitrary angle portion can be estimated to some extent from the conversion parameter, it is suitable to use the value as the first allowable error value.

FIG. 9shows an example of the operation result of the arbitrary angle portion described in Embodiment 1. When a conversion error occurred between the figures shown inFIG. 6andFIG. 8, an arbitrary-angle figure group186being an error amount of the arbitrary angle remains and is output as result data51as shown inFIG. 9. Thus, when there is a figure of the size larger than the approximation error value of the arbitrary angle portion, it can be detected as an error figure. If the arbitrary angle is appropriately approximated within the allowable error, since the arbitrary-angle figure group186is removed, no figure is output as the result data51. In that case, it can be judged that no conversion error has been generated with respect to the arbitrary angle portion.

On the other hand, the error removal circuit134removes figures of the size smaller than a second allowable error value from the figures produced as a result of the operation between the data of the non-arbitrary-angle figure and the data of the figure corresponding to the non-arbitrary-angle figure data. It is preferable to use the maximum error value which is estimated to be generated in converting an AU, as the second allowable error value. In particular, as the second allowable error value, it is preferable to use the maximum of the error generated when rounding the values in the AU conversion.

Furthermore, the first allowable error value is a value of the error which can be assumed to be generated by the slit-like dividing of the arbitrary angle and is generally larger than the second allowable error.

FIG. 10shows an example of the figure on the grid of CAD data, and the figure on the grid of writing data. InFIG. 10, afigure 80is defined by a grid71which is drawn in lattice by the AU of the CAD data10. When thefigure 80is converted into the writing data12, it becomes afigure 82. Thefigure 82is defined by a grid73which is drawn in lattice by the AU of the writing data12. An error arises before and after this data conversion by the change of the AU.

FIG. 11shows a figure obtained by enlarging a part of the figure inFIG. 10. Since the defined figures depend upon the AU of each data, an error ±0.5 of the AU may be generated as shown inFIG. 11. Therefore, such error of one AU serves as a conversion error value of the AU. Thus, by removing figures of the size smaller than the conversion error value of the AU, it becomes possible to eliminate the figures produced by the error.

FIG. 12shows the AU conversion error portion detected as a result of the XOR operation of the figure ofFIG. 10. Afigure 84of the area shown in slash lines is a figure produced by the AU conversion error. The amount of data to be verified can be reduced by removing the figure produced by this AU conversion error from the XOR operation result.

FIG. 13shows an example of an operation result of the non-arbitrary angle portion described in Embodiment 1. Since there is a displacement between the figures144and164inFIGS. 5 and 7, figures182and184showing the displaced amount are output as the result data53. Furthermore, as the error value is herein set up independently of the arbitrary-angle figure, the figures167of the size smaller than the approximation error value of the arbitrary angle portion can also be detected as an error figure. Since the AU conversion error in the case of the error figure becoming the minimum is set up as a threshold, an error detection can be performed in high precision.

As an output step, the verification part100outputs a result after the removal. The output may be outputted outside through the I/F circuit104or may be displayed on the monitor102. Owing to the configuration stated above, it becomes possible to perform highly precise data verification.

The approximation error value of the arbitrary angle part is not herein restricted to being set as a unique value. The approximation error value of the arbitrary angle portion may be changed according to a value of the arbitrary angle. That is, as the first allowable error value, it is preferable to use a different value according to the value of the arbitrary angle.

FIG. 14shows a relation between the arbitrary angle and the error value described in Embodiment 1. As shown inFIG. 14, by grouping angles according to a predetermined extent, an approximation error value of the arbitrary angle portion is set for each group. For example, an error value α1 is used for the degrees from 0 to less than or equal to 30. An error value α2 is used for the degrees from greater than 30 to less than or equal to 60 degrees. An error value α3 is used for the degrees from greater than 60 to less than or equal to 90 degrees. With respect to degrees subsequent to 90 degrees, it may be set similarly. It is also preferable for the error removal circuit132to perform processing by use of the error value of the corresponding group according to the angle of the arbitrary-angle figure.

As mentioned above, according to the present Embodiment, since the figures are sorted into the arbitrary-angle figure and the non-arbitrary-angle figure, it is possible to independently set up the size of the figure to be removed in the area where the arbitrary-angle figures are arranged and in the area where the non-arbitrary-angle figures are arranged. Therefore, in the area where the non-arbitrary-angle figures are arranged, an error figure smaller than the arbitrary angle error can be discovered. Accordingly, a conversion error can be verified with high precision.

In the above Embodiment 1, an XOR operation is performed after sorting the figures into the arbitrary-angle figure and the non-arbitrary-angle figure. However, it is not limited thereto. In the configuration according to the present Embodiment 2, figures are sorted into the arbitrary-angle figure and the non-arbitrary-angle figure after performing an XOR operation, which will be described below.

FIG. 15is a schematic diagram showing an example of the internal structure of a data verification apparatus described in Embodiment 2. InFIG. 15, the verification part100includes a sorting circuit116(sorting part), the memory106, an XOR operation circuit126(operation part), the error removal circuit132(first removal part), and the error removal circuit134(second removal part).

First, as an input step, the verification part100inputs the CAD data10. Then, the inputted CAD data10is sent to the XOR operation circuit126. On the other hand, the verification part100inputs the writing data12which was converted from the CAD data10. The inputted writing data12is also sent to the XOR operation circuit126. InFIG. 15, although the XOR operation circuit126inputs the data directly, it is also acceptable to input the data through the I/F circuit104.

As an XOR operation step, the XOR operation circuit126performs an XOR operation between the data of a figure included in the CAD data10and the data of a figure included in the writing data12. This process is repeated for all the figures included in the CAD data10. That is, this process is repeated for all the figures included in the writing data12.

Next, as a sorting step, the sorting circuit116sorts the figures produced as a result of the operation into at least one arbitrary-angle figure and at least one non-arbitrary-angle figure. Then, if an XOR operation is performed between the arbitrary-angle figure and a slit-like divided figure, the arbitrary-angle figure certainly remains. Therefore, when there is an arbitrary-angle figure included in the operation result, it can be judged that the area concerned has been the arbitrary angle part from the first. The sorting circuit116creates a file61in which only the arbitrary-angle figures are defined, and stores it in the memory106. On the other hand, the sorting circuit116creates a file63in which only the non-arbitrary-angle figures are defined, and stores it in the memory106.

As a removal step, the error removal circuit132reads the file61, in which only the arbitrary-angle figures are defined, from the memory106. Then, figures of the size smaller than a first allowable error value are removed from the figures defined in the file61. As well as Embodiment 1, it is preferable to use an approximation error value of the arbitrary angle portion as the first allowable error value.

On the other hand, the error removal circuit134reads the file63, in which only the non-arbitrary-angle figures are defined, from the memory106. Then, figures of the size smaller than a second allowable error value are removed from the figures defined in the file63. As well as Embodiment 1, it is preferable to use an Au conversion error value as the second allowable error value.

As an output step, the verification part100may just output a result after the removal like Embodiment 1.

Even with the configuration described above, since the arbitrary-angle figure and the non-arbitrary-angle figure independently set up the error values respectively, it is possible to perform highly precise data verification like Embodiment 1.

What is represented by the word “part”, “circuit”, or “step” in the above description can be configured by a computer program. It may be executed by a software program, or alternatively by any combination of software, hardware and/or firmware. When configured by a program, the program is recordable on a recording medium, such as a magnetic disk drive, a magnetic tape drive, an FD, or a ROM (Read Only Memory).

FIG. 16is a block diagram showing an example of a hardware structure when configured by a program. A CPU50being a computer, through a bus74, is connected to a RAM (Random Access Memory)52, a ROM54, a magnetic disk (HD) drive62, a keyboard (K/B)56, a mouse58, an external interface (I/F)60, a monitor64, a printer66, an FD68, a DVD70, and a CD72. The RAM52, ROM54, magnetic disk (HD) drive62, FD68, DVD70, and CD72are examples of a storage device. The keyboard (K/B)56, mouse58, external interface (I/F)60, FD68, DVD70, and CD72are examples of an input means. The external interface (I/F)60, monitor64, printer66, FD68, DVD70, and CD72are examples of an output means. It may be configured so that operations performed by each circuit in the verification part100can be executed by the CPU50. Then, input data operated in the CPU50may be stored in a storage device such as the RAM52.

As mentioned above, the embodiments have been described with reference to concrete examples. However, the present invention is not limited these concrete examples.

Moreover, although description of the apparatus structure, control method, etc. not directly required for explaining the present invention is omitted, it is possible to suitably select and use some or all of them when needed. For example, as to the structure of the data verification apparatus200, it should be understood that a necessary control unit structure can be appropriately selected and used.

In addition, any generation method of electron beam writing data, conversion method of electron beam writing data, and devices therefor that include elements of the present invention and that can be appropriately modified by those skilled in the art are included within the scope of the present invention.