JP2003099771A - Data converter, its method, and program using it - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a data converter capable of greatly reducing a data conversion processing time when diagram data such as CAD data are converted into imaging data such as run length data and to provide a method of this converter and a program using this method. SOLUTION: In this data converter 1, all the CAD data used for imaging are sorted into a plurality of circuit patterns, and for each of the circuit patterns, pattern information and paging position information for imaging the respective circuit patterns are given. In the data converter 1, conversion into pattern run length data is carried out for each pattern information (step S15), and respective start points are computed (step S16). For each of the converted pattern run length data, the pattern run length data are allocated in an imaging area on the basis of the start point of the circuit pattern (step S20). In this way, a data conversion processing time can be reduced greatly.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data conversion device and method, and a program using the method. More specifically, it converts line drawing data such as CAD data into drawing data such as run length data. Data conversion device and method, and a program using the method.

[0002]

2. Description of the Related Art Conventionally, a mask film or mask plate used for manufacturing a printed circuit board generally has a desired pattern on a photosensitive mask base material by a drum scan type or flat bed type laser plotter. It is created by laser drawing (exposure). Further, in recent years, a direct drawing type laser plotter has been developed in which a photosensitive photoresist film is formed on the substrate itself of a printed circuit board and the photoresist film is subjected to laser drawing.

CAD data is generally used as the diagram data for creating the pattern of the drawing data to be drawn by the laser plotter. The CAD system is a design drawing system using a computer and is used in various fields. The CAD data created by this CAD system is used to draw the fine design pattern as described above. However, since the format of the input data of the laser plotter is different from the format of the output data of the CAD system, some data conversion is required.

For this data conversion, a data conversion device (image processing device) for creating run length data from CAD data is generally used. The outline of the data conversion will be described below. 15 is a flowchart showing the data conversion method, and FIG. 16 is a schematic diagram showing a process of generating run length data from CAD data by the data conversion.

In FIGS. 15 and 16, the data converter reads CAD data including the aperture data AP output from the CAD system and the trajectory data KD indicating the trajectory of the aperture data AP (step S201). As shown in FIG. 16A, the trajectory data KD is represented by the start point and end point of the vector in the case of straight line information, and the aperture data AP is the type of pen used for drawing (that is, the shape of the pen tip). Expressed. Further, format information and arrangement data are given to the data conversion device. Format information is C
The placement data includes information for defining the format of the AD data, and the placement data includes information (position, rotation, positive / negative, enlargement / reduction) when the CAD data is placed in the display area.

Next, as shown in FIG. 16 (b), the data conversion device draws the contour of the locus of the aperture data AP generated when the aperture data AP is moved based on the locus data KD. The locus data KD is represented by a vector (hereinafter referred to as a contour vector RV).
And the aperture data AP are converted into the contour vector RV (step S202). The contour vector RV
Are transformed so as to be formed in a clockwise direction in order from an arbitrary start point.

Next, as shown in FIG. 16 (c), the data converter converts the contour vector RV into the ON vector ON-V.
And OFF vector OFF-V (step S
203). In the sorting operation, when the scanning direction of the light beam of the laser plotter is the main scanning direction and the direction perpendicular to the main scanning direction is the sub scanning direction, the contour vector RV oriented in the sub scanning direction is the ON vector ON-V. Then, the contour vector RV oriented in the anti-sub-scanning direction is set to the OFF vector OFF-V.
And the contour vector RV perpendicular to the sub-scanning direction is deleted.

Next, the data conversion apparatus, as shown in FIG. 16 (d), for the ON vector ON-V and the OFF vector OFF-V created in step S203,
After reversing only the OFF vector OFF-V,
The respective starting points are sorted in ascending order in the sub-scanning direction (step S204). Here, sorting means rearranging data according to a predetermined standard. In the conventional example,
As a result of sorting, ON-V1 → OFF-V3 → OFF-V
They are rearranged in the order of 2 → ON-V2 → OFF-V1.

Next, as shown in FIG. 16 (e), the data conversion apparatus selects one scanning line in the main scanning direction from a plurality of scanning lines corresponding to the resolution of the laser plotter in the display area and at step S204. The intersection with the created vector is detected based on the sorting result, and the intersection with the ON vector ON-V is turned on and the OFF vector O is turned off.
Run length data is created by converting the intersection with FF-V into an OFF change point (step S20).
5). At this time, if the intersection does not match the scanning line in the sub-scanning direction, the intersection of the scanning line in the main scanning direction and the scanning line in the sub-scanning direction that is first detected by moving the intersection in the main scanning direction is , Are converted as the above change points (truncation processing). This run-length data changes the drawing data for each scanning line of the display area from the white area (non-exposed area) to the black area (exposed area) (O
Since the data is represented by a change point (N change point) and a change point (OFF change point) from a black area to a white area, the data is suitable for laser plotter drawing processing. Drawing can be performed line by line.

Next, the data conversion apparatus carries out step S20.
The change points converted in 5 are sorted in ascending order in the main scanning direction (step S206). Then, the data conversion device determines whether or not there is a vector that has not been converted to the run-length data (step S207), and if there is a vector that has not been converted, step S20.
The scanning line in the main scanning direction targeted by the conversion of 5 is targeted for another scanning line in the main scanning direction in the sub scanning direction (step S208), and the process returns to step S205. On the other hand, when the data conversion device determines in step S207 that all the vectors have been converted into run-length data, it sends all the converted run-length data to the laser plotter (step S209) and ends the flow.

[0011]

However, in recent years,
The printed circuit board to be drawn as described above is becoming higher in density and finer, and the data amount of the CAD data is also increased. In addition, in recent high-density and miniaturized circuits, BGA (Ball Grid Array) is used.
And TAB (Tape Automated Bond)
There are many patterns in which a plurality of the same circuit patterns of a small size are arranged in the drawing area. Even in such a case, regardless of the presence or absence of the plurality of arranged patterns in the drawing area, in the conventional method, after all the CAD data in the drawing area are vector-converted and sorted, the run-length data is converted. , The conversion process took a huge amount of time.

Therefore, an object of the present invention is to provide a data conversion device and method capable of greatly reducing the data conversion processing time when converting line drawing data such as CAD data into drawing data such as run length data. And to provide a program using the method.

[0013]

Means for Solving the Problems and Effects of the Invention In order to achieve the above object, the present invention has the following features. A first aspect of the present invention is a data conversion device that converts line drawing data including a plurality of line drawing patterns into drawing data that is suitable for drawing processing by a predetermined output machine. Pattern position data showing the position where the pattern is placed in the drawing area of the output machine,
A reading unit that reads in association with each other, a pattern drawing data generation unit that generates drawing data of a line drawing pattern based on the line drawing pattern, and a line drawing pattern generated by the pattern drawing data generation unit based on pattern position data And a pattern arranging unit for arranging each of the drawing data at the positions of the corresponding drawing areas.

According to the first aspect of the invention, when converting the line drawing data in which a plurality of line drawing patterns are allocated in the drawing area into the drawing data of the whole drawing area suitable for the drawing processing of a predetermined output machine, After the drawing data is converted into the drawing data by the line drawing pattern, the drawing data is allocated to respective allocated positions. Therefore, when the same line drawing pattern is included in the line drawing data, the area for converting the line drawing data into the drawing data is reduced, and the data conversion processing time can be greatly shortened.

A second invention is according to the first invention, wherein the drawing data includes a change point from a non-drawing pixel to a drawing pixel along a scanning line of an output machine and a drawing pixel to a non-drawing pixel. It is characterized in that it is run-length data describing the change point to.

According to the second invention, it is possible to convert into run length data which is drawing data which can be suitably used in an output machine such as a laser plotter. Further, since the drawing data is represented only by the change points of the drawing pixels and the non-drawing pixels for each reference line, the data conversion processing time can be greatly shortened.

A third invention is an invention according to the second invention, wherein the line drawing pattern at least overlaps with the filled line drawing pattern representing the basic line drawing shape pattern. And the outline placement pattern that deletes a part of the filled outline pattern, and the pattern placement unit arranges the run length data of the filled outline pattern and the outline diagram pattern in the drawing area. Further, it further includes a pattern synthesizing unit for performing a fill-out synthesizing process for deleting an area where the outline diagram patterns overlap with each other by using run length data.

According to the third aspect of the present invention, since the run-length data can be used for the fill-out composition, the data conversion processing time in the paint-out composition can be greatly shortened.

A fourth invention is an invention according to the second invention, wherein the pattern drawing data generating section is designed to reduce or thicken the image drawn by the output machine, and to execute the drawing pattern run. It further includes a thinning / thickening processing unit that performs processing of thinning or thickening the length data in at least one direction.

According to the fourth aspect of the invention, in the thinning / thickening process using run length data, the thinning process or the thickening process is performed for each line drawing pattern by simple subtraction or addition of the run length data. Since this is required, the data conversion processing time can be shortened as compared with the processing using vector data.

A fifth invention is according to the second invention, wherein the pattern drawing data generator further sorts the run length data generated for each line drawing pattern by a predetermined standard. The pattern arranging unit further sorts the run length data for the entire drawing area based on the result of sorting and the pattern position data for each line drawing pattern by the pattern drawing data generating unit.

According to the fifth aspect of the invention, as compared with the process of sorting the run length data of the entire drawing area, since the sorting result for each line drawing pattern is used, the area for sorting the run length data is reduced, and the sorting processing time is reduced. Is shortened.

A sixth aspect of the present invention is a data conversion method for converting line drawing data containing a plurality of the same line drawing patterns into drawing data suitable for drawing processing by a predetermined output machine.
A reading step of reading the line drawing pattern and the pattern position data indicating the position where each line drawing pattern is arranged in the drawing area of the output machine in association with each other, and the drawing data of the line drawing pattern is generated based on the line drawing pattern. And a pattern arranging step of arranging the drawing data of the line drawing pattern generated in the pattern drawing data generating step at the position of the drawing area corresponding to each pattern drawing data generating step.

A seventh invention is according to the sixth invention, wherein the drawing data includes a change point from a non-drawing pixel to a drawing pixel and a drawing pixel to the non-drawing pixel along a scanning line of the output machine. It is characterized in that it is run-length data describing the change point to.

An eighth invention is an invention according to the seventh invention, wherein the line drawing pattern at least overlaps the filled line drawing pattern representing the basic line drawing shape pattern and the filled line drawing pattern. And the outline drawing pattern that deletes a part of the outline drawing pattern, and the pattern arranging step includes the outline drawing pattern when the run length data of the outline drawing pattern and the outline drawing pattern is arranged in the drawing area. Further, the method further includes a pattern synthesizing step of processing the fill-out synthesizing process for deleting the area where the outline diagrams overlap with each other using the run length data.

A ninth invention is according to the seventh invention, and in the pattern drawing data generating step, the image drawn by the output machine is made thin or thick,
The method further includes a thinning / thickening processing step of performing processing of thinning or thickening the run length data of the line drawing pattern in at least one direction.

A tenth invention is an invention according to the seventh invention, and the pattern drawing data generating step further sorts the run length data generated for each line drawing pattern by a predetermined criterion. The pattern arranging step further sorts the run length data for the entire drawing area based on the sorting result and the pattern position data for each line drawing pattern in the pattern drawing data generating step.

An eleventh aspect of the invention is a data conversion program executed by a program for converting line drawing data containing a plurality of the same line drawing patterns into drawing data suitable for drawing processing by a predetermined output machine. Then, based on the diagram step, the reading step of reading the pattern pattern and the pattern position data indicating the position where each diagram pattern is arranged in the drawing area of the output machine in association with each other,
The pattern drawing data generation step for generating the drawing data of the line drawing pattern and the drawing data of the line drawing pattern generated in the pattern drawing data generation step based on the pattern position data are arranged at the positions of the corresponding drawing areas. And a pattern arranging step.

A twelfth aspect of the invention is an invention according to the eleventh aspect of the invention, wherein the drawing data includes a change point from a non-drawing pixel to a drawing pixel and a drawing pixel to a non-drawing pixel along a scanning line of the output machine. It is characterized in that it is run-length data describing the change point to.

A thirteenth invention is an invention according to the twelfth invention, wherein the line drawing pattern at least overlaps with the filled line drawing pattern representing the basic line drawing shape pattern. And the outline drawing pattern that deletes a part of the outline drawing pattern, and the pattern arranging step includes the outline drawing pattern when the run length data of the outline drawing pattern and the outline drawing pattern is arranged in the drawing area. Further, the method further includes a pattern synthesizing step of processing the fill-out synthesizing process for deleting the area where the outline diagrams overlap with each other using the run length data.

A fourteenth invention is an invention according to the twelfth invention, wherein the pattern drawing data generating step is performed in order to thin or thicken the image drawn by the output machine. The method further includes a thinning / thickening process step of performing a process of thinning or thickening the length data in at least one direction.

A fifteenth invention is according to the twelfth invention, and in the pattern drawing data generating step, the run length data generated for each line drawing pattern is further sorted by a predetermined criterion. The pattern arranging step further sorts the run length data for the entire drawing area based on the sorting result and the pattern position data for each line drawing pattern in the pattern drawing data generating step.

[0033]

1 is a block diagram showing the configuration of an exposure drawing system using a data conversion apparatus according to an embodiment of the present invention. CAD data is typically used as the diagram data used in the data conversion device. In FIG. 1, the data converter 1 is provided with CAD data including trajectory data and aperture data from an external CAD system (not shown) via an online transmission line 3. Further, CAD data including the trajectory data and the aperture data stored in the storage device 2 such as DAT is read and given to the data conversion device 1.
That is, the CAD data is given to the data conversion device 1 in the online or offline format. The data converter 1 converts the CAD data including the given trajectory data and aperture data into vector data, and further into run-length data, and outputs it to the laser plotter 4. The details of the data conversion performed by the data conversion device 1 will be described later.

FIG. 2 is a block diagram showing a more detailed structure of the data converter 1 in FIG. In FIG. 2, the data conversion device 1 includes a CPU 11, a program memory 12, and a RAM 13. An operation program of the CPU 11 is stored in the program memory 12, and the CPU 11 follows the operation program according to the operation program.
Execute a predetermined process. The program memory 12
May be composed of a ROM and pre-stored with a program, or may be a rewritable storage medium (RAM,
A hard disk, MOD), and the program may be installed before shipping. Further, the program may be downloaded to the program memory 12 via the online transmission path 3. RAM 13 is a CPU
11 stores various data necessary for executing a predetermined process.

FIG. 3 is a flow chart showing the operation of the data converter 1 in FIG. 4 to 11 are schematic diagrams showing the process of data conversion performed by the data conversion device 1. The operation of the data conversion device 1 will be described below with reference to FIGS. 3 and 4 to 11.

First, the CPU 11 of the data converter 1
The CAD data is read and stored in the RAM 13 (step S11). As shown in FIG. 4, the CAD data includes aperture data AP and trajectory data KD. The aperture data AP is represented by the type of pen used for drawing (that is, the shape of the pen tip), and the trajectory data KD represents the trajectory of the aperture data AP.
In the case of the straight line, the locus data KD represents information by a start point and an end point, and in the case of a circle, information is represented by a start point, an end point and a center point.

Further, the CPU 11 of the data converter 1 is provided with the format information and the arrangement data, and R
It is stored in the AM 13 (step S12). As shown in FIG. 5, the format information includes information for defining the format of CAD data, in which all the CAD data used for drawing are classified into a plurality of circuit patterns, and each circuit pattern is classified. Pattern information is also included as a diagram pattern obtained by grouping the CAD data. The above circuit pattern is based on the BGA (Ball G
for rid Array) and TAB (Tape Auto)
In many cases, there are a plurality of identical circuit patterns of a small size, such as for the case of material bonding, and when the CAD data includes a plurality of the same circuit patterns, one piece of the pattern information is provided for the circuit patterns. Correspond. Further, unlike the above-described circuit pattern having a plurality of identical ones, there are also individual patterns such as a character pattern indicating a character such as a manufacturing number and other graphic patterns.
Even such a single pattern is treated in the same manner as the above-mentioned circuit pattern, and the pattern information corresponds to each single pattern. In the example of FIG. 5, as the circuit pattern and the pattern information, the pattern information Pa is set for four circuit patterns A and B, respectively.
And Pb are included.

The layout data is information (position, rotation, positive / negative, information when the CAD data is arranged in the display area).
(Enlargement / reduction). When the format information includes the pattern information, the arrangement data includes the single pattern and each of the same circuit patterns as a reference drawing position to be drawn in the drawing area α in a predetermined coordinate system. It is included as coordinate data (hereinafter referred to as imposition position information). That is, since the imposition position information defines a position with respect to the drawing area α as pattern position data of the diagram pattern, the imposition position information and the position information of the drawing area α are created in the same coordinate system. . In the example of FIG. 5, as the imposition position information,
Imposition position information Ma for the pattern information Pa and Pb of the four circuit patterns A and B, respectively.
1-4 and Mb1-4 are included.

Next, the data conversion device 1 performs step S1.
From the given pattern information indicating the circuit pattern in 2, one pattern information is selected as a processing target in a predetermined order (step S13). Hereinafter, an example in which the pattern information Pa shown in FIG. 5 is selected will be described.

Next, the data converter 1 determines whether or not the pattern information having the same shape as the selected pattern information has already been converted into run length data (step S14). If it is determined in step S14 that the pattern information having the same shape as the selected pattern information has not been converted to run-length data, the process proceeds to the next step S15, and the pattern information of the same shape converted to run-length data is processed. If it is determined that there is pattern information, the process proceeds to step S16. That is, when the CAD data includes a plurality of pieces of pattern information of the same shape, the data converter 1 converts one piece of pattern information into run length data and the other piece of pattern information into run length data. do not do.

Next, the data converter 1 converts the selected pattern information into run length data (step S15). FIG. 12 is a subroutine showing details of the run length data conversion operation in step S15. The operation of the data converter 1 will be described below with reference to FIG.

In FIG. 12, first, the data converter 1
As shown in FIG. 6, when the locus data KD and the aperture data AP of the circuit pattern corresponding to the pattern information selected in step S13 are read and the aperture data AP is moved based on the locus data KD, The contour of the locus of the generated aperture data AP is represented by a vector (hereinafter, referred to as a contour vector RV) to perform vector conversion (step S151).
The contour vector RV is converted so as to be formed in the clockwise direction with reference to each drawing line. However, in the case of the loop-shaped pattern shown in FIG. 6, since it is formed in the clockwise direction with respect to each drawing line (that is, the upper side, the lower side, the left side, and the right side), the outer contour vector R
V is formed clockwise, and the inner contour vector RV is formed counterclockwise.

Next, the data converter 1 sets the contour vector RV to the ON vector ON-V and OF as shown in FIG.
F vector OFF-V is selected (step S15).
2). Here, the drawing area α of the laser plotter 4 in FIG. 1 is in the scanning direction (main scanning direction) of the light beam represented by the resolution of the laser plotter 4 and in the direction perpendicular to the main scanning direction (sub scanning direction). The image is generated by distinguishing whether or not the intersection of the scanning lines in each direction is divided by a plurality of scanning lines and is exposed by the laser plotter 4. In the sorting operation, the contour vector RV oriented in the sub-scanning direction is changed to the ON vector ON-V,
A contour vector RV oriented in the sub-scanning direction is defined as an OFF vector OFF-V, and a contour vector R perpendicular to the sub-scanning direction is set.
V is deleted.

Next, as shown in FIG. 8, the data conversion apparatus 1 turns ON the ON vector created in step S152.
OFF for -V and OFF vector OFF-V
After inverting the direction of only the vector OFF-V, sorting is performed in the ascending order of the sub-scanning direction of each starting point (step S
153). Here, sorting means rearranging data according to a predetermined standard.

Next, as shown in FIG. 9, the data converting apparatus 1 sets 1 in the main scanning direction for a plurality of scanning lines corresponding to the resolution of the laser plotter 4 in the drawing area α described above.
An intersection between the scan line and the vector created in step S153 is detected based on the sorting result, an intersection with the ON vector ON-V is an ON transition point, and an intersection with the OFF vector OFF-V is an OFF transition point. Is converted into run-length data for all the vectors intersecting the one scanning line (step S1).
54). The run length data is created by detecting the intersection of one scan line in the main scanning direction and the vector created in step S153, and determining the intersection with the ON vector ON-V as the ON transition point and the OFF vector OFF-V. Run length data is created by converting the intersection point with and to the OFF change point by truncation processing. If the end point of the vector to be converted and the intersection of the scan lines match,
The process of converting the intersection to each change point is not performed,
Delete the intersection.

Here, the truncation processing means that when the intersection with the above vector does not coincide with the scanning line in the sub-scanning direction,
This means that the intersection of the scanning line in the main scanning direction and the scanning line in the sub scanning direction that is first detected by moving the intersection with the vector in the main scanning direction is converted as the change point. The truncation process is performed by moving the intersection of the scanning line in the sub-scanning direction and the vector in the anti-main scanning direction. The intersection of the scanning line in the main-scanning direction and the scanning line in the sub-scanning direction that is first detected. May be converted as the above-mentioned change point. As the truncation processing of the data processing device 1, by setting the direction in which the intersection is moved to either one direction, run length data can be created regardless of which direction is set.

The run length data is the ON change point, which is the change point from the non-drawing pixel to the draw pixel, and the change point, which is the change point from the draw pixel to the non-draw pixel, in the draw data for each scanning line in the display area. It is data representing an OFF change point. That is, the run-length data is obtained by changing the drawing data for each scanning line from the white area (non-exposed area) to the black area (exposed area) (ON change point) and from the black area to the white area (change point). Since the data is represented by (OFF change point), it is suitable for the drawing process of the laser plotter 4, and the laser plotter 4 can perform drawing for each line according to the given run length data.

Next, the data conversion device 1 performs step S1.
The change points of one scanning line converted in 54 are sorted in ascending order in the main scanning direction (step S155). Then, the data conversion device 1 determines whether or not there is a vector that has not been converted into run-length data in the circuit pattern corresponding to the selected pattern information (step S15).
6) If there is still a vector that has not been converted, the scanning line in the main scanning direction targeted in the conversion in step S154 is targeted for another scanning line in the main scanning direction (step S157). ), Step S1
Return to 54. On the other hand, the data conversion device 1 uses step S1.
When it is determined that all the vectors have been converted into run-length data in 56, with respect to all the run-length data (hereinafter, referred to as pattern run-length data) obtained by converting the circuit pattern corresponding to the selected pattern information, It is determined whether there is a request for thinning processing or thickening processing (step S158). The details of the thinning process and the thickening process and step S159.
Will be described later.

Then, the data conversion device 1 carries out step S.
If there is no request for thinning or thickening at 158,
The pattern run length data is stored in the RAM 13 (step S160), and the flow ends.

Returning to FIG. 3, the data converter 1 calculates the run length data corresponding to the selected pattern information by replacing the start point with the coordinates of the drawing area α (step S16). Here, the start point is a starting point for scanning the drawing area in which the run length data is indicated, and is the scan in the drawing area of the pattern information, which is the most anti-sub-scanning direction and the most anti-main scanning direction. It is the intersection of the lines. The data conversion apparatus 1 calculates the start point by replacing it with the intersection point coordinates of the scanning line of the drawing area α of the laser plotter 4 based on the imposition position information acquired in step S12. Here, the intersection point coordinates are represented by the intersection point coordinates (X, Y) with the sub-scanning direction as the X direction and the main scanning direction as the Y direction, and the start point SP replaced with the intersection point coordinates. For example, in step S16, if the selected pattern information Pa is converted into run length data Ra and the run length data Ra corresponds to the imposition position information Ma1,
The start point SPa1 (Xa1, Ya1) is calculated.

Next, the data conversion device 1 determines whether or not there is pattern information for which the start point has not been calculated yet (step S17). If there is pattern information that has not been calculated yet, another pattern information for which the start point has not been calculated is selected based on a predetermined reference (step S18), and the process returns to step S14. on the other hand,
If there is no pattern information for which the start point has not been calculated, the process proceeds to the next step S19.

Then, the data converter 1 creates the imposition table by sorting the pattern information converted into run-length data and associated with the start point SP in ascending order of the X coordinate of the start point SP. Yes (step S19). FIG. 10 shows an example in which the above-mentioned pattern information Pa and Pb are converted into run-length data Ra and Rb and registered in the imposition table based on their start points SP. The data conversion device 1 uses, as the imposition table,
Start points SPa1 (Xa1, Ya1) to SP for the run length data Ra and Rb, respectively.
a4 (Xa4, Ya4) and SPb1 (Xb1, Yb
1) to SPb4 (Xb4, Yb4) are registered in the ascending order of the X coordinate of the start point SP.

Next, the data converter 1 allocates run length data for each scanning line in the main scanning direction in the ascending order of the sub scanning direction (step S20). First, the data converter 1 determines one scanning line in the main scanning direction to be assigned in ascending order of the sub scanning direction, and the pattern run length in which the X coordinate of the start point SP of the imposition table matches the X coordinate of the scanning line. Determine the data as the allocation target (if multiple matches, target multiple pattern run length data). Then, the data conversion device 1 detects the run length data in the scan line only for the pattern run length data that is the allocation target, and allocates it to the drawing area α. At this time, the run length data to be allocated is converted to the coordinates of the intersection of the drawing area α based on the coordinates of the intersection of the start point SP and then allocated. Then, the data conversion apparatus 1 changes the scan lines to be allocated in ascending order in the sub-scanning direction, and allocates to all the pattern run length data that are the allocation targets. When the new pattern run length data becomes the allocation target due to the change of the scan line, the data conversion device 1 also allocates the pattern run length data. Then, the data conversion device 1
Finishes the allocation of run length data for all the scanning lines in the drawing area α, and proceeds to the next step.

FIG. 11 shows that in step S20,
FIG. 6 is a diagram in which pattern run length data Ra and Rb are assigned to a drawing area α. In FIG. 11, the pattern run length data Ra of the four circuit patterns A is
Each is assigned to the drawing area α based on the start points SPa1 to SPa4. The pattern run length data Rb of the four circuit patterns B are assigned to the drawing area α based on the start points SPb1 to SPb4, respectively.

Next, the data conversion device 1 performs step S2.
The run length data of the entire drawing area α assigned with 0 is output to the laser plotter 4 (step S21), and the flow is ended.

As described above, according to the data conversion apparatus in the embodiment of the present invention, the CAD data to which a plurality of the same circuit patterns are allocated is used for the run length of the entire drawing area suitable for the drawing process of the laser plotter. When converting into data, after vector conversion and run length conversion with the above circuit pattern, the respective positions are allocated in the state of run length data. Therefore, the area for performing the vector conversion and the run length data conversion is reduced, and the data conversion processing time can be significantly shortened.

In the present invention, when a plurality of circuit patterns are allocated to the drawing area, they are allocated to respective positions in the state of being converted into run length data (hereinafter, run length data allocation). A method of allocating the CAD data described in step S151 to each allocation position in the state of being converted into the contour vector (hereinafter, vector data allocation) is also conceivable. However, when the present invention is compared with the above vector data allocation, the present invention has the following effects.

First, in the above vector data allocation,
After assigning each contour vector to the drawing area, it is necessary to convert the entire drawing area into run length data. However, in the present invention, since conversion to run length data is performed for each circuit pattern, there is little area for performing run length data conversion, and conversion to run length data for the entire drawing area is unnecessary. Data conversion processing time is short.

Further, the above circuit pattern has a plurality of CADs.
It is often the case that data is formed by compositing on top of each other. For example, the final circuit pattern is formed by synthesizing the fill data forming the basic structure of the circuit pattern with the blank data for deleting a part of the fill data at the allocation process in step S18. To be done. FIG. 13 is a diagram showing an example of combining the fill data and the blank data by the vector data allocation.

In FIG. 13A, the circuit pattern X
Is the above-mentioned painting data and is indicated by the contour vector RVx. On the other hand, the circuit pattern Y is the above-mentioned blank data and is indicated by the contour vector RVy. The circuit patterns X and Y are circuit patterns arranged in the drawing area based on the same imposition position information M.

FIG. 13B is a diagram in which the circuit patterns X and Y are allocated to the drawing area based on the imposition position information M. Here, the contour vectors RVx and RVy are in a state where they have not been combined yet and simply overlapped.

FIG. 13C is a diagram showing a state in which the contour vectors RVx and RVy arranged in FIG. 13B are combined to create a new contour vector RVxy. As described above, since the contour vector RVx is the fill data and the contour vector RVy is the blank data, the above-mentioned combination is processed by the fill-out combination. This blanking composition is a composition in which only the area where the blank data overlaps with the fill data is deleted. FIG. 13B and FIG.
Comparing with (c), the outline vector RV which is the extraction data in the fill-out composition by the vector data allocation.
deletion of a vector that is not included in the overlapping region with respect to y, processing of connecting the contour vectors RVx and RVy to each other, processing of deleting a part of vector data, etc.
Since the above-mentioned blanking composition must be calculated with vector data, the data processing is complicated and the data processing takes time.

On the other hand, FIG. 14 is a diagram showing an example of synthesizing the fill data and the extracted data by the run length data allocation.

In FIG. 14A, the circuit pattern X
Is the above-mentioned paint data and is indicated by the run length data Rx. On the other hand, the circuit pattern Y is the above-mentioned omitted data and is indicated by the run length data Ry. The respective circuit patterns X and Y are circuit patterns arranged in the drawing area based on the start point SP in which the coordinates of the drawing area to be allocated are the same, and the run length data Rx and Ry have black circles ON. The change points and white circles indicate the OFF change points.

FIG. 14B is a diagram in which the circuit patterns X and Y are assigned to the drawing area based on the start point SP. Here, the run length data Rx and Ry have not been combined yet and are simply placed in a superposed manner.

FIG. 14C is a diagram showing a state in which the run length data Rx and Ry arranged in FIG. 14B are combined to create new run length data Rxy. As described above, since the run-length data Rx is the fill data and the run-length data Ry is the blank data, the above-mentioned combination is processed by the fill-out combination. Comparing FIG. 14 (b) and FIG. 14 (c), in the fill-out composition by the run-length data allocation, the run-length data Rx is the run-length data R for the ON area.
It is calculated by the exclusive OR of y. That is, in the run length data allocation, the run length data Rx is OFF.
For the area of, the run length data Ry is simply deleted, and for the area of which the run length data Rx is ON,
Since the run length data Ry is simply processed by exclusive OR, the data processing time can be significantly shortened as compared with the vector data allocation.

In the data conversion apparatus 1, the above-described operation of the fill-out composition is performed when the pattern run length data in step S20 of FIG. 3 described above is allocated to the drawing area based on the start point. That is, when the pattern run length data to be allocated do not overlap with each other, the data conversion device 1 performs only the operation of allocating based on the imposition position information, and the pattern run length data overlaps with each other to perform the above-mentioned blanking composition. If applicable, the above-mentioned run-length data allocation is used to perform the fill-out composition to allocate it to the drawing area.

In addition, the circuit pattern may be adjusted to the etching conditions when the pattern forming body such as a printed board is etched with a copper foil or the like, or the CAD
In order to approximate the line width drawn to the design value of the data,
Thinning processing or thickening processing for thinning or thickening an image drawn by a laser plotter or the like may be performed in advance. In such a case, in the vector data allocation, it is necessary to calculate the above-described thinning processing or thickening processing for each circuit pattern with vector data, and the data processing is complicated and the time required for the data processing is the same as the above-mentioned composition. It takes. On the other hand, in the run-length data allocation of the present invention, the thinning processing or the thickening processing described above for each circuit pattern can be obtained by simple subtraction or addition of the run-length data, so that the data processing time is shorter than the vector data allocation. it can.

In the data converter 1, the thinning or thickening process is performed in step S159 of FIG. 12 described above. If the data conversion apparatus 1 wants to thin or thicken the image for the reason described above, the thinning or thickening processing is performed in step S158 by inputting the thinning or thickening amount in advance. And judge
It proceeds to step S159. After that, the data converter 1
Performs the thinning or thickening processing using the pattern run length data described above based on the thinning or thickening amount (step S159), and the pattern run length data subjected to the thinning or thickening processing. RAM
13 (step S150), and the flow ends.

In the above description, an example in which the data conversion device converts CAD data to run length data as drawing data has been shown, but the drawing data may be converted to bitmap data. Further, although the example in which the run length data converted by the data conversion device is used for the drawing process of the laser plotter or the like is shown, the data conversion device can also be used for purposes other than the drawing process. For example, the drawing pixel data represented by the run length data output from the data conversion device can be used as the master data of the appearance inspection device to perform the comparison inspection with the run length data which is the imaged data of the inspection object. Further, by using other format data such as bitmap data output from the data conversion device as the master data and performing a comparison inspection with the bitmap data etc. which is the imaging data of the inspection object, the same appearance can be obtained. It can be used for comparison inspection of inspection devices.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of an exposure drawing system using a data conversion device according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration of a data conversion device 1 in FIG.

FIG. 3 is a flowchart showing an operation of the data conversion device 1 in FIG.

FIG. 4 is a schematic diagram showing a process of data conversion performed by the data conversion device 1.

FIG. 5 is a schematic diagram showing a process of data conversion performed by the data conversion device 1.

FIG. 6 is a schematic diagram showing a process of data conversion performed by the data conversion device 1.

FIG. 7 is a schematic diagram showing a process of data conversion performed by the data conversion device 1.

FIG. 8 is a schematic diagram showing a process of data conversion performed by the data conversion device 1.

FIG. 9 is a schematic diagram showing a process of data conversion performed by the data conversion device 1.

FIG. 10 shows that the data conversion device 1 uses the run length data R.
Converted to a and Rb, each start point S
It is a figure which shows the example registered into the imposition table based on P.

FIG. 11 is a schematic diagram showing a process of data conversion performed by the data conversion device 1.

FIG. 12 is a subroutine showing details of the run-length data conversion operation in step S15 of FIG.

FIG. 13 is a diagram showing an example of combining fill data and blank data by vector data allocation.

FIG. 14 is a diagram showing an example of combining fill data and blank data by assigning run length data.

FIG. 15 is a flowchart showing a conventional data conversion method.

FIG. 16 is a schematic diagram showing a process of generating run length data from CAD data by conventional data conversion.

[Explanation of symbols]

1 ... Data converter 11 ... CPU 12 ... Program memory 13 ... RAM 2 ... Storage device 3 ... Transmission line 4 ... Laser plotter AP ... Aperture data KD ... Locus data M: Imposition position information OFF-V ... OFF vector ON-V ... ON vector P ... pattern information R ... Run length data RV ... contour vector α: drawing area

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Toshihiro Sato             4-chome Tenjin, which runs up to Teranouchi, Horikawa-dori, Kamigyo-ku, Kyoto             1 Kitamachi No. 1 Dai Nippon Screen Manufacturing Co., Ltd.             Inside the company F-term (reference) 2H095 BB01 BB08                 5B057 CA12 CA17 CB12 CB18 CF01                       CF02 CF04 CG09                 5B080 EA00 GA28

Claims (15)

[Claims] 1. A data converter for converting line drawing data including a plurality of line drawing patterns into drawing data suitable for drawing processing by a predetermined output machine, wherein the line drawing pattern and each line A reading unit for reading pattern position data indicating a position where the figure pattern is arranged in the drawing area of the output machine in association with each other, and a pattern drawing for generating the drawing data of the line drawing pattern based on the line drawing pattern A data generating unit; and a pattern arranging unit for arranging the drawing data of the line drawing pattern generated by the pattern drawing data generating unit on the basis of the pattern position data at respective positions of the drawing area. , Data converter. 2. The drawing data is run-length data which describes a change point from a non-drawing pixel to a drawing pixel and a change point from a drawing pixel to a non-drawing pixel along a scanning line of the output device. The data conversion device according to claim 1, wherein: 3. The line drawing pattern is at least a filled-out line drawing pattern representing a basic line-drawing shape pattern, and a part of the filled-out line drawing pattern is deleted by overlapping with the filled-out line drawing pattern. And a line drawing pattern, wherein the pattern placement unit arranges the run length data of the filled line pattern and the outline line pattern in the drawing area, and the outline line pattern with respect to the filled line pattern. The data conversion apparatus according to claim 2, further comprising a pattern synthesis unit that performs a fill-out synthesis process that deletes an overlapping region using the run-length data. 4. The pattern drawing data generation unit thins or thickens the run length data of the diagram pattern in at least one direction in order to thin or thicken an image drawn by the output machine. Thinning / processing
The data processing device according to claim 2, further comprising a thickening processing unit. 5. The pattern drawing data generation unit further performs sorting by rearranging the run length data generated for each of the line drawing patterns on a predetermined basis, and the pattern arrangement unit further includes the pattern drawing data. 3. The run length data is sorted for the entire drawing area based on the sorting result of each of the line drawing patterns of the generation unit and the pattern position data.
The data converter described in 1. 6. A data conversion method for converting line drawing data including a plurality of line drawing patterns into drawing data suitable for drawing processing by a predetermined output machine, wherein the line drawing pattern and each line A reading step of reading pattern position data indicating a position where the drawing pattern is arranged in the drawing area of the output machine in association with each other; and pattern drawing for generating the drawing data of the line drawing pattern based on the line drawing pattern A data generating step; and a pattern arranging step of arranging the drawing data of the line drawing pattern generated in the pattern drawing data generating step on the basis of the pattern position data at respective positions of the drawing area , Data conversion method. 7. The drawing data is run-length data which describes a change point from a non-drawing pixel to a drawing pixel and a change point from a drawing pixel to a non-drawing pixel along a scanning line of the output machine. The data conversion method according to claim 6, wherein: 8. The line drawing pattern is at least a painted line drawing pattern that represents a basic line drawing shape pattern, and a blanking pattern that deletes a part of the painted line drawing pattern by overlapping with the filled line drawing pattern. Including the line drawing pattern, the pattern arranging step, when the run length data of the filled line drawing pattern and the outline drawing pattern is arranged in the drawing area, the outline drawing pattern with respect to the filled line drawing pattern. 8. The data conversion method according to claim 7, further comprising a pattern synthesizing step of processing a fill-out synthesizing process for deleting an overlapping region by using run length data. 9. The pattern drawing data generating step thins or thickens the run length data of the diagram pattern in at least one direction in order to thin or thicken an image drawn by the output machine. The data processing method according to claim 7, further comprising a thinning / thickening processing step of performing processing. 10. The pattern drawing data generating step further performs sorting by rearranging the run length data generated for each of the line drawing patterns according to a predetermined reference, and the pattern arranging step further includes the pattern drawing data. 8. The data conversion method according to claim 7, wherein the run length data is sorted for the entire drawing area based on the sorting result for each of the diagram patterns in the generating step and the pattern position data. 11. A data conversion program executed by a computer, which converts drawing data including a plurality of drawing patterns into drawing data suitable for drawing processing by a predetermined output machine, wherein the drawing pattern And a reading step of reading pattern position data indicating a position where each of the line drawing patterns is arranged in the drawing area of the output machine in association with each other, and the drawing data of the line drawing pattern based on the line drawing pattern. A pattern drawing data generating step for generating the pattern drawing data, and a pattern for arranging the drawing data of the line drawing pattern generated in the pattern drawing data generating step on the basis of the pattern position data at positions corresponding to the drawing areas. A data conversion program including a placement step. 12. The drawing data is run-length data describing a change point from a non-drawing pixel to a drawing pixel and a change point from a drawing pixel to a non-drawing pixel along a scanning line of the output machine. The data conversion program according to claim 11, wherein: 13. The line drawing pattern is at least a painted line drawing pattern that represents a basic line drawing shape pattern, and a blanking line pattern that overlaps the painted line drawing pattern to delete a part of the painted line drawing pattern. Including the line drawing pattern, the pattern arranging step, when the run length data of the filled line drawing pattern and the outline drawing pattern is arranged in the drawing area, the outline drawing pattern with respect to the filled line drawing pattern. 13. The data conversion program according to claim 12, further comprising a pattern synthesis step of performing a fill-out synthesis process that deletes an overlapping region using the run-length data. 14. The pattern drawing data generating step thins or thickens the run length data of the diagram pattern in at least one direction in order to thin or thicken an image drawn by the output machine. 13. The method according to claim 12, further comprising a thinning / thickening processing step for performing processing.
The data processing program described in. 15. The pattern drawing data generating step further performs sorting by rearranging the run length data generated for each of the line drawing patterns according to a predetermined reference, and the pattern arranging step further includes the pattern drawing data. The data conversion program according to claim 12, wherein the run length data is sorted for the entire drawing area based on the sorting result for each of the line drawing patterns in the generating step and the pattern position data.