JPH09325985A - Pattern gap calculator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To speedily secure a minimum gap through a little processes by classifying the form of arrangement between a pair of line patterns into parallel relationship, fan-shaped relation or zigzag relationship and respectively calculating the minimum gap between these respective line patterns through 1st, 2nd and 3rd arithmetic means. SOLUTION: In the respective line patterns, straight lines L1 and L2 are generated by extending center line segments AB and CD of these patterns. When the straight lines L1 and L2 are parallel, the 1st arithmetic means calculates a minimum gap G between the line patterns by discriminating whether the line segments AB and CD are mutually overlapped or not. When the straight lines L1 and L2 are fan-shaped, the 2nd arithmetic means finds the absolute value of shorter distance between the end points of the line segments AB and CD and defines a value subtracting double edge width (d) from that value as the minimum gap G. Further, when the straight lines L1 and L2 are zigzag- positioned, the 3rd arithmetic means finds the absolute value of a distance between the closest end points and defines a value subtracting the double edge width (d) from that absolute value as the minimum gap G.

Description

Detailed Description of the Invention

The present invention relates to a pattern gap calculating device and a pattern gap calculating method for calculating a minimum gap between line patterns of a constant width formed on a printed wiring board.

[0002]

2. Description of the Related Art A design value of a gap between patterns arranged on a printed wiring board must be secured at a certain value or more in consideration of factors such as manufacturing tolerances and insulation resistance. The line pattern is usually formed with a constant pattern width. The gap between the two patterns can be determined by calculating the distance between the contour lines of the two patterns and determining the shortest distance.

[0003]

However, the method of calculating the minimum gap from the distance between the contour lines of the pattern is complicated in processing. The present invention has been made in view of such conventional problems, and provides a pattern gap calculating device and a pattern gap calculating method capable of quickly calculating a minimum gap for a line pattern having a constant width with a small number of processing steps. It is the one we are trying to provide.

[0004]

A first invention of the present application is a pattern gap calculating device for a printed wiring board, which automatically calculates a minimum gap between a pair of linear line patterns having a constant width and formed on the printed wiring board. Therefore, each of the pair of line patterns is divided into a center line segment AB, CD of the pattern and a line segment A.
Modeling means characterized by the edges of width d formed around B and CD, and straight lines L1 (y = a ₁ x + b ₁ ), L2 (y = a ₂ x + b) extending the line segments AB and CD.
₂ ) is generated and whether the slopes of the straight lines L1 and L2 are equal (a ₁ = a ₂ ) or not (a ₁ ≠ a ₂ ) is determined by the parallel relationship determination means and the parallel relationship determination means. If the result is yes, the above L1 and L2 are rotationally converted so as to be parallel to the first coordinate axis x-axis or y-axis, and the line segments AB ′ and CD ′ that are parallel to the first coordinate axis due to rotational conversion. In, it is determined whether or not the values of the component x or y with respect to the first coordinate axis overlap each other, and if they overlap with each other, the difference value of the component of the second coordinate axis with respect to the converted line segments AB ′, CD ′ is determined. The absolute value D is obtained, and a value (= D-2d) obtained by subtracting twice the edge width d from the absolute value D is set as the minimum gap G between the line patterns. If they do not overlap, the line segment AB 'and The smallest distance between the CD's or the end points between the line segments AB and CD The absolute value Dn, a value obtained by subtracting twice the edge width d from the value Dn (= Dn
-2d) is the minimum gap G between the line patterns, and the result of the parallel relationship determination means is negative,
The intersection point O of the straight lines L1 and L2 is obtained, and the shortest distances r1 and r2 between the intersection point O and the line segments AB and CD are obtained and the distance r
A preprocessing unit that rotationally transforms a line segment AB or CD whose 1 or r2 is shorter so as to be parallel to the first coordinate axis x-axis or y-axis, and a line segment that is parallel to the first coordinate by rotational conversion. A
The closest end point (xn, xn, of the line segment CD 'or AB' after the other rotational transformation, which is closer to B'or CD '
yn) and both end points (x ₁ , y ₁ ) and (x _{1 of} the line segment AB ′ or CD ′ parallel to the first coordinate by the rotation transformation.
₂ , y ₂ ) and the coordinate component xn or yn of the end point (xn, yn) with respect to the first coordinate axis is the end point (x ₁ , y ₁ ) of the parallel line segment AB ′ or CD ′ and (X
₂ , y ₂ ) coordinate range of the first coordinate x _{1 to} x ₂ or y ₁ to
In the case of the first case between y ₂ and y ₂ , the component yn or xn of the second coordinate of the closest end point (xn, yn) and the end points (x ₁ , y ₁ ) and (x ₂ , y ₂ ) The absolute value D of the difference from the second coordinate component is obtained, and a value (= D-2d) obtained by subtracting twice the edge width d from this value D is set as the minimum gap G between the line patterns. Computation means and coordinate component xn or yn of the end point (xn, yn) with respect to the first coordinate axis
Is an end point (x ₁ , of the parallel line segment AB ′ or CD ′,
The coordinate range x ₁ of the first coordinate of y ₁ ) and (x ₂ , y ₂ )
In the second case, which is not between x ₂ or y ₁ -y _2, the distance between the end point (xn, yn) and the end points (x ₁ , y ₁ ) and (x ₂ , y ₂ ) A third calculation means for obtaining the absolute value Dn of the smaller distance among them, and taking a value (= Dn-2d) obtained by subtracting twice the edge width d from the value Dn as the minimum gap G between the line patterns. And a pattern gap calculating device for a printed wiring board.

The second invention of the present application is a method for calculating a pattern gap of a printed wiring board, which automatically calculates a minimum gap between a pair of linear line patterns of a constant width formed on the printed wiring board. Then, each of the pair of line patterns is divided into a center line segment AB, CD and a line segment A.
Modeling means characterized by the edges of width d formed around B and CD, and straight lines L1 (y = a ₁ x + b ₁ ), L2 (y = a ₂ x + b) extending the line segments AB and CD.
₂ ) is generated and whether the slopes of the straight lines L1 and L2 are equal (a ₁ = a ₂ ) or not (a ₁ ≠ a ₂ ), the parallel relationship determination step and the parallel relationship determination step If the result is yes, the above L1 and L2 are rotationally converted so as to be parallel to the first coordinate axis x-axis or y-axis, and the line segments AB ′ and CD ′ that are parallel to the first coordinate axis due to rotational conversion. In, it is determined whether or not the values of the component x or y with respect to the first coordinate axis overlap each other, and if they overlap with each other, the difference value of the component of the second coordinate axis with respect to the converted line segments AB ′, CD ′ is determined. The absolute value D is obtained, and a value (= D-2d) obtained by subtracting twice the edge width d from the absolute value D is set as the minimum gap G between the line patterns. If they do not overlap, the line segment AB 'and The smallest distance between the CD's or the end points between the line segments AB and CD The absolute value Dn, a value obtained by subtracting twice the edge width d from the value Dn (= Dn
-2d) is the minimum gap G between the line patterns, and the result of the parallel relationship determination step is negative,
The intersection point O of the straight lines L1 and L2 is obtained, and the shortest distances r1 and r2 between the intersection point O and the line segments AB and CD are obtained and the distance r
A preprocessing step of rotationally converting a line segment AB or CD having a shorter 1 or r2 to be parallel to the first coordinate axis x-axis or y-axis, and a line segment parallel to the first coordinate by rotational conversion. The closest end point (x of the other line segment CD ′ or AB ′ after the rotational transformation, which is closer to AB ′ or CD ′ (x
n, yn) and the end points (x ₁ , y ₁ ) and (x ₂ , y ₂ ) of the line segment AB ′ or CD ′ parallel to the first coordinate by the rotation transformation are compared, and the first The coordinate component xn or yn of the end point (xn, yn) with respect to the coordinate axis of the end point (x ₁ ,
The coordinate range x ₁ of the first coordinate of y ₁ ) and (x ₂ , y ₂ )
In the case of x ₂ or y _{1 to} y ₂ in the first case, the second coordinate component yn of the closest end point (xn, yn).
Or, obtain the absolute value D of the difference between xn and the second coordinate component of the end points (x ₁ , y ₁ ) and (x ₂ , y ₂ ) and subtract twice the edge width d from this value D. And the coordinate component xn or yn of the end point (xn, yn) with respect to the first coordinate axis is parallel to the first coordinate. such line segment AB 'or CD' endpoints (x _1, y ₁₎ and (x _2, y ₂₎ of the first coordinate of the coordinate range x ₁ ~x not between ₂ or y ₁ ~y ₂ second In the case, the absolute value Dn of the smaller distance between the end point (xn, yn) and the end points (x ₁ , y ₁ ) and (x ₂ , y ₂ ) is calculated, and A value obtained by subtracting twice the edge width d from the value Dn (= Dn-2d)
Is a minimum gap G between the line patterns.

A pattern gap calculating device according to the first aspect of the invention and a second aspect.
According to the pattern gap calculation method of the invention, when a pair of line patterns has a parallel relationship as shown in FIG. 3, a C-shaped relationship as shown in FIG. 5, and a space relationship shown in FIG. In each case, the first calculation means (process),
The second calculation means (step) and the third calculation means (step) are configured to calculate the minimum gap.

That is, first, the parallel relationship determining means (process)
In which each of the line patterns is characterized by a central line segment AB, CD of the pattern and an edge of width d formed around the line segments AB, CD,
Straight lines L1 (y = a ₁ x + b ₁ ) extending from B and CD, L
2 (y = a ₂ x + b ₂ ) is generated. And the straight line L
1 and L2 have the same slope (a ₁ = a ₂ ), no (a ₁ ≠
a ₂ ) is determined. When the straight lines L1 and L2 are parallel (a ₁ = a ₂ ), the L1 and L2 are rotationally converted so as to be parallel to the first coordinate axis x axis or y axis.

Then, as shown in FIGS. 6 and 7, for example,
Line segment AB 'that has become parallel to the first coordinate axis due to rotation conversion
And CD ′ the component x or y with respect to the first coordinate axis
It is determined whether or not the values of A and B overlap each other. If they overlap, as shown in FIG. 6, the line segments AB ′, C after conversion are converted.
The absolute value D of the difference value of the components of the second coordinate axis with respect to D ′ is obtained, and a value (= D−2d) obtained by subtracting twice the edge width d from this value D is defined as the minimum gap G between the line patterns. To do. On the other hand, as shown in FIG. 7, when there is no overlap, the line segments AB ′ and CD ′ or the line segments AB and CD
The absolute value Dn of the minimum distance between the end points is calculated, and the value (= Dn-2d) obtained by subtracting twice the edge width d from this value Dn is the minimum gap between the line patterns. Let G.

On the other hand, as shown in FIG. 8, when L1 and L2 are not parallel to each other, the intersection O of the straight lines L1 and L2 is obtained, and the shortest distances r1 and r between the intersection O and the line segments AB and CD are obtained.
2 is obtained, and as shown in FIGS.
The line segment AB or CD whose 2 is shorter is rotationally converted so as to be parallel to the first coordinate axis x-axis or y-axis. Then, the closest end point (xn, yn) of the line segment CD ′ or AB ′ after the other rotation transformation, which is closer to the line segment AB ′ or CD ′ parallel to the first coordinate by the rotation transformation.
And the line segment A that became parallel to the first coordinate by rotation conversion
Both end points (x ₁ , y ₁ ) of B ′ or CD ′ and (x ₂ ,
y ₂ ).

The coordinate component xn or yn of the end point (xn, yn) with respect to the first coordinate axis is the end point (x ₁ , y ₁ ) or (x of the parallel line segment AB 'or CD'.
₂ , y ₂ ) coordinate range of the first coordinate x _{1 to} x ₂ or y ₁ to
For the first case is between y _2, i.e. AB as shown in FIG. 10, when the CD is a relation of Hasukai, the components of the second coordinate of the near end points (xn, yn) yn Or x
The absolute value D of the difference between n and the second coordinate component of the end points (x ₁ , y ₁ ) and (x ₂ , y ₂ ) is obtained, and the value obtained by subtracting twice the edge width d from this value D Let (= D-2d) be the minimum gap G between the line patterns (FIG. 10). As can be seen from the figure, the value D is the first from the closest end point (xn, yn).
It is equal to the length of the perpendicular line drawn on the line segment AB 'or CD' parallel to the coordinates.

Further, the end point (x
The coordinate component xn or yn of (n, yn) is the end point (x ₁ , y ₁ ) and (x ₂ , of the parallel line segment AB ′ or CD ′,
coordinate range of the first coordinate of the y ₂₎ x ₁ ~x ₂ or y ₁ ~y ₂
In the case of the second case which is not between, ie, FIG. 9 or FIG.
In the case of the C-shaped relationship as shown in, the end point (x
n, yn) and the end points (x ₁ , y ₁ ) and (x ₂ ,
y ₂ ) the absolute value D of the smaller distance from
n is obtained, and a value (= Dn-2d) obtained by subtracting twice the edge width d from the value Dn is set as the minimum gap G between the line patterns. As can be seen from the figure, the closest end point (xn, y
This is because the shortest distance between AB and CD occurs between n) and the end point (x ₁ , y ₁ ) or (x ₂ , y ₂ ).

As described above, according to the first and second inventions, the layout patterns between the line patterns are classified into each type as shown in FIGS. 3 to 5, and the line patterns are calculated by a relatively simple operation. The minimum gap between them can be calculated.

Next, a third aspect of the present invention is a printed wiring board for automatically calculating a minimum gap between a straight line pattern LP having a constant width and a curved line pattern C formed on the printed wiring board. A pattern gap calculating device, which divides a curved line pattern C into linear sub patterns C _{1 to} C _N having a length equal to or shorter than a predetermined value that changes in accordance with required accuracy, and approximates the line pattern C. a polygonal line approximation means, a minimum gap G ₁ ~G _N to claim 1 between respectively the line pattern LP of the subpattern C ₁ -C _N
Has a gap calculating means for calculating each of the judging means to minimize the gap between the gap G ₁ ~G value by comparing the minimum value Gm line pattern LP _N and line pattern C by means described According to another aspect of the present invention, there is provided a pattern gap calculating device for a printed wiring board.

Further, the fourth invention is a pattern of a printed wiring board for automatically calculating a minimum gap between a linear line pattern LP having a constant width and a curved line pattern C formed on the printed wiring board. A gap calculation method, which is a polygonal line that approximates the line pattern C by dividing the curved line pattern C into linear sub-patterns C _{1 to} C _N having a length equal to or shorter than a predetermined value that changes in accordance with the required accuracy. and approximation process, the minimum clearance G ₁ ~G _N claims 2 between respectively the line pattern LP of the subpattern C ₁ -C _N
Yes and gap calculation step of calculating, respectively, and a final determination step to minimize the gap between the gap G ₁ ~G value by comparing the minimum value Gm line pattern LP _N and line patterns C by the method described A method of calculating a pattern gap of a printed wiring board, which is characterized in that

In the third and fourth aspects of the invention, first, the curved line pattern C is changed to a straight line having a length equal to or shorter than a predetermined value by the broken line approximation means (step). It is divided into sub patterns C _{1 to} C _N. The degree of division into the sub-patterns C _{1 to} C _N is determined by whether or not the error when the curve is approximated by a straight line is a highly accurate approximation that satisfies the required accuracy.

Next, the minimum gap G ₁ between each of the sub patterns C _{1 to} C _N and the line pattern LP.
Means or method of claim 2 wherein the claim 1, wherein the ~G _N, that is calculated by the means or method for calculating a gap between the straight line pattern. Then, the gap G ₁ ~
The values of G _N are compared, and the minimum value Gm is used as the line pattern LP.
And the line pattern C is the minimum gap. As described above, even if one of the line patterns is curved, the minimum gap can be calculated with desired accuracy. In this case, the gap between many linear line patterns has to be calculated, but by using a computer that is good at repetitive calculations, the processing becomes easy with a simple program.

Next, a fifth aspect of the present invention is directed to a printed wiring board which automatically calculates a minimum gap between a curved line pattern C1 having a constant width and a curved line pattern C2 formed on the printed wiring board. A pattern gap calculating device, which is a linear sub-pattern C having a length equal to or shorter than a predetermined value for changing curved line patterns C1, C2 in accordance with required accuracy.
_{1 ~C N,} C _{1 ~C} divided into _M and line patterns C1, C
A polygonal line approximation means for approximating the 2, each with a minimum gap G ₁₁ ~G _NM means according to claim 1, wherein between each and the subpattern C ₁ -C _M of the sub-pattern C ₁ -C _N Gap calculating means for calculating and the gaps G _{11 to} G _NM
And a determining unit that determines the minimum value Gm as the minimum gap between the line pattern C1 and the line pattern C2.

A sixth aspect of the present invention is a method for calculating a pattern gap of a printed wiring board, which calculates a minimum gap between a curved line pattern C1 having a constant width and a curved line pattern C2 formed on the printed wiring board. In addition, linear sub-patterns C ₁ -C _{1 having} a length equal to or shorter than a predetermined value for changing the curved line patterns C 1 and C 2 in accordance with the required accuracy.
A polygonal line approximation step of approximating the C _N, C ₁ -C dividing line pattern in _M C1, C2, the sub-pattern C ₁
To C _N and the sub patterns C _{1 to} C _M , the minimum gap G _{11 to} G _NM is calculated by the method according to claim 2, and the values of the gaps G _{11 to} G _NM are calculated. And a final determination step of setting the minimum value Gm as the minimum gap between the line patterns C1 and C2, and a pattern gap calculation method for a printed wiring board.

In the fifth and sixth inventions, the line patterns are both curved, and the polygonal line approximation is applied to both patterns.
Minimum gap G _IJ between sub-patterns (I = 1 to N, J = 1 to 1
M) is the means or method according to claim 1 or claim 2,
That is, it is calculated by a means or method for calculating the gap between the linear line patterns. And the above gaps G _{11 to} G _NM
And the minimum value Gm is set as the minimum gap between the line pattern C1 and the line pattern C2. As described above, even if both line patterns are curved, the minimum gap can be calculated with desired accuracy. In this case, the gap between many linear line patterns has to be calculated, but by using a computer that is good at repetitive calculations, the processing becomes easy with a simple program.

[0020]

BEST MODE FOR CARRYING OUT THE INVENTION

Embodiment Example As shown in FIG. 2, the pattern gap calculation device 1 of the present embodiment is
It comprises a data holding unit 41 for inputting and holding line pattern data, a calculation unit 10 for calculating the minimum gap between line patterns based on the data of the data holding unit 41, and a printer 42 for outputting the calculated result. . The data holding unit 41 includes an input unit 411 that receives data from the CAD system 80 and a recording unit 412 that stores the data. The data holding unit 41 and the arithmetic unit 10 are composed of a microprocessor as hardware resources and application software.

First, the arithmetic unit 10 converts a series of line patterns 91 to 94 of a printed wiring board 90 as shown in FIG. 18, for example, into a simple line pattern, that is, linear line patterns 911 to 914, 921. , 922
931 to 933, 941 to 945 and arc-shaped line patterns 915, 916 and 923. In the figure, reference numeral 95 is a land pattern. After that, the minimum gaps between linear line patterns belonging to different continuous line patterns, linear line patterns and arc line patterns, and arc line patterns are calculated as described below. , Its minimum value is the minimum gap between different continuous line patterns 91 to 94.

In the case of straight line patterns, the minimum gap calculation process is performed according to the flow chart shown in FIG. First, in step 601, as shown in FIG.
~ As shown in FIG. 5, a pair of line patterns 81, 82
The center line segments AB and CD of the pattern and the line segment A
B, characterized by edges of width d formed around CD. Next, in step 602, the line segment A
Straight lines L1 (y = a ₁ x + b ₁ ) extending from B and CD, L
2 (y = a ₂ x + b ₂ ) is generated.

Next, in step 603, the slopes of the straight lines L1 and L2 are equal as shown in FIG. 3 (a ₁ = a ₂ ).
It is determined whether or not (a ₁ ≠ a ₂ ) as shown in FIGS. 4 and 5, and if they are equal, that is, if L 1 and L 2 are parallel, the process proceeds to step 604, and if not, After solving the simultaneous equations and calculating the intersection O as shown in FIG. 8, the process proceeds to step 620.

If L1 and L2 are parallel to each other, first in step 604, as shown in FIGS. 6 and 7, the straight lines L1 and L2 are rotationally converted so as to be parallel to the x axis, and the line segments AB and CD are converted. Convert into line segments AB ′ and CD ′ parallel to the x-axis. And
In step 605, the coordinates (x1, y1), (x2, y1), (x3, y) of the end points of the line segments AB ′ and CD ′ are included.
3) and (x4, y3) are calculated (where x1> x2
x3> x4).

Then, the x coordinate component of the line segment AB 'and the CD'
If the x-coordinate component does not overlap, that is, step 606
Or the result of 608 is good (x2 <x3, or x4 <x1)
In the case of, the process proceeds to step 607 or 609 to calculate the distance Dn (FIG. 7) between the end points at the closest distance, and the value Dn minus twice the edge width d (=
Let Dn-2d) be the minimum gap G between the line patterns.

On the other hand, when the x coordinate component of the line segment AB 'and the x coordinate component of CD' overlap, that is, steps 606 and 6
When the results of 08 are both negative, the process proceeds to step 610, and the absolute value D (FIG. 6) of the difference between the y coordinate value y1 of the line segment AB ′ and the y coordinate value y2 of the line segment CD ′ is calculated, A value (= D-2d) obtained by subtracting twice the edge width d from the value D is defined as the minimum gap G between the line patterns.

When the result of step 603 is correct, that is, when the straight lines L1 and L2 intersect, in step 620, the distances r1 and r2 between the intersection point O and the line segments AB and CD are calculated as shown in FIG. To do. Then, as shown in FIGS. 9 to 11, the line segments AB and CD are rotated so that the line segment AB or CD having a shorter distance from the intersection O becomes parallel to the x axis.

That is, the result of step 621 is (r1≤
In the case of r2), in step 622, the line segment AB
Is reversely rotated (−θ rotation) by an angle θ formed with respect to the x axis so that the line segment AB ′ after turning becomes parallel to the x axis. When the result of step 621 is negative (r2 ≦ r1), in step 631, the line segment CD is rotated by the angle θ formed by the x axis in the reverse direction (−θ rotation) to obtain the line segment CD ′ after turning. Should be parallel to the x-axis. Then, as shown in FIGS. 9 to 11, in step 623 or 632, the coordinates (xn, xn, of the end point E close to the y coordinate of the other line segment that is not parallel to the x axis, that is, the end point E having a small absolute value of the y coordinate component. yn) is calculated. Then, in steps 623 and 633, the coordinates (x1, y1) and (x1, y1) of the end points of the line segment AB ′ or CD ′ that is parallel to the x axis after turning are obtained.

Then, as shown in FIG. 10, when the perpendicular line drawn from the end point E to the other line segment parallel to the x-axis intersects on the other line segment, that is, the result of step 641 is correct (x
If 1 ≦ xn ≦ x2), the process proceeds to step 642.
In step 642, the length D (FIG. 10) of the perpendicular line is obtained from the absolute value of the difference between the end point E and the y coordinate value of the line segment, and this value D
Value obtained by subtracting twice the above-mentioned edge width d (= D-2d)
Is the minimum gap G between the line patterns.

Then, as shown in FIGS. 9 and 11, when the perpendicular line drawn from the end point E to the other line segment parallel to the x-axis does not intersect on the other line segment, that is, the result of step 641 is negative ( If x1 <xn or xn> x2), the process proceeds to step 643. In step 643, which side of the other line segment the x coordinate value xn of the end point E is out of, that is,
It is determined whether the relationship (xn <x1) as shown in FIG. 9 or the relationship (xn ≧ x2) as shown in FIG. 11 is satisfied, and at step 644 or 645, the relationship between the end point closer to the line segment is determined. The distance Dn is calculated. That is, if xn <x1, D
n ² = (xn-x1) ² + (yn-y1) ² and x
In the case of ^{n <x1, Dn 2 = (} xn-x2) 2 + (yn
-Y1) ² . Then, a value (= Dn-2d) obtained by subtracting twice the edge width d from this value Dn is set as the minimum gap G between the line patterns.

Next, regarding the minimum gap between the linear line pattern P1 and the arc-shaped line pattern R2,
The process is performed according to the flowchart shown in FIG.
First, in step 651, as shown in FIG.
The arc-shaped line pattern R2 is approximated to a polygonal line as a set of N linear line patterns _C1i (i = 1 to N) (N = 8 in the figure). Then, in step 652, as the initial setting, the numerical value i of the counter is set to 1 and the value of the gap Gm is set to infinity.

Then, in step 653, it is confirmed that the counter value i is N or less, and in step 653
Go to 4. In step 654, the gap G _1i between the linear line pattern P1 and the linear line pattern C _1i is calculated according to the flow shown in FIG. That is, FIG.
As shown in FIG. 4, a gap G _1i between the linear line pattern P 1 and the linear line pattern C _{1i that} is approximated by the broken line is calculated (the figure shows an example in the case of i = 1). Then, in step 655, it is determined whether or not the calculated gap G _1i is smaller than the stored minimum gap Gm. If yes, in step 656 the G _1i is replaced with Gm. Then, in step 657, the counter value i is incremented by one, and the process returns to step 653.

When the result of step 653 is negative, that is, all line patterns C _1i (i = 1 to 1)
N) and the gap G _1i between P 1 is calculated, the minimum gap Gm recorded in step 658 is calculated.
Is determined as the final minimum gap between the line patterns P1 and R2.

Next, the minimum gap between the arcuate line pattern R1 and the arcuate line pattern R2 as shown in FIG. 16 is processed according to the flowchart shown in FIG. First, in step 661, as shown in FIG. 15, the arc-shaped line pattern R1 is approximated to a polygonal line as a set of N linear line patterns C _1i (i = 1 to N) (in the figure, N = 8). Step 6
62, the arc-shaped line pattern R2 is similarly M.
Polygonal line approximation is performed as a set of individual linear line patterns C _2j (j = 1 to M) (M = 8 in the figure).

Then, in step 663, the numerical values i and j of the counter are set to 1 as the initial setting.
And the value of the gap Gm is set to infinity. Then, in steps 664 and 665, it is confirmed that the counter value i is N or less and the value j is M or less, and the process proceeds to step 666. In step 666, FIG.
According to the above-described flow shown in FIG. 5, the gap G _ij between the linear line patterns C _1i (i = 1 to N) and C _2j (j = 1 to M)
Is calculated. That is, as shown in FIG. 17, the gap G _ij between the line patterns C _1i and C _2J linearly approximated by the broken line is calculated (the figure shows i = 1 and d = 1).

Then, in step 667, it is judged whether or not the calculated gap G _ij is smaller than the stored minimum gap Gm. If yes, in step 668 the G _ij is replaced with Gm. Then, in step 669, the counter value j is incremented by one, the process returns to step 665, and the loop is repeated until the counter value j reaches the predetermined value M.

When the value of the counter j exceeds M in step 655, the counter value i is incremented by 1 in step 670 and then step 6 is executed.
Return to 64. Then, the same processing is repeated and step 6 is performed.
If the result of 64 is negative, that is, all G _ij are calculated, the counter value i exceeds M, and the counter value j
If N exceeds N, in step 671, the gap Gm is set to the minimum gap between the line patterns R1 and R2.

As described above, according to the processing flowchart of FIG. 1, FIG. 12 or FIG. 15, all straight line patterns and arc-shaped lines belonging to different continuous line patterns 91 to 94 as shown in FIG. The minimum gap Gm with the pattern is calculated. Then, it is possible to automatically check whether or not the minimum gap Gm is a value equal to or larger than a predetermined value.

[0039]

As described above, according to the present invention, it is possible to provide a pattern gap calculating device and a pattern gap calculating method capable of easily calculating the minimum gap between line patterns having a constant width.

[Brief description of drawings]

FIG. 1 is a flowchart showing a procedure of calculating a minimum gap G between a pair of linear line patterns in an embodiment.

FIG. 2 is a system configuration diagram of a pattern gap calculation device according to an exemplary embodiment.

FIG. 3 is an arrangement mode (parallel relationship) of a pair of linear line patterns.

FIG. 4 is a layout mode of a pair of linear line patterns (space relation).

FIG. 5 is an arrangement mode of a pair of linear line patterns (a C-shaped relationship).

FIG. 6 is an arrangement mode of a pair of parallel lines (overlapping relationship).

FIG. 7 is an arrangement mode of a pair of parallel lines (shifted parallel relationship).

FIG. 8 shows a distance r1 between a pair of intersecting straight lines and an intersection O.
The figure which shows one example of r2.

FIG. 9 is a view (No. 1) showing a mode of arrangement of a pair of straight lines, one of which is parallel to the x-axis and which intersects with each other.

FIG. 10 is a view (No. 2) showing a mode of arrangement of a pair of straight lines, one of which is parallel to the x axis and one of which intersects with each other.

FIG. 11 is a view (No. 3) showing a mode of arrangement of a pair of straight lines, one of which is parallel to the x-axis and which intersects with each other.

FIG. 12 is a flowchart showing a procedure for calculating a minimum gap Gm between a linear line pattern and an arc line pattern in the embodiment.

FIG. 13 is a diagram showing an example of an arrangement mode of a linear line pattern P1 and an arc line pattern R2.

14 is a linear line pattern C ₁₁ and a line pattern P1 that approximate a part of the arc-shaped line pattern of FIG.
An enlarged view of FIG.

FIG. 15 is a flowchart showing a procedure for calculating a minimum gap Gm between a pair of arc-shaped land patterns R1 and R2 in the embodiment.

FIG. 16 is a diagram showing an example of a layout of arc-shaped line patterns R1 and arc-shaped line patterns R2.

17 is a linear line pattern C ₁₁ approximating a part of the arc line pattern R1 and a linear line pattern C approximating a part of the arc line pattern R2 of FIG.
₂₁ enlarged views.

FIG. 18: 1 of arrangement of line pattern of printed wiring board
The figure which shows an example.

[Explanation of symbols]

AB, CD. . . . The line segment that is the center of the line pattern, AB ', CD'. . . Line segments AB and CD are rotated so that one is parallel to the first coordinate, d. . . Edge width around line segments AB, CD, D. . . Perpendicular length, Dn. . . The distance between the closest endpoints, E. . . The end point of the other line segment close to the line segment parallel to the first coordinate, G, Gm. . . Minimum gap between line patterns, L1, L2. . . Line segment AB, straight line of CD, O. . . Intersection of L1 and L2,

Claims (6)

[Claims] 1. A pattern gap calculation device for a printed wiring board, which automatically calculates a minimum gap between a pair of linear line patterns having a constant width formed on a printed wiring board, wherein the pair of line patterns is provided. Modeling means for characterizing each of these by a center line segment AB, CD of the pattern and an edge of width d formed around the line segments AB, CD;
Straight line L1 (y = a ₁ x +) obtained by extending the above line segments AB and CD
b ₁ ), L2 (y = a ₂ x + b ₂ ) are generated, and the slopes of the straight lines L1 and L2 are equal (a ₁ = a ₂ ), or not (a 1
₁ ≠ a ₂ ), and if the result of the determination by the parallel relationship determining means is YES, then L1,
L2 is rotationally converted so as to be parallel to the first coordinate axis x-axis or y-axis, and the component x or y with respect to the first coordinate axis in the line segments AB ′ and CD ′ that are parallel to the first coordinate axis due to rotational conversion. Determines whether the values of overlap with each other,
In the case of overlap, the absolute value D of the difference value of the components of the second coordinate axis with respect to the converted line segments AB ′ and CD ′ is obtained, and a value obtained by subtracting twice the edge width d from this value D ( = D-2
d) is the minimum gap G between the line patterns, and when they do not overlap, between the line segments AB ′ and CD ′ or the line segment A
The absolute value Dn of the minimum distance between the end points between B and CD is calculated, and the value (= Dn-2d) obtained by subtracting twice the edge width d from the value Dn is calculated between the line patterns. If the result of the parallel relation determining means is the negative, the intersection O of the straight lines L1 and L2 is determined, and the shortest distance r1 between the intersection O and the line segments AB and CD. The line segment AB with the shorter distances r1 and r2 is obtained by calculating r2.
Alternatively, a pre-processing unit that rotationally transforms CD so as to be parallel to the first coordinate axis x-axis or y-axis, and a line segment AB ′ or CD ′ that is parallel to the first coordinate by rotational transformation is closer. The closest end point (xn, yn) of the other line segment CD 'or AB' after the rotation conversion and the end point (x of the line segment AB 'or CD' that has become parallel to the first coordinate by the rotation conversion. ₁ , y ₁ ) and (x ₂ , y ₂ )
The coordinate component x of the end point (xn, yn) with respect to the coordinate axis of
n or yn is, the parallel endpoint of line segment AB 'or _{CD' (x 1, y 1} ) and (x _2, y ₂₎ coordinate range of the first coordinate of x ₁ ~x ₂ or y ₁ ~y ₂ In the case of the first case between the two, the component yn or xn of the second coordinate of the closest end point (xn, yn) and the end points (x ₁ , y ₁ ) and (x ₂ , y).
₂ ) The absolute value D of the difference from the second coordinate component is obtained, and a value obtained by subtracting twice the edge width d from this value D (= D-2
d) is the minimum gap G between the line patterns, and the coordinate component xn or yn of the end point (xn, yn) with respect to the first coordinate axis is the end point of the parallel line segment AB 'or CD'. The first of (x ₁ , y ₁ ) and (x ₂ , y ₂ )
In the case of the second case, which is not within the coordinate range x _{1 to} x ₂ or y _{1 to} y ₂ , the end point (xn, yn) and the end points (x ₁ , y ₁ ) and (x ₂ , y). ₂ ) Obtain the absolute value Dn of the smaller distance from the distances to the line distance, and subtract the value twice the edge width d from the value Dn (= Dn-2d) to obtain the minimum gap between the line patterns. A pattern gap calculating device for a printed wiring board, comprising: a third calculating means G. 2. A pattern gap calculation method for a printed wiring board, which automatically calculates a minimum gap between a pair of linear line patterns having a constant width formed on the printed wiring board, wherein the pair of line patterns is provided. A modeling step that characterizes each of the two by a central line segment AB, CD of the pattern and an edge of width d formed around the line segments AB, CD,
Straight line L1 (y = a ₁ x +) obtained by extending the above line segments AB and CD
b ₁ ), L2 (y = a ₂ x + b ₂ ) are generated, and the slopes of the straight lines L1 and L2 are equal (a ₁ = a ₂ ), or not (a 1
₁ ≠ a ₂ ), if the determination result in the parallel relationship determination step and the parallel relationship determination step is YES, the above L1,
L2 is rotationally converted so as to be parallel to the first coordinate axis x-axis or y-axis, and the component x or y with respect to the first coordinate axis in the line segments AB ′ and CD ′ that are parallel to the first coordinate axis due to rotational conversion. Determines whether the values of overlap with each other,
In the case of overlap, the absolute value D of the difference value of the components of the second coordinate axis with respect to the converted line segments AB ′ and CD ′ is obtained, and a value obtained by subtracting twice the edge width d from this value D ( = D-2
d) is the minimum gap G between the line patterns, and when they do not overlap, between the line segments AB ′ and CD ′ or the line segment A
The absolute value Dn of the minimum distance between the end points between B and CD is calculated, and a value (= Dn-2d) obtained by subtracting twice the edge width d from this value Dn is calculated between the line patterns. When the result of the parallel operation determining step and the first calculation step of setting the minimum gap G of the above is negative, the intersection point O of the straight lines L1 and L2 is obtained and the shortest distance r1 between the intersection point O and the line segments AB and CD. The line segment AB with the shorter distances r1 and r2 is obtained by calculating r2.
Alternatively, a pre-processing step of rotating the CD so as to be parallel to the first coordinate axis x-axis or y-axis, and a first step by rotating conversion
Of the other line segment CD ′ or AB ′ after the rotational transformation, which is closer to the line segment AB ′ or CD ′ parallel to the coordinates of x, and the first by the rotational transformation. Comparing the end points (x ₁ , y ₁ ) and (x ₂ , y ₂ ) of the line segment AB ′ or CD ′ parallel to the coordinates of, the above-mentioned end point (xn, yn) with respect to the first coordinate axis coordinate component xn or yn are the end points of the line segment parallel to the first coordinate AB 'or _{CD' (x 1, y 1} ) and (x _2, y ₂₎ coordinate range of the first coordinate of x ₁ ~x ₂ Alternatively, in the case of the first case between y _{1 and} y ₂ , the above-mentioned closest end point (xn, yn)
The absolute value D of the difference between the component yn or xn of the second coordinate of x and the component of the second coordinate of the end points (x ₁ , y ₁ ) and (x ₂ , y ₂ ).
And a second calculation step in which a value (= D-2d) obtained by subtracting twice the edge width d from the value D is set as the minimum gap G between the line patterns, and the end point (x
(n, yn) coordinate component xn or yn is the end point (x ₁ , y ₁ ) of the line segment AB ′ or CD ′ parallel to the first coordinate.
And (x _2, y ₂₎ in the case of the second case not between the coordinate range x ₁ ~x ₂ or y ₁ ~y ₂ of the first coordinate of the end point (xn, yn) and the end point (x ₁ , y ₁ ) and (x ₂ ,
y ₂ ) the absolute value D of the smaller distance from
and a third calculation step in which a value (= Dn-2d) obtained by subtracting twice the edge width d from the obtained value Dn is set as the minimum gap G between the line patterns. Method for calculating pattern gap of printed wiring board. 3. A pattern gap calculation device for a printed wiring board, which automatically calculates a minimum gap between a linear line pattern LP having a constant width and a curved line pattern C formed on the printed wiring board. A polygonal line approximating means for approximating the line pattern C by dividing the curved line pattern C into linear sub-patterns C _{1 to} C _N having a length equal to or less than a predetermined value that changes in accordance with the required accuracy; a gap calculation means for calculating each by means of claim 1, wherein the minimum gap G ₁ ~G _N between respectively the line pattern LP of the subpattern C ₁ -C _N, the gap G ₁ ~G _N
And a determination unit that determines the minimum value Gm as the minimum gap between the line pattern LP and the line pattern C, and a pattern gap calculation device for a printed wiring board. 4. A pattern gap calculation method for a printed wiring board, which automatically calculates a minimum gap between a linear line pattern LP having a constant width and a curved line pattern C formed on the printed wiring board. A polygonal line approximating step of approximating the line pattern C by dividing the curved line pattern C into linear sub-patterns C _{1 to} C _N having a length equal to or less than a predetermined value for changing in accordance with the required accuracy, a gap calculation step of calculating each by the method of the minimum gap G ₁ ~G _N to claim 2 wherein between each and the line patterns LP of the subpattern C ₁ -C _N, the gap G ₁ ~G _N
And a final determination step of setting the minimum value Gm as the minimum gap between the line pattern LP and the line pattern C, and a pattern gap calculation method for a printed wiring board. 5. A pattern gap calculation device for a printed wiring board, which automatically calculates a minimum gap between a curved line pattern C1 having a constant width and a curved line pattern C2 formed on the printed wiring board. Then, linear sub-patterns C _{1 to} C _N , C ₁ to having a length equal to or shorter than a predetermined value for changing the curved line patterns C 1 and C 2 in accordance with the required accuracy.
A polygonal line approximation means for dividing into C _M and approximating the line patterns C1 and C2, and a minimum gap G between each of the sub patterns C _{1 to} C _N and the sub patterns C _{1 to} C _M.
11 and gap calculation means for calculating each by means of claim 1, wherein the ~G _NM, the gap G ₁₁ ~G _NM value comparing line pattern its minimum value Gm C1 and the line pattern C2
And a determining means for determining a minimum gap between the pattern gap and the pattern gap calculating device for a printed wiring board. 6. A pattern gap calculation method for a printed wiring board, comprising: calculating a minimum gap between a curved line pattern C1 having a constant width and a curved line pattern C2 formed on the printed wiring board; Line pattern C
1, C2 subpattern C ₁ predetermined value or less of the length of the linear changing in response to a request accuracy -C _N, polygonal line approximation to approximate the C ₁ -C divided into _M line patterns C1, C2 Process, and the minimum gaps G _{11 to} G between the sub patterns C _{1 to} C _N and the sub patterns C _{1 to} C _M , respectively.
A gap calculating step of calculating _NM by the method according to claim 2 and the values of the gaps G _{11 to} G _NM are compared, and the minimum value Gm is set as the minimum gap between the line pattern C1 and the line pattern C2. A method for calculating a pattern gap of a printed wiring board, comprising: a determining step.