JPH036670A - Automatic wiring system - Google Patents

Abstract

PURPOSE:To retrieve a route at higher speed with use of a maze method by setting previously a route retrieving area so as not include a part having a large degree of congestion. CONSTITUTION:The entire printed board is divided into 20 rectiangular grids, and the marks ( ) show the inserting positions of electronic lead pins. While the marks (O) show the position of via which secure the electrical connection between the wiring pattern parts on the surface side of a print panel and the wiring pattern parts on the rear side of the panel. When a process is started, the surface side idle pattern number 1, the rear side idle pattern number 2, and the idle pattern number 1, the rear side idle pattern number 2, and the idle viahole number 3 are initialized as prescribed for each rectangular grid. These initialization data corresponding to the rectangular grids are stored in a table. Then a wiring pattern route is decided between two points by refer ence to the contents of the table. When this route is decided, the contents of the table are updated. Then the wiring pattern routes are successively decided between two points respectively. As a result, a route can be retrieved at a higher speed with use of a maze method.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to an automatic wiring method in which a path for a two-point wiring pattern on a printed board is automatically designed by a maze method, and particularly Prior to route searching using the maze method,
This invention relates to an automatic wiring method in which the search area is limited based on congestion evaluation.

[Conventional technology]

Up until now, the method for automatically designing wiring patterns on a printed board has been to divide the printed board vertically and horizontally and store the number of patterns inside each grid as a table. There is a known method that determines whether wiring is possible or not by referring to this table. It has also been considered to set route search areas in advance in order to design wiring patterns faster using the maze method.

Incidentally, examples related to this type of technology include, for example, Japanese Patent Application Laid-Open No. 173384/1984 and Japanese Patent Application Laid-open No. 3769/1983.
Publication No. 6 is mentioned.

[Problem to be solved by the invention]

However, when using a table, the information on the number of patterns existing inside each grid is used only to determine whether connection is possible between two points, so even if the wiring patterns are crowded, If possible, a pattern is drawn at that location without considering the degree of congestion. As a result, there may be places where the wiring pattern becomes locally crowded, and in such places it becomes difficult to pull out the pattern from the input/output pin position or pass through the wiring pattern, and from the perspective of improving the wiring rate. This makes it undesirable.

On the other hand, when the route search area is set in advance, the area is set in an L-shape with a predetermined width so that each of the two points is included in the end area. If there is an object, route searching is impossible unless the width of the area is increased. As the width of the area increases, the processing time also increases.

An object of the present invention is to provide an automatic wiring method that allows route searching using the maze method to be performed more quickly by setting a route searching area in advance such that the crowded Keio University area is not included therein. It is to provide. Another object of the present invention is to provide an automatic wiring system in which a route search area with a smaller degree of congestion is set in advance from among route search areas as candidates, including the figure 7 shape. To provide an automatic wiring method that takes into consideration the case where a route cannot be searched in a search area.

[Means to solve the problem]

The above purpose is to store updatable margin data (or congestion data) for each rectangular grid divided at a predetermined pitch on a printed board, and to refer to these margin data to determine the congestion degree. This is achieved by setting in advance a route search area with a small area. Another purpose is to evaluate the degree of congestion for each route search area as a candidate, including the figure 7 shape, based on margin data, and to set the one with the smaller degree of congestion as the route search area. achieved. Still another object is achieved by setting the next lowest congestion level as the route search area when a route cannot be searched in each of the set route search areas.

[Effect]

The printed board is divided by a rectangular grid containing n'' (n: an integer of 2 or more) rectangular grids in the maze method, and the margin data stored as updatable for each of these rectangular grids is referred to. By doing so, the area where the two-point wiring pattern is provided can be roughly set.

More specifically, in addition to the conventional 1-shaped and L-shaped route search areas, 2-shaped route search areas are also considered as candidates, and the degree of congestion for each of all possible candidates is evaluated based on the margin data. As a result, the candidate with the lowest degree of congestion is set as the route search area. 7
By adding the letter-shaped route search area, the number of route search areas as candidates increases, and among these, the one with the smaller degree of congestion is set as the route search area in the maze method. If a route cannot be searched in each of the set route search areas, the route search area with the next lowest degree of congestion is newly set as the route search area, and so on. It's good.

〔Example〕 The present invention will be explained below with reference to FIGS. 1 to 7.

First, an overview of the automatic wiring system according to the present invention will be explained. FIG. 1 shows a general flow of the automatic wiring process. In this case, when starting the process, first, the number of empty patterns on the front side, the number of empty patterns on the back side, and the number of empty vias for each rectangular grid are initially set to predetermined values. The number of empty patterns here is defined as the number of wiring patterns that can still pass through the rectangular grid, and the number of empty vias is defined as the number of vias that can still be drilled within the rectangular grid. It has become. These initialization data corresponding to the rectangular grid are stored in a table called a density management file, but after this, 2
The contents of the table are referred to in order to determine the route of the wiring pattern between points, and the contents of the table are updated as the route of the wiring pattern is determined, so that the route of the wiring pattern between two points is sequentially determined. It is something.

To explain more specifically, if two points to be connected to each other are set by wiring section extraction, there is generally one route search area as a candidate that includes each of these two points within the edge of the area.
The above is what is uniquely required. Evaluation values are calculated for each of these route search areas according to a predetermined evaluation formula based on the table contents, but if the larger the evaluation value, the smaller the degree of congestion, the route with the maximum evaluation value is the route in the maze method. This is set as a search area, and within this area, a two-point wiring pattern route is searched using a maze method. If the dispersion of evaluation values is small (if no route can be searched, then the one with the next highest evaluation value is set as a new route search area, and the wiring pattern route between two points is searched within that area. When a two-point wiring pattern route can be searched in this way, the data corresponding to the rectangular grid of each route search area containing the route is updated. In this way, the above process is repeated until a two-point wiring pattern route is searched for the entire wiring section.

To explain the automatic wiring system according to the present invention in more detail, FIG. 2 shows a printed board whose front and back surfaces are divided by a rectangular grid according to the present invention.

As shown in the figure, in this example, the entire printed board is divided into 20 rectangular grids, and the Δ marks in the figure indicate the insertion positions of electronic component lead pins or through-hole positions, and the O marks on the printed board. It shows the positions of vias for electrically connecting the front side, the wiring pattern portion, and the back side wiring pattern portion. Normally, when the wiring pattern between two points exists in the same column (rectangular lattice) or the same row (rectangular lattice), the wiring pattern between two points is The pattern path is searched by the maze method. In addition, if the wiring pattern route does not exist in the same column or row, the wiring pattern route is searched in the L-shaped route search area, but according to the present invention, a new 7-shaped route search area is used. has been added as a new candidate. In the case of a 7-shaped route search area, the wiring pattern between two points is, for example, as shown in FIG. Incidentally, in a printed board, the wiring pattern is wired on either the front side or the back side of the printed board depending on the wiring direction.

In this example, the wiring pattern in the Y direction is wired on the front side, and the wiring pattern in the X direction is wired on the back side, but it is of course possible to wire in the opposite direction.

Now, the contents of the table in the wiring state shown in FIG. 2 are as shown in FIG. 3, for example. The numbers 1, 2, and 3 in FIG. 3 indicate the number of empty patterns on the front side, the number of empty patterns on the back side, and the number of empty vias, respectively, as described above. With the table contents like this, as shown in FIG. A concrete explanation of how the route of the wiring pattern between two points regarding points S and E is determined is as follows.

That is, for the sake of simplicity of explanation, if we associate the inside of the rectangular grid shown in FIG. 2 with the rectangular grid a - t shown in FIG. 4,
There is no 1-character shape as a route search region as a candidate, but L-shape and 7-character shapes are possible. As an L-shaped one, a-b-c-d-h
-1-pt route search area and a-e-i-m-q
-r-s -L route search area exists, and two-character-shaped ones also include a-e-f-g-h-1-p-t, a
-e-1-j- to -t -p-t, a-e-t -
m -n-o-p-tXa-b-f-j -m-r-s
There are a total of seven route search areas, including an L-shaped one, such as t, a-b-c-g, and -os-t. The evaluation value F for each of these seven route search areas is calculated, for example, by the following formula.

F=Cafa+Cbfb+Ccfc+Cdfd+Ce
fe However, Ca - Ca is a weighting coefficient that is set to be updatable from the outside, and fa - fe is defined as follows.

fa; the minimum number fb of the number of free patterns that each rectangular grid in each of the route search areas has; the average value fc of the number of free patterns that each rectangular grid in each of the route search areas has; the minimum number of free patterns Number of rectangular grids fd: Minimum value of the number of empty vias at the corner 101 Average value of the number of empty vias at the corner Well, the weighting coefficient is specifically Cc<0, Ca, Cb, Cd, Ce>O
For example, the settings are as follows.

Ca = 100 Cb = 10 Cc = -1 Cd = Ce = 1 Therefore, it can be seen that the fcO value acts in the direction of decreasing the evaluation value F, and the larger the fcO value, the greater the congestion degree.

Incidentally, based on the table contents shown in Figure 3, a
-b -f -j -n -r -s -t If we calculate the evaluation value F for the route search area, fa=1, fb=2
．． 3, f c=2, f d=f e=1, so F
is obtained as F=123.

Similarly, the evaluation values F for the two L-shaped route search areas are both 215, and the evaluation values F for each of the remaining four Z-shaped route search areas are 212 and 214.1.
16.228. In the end, the evaluation value F was 228, a-b-c-g--o-s-t
The route search area is set as the route search area in the maze method. As shown in FIG. 5, if a 5-P-Q-H two-point pattern path can be found in the path search using the maze method, the table contents shown in FIG. It is updated as shown in the figure. Furthermore, if a two-point pattern route cannot be searched in that route search area, it is sufficient to search for a two-point pattern route for the L-shaped one with the next largest evaluation value F. .

Even if the evaluation value F is large, it does not necessarily mean that a two-point pattern path can be searched. Incidentally, the contents of the table are updated according to rules such as, for example, vias or through holes are responsible for the use of one pattern on both the front side and the back side, and diagonal line segments are equivalent to the use of two patterns. ing.

By the way, in the above example, the width of the route search area as a candidate is assumed to be one rectangular grid, but it can also be set as three rectangular grids, etc., which can generally be set as multiple rectangular grid bones. ing. It is also conceivable to increase the width as the automatic wiring design progresses. Incidentally, FIG. 7 shows an example of a route search area as a candidate whose width is three rectangular grids. Although a detailed explanation will be omitted, in such cases, the values for the predetermined item names are obtained by referring to the table, and the evaluation value is similarly obtained as the sum of the weighted item values. be.

〔Effect of the invention〕

According to claim 1, by setting the route search area in advance such that the area of the crowded strange person is not included therein, the route search using the maze method can be performed faster. In the case according to claim 2, a route search area with a smaller degree of congestion can be set in advance from route search areas as candidates including the Z-shape, and in the case according to claim 3, the set route By updating the search area, a two-point pattern path can be reliably searched.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing a general flow of an example of automatic wiring processing according to the present invention, and FIG. 2 is a diagram showing an example of a printed board whose front and back surfaces are divided by a rectangular grid according to the present invention. Figure 3 shows the contents of a table for managing the degree of wiring congestion in a certain wiring state, and Figure 4 shows the correspondence when each rectangular grid shown in Figure 2 is labeled with a code. figure,
FIG. 5 is a diagram for explaining how the route of the wiring pattern between two points is determined, and FIG. 6 is a diagram for explaining how the route of the wiring pattern between two points is determined, and the contents of the table shown in FIG. FIG. 7 is a diagram showing an example of a route search area whose width is three grids.

Claims (3)

[Claims] 1. Prior to automatically designing a path for a two-point wiring pattern on a printed board using the maze method,
An automatic wiring method for roughly determining the route search area in advance in the maze method, which is an automatic wiring method for each rectangular grid on a printed board divided at a predetermined pitch larger than the pitch of the rectangular grid in the maze method. , an automatic wiring method in which margin data regarding the number of wiring patterns and the number of via positions is stored in a table as updateable, and a route search area in a maze method is roughly set by referring to the table. 2. For each of the I-shaped, L-shaped, and Z-shaped route search areas as candidates, the degree of congestion is evaluated based on the margin data corresponding to the rectangular grid within the area, and the one with the lowest degree of congestion is evaluated. 2. The automatic wiring system according to claim 1, wherein: is set as a route search area in a maze method. 3. If the route of the two-point wiring pattern cannot be searched by the maze method within the set route search area,
3. The automatic wiring system according to claim 2, wherein the next lowest congestion level is set as the route search area in the maze method.