JP3605288B2 - Method and apparatus for determining wiring route of circuit board and information storage medium - Google Patents

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a method and an apparatus for determining a wiring route of a circuit board for determining a wiring route from a plurality of inner leads to lands arranged in a matrix around the inner leads, and an information storage medium.
[0002]
BACKGROUND ART AND PROBLEMS TO BE SOLVED BY THE INVENTION
In pursuit of miniaturization of semiconductor devices, bare chip mounting is ideal. However, since it is difficult to guarantee quality and handling, it has been dealt with by processing into a package form. In particular, in recent years, a BGA (ball grid array) type package has been developed as a package form corresponding to a demand for multi-terminals.
[0003]
As one of the BGA type packages, there is a package using a flexible circuit board. Such a circuit board is provided with an inner lead group connected to a terminal group of the IC, and a ball land group arranged in a matrix around the inner lead group. Each land is provided with a solder ball as required. The circuit board is configured to be surface-mounted on a motherboard or the like via the solder balls with the IC mounted.
[0004]
When such a circuit board is used, it is important how to determine the wiring path between each lead constituting the inner lead group and each land ball constituting the land group arranged therearound. .
[0005]
In particular, a circuit board used today has a large number of inner leads and land balls provided on the mounting circuit board due to the increase in the number of terminals of the mounted IC. Therefore, it is important how to efficiently design the wiring path from each inner lead to each ball land without crossing the wiring with each other, in order to shorten the development period of the circuit board and reduce the cost. Will be an issue.
[0006]
However, in the conventional method, a designer manually sets a wiring path between each inner lead and each land on a drawing by trial and error. For this reason, there is a problem that it takes time and labor for the work, and it is not possible to design a circuit board in a short time and at low cost.
[0007]
That is, the number of wirings that can pass between the lands differs depending on various parameters such as the distance between the ball lands and the width of the wiring lead to be used. Therefore, it is necessary to determine the wiring paths so that the number of wirings between the lands does not exceed the allowable number and the wirings do not cross each other.
[0008]
However, in a conventional method in which a designer manually sets a wiring route between each inner lead and each land by trial and error on the drawing, when a land where wiring is impossible during the work appears. In this method, it is necessary to change the parameters again and set the wiring route again from the beginning, so that there is a problem that the vigorous design work must rely on the experience and intuition of the operator.
[0009]
The present invention has been made in view of such a conventional problem, and an object of the present invention is to efficiently and quickly determine a wiring path between an inner lead group and a land group arranged in a matrix around the inner lead group. An object of the present invention is to provide a method, an apparatus, and an information storage medium for determining a wiring route of a circuit board that can be performed.
[0010]
[Means for Solving the Problems]
(1) To achieve the above object, the present invention provides:
In a method of determining a wiring route between a group of inner leads arranged in a rectangular shape and a group of lands arranged in a matrix so as to surround the inner lead group in a rectangular shape,
A first step of dividing the land group into four trapezoidal regions corresponding to respective sides of a rectangular shape and specifying a trapezoidal region having the same land matrix arrangement;
A second step of determining a wiring path between a corresponding inner lead group and a land group for each divided region having a different land matrix arrangement;
A third step of diverting the determined wiring path as a wiring path of another divided region having the same land matrix arrangement;
It is characterized by including.
[0011]
The information storage medium of the present invention comprises:
Based on the input information, means for setting a virtual circuit board having a group of inner leads arranged in a rectangular shape and a group of lands arranged in a matrix so as to surround the inner lead group in a rectangular shape,
Means for determining a wiring route between an inner lead group and a land group of the virtual circuit board
In a computer-readable information storage medium storing a program that causes the computer to function as
The means for determining the wiring route includes:
A first means for dividing the land group into four trapezoidal divided regions each having four bases of four outer sides of the virtually rectangular land group,
Second means for performing a process of determining a wiring route between the inner lead group and the land group for each of the divided regions having different land matrix arrangements from the four divided regions subjected to the four divided processing;
Third means for diverting the determined wiring route as a wiring route of another divided region having the same land matrix arrangement and performing a process of determining a wiring route of the another divided region;
Including
The first means includes:
Performing the quadrant division process on the land group so that each of the adjacent trapezoidal divided regions shares one row of land rows corresponding to trapezoidal sides as a surface sharing unit;
The second means includes:
A trapezoidal divided area to be wired is divided into a center common portion composed of at least two rows of lands at the center of the matrix, a pair of processing surfaces located on both sides thereof, and the surface sharing portion located outside each processing surface. Means for performing processing for subdividing into
The determination of the wiring route of the divided area is performed in the order of the central shared portion, the processing surface, and the surface shared portion. Determining means for determining;
Including
The determining means comprises:
Means for virtually arranging a plurality of counters for counting the number of wiring paths that are opened and controlled by a predetermined rule and pass between adjacent lands, around each of the lands,
The wiring path between the next inner lead adjacent to the inner lead for which the wiring path has been determined and the next wiring target land determined by the predetermined rule intersects with the immediately preceding wiring path between the lands where the open counter exists. Wiring route determining means for performing processing of determining to pass without passing through, the center shared portion, the processing surface, the surface shared portion in order,
The open counter whose count value has been exceeded and the open counter determined by the wiring route of the corresponding land are closed, and the closed counter located on the opposite side to the closed controlled counter via the corresponding land is opened and controlled. Counter control means for setting a route leading the wiring,
It is characterized by including.
[0012]
According to the present invention, a land group arranged in a matrix so as to surround the inner lead group in a rectangular shape is divided into four trapezoidal shapes corresponding to each side of the rectangular shape. Some of the trapezoidal divided areas divided into four have the same land matrix arrangement.
[0013]
For example, when the land group arranged in a matrix is formed so as to surround the inner lead group in a square shape, the matrix arrangement of the four divided regions is the same.
[0014]
Further, for example, in the case where the periphery of the inner lead group is surrounded in a rectangular shape, the divided regions corresponding to opposing sides have the same land matrix arrangement.
[0015]
Therefore, according to the present invention, the processing of determining the wiring path between the inner lead group and the land group is performed only for the divided areas having different land matrix arrangements, and the determined wiring path is determined by the land matrix arrangement. It is diverted as a wiring route of the same other divided region.
[0016]
By doing so, the processing for determining the wiring path between the inner lead group and the land group can be greatly reduced, and the time and cost for the development and design of the circuit board can be reduced.
[0017]
In particular, in the case of a circuit board having land groups arranged in a matrix so as to surround the inner lead group in a square shape, if a circuit path is determined only for one divided region divided into four, the remaining three Since the determined wiring path can be reused for the divided area, the load for determining the wiring path can be reduced to approximately １ ／.
[0018]
In a land group arranged in a matrix so as to surround the inner lead group in a rectangular shape, if a wiring route of two divided regions corresponding to two sides of the rectangular shape is determined, this wiring route is left. Can be reused as the wiring route of the two divided regions, so that the load for determining the circuit route can be reduced to half.
[0019]
(2) Here, the first step includes:
The land group is divided so that adjacent divided regions share one row of lands corresponding to the trapezoidal side as a surface sharing portion,
The second step includes:
The target trapezoidal divided area is divided into a central shared portion composed of at least two rows of lands at the center of the matrix, a pair of processing surfaces located on both sides thereof, and the surface shared portion located outside each processing surface. Subdividing into and
Determining the wiring route of the divided region, the central shared portion, the processing surface, a determination step of performing the surface shared portion in order,
It is preferable that the surface sharing unit determines a wiring path so as to share wiring to an adjacent divided region and each land.
[0020]
Further, the first information includes:
Including information for dividing the land group, such that adjacent divided regions share a land row for one row corresponding to a trapezoidal side as a surface sharing unit;
The second information is
A trapezoidal divided area to be wired is divided into a center common portion composed of at least two rows of lands at the center of the matrix, a pair of processing surfaces located on both sides thereof, and the surface sharing portion located outside each processing surface. Information for subdivision into
The determination of the wiring route of the divided region is performed in the order of the central shared portion, the processing surface, and the surface shared portion, and further, the surface shared portion determines the wiring route so as to share the wiring to the adjacent divided region and each land. Decision information for deciding,
It is preferable to form them so as to contain.
[0021]
According to the present invention, the wiring between the inner leads and the lands can be performed in the shortest path and substantially symmetrically to the left and right.
[0022]
In particular, according to the present invention, since the determination of the wiring path is sequentially performed from the central shared portion to the processing surfaces located on both sides thereof, it is possible to efficiently determine the wiring path in the divided region in a short time. it can.
[0023]
Further, according to the present invention, the determination of the wiring path on the trapezoidal divided region is performed by the central shared portion, the pair of processing surfaces located on both sides thereof, and the surface shared portion located outside each processing surface. The wiring path can be determined efficiently while taking into account the special characteristics of the subdivided and subdivided areas.
[0024]
In this case, it is preferable that the common center portion be formed as two rows of lands at the center of the trapezoidal divided region in order to efficiently perform wiring of this portion.
[0025]
Further, in the present invention, adjacent divided regions share one row of land rows corresponding to the trapezoidal sides as a plane shared portion.
[0026]
That is, special wiring may be required in a region where the trapezoidal divided regions are in contact with each other. In the present invention, such a region is subdivided as a region different from the processing surface where the wiring pattern is determined by the normal rule, and the wiring pattern is determined according to the characteristics of the region. As a result, the wiring pattern of the divided area can be determined more efficiently.
[0027]
Here, in the wiring pattern of the plane sharing portion, adjacent divided regions share lands that are wiring symmetrical. For example, when there are ten lands in this area, it is preferable that each divided area equally divides five lands.
[0028]
More preferably, each divided region may be configured to share the lands of the surface sharing portion every other land and determine the wiring route. This makes it possible to more efficiently determine the wiring path in the plane sharing unit.
[0029]
(3) In the present invention,
The determining step includes:
A step of virtually arranging a plurality of counters that count the number of wiring paths that are opened and controlled by a predetermined rule and pass between adjacent lands around each of the lands,
The wiring path between the next inner lead adjacent to the inner lead for which the wiring path has been determined and the next wiring target land determined by the predetermined rule intersects with the immediately preceding wiring path between the lands where the open counter exists. A wiring path determining step of performing a process of deciding to pass without passing through, in the order of the center sharing unit, the processing surface, and the surface sharing unit;
The open counter whose count value has been exceeded and the open counter determined by the wiring route of the corresponding land are closed, and the closed counter located on the opposite side to the closed controlled counter via the corresponding land is opened and controlled. A counter control step of setting a route leading the wiring;
It is preferable to include
[0030]
In the present invention,
The decision information is
Information for virtually arranging a plurality of counters for counting the number of wiring paths that are opened and controlled by a predetermined rule and pass between adjacent lands around each land,
The wiring path between the next inner lead adjacent to the inner lead for which the wiring path has been determined and the next wiring target land determined by the predetermined rule intersects with the immediately preceding wiring path between the lands where the open counter exists. Wiring path determination information for performing the process of determining to pass without passing through, the center shared portion, the processing surface, the surface shared portion in order,
The open counter whose count value has been exceeded and the open counter determined by the wiring route of the corresponding land are closed, and the closed counter located on the opposite side to the closed controlled counter via the corresponding land is opened and controlled. Counter control information for setting a route leading the wiring,
It is preferable to include
[0031]
According to the present invention, the determination of the wiring route in each of the divided areas can be automatically performed using a counter virtually arranged around each land.
[0032]
(4) In the present invention,
The wiring route determining step includes:
From the lands arranged in the matrix, the wiring path to the plating lead provided on the outer periphery thereof is determined such that the wiring immediately before the wiring path does not intersect with the wiring path while the open counter exists,
The counter control step includes:
The open counter whose count value is exceeded by the wiring route determination process between the plating lead and the land is closed and the closed counter located on the opposite side to the closed control counter is opened and controlled via the corresponding land, and new wiring is performed. It is preferable to perform a process of setting an area that leads to
[0033]
In the present invention,
The wiring route determination information includes:
The wiring path from the land arranged in the matrix to the plating lead provided on the outer periphery thereof is determined between the lands where the counter is open so that the wiring can pass without intersecting with the wiring path immediately before. Information for
The counter control information,
The open counter whose count value is exceeded by the wiring route determination process between the plating lead and the land is closed and the closed counter located on the opposite side to the closed control counter is opened and controlled via the corresponding land, and new wiring is performed. It is preferable to include information for performing a process of setting a region that leads to.
[0034]
According to the present invention, it is possible to automatically determine a wiring path between each land and a plating lead arranged on the outer periphery thereof by using a counter virtually arranged for each land.
[0035]
(5) In the present invention,
Priorities are assigned in advance to each land arranged in a matrix,
The wiring route determining step includes:
A step of determining the next wiring target land based on the priority of each land and the presence or absence of a counter whose count value has been exceeded,
Performing a process of determining the determined wiring route between the wiring target land and the inner lead based on the position of the open counter;
It is preferable to include
[0036]
Further, the information storage medium of the present invention,
Contains information on the priority assigned to each land arranged in a matrix,
The wiring route determination information includes:
Information for determining the next wiring target land based on the priority of each land and the presence or absence of a counter whose count value has been exceeded,
Information for performing a process of determining the determined wiring path between the wiring target land and the inner lead based on the position of the open counter;
It is preferable to include
[0037]
According to the present invention, each time a wiring route is determined based on a count value of a virtually arranged counter and a priority assigned to each land in advance, a next land to be wired is determined, The wiring route to the land can be determined automatically and efficiently.
[0038]
Note that the priority order means a priority order or a priority order in which a land having a higher priority is determined as a wiring target land unless there is another restriction.
[0039]
(6) In the present invention,
It is preferable that the priority of each land arranged in a matrix is set as follows.
[0040]
First, a center line passing through each of the rectangular sides formed by the land groups arranged in the matrix and the rectangular diagonal line are assumed.
[0041]
The priority order of each land included in each trapezoidal area divided into eight by the center line and the diagonal line is defined as a plurality of diagonal lines connecting diagonally adjacent lands along the diagonal line as priority order setting lines. Sometimes, the priority order of the lands included in the priority order setting line far from the diagonal line is high, and the lands located on the same priority order setting line have higher priority as they are located on the outer peripheral side of the land group. Set.
[0042]
In other words, the priority is
Assuming a reference line that divides the central shared portion into two on both processing surface sides, priority is given to a plurality of diagonal lines connecting lands located diagonally to the reference line side from each land located on the opposite side to the inner lead. The lands located on the opposite side of the inner lead are higher than the lands included in the priority setting line, and lands located on the same priority setting line are located on the opposite side of the inner lead. It is preferable that the priority is set higher as the position is higher.
[0043]
This makes it possible to efficiently determine the wiring route in each of the trapezoidal divided regions in the order of the central shared portion at the center, the processing surfaces located on both sides thereof, and the surface shared portion located on the outermost side. .
[0044]
In particular, according to the present invention, the wiring between each inner lead and the land can be efficiently performed with the shortest distance and substantially bilaterally symmetric when viewed from the entire divided region.
[0045]
(7) In addition, the wiring route determining step includes:
Open control of the first counter on the reference line side and the fourth counter on the opposite side of the inner lead for a pair of lands having the highest priority and belonging to the center common portion and located on both sides of the reference line Initially, the second and third counters located on opposite sides of the first and fourth counters are closed and the reference line counters of the lands belonging to the rows adjacent to the reference line are opened. A step of setting,
A step of determining a reference wiring path between each inner lead serving as a reference and the pair of lands along a path guided by the open counter,
A step of repeatedly performing a process of determining a wiring route from the reference wiring route side to the surface sharing unit side without intersecting with the reference wiring route,
It is preferable to include
[0046]
Further, the wiring route determination information includes:
Open control of the first counter on the reference line side and the fourth counter on the opposite side of the inner lead for a pair of lands having the highest priority and belonging to the center common portion and located on both sides of the reference line Initially, the second and third counters located on opposite sides of the first and fourth counters are closed and the reference line counters of the lands belonging to the rows adjacent to the reference line are opened. Information for setting,
A step of determining a reference wiring path between each inner lead serving as a reference and the pair of lands along a path guided by the open counter,
Information for repeatedly performing a process of determining a wiring route from the reference wiring route side to the surface sharing unit side without intersecting with the reference wiring route,
It is preferable to include
[0047]
In the present invention, lands having the highest priority located on both sides of the reference line are lands located on the opposite side of the divided area when viewed from the central inner lead corresponding to the divided area.
[0048]
In the present invention, this pair of lands is first set as a land for which a wiring route is to be determined. Then, of the plurality of counters present around the pair of lands, the first counter on the side of the central shared portion and the fourth counter located on the side opposite to the inner lead are opened and controlled, That is, the second counter located on the inner lead side and the third counter located on the surface sharing unit side are controlled to close.
[0049]
Further, the reference line side counter of each land located in the row adjacent to the reference line is controlled to open. That is, the counters belonging to the same row as the first counter located on the side of the common center of the wiring symmetric land are controlled to be opened.
[0050]
In this way, the initial setting of the virtually arranged counter is performed, and the reference wiring path between the inner lead serving as a reference and the pair of wiring symmetric lands is determined.
[0051]
Then, the process of determining the wiring route in the trapezoidal divided region is sequentially and repeatedly performed from the reference wiring route side to the surface sharing unit side on both sides thereof.
[0052]
This makes it possible to more efficiently determine the wiring path of the divided area.
[0053]
(8) The method of the present invention comprises:
Including inputting parameters for wiring,
The wiring route determining step includes:
It is preferable to perform a process of determining the wiring route based on the input parameters.
[0054]
Further, the information storage medium of the present invention,
Includes information for entering wiring parameters,
The wiring route determination information includes:
It is preferable to include information for performing a process of determining the wiring route based on the input parameters.
[0055]
With the above configuration, it is possible to automatically determine the wiring route according to the wiring parameters.
[0056]
In particular, when it is determined that wiring cannot be performed based on the input wiring parameters, new parameters may be input, so that a circuit board having optimal parameters can be designed in a short time and efficiently. Can be.
[0057]
(9) In addition, the wiring route determination device according to the present invention
Means for inputting wiring parameters;
Using the method, the inner lead group arranged in a rectangular shape, means for determining the wiring path between the land group arranged in a matrix to surround the inner lead group in a rectangular shape,
It is characterized by including.
[0058]
By doing so, it is possible to realize an apparatus that can automatically and efficiently determine the wiring path between the inner lead group and the land group.
[0059]
(10) Further, the wiring board of the present invention comprises:
A group of inner leads arranged in a rectangular shape,
Land groups arranged in a matrix so as to surround the inner lead group in a rectangular shape,
A pattern wiring group for electrically connecting the inner lead group and the land group,
Including
The pattern wiring group includes:
When the land group is virtually divided into a plurality of symmetrical regions, wiring is performed in the same pattern for each divided region.
[0060]
put it here,
The land group,
When placed around the inner lead group in a square shape,
The pattern wiring group includes:
When the land group is virtually divided into four symmetrical regions corresponding to the respective sides of the square, the lands are wired in the same pattern for each divided region.
[0061]
In addition, the land group is
When placed around the inner lead group in a rectangular shape,
The pattern wiring group includes:
When the land group is virtually divided into two symmetrical regions corresponding to two adjacent sides of the rectangular shape, wiring is performed in the same pattern for each divided region.
[0062]
BEST MODE FOR CARRYING OUT THE INVENTION
Next, a preferred embodiment of the present invention will be described in detail with reference to the drawings.
[0063]
(1) Outline of circuit to which the present invention is applied
FIG. 1 is a schematic view showing a film carrier tape to which the present invention is applied.
[0064]
In FIG. 1, a device hole 12 and a sprocket hole 14 are formed in a tape-shaped film 10 formed of a resin.
[0065]
The film 10 includes an inner lead group 20 formed so as to surround the device hole 12 in a square shape, a land group 30 arranged in a matrix so as to surround the inner lead group in a rectangular shape, and a periphery of the land group 30. Are formed so as to surround. Further, a first wiring lead 40 is formed in a one-to-one relationship between each inner lead 22 forming the inner lead group 20 and each land 32 forming the land group 30. A second wiring lead 42 is formed between 32 and the plating lead 16. The inner lead group 22, land group 30, first and second wiring leads 40 and 42, and plating lead 16 are formed by etching a copper foil on a tape substrate.
[0066]
Each land 32 is an area for providing a ball terminal (not shown). The inner lead 22 has one end protruding from the device hole 12 and the other end connected to the first lead 40.
[0067]
Inside the device hole 12, the end of the inner lead 22 is bonded to an electrode (not shown) of the semiconductor chip 18.
[0068]
Each land 32 is connected to the plating lead 16 via the second lead 42. For this reason, all the lands 32 and the leads 22, 40, and 42 are conducted through the plating leads 16, so that they can be electroplated.
[0069]
After the semiconductor chip 18 is mounted on the film 10, the film 10 is punched as a tape circuit board 11 indicated by a chain line in the figure.
[0070]
When designing such a tape circuit board 11, the first inner lead group 20 having a rectangular shape and the land group 30 arranged in a rectangular shape around the inner lead group 20 do not intersect with each other in the first group. An important issue is how to determine the wiring path of the wiring lead 40. An important issue is how to determine the wiring path of the second wiring lead 42 without intersecting the wiring between the land group 30 and the plating lead 16 arranged around the land group 30. Become.
[0071]
In particular, each of the inner leads 22 forming the inner lead group 20 and each of the lands 32 forming the land group 30 arranged in a matrix basically have a one-to-one relationship. If the ratio is not one-to-one, for example, if the number of inner leads is small or the number of ball lands is small, the larger number is used alone. Therefore, how to determine a wiring path between the inner lead group 20 and the land group 30, that is, a wiring pattern in a limited space is an important issue in the development and design of the circuit board 11.
[0072]
In particular, the number of leads 40 and 42 that can be wired between lands 32 adjacent to each other in the land group 30 is limited. Within this limitation, it is not possible to design and determine a wiring pattern for selecting all the inner leads 22 and the lands 32 before manufacturing the circuit board 11 without intersecting adjacent leads. Very important.
[0073]
Conventionally, such a wiring route is determined manually by a designer through trial and error. For this reason, it takes too much time and effort to determine the wiring route, which has been a major problem in circuit board development.
[0074]
An object of the present embodiment is to make it possible to automatically and efficiently determine the wiring paths of the first and second wiring leads 40 and 42 in the circuit design stage.
[0075]
(2) Circuit board design equipment
FIG. 2 shows an example of a design device for determining the wiring path of the tape circuit board 11, more specifically, the film 10, and designing the circuit board.
[0076]
The design apparatus according to the present embodiment includes an input unit 110 operated by an operator, a data processing unit 120 configured using various CPUs and memories, an information storage medium 130 storing various information, and an output unit. 140.
[0077]
The information storage medium 130 stores information such as an algorithm for circuit design and various data. This information includes an algorithm for determining a wiring path, an algorithm for designing a circuit pattern, and programs and data having other necessary algorithms, which will be described later. It functions as the wiring route determination unit 124.
[0078]
FIG. 3 shows a flowchart for the wiring route determination calculation.
[0079]
In step S10, the designer inputs circuit board data and various parameters for determining a wiring route. 4 and 5 show an example thereof.
[0080]
For example, when designing the tape circuit board 11 shown in FIG. 1, the size of the land group 30 arranged in a rectangular matrix is input. Here, each land is regarded as a cell, and the size of the land group 30 is input as the size of a frame in which a plurality of cells are arranged in a matrix. Specifically, the vertical and horizontal lengths a1 and a2 of the outer periphery of the frame and the thicknesses b1 and b2 of the vertical and horizontal frames are input as frame sizes. Further, the number of cells constituting the frame, that is, the number of lands 32 is input.
[0081]
Further, as shown in FIG. 5, the size of each cell constituting the matrix, the land size of the land 32 existing in each cell, and the land gap are input. Further, as shown in FIG. 5C, the lead wire width of each of the leads 40 and 42 and the gap between the leads to be wired so as to pass through the region between the lands 32 are input.
[0082]
When such an input is completed, the processing unit 120 performs a process for designing the circuit board 11 in step S12.
[0083]
First, the virtual board setting unit 122 virtually designs, for example, the circuit shown in FIG. 1 based on the input data.
[0084]
At this time, the cell size of the matrix, the area that cannot pass between the lands 32, the area that can pass, the lead wire pitch, and the like are obtained based on the following formulas.
Cell size = frame size / number of cells
Non-passable area = Land size + (Land gap x 2)
Passable area = cell size-impassable area
Lead pitch = Lead width + Lead gap
Using the data of the non-passable area, the passable area, and the like thus obtained, the number of leads 40 and 42 that can pass between the lands 32 adjacent in the vertical and horizontal directions and the number of the lands adjacent in the oblique direction The number of oblique lines that can pass between 32 is obtained based on the following equation. In addition, the surplus power of the number of passable lines and the number of passable lines of oblique lines is omitted.
Passable number = (passable area + lead gap) ギ ャ ッ プ lead pitch
Number of passing shaded parts =
(Passable area + gap between leads) x {2} lead pitch
The wiring path determining unit 128 is configured to provide a wiring path of the first wiring lead 40 connecting the inner lead group 20 and the land group 30 and a wiring path of the second wiring lead 42 connecting the land group 30 and the plating lead 16. Is determined so that the number of wires passing between the lands falls within the number of passable wires, and the leads do not cross each other.
[0085]
Then, the data processing unit 120 outputs the data via the output unit 140 when the determination of all the wiring paths is completed.
[0086]
If the input parameters do not allow wiring of the leads 40 and 42 described above, the data processing unit 120 outputs an error message via the output unit 140 in step S14. At this time, the designer only has to input new parameters, such as a land size, a land gap, a lead wire width, and a gap between leads from the input unit 110 again. Accordingly, the data processing unit 120 performs the calculation process for determining the wiring route shown in step S12 based on the new parameter, and outputs the calculation result from the output unit 140 in step S14.
[0087]
As described above, according to the apparatus of the present embodiment, the designer inputs the wiring parameters, thereby determining the wiring path of the first wiring lead 40 connecting the inner lead group 20 and the land group 30. In addition, the wiring path of the second wiring lead 42 connecting the land group 30 and the plating lead 16 can be automatically determined.
[0088]
The details will be described below.
[0089]
(3) Division of wiring area
FIG. 6 schematically shows land groups 30 arranged in a matrix on the outer periphery of the inner lead group 20 arranged in a rectangular shape so as to surround the inner lead group 20 in a rectangular shape. Here, each cell 34 in the land group 30 virtually represents an area where the land 32 exists. It should be noted that the number of cells shown here is set as a number that is significantly smaller than the actual number of cells in order to simplify the description.
[0090]
(3-1) Dividing into four divided areas
In the present embodiment, when determining the wiring path of the wiring leads 40 and 42, the land group 30 having a rectangular shape is virtually divided into four trapezoidal areas corresponding to the respective sides of the rectangular shape. Here, the rectangular land group 30 is virtually divided into four trapezoidal divided regions 200-1, 200-2,..., 200-4 along a pair of diagonal lines 202-1 and 202-2.
[0091]
Further, a pair of center lines 204-1 and 204-2 orthogonal to the top, bottom, left, and right in the figure are assumed for the rectangular land group 30.
[0092]
In each divided area 200, one land row corresponding to both sides of the trapezoid is an area shared with an adjacent divided area, that is, a plane sharing unit 220-1 or 220-2.
[0093]
(3-2) Subdivision of divided area
FIG. 7 shows an example of each divided area 200. Here, the divided area 200 is divided into a center shared part 210 composed of two rows of lands located on both sides of the center line 204, and a plane shared part 220-1 located in an area corresponding to both sides of the trapezoid. , 220-2 and the processing surfaces 230-1 and 230-2 located between the center sharing unit 210 and the plane sharing unit 220. Then, as will be described later, the determination of the wiring route of the divided area 200 is performed in the order of the center sharing unit 210, the processing surfaces 230-1, 220-1 from the area on the left side of the center line 204, and then the center The processing is performed on the area on the right side of the line 204 in the order of the center sharing unit 210, the processing surface 230-2, and the surface sharing unit 220-2. In addition, the processing may be sequentially performed from the central sharing unit 210 to the processing surfaces 230-1 and 230-2 and the surface sharing units 220-1 and 220-2 located on both sides thereof.
[0094]
By doing so, the wiring of the wiring leads 40 and 42 in the divided area 200 can be made substantially symmetrical with respect to the center line 204.
[0095]
In performing such a wiring, as described later, the wiring of the processing surfaces 230-1 and 230-2 is performed according to a normal algorithm. -1 and 230-2, a special connection processing method is employed in part because of the processing of expanding the wiring path. Further, the wiring in the surface sharing units 220-1 and 220-2 partially adopts a special connection processing method based on the relationship with the adjacent divided regions. A specific connection processing method will be described later.
[0096]
Thus, according to the present embodiment, the wiring path of the divided region 200 having a substantially trapezoidal shape is determined. At this time, when the land matrix of the four divided regions 200-1, 200-2, 200-3, and 200-4 is the same, if the wiring route of one divided region is determined, The wiring path can be diverted as it is as a wiring path of another divided area. That is, as shown in FIG. 8A, if the wiring route of the divided region 200-1 is determined, then as shown in FIG. 8B, this wiring route is changed to the wiring route of the divided region 200-2. As shown in FIG. 8 (C), it is further diverted as a wiring route of another divided region 200-3, and further, as shown in FIG. 8 (D), further diverted as a wiring route of divided region 200-4. can do. Thus, by determining the wiring pattern of the wiring leads 40 and 42 of one divided area 200-1, this wiring pattern is used as the wiring pattern of the remaining three areas 200-2, 200-3 and 200-4. Since it can be reused, the calculation load required for determining the wiring route can be significantly reduced.
[0097]
When only the opposing divided areas of the land group 30 are formed as divided areas having the same land matrix arrangement, first, as shown in FIG. 9A, the divided areas 200-1 and 200- 9, the wiring route of the divided region 200-1 is diverted as the wiring route of the divided region 200-3 as shown in FIG. This is diverted as a wiring route of the divided route 200-4 to be divided.
[0098]
By doing so, the load for determining the wiring route can be significantly reduced.
[0099]
(4) Determination of wiring route in divided area
Next, details for determining the wiring paths of the first and second leads 40 and 42 in each divided region 200 will be described.
[0100]
FIG. 10 schematically shows the divided area 200. Here, the same direction as the center line 204 is defined as a row, and the direction orthogonal to this is defined as a column.
[0101]
(4-1) Lead number
FIG. 11 is an explanatory diagram of the inner lead group 20 located inside the divided area 200. In the inner lead group 20, each inner lead 22 is assigned a lead number of 1, 2, 3,... From the inner leads located on both sides of the center line 204 toward both sides.
[0102]
Then, the inner leads 22 are sequentially selected as wiring target leads in ascending order of allocation number.
[0103]
(4-2) Priority of land
FIG. 12 shows an example of priorities assigned in advance to the lands 32 arranged in a matrix. Here, in the divided area 200 shown in FIG. 7, the priority order assigned to the lands in the area on the left side of the center line 204 is shown.
[0104]
First, the lands 32 located on the row adjacent to the left side of the center line 204, that is, the lands 32 located on the left side of the center line 204 of the center common portion 210 have higher priority as the lands 32 located on the plating lead 16 side. Is set. As a result, if there are no other constraints, the lands of the central shared unit 210 are sequentially selected as the wiring target lands in the order indicated by the arrows.
[0105]
In the processing surface 230 and the surface sharing unit 220, the priorities of the lands arranged in a matrix are set as follows.
[0106]
The priority order of each land included in each trapezoidal area divided into eight by the center line 204 and the diagonal line 202 is set as a priority order setting line. Suppose. The lands included in the priority setting line far from the diagonal line 202 have a higher priority, and the lands located on the same priority setting line have higher priority as they are located closer to the outer periphery of the land group. Set. As a result, if there are no other constraints, the lands on the processing surface 230 and the surface sharing surface 220 are sequentially selected as the lands for wiring in the order indicated by the arrows.
[0107]
In the divided area 200, the priority order is assigned to the area on the right side of the center line 204 such that the priority order is line-symmetric with the priority order shown in FIG.
[0108]
By assigning such priorities, as shown in FIG. 11, each inner lead 22 is sequentially selected as a wiring target lead from the lead on the center line 204 side, and further, each land is As shown in (1), the lands are selected as wiring target lands in accordance with priorities assigned in advance. Therefore, if there are no other restrictions, the wiring paths of the leads 40 are connected so that the inner leads 22 corresponding to the lead numbers shown in FIG. 11 and the lands according to the priority shown in FIG. Will be determined.
[0109]
(4-3) Wiring route determination process using virtual counter
As described above, the number of leads 40 and 42 that can pass between the lands 32 is limited to a predetermined number. In the present embodiment, it is assumed that the number is limited to a maximum of four.
[0110]
Under such a restriction, it is not possible to simply sequentially select the wiring target lands according to the priority shown in FIG. 12 and determine the wiring route.
[0111]
Therefore, the wiring circuit determination unit 124 of the present embodiment is configured to function as the virtual counter setting control unit 126 and the target land determination unit 128.
[0112]
As will be described in detail below, the virtual counter setting control unit 126 virtually sets a counter 300 for counting the number of leads 40 and 42 that pass through an area between adjacent lands 32 around each land 32.
[0113]
The target land determination unit 128 determines the land 32 to be wired each time based on the priority of each land 32 and the data of the virtual counter 300 described above.
[0114]
Then, the wiring circuit determination unit 124 determines the wiring paths of the wiring leads 40 and 42 connecting the determined wiring target land 32 and the leads 22 and 16 based on the data of the counter 300.
[0115]
The details will be described below.
[0116]
As shown in FIG. 13, a total of four virtual counters are virtually installed in the row and column directions around each land 32 arranged in a matrix. Here, first to fourth counters 300-1, 300-2, 300-3, and 300-4 are virtually installed around the land 32 and between adjacent lands.
[0117]
In the algorithm for determining the wiring path according to the present embodiment, the setting of the wiring path of the new leads 40 and 42 to the area between the lands 32 is performed by controlling the counter 300 installed between the lands to open. It is configured to allow only when there is.
[0118]
Therefore, by controlling the open / close state of the virtually arranged counter 300, the wiring path of the wiring leads 40 and 42 can be automatically determined.
[0119]
Each of the counters 300 counts the number of the leads 40 and 42 determined to pass through the area between the leads 32 where the open counter 300 is present when the open counter is in the open counter state. I do. Each counter 300 does not perform such a counting operation when it is in the closed counter state under the closed control.
[0120]
FIG. 14 schematically shows rules for controlling the opening and closing of the virtual counter 300. As shown in FIG. 14A, adjacent lands 32 share a counter 300 with each other.
[0121]
FIG. 15 schematically shows a procedure for determining a wiring route in the center sharing unit 210.
[0122]
First, the target inner lead is the inner lead 22 having the first lead number shown in FIG. The wiring target land 32T of the inner lead is the land with the highest priority in the center sharing unit 210, that is, the land 32-1 located on the plating lead 16 side.
[0123]
A: Initial setting of counter
The virtual counter setting control unit 124 according to the present embodiment sets the virtual counter 300 around the first wiring target land 32-1 (32T) in order to determine the wiring path of the first wiring leads 40 and 42. Initial setting is performed as shown in FIG.
[0124]
That is, the first virtual counter 300-1 located on the center line 204 side and the fourth virtual counter 300-4 located on the plating lead 16 side are controlled to open, and the first and fourth virtual counters 300- The first and third virtual counters 300-2 and 300-3 opposed to each other across the land 32-1 are controlled to be closed.
[0125]
Further, the virtual counter (first virtual counter) 300 on the center line 204 side of the lands 32-2, 32-3, and 32-4 belonging to the same row as the wiring target land 32-1 is similarly opened.
[0126]
All other counters are controlled to be closed. In this way, the virtual counter is initialized before the wiring route is determined.
[0127]
B: Count operation
In the present embodiment, the wiring path between the wiring target inner lead 22 and the wiring target land 32-1 is determined so that the lead 40 passes through the area where the open counter 300 exists. Further, the path of the wiring lead 42 between the wiring target land 32-1 and the plating lead 16 is determined so that the lead 42 passes through the area where the open counter exists.
[0128]
As a result, as shown in FIG. 15, the wiring paths of the first first wiring lead 40 and the second wiring lead 42 are determined.
[0129]
At this time, each open counter 300 located in the wiring path of the wiring leads 40 and 42 is controlled so as to increment its count value.
[0130]
C: Counter control around the land to be wired
When the wiring paths of the wiring leads 40 and 42 with respect to the wiring target land 32-1 are determined, each of the virtual counters 300 that are opened and closed around the wiring target land 32-1 as shown in FIG. -1,..., 300-4 are controlled to open and close as shown in FIG. That is, the first and fourth counters 300-1 and 300-4 are controlled to be closed, and the second and third counters 300-2 and 300-3 are controlled to be opened.
[0131]
As a result, a planned route for new wiring of the wiring leads 40 and 42 to the next land to be wired is set.
[0132]
D: Control for determining the second and subsequent wiring routes
The path of the first wiring lead 40-2 connecting the second inner lead 22 and the second wiring target land 32-2 is based on the area where the open counter 300 exists as shown in FIG. It is determined. Similarly, the wiring path of the second wiring lead 42-2 connecting the wiring target land 32-2 and the plating lead 16 is also determined based on the area where the open counter exists. Then, the count value of the virtual counter 300 located on the wiring path of these wiring leads 40-2 and 42-2 is incremented.
[0133]
After the determination of the wiring route, the virtual counter 300 located around the wiring target land 32-2 is controlled to open and close according to the rule shown in FIG. That is, the first and fourth counters 300-1 and 300-4 are controlled to be closed, and the second and third virtual counters 300-2 and 300-3 are controlled to be opened.
[0134]
E: Wiring rules specific to the common center
Similarly, the wiring path between the third inner lead 22-3 and the third wiring target land 32 is determined. In the center sharing unit 210, it is preferable to determine the wiring path of the wiring lead 40 so as to be substantially symmetrical in the right and left regions via the center line 204. For this reason, the wiring between the inner lead 22 and the land 40 is restricted so that it is permitted only when the value of the virtual counter 300 located on the side of the center line 204 is within two.
[0135]
Therefore, as shown in FIG. 16, even when the counters 300A3 and 300A4 are open, the wiring path determination unit 128 sets the wiring path of the first wiring lead 40 in the area where the counters 300A3 and 300A4 exist. not allowed. For this reason, according to the priority shown in FIG. 12, the next wiring target land should be 32-3, but here, the above-described wiring restriction rule of the counter has priority. Then, a land that can be wired under this condition is determined as a land to be wired. Here, as shown in FIG. 17, a special process is performed in which the counter 32-4 on the inner lead side is determined as the wiring target land 32T. Then, the wiring path of the first wiring lead 40 connecting the third inner lead 22 to the wiring target land 32-4 is determined. At this time, the process of determining the wiring route of the second wiring lead 42 is not restricted by the wiring restriction rule of the counter described above. For this reason, the wiring path of the second wiring lead 42 is determined based on the position of the open counter so as not to intersect with the immediately preceding wiring lead 42-2.
[0136]
Then, the count value of the counter located between the lands 32 through which the wiring leads 40 and 42 have passed is automatically incremented.
[0137]
F: Counter control around wiring target land during special processing
The counter around the land 32-3 for which the wiring route is determined is controlled to open and close as shown in FIG. That is, as shown in FIG. 14D, when only the counter 300 on the center line 204 side of the land 32 is open and the wiring route to the land 32 is determined, only the open counter 300-1 is turned on. Close control is performed, and only the third counter 300-3 located in the opposite direction is controlled to open.
[0138]
When the wiring route is determined as shown in FIG. 17, next, as shown in FIG. 18, based on the existing position of the open counter 300 and the priority order of the lands, the land of 32-3 becomes 4 It is determined as the second wiring target land 32T. Then, the wiring paths of the first and second wiring leads 40 and 42 are determined based on the data on the position of the open counter.
[0139]
In this way, the wiring path between each land 32 belonging to the central shared portion 210 and the inner lead 22 is automatically determined.
[0140]
G: Other control rules of the counter
It should be noted that, in addition to the rules described above, when the count value of the open counter exceeds the count value of the open counter, that is, when the count value exceeds 4, as shown in FIG. There is a rule that the open counter 300 is closed and the counter 300 located in the opposite direction across the land 32 is opened.
[0141]
H: Summary of counter control rules
The control rules of the counter according to the present embodiment are summarized as follows.
[0142]
First, the rules for initializing the counter are summarized.
[0143]
(First rule)
As shown in FIG. 14B, the first and fourth counters 300-1 and 300-4 are opened and the second and third counters 300-2 are opened for the first wiring target land 32T. , 300-3 are closed.
[0144]
(Second rule)
First, the virtual counter 300 located on the center line 204 side of the land belonging to the same row as the land 32T to be wired is opened, and the other counters are closed.
[0145]
Next, the control rules of the counter during the operation of the wiring route determination processing are summarized.
[0146]
(First rule)
When the wiring route is determined for the wiring target land 32T in the state shown in FIG. 14B, the surrounding counter is controlled from the state shown in FIG. 14B to the state shown in FIG. I do.
[0147]
(Second rule)
As shown in FIG. 14D, when the wiring path is determined for the wiring target land 32T in which only the counter on the side of the center line 204 is open, the open counter 300 is closed and the counter is located on the opposite side. Open control of the closed counter.
[0148]
(Third rule)
As shown in FIG. 14 (D), when the count value of the open counter 300 is exceeded, the open counter is closed, and the open counter of this counter and the closed counter located on the opposite side of the land 32 is controlled to open.
[0149]
By controlling the counter 300 based on the above first to third rules, the wiring target land 32T is appropriately determined based on the area where the open counter exists and the priority order of the land 32 shown in FIG. The wiring path between the land 32 and the inner lead 20 and the plating lead 16, that is, the wiring path of the first and second wiring leads 40 and 42 can be automatically determined.
[0150]
I: Summary of wiring route determination rules
Next, the wiring route determination rules will be summarized.
[0151]
(basic rule)
The wiring route is sequentially set in the inter-land area where the open counter exists.
[0152]
(Restrictive rules)
The basic rules have restrictions. This is a specific rule for wiring the first wiring lead 40 in the center sharing unit 210.
[0153]
In the central sharing unit 210, when the count value of the open counter 300 exceeds 2 (when the number exceeds half of the number that can pass), even if the counter is open, The rule is that a new wiring of the first wiring lead 40 is not allowed in the existing land area. Note that this rule is applied only when determining the wiring route of the first wiring lead 40 in the center sharing unit 210, and when determining the wiring route of the second wiring lead 42 and determining the wiring route in other areas. Not applicable.
[0154]
FIG. 19 shows the wiring paths of the entire area of the central sharing unit 210 determined according to such a rule.
[0155]
J: Wiring path on processing surface
When the wiring pattern in the central sharing unit 320 is determined in this manner, the operation of determining the wiring path on the processing surface 230 is performed next, as shown in FIGS.
[0156]
This wiring path determination processing operation is basically performed based on the priority assigned to each land as shown in FIG. 12 and the position of the open counter of the counter that is controlled to open and close according to the above-described rule. Is
[0157]
In the present embodiment, as shown in FIGS. 15 to 18 described above, when the wiring route of the center sharing unit 210 is determined, there is no open counter whose count value has exceeded. Therefore, as shown in FIG. 20, the land 32-5 having the highest priority among the remaining lands is determined as the wiring target land 32T. Then, based on the position where the open counter 300 exists, the wiring path of the first and second wiring leads 40 and 42 to the wiring target land 32-5 (32T) is determined.
[0158]
Thus, even when the wiring route to the land 32-5 is determined, there is no open counter exceeding the count value among the open counters. For this reason, as shown in FIG. 21, the land with the next highest priority, 32-6, is determined as the wiring target land 32T. Then, the wiring paths of the first and second wiring leads 40 and 42 are determined based on the position where the open counter 300 exists. Similarly, as shown in FIG. 22, the next wiring route is determined using the land 32-7 as the wiring target land 32T.
[0159]
When the wiring route is determined as shown in FIG. 22, some of the open counters exceed the count value. In this case, if it is simply based on the priority, the land 30-8 at the lower left becomes the next wiring target land. However, since an excess counter is generated, as shown in FIG. A special process for determining −14 as the next wiring target land 32T is performed. Then, the wiring paths of the first and second wiring leads 40 and 42 are determined based on the position of the open counter.
[0160]
When the wiring path is determined as shown in FIG. 23, next, the land 30-10 is set as the wiring target land 32T, and the next wiring path is determined as shown in FIG.
[0161]
By repeatedly performing such processing, the wiring paths of the first and second wiring leads 40 and 42 on the processing surface 230 can be automatically determined.
[0162]
K: Processing of surface supply unit
FIG. 25 shows details of the plane sharing unit 220.
[0163]
In the plane sharing unit 220, adjacent divided areas 200-1 and 200-4 share a land to be wired, as indicated by a chain line in the drawing.
[0164]
The determination of the wiring route for each of the lands 32 is performed using the same algorithm as the determination of the wiring route on the processing surface 230 described above, except that only the lands 32 of the divided region 200 to which the user belongs are targeted.
[0165]
According to the present embodiment, such a wiring process for the divided region 200 is performed by, as shown in FIG. 7, one central shared unit 210, one processing surface 230-1, one surface shared unit 220-1, and the other. The processing is performed in the order of the central sharing unit 210, the other processing surface 230-2, and the surface sharing unit 220-2.
[0166]
When it is determined that wiring is not possible in the calculation of the wiring route, an error message is output from the output unit 140 shown in FIG. Therefore, in this case, a new parameter may be input from the input unit 110 again, and an arithmetic process for determining a wiring path may be performed under different conditions.
[0167]
In this manner, it is possible to efficiently determine the wiring route in the divided area 200 automatically and efficiently while changing the value of the input parameter.
[0168]
When the wiring pattern of one divided area 200 is determined in this way, as shown in FIGS. 8A to 8D, the pattern of the wiring path of this divided area 200-1 is changed to another divided area. The wiring patterns of the regions 200-2, 200-3, and 200-4 can be diverted as they are. Therefore, the process of determining the wiring route of the entire circuit board can be performed in an extremely short time.
[0169]
In addition, as shown in FIG. 9, when only the opposing divided areas have a symmetric configuration, the wiring path is determined for the divided areas 200-1 and 200-2 using the above-described method. After that, as shown in FIG. 9B, the wiring paths of the divided regions 200-1 and 200-2 that have already been determined can be diverted to the remaining divided regions 200-3 and 200-4. Therefore, even in this case, the calculation load for the wiring route determination processing can be significantly reduced.
[0170]
(5) Detailed algorithm for wiring route determination
Hereinafter, a more detailed algorithm for determining the wiring path of the first and second wiring leads 40 and 42 will be described.
[0171]
(5-1) Algorithm for determining the wiring route of the entire circuit board
FIG. 26 shows a flowchart of this algorithm.
[0172]
First, in step S20, conditions for determining a wiring route, for example, various parameters described above are input.
[0173]
Next, in step S22, the virtual board setting unit 122 virtually sets the circuit board 11 as shown in FIG. 6, for example, and performs a process of creating a work area on the circuit board 11. Here, as a work area, the land group 30 is divided into four divided areas 200-1, 200-2, 200-3, and 200-4, and each divided area is further divided into a central shared section 210 as shown in FIG. It is subdivided into processing surfaces 230-1 and 230-2 and surface sharing units 220-1 and 220-2.
[0174]
Then, in the next steps S24 to S32, a process of determining the wiring pattern of the first and second wiring leads 40 and 42 is performed on the subdivided divided area 200-1.
[0175]
Next, in step S34, it is determined whether or not the number of cells in the divided region 300-1 is equal to the number of cells in the remaining divided regions 300-2 to 300-4. That is, it is determined whether or not the matrix arrangement of the lands 32 of the divided area 300-1 in which the wiring pattern is determined and the remaining divided areas 300-2 to 300-4 are the same.
[0176]
If it is determined that they are the same, in step S36, the generated wiring pattern data is rotated by 90 degrees, 180 degrees, and 280 degrees as shown in FIGS. A process of copying as wiring pattern data of the areas 200-2, 200-3, and 200-4 is performed.
[0177]
If it is determined in step S34 that the number of cells is not the same, in the next step S38, the wiring pattern determination processing in steps S24 to S32 is performed again on another divided area 200-2.
[0178]
Then, in the next step S40, the generated wiring pattern data of the divided areas 200-1 and 200-2 is rotated by 180 degrees and copied as the wiring pattern data of the divided areas 200-3 and 200-4. Perform processing.
[0179]
As described above, according to the present embodiment, the wiring paths of the plurality of first wiring leads 40 connecting the inner lead group 20 and the land group 30 are determined, and the land group 30 and the plating lead 16 are connected. The determination of the wiring path of the second wiring lead 42 can be performed automatically and efficiently.
[0180]
(5-2) Algorithm for determining wiring route in divided area
FIG. 27 shows a flowchart of the wiring path determination processing for the first and second leads 40 and 42, which is performed in steps S24 to S32 described above.
[0181]
First, in step S60, it is determined whether the acquisition direction of the wiring route in the divided area 200 shown in FIG. 7 is to be directed leftward or rightward from the center line 204.
[0182]
Next, in step S62, a process of listing candidates for the wiring target land 32T existing in the determined acquisition direction is performed.
[0183]
Next, in step S64, a process of determining the next wiring target land 32T from the group of lands listed as candidates is performed. Details of this processing will be described later with reference to FIG.
[0184]
Next, in step S66, when it is determined that an error has occurred in the processing in step S64, it is determined that the subsequent wiring path cannot be determined, and the wiring path determination processing operation is stopped here.
[0185]
If it is determined in step S66 that no error has occurred, it is next determined in step S68 whether or not the wiring target land 32T exists. When it is determined that there is no wiring route, the wiring routes for all the lands in the area have been determined, and the work of determining the wiring route is completed at this time.
[0186]
If it is determined in step S68 that the wiring target land 32T exists, in the next step S70, the lead wire numbers of the first and second leads 40 and 42 to be wired to the wiring target land 32T are determined. I do. This number is assigned to each of the leads 40 and 42 as a serial number.
[0187]
Next, in step S72, it is determined whether or not the allocated number is the first number, that is, whether or not the lead is the lead 40 or 42 for which the wiring route is determined first.
[0188]
If it is determined that it is the first lead, then in step S74, an initial route determination process is performed. This initial route determination process will be described later with reference to FIG.
[0189]
If it is determined in step S72 that the read is not the first read, a normal route determination process is performed in step S76. This route determination processing will be described later with reference to FIG.
[0190]
In the present embodiment, such a series of processing of steps S60 to S76 is repeatedly performed, the land 32T to be wired is specified each time, and the first and second wiring leads 40 and 42 for the land 32T are specified. The process of determining the wiring route, that is, the route determination process, is repeatedly performed.
[0191]
(5-3) Initial Route Determination Algorithm
FIG. 28 shows a detailed algorithm of the initial route determination processing in step S74, and FIGS. 33 to 38 show specific examples of control of the counter 300 associated with this route determination.
[0192]
First, prior to the initial route determination process in step S74, in step S64, the wiring target land 32T is determined.
[0193]
As shown in FIG. 33, when the initial route is created, that is, when the initial route is created in the center sharing unit 210, the land located on the plating lead 16 side (the side opposite to the inner lead 22) is the wiring of the first lead wire. It is set as the target land 32T.
[0194]
Then, in step S80 in FIG. 28, the four counters 300-1 to 300-4 existing around the wiring target land 32T are determined as the use counters 300T, and the four use counters 300T are determined as shown in FIG. Open / close control is performed as shown in FIG.
[0195]
The use counter 300T located on the side opposite to the lead acquisition direction with respect to the wiring target land 32T, that is, the first counter 300-1 located on the center line 204 side is used as a route start / end counter determination counter. Determine as 300 ref. (See FIG. 33)
Next, in step S82, a route start counter 300S is determined based on the use counter 300ref as shown in FIG. That is, the counter closest to the inner lead 22 in the row where the determination counter 300ref exists is determined as the route start counter 300S.
[0196]
Next, in step S84, a route end counter 300E is determined based on the determination counter 300ref as shown in FIG. Here, the counter closest to the plating lead 16 in the row where the determination counter 300ref exists is defined as the route end counter 300E. Here, the same counter 300 is set as the determination counter 300ref and the route end counter 300E.
[0197]
Next, in step S86, a movement counter 300M for determining a wiring route is set at the position of the start counter 300S.
[0198]
Next, in step S88, it is determined whether or not the movement counter 300M has moved to the use counter 300T. Here, since it has not yet moved to the use counter 300T, the passage counter process is performed next in step S90.
[0199]
36 and 37 show specific examples of the passage counter processing.
[0200]
That is, in the present embodiment, a pair of passing flags fa and fb are virtually set in each counter 300 toward a pair of lands 32 adjacent thereto. Then, as shown in FIG. 36, when a predetermined open counter 300 is set as the movement counter 300M in order to set a wiring route, a direction in which a new wiring route is obtained (a direction opposite to the center line 204). The flag on the side of the adjacent land 32a is set to a passable state, and the land 32a is set as a land where new wiring can be obtained. Then, the count value of the movement counter 300M is incremented.
[0201]
At the same time, as shown in FIG. 37, the counter 32b located on the center line 204 side of the movement counter 300M is set to a ball land that cannot be acquired. That is, the passage flag set corresponding to the land 32b is set to an unpassable state.
[0202]
In this way, when the movement counter 300M passes, of the pair of lands 32A and 32B located on both sides of the wiring route newly set with the passage of the movement counter 300M, the land located on the surface sharing unit 220 side. 32a is set as a newly routable ball land 32a, and the land 32b located on the center line 204 side is set as an unobtainable ball land.
[0203]
This prevents the wiring path of the next lead from intersecting with the immediately preceding wiring path.
[0204]
Next, in step S96, it is determined whether or not the movement counter 300M has reached the end counter 300E.
[0205]
Here, since it is determined that it has not reached yet, next, in step S92, a process of moving the movement counter 300M to the counter of the next column in the same row is performed.
[0206]
Such a series of processing of steps S88 to S92 is repeatedly performed until the movement counter 300M reaches the use counter 300T, here the determination counter 300ref.
[0207]
If it is determined in step S88 that the movement counter 300M has reached the determination counter 300ref, then in step S94, use counter processing is performed.
[0208]
The use counter process of step S94 is performed by adding four counters 300-1, 300-2,..., 300-4 existing as the use counter 300T in the state shown in FIG. This is executed as a process of controlling the switching to the state shown in FIG. 4C and passing the wiring leads 40 and 42 through the land 32T to be wired.
[0209]
In the present embodiment, the second wiring lead 42 is directly pulled out from the counter 300-4 side of the wiring target land 32 and connected to the plating lead 16 so that the lead length of the second wiring lead 42 is made as short as possible. Execute the wiring process. For this purpose, in the present embodiment, the four use leads 300-1, 300-2,..., 300-4 are opened and closed as shown in FIGS.
[0210]
That is, as shown in FIG. 38, when the movement of the movement counter 300M reaches the determination counter 300ref, the wiring cannot pass through the flag on the wiring target land 32T set corresponding to the movement counter 300M. The wiring lead 40 is passed through the land 32T as shown in FIG. Then, the land 32T is set as the acquired ball land.
[0211]
Next, as shown in FIG. 40, processing is performed on each of the lands 32c, 32d, and 32e adjacent to the wiring target land 32T.
[0212]
If each of the adjacent lands 32c, 32d, and 32e is an acquired ball land for which a wiring route has already been determined, a process of closing a shared counter between the adjacent land and the wiring target land 32T is performed.
[0213]
If each of these adjacent lands 32c, 32d, 32e is a land that can be wired, that is, a land that can be acquired, a pass flag assigned to a shared counter with the land is set to a passable state.
[0214]
If the common counter for the adjacent lands 32c, 32d, and 32e is open and these adjacent counters are unobtainable ball lands, a flag is set so that these adjacent lands are set as obtainable lands. Change and open the shared counter.
[0215]
The process of opening the passage flag on the side of the land 32T is performed on the counter (the fourth counter 300-4 in the present embodiment) located in the direction where there is no adjacent ball land. Thus, it is possible to determine the wiring path for directly pulling out the second wiring lead 42 from the target land 32T toward the fourth counter 300-4 and connecting to the plating lead 16.
[0216]
When the use counter processing of such an example is completed, the processing of steps S88 to 92 is repeated until it is determined in step S96 that the movement counter 300M has reached the end counter 300E.
[0217]
Then, to step S92, when it is determined that the movement counter 300M has reached the end counter 300E, the initial route setting process is completed (step S98).
[0218]
(5-4) Normal Route Determination Algorithm
FIG. 29 shows a detailed flowchart of the normal route determination process described in step S76 of FIG.
[0219]
Prior to performing the process in step S76, in step S64, the land 32T to be next wired is determined.
[0220]
In the route determination process shown in FIG. 29, first, in step S100, a process of determining the counters 300-1, 300-2,..., 300-4 existing around the wiring target land 32T as the use counter 300T is performed.
[0221]
Here, since the wiring target land 32T is set as shown in FIG. 42, four counters existing around the land 32T are set as the use counter 300T.
[0222]
Next, in step S102, the route start counter 300S is determined, and in the next step S104, the route end counter 300E is determined.
[0223]
FIG. 43 shows a specific example of a process for setting the route start counter 300S and the route end counter 300E.
[0224]
The determination of the route start counter 300S in step S102 is performed based on the following rules.
[0225]
The basic rule is that a start counter 300S of the same route as the immediately preceding wiring route is used as a route start counter for the current wiring.
[0226]
If the immediately preceding route start counter is closed, the counter located on the side of the surface sharing unit 220 via the ball land 32S is opened with respect to the immediately preceding route start counter, and this counter is set to a new route start counter. The first exception rule is set as a counter.
[0227]
If the new route start counter set according to the first exception rule is already set as the use counter, the counter located on the inner lead side of the land 32s is set as the route start counter 300S. To the second exception rule. This is a process when the land 32s facing the inner lead side is set as the wiring target land 32T.
[0228]
The determination of the route end counter 300E in step S104 is performed based on the following rules.
[0229]
The basic rule is that the route end counter 300E used for determining the route of the immediately preceding wiring lead is used as a new route end counter 300E.
[0230]
If the route end counter 300E used immediately before is closed, a counter located on the side of the surface sharing unit 220 via the land 32E is selected as a new route end counter for this counter, and processing for opening this counter is performed. Do the first exception rule.
[0231]
If the new counter has already been set as the use counter, the second exception is that a counter located on the plating lead side of the land 32E is acquired and set as a new route end counter 300E. Follow the rules. If this counter is also set as the usage counter and is closed, the processing is interrupted.
[0232]
When the route start counter 300S and the route end counter 300e are determined in this way, next, in step S106, the movement counter 300M is set to the route start counter 300S, and the route determination operation of steps S108 to S134 is started.
[0233]
First, in step S108, it is determined whether or not the movement counter 300M has moved to the position of the use counter 300T.
[0234]
Immediately after the processing in step S106, the movement counter has not moved to the use counter 300T.
[0235]
Since the passage counter processing in step S110 is similar to the passage counter processing described in step S90 in FIG. 28, the description thereof is omitted here.
[0236]
Next, in step S112, it is determined whether or not the movement counter 300M has moved to the end counter 300E.
[0237]
Next, in step S114, it is determined whether or not the movement counter 300M is the same counter as the counter used for determining the wiring route of the immediately preceding lead wire.
[0238]
If it is determined that the counters are the same, then in step S116, it is determined whether a counter adjacent to the plating lead side in the same row as the movement counter 300M is open.
[0239]
If it is determined that it is open, in step S118, processing is performed to move the movement counter 300M to the next counter adjacent to the plating lead side.
[0240]
The processing of steps S114 to S118 is repeated until a counter controlled to be closed appears on the same wiring route as the immediately preceding lead wire.
[0241]
Then, when a counter that has been used for the immediately preceding route setting and that has been closed and controlled has appeared, in step 120, an open counter to be moved by the movement counter 300M is searched. In steps S122 and S126, the search is performed. The movement counter 300M is moved toward the counter.
[0242]
That is, when it is determined in step S114 that the movement counter 300M is different from the counter used for determining the wiring path of the immediately preceding lead, or in step S116, the counter adjacent to the movement counter 300M on the plating lead side is different from the movement counter 300M. If it is determined that the counter is not open, a search for an open counter is performed in step S120.
[0243]
If it is determined in step S122 that the search in step S120 has failed, the route creation is interrupted at that time (step S124).
[0244]
If it is determined in step S122 that the search was successful, in step S126, a process of moving the movement counter 300M to the newly found counter is performed.
[0245]
In this way, the movement counter 300M is sequentially moved, and new wiring paths for the wiring leads 40 and 42 are sequentially determined.
[0246]
If it is determined in step S108 that the movement counter 300M has moved to the use counter 300T, then use counter processing is performed in step S130. This use counter process is the same as the process described in detail in step S94 in FIG. 28, and thus the description thereof is omitted here.
[0247]
Next, in step S132, a process of changing the usage counter is performed. This processing is also similar to the above-described processing of step S94, and thus the description thereof is omitted here.
[0248]
When the processing of steps S130 and S132 is completed in this way, the processing of steps S108 to S126 is repeatedly performed until the movement counter 300M moves to the end counter 300E next, and the movement from the target land 32T to the plating lead 16 is performed. The wiring path of the second wiring lead 42 is determined.
[0249]
When it is determined in step S112 that the movement counter 300M has reached the end counter 300E, the process moves to step S134, and the route creation processing is completed.
[0250]
(5-5) Processing for determining wiring target land 32T
Next, the determination processing of the wiring target land 32T in step S64 of FIG. 27 will be described.
[0251]
FIG. 30 shows a flowchart of the process of determining the wiring target land 32T.
[0252]
First, in step S200, it is determined whether there is a land for which a wiring route has not yet been determined, that is, a land that has not been acquired.
[0253]
Next, in step S204, it is determined whether or not an open counter whose count value has exceeded has occurred.
[0254]
If it is determined in step S204 that no occurrence has occurred, the land acquisition basic process in step S206 is performed. Details of this process are shown in FIG.
[0255]
If it is determined in step S204 that the excess counter has occurred, the land acquisition special process in step S208 is performed. Details of this processing are shown in FIG.
[0256]
Then, in step S210, it is determined whether an error has occurred in the land acquisition processing in step S208. If it is determined that an error has occurred, the process of determining the wiring target land 32T ends in step S212.
[0257]
If it is determined in step S210 that no error has occurred, or if the process of step S206 is completed, then, in step S214, a process of determining the obtained highest priority pole land as the wiring target land 32T is performed.
[0258]
If it is determined in step S200 that there is no land that has not been acquired, the process of determining the land 32T to be wired ends at that time. (Step S202).
[0259]
Next, the details of the land acquisition basic process of step S206 and the land acquisition special process of step S208 will be described.
[0260]
FIGS. 45 and 46 show details of the assignment of the priority order to each land 32 described with reference to FIG. Although FIG. 12 assumes that four lands 32 exist between the inner lead and the plating lead, FIGS. 45 and 46 show an example in which six lands exist between them. I will explain.
[0261]
FIG. 45 shows an example of priorities assigned to one processing surface 30-1 and surface sharing unit 220-1. FIG. 46 shows the other processing surface 230-2 and surface sharing. An example of the priority order assigned to the unit 220-2 is shown.
[0262]
FIG. 47 shows a specific example of the process of determining the wiring target land 32T based on the priority order assigned to each land in this way and the location of the open counter.
[0263]
First, the land acquisition basic process in step S206 will be described. FIG. 31 shows a detailed flowchart of this process.
[0264]
This land acquisition basic process S206 is based on the premise that it is determined in step S204 that an open counter exceeding the count value has not occurred. In such a case, for example, a state shown in FIG.
[0265]
In this state, in step S300, an arbitrary ball land is selected with the highest priority from the N obtainable lands.
[0266]
In steps S304 and S306, the priority of the currently selected land is compared with the priority of the next candidate land. If there is a land with a higher priority, the selected land is replaced with a land with a higher priority. Is performed. Such a process is performed for all candidates.
[0267]
If it is determined in step S302 that the comparison process in steps S304 and S306 has been completed for all candidates, a process of determining the land 32 selected at this time as the highest priority pole land is performed (step S308). ).
[0268]
For example, in the case of the specific example shown in FIG. 47A, in step S300, when the connection processing for the land with the second priority is completed, the priority of 4 is set as a candidate for the next land to be connected. The lands of 5, 5, 6, 10, 15, and 21 are selected as acquisition target lands. An arbitrary land is selected in step S300.
[0269]
Then, the priority of the selected land is compared with the priority of the other lands, and finally the land with the highest priority, here, the land with the priority “3” is determined as the highest priority pole land.
[0270]
Next, the land acquisition special process in step S208 will be described. FIG. 32 shows a detailed flowchart of this process. The process in step S208 is based on the premise that it is determined in step S204 that an open counter whose count value has been exceeded has occurred.
[0271]
47B and 47C show specific examples of the land acquisition special processing.
[0272]
In any case, it is assumed that lead wiring paths have already been determined for the two lands having the priorities of 1 and 2.
[0273]
Accordingly, here, the land with the next highest priority is the land with the third priority.
[0274]
In this state, lands that are candidates for the next wiring target land 32T are lands having priorities of 4, 5, 3, 6, 10, 15, and 21, respectively.
[0275]
Then, in the land acquisition special process shown in FIG. 32, first, in step S400, it is determined whether or not there are a plurality of lands having counters whose count values have exceeded the acquisition target lands.
[0276]
Here, for example, as shown in FIG. 47B, when it is determined that there is only one land having an excess counter (here, a land of priority 15), this land (ie, a land of priority 15) Is determined as the highest priority pole land (step S402).
[0277]
If it is determined in step S400 that there are a plurality of corresponding lands, then in step S404, the excess land number counter is set to 0, and in step S406, whether or not land extraction has been completed is determined. to decide.
[0278]
Then, in step S408, a process of extracting a plurality of lands having a counter whose count value has been exceeded is performed.
[0279]
Then, it is determined whether or not the extracted land is a land belonging to the center sharing unit 210.
[0280]
If it is determined that the land is the land of the central shared portion, then, in step S142, it is determined whether or not the excess counter of the land exceeds the maximum passable number. If it is determined that it has exceeded, in step S414, this land is registered as the top priority land.
[0281]
If it is determined in step S412 that the number does not exceed the maximum passable number, then in step S420, the value of the excess land number counter is determined. If it is determined that the count value is zero, it is next determined in step S422 whether or not there is an already registered highest priority land. If it is determined that the land is not zero, the extracted land is registered as the highest priority land in step S424.
[0282]
If it is determined in step S422 that there is an already registered highest priority land, then in step S426, the extracted land is compared with the already registered highest priority land, and the land closer to the inner lead is determined. Register the land as the top priority land.
[0283]
If it is determined in step S410 that the extracted land is not the land of the central shared portion, then in step S414, this land is registered as the highest priority land.
[0284]
When the registration process in step S414 is completed, a process of counting up the excess land number counter is performed in step S416, and it is determined in step S418 whether the value of the excess land number counter has exceeded 2. You. If it is determined that the number has exceeded 2, a land acquisition error is determined (step S430).
[0285]
If it is determined in step S418 that the count number does not exceed 2, the process returns to step S406.
[0286]
Then, such a series of processing is repeated, and when it is determined in step S406 that the land extraction is completed, processing for determining the registered highest priority land as the highest priority ball land in step S402 is performed. .
[0287]
For example, as shown in FIG. 47 (C), when it is determined that the excess has occurred in the three lands of the priority levels 10, 15, and 21, the land of the priority level 21 closest to the inner lead is determined to be the highest. It is determined as a priority ball land.
[0288]
Note that the present invention is not limited to the above-described embodiment, and various modifications can be made within the scope of the present invention.
[0289]
For example, in the above-described embodiment, the present invention has been described by exemplifying the case where the wiring route of the tape circuit board 11 is determined. However, the present invention is applicable to the case where the wiring route of other various circuit boards is determined. Is possible.
[0290]
Further, in the above-described embodiment, the case where the process of determining the wiring route is started from the center shared portion side of the divided area is described as an example. However, the present invention is not limited to this, The processing may be started.
[0291]
[Brief description of the drawings]
FIG. 1 is an explanatory diagram showing an example of a tape circuit board to which the present invention has been applied.
FIG. 2 is a functional block diagram illustrating an example of a wiring route determination device to which the present invention has been applied.
FIG. 3 is a flowchart showing the operation of the apparatus shown in FIG. 2;
FIG. 4 is an explanatory diagram of various input items input in a condition input step shown in FIG. 3;
FIG. 5 is an explanatory diagram of another input item input in the condition input step shown in FIG. 3;
FIG. 6 is an explanatory diagram of a divided area.
FIG. 7 is an explanatory diagram of a state in which a divided area is subdivided into a central shared unit, a processing plane, and a plane shared unit.
FIG. 8 is an explanatory diagram of a series of processes for determining a wiring route of the entire circuit by diverting a wiring pattern determined for one divided region to another divided region.
FIG. 9 is an explanatory diagram of a process of determining a series of wiring paths of the entire circuit by diverting wiring paths determined for a plurality of divided areas to other wiring paths.
FIG. 10 is an explanatory diagram of rows and columns of a divided area.
FIG. 11 is an explanatory diagram of numbers assigned to inner lead groups.
FIG. 12 is an explanatory diagram of priorities assigned to land groups.
FIG. 13 is an explanatory diagram of a counter virtually arranged for each land.
FIG. 14 is an explanatory diagram of a specific example of control on a counter virtually arranged for each land.
FIG. 15 is an explanatory diagram of a wiring route determination process for a land of a central shared unit.
FIG. 16 is an explanatory diagram of a wiring route determination process for a land of a central shared unit.
FIG. 17 is an explanatory diagram of a wiring route determination process for a land in the center common part.
FIG. 18 is an explanatory diagram of a wiring path determination process for a land of a common center part.
FIG. 19 is an explanatory diagram of a wiring route determination process for a land of a common center part.
FIG. 20 is an explanatory diagram of a wiring route determination process for a land on a processing surface.
FIG. 21 is an explanatory diagram of a wiring route determination process for a land on a processing surface.
FIG. 22 is an explanatory diagram of a wiring route determination process for a land on a processing surface.
FIG. 23 is an explanatory diagram of a wiring route determination process for a land on a processing surface.
FIG. 24 is an explanatory diagram of a wiring route determination process for a land on a processing surface.
FIG. 25 is an explanatory diagram of a process performed on a land by the plane sharing unit.
FIG. 26 is a flowchart illustrating a specific operation of a wiring route determination process.
FIG. 27 is a flowchart illustrating a specific operation of a wiring route determination process.
FIG. 28 is a flowchart showing a detailed process of step S74 in FIG. 27;
FIG. 29 is a flowchart showing a detailed process in step S76 in FIG. 27;
FIG. 30 is a flowchart showing a detailed process of step S64 in FIG. 27;
FIG. 31 is a flowchart showing a detailed process of step S206 in FIG. 30;
FIG. 32 is a flowchart illustrating a detailed process of step S208 in FIG. 30;
FIG. 33 is an explanatory diagram of a specific process of an initial route determination process in step S74 of FIG. 27;
FIG. 34 is an explanatory diagram of a setting process of a route start counter when setting an initial route.
FIG. 35 is an explanatory diagram of a process of setting a route end counter when setting an initial route.
FIG. 36 is an explanatory diagram of the operation of the movement counter when setting an initial route.
FIG. 37 is an explanatory diagram of the operation of the movement counter when setting an initial route.
FIG. 38 is an explanatory diagram of processing when a movement counter moves to a use counter when setting an initial route.
FIG. 39 is an explanatory diagram of a process when the movement counter moves to the passage counter.
FIG. 40 is an explanatory diagram of a control operation of a counter when setting an initial route.
FIG. 41 is an explanatory diagram of a control operation of a counter when setting an initial route.
FIG. 42 is an explanatory diagram of a counter control operation for a wiring target ball land when setting a normal route.
FIG. 43 is an explanatory diagram of setting processing of a start counter and an end counter when setting a normal route.
FIG. 44 is an explanatory diagram of a process of moving a movement counter when setting a normal route.
FIG. 45 is an explanatory diagram of priorities set for one processing surface and the surface sharing unit;
FIG. 46 is an explanatory diagram of priorities set for the other processing surface and the surface sharing unit.
FIG. 47 is an explanatory diagram showing a specific example of a process of determining a land to be wired based on a priority set in advance for each land and the existence intention of an excess counter.
[Explanation of symbols]
10 films
11 Tape circuit board
20 Inner lead group
22 Inner lead
30 lands
32 Land
40 First Wiring Lead
42 Second Wiring Lead
110 Input unit
120 processing unit
122 Virtual board setting unit
124 virtual counter setting control unit
126 Target land determination unit
128 Wiring path determination unit
130 Information storage medium
140 Output unit
200 divided areas
202 Opposite line
204 center line
210 Central shared part
220-1 and 220-2 plane shared unit
230-1, 230-2 processing surface
300 virtual counters

Claims (10)

Based on the input information, means for setting a virtual circuit board having a group of inner leads arranged in a rectangular shape and a group of lands arranged in a matrix so as to surround the inner lead group in a rectangular shape,
  Means for determining a wiring route between an inner lead group and a land group of the virtual circuit board
  In a computer-readable information storage medium storing a program that causes the computer to function as
  The means for determining the wiring route includes:
  A first means for dividing the land group into four trapezoidal divided regions each having four bases of four outer sides of the virtually rectangular land group,
  Second means for performing a process of determining a wiring route between the inner lead group and the land group for each of the divided regions having different land matrix arrangements from the four divided regions subjected to the four divided processing;
  Third means for diverting the determined wiring route as a wiring route of another divided region having the same land matrix arrangement and performing a process of determining a wiring route of the another divided region;
  Including
  The first means includes:
  Performing the quadrant division process on the land group so that each of the adjacent trapezoidal divided regions shares one row of land rows corresponding to trapezoidal sides as a surface sharing unit;
  The second means includes:
  A trapezoidal divided area to be wired is divided into a center common portion composed of at least two rows of lands at the center of the matrix, a pair of processing surfaces located on both sides thereof, and the surface sharing portion located outside each processing surface. Means for performing processing for subdividing into
  The determination of the wiring route of the divided region is performed in the order of the central shared portion, the processing surface, and the surface shared portion, and further, the surface shared portion determines the wiring route so as to share the wiring to the adjacent divided region and each land. Determining means for determining;
  Including
  The determining means includes:
  Means for virtually arranging a plurality of counters for counting the number of wiring paths that are opened and controlled by a predetermined rule and pass between adjacent lands around each of the lands,
  The wiring path between the next inner lead adjacent to the inner lead for which the wiring path has been determined and the next wiring target land determined by the predetermined rule intersects with the immediately preceding wiring path between the lands where the open counter exists. Wiring path determining means for performing a process of deciding to pass without passing, the center shared portion, the processing surface, the surface shared portion in order,
  The open counter whose count value has been exceeded and the open counter determined by the wiring route of the corresponding land are closed, and the closed counter located on the opposite side to the closed controlled counter via the corresponding land is opened and controlled. Counter control means for setting a route leading the wiring,
  An information storage medium comprising: In claim 1 ,
The wiring route determining means includes:
The wiring route from the lands arranged in the matrix to the plating leads provided on the outer periphery thereof is determined so that the wiring passes through the land where the counter is open without intersecting with the wiring route immediately before. Means for
The counter control means ,
The open counter whose count value is exceeded by the wiring route determination process between the plating lead and the land is closed and the closed counter located on the opposite side to the closed control counter is opened and controlled via the corresponding land, and new wiring is performed. An information storage medium including means for performing a process of setting an area leading to the information. In any one of claims 1 and 2 ,
Data of the priority assigned to each land arranged in a matrix is further stored ,
The wiring route determining means includes:
Means for determining the next wiring target land based on the priority of each land and the presence or absence of a counter whose count value has been exceeded,
Means for performing a process of determining the determined wiring path between the wiring target land and the inner lead based on the position of the open counter;
An information storage medium comprising: In claim 3 ,
The priority of each land in the matrix is
Assuming a center line passing through each of the rectangular sides formed by the land groups arranged in the matrix, and the rectangular diagonal line,
The priority order of each land included in each area divided into eight by the center line and the diagonal line,
When a plurality of diagonal lines connecting lands adjacent in the diagonal direction along the diagonal line are set as priority setting lines, the priority of the lands included in the priority setting line far from the diagonal line is high and the same. An information storage medium, wherein lands located on a priority order setting line are set so as to have higher priority as they are located closer to the outer periphery of the land group. In claim 4 ,
The wiring route determining means includes:
Open control of a first counter on the reference line side and a fourth counter on the opposite side of the inner lead for a pair of lands having the highest priority and belonging to the center shared portion and located on both sides of the reference line Initially, the second and third counters located on the opposite side of the first and fourth counters are closed and the reference line side counters of the lands belonging to the rows adjacent to the reference line are opened. Means for making settings;
Means for determining a reference wiring path between each inner lead serving as a reference and the pair of lands along a path guided by the open counter,
Means for repeatedly performing a process of determining a wiring route from the reference wiring route side to the surface sharing unit side without intersecting with the reference wiring route,
An information storage medium comprising: Based on the input information, means for setting a virtual circuit board having a group of inner leads arranged in a rectangular shape and a group of lands arranged in a matrix so as to surround the inner lead group in a rectangular shape,
  Means for determining a wiring path between the inner lead group and the land group of the virtual circuit board,
  In a circuit board design device having
  The means for determining the wiring route includes:
  A first means for dividing the land group into four trapezoidal divided regions each having four bases of four outer sides of the virtually rectangular land group,
  Second means for performing a process of determining a wiring route between an inner lead group and a land group from the four divided areas subjected to the four division processing, for each divided area having a different land matrix arrangement;
  Third means for diverting the determined wiring route as a wiring route of another divided region having the same land matrix arrangement and performing a process of determining a wiring route of the another divided region;
  Including
  The first means includes:
  Performing the quadrant division process on the land group so that each of the adjacent trapezoidal divided regions shares one row of land rows corresponding to trapezoidal sides as a surface sharing unit;
  The second means includes:
  A trapezoidal divided area to be wired is divided into a center common portion composed of at least two rows of lands at the center of the matrix, a pair of processing surfaces located on both sides thereof, and the surface sharing portion located outside each processing surface. Means for performing processing for subdividing into
  The determination of the wiring route of the divided area is performed in the order of the central shared part, the processing surface, and the surface shared part, and the wiring shared by the surface shared part is such that the wiring to the adjacent divided area and each land is shared. Determining means for determining
  Including
  The determining means comprises:
  Means for virtually arranging a plurality of counters for counting the number of wiring paths that are opened and controlled by a predetermined rule and pass between adjacent lands around each of the lands,
  The wiring path between the next inner lead adjacent to the inner lead for which the wiring path has been determined and the next wiring target land determined by the predetermined rule intersects with the immediately preceding wiring path between the lands where the open counter exists. Wiring path determining means for performing a process of deciding to pass without passing, the center shared portion, the processing surface, the surface shared portion in order,
  The open counter whose count value has been exceeded and the open counter determined by the wiring route of the corresponding land are closed, and the closed counter located on the opposite side to the closed controlled counter via the corresponding land is opened and controlled. Counter control means for setting a route leading the wiring,
  A circuit board designing apparatus, comprising: In claim 6,
  The wiring route determining means includes:
  The wiring path from the land arranged in the matrix to the plating lead provided on the outer periphery thereof is determined between the lands where the counter is open so that the wiring can pass without intersecting with the wiring path immediately before. Means for
  The counter control means,
  The open counter whose count value is exceeded by the wiring route determination process between the plating lead and the land is closed and the closed counter located on the opposite side to the closed control counter is opened and controlled via the corresponding land, and new wiring is performed. A circuit board design apparatus including means for performing a process of setting an area leading to the circuit board. In any one of claims 6 and 7,
Data of the priority assigned to each land arranged in a matrix is further stored,
The wiring route determining means includes:
Means for determining the next wiring target land based on the priority of each land and the presence or absence of a counter whose count value has been exceeded,
Means for performing a process of determining the determined wiring path between the wiring target land and the inner lead based on the position of the open counter;
A circuit board designing apparatus, comprising: In claim 8,
  The priority of each land in the matrix is
  Assuming a center line passing through each of the rectangular sides formed by the land groups arranged in the matrix, and the rectangular diagonal line,
  The priority order of each land included in each area divided into eight by the center line and the diagonal line,
  When a plurality of diagonal lines that connect lands adjacent in the diagonal direction along the diagonal line are set as priority setting lines, the priority of the lands included in the priority setting line far from the diagonal line is high and the same. A circuit board design apparatus, wherein lands located on a priority order setting line are set so as to have higher priority as they are located closer to the outer periphery of the land group. In claim 9,
The wiring route determining means includes:
Open control of a first counter on the reference line side and a fourth counter on the opposite side of the inner lead for a pair of lands having the highest priority and belonging to the center shared portion and located on both sides of the reference line Initially, the second and third counters located on the opposite side of the first and fourth counters are closed and the reference line side counters of the lands belonging to the rows adjacent to the reference line are opened. Means for making settings;
Means for determining a reference wiring path between each inner lead serving as a reference and the pair of lands along a path guided by the open counter,
Means for repeatedly performing a process of determining a wiring route from the reference wiring route side to the surface sharing unit side without intersecting with the reference wiring route,
A circuit board designing apparatus, comprising:

Images