JP2006209493A - Device for designing electrical wiring board - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a device for designing an electrical wiring board, the device which has a data inputting means 5, a wiring pattern illustrating means 1, a network generating means 2 and a data outputting means 6 and enables inspection contents to be set in a designing stage, the inspection being performed during a manufacturing process of a wide variety of electrical wiring boards and after completing the product. <P>SOLUTION: The device for designing an electrical wiring board is provided with a network attribute information defining means 3 for setting an attribute value with respect to a network prepared by the network generating means 2 and an inspection attribute information defining means 4 for setting inspection information of the electrical wiring board by referring to the network attribute value set by the network attribute information defining means 3. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an electric wiring board designing apparatus used when designing an electric wiring board such as a printed board or a BGA board.

  Conventionally, when designing an electrical wiring board such as a printed circuit board for mounting a semiconductor package or a BGA board for mounting a semiconductor chip, an electrical wiring board design apparatus (or CAD) having an integrated function has been used. ing. The electrical wiring board design apparatus has a wiring drawing function for generating a net based on a net list and connecting two points indicated by the net based on the net information. In addition to this, if the design rule check function of the electrical wiring board is provided in addition to this, wiring design that can be manufactured according to the manufacturing process and the characteristics after completion are expected to meet the specifications is possible. Can be completed.

  In the case of a conventional ordinary electric wiring board, if the wiring is simply geometrically connected and there is no abnormality such as dirt on the appearance, the product satisfies the specifications. In such a substrate, inspection items during manufacture and after production of the product are relatively simple. It is sufficient to perform a pattern inspection that inspects the connection state of the wiring pattern of each layer, an appearance inspection that inspects dirt, foreign matter, and discoloration on the appearance, and an open short inspection that inspects the connection state of the wiring after the product is completed. . In addition, in these inspections, the inspection contents are not changed depending on the attributes of each net, and the same inspection contents are performed on all nets in principle.

  On the other hand, electrical wiring boards are required to have many strict product specifications and functions in response to the recent increase in speed and functionality of electronic devices and electronic devices. Typical examples are as follows. One is a board with controlled characteristic impedance, transmission delay, and skew for high speed. The other is a board with built-in passive components for noise and ground bounce countermeasures or analog circuits. Such high-function and multifunctional electrical wiring boards have a wide variety of inspections related to products. For example, a high-speed board requires characteristic impedance inspection, S-parameter inspection, and the like, and if the transmission method becomes differential, these change the inspection contents to differential impedance inspection and differential S-parameter inspection. In the component built-in board, circuit parameter measurement such as LCR of passive components is further added.

  In contrast to the current state of such electric wiring boards, the conventional electric wiring board designing apparatus is dedicated exclusively to the drawing of wiring patterns, and functions that take efficiency into consideration when inspecting the electric wiring boards or wiring patterns. It did not have in particular. In the conventional electric wiring board design apparatus, after completion of the wiring pattern design, it is output as Gerber data and the geometric shape of the wiring pattern is sent to the manufacturing process and the inspection process. In the inspection process, the wiring connection status is extracted as a net from the geometric shape data of the wiring pattern, and this net data is used for the inspection.

  However, if only the geometric shape data of the wiring pattern is shared between the design process and the inspection process, it is necessary to generate completely different nets in both processes. Of course, there is a big problem other than that. If a defect occurs in a net, which is an inspection process, the net is generated according to different rules in the design process, and the net name is not common to both processes, so the defect location is fed back to the design process using the net name. Can not do it. Therefore, there is a problem in that it is impossible to design a wiring pattern with a low production defect rate by quickly feeding back defects in the production process to the design process.

  The above problems are in the conventional normal electrical wiring board, which becomes more serious in the high-speed multifunctional electrical wiring board. For electrical wiring boards that meet specifications simply by connection, there are three inspection items: pattern, appearance, and open short. In addition, it is only necessary to perform a common inspection for all nets. Therefore, even if information related to inspection is not added to the net at the design stage, if a new net is generated at the inspection stage and this net is inspected, it can be managed even if the efficiency is low. On the other hand, inspection items such as characteristic impedance, S-parameters, and LCR circuit parameters are very large for high-speed substrates and component-embedded substrates. Further, these inspection items are performed not on all nets but on specific nets. For example, inspection of characteristic impedance is unnecessary for a power supply or ground net. In a net in which the characteristic impedance is specified, the value and the allowable range are different for each net. If the net impedance value and its allowable range are not set for each net, the quality of the wiring pattern cannot be determined by inspection. Therefore, it is necessary to generate new nets in the inspection process and first specify which inspection target these nets are. Further, if the characteristic value such as impedance required for the net and its allowable range are not set, the inspection cannot be performed. That is, there is a big problem that a necessary inspection cannot be performed accurately unless the design specifications of the net are known in the inspection process. And, setting inspection items based on the net design specifications in the inspection process is very inefficient because it is mostly repetitive work with the net setting performed in the design process. In addition, since it is highly likely that the person in charge of inspection is not technically familiar with the specifications related to the electrical characteristics, which is the main part of the net design specifications, the inspection staff sets inspection items based on the net design specifications in the inspection process. Easy to make mistakes.

The known literature is shown below.
JP2003-216680A.

  An object of the present invention is to provide an electric wiring board designing apparatus that solves the above-described problems and enables setting of inspection contents performed in a wide variety of electric wiring board manufacturing processes and after product completion at a design stage. It is in.

In order to achieve the above object, the present invention provides an electrical wiring board design apparatus according to claim 1, wherein the electrical wiring board design apparatus includes a data input means, a wiring pattern drawing means, a net generation means, and a data output means. In the wiring board designing apparatus, referring to the net attribute information defining means for setting the attribute value for the net created by the net generating means, and the net attribute value set by the net attribute information defining means, Inspection attribute information defining means for setting the inspection contents is provided.

  3. The electrical wiring board designing apparatus according to claim 2, wherein the inspection attribute information defining means includes global inspection attribute information defining means for setting inspection contents independent of a net, and inspection contents for a single net. And a net group inspection attribute information defining means for setting inspection contents for a net group composed of a plurality of nets.

  4. The electrical wiring board design device according to claim 3, wherein the net attribute information defining means is composed of a plurality of nets and net attribute information defining means for setting an attribute value for a single net. It comprises a net group attribute information defining means for setting an attribute value for a net group.

  5. The electrical wiring board device according to claim 4, wherein the inspection attribute information defining unit refers to a net attribute value set by the net attribute information defining unit and calculates the net attribute value. An arithmetic or programming function for setting inspection attribute information is provided.

  The electrical wiring board designing apparatus according to the present invention can set inspection attribute information such as inspection items and inspection pass / fail criteria for the net by referring to the net attribute information set for the net, and is manufactured at the design stage. The inspection contents to be implemented after the process and product creation can be set at once. Thereby, it is not necessary to extract the net from the Gerber data of the wiring pattern again in the inspection process, and the inspection work is made efficient. In addition, since the same net is handled in the design process and the inspection process, it is possible to quickly feed back to the design process the net in which defects occurred in the inspection process, and to realize the design and manufacture of electrical wiring boards with a low defect occurrence rate. It becomes like this. In a high-speed and multifunctional electric wiring board, net inspection attribute information can be set from the net attribute for each net at the design stage. Therefore, which net performs what inspection in the inspection process can be automatically set by reading the net inspection attribute information attached to the net data. The reference values such as impedance and LCR and the allowable range are automatically read in the same manner, and become inspection criteria. The same applies to the net group attribute assigned to the net group. By reading the net group inspection attribute information, it is possible to automatically set inspection items and pass / fail judgment criteria for the net group. In this way, since the inspection contents for the net can be automatically set in the inspection process, the work efficiency of the inspection process can be further improved and the inspection content setting errors can be reduced in the high-speed and multifunctional substrate.

  By using the net attribute information set for the net to calculate the net inspection attribute information by calculation or program, it is possible to make the setting of the inspection attribute information more efficient. In particular, since inspection attribute information related to electrical characteristics can be calculated from net attribute information by calculation, the set time can be greatly reduced.

  Embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 1 shows a block configuration in the first embodiment of the electrical wiring board designing apparatus according to the present invention. The wiring pattern drawing unit 1, the net generation unit 2, the net attribute information definition unit 3, and the inspection attribute information definition unit 4 are connected so that data can be input from the data input unit 5. Further, the wiring pattern drawing unit 1, the net generation unit 2, the net attribute information definition unit 3, and the inspection attribute information definition unit 4 are connected to the data output unit 6 so that data can be output. The wiring pattern drawing means 1 and the net generation means 2, the net generation means 2 and the net attribute information definition means 3, and the net attribute information definition means 3 and the inspection attribute information definition means 4 are connected so that they can refer to each other. Has been.

FIG. 2 shows a flowchart of typical design work of the electrical wiring board designing apparatus configured as described above. This flowchart is for when the design object is an FC-BGA substrate. First, a net list prepared in advance, that is, a list indicating the connection status between the FC pad of the semiconductor chip and the BGA pad of the BGA package is read (S1). Since the net names and coordinates of the FC pad and the BGA pad are described in this net list, the FC pad and the BGA pad are arranged in the respective wiring layers based on this (S2). When the arrangement of the FC and BGA pads is completed, pin assignment is made to these pads according to the net name of the net list (S3). A net that virtually connects the same assignment names of the FC pad and the BGA pad is generated (S4). Net creation is completed at this stage. Up to this point, there is no difference from the conventional electric wiring board design apparatus. Here, net attribute information is defined for the generated net (S5). As the net attribute information, a very large number of information can be conceived centering on electrical characteristic parameters. For example, the following are typical examples.

・ Signal system (power supply, ground, clock, address, data, etc.)
・ Transmission method (single-ended, differential, etc.)
・ Transmission line type (microstrip line, coplanar line, etc.)
・ Signal frequency ・ Transmission waveform ・ Transmission delay ・ Skew ・ Characteristic impedance ・ Type of built-in element ・ Characteristic of built-in passive element (LCR value)
Next, inspection attribute information is defined with reference to the set net attribute information (S6). For example, if the characteristic impedance is described in the net attribute information, the characteristic impedance inspection is set in the inspection attribute information of the net. The impedance reference value and allowable range are referred to from the net attribute information, and set as a quality determination criterion for the inspection of the inspection attribute information. The setting of inspection attribute information for such a net is sequentially performed. However, it is not necessary to set it for the net that you want to exclude from inspection. This setting procedure may be manually input for each net. However, in the example such as the characteristic impedance described above, the inspection attribute information can be easily set from the net attribute information, so the setting may be automated. When the setting of the inspection attribute information is completed, a wiring pattern is created in the same manner as in the conventional electric wiring board designing apparatus (S7). When the wiring has been created, the wiring pattern shape, net information, net attribute information, and inspection attribute information are output as design data (S8).

  If the design is performed in consideration of the inspection contents from the design stage as described above, it is not necessary to regenerate the net or set the inspection item for the generated net in the inspection process, so that the work efficiency is greatly improved. At the design stage, if net attribute information is defined, a lot of inspection attribute information can be set from the attribute information in a procedure almost automatic, which is far more efficient than performing it in the inspection process. For example, if a power source is defined as a net attribute, it can be determined from the power source information that the open short test is sufficient as the test attribute information automatically. Alternatively, it can be easily programmed to set the characteristic impedance and S-parameter as inspection items only for nets having a predetermined frequency or higher from the attribute of the signal frequency. Since there are many people who are not familiar with electrical characteristics in general, the operator of the inspection process is likely to cause many setting mistakes when setting such inspection items. Therefore, from this point of view, it is important to set inspection attribute information at the design stage.

  Next, FIG. 3 shows a partial block configuration in the second embodiment of the electrical wiring board designing apparatus. In general, the net of an electrical wiring board often has the same net attribute, such as a data bus and an address bus. In addition, for inspection items, there are pattern inspection, appearance inspection, open short inspection, etc. performed on all nets regardless of net attributes. Therefore, as shown in FIG. 3, the net attribute information defining means 3 comprises a single net attribute information defining means 3a and a net group attribute information defining means 3b, and the inspection attribute information defining means 4 is a global inspection attribute information defining means 4a. , Net inspection attribute information defining means 4b and net group inspection attribute information defining means 4c.

The procedure for setting the inspection attributes at this time is as shown in FIG. First, global inspection attributes are set (U1). This is a part for setting inspection contents that do not depend on the entire net or the net. Next, it is determined whether the target of the inspection attribute is a single net or a net group (U
2). This determination can be made easily and automatically because it is only necessary to determine whether the net attribute of the target net is a single net attribute or a net group attribute. A case where the target net has a net group attribute will be described. The net group attribute is referred from the net group attribute information defining means 3b (U3). A net group inspection attribute is set from the net group attribute value (U4). For example, it is assumed that the S-parameter of the wiring is to be inspected if the frequency is equal to or higher than a specified frequency. The signal frequency of the net group attribute is referred to and it is determined whether or not it is equal to or higher than the specified frequency. If the specified frequency is exceeded, set S-parameter in the net group inspection attribute. Also, the frequency range for measuring the S-parameter from the signal frequency is set in the net group inspection attribute. Since the above procedure can be set from a signal frequency by a simple calculation or program, it is possible to automatically set a net group inspection attribute. However, a unique net group inspection attribute that exists only in a certain product cannot be automatically set, so it is set manually (U5). The above procedure is the same for setting the net inspection attribute (U6, U7, U8).

  By having the means for defining net group attributes and net group inspection attributes in this way, inspection attributes can be set for a plurality of nets at once, so that the setting operation becomes very efficient.

  In the above embodiment, inspection attributes are set at the design stage and utilized in the inspection process to improve the efficiency of the inspection work. On the other hand, in the embodiment shown in FIG. 5, the inspection result in the inspection process is fed back to the design process to improve the design / manufacturing quality. Since the block configuration is almost the same as in the first embodiment, only the different parts will be described here. The inspection result registration means 7 is connected to the data input means 5 and the data output means 6 so that data can be input and output. The inspection result registration means 7 is configured to be able to refer to data mutually with the inspection attribute information definition means 4.

  In such a configuration, at the initial design stage, after the inspection attributes are set, the inspection result registration means 7 determines that the inspection result is blank because the inspection result is blank. The data output means 6 outputs an uninspected flag accompanying the design data together with the inspection attribute. In the inspection process, this design data is read and an inspection according to the inspection attribute is performed. When the inspection is completed, the uninspected flag is cleared, and the inspection result is registered in the inspection attribute item. When the inspected design data is read again by the data input means 5 of the electrical wiring board design apparatus, the inspection result can be referred to by the inspection result registration means 7. The inspection result registration means 7 is indirectly connected to the wiring pattern drawing means 1 through the inspection attribute information definition means 4, the net attribute definition means 3, and the net generation means 2 in this order, so that the wiring pattern is connected via the net attribute. You can call up the inspection results. Therefore, the design of the wiring pattern shape can be changed based on the inspection result. This function is extremely important for electrical wiring boards with built-in elements such as LCR. For example, the capacitance of the target net assumed in the initial design is set as an inspection attribute. The capacitance of the target net of the created electric wiring board is inspected, and the inspection result is attached to the inspection attribute and fed back to the electric wiring board designing apparatus as data. It becomes possible to correct the wiring pattern of the target net and the shape of the element again based on the inspection result at the design stage. If this process is performed without using design data and network information, it takes an enormous amount of time to match the inspection result with the designed wiring pattern when the number of built-in components is large.

It is a block block diagram which shows 1st Embodiment of the electrical wiring board design apparatus which concerns on this invention. It is a flowchart figure of the typical design work in the 1st Embodiment of this invention. It is the partial block block diagram which showed the 2nd Embodiment of this invention. It is a flowchart figure of typical test | inspection attribute information setting in the 2nd Embodiment of this invention. It is the block block diagram which showed the 3rd Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Wiring pattern drawing means 2 ... Net generation means 3 ... Net attribute information definition means 3a ... Single net attribute information definition means 3b ... Net group attribute information definition means 4 .... Inspection attribute information defining means 4a ... Global inspection attribute information defining means 4b ... Net inspection attribute information defining means 4c ... Net group inspection attribute information defining means 5 ... Data Input means 6... Data output means 7... Inspection result registration means

Claims (4)

In an electrical wiring board designing apparatus having data input means, wiring pattern drawing means, net generation means, and data output means, net attribute information definition means for setting attribute values for the net created by the net generation means, An electrical wiring board design apparatus comprising inspection attribute information defining means for setting inspection contents of an electrical wiring board with reference to a net attribute value set by the net attribute information defining means. The inspection attribute information defining means includes a plurality of nets, global inspection attribute information defining means for setting inspection contents independent of nets, net inspection attribute information defining means for setting inspection contents for a single net. 2. The electrical wiring board designing apparatus according to claim 1, further comprising: net group inspection attribute information defining means for setting inspection contents for the net group. The net attribute information defining means includes a net attribute information defining means for setting an attribute value for a single net, and a net group attribute information defining means for setting an attribute value for a net group composed of a plurality of nets. The electrical wiring board design apparatus according to claim 1 or 2, characterized by comprising: The inspection attribute information defining means has an operation or programming function for referring to the net attribute value set by the net attribute information defining means and calculating the net attribute value to set inspection attribute information. The electrical wiring board designing apparatus according to any one of claims 1 to 3.

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