CN101452499B - Element structure graph intelligent correcting system and method - Google Patents
Element structure graph intelligent correcting system and method Download PDFInfo
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- CN101452499B CN101452499B CN200710202811XA CN200710202811A CN101452499B CN 101452499 B CN101452499 B CN 101452499B CN 200710202811X A CN200710202811X A CN 200710202811XA CN 200710202811 A CN200710202811 A CN 200710202811A CN 101452499 B CN101452499 B CN 101452499B
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Abstract
The invention relates to a method for intelligently correcting element structural figures. The method comprises the following steps: acquiring information of all the element structural figures in a database; classifying all the element structural figures according to attribute information in the information of the element structural figures; selecting a type of element structural figures from the classified element structural figures; checking and correcting the corresponding relation of the selected element structural figures in three view drawings and the correction angle, the structural direction and the design parameters in the attribute information of the selected element structural figures; and prompting users that the precision of the selected element structural figures does not accord with the requirement when the design precision of the selected element structural figures does not reach the design precision in the attribute information. Moreover, the invention also provides a system for intelligently correcting the element structural figures.
Description
Technical field
The present invention relates to a kind of element structure graph intelligent correcting system and method.
Background technology
In stamping Die Design, component structure be the most frequently used also be most important a kind of normal structure.The kind of element structure graph is very various, and the information of each element structure graph also is not quite similar.In existing mould design software, the standard insertion system of element structure graph much is provided, can well finish the robotization generating run of component structure.
But, the generation that has only provided component structure and the insertion of the standardization insertion system of existing element structure graph, after the designer made amendment to the component structure that generates, this system just can't check the designer to revise the correctness of back component structure.The designer is after element structure graph is made amendment, can only be to rely on individual's working experience to be tested, there is not reliable perfect scheme to guarantee the result who checks, when particularly just carrying out tiny modification, naked eyes can't be checked out these tiny difference at all, therefore, caused a large amount of component structures, made designer and processing personnel all be sorely distressed for this reason mistake occurring through behind the manual amendment.
Summary of the invention
In view of above content, be necessary to provide a kind of element structure graph intelligent correcting system, can automatic gauging also proofread and correct through the element structure graph in the amended mould design figure file of designer.
In view of above content, be necessary to provide a kind of element structure graph intelligent bearing calibration, can automatic gauging also proofread and correct through the element structure graph in the amended mould design figure file of designer.
A kind of element structure graph intelligent correcting system comprises main frame and the database that links to each other with this main frame, and this main frame comprises: acquisition module is used for obtaining the information of described all element structure graphs of database; Sort module is used for according to the attribute information of described element structure graph information all element structure graphs being classified; Choose module, be used for choosing a class component structure graph from described sorted element structure graph; Correction module, be used for when selected element structure graph not having at three-view diagram at once, proofread and correct the selected corresponding relation of element structure graph in three-view diagram, when ajusting angle when incorrect in the attribute information of selected element structure graph, proofreading and correct this, to ajust angle be the actual angle of ajusting in the three-view diagram, when the structure direction in the attribute information of selected element structure graph is incorrect, proofreading and correct this structure direction is practical structure direction in the three-view diagram, and when the design parameter in the attribute information of selected element structure graph was incorrect, proofreading and correct this design parameter was practical design parameter in the three-view diagram; And reminding module, be used for when the design accuracy of selected element structure graph does not reach the design accuracy of attribute information, point out the precision of the user-selected element structure graph of getting undesirable.
A kind of element structure graph intelligent bearing calibration, this method comprises the steps: to obtain the information of all element structure graphs in the database; According to the attribute information in the described element structure graph information all element structure graphs are classified; From described sorted element structure graph, choose a class component structure graph; When selected element structure graph in three-view diagram not at once, proofread and correct the selected corresponding relation of element structure graph in three-view diagram, otherwise, when selected element structure graph in three-view diagram at once, directly enter next step; When ajusting angle when incorrect in the attribute information of selected element structure graph, proofreading and correct this, to ajust angle be the actual angle of ajusting in the three-view diagram, otherwise,, directly enter next step when ajusting angle when correct in the attribute information of selected element structure graph; When the structure direction in the attribute information of selected element structure graph is incorrect, proofreading and correct this structure direction is practical structure direction in the three-view diagram, otherwise, when the structure direction in the attribute information of selected element structure graph is correct, directly enter next step; When the design parameter in the attribute information of selected element structure graph is incorrect, proofreading and correct this design parameter is practical design parameter in the three-view diagram, otherwise, when the design parameter in the attribute information of selected element structure graph is correct, directly enter next step; And when the design accuracy of selected element structure graph does not reach design accuracy in the attribute information, point out the precision of the user-selected element structure graph of getting undesirable.
Compared to prior art, element structure graph intelligent correcting system provided by the present invention and method, can automatic gauging also proofread and correct through the element structure graph in the amended mould design figure file of designer, guarantee the correctness of each element structure graph in the mould design figure file, improved designer's work efficiency.
Description of drawings
Fig. 1 is the hardware structure figure of element structure graph intelligent correcting system preferred embodiment of the present invention.
Fig. 2 is the functional block diagram of main frame among Fig. 1.
Fig. 3 is the process flow diagram of element structure graph intelligent bearing calibration preferred embodiment of the present invention.
Embodiment
As shown in Figure 1, be the system architecture diagram of element structure graph intelligent correcting system preferred embodiment of the present invention.This system mainly comprises main frame 1, database 2, display 3, keyboard 4 and mouse 5.This main frame 1 is used for all component structures in the database 2 are classified, and the related data of every class component structure is tested automatically and proofreaied and correct.This database 2 links to each other with this main frame 1, is used for storing the information of all element structure graphs of mould design figure file.Described main frame 1 is connected with display 3, keyboard 4 and mouse 5, is used for input and output in component structure trimming process related data.
As shown in Figure 2, be the functional block diagram of main frame 1 among Fig. 1.Described main frame 1 comprises acquisition module 10, sort module 12, chooses module 14, judge module 16, correction module 18 and reminding module 20.
Described acquisition module 10 is used for obtaining the information of database 2 all element structure graphs.The information of described element structure graph includes, but are not limited to, the attribute information of element structure graph.
Described sort module 12 is used for according to the attribute information of described element structure graph information all element structure graphs being classified.Sorted element structure graph includes, but not limited to fixed pin class component structure graph, spring-like element structure graph, guide pillar class component structure graph and drift class component structure graph.
The described module 14 of choosing is used for choosing a class component structure graph from described sorted element structure graph.
Described judge module 16 is used for judging the above-mentioned element structure graph of choosing whether corresponding at three-view diagram.Described three-view diagram comprises the front view of figure, following view and right view.When the X-axis coordinate figure of selected element structure graph arbitrfary point in front view identical with this X-axis coordinate figure in view down, and the Y-axis coordinate figure of selected element structure graph arbitrfary point in front view judges that selected element structure graph is corresponding in three-view diagram when this Y-axis coordinate figure is identical in right view; When the X-axis coordinate figure of selected element structure graph arbitrfary point in front view and in view down this X-axis coordinate figure inequality, the Y-axis coordinate figure of perhaps selected element structure graph arbitrfary point in front view and when this Y-axis coordinate figure is inequality in right view judges that selected element structure graph is not corresponding in three-view diagram.
Described correction module 18 be used for when selected element structure graph three-view diagram not at once, proofread and correct the selected corresponding relation of element structure graph in three-view diagram.The corresponding relation of described correcting element structure graph be meant with the X-axis coordinate figure of selected element structure graph arbitrfary point in front view and in view down the X-axis coordinate figure of this point proofread and correct identically, reach the Y-axis coordinate figure of selected element structure graph arbitrfary point in front view identical with this Y-axis coordinate figure correction in right view.
Described judge module 16 also be used for judging selected element structure graph attribute information whether ajust angle correct.When ajusting in angle and the three-view diagram in the attribute information of selected element structure graph actual ajust angle when inequality, judge in the attribute information of selected element structure graph to ajust angle incorrect; When ajusting in angle and the three-view diagram the actual angle of ajusting when identical in the attribute information of selected element structure graph, judge in the attribute information of selected element structure graph to ajust angle correct.
Described correction module 18 also be used for when the attribute information of selected element structure graph ajust angle when incorrect, proofreading and correct this, to ajust angle be the actual angle of ajusting in the three-view diagram.
Described judge module 16 is used for also judging whether the structure direction of attribute information of selected element structure graph is correct.When the practical structure direction is inequality in structure direction in the attribute information of selected element structure graph and the three-view diagram, judge that the structure direction in the attribute information of selected element structure graph is incorrect; When ajusting angle when identical in the attribute information of selected element structure graph, judge that the structure direction in the attribute information of selected element structure graph is correct with practical structure direction in the three-view diagram.
Described correction module 18 also is used for when the structure direction of the attribute information of selected element structure graph is incorrect, and proofreading and correct this structure direction is practical structure direction in the three-view diagram.
Described judge module 16 is used for also judging whether the design parameter of attribute information of selected element structure graph is correct.When the practical design parameter is inequality in design parameter in the attribute information of selected element structure graph and the three-view diagram, and when described practical design parameter can find, judge that the design parameter in the attribute information of selected element structure graph is incorrect in database 2; When the design parameter in the attribute information of selected element structure graph identical with practical design parameter in the three-view diagram, perhaps when the practical design parameter is inequality in design parameter in the attribute information of selected element structure graph and the three-view diagram, but described practical design parameter is searched not then in database 2, judges that the design parameter in the attribute information of selected element structure graph is correct.
Described correction module 18 also is used for when the design parameter of the attribute information of selected element structure graph is incorrect, and proofreading and correct this design parameter is practical design parameter in the three-view diagram.
Described judge module 16 is used for also judging whether the design accuracy of selected element structure graph reaches the design accuracy of attribute information.
Described reminding module 20 is used for when the design accuracy of selected element structure graph does not reach the design accuracy of attribute information, points out the precision of the user-selected element structure graph of getting undesirable.
Described judge module 16 also reaches design accuracy in the attribute information with the design accuracy when selected element structure graph, perhaps when the design accuracy of selected element structure graph does not reach design accuracy in the attribute information, after the precision of the user-selected element structure graph of getting of reminding module 20 prompting was undesirable, whether the element structure graph of judging described all categories was all proofreaied and correct and is finished.
As shown in Figure 3, be the process flow diagram of element structure graph intelligent bearing calibration preferred embodiment of the present invention.At first, step S10, acquisition module 10 obtains the information of all element structure graphs in the database 2.The information of described element structure graph includes, but are not limited to, the attribute information of element structure graph.
Step S12, sort module 12 is classified all element structure graphs according to the attribute information in the described element structure graph information.Sorted element structure graph includes, but not limited to fixed pin class component structure graph, spring-like element structure graph, guide pillar class component structure graph and drift class component structure graph.
Step S14 chooses the class component structure graph that module 14 is chosen from described sorted element structure graph.
Whether corresponding step S16, judge module 16 judge selected element structure graph in three-view diagram.When the X-axis coordinate figure of selected element structure graph arbitrfary point in front view identical with this X-axis coordinate figure in view down, and the Y-axis coordinate figure of selected element structure graph arbitrfary point in front view judges that selected element structure graph is corresponding in three-view diagram when this Y-axis coordinate figure is identical in right view; When the X-axis coordinate figure of selected element structure graph arbitrfary point in front view and in view down this X-axis coordinate figure inequality, the Y-axis coordinate figure of perhaps selected element structure graph arbitrfary point in front view and when this Y-axis coordinate figure is inequality in right view judges that selected element structure graph is not corresponding in three-view diagram.
Step S18, when selected element structure graph not having at once in three-view diagram, correction module 18 is proofreaied and correct the selected corresponding relation of element structure graph in three-view diagram.
Step S20, judge module 16 judge in the attribute information of selected element structure graph whether ajust angle correct.When ajusting in angle and the three-view diagram in the attribute information of selected element structure graph actual ajust angle when inequality, judge in the attribute information of selected element structure graph to ajust angle incorrect; When ajusting in angle and the three-view diagram the actual angle of ajusting when identical in the attribute information of selected element structure graph, judge in the attribute information of selected element structure graph to ajust angle correct.
Step S22, when ajusting angle when incorrect in the attribute information of selected element structure graph, correction module 18 is proofreaied and correct this, and to ajust angle be the actual angle of ajusting in the three-view diagram.
Step S24, judge module 16 judge whether the structure direction in the attribute information of selected element structure graph is correct.When the practical structure direction is inequality in structure direction in the attribute information of selected element structure graph and the three-view diagram, judge that the structure direction in the attribute information of selected element structure graph is incorrect; When ajusting angle when identical in the attribute information of selected element structure graph, judge that the structure direction in the attribute information of selected element structure graph is correct with practical structure direction in the three-view diagram.
Step S26, when the structure direction in the attribute information of selected element structure graph was incorrect, it was practical structure direction in the three-view diagram that correction module 18 is proofreaied and correct this structure direction.
Step S28, judge module 16 judge whether the design parameter in the attribute information of selected element structure graph is correct.When the practical design parameter is inequality in design parameter in the attribute information of selected element structure graph and the three-view diagram, judge that the design parameter in the attribute information of selected element structure graph is incorrect; When the design parameter in the attribute information of selected element structure graph is identical with practical design parameter in the three-view diagram, judge that the design parameter in the attribute information of selected element structure graph is correct.
Step S30, when the design parameter in the attribute information of selected element structure graph was incorrect, it was practical design parameter in the three-view diagram that correction module 18 is proofreaied and correct this design parameter.
Step S32, judge module 16 judge whether the design accuracy of selected element structure graph reaches the design accuracy in the attribute information.
Step S34, when the design accuracy of selected element structure graph did not reach design accuracy in the attribute information, the precision of the user-selected element structure graph of getting of reminding module 20 promptings was undesirable.
Step S36, when the design accuracy of selected element structure graph reaches design accuracy in the attribute information, perhaps when the design accuracy of selected element structure graph does not reach design accuracy in the attribute information, after the precision of the user-selected element structure graph of getting of reminding module 20 prompting was undesirable, whether all the element structure graph that judge module 16 is judged described all categories correction was finished.
In step S16, when selected element structure graph in three-view diagram at once, go to S20 and judge and ajust the whether correct step of angle in the attribute information of selected element structure graph.
In step S20,, go to S24 and judge the whether correct step of structure direction in the attribute information of selected element structure graph when ajusting angle when correct in the attribute information of selected element structure graph.
In step S24, when the structure direction in the attribute information of selected element structure graph is correct, goes to S28 and judge the whether correct step of design parameter in the attribute information of selected element structure graph.
In step S28, when the design parameter in the attribute information of selected element structure graph is correct, goes to S32 and judge whether the design accuracy of selected element structure graph reaches the design accuracy in the attribute information.
In step S36, when the element structure graph correction of described all categories is not finished, be back to S14 chooses a class component structure graph from described sorted element structure graph step.
Claims (5)
1. an element structure graph intelligent correcting system is characterized in that, this system comprises:
Acquisition module is used for obtaining the information of all element structure graphs of database;
Sort module is used for according to the attribute information of described element structure graph information all element structure graphs being classified;
Choose module, be used for choosing a class component structure graph from described sorted element structure graph;
Correction module, be used for when selected element structure graph not having at three-view diagram at once, proofread and correct the selected corresponding relation of element structure graph in three-view diagram, when ajusting angle when incorrect in the attribute information of selected element structure graph, proofreading and correct this, to ajust angle be the actual angle of ajusting in the three-view diagram, when the structure direction in the attribute information of selected element structure graph is incorrect, proofreading and correct this structure direction is practical structure direction in the three-view diagram, and when the design parameter in the attribute information of selected element structure graph was incorrect, proofreading and correct this design parameter was practical design parameter in the three-view diagram; And
Reminding module is used for when the design accuracy of selected element structure graph does not reach the design accuracy of attribute information, points out the precision of the user-selected element structure graph of getting undesirable.
2. element structure graph intelligent correcting system as claimed in claim 1 is characterized in that, this system also comprises:
Judge module, be used for reaching the design accuracy of attribute information when the design accuracy of selected element structure graph, after perhaps the precision of the user-selected element structure graph of getting of reminding module prompting did not reach design accuracy in the attribute information, whether all the correction of the element structure graph of judging all categories was finished.
3. element structure graph intelligent correcting system as claimed in claim 1, it is characterized in that, the corresponding relation of described correcting element structure graph be meant with the X-axis coordinate figure of selected element structure graph arbitrfary point in front view and in view down the X-axis coordinate figure of this point proofread and correct identically, reach the Y-axis coordinate figure of selected element structure graph arbitrfary point in front view identical with this Y-axis coordinate figure correction in right view.
4. an element structure graph intelligent bearing calibration is characterized in that, this method comprises the steps:
Obtain the information of all element structure graphs in the database;
According to the attribute information in the described element structure graph information all element structure graphs are classified;
From described sorted element structure graph, choose a class component structure graph;
When selected element structure graph in three-view diagram not at once, proofread and correct the selected corresponding relation of element structure graph in three-view diagram, otherwise, when selected element structure graph in three-view diagram at once, directly enter next step;
When ajusting angle when incorrect in the attribute information of selected element structure graph, proofreading and correct this, to ajust angle be the actual angle of ajusting in the three-view diagram, otherwise,, directly enter next step when ajusting angle when correct in the attribute information of selected element structure graph;
When the structure direction in the attribute information of selected element structure graph is incorrect, proofreading and correct this structure direction is practical structure direction in the three-view diagram, otherwise, when the structure direction in the attribute information of selected element structure graph is correct, directly enter next step;
When the design parameter in the attribute information of selected element structure graph is incorrect, proofreading and correct this design parameter is practical design parameter in the three-view diagram, otherwise, when the design parameter in the attribute information of selected element structure graph is correct, directly enter next step; And
When the design accuracy of selected element structure graph does not reach design accuracy in the attribute information, point out the precision of the user-selected element structure graph of getting undesirable.
5. element structure graph intelligent bearing calibration as claimed in claim 4 is characterized in that, this method also comprises step:
When the design accuracy of selected element structure graph reaches design accuracy in the attribute information, perhaps point out the precision of the user-selected element structure graph of getting undesirable after, whether the element structure graph of judging all categories is all proofreaied and correct and is finished;
When also having element structure graph not have correction not finish, be back to the step of from described sorted element structure graph, choosing a class component structure graph.
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Citations (3)
Publication number | Priority date | Publication date | Assignee | Title |
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CN1286415A (en) * | 1999-08-30 | 2001-03-07 | 旺宏电子股份有限公司 | Calibration method for photoetching |
CN1804848A (en) * | 2004-11-05 | 2006-07-19 | 国际商业机器公司 | Method for improving optical proximity correction |
US7263683B1 (en) * | 2004-09-07 | 2007-08-28 | Advanced Micro Devices, Inc. | Simplified optical proximity correction based on 1-dimension versus 2-dimension pattern shape classification |
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Publication number | Priority date | Publication date | Assignee | Title |
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CN1286415A (en) * | 1999-08-30 | 2001-03-07 | 旺宏电子股份有限公司 | Calibration method for photoetching |
US7263683B1 (en) * | 2004-09-07 | 2007-08-28 | Advanced Micro Devices, Inc. | Simplified optical proximity correction based on 1-dimension versus 2-dimension pattern shape classification |
CN1804848A (en) * | 2004-11-05 | 2006-07-19 | 国际商业机器公司 | Method for improving optical proximity correction |
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JP特开平7-262255A 1995.10.13 |
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