JPH06131409A - Method and device for design backup - Google Patents

Abstract

PURPOSE:To reduce the number of commands to be presented to a user by performing the processing with combined command where command related to generation and that related to evaluation are combined. CONSTITUTION:A combination selecting part 101 takes out a combination of processing discrimination information corresponding to a processing instruction from a processing combination storage part 102 and outputs it to a combination processing interpreting part 103 and outputs processing discrimination information to a processing selecting part 603 in order. The processing selecting part 603 takes out processing procedures corresponding to processing discrimination information from a processing storage part 604 in order and outputs them to a processing execution part 605 to execute them one by one. The combination of processing discrimination information consists of shape generation processing discrimination information, one or more feature extraction processing discrimination information, and one or more shape correction processing discrimination information. Consequently, a processing procedure classified to shape generation, one or more processing procedures classified to feature extraction, and one or more processing procedures classified to shape correction are executed in order correspondingly to the processing instruction.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION The present invention relates to CAD / CAM / CA.
The present invention relates to a design support apparatus such as an E system, and particularly to a design support apparatus and method suitable for correcting shape data efficiently and accurately.

[0002]

2. Description of the Related Art When completing the creation of shape data using a conventional design support device such as a CAD / CAM / CAE system, the user of the design support device (hereinafter referred to as the user) inputs the shape data. After that, the shape data is completed by repeating the evaluation and correction of the shape data so as to obtain the desired shape data.

Here, the evaluation of shape data means, for example,
After creating the planar shape data, the desired planar shape data is created by displaying the contour lines of this planar shape and verifying whether the contour lines are equidistant or whether the contour lines are straight lines. Refers to the operation that the user confirms whether or not

Further, the correction of the shape data is, for example, an operation of correcting the plane shape data by creating the plane shape data or after evaluating the plane shape data to correct the vertices and contour lines of the plane. Say.

FIG. 6 shows a schematic diagram of a general design support device for performing such an operation. According to this device, one process is executed by one command (or processing instruction).

[0006] Further, as an indication that one process corresponds to one command, the document "3D Design System HICAD / DESIGN / W (Hitachi Engineering Workstation 2050G Solid Design System
HICAD / DESIGN / W User's Guide 205G
-7-616-10 Hitachi, Ltd. 1989
The three-dimensional design system described in "Month". In this three-dimensional design system, Appendix A HICAD /
As shown in the DESIGN / W command list (pages 393 to 401), processing commands called commands are hierarchically displayed on the display device, and the command is processed by the user selecting the command using the input device. Has been shown to be performed.

For example, in the case of defining a plane by designating a point sequence, the user selects a processing instruction for creating a plane, which is a command, using an input device, so that the three-dimensional design system can generate a processing instruction for creating a plane. Processing corresponding to sopl
Run np. Since the processing soplnp displays the guidance of the data to be input on the display device, the user inputs the data according to the guidance using the input device. processing
soplnp takes in data according to the guidance, creates a plane shape based on the data, and outputs display data of the plane shape to a display device. The user confirms the planar shape data displayed on the display device and repeats the operation of inputting the next command.

As described above, in the prior art, the processing command, which is a command, and the actual processing have a one-to-one correspondence. Therefore, when performing an operation such as creating a shape, the necessary commands are selected one by one. Running.

[0009]

In the above prior art, the user searches for a desired command from all or some of the commands which are the processing instructions displayed on the display device of the design support apparatus, and uses the input device. Repeating the selection of commands to create the shape data desired by the user,
We are evaluating and correcting. The sum of commands for processing such as creation is large in quantity and complicated in response to a user's request. Therefore, an erroneous operation occurs such that the user forgets to select a command relating to shape data evaluation and makes a correction, or selects a command different from the shape data evaluation. The shape data is not evaluated by such an erroneous operation. As a result, unsatisfactory shape data is created for the user. In such a case, the shape data has to be recreated from the beginning, and there is a problem that the operation efficiency is deteriorated.

Even if the method of presenting the command is devised, for example, if the commands are hierarchically disclosed, the user's operation of selecting the command using the input device becomes complicated. In particular, when the command regarding the evaluation of the shape data is not selected, there is a problem that the user cannot easily create the desired shape data because it is difficult for the user to notice an error in the shape data.

An object of the present invention is to reduce the number of commands presented to the user. Another object of the present invention is to execute a process related to evaluation after executing a process related to creation.

[0012]

In order to achieve the above object, the present invention enables processing by a combination command in which a creation command and an evaluation command are combined. That is, the command regarding evaluation is forcibly executed when the processing regarding creation is completed.

In order to achieve the above object, according to the present invention, a process related to creation, a process related to evaluation, and a process related to modification can be sequentially executed by a combination command in which a command related to creation, a command related to evaluation, and a command related to modification are combined. You can do it.

Further, in order to achieve the above object, the present invention is configured to repeatedly execute a combination command in which a command related to evaluation and a command related to correction are combined until an end command is input from a user.

[0015]

In order to solve the above-mentioned problems, the design support apparatus of the present invention, as shown in FIG. 1, is a combination selection unit for selecting a combination of process identification information to be continuously executed according to a processing command input by a user. 101 and the process identification information to be executed from the combination of the process identification information in order, and the process identification information classified into feature extraction and shape correction is selected and the process identification information is repeatedly output in order. An interpreting unit 103 and a process combination storage unit 102 for storing a combination of process identification information corresponding to the user's shape data creation, evaluation, and correction work are provided. The process identification information is one-to-one correspondence with a processing procedure, and corresponds to information for making a one-to-one correspondence between the processing life and the processing procedure in the conventional design support apparatus.

Here, the design support apparatus may be configured such that the procedure 201 corresponding to the combination processing interpretation unit 103 is provided in the processing selection unit 603 as shown in FIG. Further, the design support apparatus may include a plurality of processing selection units 603 corresponding to the classification of processing procedures as shown in FIG.

[0017]

EXAMPLE A combination selection unit 101 and a combination interpretation unit 103 are inserted between an input data interpretation unit and a process selection unit 603 in a conventional design support device. Therefore, in the design support apparatus of the present invention, it means that a processing instruction continuously executes a plurality of processing procedures. The operation of the design support apparatus of the present invention will be described below.

When the user inputs a processing command using the input unit 601, the input data interpretation unit 602 receives the processing command from the input unit 601 and outputs it to the combination selection unit 101. The combination selection unit 101 stores the combination of the processing identification information corresponding to the processing instruction in the processing combination storage unit 1
02 and outputs it to the combination processing interpretation unit 103. The combination process interpretation unit 103 sequentially outputs the process identification information to be executed from the combination of the process identification information to the process selection unit 603. The process selection unit 603 receives the process identification information in order, extracts the process procedure corresponding to the process identification information from the process storage unit 604 in order, and outputs the process procedure to the process execution unit 605. The processing execution unit 605 receives the processing procedures in order and executes them one by one. The execution result is
It is displayed on the display device on the display unit 606. In this way, a plurality of processing procedures corresponding to processing instructions are continuously executed. Here, the combination of the process identification information stored in the process combination storage unit 102 is the shape creation process identification information, the one or more feature extraction process identification information, and the one or more shape correction process identification information. Therefore, the design support apparatus, in accordance with the processing instruction, processes a processing procedure classified into shape creation, a processing procedure classified into one or more feature extractions, and a processing procedure classified into one or more shape corrections. Can be executed in order. Note that the combination processing interpretation unit 103 can also select processing identification numbers classified into feature extraction and shape correction and repeatedly output them in order. Therefore, the design support apparatus, in accordance with the processing instruction, processes a processing procedure classified into shape creation, a processing procedure classified into one or more feature extractions, and a processing procedure classified into one or more shape corrections. Can be executed in order. The operation is the same when the design support device has the configuration shown in FIGS.

From the above, for example, (Step 1) processing 1607 classified into shape creation
Execution of one of the processes m608.

(Step 2) Execution of at least one of processing n609 to processing o610 classified into feature extraction.

(Step 3) Reception of input data input from the input unit.

(Step 4) Execution of processing p611 to processing q612 classified into shape correction based on the input data.

After performing the steps in order, it is possible to repeat the operation from (step 2).

When the user creates and modifies the shape data by the above-mentioned respective parts acting as described above, the design support device automatically presents the characteristics of the shape data, and the required processing 1607 to processing q612. In order to execute, the user can create, evaluate, and correct the shape data without forgetting to make an erroneous operation. Further, when shape data is created and modified, processing n609 classified as feature extraction is performed.
-Since the process o610 is continuously executed, the process command corresponding to the process n609-process o610 classified into the feature extraction can be omitted from the process command output to the display device, and the presented process command. Can be reduced. Further, it is also possible to correct the shape data and the feature data that are continuously presented, and the user can easily correct the shape data while grasping the features of the shape data. As a result, the user can revise the shape data faster and to a shape having the characteristic data desired by the user.

The above operation is shown in a flowchart of FIG.

An embodiment of the present invention will be described below by taking as an example a polyhedral design support device having a function of creating, evaluating, and modifying a flat shape.

FIG. 7 shows a combination A1 stored in the processing combination storage unit 102 of the polyhedral design support apparatus.
21 is a configuration diagram showing a configuration of 21 to combination B122 and processing 1607 to processing q612 stored in the processing storage unit 604. FIG.

The polyhedron design support apparatus uses the plane creation processing procedure 7 as processing 1607 to processing m608 shown in FIG.
12, processing n609 to processing o610, contour line display processing procedure 713, processing p611 to processing q612, plane change processing procedure 714 is used, and combination A121 to
Plane creation processing procedure 712 as a combination B122
Contour line display processing procedure 713, plane change processing procedure 71
Combination 1 (701) consisting of 4 combinations, plane change processing procedure 714, contour line display processing procedure 713.
The combination 2 (702) which is a combination of the above is used. Here, the plane creation processing procedure 712 is classified into the shape creation described in FIG. Similarly, the procedures (713, 714) other than the plane creation processing procedure 712 are
These are classified into the feature extraction and shape correction shown in FIG.

The processing combination storage unit 1 having the configuration shown in FIG.
02, the polyhedron design support apparatus in the processing storage unit 604 operates as described below.

When the user activates the polyhedron design support apparatus, the display unit 606 presents a processing command. The display unit 6
Reference numeral 06 denotes, for example, a processing command identification number 411 for identifying the processing command as shown in FIG. 8, an arrangement position 812 for displaying “plane creation”, which is the name of the processing command, at a predetermined position of the display device. Character string data 801 including a character string 813 to be displayed as a processing instruction is created, and the character string 813 is displayed at a predetermined position of the display device indicated by the arrangement position 812. The display unit 606 outputs a processing command to the display device each time it operates. FIG. 9 shows the display unit 60.
6, the display result (902) of the processing instruction “plane creation” displayed on the display device 901, and the display unit 606.
Shows the display result (903) of the processing instruction “change plane” displayed on the display device 901 in the same character string data format as the processing instruction identification number 411 to the character string 813. The user displays the display result of the processing instruction displayed on the display device 901, for example, the display result of the processing instruction “plane creation” (90
By selecting 2) in the input unit 601 using an input device, the processing instruction is input to the polyhedral design support apparatus.

FIG. 9 also shows a specific example of a user's operation from the activation of the polyhedron design support apparatus by the user to the input of a processing command using an input device and the input of vertex coordinate values of a plane. Hereinafter, the input operation of the processing instruction and the input operation of the vertex coordinates of the plane will be described with reference to FIG.

When the user starts the polyhedron design support apparatus, the display unit 606 in the polyhedron design support apparatus.
Displays the processing instruction on the display device 901 using the character string data 801 as shown in FIG. User input section 6
When an input device is used in 01 to indicate the display result (902) of the processing instruction “plane creation” displayed on the display device 901, the input unit 601 detects the indicated position, and the character “#” 904 is displayed. Display at the indicated position. This makes it possible to confirm which processing instruction the user has instructed. Through the above operation, the user inputs the processing command "planar creation" to the polyhedral design support apparatus.

When the user inputs the processing command "plane creation" using the input device in the input unit 601, the input unit 601 outputs the processing command identification number 411 for identifying the processing command "plane creation" shown in FIG. The data is output to the input data interpretation unit 602. The input data interpretation unit 602 interprets that the input data received from the input unit 601 is the processing instruction identification number 411, and outputs the value of the processing instruction identification number 411 to the combination selection unit 101.

The combination selection unit 101 matches the value received from the input data interpretation unit 602 and the processing instruction identification number 411 of the combination 1 (701) or the combination 2 (702) stored in the processing combination storage unit 102. For example, the contents (411 to 414) described in the combination 1 (701) are output to the combination interpretation unit 103. In the present embodiment, as the combination 1, the plane creation processing procedure 712 / the contour line display processing procedure 71.
A combination of 3 / plane change processing procedures 714 is prepared, and the processing instruction identification number 411 of the combination 1 (701) is set to "1". Similarly, combination 2 (70
The processing instruction identification number 411 in 2) is set to "2". That is,
When the user inputs a processing instruction “planar creation” to the polyhedron design support apparatus, the combination selection unit 101 causes the input data interpretation unit 602 to input the processing instruction identification number 41.
It receives a value of 1, "1". The combination selection unit 101 selects the combination 1 (701) corresponding to the value “1” of the processing instruction identification number 411, and the combination processing interpretation unit 103 displays the contents of the combination 1 (412) shown in FIG. ˜414) is output. The combination processing interpretation unit 103 determines the contents of combination 1 (412).
~ 414) is received, the processing decomposition unit 501 shown in FIG. 5 is executed. The processing decomposition unit 501 uses the plane creation processing identification number 41, which is the content (412 to 414) of the combination 1.
2, the contour line display process identification number 413 and the plane change process identification number 414 are taken out one by one and output to the process output unit 502. The value “10” of the plane creation process identification number 412 is
This is a number for identifying the plane creation processing procedure 712. Similarly, the values “20” and “30” of the contour line display process identification number 413 and the plane change process identification number 414 are numbers for identifying the contour line display process procedure 713 and the plane change process procedure 714. The process output unit 502 has a plane creation process identification number 4
The value “10” of 12, the value “20” of the contour line display process identification number 413, and the value “30” of the plane change process identification number 414 are sequentially output to the process selection unit 603. Processing selection unit 603
Searches the processing storage unit 604 for the number 711 of the plane creation processing procedure 712 that matches the value “10” of the plane creation processing identification number 412 that was first received from the combination processing interpretation unit 103, and retrieves the plane creation processing procedure 712. It is output to the process execution unit 605. Similarly, the value “2” of the contour line display processing identification number 413 from the processing storage unit 604.
The contour display processing procedure 713 and the plane modification processing procedure 714 having the number 711 that matches the value “30” of the plane modification processing identification number 414 are sequentially output to the processing execution unit 605. The process execution unit 605 executes the plane creation process procedure 712, the contour line display process procedure 713, and the plane change process procedure 714 output by the process selection unit 603 one by one in a receiving order. That is, the processing execution unit 605 first executes the plane creation processing procedure 712, and outputs a message to the display unit 606 as permission to input the vertex coordinate values of the plane according to the plane creation processing procedure 712. The display unit 606 is
The input permission message output by the process execution unit 605 is received and displayed on the display device.

When the display unit 606 outputs the input permission message to the display device, the user instructs the screen of the display device 901 using the input device in the input unit 601 according to the input permission message as shown in FIG. The input unit 601 detects the designated position and displays the dot graphic 905 at the designated position. This makes it possible to confirm where the user has set the vertex coordinate values of the plane. With the above operation,
The user inputs the vertex coordinate values of the plane into the input data interpretation unit 602.

When the user inputs the vertex coordinate values of the plane with the input unit 601, the input vertex coordinate values are input position data 1001 consisting of input position 1 (1011) to input position 4 (1014) shown in FIG. Is taken in. The input unit 601 outputs the input position data 1001 to the input data interpretation unit 602. Input data interpretation unit 602
Interprets that the input data received from the input unit 601 is the input position data, and outputs the input position data 1001 to the process execution unit 605. The process execution unit 605 receives the input position data 100 from the input data interpretation unit 602.
11, and in accordance with the plane creation processing procedure 712, as shown in FIG. 11, the plane creation processing identification number 412 of the plane creation processing procedure 712 and the input position 1 (1011).
The point graphic / polygonal line data 1101 consisting of the input position 4 (1014) is stored in the shape storage unit 615, and the point graphic / polygonal line data 1101 is output to the display unit 606. The display unit 606 receives the point graphic / polygon line data 1101 from the process execution unit 605 and displays a plane graphic on the display device. The plane creation processing procedure 712 executed by the processing execution unit 605 is a point graphic / polygon line data 1
The process ends by outputting 101 to the display unit 606. Figure 9
Is executed by the processing execution unit 605.
Is executed and the processing execution unit 605 outputs the point graphic / polygonal line graphic data 1101 to the display unit 606, and the display result (905, 906) of the point graphic / polygonal line data displayed on the display device by the display unit 606. ) Is shown. When the process execution unit 605 finishes the execution of the plane creation process procedure 712, the process execution unit 605 executes the contour line display process procedure 713 which is the next procedure output by the process selection unit 603. According to the contour line display processing procedure 713, the processing execution unit 605 outputs a message asking the display unit 606 to input a direction for displaying contour lines and a contour line interval.

FIG. 12 is a diagram showing a specific operation example by the user when inputting a direction for displaying contour lines and a contour line interval.

When the processing execution unit 605 outputs the input permission message to the display unit 606 according to the contour line display processing procedure 713, the display unit 606 outputs the input permission message to the display device 901. The user uses the input device to input the screen of the display device 901 twice in the input unit 601 according to the input permission message output to the display device 901. The input unit 601 detects the designated position, displays the character “#” 1201 at the designated position, and
An arrow 1202 connecting the two designated positions is displayed. The character “#” 1201 and the arrow 1202 allow confirmation of the position designated by the user and the direction in which contour lines are displayed. next,
The user instructs the arrow 1202 by using the input device according to the input permission message. The input unit 601 detects the designated position and displays the character “#” 1203 at the designated position. The contour interval can be confirmed by the interval 1204 between the character “#” 1201 and the character “#” 1203 displayed on the display device 901. By the above operation, the user can display the contour lines in the input data interpretation unit 602,
Enter the contour spacing.

When the user inputs the contour line display direction and the contour line interval to the input data interpretation unit 602, the input contour line display direction and the contour line interval are input position 1 (1311) as shown in FIG. ~ Input position 3 (131
It is captured by the input position data 1301 composed of 3).
The input data interpretation unit 602 uses the input position data 130.
1 and interprets the input position data 130 in the process execution unit 605.
1 is output. The processing execution unit 605 follows the input position data 1 according to the contour line display processing procedure 713 currently being executed.
301 to input position 1 (1311) and input position 2 (13
12) is taken out and the direction of displaying the contour line is calculated by obtaining the direction from the input position 1 (1311) to the input position 2 (1312). Furthermore, the processing execution unit 60
In accordance with the contour line display processing procedure 713, the reference numeral 5 retrieves the input position 3 (1313) and the input position 1 (1311) from the input position data 1301 and obtains the distance between the input position 3 (1313) and the input position 1 (1311). Calculate contour spacing. Next, the processing execution unit 605 follows the contour line display processing procedure 713, fetches the point graphic / polygon line data 1101 created by the processing execution unit 605 according to the plane creation processing procedure 712 from the storage device 615, and sets the point graphic as the vertex coordinate value. Create a plane to do. According to the contour line display processing procedure 713, the processing execution unit 605 cuts the plane having the vertex coordinates of the point figure into a plane created at the contour line display direction and the contour line interval, and thereby the start / end point coordinate values of the contour line. To calculate. The processing execution unit 605 calculates the starting point / end point coordinate values of the contour line according to the contour line display processing procedure 713, and then calculates the contour line display processing identification number 413 and the starting point / end point coordinate values (1412 to 1415) of the contour line shown in FIG. The contour line data 1401 is stored in the storage device 615, and the contour line data 1401 is output to the display unit 606. The display unit 606 displays the contour line graphic on the display device by outputting the contour line data 1401 received from the processing execution unit to the display device.
The processing execution unit 605 outputs the contour line data to the display unit 606, and then ends the contour line display processing procedure 713. In FIG. 15, the processing execution unit 605 displays the contour line data 140 on the display unit 606 according to the contour line display processing procedure 713.
1 is output and the display unit 606 displays the result (1501) of displaying a contour line graphic on the display device. When the contour line display processing procedure 713 is completed, the processing execution unit 605 executes a plane change processing procedure 714 that is the next procedure. The processing execution unit 605 uses the plane change processing procedure 71.
In accordance with No. 4, a message is output to the display unit 606 as a message to permit the correction of the contour lines representing the inside of the plane.

FIG. 15 also shows a specific operation example by the user when correcting the contour lines representing the inside of the plane.

When the processing execution unit 605 outputs an input permission message for correcting the contour lines representing the inside of the plane to the display unit 606 according to the plane change processing procedure 714, the display unit 606 outputs the input permission output by the processing execution unit 605. According to the message, the input permission message is output to the display device 901. The user uses the input device in the input unit 601 in accordance with the input permission message displayed on the display device 901 to draw contour lines 1501 representing the inside of the plane displayed on the screen of the display device 901, and processing instructions (902 to 903).
One of them, for example, a contour line 1501 representing the inside of the plane is designated. The input unit 601 detects the designated position and displays the character “#” 1502 at the designated position. Thereby, it can be confirmed that the user has designated the contour line 1501 representing the inside of the plane. Through the above operation, the user inputs the corrected portion of the contour line to the input data interpretation unit 602. Also,
When the user uses the input device to instruct the processing command (902 to 903) displayed on the screen of the display device 901,
As described above, the input data interpretation unit 602 interprets the processing instruction identification number and outputs the value of the processing instruction identification number to the combination selection unit 101. At this time, the processing execution unit 605
Is being executed and the procedure output by the process selecting unit 603 and waiting for execution by the process executing unit 605 is stopped, and the process executing unit 605 determines that the new procedure is the process selecting unit 6
Wait until output from 03.

When the user uses the input device to input the correction point of the contour line in the input unit 601, the input data interpretation unit 602 receives the input position 1 (1612) shown in FIG. 16, and the input position 1 (1612) processes it. Command (902-9
03), the input position 1 (1612) is output to the process execution unit 605. The process execution unit 605
According to the plane change processing procedure 714, outputs a message to the display unit 606 asking for permission to input the position after the contour line change. The display unit 606 receives the input permission message from the process execution unit 605 and outputs the input permission message to the display device 901.

When the display unit 606 outputs an input permission message to the display device 901, the user instructs the screen of the display device 901 using the input device in the input unit 601 according to the input permission message as shown in FIG. .
The input unit 601 detects the designated position,
503 is displayed at the designated position. This makes it possible to confirm where the user has set the position after the contour line change. Through the above operation, the user inputs the position after the contour line change to the input data interpretation unit 602.

When the user inputs the position after the contour line change to the input data interpretation unit 602, the position after the contour line change is the process identification number 413, input position 1 of the procedure that created the selected figure shown in FIG. (1612), and the correction data 1601 including the input position 2 (1613) is fetched. The input data interpretation unit 602 interprets the modified data 1601 and outputs the modified data 1601 to the process execution unit 605. The process execution unit 605 extracts the process identification number 413 from the modified data 1601 according to the plane change process procedure 714, and stores the contour line data 1401 having a number matching the process identification number 413 in the storage device 61.
5 and retrieves the contour line data 1401 from the storage device 615. Next, the contour line data 14
Point figure / Polyline figure data 110 when 01 is created
1 is searched from the storage device 615 and the storage device 615 is searched.
Then, the point graphic / polygon line graphic data 1101 is extracted from. The processing execution unit 605 uses the plane change processing procedure 714.
According to the contour line data 1401, the contour line start point / end point coordinate values (1412 to 1415) are extracted, and the correction data 1
One of the start point / end point coordinate values (1412 to 1415) of the contour line designated by the input position 1 (1612) of 601 is determined, for example, the contour line 2 (1413). The process execution unit 605 follows the contour line 2 (1413) according to the plane change processing procedure 714 and inputs the position 2 (161) of the correction data 1601.
The input positions 1 to 4 (1011 to 1014) of the point graphic / polygon line graphic data 1101 are corrected so as to move to 3). Next, the processing execution unit 605 follows the plane change processing procedure 714, and as shown in FIG. 17, the process identification number 414 of the plane change processing procedure 714, the correction position 1
~ 4 (1711-1714) after change point figure /
The polygonal line graphic data 1701 is stored in the storage device 615,
The changed point graphic / polygon line graphic data 1701 is output to the display unit 606. The display unit 606 is the processing execution unit 60.
From 5 to the changed point figure / polygon line figure data 1701
By receiving and outputting to the display device 901,
The changed plane figure is displayed on the display device 901. The processing execution unit 605 ends the plane change processing procedure 714 by outputting the changed point graphic / polygon line graphic data 1701 to the display unit 606. In FIG. 18, the processing execution unit 605 outputs to the display unit 606, and
6, the display result (1801, 1801) of the changed point figure / polyline figure data 1701 displayed by the display device 901.
1802) is shown. When the plane changing process procedure 714 in the process executing unit 605 ends, the process executing unit 605 ends the execution of the procedure. The operation after the process execution unit 605 finishes executing the procedure is the same as the above-described operation after the processing instruction is selected.

As described above, the combination selection unit 10
1. When the combination interpreting unit 103 operates, the contour line display processing procedure 713 classified into feature extraction after the completion of the plane creation processing procedure 712 classified into shape creation
It becomes possible to execute. In the above embodiment, the case where the user inputs the processing instruction "plane creation" has been described. However, even when the user inputs the processing instruction "plane change",
The combination selection unit 101 and the combination interpretation unit 103 perform similar operations. This makes it possible to execute the contour line display processing procedure 713 classified into feature extraction after the completion of the plane change processing procedure 714 classified into shape correction. Further, it becomes possible to correct the data displayed after the contour line display processing procedure 713 classified into the feature extraction is completed.

FIG. 19 is a diagram presented to the user when the combination selection unit 101 and the combination interpretation unit 103 are used in the polyhedral design support apparatus and the combination selection unit 101 and the combination interpretation unit 103 operate. Is shown. The graphic 1 (1901) is the result of the contour line display processing procedure 713 being executed after the completion of the plane creation processing procedure 712, and the graphic 2 (1902) is the contour line correction result after the execution of the contour line display processing procedure 713.

Further, as shown in FIG. 5, the combination processing interpretation unit 103 is provided with a repetition control unit 504 and a process identification number temporary saving unit 505 so that the procedures classified into the feature extraction and the shape modification can be classified. It can be repeatedly output to the process selection unit 603. This operation will be described by taking as an example the case where the combination 1 (701) is output from the combination selection unit 101.

The combination selecting section 101 is arranged to
Of the contents (412 to 414) of the combination processing interpretation unit 10
Output to 3. The combination processing interpretation unit 103 outputs the contents of the combination 1 output from the combination selection unit 101 (41
2 to 414) are decomposed by the process decomposition unit 501, and the plane creation process identification number 412, the contour line display process identification number 413, and the plane change process identification number 414 are output to the repetition control unit 504 and the process identification number temporary saving unit 505. . When the process decomposition unit 501 outputs the plane creation process identification number 412, the contour line display process identification number 413, and the plane change process identification number 414, the repetition control unit 504 outputs the process identification numbers 412 to 414 to the process output unit 502. Is output. The process output unit 502 sequentially outputs the process identification numbers 412 to 414 to the process selection unit 603, and when the output ends, outputs the output end data to the repeat control unit 504. Further, the process identification number temporary saving unit 505 outputs the process identification number only when the process decomposition unit 501 outputs the contour line display process identification number 413 classified into the feature extraction and the plane change process identification number 414 classified into the shape modification. Store and repeat control unit 50
The contour display process identification number 413 and the plane change process identification number 414 are output to 4. The repetition control unit 504 receives the process identification number output by the process identification number temporary saving unit 505 only when the output end data is output from the process output unit 502, and outputs the process identification number to the process output unit 502. In this way, the repetition control unit 504 and the process output unit 502 operate so that the contour line display process identification number 413 and the plane change process identification number 414 can be repeatedly output. To end the repetition in the process execution unit 605, the process command may be selected by the input device in the input unit 601.

In this way, the combination processing interpretation unit 103
Is operated, the plane change processing procedure 714 and the contour line display processing procedure 713 can be continuously executed. A figure 3 (1903) in FIG. 19 is a result of continuous execution of the plane change processing procedure 714 and the contour line display processing procedure 713 according to the contour line correction result. By executing the contour line display processing procedure 713 after the plane creation processing procedure 712, the polyhedron design support apparatus automatically presents the features of the plane data as contour lines as shown in FIG. In order to execute the essential contour line display processing procedure 713, the user can create and evaluate the plane data without erroneous operation or forgetting to do the operation. In addition, since the contour line display processing procedure 713 is continuously executed when the plane data is created, the processing instruction related to the contour line display processing procedure 713 can be omitted from the processing instruction displayed on the display device by the display unit 606. Therefore, the processing command presented by the display unit 606 to the display device can be reduced. As a result, when the polyhedron design support apparatus is used, it becomes possible for the user to facilitate the processing instruction selection operation.
Further, in the polyhedron design support apparatus, the user can edit the contour lines by using the input device as shown in the figure 2 (1902). Thereby, the correction data can be given to the polyhedron design support apparatus by editing the contour lines displayed on the output device. Graphic 3 (1903) is the result of modifying graphic 1 (1901) in the plane change processing procedure 714 with the correction data. Graphic 3 (1903) is evaluated by the user,
If the user is not satisfied, the operation shown in the figure 2 (1902) is repeated. In this way, the user can correct the continuously presented contour lines, and the user can easily correct the plane data while grasping the features of the plane data by the contour lines.

In the polyhedron design support device, shape creation,
Although one processing procedure is classified into feature extraction and shape correction, each processing procedure classified into shape creation, feature extraction, and shape correction may be plural as shown in the combination example of FIG. The combination processing interpretation unit 103 operates normally. This allows the user to perform multifaceted evaluation of shape data.

[0051]

As described above, according to the present invention,
Since the design support device automatically presents the characteristics of the shape data and executes the required processing 1607 to processing q612, the user can create, evaluate, and correct the shape data without forgetting to make mistakes. It will be possible. Further, when the shape data is created and modified, the process classified into the feature extraction n609
-Since the process o610 is continuously executed, the process command corresponding to the process n609-process o610 classified into the feature extraction can be omitted from the process command output to the display device, and the presented process command. Can be reduced. Further, it is also possible to correct the shape data and the feature data that are continuously presented, and the user can easily correct the shape data while grasping the features of the shape data. As a result, the user can revise the shape data faster and to a shape having the characteristic data desired by the user.

[Brief description of drawings]

FIG. 1 is a configuration diagram showing a configuration of a design support device according to the present invention.

FIG. 2 is a configuration diagram showing a configuration of a processing selection unit.

FIG. 3 is a configuration diagram having a plurality of processing selection units.

FIG. 4 is an example of processing combination data stored in a processing combination storage unit.

FIG. 5 is a configuration diagram showing a configuration of a combination processing interpretation unit.

FIG. 6 is a configuration diagram showing a configuration of a conventional design support apparatus such as a general CAD / CAM / CAE system.

FIG. 7 is an explanatory diagram showing processing combination data stored in a processing combination storage unit and processing procedures stored in the processing storage unit in the polyhedral design support apparatus.

FIG. 8 is an explanatory diagram showing character string data displayed on a display device by a display unit.

FIG. 9 is a diagram showing a state in which the user starts the polyhedral design support device,
It is a display example showing up to the result of the display device displaying a plane figure on the display unit.

FIG. 10 is an explanatory diagram showing input data relating to a plane creation processing procedure received by an input data interpretation unit.

FIG. 11 is an explanatory diagram showing point graphic / polygon line graphic data created when the processing execution unit executes a plane creation procedure.

FIG. 12 is a specific operation example by the user until the contour display direction and the contour interval using the input device are input to the processing execution unit that is executing the contour display processing procedure.

FIG. 13 is an explanatory diagram showing input data relating to a contour line display processing procedure received by an input data interpretation unit.

FIG. 14 is an explanatory diagram showing contour line data created when the processing execution unit executes a contour line display processing procedure.

FIG. 15 is a diagram showing a case of correcting a contour line using an input device,
It is a specific operation example by a user.

FIG. 16 is an explanatory diagram showing correction data regarding a plane change processing procedure received by an input data interpretation unit.

FIG. 17 is an explanatory diagram showing the changed point graphic / polygon line graphic data created when the processing execution unit executes the plane change processing procedure.

FIG. 18 is a display result of the changed point graphic / polygon line graphic / contour line graphic displayed on the display device in the display unit when the processing execution unit executes the plane change processing procedure and the contour line display processing procedure.

FIG. 19 is an explanatory diagram showing a series of flows regarding creation, evaluation, and correction of a plane.

FIG. 20 is an example of a flowchart showing the processing procedure of the present invention.

[Explanation of symbols]

101 ... Combination selection unit, 102 ... Process combination storage unit, 103 ... Combination process interpretation unit, 121 ... Combination A, 122 ... Combination B, 201 ... Combination process interpretation, 202 ... Process selection, 301 ... Process selection unit A, 3
02 ... Process selection part B, 303 ... Process selection part C, 401 ...
An example of combination data, 402 ... An example of combination data, 411 ... Processing command identification number, 412 ... Plane creation processing identification number, 413 ... Contour line display processing identification number, 414
... plane change process identification number, 423 ... contour line display process A identification number, 424 ... contour line display process B identification number, 425 ...
Contour line display process C Identification number, 426 ... Contour line display process D
Identification number, 427 ... Plane changing process A identification number, 428 ...
Plane change process B identification number, 429 ... Plane change process C identification number, 430 ... Plane change process D identification number, 501 ... Process decomposition unit, 502 ... Process output unit, 503 ... Process identification number sequence, 504 ... Repeat control unit, 505 ... Process identification number temporary saving unit, 506 ... Process identification number sequence, 601 ... Input unit,
602 ... Input data interpreting unit, 603 ... Process selecting unit, 60
4 ... Process storage unit, 605 ... Process execution unit, 606 ... Display unit, 607 ... Processing means l, 608 ... Processing means m, 609
... processing means n, 610 ... processing means o, 611 ... processing means p, 612 ... processing means q, 613 ... processing means r, 614
... processing means s, 615 ... shape storage unit, 701 ... plane creation / contour display / plane change combination data, 702 ... plane modification / contour display combination data, 703 ... processing procedure, 711 ... process identification number, 712 ... plane creation processing Procedure, 713 ... Contour line display processing procedure, 714 ... Plane changing processing procedure, 801 ... Character string data in the case of processing instruction "plane creation", 812 ... Arrangement position of character string in the case of processing instruction "plane creation", 813 ... Character string in the case of processing instruction "plane creation", 901 ... Display device, 902 ... Display result of character string in case of processing instruction "plane creation", 903 ... Display result of character string in case of processing instruction "plane change" , 904 ... Character "#" indicating the position designated by the input device, 905 ... Point graphic indicating the position designated by the input device, 906 ... Display result of polygonal line graphic, 100 ... processing input data related to the instruction "plane creation", 1011 ... user input position was instructed by a mouse is 1,1012 ... user input position was instructed by a mouse is 2,1013 ... input position 3 the user instructs the mouse,
1014 ... Input position 4, 11 designated by the user with the mouse
01 ... Point figure / line figure data, 1201 ... Character "#" indicating the position designated by the mouse, 1202 ... Arrow indicating the direction in which contour lines are displayed, 1203 ... Character "#" indicating the position designated by the mouse, 1204 ... Contour spacing, 130
1 ... Input position data, 1311 ... Input position 1, 1312
Input position 2, 1313 ... Input position 3, 1401 ... Contour line data, 1412 ... Start / end coordinate values of contour line 1, 1
413 ... Start point / end point coordinate value of contour line 2, 1414 ... Start point / end point coordinate value of contour line 3, 1415 ... Start point / point of contour line 4
End point coordinate values, 1501 ... Contour line display result displayed by the contour line display device, 1502 ... Characters "#" indicating the position designated by the mouse, 1503 ... Point graphic, 1601 ... Correction data, 1612 ... Input position 1, 1613 ... Input Position 2, 1
701 ... Point graphic / polygonal figure after change, 1711 ... Corrected position 1, 1712 ... Corrected position 2, 1713 ... Corrected position 3, 1714 ... Corrected position 4, 1801 ... Display result of point graphic displayed by plane changing device, 1802 ... Display result of polygonal line figure displayed by plane changing device, 1803 ... Display result of contour line displayed by contour line display device, 1901 ... Figure 1, 19
02 ... Graphic 2, 1903 ... Graphic 3, 2001 ... Process input, 2002 ... Combination command selection, 2003 ...
Interpretation of combination commands, 2004 ... Selection of processing, 20
05 ... Execution of processing program, 2006 ... End of processing or 2
007 ... Data storage, 2008 ... Data output, 2010 ...
Combination command, 2011 ... Processing program, 20
051 ... Creation processing program execution, 20052 ... Evaluation processing program execution, 20053 ... Correction processing program execution.

Front Page Continuation (72) Inventor Yoshiaki Shinozuka 4026 Kujimachi, Hitachi City, Ibaraki Prefecture Hitachi Research Laboratory, Nitate Manufacturing Co., Ltd.

Claims (12)

[Claims] Claims: 1. Input means for instructing processing of shape data and inputting shape data, a command for creating the shape data, a command for evaluating displaying characteristics of the shape data, and correcting the shape data. Processing combination storage means for holding a command in which any command is arbitrarily combined, processing storage means for holding a processing program for processing the shape data corresponding to the command, and the processing corresponding to an instruction from the input means A combination selecting means for selecting a combination command in the combination storage section, an interpreting means for specifying the processing of the shape data designated by the combination command, and the processing program corresponding to the specified processing is selected from the processing storage means. Processing selection means to perform, and the shape data input from the input means Design support apparatus characterized by comprising a process execution means for executing, based on the processing program to be outputted from the process selecting means, and output means for outputting the shape data processed by said process execution means. 2. Input means for instructing processing of shape data and inputting the shape data, a command for creating the shape data, a command for evaluation for displaying characteristics of the shape data, and a correction for the shape data. Processing combination storage means for holding a command in which any command is arbitrarily combined, processing storage means for holding a processing program for processing the shape data corresponding to the command, and the processing corresponding to an instruction from the input means Combination selecting means for selecting a combination command of the combination storage unit, processing for specifying the shape data designated by the combination command, processing for creating the shape data, and processing for evaluation for displaying characteristics of the shape data. , An interpreting means for classifying the shape data correction processing, The first processing selection means for selecting from the processing storage means a processing program for creating the shape data corresponding to the classified processing, and the processing program for evaluating the shape data corresponding to the classified processing Input from the second processing selection means to select from the storage means, the third processing selection means to select from the processing storage means a processing program related to the correction of the shape data corresponding to the classified processing, and the input means. Process execution means for executing the formed shape data based on the processing program output from the first, second, or third processing selection means, and the shape data processed by the processing execution means are output. A design support apparatus comprising: an output unit. 3. The design support apparatus according to claim 1 or 2, wherein the combination commands are a command related to the creation of the shape data and a command related to the evaluation. 4. The design support apparatus according to claim 1, wherein the combination command is a command relating to the evaluation and a command relating to the correction. 5. The design support apparatus according to claim 4, wherein the processing program corresponding to the combination command according to claim 4 is repeatedly executed until an instruction regarding processing end is given from the input unit. 6. The processing program according to claim 1 or 2, wherein the processing program held in the processing storage means is divided into a processing program for creating shape data, a program for evaluation, and a program for correction. Design support device. 7. A combination command in which a command relating to creation of the shape data, a command relating to evaluation for displaying characteristics of the shape data, and a command relating to correction of the shape data are arbitrarily combined. Is selected, a processing program for processing the shape data corresponding to the selected command is selected, and the processing program corresponding to the selected command is executed to output the shape data. . 8. A combination command that arbitrarily combines a command related to creation of the shape data, a command related to creation of the shape data, a command related to evaluation for displaying characteristics of the shape data, and a command related to correction of the shape data. Select a processing program for processing the shape data corresponding to the selected command, execute the creation processing program corresponding to the selected command for creating the shape data, and output the shape data, The evaluation processing program corresponding to the selected shape data evaluation command is executed to output the characteristic data or the combined data obtained by combining the characteristic data and the shape data, and the selected shape data correction command is responded to. Execute the correction processing program and output the corrected shape data Design support and wherein the door. 9. A combination command in which a command relating to creation of the shape data, a command relating to evaluation for displaying characteristics of the shape data, and a command relating to correction of the shape data are arbitrarily combined. Select a processing program for processing the shape data corresponding to the selected command, execute the creation processing program corresponding to the selected command for creating the shape data, and output the shape data, The evaluation processing program corresponding to the selected shape data evaluation command is executed to output the characteristic data or the combined data obtained by combining the characteristic data and the shape data, and the selected shape data correction command is responded to. Execute the correction processing program to output the corrected shape data, If the processing is terminated, the output data is saved. If the processing is continued, the evaluation processing program corresponding to the command relating to the evaluation of the shape data and the shape data. A design support method characterized in that a modification processing program corresponding to a command related to the modification is repeatedly executed. 10. The execution order of the processing programs according to claim 7, 8 or 9, wherein the processing programs corresponding to the commands relating to the creation of the shape data are executed, and thereafter,
A design support method comprising executing a processing program corresponding to an evaluation-related command for displaying the characteristics of the shape data. 11. The execution order of the processing programs according to claim 7, 8 or 9, wherein the processing programs corresponding to the commands relating to the evaluation of the shape data are executed, and thereafter,
A design support method comprising executing a processing program corresponding to a command relating to correction of the shape data. 12. The design support method according to claim 11, wherein the execution order of the processing programs is repeated until an instruction regarding the end of processing is given.