JPH08147498A - Element selecting system for three-dimensional model - Google Patents

Abstract

PURPOSE: To emphasis-display the related edge or plane of a two-dimensional view and a three-dimensional view in accordance with the selection of the edge or plane of the two-dimensional view or the three-dimensional view so that it is displayed plainly what edge or plane is selected in respect of the element selecting system of a three-dimensional model. CONSTITUTION: This system is constituted so as to be provided with a model display means 4 which displays the two-dimensional view 21 on a window and displays the three-dimensional view 31 on another window, and an element selecting means 5 which emphasis-displays the edge or plane on the designated two-dimensional view 21 or three-dimensional view 31 in accordance with the designation of the arbitrary edge or plane on the two-dimensional view 21 or three-dimensional view 31, and simultaneously, emphasis-displays together the corresponding edge or plane on another three-dimensional view 31 or two-dimensional view 21.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a three-dimensional model element selection system.

[0002]

2. Description of the Related Art Conventionally, in CAD and the like, at the stage of displaying and creating a three-dimensional model on a screen, the visual direction of the three-dimensional model is indicated by pointing a certain direction to the front so as to facilitate the work. The two-dimensional view viewed from is displayed and a new sketch is added on the two-dimensional view.

[0003]

When a certain direction as described above is designated to the front and the two-dimensional view is displayed on the screen and an operation is performed on the two-dimensional view, an edge of the three-dimensional model is present. If you try to select, there is a problem that you do not know which edge is selected.

Further, when it is desired to select a plane perpendicular to the two-dimensional view, it is necessary to return to the three-dimensional view and select it. In order to solve this problem, the present invention displays a two-dimensional view of a three-dimensional model and creates a three-dimensional model by displaying the three-dimensional view together with a sub-window. It is intended to highlight the related edges or faces of the two-dimensional view and the three-dimensional view in correspondence with the selection of the edges or faces, and to easily display which edge or face has been selected.

[0005]

FIG. 1 shows a block diagram of the principle of the present invention. In FIG. 1, the display screen 1 is provided with a main window 2 and a sub window 3.

The main window 2 has a two-dimensional view 21.
Is displayed. The sub window 3 is for displaying a three-dimensional view 31. The model display means 4 is
The two-dimensional view 21 is displayed on the main window 2 and the three-dimensional view 31 is displayed on the sub window 3.

The element selecting means 5 highlights the designated edge or face in response to designation of the edge or face on the two-dimensional view 21 or the three-dimensional view 31.

[0008]

According to the present invention, as shown in FIG. 1, the model display means 4 displays the two-dimensional view 21 on the window and the three-dimensional view 31 on another window, and the element selection means 5
In response to designation of an arbitrary edge or surface on the two-dimensional view 21 or three-dimensional view 31, the edge or surface on the designated two-dimensional view 21 or three-dimensional view 31 is highlighted and The corresponding edges or faces on the three-dimensional view 31 or the two-dimensional view 21 are also highlighted.

Further, in response to the model display means 4 designating a surface on the three-dimensional view and designating the display of the two-dimensional view, the designated two-dimensional view 21 is displayed on the main window 2 and The three-dimensional view 31 is also displayed on the sub-window 3, and the element selection means 5 selects the selected edge or face in response to the selected edge or face on the two-dimensional view 21 or the three-dimensional view 31. On the two-dimensional view 21 and the three-dimensional view 31, while highlighting on the three-dimensional view 21 or the three-dimensional view 31, related edges or faces are also highlighted on the other three-dimensional view 31 or the two-dimensional view 21. The three-dimensional view 31 of the sub-window 3 is automatically generated in response to the user's OK instruction to select an edge or a surface when viewing the highlighted display. Flip, and to perform the creation of the three-dimensional model on the two-dimensional view 21.

Therefore, two of the designated surfaces of the three-dimensional model
When the three-dimensional model is created by displaying the three-dimensional view 21, the three-dimensional view 31 is also displayed on the sub-window 3 so that any edge or surface of the two-dimensional view 21 or the three-dimensional view 31 can be selected. Two-dimensional view 21
By highlighting the corresponding edge or face of the three-dimensional view 31, it is possible to easily display which edge or face on the three-dimensional model has been selected.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, the construction and operation of an embodiment of the present invention will be described in detail with reference to FIGS.

FIG. 2 shows a flowchart for explaining the operation of the present invention. This is a detailed description of the operation of the configuration of FIG. 1, which will be specifically described with reference to FIGS. 2 to 6. In FIG. 2, S1 displays a three-dimensional model in a two-dimensional view. This displays the 3D model as a 2D view 21 on the main window 2 of FIG. At this time, the surface with the three-dimensional model and the upward direction when displayed in two dimensions are specified, and the two-dimensional view 21 according to the specified direction of the specified surface is displayed on the main window 2.

In S2, a cross-section sketch is performed. This sketches the cross section of the three-dimensional shape to be added, as shown by the dotted line on the two-dimensional view 21 in FIG. S
3 determines whether the selected element is an edge element or a surface element. This is done by performing a cross-section sketch in S2 and determining whether the element selected to confirm the position of the three-dimensional shape to be added at that time is an edge element or a surface element. When the edge element is selected by the operator, the processing is performed from S5 to S17. On the other hand, when the surface element is selected, the processing of S18 to S30 is performed.

In step S5, it is determined whether to open the three-dimensional view.
This determines whether the three-dimensional view has been initially set to be automatically opened when the two-dimensional view 21 is displayed. Here, since it is YES, the process proceeds to S6.

In step S6, another window is opened to display the three-dimensional view. This opens the subwindow 3 of FIG. 1 and displays the 3D view 31 as shown. S7 is
It is determined whether the selected element is a two-dimensional view or a three-dimensional view.
This is shown on the main window 2 as shown in FIG.
In the state where the three-dimensional view 31 is displayed on the sub window 3 while displaying the three-dimensional view 21, it is determined whether the operator has selected the edge element on the two-dimensional view or the three-dimensional view 31. When selecting an edge element on the two-dimensional view 21, the processing from S8 to S12 is performed.
On the other hand, when selecting an edge element on the three-dimensional view 31, the processes of S13 to S17 are performed.

(1) When selecting an edge on the two-dimensional view 21: S8 selects an edge on the two-dimensional view 21. For example, the two-dimensional view 2 of FIG.
1. Select edge on 1.

In S9, the edge on the two-dimensional view 21 is highlighted. For example, an edge on the selected two-dimensional view 21 in FIG. 3A, which will be described later, is highlighted. S
Reference numeral 10 extracts edge information (start and end XYZ coordinates). For example, the two-dimensional view 21 of FIG.
Thick line of the start point of edge information of the above, as XYZ coordinates of the end point, - the illustrated _{A (X A, Y A,} Z A) · B (X B, Y B, Z B) to extract.

In step S11, the edge information is displayed in highlight or another color on the three-dimensional view 31, and the selection is recognized and confirmed. For example, as shown by the thick line highlighting on the three-dimensional view 31 in FIG. 3B described later, the edge information extracted in S10 is displayed in highlight or another color, and the edge selected in the two-dimensional view 21 is displayed. The three-dimensional view 31 is highlighted for easy viewing, and the operator recognizes and confirms the selected edge.

In step S12, a selection OK instruction is given. This confirms that the operator who saw the highlighted edge on the three-dimensional view 31 in S11 recognizes whether the edge selected on the two-dimensional view 21 is correct and then gives an instruction to select OK. Then, in S31, the display window of the three-dimensional view 31 is closed.

As described above, when an edge is selected on the two-dimensional view 21, the selected edge information is extracted, the corresponding edge is highlighted on the three-dimensional view 31 based on this edge information, and the operator is given a 2 The edge selected in the three-dimensional view 21 is highlighted to inform the user, and when OK, the three-dimensional view 31 is closed in response to the instruction to that effect, and the operator selects the edge on the two-dimensional view 21 and confirms the edge. Create a 3D model.

(2) When selecting an edge on the three-dimensional view 31: In S13, an edge on the three-dimensional view 31 is selected. For example, an edge is selected on the three-dimensional view 31 shown in FIG.

In step S14, the edge on the three-dimensional view 31 is highlighted. For example, an edge on the selected three-dimensional view 31 in FIG. 4A, which will be described later, is highlighted.
In step S15, edge information (XYZ coordinates of the start point and the end point) is extracted. For example, the three-dimensional view 3 of FIG.
Thick line of the start point of edge information on 1, as XYZ coordinates of the end point, - the illustrated _{A (X A, Y A,} Z A) · B (X B, Y B, Z B) to extract.

In S16, the edge information is displayed in highlight or another color on the two-dimensional view 21, and the selection is recognized and confirmed. For example, the edge information extracted in S15 is displayed in highlight or another color as shown by the thick line highlighting on the two-dimensional view 21 in FIG. 4B described later, and the edge selected in the two-dimensional view 21 is displayed. The two-dimensional view 21 is highlighted for easy viewing, and the operator is made to recognize and confirm the selected edge.

In step S17, a selection OK instruction is given. This confirms that the operator who saw the highlighted edge on the two-dimensional view 21 in S16 recognizes whether the edge selected on the three-dimensional view 31 is correct and then gives an instruction to select OK. Then, in S31, the display window of the three-dimensional view 31 is closed.

As described above, when an edge is selected on the three-dimensional view 31, the selected edge information is extracted, the corresponding edge is highlighted on the two-dimensional view 21 based on this edge information, and the operator is given a 3 The edge selected in the three-dimensional view 31 is highlighted for easy notification, and when OK, the three-dimensional view 31 is closed in response to the instruction to that effect, and the operator selects and confirms the edge on the three-dimensional view 31. A three-dimensional model is created on the two-dimensional view 21.

Next, in S18, since it is found that the surface element is selected in S3, it is further determined whether or not the three-dimensional view is opened.
In the case of YES, another window is opened and the three-dimensional view 31 is displayed in S19, and the process proceeds to S20.

In S20, whether the selected element is a two-dimensional view or 3
Determine any of the dimensional views. When the selected element is the two-dimensional view 21, the processing of S21 to S25 is performed. When the selected element is the three-dimensional view 31, the processes of S26 to S30 are performed.

(3) When selecting a surface element on the two-dimensional view 21: S21 selects an edge on the two-dimensional view 21. For example, an edge is selected on the two-dimensional view 21 shown in FIG.

In step S22, the edge on the two-dimensional view 21 is highlighted. For example, an edge on the selected two-dimensional view 21 in FIG. 5A, which will be described later, is highlighted.
In S23, surface information (XYZ coordinates of all bending points) is extracted. For example as XYZ coordinates of all the bending points of the thick line of surface information on a two-dimensional view 21 in FIG. 5 to be described later (a), · the illustrated _{A (X A, Y A,} Z A) · B (X B, Y _B , Z _B ) · C (X _C , Y _C , Z _C ) · D (X _D , Y _D , Z _D ) are extracted.

In step S24, the edge and the surface composed of the surface information are displayed in highlight or different colors on the three-dimensional view 31, and the selection is recognized and confirmed. For example, as shown by the thick line highlighting on the three-dimensional view 31 in FIG. 5B, which will be described later, the edge composed of the surface information extracted in S23 is displayed in highlight or another color,
The surface including the edge selected in the two-dimensional view 21 is highlighted on the three-dimensional view 31 so that it is easy to see, and the operator is made to recognize and confirm the surface including the selected edge.

In step S25, a selection OK instruction is given. This is to confirm that the operator who saw the highlighted surface on the three-dimensional view 31 in S24 recognizes whether the surface including the edge selected in the two-dimensional view 21 is correct, and then gives an instruction to select OK. . Then, in S31, the display window of the three-dimensional view 31 is closed.

As described above, when the surface including the edge is selected on the two-dimensional view 21, the selected surface information is extracted,
Based on this surface information, the edge of the corresponding surface is highlighted on the three-dimensional view 31, and the operator is instructed by highlighting the surface including the edge selected on the two-dimensional view 21. In response to the instruction to that effect, the three-dimensional view 31 is closed, and the operator creates a three-dimensional model on the surface selected and confirmed on the two-dimensional view 21.

(4) When selecting a surface element on the three-dimensional view 31: S26 selects a surface on the three-dimensional view 31. For example, the three-dimensional view 31 of FIG.
Make a face selection above.

In step S27, faces on the three-dimensional view 31 and edges formed by the faces are highlighted. For example, a face on the selected three-dimensional view 31 in FIG. 6A, which will be described later, and an edge composed of the face are highlighted.

In step S28, surface information (XYZ coordinates of all bending points) is extracted. For example as XYZ coordinates of all the bending points of the thick line of surface information on the three-dimensional view 31 in FIG. 6 to be described later (a), · the illustrated _{A (X A, Y A,} Z A) · B (X B, Y _B , Z _B ) · C (X _C , Y _C , Z _C ) · D (X _D , Y _D , Z _D ) are extracted.

In step S29, the edge composed of the surface information is displayed on the two-dimensional view 21 in highlight or another color, and the selection is recognized and confirmed. For example, as shown by the thick line highlighting on the two-dimensional view 21 in FIG. 6B, which will be described later, the edge composed of the surface information extracted in S28 is highlighted or displayed in another color, and the three-dimensional view 31 is displayed. The surface selected by is highlighted on the two-dimensional view 21 so that it can be easily seen, and the operator is made to recognize and confirm the surface including the selected edge.

In step S30, a selection OK instruction is given. This confirms that the operator who saw the highlighted surface on the two-dimensional view 21 in S29 recognizes whether the surface selected on the three-dimensional view 31 is correct, and then gives an instruction to select OK. Then, in S31, the display window of the three-dimensional view 31 is closed.

As described above, when a surface is selected on the three-dimensional view 31, the selected surface information is extracted, the edge of the corresponding surface is highlighted on the two-dimensional view 21 based on this surface information, and the operator , The surface selected in the three-dimensional view 31 is highlighted and informed, and when OK, the three-dimensional view 31 is closed in response to the instruction to that effect, and the operator selects and confirms on the two-dimensional view 21. Create a three-dimensional model on the surface.

FIG. 3 shows a display example (1) of the present invention. This corresponds to S8 to S12 in FIG. 2 described above, and is a display example when an edge element is selected on the two-dimensional view 21.

FIG. 3A shows how edges are selected, highlighted, and edge information is extracted on the two-dimensional view 21. The dotted rectangle is a sketch.

FIG. 3B corresponds to the three-dimensional view 31 corresponding to the edge selection, highlighting, and edge information extraction on the two-dimensional view 21 in FIG. 3A. The state where the edge is highlighted is shown.

As described above, when an edge is selected on the two-dimensional view 21 in FIG. 3A, the edge on the selected two-dimensional view 21 is highlighted and the three-dimensional view in FIG. 3B is displayed. Corresponding edges on 31 are highlighted and the correspondence is displayed in an easy-to-understand manner.

FIG. 4 shows a display example (2) of the present invention. This corresponds to S13 to S17 of FIG. 2 described above, and is a display example when the edge element is selected on the three-dimensional view 31.

FIG. 4A shows how an edge is selected, highlighted, and edge information is extracted on the three-dimensional view 31. The dotted rectangle is a sketch.

FIG. 4B corresponds to the two-dimensional view 21 corresponding to the edge selection, highlighting, and edge information extraction on the three-dimensional view 31 in FIG. 4A. The state where the edge is highlighted is shown.

As described above, when an edge is selected on the three-dimensional view 31 in FIG. 4A, the edge on the selected three-dimensional view 31 is highlighted and the two-dimensional view in FIG. 4B is displayed. Corresponding edges on 21 are highlighted, and the correspondence is displayed in an easy-to-understand manner.

FIG. 5 shows a display example (3) of the present invention. This corresponds to S21 to S25 of FIG. 2 described above, and is a display example in the case of selecting a surface including an edge on the two-dimensional view 21.

FIG. 5A shows how a surface including an edge is selected, highlighted, and surface information is extracted on the two-dimensional view 21. The dotted rectangle is a sketch.

FIG. 5 (b) shows that the face including the edge is selected and highlighted on the two-dimensional view 21 in FIG. 5 (a).
In response to the extraction of the surface information, the state in which the edge including the corresponding surface is highlighted on the three-dimensional view 31 is shown.

As described above, when a face including an edge is selected on the two-dimensional view 21 in FIG.
The surface including the edge on the three-dimensional view 21 is highlighted, and the edge of the corresponding surface on the three-dimensional view 31 of FIG. 5B is highlighted, so that the correspondence is displayed in an easy-to-understand manner. .

FIG. 6 shows a display example (No. 4) of the present invention. This corresponds to S26 to S30 of FIG. 2 described above, and is a display example when a surface is selected on the three-dimensional view 31.

FIG. 6A shows how a surface is selected, highlighted, and surface information is extracted on the three-dimensional view 21. The dotted rectangle is a sketch.
6B includes the corresponding surface on the two-dimensional view 21 in response to the selection, highlighting, and extraction of the surface information of the surface on the three-dimensional view 31 in FIG. 6A. The state where the edge is highlighted is shown.

As described above, when a surface is selected on the three-dimensional view 31 in FIG. 6A, the selected three-dimensional view 3
1 is highlighted, and 2 of FIG. 6B is displayed.
The edge of the corresponding surface on the dimensional view 21 is highlighted, and the correspondence is displayed in an easy-to-understand manner.

[0054]

As described above, according to the present invention,
When the two-dimensional view 21 of the specified surface of the three-dimensional model is displayed to create the three-dimensional model, the three-dimensional view 31 is displayed together with the sub-window 3, and the two-dimensional view 21 or the three-dimensional view 31 is arbitrarily selected. 2D view 21 and 3D view 31 corresponding to the selection of edges or faces of
Since the corresponding edge or face of the 3D model is highlighted, it is easy to understand which edge or face on the 3D model is selected, and the corresponding relationship is provided on the 2D view 21 and the 3D view 31. Can be displayed.

[Brief description of drawings]

FIG. 1 is a principle block diagram of the present invention.

FIG. 2 is a flowchart explaining the operation of the present invention.

FIG. 3 is a display example (1) of the present invention.

FIG. 4 is a display example (2) of the present invention.

FIG. 5 is a display example (3) of the present invention.

FIG. 6 is a display example (4) of the present invention.

[Explanation of symbols]

 1: Display display screen 2: Main window 21: Two-dimensional view 3: Sub-window 31: Three-dimensional view 4: Model display means 5: Element selection means

Claims (2)

[Claims] 1. Model display means (4) for displaying a two-dimensional view (21) on a window and a three-dimensional view (31) on another window, and the two-dimensional view (21) or the three-dimensional view (3).
1) In response to the designation of an arbitrary edge or face on the above, the edge or face on the designated two-dimensional view (21) or three-dimensional view (31) is highlighted and another three-dimensional view is displayed. (31) or an element selection means (5) for highlighting corresponding edges or faces on the two-dimensional view (21) together, the element selection method for a three-dimensional model. 2. A corresponding two-dimensional view (21) is displayed in the main window in response to an instruction to display a two-dimensional view by designating a surface on the three-dimensional view, and
Model display means (4) for displaying the three-dimensional view (31) together with the sub-window, and the above-mentioned two-dimensional view (21) or three-dimensional view (3
1) Corresponding to the selection of the edge or face on the two-dimensional view (2
1) or element selection means (5) for highlighting on the three-dimensional view (31) and also for highlighting related edges or surfaces on the other three-dimensional view (31) or two-dimensional view (21). And selecting the edge or face from the user who sees the highlighting on the two-dimensional view (21) and the three-dimensional view (31).
In response to the instruction of K, the three-dimensional view (31) on the sub-window is automatically closed and the three-dimensional view (21) is displayed on the sub-window.
An element selection method for a three-dimensional model characterized by being configured to create a three-dimensional model.