JP2010244403A - Vehicle model deformation display method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a vehicle model deformation display method having an advantage in performing carefully and effectively deformation operations of an outline image of a vehicle model using a basic structure of a vehicle as constraint. <P>SOLUTION: A deformation portion selection part 44A selects a deformation portion to be deformed of the outline image 50 of the vehicle model by a user's operation of an input device 6D. When the deformation portion is selected, a deformation region setup part 44B sets up the region of the outline image 50 corresponding to the deformation portion on a screen as a deformation region 52. A guide bar 60 is displayed on the screen. When the user selects and moves one operation point of all the operation points by operation of the input device 6D on the screen of the display device 6E, a guide bar interlocking display part 44D moves and displays the guide bar 60 in conjunction with the move of the operation point. An outline image deformation display part 44E deforms and displays the deformation region 52 in conjunction with the guide bar 60, and thereby the outline image 50 is deformed and displayed. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a vehicle model deformation display method.

Conventionally, various techniques for supporting planning examination or design have been proposed in order to efficiently perform planning examination or design of a vehicle (see Patent Documents 1 to 5).
In these techniques, an outline image of a vehicle model is displayed on the display screen of the display device, and an outline image is displayed by clicking and dragging a specific portion of the vehicle model, for example, a part, using a mouse as an input device. The appearance of the new vehicle is being examined by deforming.
Such a deformation operation of the image on the screen is the same as the operation in the case of using various conventionally known application software for image processing used in CG or CAD.

JP 2003-99499 A JP 2003-108625 A JP 2004-302673 A JP 2002-366606 A JP 2007-4423 A

By the way, for example, when creating an image of the external shape of a vehicle model when planning a new vehicle while sharing the structure, performance, and parts of the existing vehicle, a vehicle model based on the external shape of the existing vehicle is used. Therefore, it is required to perform the deformation of the external shape with a simple operation and in a short time.
However, in the above prior art, the outer shape of the vehicle model can be freely deformed, but the degree of freedom of deformation is too large. It was impossible to perform detailed operations such as examining the appearance of the new vehicle while gradually deforming the.
The above-described prior art cannot be said to satisfy such requirements sufficiently.
The present invention has been made in view of such circumstances, and an object of the present invention is to provide a vehicle model deformation display method that is advantageous in performing finely and efficiently performing a deformation operation of an outline image of a vehicle model with the basic structure of the vehicle as a constraint. Is to provide.

  In order to achieve the above-described object, the present invention is a vehicle model deformation display method for displaying an outline image of a vehicle model on a screen of a display device and deforming the outline image of the vehicle model in accordance with an operation of an input device. A deformed portion selecting step for selecting a deformed portion to be deformed from the contour image of the vehicle model, and a deformed region setting step for setting a region of the contour image corresponding to the deformed portion on the screen as a deformed region. A guide bar display step for displaying a guide bar including a straight line portion extending in a straight line and at least one operation point formed in the straight line portion on the screen in association with the deformation area; and When the operation point is selected and moved by operating the input device, the guide bar is moved or deformed in conjunction with the movement of the operation point. A guide bar interlocking display step for displaying, an external image deformation display step for displaying the external image of the vehicle model in which the deformation area is deformed in conjunction with the movement or deformation of the guide bar, and the movement of the guide bar or And an outer shape image deformation display step of deforming and displaying the deformation area in conjunction with deformation.

  According to the present invention, the guide bar displayed on the screen of the display device is set in consideration of the basic structure of the vehicle in the deformation area corresponding to the deformation portion to be deformed in the outline image of the vehicle model. Since the outer shape image is deformed by operating the input device with the input device, it is advantageous in performing the deformation operation of the outer shape image of the vehicle model finely and efficiently for each portion.

It is a block diagram of the new vehicle plan examination support system to which the present invention is applied. 3 is a block diagram showing a configuration of a client terminal 6. FIG. 3 is a functional block diagram of a server 2 and a client terminal 6. FIG. 4 is a functional block diagram of a vehicle model deforming unit 44. FIG. 4 is a flowchart for explaining the operation of a new vehicle plan review support system 8. It is explanatory drawing which shows the state in which the external shape image 50 which shows the side surface of a vehicle model, and the guide bar 60 are displayed on the screen. It is explanatory drawing explaining operation of the guide bar 60 in case the deformation | transformation part selected by the deformation | transformation part selection step is full height. It is explanatory drawing explaining operation of the guide bar 60 in case the deformation | transformation part selected by the deformation | transformation part selection step is a center volume of the upper part of a body. It is explanatory drawing explaining operation of the guide bar 60 in case the deformation | transformation part selected by the deformation | transformation part selection step is a front slant. It is explanatory drawing explaining operation of the guide bar 60 in case the deformation | transformation part selected by the deformation | transformation part selection step is a rear slant. It is explanatory drawing explaining operation of the guide bar 60 in case the deformation | transformation part selected by the deformation | transformation part selection step is a front overhang. It is explanatory drawing explaining operation of the guide bar 60 in case the deformation | transformation part selected by the deformation | transformation part selection step is a rear overhang. It is explanatory drawing explaining operation of the guide bar 60 in case the deformation | transformation part selected by the deformation | transformation part selection step is a wheel base. 7 is a flowchart for explaining the operation of the new vehicle plan review support system 8 when the guide bar 60 has a movable reference point 72. It is explanatory drawing which shows the state where the external shape image 50 which shows the front of a vehicle model, and the guide bar 60 are displayed on the screen. It is explanatory drawing explaining operation of the guide bar 60 in case the deformation | transformation part selected by the deformation | transformation part selection step is full width. It is explanatory drawing explaining operation of the guide bar 60 in case the deformation | transformation part selected by the deformation | transformation part selection step is the inclination of a body upper part. It is explanatory drawing explaining operation of the guide bar 60 in case the deformation | transformation part selected by the deformation | transformation part selection step is a departure angle. It is explanatory drawing explaining operation of the guide bar 60 in case the deformation | transformation part selected by the deformation | transformation part selection step is the inclination of a belt line.

Next, an embodiment of the present invention will be described with reference to FIGS.
First, the configuration of a new vehicle plan review support system that executes the method of the present invention will be described.
As shown in FIG. 1, the new vehicle plan review support system 8 includes a server 2 and one or more client terminals 6 connected to the server 2 via a communication network 4.
Server 2 constitutes each database mentioned below.
As the communication network 4, various conventionally known communication networks such as a LAN and a WAN can be used.

The client terminal 6 is configured by a personal computer.
As shown in FIG. 2, the client terminal 6 includes a central processing unit (CPU) 6A, a main storage device 6B, an external storage device 6C, an input device 6D, a display device 6E, a communication device 6F, and the like. 6A, 6B, 6C, 6D, 6E, and 6F are connected by a bus 6G.
The main storage device 6B provides a working area for the central processing unit 6A, and is constituted by a RAM or the like.
The external storage device 6C stores, in addition to conventionally known control programs and information, a new vehicle plan review support program, a vehicle model deformation display program, and the like, and is configured by, for example, a hard disk device.
The input device 6D is composed of a keyboard, a mouse, and the like, and accepts user input operations.
The display device 6E is composed of a display device, and outputs data such as images and characters on the screen.
The communication device 6 </ b> F exchanges information with the server 2 via the communication network 4.
The central processing unit 6A controls the main storage device 6B, the external storage device 6C, the input device 6D, the display device 6E, and the communication device 6F by executing the control program.
Further, the central processing unit 6A realizes the functions of the respective units shown in FIG. 3 by executing the new vehicle plan review support program and the vehicle model deformation display program.

Next, the server 2 will be described.
As shown in FIG. 3, the server 2 includes an existing vehicle model database (hereinafter referred to as DB) 10, an existing vehicle 2DDB 12, a platform component DB 14, a vehicle component DB 16, and the like.

  Existing vehicle 3D model DB10 stores the vehicle model which shows the three-dimensional shape of the existing vehicle.

  The existing vehicle 2DDB 12 stores data indicating dimensions of each part when an existing vehicle is expressed on a two-dimensional drawing, that is, data of a basic layout.

The platform component DB 14 stores data indicating the external shape and external dimensions of a plurality of existing platform components constituting the platform.
Here, the platform and the platform components will be described.
A platform is called a chassis without a body.
When an automobile is made, a large amount of cost is spent on the platform, and different types of vehicles are made by variously changing the vehicle components assembled to the platform.
The platform is composed of a plurality of existing platform components.
The platform component includes a frame that constitutes most of the platform, and a frame assembly component that is assembled to the frame.
Here, the frame is a frame called a main floor or the like, and includes a floor pan, a side member, a cross member, a side sill, and the like.
Further, the frame assembly parts are an engine, a power train, a muffler, a fuel tank, a suspension, and the like, including an axle (axle), a suspension arm, and the like.

The vehicle component DB 16 stores data indicating the external shape and external dimensions of a plurality of existing vehicle component parts that constitute a vehicle by being assembled to a platform.
In the present embodiment, the vehicle components are components that mainly determine the outer shape and design of the vehicle, and include the body, the outer plate attached to the body, the seats that make up the vehicle interior in the body, and various interior parts. It is.
These parts are parts that are deformed corresponding to the appearance and design of the vehicle.

Next, the client terminal 6 will be described.
As described above, the client terminal 6 functions as the following units when the central processing unit 6A executes the new vehicle plan review support program.
In the present embodiment, the client terminal 6 includes a basic vehicle model construction unit 40, an image display unit 42, a vehicle model deformation unit 44, a vehicle model measurement unit 46, a vehicle model output unit 48, and the like.

The basic vehicle model construction unit 40 constructs a vehicle model configured by assembling a plurality of vehicle component parts on an existing platform composed of a plurality of platform component parts as a basic vehicle model.
In the present embodiment, the basic vehicle model construction unit 40 receives the vehicle model indicating the three-dimensional shape of the existing vehicle read from the existing vehicle 3D model DB 10 and the basic layout data of the existing vehicle read from the existing vehicle 2DDB 12. Providing and constructing a basic vehicle model having necessary and sufficient information for creating a new vehicle planning study model.
The basic vehicle model includes a shape of a vehicle when the vehicle is viewed from the outside and a shape of a vehicle compartment when the vehicle is viewed from the vehicle interior.

  The image display unit 42 displays an outline image of the basic vehicle model on the screen of the display device 6E based on the basic vehicle model constructed by the basic vehicle model construction unit 40.

The vehicle model deformation unit 44 deforms and displays the outline image of the basic vehicle model displayed on the screen of the display device 6E based on the operation of the user, and displays the basic vehicle model in conjunction with the deformation of the outline image. It will be deformed.
By deforming the outer shape image of the basic vehicle model, the outer shape image of the vehicle model having a desired outer shape, that is, the outer shape image of the new vehicle planning study model is displayed on the screen of the image display unit 42.
Further, by deforming the basic vehicle model, a vehicle model having a desired outer shape, that is, a new vehicle plan study model can be obtained.
In the present embodiment, the external image of the basic vehicle model and the external image of the new vehicle planning study model are an external image as a three-dimensional shape drawn in a three-dimensional space and a two-dimensional image drawn on a plane. It includes both an outer shape image as a shape.

More specifically, as shown in FIG. 4, the vehicle model deforming unit 44 includes a deformed portion selecting unit 44A, a deformed region setting unit 44B, a guide bar display unit 44C, a guide bar interlocking display unit 44D, and an outline image. A deformation display unit 44E and a vehicle model deformation unit 44F are included.
The deformed part selection unit 44A is for selecting a deformed part to be deformed from the outline image of the vehicle model displayed on the screen of the display device 6E.
For example, as shown in FIG. 7, the deformation area setting unit 44 </ b> B sets an area of the vehicle model outline image 50 corresponding to the deformation portion on the screen as a deformation area 52.
As shown in FIG. 7, the guide bar display unit 44 </ b> C associates a guide bar 60 including a linear part 62 that extends linearly and at least one operation point formed on the linear part 62 with the deformation region 52. Is displayed on the screen.
The guide bar interlocking display unit 44D is displayed by moving or deforming the guide bar 60 in conjunction with the movement of the operation point when the operation point is selected and moved by the input operation of the input device 6D on the screen. To do.
The outline image deformation display unit 44E is for deforming and displaying the deformation area 52 in conjunction with the movement or deformation of the guide bar 60.
The vehicle model deforming unit 44 </ b> F generates a vehicle planning study model by deforming the basic vehicle model in conjunction with the deformation of the outer shape image 50.

The vehicle model measuring unit 46 measures the size, area, volume, angle, etc. of a desired portion of the new vehicle planning examination model obtained by the vehicle model deforming unit 44 and outputs the measurement result as measurement data. It is.
In addition, the output form of the measurement data of the new vehicle planning examination model output from the vehicle model measurement unit 46 is displayed on the screen of the display device 6E, or printed out using a printer. Various forms are possible.

The vehicle model output unit 48 outputs data of a new vehicle plan study model obtained by the vehicle model deformation unit 44.
The model data for the new vehicle planning examination output from the vehicle model output unit 48 may be in any data format that can be used by various conventionally known application software for image processing used in, for example, CG and CAD. It is not limited.
Further, the data output form of the new vehicle plan review model data output from the vehicle model output unit 48 can be various forms known in the art such as print output using a printer.

Next, the operation of the new vehicle plan review support system 8 will be described with reference to the flowchart of FIG. 5, and the vehicle model deformation display method of the present embodiment will be described in detail.
First, the basic vehicle model construction unit 40 of the client terminal 6 includes a vehicle model indicating the three-dimensional shape of an existing vehicle read from the existing vehicle 3D model DB 10 of the server 2 and a basic layout of the existing vehicle read from the existing vehicle 2DDB 12. Based on these data, a basic vehicle model is constructed (step S10).
Then, the image display unit 42 displays the outline image 50 of the basic vehicle model on the screen of the display device 6E based on the basic vehicle model constructed by the basic vehicle model construction unit 40 (step S12).

Next, the vehicle model deforming unit 44 deforms the outline image 50 of the basic vehicle model displayed on the screen of the display device 6E based on the user's operation, and links the basic vehicle in conjunction with the deformation of the outline image 50. Transform the model.
Hereinafter, the deformation operation of the external image 50 of the vehicle model will be described in detail.

In this example, as shown in FIGS. 6 and 7, it is assumed that the side surface of the vehicle model is displayed on the screen as an outline image 50 in advance.
First, the deformed portion selection unit 44A that has received this input operation by the operation of the input device 6D by the user selects a deformed portion to be deformed from the outer shape image 50 of the vehicle model (step S14: deformed portion selecting step).
Examples of the selected deformation portion include the following.
That is, the overall height of the vehicle model, the center volume of the upper part of the body, the front slant, the rear slant, the front overhang, the rear overhang, the wheel base, the full width, the inclination of the upper part of the body, the belt line, the departure angle, and the like.
In the following, a general description will be given by taking as an example the case where the selected deformed portion is the total height of the vehicle model. The case where the selected deformed portion is a portion other than the overall height of the vehicle model will be described individually.
As the operation of the input device 6D by the user, for example, the following method can be used.
In other words, a list-type menu listing a plurality of deformation portions to be selected is displayed on the screen of the display device 6E, and the user selects the deformation portion from the menu by operating the input device 6D. In response to this selection operation, the deformed portion selection unit 44A selects a deformed portion. Of course, various conventionally known input methods can be used as the selection operation of these deformed portions.

When the deformation part is selected, the deformation area setting unit 44B sets the area of the outline image 50 corresponding to the deformation part on the screen as the deformation area 52 as shown in FIG. 7 (step S16: deformation area setting). Step).
For convenience of explanation, in FIG. 7 and subsequent drawings, the deformation region 52 is indicated by surrounding it with a rectangular frame-like line, but this rectangular frame-like line is not displayed on the screen.

Next, the guide bar display unit 44C displays the guide bar 60 on the screen as shown in FIGS. 6 and 7 (step S18: guide bar display step).
As described above, the guide bar 60 includes the straight portion 62 and at least one operation point formed on the straight portion 62.
When the deformed portion selected by the deformed portion selecting step is full height, the guide bar 60 is positioned at a position on the screen away from the vehicle model outline image 50 (in other words, above the vehicle model outline image 50). It has a straight line portion 62 extending substantially parallel to the front-rear direction (horizontal direction) of the vehicle model.
In this example, first, second, and third operation points 64, 66, and 68 and a first reference point 70 are formed and displayed on the straight line portion 62.
The first operation point 64 is an operation point displayed at a location corresponding to the front end position of the outline image 50 in the front-rear direction of the vehicle model.
The second operation point 66 is an operation point displayed at a location corresponding to the rear end position of the outline image 50 in the front-rear direction of the vehicle model.
The third operation point 68 is an operation point displayed at an intermediate position between the first operation point 64 and the second operation point 66 in the front-rear direction of the vehicle model.
The first reference point 70 is a point at which the location of the vehicle model outline image 50 corresponding to the first reference point 70 does not move on the screen when the vehicle model outline image 50 is deformed. .
The first reference point 70 is a front deck FD that is a location where the outer plate portion constituting the hood 5002 of the vehicle model and the windshield 5004 intersect with the external image 50 of the side surface of the vehicle model displayed on the screen. This is where the vertical line passing through and the straight line portion 62 of the guide bar 60 intersect.
Here, the front deck FD and the center point 5012 of the front wheel 5010 of the vehicle model are set in a predetermined relative positional relationship.
In the example of FIG. 7, in order to identify the first, second, and third operation points 64, 66, 68 and the first reference point 70, the display color of each point on the screen is made different. .
That is, in FIG. 7, the first and second operation points 64 and 66, the third operation point 68, and the first reference point 70 are indicated by different hatching. 64, 66, the third operation point 68, and the first reference point 70 are displayed in different display colors on the screen.
Thus, the visibility and operability of the guide bar 60 are improved by changing the display colors of the operation point and the reference point.
7 and the subsequent drawings are the same as in this example in that the display colors of the operation point and the reference point of the guide bar 60 are different. In the present embodiment, the mouse as the input device 6D is used. And a click operation and a drag operation on the guide bar 60 using a mouse pointer displayed on the screen of the display device 6E.

Next, when the user selects and moves one of the operation points by operating the input device 6D on the screen of the display device 6E, the guide bar interlocking display unit 44D that has received this operation input displays The guide bar 60 is moved and displayed in conjunction with the movement of the operation point (step S20: guide bar interlocking display step).
When the selected change portion is full height, the user moves the mouse pointer displayed on the screen on the third operation point 68 and maintains the clicked state, and drags the third operation point 68 upward or downward. To do. Then, the guide bar interlocking display unit 44D that has received this operation input displays the guide bar 60 translated in parallel upward or downward in conjunction with the movement of the third operation point 68.

The outline image deformation display unit 44E deforms and displays the deformation area 52 in conjunction with the movement of the guide bar 60 in step S20, thereby deforming and displaying the outline image 50 (step S22: outline image deformation display step). ).
When the selected change part is full height, as shown in FIG. 7, the deformation area 52 is expanded and contracted up and down in conjunction with the upward or downward movement of the guide bar 60, whereby the outline image 50 is changed into a solid line and a broken line. As shown in FIG.
At this time, as described above, the location of the vehicle model outline image 50 corresponding to the first reference point 70 is a fixed point that does not move on the screen. That is, the fixed point is located on the vertical line passing through the first reference point 70.

  The vehicle model deforming unit 44F generates a vehicle planning study model by deforming the basic vehicle model in conjunction with the deformation of the outer shape image 50 in step S22 (step S24).

  The user visually recognizes the outline image 50 on the step S screen and determines whether or not to end the deformation operation (step S26). If the desired outer shape image 50 is not obtained, the process returns to step S14 to perform the deformation operation.

When the desired outer shape image 50 is obtained, the user ends the deformation operation and performs the measurement operation.
In other words, the vehicle model measurement unit 46 measures each part of the new vehicle plan review model according to the measurement operation of the user, and outputs measurement data of the new vehicle plan review model as a measurement result (step S28).
The measurement of each part is performed by operating an operation index such as a cursor or a pointer displayed on the screen of the display device 6E using a pointing device such as a mouse as the input device 6D.
For example, a measurement position as a starting point is determined by clicking with an operation index such as a cursor or a pointer positioned on the outer shape image 50 of the new vehicle plan review model.
Then, after dragging the operation indicators such as the cursor and the pointer to the measurement position as the end point, click again.
By operating in this way, the dimension from the start point to the end point is measured.
Such an operation for measuring an arbitrary portion of the image on the screen is the same as the operation when using various conventionally known application software for image processing used in CG, CAD, and the like.

  Next, the vehicle model output unit 48 outputs the data for the new vehicle plan consideration model obtained by the vehicle model deformation unit 44 (step S30).

As described above, the measurement data of the new vehicle planning examination model output from the vehicle model measurement unit 46 and the new vehicle planning examination model data output from the vehicle model output unit 48 are displayed on the screen of the display device. Alternatively, it is displayed as a print screen for evaluation.
Thus, a series of operations is completed.

Next, the case where the deformed portion selected by the deformed portion selecting step is other than the total height will be described with a focus on the operations of steps S14, S16, S18, S20, and S22, and other than steps S14, S16, S18, S20, and S22. Description of the operation of is omitted.
That is, the case where the selected deformation part is the center volume at the upper part of the body, the front slant, the rear slant, the front overhang, the rear overhang, the wheel base, the full width, the inclination of the upper part of the body, the inclination of the belt line, and the departure angle. Each will be explained.

(Center volume at the top of the body)
The case where the deformed portion selected in the deformed portion selecting step is the center volume at the upper part of the body (the height of the upper part of the body at the center in the front-rear direction) will be described with reference to FIGS.
When the deformed portion is selected in step S14, the deformed region setting unit 44B sets the region of the outline image 50 corresponding to the deformed portion on the screen as the deformed region 52 as shown in FIG. 8 (step S16). : Deformation area setting step).
Next, the guide bar display unit 44C displays the guide bar 60 on the screen (step S18: guide bar display step).
When the deformed portion selected by the deformed portion selecting step is the central volume at the upper part of the body, the guide bar 60 extends substantially parallel to the front-rear direction of the vehicle model with an interval above the outline image 50 of the vehicle model. It has the straight part 62 to do.
The first to third operation points 64, 66, 68, and the first reference point 70 are the same as those in the case where the selected deformed portion has an overall height.
Next, when the user selects and moves one of the operation points by operating the input device 6D on the screen of the display device 6E, the guide bar interlocking display unit 44D that has received this operation input displays The guide bar 60 is moved and displayed in conjunction with the movement of the operation point (step S20: guide bar interlocking display step).
When the selected change part is the center volume at the upper part of the body, the user moves the third operation point 68 forward while keeping the mouse pointer displayed on the screen positioned on the third operation point 68 and clicking. Or drag backward.
Then, the guide bar interlocking display unit 44D that has received this operation input displays the third operation point 68 by moving it back and forth between the first and second operation points 64 and 66 along the straight line portion 62.
Further, the user places the mouse pointer displayed on the screen on the third operation point 68 and maintains the clicked state, and drags the third operation point 68 upward or downward.
Then, the guide bar interlocking display unit 44D that has received this operation input moves and displays the guide bar 60 upward or downward in conjunction with the upward or downward movement of the third operating point 68.

The contour image deformation display unit 44E deforms and displays the deformation region 52 in conjunction with the movement of the guide bar 60 in step S20, thereby deforming and displaying the contour image 50 (step S22: contour image deformation display step). ).
When the selected changed portion is the center volume at the upper part of the body, as shown in FIG. 8, the deformation area 52 is deformed in conjunction with the vertical movement amount of the third operation point 68, whereby the outline image 50 is displayed. As shown by a solid line and a broken line, it is displayed by being deformed in the vertical direction.
In this case, the degree of deformation of the deformation area 52 is larger at a position closer to the third operation point 68 in the front-rear direction, and a position farther from the third operation point 68 in the front-back direction (a position closer to the first operation point 64 or the second operation point). The point closer to point 66 is smaller).
Therefore, in the state where the external image 50 of the side surface of the vehicle model is displayed on the screen, the position in the front-rear direction of the curved shape on the upper part of the vehicle model can be adjusted by moving the third operation point 68 in the front-rear direction. The amount of bending of the upper part of the vehicle model body can be adjusted by moving the operating point 68 in the vertical direction.
It is to be noted that the location of the vehicle model outer shape image 50 corresponding to the first reference point 70 is a fixed point that does not move on the screen, as in the case where the selected changed portion is full height. The vertical line passing through the first reference point 70 passes through the fixed point.

(Front slant)
Next, the case where the deformed portion selected by the deformed portion selecting step is a front slant will be described with reference to FIGS.
When the deformed portion is selected, the deformed region setting unit 44B sets the region of the outline image 50 corresponding to the deformed portion on the screen as the deformed region 52 as shown in FIG. 9 (step S16: deformed region setting). Step).
Next, the guide bar display unit 44C displays the guide bar 60 on the screen (step S18: guide bar display step).
When the deformed portion selected by the deformed portion selecting step is a front slant, the guide bar 60 includes a straight portion 62 that extends along the front-rear direction of the vehicle model with an interval above the outline image 50 of the vehicle model. Have.
The first to third operation points 64, 66, 68, and the first reference point 70 are the same as the case where the selected deformed portion is full height.
Also in this case, the location of the vehicle model outline image 50 corresponding to the first reference point 70 is a fixed point that does not move on the screen. That is, the vertical line passing through the first reference point 70 passes through the fixed point.
Next, when the user selects and moves one of the operation points by operating the input device 6D on the screen of the display device 6E, the guide bar interlocking display unit 44D that has received this operation input displays The guide bar 60 is deformed and displayed in conjunction with the movement of the operation point (step S20: guide bar interlocking display step).
When the selected change portion is a front slant, the user places the mouse pointer displayed on the screen on the first operation point 64 and keeps the clicked state, and moves the first operation point 64 upward or downward. Drag.
Then, the guide bar interlocking display unit 44D that has received this operation input fixes the portion 6204 of the straight line portion 62 from the first reference point 70 to the second operation point 68, and performs the first operation from the first reference point 70. The portion 6202 of the straight line portion 62 up to the point 64 is displayed in conjunction with the vertical movement of the first operation point 64.
That is, when the first operating point 64 is moved by the operation of the input device 6D, the guide bar 60 is deformed such that the portion 6202 of the straight line portion 62 that connects the first reference point 70 and the first operating point 64 is the first. This is done by swinging following the movement of the operating point 64.

The outline image deformation display unit 44E deforms and displays the deformation area 52 in conjunction with the deformation of the guide bar 60 in step S20, thereby deforming and displaying the outline image 50 following the swing of the guide bar 60. (Step S22: Outline image deformation display step).
That is, a portion corresponding to the portion 6202 of the straight portion 62 in the deformation region 52 of the outer shape image 50 of the vehicle model is deformed following the swinging of the portion 6202 of the straight portion 62, whereby the outer shape image 50 is changed to a solid line and a broken line. It is displayed as deformed as shown in.
In this case, the deformation of the deformation region 52 is such that the portion of the deformation region 52 corresponding to the intermediate portion of the portion 6202 of the straight portion 62 is a straight portion with respect to the portions of the deformation region 52 corresponding to both ends of the portion 6202 of the straight portion 62. 62 is a deformation that displaces in the direction of swinging following the swing of the portion 6202 of 62.
When the selected changed portion is a front slant, as shown in FIG. 9, the deformation region 52 is deformed in conjunction with the swing of the first operating point 64, and the degree of deformation is the linear portion 62 in the front-rear direction. The portion closer to the deformation region 52 corresponding to the intermediate portion of the portion 6202 is larger, and the portion closer to the deformation region 52 corresponding to both ends of the portion 6202 of the linear portion 62 in the front-rear direction is smaller.
Accordingly, by moving the first operating point 64 in the up-down direction in a state where the external image 50 of the side surface of the vehicle model is displayed on the screen, the amount of bending of the curved shape of the body front portion 5020 of the vehicle model and the front of the body The degree of inclination of the part can be adjusted.

(Rearthland)
Next, the case where the deformation part selected by the deformation part selection step is a front slant will be described with reference to FIGS.
Hereinafter, the description of steps S10 to S14 and S26 to S30 in FIG. 14 is omitted.
When the deformed portion is selected in step S14, the deformed region setting unit 44B sets the region of the outline image 50 corresponding to the deformed portion on the screen as the deformed region 52 as shown in FIG. 10 (step S16). : Deformation area setting step).
Next, the guide bar display unit 44C displays the guide bar 60 on the screen (step S18: guide bar display step).
When the deformed portion selected by the deformed portion selecting step is a rear slant, the guide bar 60 has a linear portion 62 that extends along the front-rear direction of the vehicle model with an interval above the outline image 50 of the vehicle model. is doing.
The guide bar 60 has first and second operation points 64 and 66 and a first reference point 70, and further has a movable reference point 72 instead of the third operation point 68.
The position of the movable reference point 72 on the linear portion 62 can be adjusted.
When the selected changed portion is a rear slant, the movable reference point 72 is a fixed point where the location of the outline image 50 of the vehicle model corresponding to the movable reference point 72 does not move on the screen. A vertical line passing through the movable reference point 72 passes through a fixed point.
When the selected change portion is a rear slant, the guide bar 60 is deformed by a straight line connecting the movable reference point 72 and the second operation point 66 when the second operation point 66 is moved by the operation of the input device 6D. 62 portion 6202 swings following the movement of the second operation point 66 with the movable reference point 72 as a fulcrum.
In this example, prior to step S20 (guide bar interlocking display step), the position of the movable reference point 72 on the straight line portion 62 is set (step S19: movable reference point setting step).
Specifically, when the selected changed part is a rear slant, the user moves the mouse pointer displayed on the screen on the movable reference point 72 and keeps the clicked state, and moves the movable reference point 72 forward or Drag backward.
Then, the guide bar interlocking display unit 44D that has received this operation input moves the movable reference point 72 back and forth along the straight line unit 62 and displays it.
Thereby, the position in the front-rear direction of the fixed point of the outline image 50 of the vehicle model is set.

Next, when the user selects and moves one of the operation points by operating the input device 6D on the screen of the display device 6E, the guide bar interlocking display unit 44D that has received this operation input displays The guide bar 60 is deformed and displayed in conjunction with the movement of the operation point (step S20: guide bar interlocking display step).
When the selected change portion is a rear slant, the user moves the mouse pointer displayed on the screen on the second operation point 66 and keeps the clicked state, and drags the second operation point 66 upward or downward. To do.
Then, the guide bar interlocking display unit 44D that has received this operation input fixes the portion 6204 of the straight line portion 62 from the movable reference point 72 to the first operation point 64, and the second operation point 66 from the movable reference point 72. The portion 6202 of the straight line portion 62 is swung following the up / down movement of the second operating point 66.

The outline image deformation display unit 44E deforms and displays the deformation area 52 in conjunction with the deformation of the guide bar 60 in step S20, thereby deforming and displaying the outline image 50 following the swing of the guide bar 60. (Step S22: Outline image deformation display step).
That is, a portion corresponding to the portion 6202 of the straight portion 62 in the deformation region 52 of the outer shape image 50 of the vehicle model is deformed following the swinging of the portion 6202 of the straight portion 62, whereby the outer shape image 50 is changed to a solid line and a broken line. It is displayed as deformed as shown in.
In this case, the deformation of the deformation region 52 is such that the portion of the deformation region 52 corresponding to the intermediate portion of the portion 6202 of the straight portion 62 is a straight portion with respect to the portions of the deformation region 52 corresponding to both ends of the portion 6202 of the straight portion 62. 62 is a deformation that displaces in the direction of swinging following the swing of the portion 6202 of 62.
When the selected change portion is a rear slant, as shown in FIG. 10, the deformation region 52 is deformed in conjunction with the swing of the second operation point 66. The portion closer to the deformation region 52 corresponding to the middle portion of the portion 6202 is larger, and the portion closer to the deformation region 52 corresponding to both ends of the portion 6202 of the linear portion 62 in the front-rear direction is smaller.
Accordingly, by moving the second operation point 66 in the vertical direction in the state where the external image 50 of the side surface of the vehicle model is displayed on the screen, the amount of bending of the curved shape of the body rear portion 5022 of the vehicle model, and the body rear portion 5022 The degree of inclination can be adjusted.
In this case, the fixed point of the outer shape image 50 corresponding to the movable reference point 72 is the curve of the body rear portion 5022 when adjusting the amount of curve of the vehicle body rear portion 5022 and the degree of inclination of the body rear portion 5022. It becomes an inflection point where the amount of curve and the degree of inclination of the shape do not change. In other words, the movable reference point 72 functions as a point that determines an inflection point.

(Front overhang)
Next, a case where the deformed portion selected in the deformed portion selecting step is a front overhang will be described with reference to FIGS.
When the deformed portion is selected in step S14, the deformed region setting unit 44B sets the region of the outline image 50 corresponding to the deformed portion on the screen as the deformed region 52 as shown in FIG. 11 (step S16: Deformation area setting step).
Next, the guide bar display unit 44C displays the guide bar 60 on the screen (step S18: guide bar display step).
When the deformed portion selected by the deformed portion selecting step is a front overhang, the guide bar 60 has a linear portion 62 that extends along the front-rear direction of the vehicle model with an interval above the outline image 50 of the vehicle model. have.
The guide bar 60 has first to third operation points 64, 66, 68 and a first reference point 70.
The first reference point 70 is a fixed point that does not move on the screen at the location of the vehicle model outline image 50 corresponding to the first reference point 70. The vertical line passing through the first reference point 70 passes through the fixed point. In the example of FIG. 11, the vertical line passing through the first reference point 70 passes through the center point 5012 of the front wheel 5010.
Next, when the user selects and moves one of the operation points by operating the input device 6D on the screen of the display device 6E, the guide bar interlocking display unit 44D that has received this operation input displays The guide bar 60 is deformed and displayed in conjunction with the movement of the operation point (step S20: guide bar interlocking display step).
When the selected change portion is a front overhang, the user moves the first operation point 64 forward or backward while keeping the mouse pointer displayed on the screen positioned on the first operation point 64 and clicking. Drag to.
Then, the guide bar interlocking display unit 44D that has received this operation input fixes the portion 6204 of the straight line portion 62 from the first reference point 70 to the second operation point 66, and also sets the first operation point 64 to the straight line portion 62. And move back and forth along the display. At this time, the portion 6202 of the straight line portion 62 connecting the first operation point 64 and the first reference point 70 is expanded and contracted (deformed) in conjunction with the movement of the first operation point 64.
That is, the guide bar deformation 60 is the first reference point when the first operation point 64 is moved on the guide bar 60 or on the extension line of the guide bar 60 by the operation of the input device 6D. The portion 6202 of the straight line portion 62 connecting 70 and the first operation point 64 is expanded and contracted following the movement of the first operation point 64.

The outline image deformation display unit 44E deforms and displays the deformation area 52 in conjunction with the deformation of the guide bar 60 in step S20, thereby displaying the outline image 50 by expanding and contracting following the expansion and contraction of the guide bar 60. (Step S22: Outline image deformation display step).
That is, a portion corresponding to the portion 6202 of the straight portion 62 in the deformation area 52 of the outer shape image 50 of the vehicle model expands and contracts following the expansion and contraction of the portion 6202 of the straight portion 62, whereby the outer shape image 50 is represented by a solid line and a broken line. As shown, it is transformed and displayed.
When the selected change portion is a front overhang, as shown in FIG. 11, the deformation area 52 is deformed in conjunction with the amount of movement of the first operating point 64 in the front-rear direction. In FIG. 2, the position closer to the first operation point 64 is larger, and the position farther from the first operation point 64 in the front-rear direction (the position closer to the first reference point 70) is smaller.
Therefore, in the state where the external image 50 of the side surface of the vehicle model is displayed on the screen, the dimension in the front-rear direction (from the first reference point 70) of the body front portion 5020 of the vehicle model is moved by moving the first operation point 64 in the front-rear direction. The dimension up to the front end of the body front 5050 can be adjusted.
In this case, the front wheel 5010 does not move.

(Rear overhang)
Next, the case where the deformed portion selected in the deformed portion selecting step is a rear overhang will be described with reference to FIGS.
When the deformed part is selected in step S14, the deformed area setting unit 44B sets the area of the outline image 50 corresponding to the deformed part on the screen as the deformed area 52 as shown in FIG. 12 (step S16: Deformation area setting step).
Next, the guide bar display unit 44C displays the guide bar 60 on the screen (step S18: guide bar display step).
When the deformed portion selected by the deformed portion selecting step is a rear overhang, the guide bar 60 has a linear portion 62 extending along the front-rear direction of the vehicle model with an interval above the outer image 50 of the vehicle model. have.
The guide bar 60 includes first and second operation points 64 and 66, a first reference point 70, and a movable reference point 72, as in the case where the selected change portion is a rear slant.
The position of the movable reference point 72 on the linear portion 62 can be adjusted.
When the selected changed portion is a rear overhang, the movable reference point 72 is a fixed point where the location of the outline image 50 of the vehicle model corresponding to the movable reference point 72 does not move on the screen. A vertical line passing through the movable reference point 72 passes through a fixed point.
When the selected change portion is a rear overhang, the guide bar 60 is deformed when the second operation point 66 moves and the portion 6202 of the straight line portion 62 connecting the movable reference point 72 and the second operation point 66 is changed. This is done by following the movement of the second operating point 66.
In this example, prior to step S20 (guide bar interlocking display step), the position of the movable reference point 72 on the straight line portion 62 is set (step S19: movable reference point setting step).
Specifically, when the selected change part is a rear overhang, the user moves the mouse pointer displayed on the screen on the movable reference point 72 and keeps the clicked state, and moves the movable reference point 72. Drag forward or backward.
Then, the guide bar interlocking display unit 44D that has received this operation input moves the movable reference point 72 back and forth along the straight line unit 62 and displays it.
Thereby, the position in the front-rear direction of the fixed point of the outline image 50 of the vehicle model is set.
In the example of FIG. 12, the movable reference point 72 is located on a vertical line passing through the center point of the rear wheel 5030.

Next, when the user selects and moves one of the operation points by operating the input device 6D on the screen of the display device 6E, the guide bar interlocking display unit 44D that has received this operation input displays The guide bar 60 is moved or deformed and displayed in conjunction with the movement of the operation point (step S20: guide bar linked display step).
The user places the mouse pointer displayed on the screen on the second operation point 66 and maintains the clicked state, and drags the second operation point 66 forward or backward.
Then, the guide bar interlocking display unit 44D that has received this operation input fixes the portion 6204 of the straight line portion 62 from the first operation point 64 to the movable reference point 72, and the second operation point 66 to the straight line portion 62. Move back and forth along the display. At this time, the portion 6202 of the straight line portion 62 that connects the movable reference point 72 and the second operation point 66 is expanded and deformed (deformed) in conjunction with the movement of the second operation point 66.
That is, the guide bar deformation 60 is performed when the second operation point 66 is moved on the guide bar 60 or on an extension line of the guide bar 60 by the operation of the input device 6D. This is done by expanding and contracting the portion 6202 of the straight line portion 62 connecting with the second operating point 66 following the movement of the second operating point 66.

The outline image deformation display unit 44E deforms and displays the deformation area 52 in conjunction with the deformation of the guide bar 60 in step S20, thereby displaying the outline image 50 by expanding and contracting following the expansion and contraction of the guide bar 60. (Step S22: Outline image deformation display step).
That is, a portion corresponding to the portion 6202 of the straight portion 62 in the deformation area 52 of the outer shape image 50 of the vehicle model expands and contracts following the expansion and contraction of the portion 6202 of the straight portion 62, whereby the outer shape image 50 is represented by a solid line and a broken line. As shown, it is transformed and displayed.
When the selected change portion is a rear overhang, as shown in FIG. 12, the deformation area 52 is deformed in conjunction with the amount of movement of the second operation point 66 in the front-rear direction. In FIG. 3, the position is closer to the second operation point 66 and is smaller in the front-rear direction than the second operation point 68 (the position closer to the third operation point 68).
Therefore, in the state in which the outer shape image 50 of the side surface of the vehicle model is displayed on the screen, the front and rear dimensions (from the first reference point 70 to the body) of the rear part 5022 of the vehicle model are moved by moving the second operation point 66 in the front and rear direction. The dimension up to the rear end of the rear portion 5022 can be adjusted.
In this case, the rear wheel 5030 and the center point 5032 of the rear wheel 5030 do not move.

(Wheelbase)
Next, the case where the deformation part selected by the deformation part selection step is a wheel base will be described with reference to FIGS.
When the deformed part is selected in step S14, the deformed area setting unit 44B sets the area of the outline image 50 corresponding to the deformed part on the screen as the deformed area 52 as shown in FIG. 13 (step S16: Deformation area setting step).
Next, the guide bar display unit 44C displays the guide bar 60 on the screen (step S18: guide bar display step).
When the deformed portion selected by the deformed portion selecting step is a wheel base, the guide bar 60 includes a straight portion 62 that extends along the front-rear direction of the vehicle model with an interval above the outline image 50 of the vehicle model. Have.
The guide bar 60 includes first and second operation points 64 and 66, a first reference point 70, and a movable reference point 72, as in the case where the selected change portion is a rear overhang.
The position of the movable reference point 72 on the linear portion 62 can be adjusted.
When the selected changed portion is a rear overhang, the movable reference point 72 is a fixed point where the location of the outline image 50 of the vehicle model corresponding to the movable reference point 72 does not move on the screen. A vertical line passing through the movable reference point 72 passes through a fixed point.
When the selected change portion is a wheel base, the deformation of the guide bar 60 is such that when the second operation point 66 moves, the portion 6202 of the linear portion 62 connecting the movable reference point 72 and the second operation point 66 is the first. This is done by following the movement of the two operating points 66.
In this example, prior to step S20 (guide bar interlocking display step), the position of the movable reference point 72 on the straight line portion 62 is set (step S19: movable reference point setting step).
Specifically, when the selected change portion is a wheel base, the user moves the reference point 72 forward while keeping the mouse pointer displayed on the screen positioned on the reference point 72 and clicking. Or drag backward.
Then, the guide bar interlocking display unit 44D that has received this operation input moves the movable reference point 72 back and forth along the straight line unit 62 and displays it.
Thereby, the position in the front-rear direction of the fixed point of the outline image 50 of the vehicle model is set.
In the example of FIG. 13, the movable reference point 72 is located between the center point of the front wheel 5010 and the center point of the rear wheel 5030 in the front-rear direction.

Next, when the user selects and moves one of the operation points by operating the input device 6D on the screen of the display device 6E, the guide bar interlocking display unit 44D that has received this operation input displays The guide bar 60 is moved or deformed and displayed in conjunction with the movement of the operation point (step S20: guide bar linked display step).
The user places the mouse pointer displayed on the screen on the second operation point 66 and maintains the clicked state, and drags the second operation point 66 forward or backward.
Then, the guide bar interlocking display unit 44D that has received this operation input fixes the portion 6204 of the straight line portion 62 from the first operation point 64 to the movable reference point 72, and the second operation point 66 to the straight line portion 62. Move back and forth along the display. At this time, the portion 6202 of the straight line portion 62 that connects the movable reference point 72 and the second operation point 66 is expanded and deformed (deformed) in conjunction with the movement of the second operation point 66.
That is, the guide bar deformation 60 is performed when the second operation point 66 is moved on the guide bar 60 or on an extension line of the guide bar 60 by the operation of the input device 6D. The portion of the straight line portion 62 that connects the two points is expanded and contracted following the movement of the second operation point 66.

The outline image deformation display unit 44E deforms and displays the deformation area 52 in conjunction with the deformation of the guide bar 60 in step S20, thereby displaying the outline image 50 by expanding and contracting following the expansion and contraction of the guide bar 60. (Step S22: Outline image deformation display step).
That is, a portion corresponding to the portion 6202 of the straight portion 62 in the deformation area 52 of the outer shape image 50 of the vehicle model expands and contracts following the expansion and contraction of the portion 6202 of the straight portion 62, whereby the outer shape image 50 is represented by a solid line and a broken line. As shown, it is transformed and displayed.
When the selected changed portion is a wheel base, as shown in FIG. 13, the deformation region 52 is deformed in conjunction with the amount of movement of the second operation point 66 in the front-rear direction. The portion closer to the second operation point 66 is larger, and the portion farther from the second operation point 68 in the front-rear direction (the portion closer to the third operation point 68) is smaller.
Accordingly, the vehicle model wheelbase (the center point 5012 of the front wheel 5010 and the center point of the rear wheel 5030) can be obtained by moving the second operation point 66 in the front-rear direction in a state in which the outline image 50 of the side surface of the vehicle model is displayed on the screen. 5032) is adjusted in conjunction with the second operating point 66, and the dimension from the front end of the body front portion 5020 to the rear end of the body rear portion 5022 of the vehicle model is adjusted in conjunction with the second operating point 66. .

(Full width)
Next, the case where the deformed portion selected by the deformed portion selecting step has the full width will be described with reference to FIGS.
When the deformed portion is selected in step S14, the deformed region setting unit 44B displays the front of the vehicle model on the screen as the outer shape image 50 as shown in FIG.

  When the deformed portion is selected, the deformed region setting unit 44B sets the region of the outline image 50 corresponding to the deformed portion on the screen as the deformed region 52 as shown in FIG. 16 (step S16: deformed region setting). Step).

Next, the guide bar display unit 44C displays the guide bar 60 on the screen (step S18: guide bar display step).
When the deformed portion selected by the deformed portion selecting step has a full width, as shown in FIG. 14, the guide bar 60 is parallel to the vertical direction of the vehicle model at intervals on the left and right sides of the vehicle model outer shape image 50. It has the linear part 62 extended in the direction to do.
On the straight line portion 62, a fourth operation point 74, a fifth operation point 76, a sixth operation point 78, and a second reference point 80 are displayed as three operation points.
The fourth operation point 74 is an operation point displayed at a position corresponding to the upper end position of the outer shape image 50 in the vertical direction of the vehicle model.
The fifth operation point 76 is an operation point displayed at a location corresponding to the lower end position of the outline image 50 in the vertical direction of the vehicle model, in this embodiment, at a location corresponding to the lower end position of the body.
The sixth operation point 78 is an operation point displayed at an intermediate position between the fourth operation point 74 and the fifth operation point 76 in the vertical direction of the vehicle model.
The second reference point 80 is a point at which the location of the vehicle model outline image 50 corresponding to the second reference point 80 does not move on the screen when the vehicle model outline image 50 is deformed. . That is, the horizontal line passing through the second reference point 80 passes through the fixed point.
As shown in FIG. 15, in the state in which the external image 50 in front of the vehicle model is displayed on the screen, the second reference point 80 intersects the outer plate portion constituting the hood 5002 of the vehicle model and the windshield 5004. It is located on a horizontal line that passes through the front deck FD.

Next, when the user selects and moves one of the operation points by operating the input device 6D on the screen of the display device 6E, the guide bar interlocking display unit 44D that has received this operation input displays The guide bar 60 is moved and displayed in conjunction with the movement of the operation point (step S20: guide bar interlocking display step).
When the selected changed part is full width, the user keeps the mouse pointer displayed on the screen on the sixth operation point 78 and clicks it, and the sixth operation point 78 is displayed as an outline image of the vehicle model. Drag 50 inwards in the width direction or outward in the width direction. Then, the guide bar interlocking display unit 44D that has received this operation input moves and displays the guide bar 60 in the width direction inward or the width direction outward in conjunction with the movement of the sixth operation point 78. At this time, the guide bar 60 moves in parallel.

The outline image deformation display unit 44E deforms and displays the deformation area 52 in conjunction with the movement of the guide bar 60 in step S20, thereby deforming and displaying the outline image 50 (step S22: outline image deformation display step). ).
When the selected changed portion is full width, as shown in FIG. 16, the deformation region 52 is expanded and contracted in the width direction in conjunction with the movement of the guide bar 60 in the width direction inward or width direction outward, Accordingly, the outer shape image 50 is displayed by being deformed in the width direction as indicated by a solid line and a broken line.

(Inclination at the top of the body)
Next, the case where the deformed portion selected in the deformed portion selecting step is the inclination of the upper part of the body will be described with reference to FIGS.
When the deformed portion is selected in step S14, the deformed region setting unit 44B displays an outline image 50 in front of the vehicle model on the screen as shown in FIG.

  When the deformed portion is selected, the deformed region setting unit 44B sets the region of the outline image 50 corresponding to the deformed portion on the screen as the deformed region 52 as shown in FIG. 17 (step S16: deformed region setting). Step).

Next, the guide bar display unit 44C displays the guide bar 60 on the screen (step S18: guide bar display step).
When the deformed portion selected by the deformed portion selecting step is the inclination of the upper part of the body, as shown in FIG. 17, the guide bar 60 is arranged in the vertical direction of the vehicle model with an interval to the side of the outer image 50 of the vehicle model. And a straight line portion 62 extending in parallel with each other.
On the straight line portion 62, the fourth operation point 74, the fifth operation point 76, the sixth operation point 78, and the second reference point 80 are displayed as in the case where the selected deformed portion has the full width.
Also in this case, the location of the vehicle model outline image 50 corresponding to the second reference point 80 is a fixed point that does not move on the screen. That is, the horizontal line passing through the second reference point 80 passes through the fixed point.

Next, when the user selects and moves one of the operation points by operating the input device 6D on the screen of the display device 6E, the guide bar interlocking display unit 44D that has received this operation input displays The guide bar 60 is deformed and displayed in conjunction with the movement of the operation point (step S20: guide bar interlocking display step).
When the selected change part is the inclination of the upper part of the body, the user keeps the mouse pointer displayed on the screen on the fourth operation point 74 and clicks it, and the fourth operation point 74 is kept in the vehicle model. Is dragged inward in the width direction or outward in the width direction.
Then, the guide bar interlocking display unit 44D that has received this operation input fixes the portion 6212 of the straight line portion 62 from the fifth operation point 76 to the second reference point 80, and performs the fourth operation from the second reference point 80. The portion 6210 of the straight line portion 62 up to the point 74 is displayed in conjunction with the movement of the fourth operation point 74 in the width direction.
That is, when the fourth operation point 74 is moved by the operation of the input device 6D, the guide bar 60 is deformed so that the portion of the straight line portion 62 that connects the second reference point 80 and the fourth operation point 74 is the second. This is done by swinging following the movement of the fourth operating point 74 with the reference point 80 as a fulcrum.

The outline image deformation display unit 44E deforms and displays the deformation area 52 in conjunction with the deformation of the guide bar 60 in step S20, thereby deforming and displaying the outline image 50 following the swing of the guide bar 60. (Step S22: Outline image deformation display step).
That is, a portion corresponding to the portion 6210 of the straight portion 62 in the deformation region 52 of the contour image 50 of the vehicle model is deformed following the swinging of the portion 6210 of the straight portion 62, whereby the contour image 50 is changed to a solid line and a broken line. It is displayed as deformed as shown in.
In the case where the selected changed portion is an inclination of the upper part of the body, as shown in FIG. 17, the deformation area 52 is deformed in conjunction with the movement amount of the fourth operation point 74 in the width direction. Is larger at a location closer to the fourth operation point 74 in the vertical direction and smaller at a location farther from the fourth operation point 74 in the vertical direction.
Therefore, the inclination degree (aperture degree) of the upper body 5050 can be adjusted by moving the fourth operation point 74 in the width direction in a state where the outline image 50 in front of the vehicle model is displayed on the screen.

(Departure angle)
Next, a case where the deformed portion selected in the deformed portion selecting step is a departure angle will be described with reference to FIGS.
When the deformed part is selected in step S14, the deformed region setting unit 44B displays the outline image 50 of the side surface of the vehicle model on the screen as shown in FIG.
As shown in FIG. 18, the deformation area setting unit 44B sets an area of the outline image 50 corresponding to the deformation portion on the screen as a deformation area 52 (step S16: deformation area setting step).

Next, the guide bar display unit 44C displays the guide bar 60 on the screen (step S18: guide bar display step).
When the deformed portion selected by the deformed portion selecting step is a departure angle, as shown in FIG. 18, the guide bar 60 is in a direction parallel to the lower edge 5060 of the vehicle model body located behind the rear wheel 5030. It has a linear portion 62 that extends.
In the straight line portion 62, a seventh operation point 82 and a third reference point 84 are displayed.
The seventh operation point 82 is located at the rear end of the linear portion 62.
The third reference point 84 is a location where a vertical line passing through the front end of the lower edge 5060 and the straight portion 62 of the guide bar 60 intersect.
The location of the vehicle model outline image 50 corresponding to the third reference point 84 is a fixed point that does not move on the screen, and the fixed point is the front end location of the lower edge 5060 of the vehicle model body.

Next, when the user selects and moves one of the operation points by operating the input device 6D on the screen of the display device 6E, the guide bar interlocking display unit 44D that has received this operation input displays The guide bar 60 is deformed and displayed in conjunction with the movement of the operation point (step S20: guide bar interlocking display step).
When the selected change portion is a departure angle, the user keeps the mouse pointer displayed on the screen on the seventh operation point 82 and keeps the clicked state, and moves the seventh operation point 82 upward or downward. Drag to.
When this operation input is received, the guide bar interlocking display unit 44D swings the portion of the straight line portion 62 from the third reference point 84 to the seventh operation point 82 following the up and down movement of the seventh operation point 82. Move.
That is, when the seventh operation point 82 is moved by the operation of the input device 6D, the guide bar 60 is deformed so that the portion of the straight line portion 62 that connects the third reference point 84 and the seventh operation point 82 is the third. This is done by swinging following the movement of the seventh operation point 82 with the reference point 84 as a fulcrum.

The outline image deformation display unit 44E deforms and displays the deformation area 52 in conjunction with the deformation of the guide bar 60 in step S20, thereby deforming and displaying the outline image 50 following the swing of the guide bar 60. (Step S22: Outline image deformation display step).
That is, a portion of the deformation area 52 of the outer shape image 50 of the vehicle model corresponding to the portion of the straight portion 62 is deformed following the swing of the portion of the straight portion 62 of the guide bar 60, whereby the outer shape image 50 is changed. As shown by the solid line and the broken line, the display is transformed.
When the selected changed portion is a departure angle, as shown in FIG. 18, the deformation area 52 is deformed in conjunction with the vertical movement amount of the seventh operation point 82, but the degree of deformation is the front-rear direction. In FIG. 4, the portion closer to the seventh operation point 82 is larger, and the portion farther from the seventh operation point 82 in the front-rear direction is smaller.
Therefore, the departure angle can be adjusted by moving the seventh operation point 82 in the vertical direction in a state in which the outer shape image 50 of the side surface of the vehicle model is displayed on the screen.

(Belt line)
Next, the case where the deformed portion selected in the deformed portion selecting step is the inclination of the belt line will be described with reference to FIGS.
When the deformed portion is selected in step S14, the deformed region setting unit 44B displays the outline image 50 of the side surface of the vehicle model on the screen as shown in FIG.
As shown in FIG. 19, the deformation area setting unit 44B sets the area of the outline image 50 corresponding to the deformation portion on the screen as the deformation area 52 (step S16: deformation area setting step).

Next, the guide bar display unit 44C displays the guide bar 60 on the screen (step S18: guide bar display step).
When the deformed portion selected by the deformed portion selecting step is the inclination of the belt line, as shown in FIG. 19, the guide bar 60 is a straight line portion 62 extending along the belt line 5070 of the vehicle model outer shape image 50. The front end of the straight line portion 62 (guide bar 60) and the front end of the belt line 5070 coincide with each other.
On the straight line portion 62, an eighth operation point 86 and a fourth reference point 88 are displayed.
The eighth operation point 86 is an operation point displayed at the rear end of the guide bar 60.
The fourth reference point 88 is the front end of the guide bar 60.
The part of the vehicle model outer shape image 50 corresponding to the fourth reference point 88 is a fixed point that does not move on the screen, and the fixed point is the front end part of the belt line 5070.

Next, when the user selects and moves one of the operation points by operating the input device 6D on the screen of the display device 6E, the guide bar interlocking display unit 44D that has received this operation input displays The guide bar 60 is deformed and displayed in conjunction with the movement of the operation point (step S20: guide bar interlocking display step).
When the selected change portion is an inclination of the belt line, the user keeps the mouse pointer displayed on the screen on the eighth operation point 86 and clicks it, and moves the eighth operation point 86 upward or Drag down.
Then, the guide bar interlocking display unit 44D that has received this operation input shakes the portion of the straight line portion 62 from the fourth reference point 88 to the eighth operation point 86 following the vertical movement of the eighth operation point 86. Move.
That is, when the eighth operation point 86 is moved by the operation of the input device 6D, the guide bar 60 is deformed so that the portion of the straight line portion 62 that connects the fourth reference point 88 and the eighth operation point 86 is the fourth. This is done by swinging following the movement of the eighth operating point 86 with the reference point 88 as a fulcrum.

The outline image deformation display unit 44E deforms and displays the deformation area 52 in conjunction with the deformation of the guide bar 60 in step S20, thereby deforming and displaying the outline image 50 following the swing of the guide bar 60. (Step S22: Outline image deformation display step).
That is, a portion of the deformation area 52 of the outer shape image 50 of the vehicle model corresponding to the portion of the straight portion 62 is deformed following the swing of the portion of the straight portion 62 of the guide bar 60, whereby the outer shape image 50 is changed. Deformed and displayed.
When the selected changed portion is the inclination of the belt line, as shown in FIG. 19, the deformation region 52 is deformed in conjunction with the vertical movement amount of the eighth operation point 86, but the degree of deformation is The portion closer to the eighth operation point 86 in the direction is larger, and the portion farther from the eighth operation point 86 in the front-rear direction is smaller.
Therefore, the inclination of the belt line can be adjusted by moving the eighth operation point 86 in the up-down direction in a state in which the outer shape image 50 of the side surface of the vehicle model is displayed on the screen.

According to the present embodiment, after setting the deformation area 52 corresponding to the deformation portion to be deformed in the outline image 50 of the vehicle model, the guide bar 60 displayed on the screen is moved by the input device 6D. Since the outer shape image 50 is deformed and displayed by the operation, it is advantageous to perform the deformation operation of the outer shape image 50 finely and efficiently for each portion.
In particular, since the guide bar 60 displayed on the screen can be easily and reliably operated, it is advantageous in facilitating the operation of deforming the external image of the vehicle model by reflecting a desired image considered by the user. .
Therefore, for example, when creating an image of the external shape of a vehicle model when planning a new vehicle, the external shape of the vehicle model is deformed based on the external shape of the existing vehicle with a simple operation in a short time. It is extremely advantageous to accurately realize such a request.
In particular, when the degree of freedom of deformation of the external image of the vehicle model is too large as in the prior art, it is impossible to efficiently perform detailed operation for each part, and it cannot be said that the operability is excellent. Although there is a disadvantage, the present invention is remarkably advantageous in finely and efficiently deforming the outline image.

In the embodiment, the guideline 60 is displayed at a location on the screen away from the external image 50 of the vehicle model, except when the deformed portion selected in the deformed portion selecting step is a belt line. explained.
However, it is a matter of course that the guideline 60 may be displayed so as to overlap the vehicle model outer shape image 50.
However, it is advantageous to display the guideline 60 at a location on the screen that is distant from the external image 50 of the vehicle model because the guideline 60 is easy to see and the operability is improved.

  Further, in the present embodiment, the case has been described in which the external image 50 of the vehicle model deformed by the operation of the guideline 60 is a two-dimensional shape drawn on a plane, but the vehicle model deformed by the operation of the guideline 60 Of course, the outer shape image 50 may be a three-dimensional shape drawn in a three-dimensional space.

  In the present embodiment, the case where the vehicle is a passenger car has been described. However, the vehicle to which the method of the present invention is applied is not limited to a passenger car, and can be applied to various conventionally known work vehicles and building vehicles. is there.

  50 …… Outer image, 52 …… Deformation region, 60 …… Guide bar, S14 …… Deformation part selection step, S16 …… Deformation region setting step, S18 …… Guide bar display step, S20 …… Guide bar interlocking display step , S22... Outline image deformation display step.

Claims (11)

A vehicle model deformation display method for displaying an external image of a vehicle model on a screen of a display device and deforming the external image of the vehicle model according to an operation of an input device,
A deformed portion selecting step of selecting a deformed portion to be deformed from the outer shape image of the vehicle model;
A deformation area setting step for setting an area of the outline image corresponding to the deformation portion on the screen as a deformation area;
A guide bar display step of displaying a guide bar including a straight line portion extending in a straight line and at least one operation point formed in the straight line portion on the screen in association with the deformation region;
In the screen, the operation point is selected and moved by operation of the input device, thereby moving or deforming the guide bar in conjunction with the movement of the operation point, and displaying the guide bar interlocking display step;
An outline image deformation display step for displaying an outline image of the vehicle model in which the deformation area is deformed in conjunction with movement or deformation of the guide bar;
A vehicle model deformation display method including: The guide bar has one or more reference points formed on the straight portion,
The location of the outline image of the vehicle model corresponding to the reference point is a fixed point that does not move on the screen when the outline image deformation step is executed.
The vehicle model deformation display method according to claim 1. When the operation point is moved by operating the input device, the guide bar is deformed so that the portion of the straight line portion connecting the reference point and the operation point moves the operation point with the reference point as a fulcrum. Is made by swinging to follow,
The deformation of the deformation region is a deformation in which the portion of the deformation region corresponding to the portion of the straight portion swings following the swing of the portion of the straight portion.
The vehicle model deformation display method according to claim 2. When the operation point is moved by operating the input device, the guide bar is deformed so that the portion of the straight line portion connecting the reference point and the operation point moves the operation point with the reference point as a fulcrum. Is made by swinging to follow,
The deformation of the deformation area is such that the position of the deformation area corresponding to an intermediate portion of the straight line portion is a fluctuation of the portion of the straight line portion with respect to the position of the deformation area corresponding to both ends of the straight line portion. It is a deformation that displaces in the swinging direction following the movement,
The vehicle model deformation display method according to claim 2 or 3. The deformation of the guide bar is a portion of the straight line portion that connects the reference point and the operation point when the operation point is moved on the guide bar or an extended line of the guide bar by the operation of the input device. Is made by expanding and contracting following the movement of the operation point with respect to the reference point,
The deformation of the deformation region is a deformation in which the portion of the deformation region corresponding to the portion of the linear portion expands and contracts following the expansion and contraction of the portion of the linear portion.
The vehicle model deformation display method according to any one of claims 2 to 4. The reference point includes a movable reference point whose position on the straight line portion is adjustable,
Prior to the guide bar interlocking display step, a movable reference point setting step for setting a position of the movable reference point on the straight line portion is performed.
The vehicle model deformation display method according to claim 3 or 5. When the side surface of the vehicle model is displayed on the screen, and the guide bar is displayed in the direction parallel to the front-rear direction of the vehicle model by the guide bar display step, the reference point is Including a first reference point that is a location where a vertical line passing through a location where the outer plate portion constituting the bonnet of the vehicle model and the windshield intersect, and a straight portion of the guide bar,
The fixed point is a location where an outer plate portion and a windshield that constitute a bonnet of the vehicle model intersect.
The vehicle model deformation display method according to any one of claims 2 to 6. When the front of the vehicle model is displayed on the screen and the guide bar is displayed in the direction parallel to the vertical direction of the vehicle model by the guide bar display step, the reference point is Including a second reference point that is a location where a horizontal line passing through a location where the outer plate portion constituting the bonnet of the vehicle model and the windshield intersect, and a straight portion of the guide bar intersect,
The fixed point is a location where an outer plate portion and a windshield that constitute a bonnet of the vehicle model intersect.
The vehicle model deformation display method according to any one of claims 2 to 6. A side surface of the vehicle model is displayed on the screen, and the guide bar is displayed by the guide bar display step so as to extend in a direction parallel to the lower edge of the vehicle model body located behind the rear wheel. In addition, the reference point includes a third reference point that is a location where a vertical line passing through the front end of the lower edge and a straight portion of the guide bar intersect,
The fixed point is a front end portion of a lower edge of the body of the vehicle model.
The vehicle model deformation display method according to any one of claims 2 to 6. The guide bar is displayed on the screen at a location distant from the external image of the vehicle model,
The vehicle model deformation display method according to any one of claims 1 to 9. A side surface of the vehicle model is displayed on the screen, and the guide bar display step displays the guide bar extending along the belt line of the vehicle model so that the front end of the guide bar coincides with the front end of the belt line. The reference point includes a fourth reference point that is a front end of the guide bar,
The fixing point is a front end portion of the belt line.
The vehicle model deformation display method according to any one of claims 2 to 6.

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