JPWO2010110053A1 - Pleated product wearing simulation apparatus, simulation method, and simulation program - Google Patents

Abstract

Set the wrapping position and direction for the parts on the pattern data of the pleated product, deform the parts based on the wrapping position and direction, and place the deformed parts around the model body The wearing state is simulated based on at least the friction with the body and the gravity and elastic force acting on the part. The parts of the pleated product can be easily positioned with respect to the human body model, and the wearing simulation can be executed with high accuracy in a short time.

Description

  The present invention relates to a wearing simulation of a pleated product such as a skirt.

  The inventors are developing a simulation technique for the clothing wearing state. For example, in Patent Document 1: WO2008 / 016027A, a rough polygon is used in the first half of the simulation and divided into fine polygons in the second half to shorten the simulation time. Proposed to do.

  The inventor has examined a wearing simulation of a pleated product such as a skirt, a dress, and a blouse, that is, a garment that uses folding as a design element, which has not been studied so far. Pleated products have folds and folds. For example, if a cloth with a shape cut according to the design data is placed around the human body model, and the folds are folded to provide folds, it takes a lot of time to process so far. become. Since the pleated product has a larger perimeter than the perimeter of the human body model due to folding, it is difficult to position the cloth in a cylindrical shape around the human body model. In addition, it is natural to manually specify the folding position, and it is necessary to manually specify a number of folding positions and move the cloth partially with respect to the human body model to provide folding. It ’s also hard work.

WO2008 / 016027A

  An object of the present invention is to make it possible to easily position a part of a pleated product with respect to a human body model and to perform a wearing simulation with high accuracy in a short time.

The pleated product wearing simulation apparatus of the present invention is an apparatus for simulating the wearing state of a pleated product,
Folding information setting means for setting the position and direction of folding on the parts on the pattern data of the pleated product,
A deformation means for deforming the part based on the position and direction of the folding;
Placement means for placing the deformed parts around the model body;
A simulation means for simulating the wearing state is provided for the arranged parts based on at least friction with the body and gravity and elastic force acting on the parts.

The pleated product wearing simulation method of the present invention is a method for simulating the wearing state of a pleated product,
While performing the folding information setting step for setting the position and direction of folding on the parts on the pattern data of the pleated product,
On the computer,
A deformation step for deforming the part based on the position and direction of the folding;
A placement step to place the deformed parts around the body of the model;
A simulation step for simulating the wearing state is performed on the arranged parts based on at least friction with the body and gravity and elastic force acting on the parts.

In addition, the pleated product wearing simulation program of the present invention simulates the pleated product wearing state.
Computer
Folding information setting means for setting the position and direction of folding on the parts on the pattern data of the pleated product,
A deformation means for deforming the part based on the position and direction of the folding;
Placement means for placing the deformed parts around the model body;
The arranged parts are caused to function as simulation means for simulating the wearing state based on at least friction with the body and gravity and elastic force acting on the parts.

In this specification, the description relating to the pattern data creating apparatus also applies to the pattern data creating method and creating program as it is, and the description relating to the pattern data creating method also applies to the pattern data creating apparatus and creating program.
In this invention, the parts of the pleated product are deformed in advance based on the position and direction of the folding, and are placed around the body of a human body model, animal model, etc. Also, the arrangement is easy. Since the parts are deformed in advance before the simulation, it is not necessary to fold the arranged parts, and the wearing state can be simulated with high accuracy in a short time.

Preferably, the deforming means divides the parts into a plurality of sub-parts so that the parts can be moved apart from each other at the folding position, for example, freely movable to each other.
The arrangement means arranges the sub parts around the body,
The simulation means simulates the wearing state after connecting the sub-parts to each other according to the folding position and the folding direction.
Comparing the case where the part is folded into, for example, a Z shape without dividing the part, and the case where the part is divided into sub-parts is compared. is there. On the other hand, when dividing into sub-parts, it is only necessary to divide into sub-parts with the folding position as a boundary, and deformation is easy. Then, if the sub parts are connected to each other according to the position and direction of the folding, the simulation can be performed from the folded state as designed.

  Preferably, the folding information setting means automatically sets the folding position and direction based on the type of pleats and the direction of the pleats. In this way, the operator can select the type of pleats, for example, whether the box is tilted or not, and the direction of the folds, for example, whether it is tilted to the right (counterclockwise) or left (clockwise), or the box is above or below the box. If specified, the position and direction of folding can be automatically set, and efficient simulation can be performed for various folding settings.

Block diagram of the design device of the embodiment The figure which shows the display screen of the pleat width and pattern data in an Example The figure which shows the alignment display screen of the pleat pattern to the cloth | dough in an Example. The figure which shows the display screen which changed alignment from FIG. Block diagram of the wearing simulation unit in the embodiment The flowchart which shows the dressing simulation algorithm in an Example Diagram showing division of half-turned pattern Diagram showing rotation after splitting A diagram schematically showing the parts temporarily placed around the human body model The figure which shows the state where the part of the skirt has been arranged around the human body model Plan view of parts group in the state of FIG. The figure explaining folding angle | corner (alpha) in an Example. The figure which shows the wearing state of the skirt obtained by simulation

  In the following, an optimum embodiment for carrying out the invention will be shown. The scope of the present invention should be construed in consideration of the possibility of modification by well-known techniques in the description of the scope of claims.

  FIGS. 1 to 13 show an embodiment, FIGS. 1 to 4 show the design of a pleated skirt, and FIGS. 5 to 13 show a wearing simulation of the designed pleated skirt. In FIG. 1, 4 is a bus, 5 is a color monitor, 6 is a mouse, 7 is a keyboard, 8 is a user interface, and the color monitor 5 to user interface 8 constitute a graphic user interface. In place of the mouse 6, a trackball, joystick, stylus or the like may be used. 10 is a LAN interface, 12 is a disk, 12 is a storage medium for data and design programs, 14 is a color printer, 14 is a color printer and outputs pattern data superimposed on a fabric image, and 15 is a color scanner, for example, reads pattern data of fabric. .

  Reference numeral 20 denotes a calculation unit which obtains the pleat width from the body shape data input from the graphic user interface, the type of pleats, the number of strips, and the pattern pitch of the fabric. The body shape data may be input for each wearer or only a representative size may be input. When the width of the pleats is determined, pattern data can be created by combining with the body shape data and the like, so the pattern data creating unit 22 creates the pattern data and displays it on the color monitor 5. An image memory 24 stores image data, and an image processing unit 26 obtains a pattern pitch from the color data of the fabric read by the color scanner 15, for example, and creates a pattern frame from the pattern data. Create an image superimposed on the image so as to be relatively movable. The wearing simulation unit 28 uses the obtained design data and fabric image data to create a 3D simulation image for evaluating the wearing state.

  The program memory 30 stores a pattern data creation program and the like, and the general-purpose memory 32 stores data other than image data. The design apparatus 2 is a computer and executes the design method by storing the design program of the present invention. Table 1 shows design terms related to pleats.

Table 1 Design terms
Circumferential direction The direction of the fabric perpendicular to the length direction, the direction of the wearer's torso along the torso, etc. and the type of box pleats The part of the pleated product that can be seen from the outside,
A strip along the length direction,
The width of one strip (the width of the strip) x the number of strips is hip size
Corresponding back folds Connected via folds and folds:
The surface of the fabric is a dummy that faces the torso, and the part that continues without folding: the dummy is the number of strips covered by the back folds.
Also, the number of strips per piece of fabric Pattern pitch Repeat width of the pattern that repeats the pattern on the fabric The perimeter of the fabric divided by the number of strips,
Pleated width equal to pattern pitch x number of repeats m (m is an integer) p Pattern paper frame pattern data in the circumferential direction of the folded section

  In the design of the pleated product, for example, specify whether the box is laid down or not (pleat type), specify whether it is facing right or left, or above or below the box (direction of crease), and specify the width of the pleats and the number of strips. Then, the return information can be automatically set. When the folding position is irregular, the folding position is designated in addition to the type of pleats and the direction of the pleats. The target of the simulation is not limited to a skirt but may be a one-piece or a blouse.

  FIG. 2 shows an example of a display screen on the color monitor 5 when designing a pleated product. For example, skirt length, waist, hip and hip length sizes are input. Also, as auxiliary data, the waist belt width is input, and the carry-out width is input. The pattern repeat (pattern pitch) is input by data read from the scanner or by manual measurement from the fabric. Also, if you select half-tilt as the type of pleats, the direction of half-tilt is displayed, so select the direction. If the pleat type is a box, select whether it is below the box or above the box. Enter the number of strips. Next, when the pleat width is input, the pattern data of the pleated product is determined. In FIG. 2, a plurality of pleat width candidates are displayed to facilitate selection of the pleat width.

  When the fabric is a check pattern or the like, the position of the pleated product folded with respect to the fabric pattern is important. Such an example is shown in FIGS. 3 and 4, and the color monitor 5 displays the color image of the fabric and the pattern data on the left side of FIG. 2 in an overlapping manner, or displays the images of FIGS. Reference numeral 50 denotes a texture image of the cloth, and a pattern frame 52 representing pattern data is arranged so as to be superimposed on the texture image 50 and relatively movable. The user can move the pattern frame 52 with respect to the texture 50 in the circumferential direction and the height direction with the mouse 6 or the like, and can move at least in the circumferential direction. Then, the portion hidden in the back fold and the dummy in the texture 50 and the portion appearing on the surface change, and when displayed in a projected view, the display on the right side of FIG. 3 is obtained. 3 are displayed on the color monitor 5 at the same time so that the user can place the pattern frame 52 at an appropriate position.

  FIG. 4 is an example in which the arrangement of the pattern frame 52 is changed from FIG. 3, and the pattern frame 52 is arranged so that the pattern in the vertical direction of the fabric is hidden. As described above, the pleat folding arrangement is fitted to the fabric pattern, and the width of the pleat is determined. The layout of the stencil frame determined by the user is output from the color printer 14 as, for example, an image on the left side of FIGS. 3 and 4 and used for alignment in the cutting of the fabric and the processing of the pleats. In addition to color data, pattern data can be output as numerical data. For example, the arrangement of pattern data is designated by an offset with respect to an appropriate origin on the fabric.

  As shown in FIG. 5, the wearing simulation unit 28 includes a deformation unit 90, an arrangement unit 92, and a simulation unit 94. The pattern data creation unit 22 is used as folding information setting unit, and the image memory 24 is used for storing images.

  The deformation means 90 executes the processing shown in FIGS. 7 and 8 to divide large parts such as the front side and the rear side in the design data into a plurality of subparts in a fold unit so that the subparts can be separated from each other. Preferably, they are connected to each other with a thread of zero tension, and the divided sub-parts are folded back and arranged in a zigzag shape. The arrangement means 92 arranges the sub parts so as to surround a body such as a human body model as shown in FIGS. 9 to 11, determines the orientation of the sub parts according to the turning angle α shown in FIG. 12, and the simulation means 94 uses the sub parts. Are connected to each other to execute a 3D wearing simulation.

  FIG. 6 shows a simulation algorithm. In step 1, the parts on the pattern data are divided into sub-parts composed of front folds integrated with a dummy and sub-parts on the back folds (in the case of half-turning). In the case of a box, it is divided into front folds, left and right folds, and four types of sub-parts at the back of the box. FIG. 7 shows an arrangement in the case of one-side-down, where 100 is a front fold, 102 is a dummy, the dummy 102 is integrated with the front fold 100, and 104 is a back fold. In the case of half-turning, it is virtually divided into a back fold and a front fold along the folding line, and in the case of a box, it is virtually divided into a front fold, the back of the box and the left and right back folds along the folding line. The divided sub-parts are connected to each other by freely expanding and contracting yarns, and are folded back and forth between the front fold 100 and the back fold 104 and between the back fold 104 and the dummy 102.

  As shown in FIG. 8, in the case of half-turning, the sub-parts are arranged from the start point 110 along, for example, the half-turning direction (here, the direction from left to right). When the start point 110 is the dummy 102 as shown in FIG. 7, each sub-part is bent in the correct direction. However, when the start point 110 is on the back fold 104 side as shown in the left side of FIG. For example, the back fold 104 that should extend leftward from the start point 110 extends rightward, and the front and back of the back fold 104 and the like are reversed. Therefore, after the arrangement as shown on the left side of FIG. 8 is performed, the correct arrangement on the right side of FIG. 8 is obtained by rotating the 180 ° sub-part group with respect to the axis perpendicular to the paper surface of FIG. 8 (step 2). There are various methods for obtaining the arrangement on the right side of FIG. 8, and the rotation is not limited to the arrangement on the left side of FIG. Similarly, in the case of the box, when the top and bottom of the box are reversed depending on the position of the start point, the sub-parts such as front folds are arranged and then rotated by 180 °.

  FIG. 9 schematically shows the arrangement of sub-parts ignoring the human body model. Here, the number of strips is two for front and rear for simplicity, but may be, for example, about two for front and rear and about 20 for each. Further, when the sub-parts are arranged around the human body model, the turn-back angle between the front fold 100 and the back fold 104 is taken into consideration. Specify the turn-back angle as counterclockwise (leftward) or clockwise (rightward), and change the turn-up angle between the top and bottom of the skirt, for example, 5 ° directly below the upper belt and 60 ° at the bottom. Use the value. The reason why the folding angle is small in the upper part is that each sub-part is overlapped and fixed to the belt. The reason why the folding angle is large in the lower part is that it is natural that the hem opens and the folding angle becomes large.

  The sub parts are arranged around the human body model as shown in FIG. 10 (step 3). 130 is a belt, and the connection part between the sub-parts and the belt is indicated by white thread, and the triangle is visible at the end of the parts such as the back folds because the sub-parts are divided by rough polygons. This is because the sides of the polygon can be seen at the boundary. In the arrangement of the parts, the parts are divided into a plurality of sub-parts and arranged in advance with folding folds, so that it is much easier to arrange than placing a large part around the human body model and then turning it back.

  FIG. 11 shows the arrangement of the sub-parts in FIG. 10 in a plan view, and a plurality of lines connecting the back fold 104 and the front fold 100 are these connection lines, and the positions of the folds 100, 104, etc. depending on the height position. Since these are different, these connecting lines are at different positions depending on the height position.

  The simulation is started from the state shown in FIGS. FIG. 12 shows the meaning of the folding angle α. In the simulation, the folding angle α between the sub-parts is set to, for example, 5 ° at the top of the skirt and, for example, 60 ° at the bottom, and the folding angle α is small at the top of the skirt. Make it bigger. An elastic force acts between the polygons, and the polygons share the sides at the boundary of the subparts as shown in Fig. 7 so that the subparts are connected to each other, and the friction between gravity and the human body model acts on the polygons And Then, starting from the division into coarse polygons, the simulation is started (step 4), and then the coarse polygons are divided into fine polygons and simulated (step 5). The simulation is a 3D simulation, in which a simulation is performed with a 3D model in which polygons are expressed by mass points, and a stable position and orientation of each polygon is simulated. When the polygon arrangement is stable, rendering such as texture mapping, ray tracing, and shadowing is performed to obtain a display image. In the simulation result of FIG. 13, a realistic wearing state is obtained.

  In the embodiment, the parts are divided into sub-parts and arranged around the human body model. However, large parts can be folded back and arranged in a state close to an actual skirt. For example, if there are 10 folds, 9 folds are folded back from the first front fold to the back fold, and 9 folds are folded back from the next back fold to the dummy. In the case of one-sided folding, folding is performed twice for each piece, and a total of, for example, 18 foldings are necessary. If the position and orientation of the polygon are changed by this number of times, the processing time becomes longer.

2 Design device 4 Bus 5 Color monitor 6 Mouse 7 Keyboard 8 User interface 10 LAN interface 12 Disk 14 Color printer 15 Color scanner 20 Calculation unit 22 Pattern data creation unit 24 Image memory 26 Image processing unit 28 Dressing simulation unit 30 Program memory 32 General purpose Memory 50 Texture image 52 Pattern paper frame 90 Deformation means 92 Arrangement means 94 Simulation means 100 Front fold 102 Dummy 104 Back fold 110 Start point 130 Belt 140 Join line

Claims (5)

In a device that simulates the wearing state of a pleated product,
Folding information setting means for setting the position and direction of folding on the parts on the pattern data of the pleated product,
A deformation means for deforming the part based on the position and direction of the folding;
Placement means for placing the deformed parts around the model body;
Wearing pleated product, characterized in that a simulation means for simulating the wearing state is provided for the arranged parts based on at least the friction with the body and the gravity and elastic force acting on the parts. Simulation device. The deforming means divides the part into a plurality of sub-parts so as to be separated from each other at the folding position,
The arrangement means arranges the sub parts around the body,
2. The wearing simulation apparatus for a pleated product according to claim 1, wherein the simulation means simulates a wearing state after connecting the sub-parts to each other according to the folding position and the folding direction. 3. The pleated product wearing simulation apparatus according to claim 1, wherein the folding information setting means automatically sets the position and direction of folding based on the type of pleats and the direction of the pleats. In the method of simulating the wearing state of a pleated product,
While performing the folding information setting step for setting the position and direction of folding on the parts on the pattern data of the pleated product,
On the computer,
A deformation step for deforming the part based on the position and direction of the folding;
A placement step to place the deformed parts around the body of the model;
Wearing a pleated product characterized in that a simulation step for simulating a wearing state is executed on a part after placement based on at least friction with a body and gravity and elastic force acting on the part. Simulation method. In order to simulate the wearing state of pleated products,
Computer
Folding information setting means for setting the position and direction of folding on the parts on the pattern data of the pleated product,
A deformation means for deforming the part based on the position and direction of the folding;
Placement means for placing the deformed parts around the model body;
A pleated product wearing simulation program for functioning as a simulation means for simulating a wearing state on at least a part after placement based on friction with a body and gravity and elastic force acting on the part.