KR101275538B1 - Method and apparatus for measuring gap between human body and clothes by using 3 dimensionally scanned data - Google Patents

Abstract

The present invention relates to a method and apparatus for measuring a gap between a human body and a garment using three-dimensional scan data. More specifically, the apparatus for measuring a distance between the human body and a garment receives the three-dimensional scan data of the human body from each other, and thus, each horizontal body of the human body is received. A method and apparatus for measuring the distance between a section line and a garment, ie a void distance.
According to the present invention, by analyzing the three-dimensional scan data when the consumer wears the clothing, by automatically calculating the gap distance between the human body and the clothing for each part of the human body as quantitative data, the clothing of more optimal size to the consumer To be able to provide

Description

METHOD AND APPARATUS FOR MEASURING GAP BETWEEN HUMAN BODY AND CLOTHES BY USING 3 DIMENSIONALLY SCANNED DATA}

The present invention relates to a method and apparatus for measuring a gap between a human body and a garment using three-dimensional scan data. More specifically, the apparatus for measuring a distance between the human body and a garment receives the three-dimensional scan data of the human body from each other, and thus, each horizontal body of the human body is received. A method and apparatus for measuring the distance between a section line and a garment, ie a void distance.

Recently, various techniques have been disclosed in the field of clothing fitting using 3D human body scan data. This made it possible to tailor clothing that better fits each person's body type. However, these conventional methods have been able to produce a garment design that is relatively well suited to the body size from the scanned human body data. It did not provide a way to quantitatively analyze whether the best size for each body part was provided.

The present invention was devised to solve such a problem, and analyzes three-dimensional scan data while a consumer wears clothes, and automatically calculates the gap distance between the human body and the clothes as quantitative data for each part of the human body. The aim is to provide consumers with more optimally sized garments.

In order to achieve the above object, according to the present invention, a method of measuring the air gap between the human body and the garment from the three-dimensional human body and clothing combination analysis device from the three-dimensional scan data of the human body, (a) the three-dimensional human body scan data Loading and providing a human body shape implemented by the display apparatus; (b) an upper and lower predetermined range (hereinafter referred to as a 'section setting range') for forming a horizontal cross-section curve in the human body shape, a central axis of the human body, and a distance between the central axis and the horizontal cross-section curve (hereinafter, referred to as a 'cross-section setting range') Setting reference data including a magnitude of an angular interval to measure 'an angle cross-sectional distance'; (c) generating one or more human body horizontal cross-sectional curves within the cross-sectional setting range; (d) measuring the cross-sectional distance for each angle with respect to each of the horizontal cross-sectional curves at each of the set angle intervals; (e) obtaining a distance between the central axis and the garment for each angular interval (hereinafter, referred to as 'the garment distance for each angle'); And (f) calculating the air gap distance between the human body and the garment by subtracting the sectional distance for each angle corresponding to the angle from the respective garment distances for each angle.

The step (c) may include: (c1) dividing the human body surface within the cross-sectional setting range into a plurality of dividing faces; (c2) setting a reference horizontal plane for forming a horizontal cross-section curve of the human body; (c3) extracting a point at which each of the plurality of divided planes and the reference horizontal plane intersect (hereinafter referred to as a 'cross-section point'); And (c4) generating the human body horizontal cross-sectional curve by connecting each of the cross-sectional points with a straight line (hereinafter, referred to as 'element line segment').

The step (c3) comprises: (c31) extracting, in each of the divided planes, three points which exist on the divided plane and which are not in a straight line; (c32) If the three extracted points exist above or below the reference horizontal plane, it is determined that the divided plane does not intersect the reference horizontal plane, and the step (c31) is performed for the next divided plane. If it is determined that the divided plane intersects the reference horizontal plane, proceeding to step c33; (c33) A distance from the reference horizontal plane is obtained with respect to the three points, and a distance having a sign of '+' or '-' as the distance exists above or below the reference horizontal plane (hereinafter referred to as 'signed distance'). To obtain; And (c34) extracting the cross-sectional point that intersects the reference horizontal plane by connecting two points that form different distances among the three signed distances obtained in step (c33) in a straight line.

The step (d) may include: (d1) generating a straight line corresponding to each cross-sectional angle from the central axis at each set angle interval; (d2) extracting an intersection point (hereinafter referred to as an 'section angle measurement point for each angle') between the straight lines generated in the step (d1) and the respective element line segments; And (d3) measuring a cross-sectional distance for each angle that is a distance between the angle-specific cross-sectional distance measuring point and the central axis.

In the step (a), it is possible to further provide an indication of a plurality of points (hereinafter referred to as 'landmarks') that the user can select from the human body shape on the human body shape.

The section setting range may be set to a range between upper and lower points selected by the user by the landmark.

The central axis may be set based on a point selected by the user by the landmark.

The central axis may be set as an axis perpendicular to the ground.

The central axis may be set as an axis reflecting the inclination of the human body.

The horizontal cross-section curve of the human body may be generated at predetermined predetermined intervals within the cross-sectional setting range.

According to another aspect of the invention, the device for measuring the gap between the human body and the garment from the three-dimensional scan data of the human body, the data loading unit for loading the three-dimensional human body scan data; A display unit configured to display a human body shape implemented by the 3D human body scan data; A cross-sectional curve generation unit forming one or more horizontal cross-sectional curves of the human body within a predetermined upper and lower predetermined range of the human body shape (hereinafter, referred to as a 'section setting range'); By measuring the distance between the central axis of the human body shape and the horizontal cross-sectional curve (hereinafter referred to as `` angular cross-sectional distance '') and the distance between the central axis and the garment (hereinafter referred to as `` clothing distance for each angle '') at every angular interval A gap distance calculation unit for calculating a gap distance between the human body and the garment; The three-dimensional human body scan data, reference information for forming the human body horizontal cross-sectional curve (hereinafter referred to as 'section setting information'), central axis setting information, the angular interval for measuring the cross-sectional distance for each angle or the clothing distance for each angle A data storage unit for storing various air gap measurement-related data including information about the air gap; And a controller for controlling each of the components to perform a series of processes for measuring the gap distance between the human body and the garment.

The information stored by the data storage unit may further include information regarding a plurality of points (hereinafter, referred to as 'landmarks') that the user can select from the human body shape.

The central axis setting information may include information regarding a central axis setting position in the human body shape.

The central axis setting information may include information about whether to set the central axis as an axis perpendicular to the ground or as an axis reflecting the inclination of the human body.

The section setting information includes: the section setting range; And interval information for generating the human body horizontal section curve within the section setting range, or information about the number of the human body horizontal section curves to be generated within the section setting range.

The 3D human body type analysis and clothing combination evaluation apparatus may further include an interface providing unit that provides a user interface for setting various data and performing a function for cross-sectional analysis.

The apparatus for analyzing a three-dimensional human body type and clothing combination may further include an input unit configured to receive a data input of a user when specific information is input from a user among the information stored by the data storage unit.

According to the present invention, by analyzing the three-dimensional scan data when the consumer wears the clothing, by automatically calculating the gap distance between the human body and the clothing for each part of the human body as quantitative data, the clothing of more optimal size to the consumer It is effective to provide.

1 is a view showing a setting screen for measuring the air gap distance and cross-sectional analysis of the human body cross section according to the present invention.
2 is a view showing the configuration of the three-dimensional human body type analysis and clothing combination analysis apparatus 100 according to the present invention.
3 is a flow chart of a method for measuring the air gap between the human body and the garment from the three-dimensional scan data of the human body according to the present invention.
4 is a view for explaining a method for obtaining a cross-sectional point at which the reference horizontal plane and the human body cross.
5 illustrates an embodiment of a display screen in which cross-sectional points are aligned by angle;
6 is a view showing a method of measuring the cross-sectional distance for each angle.
7 is a view showing an embodiment when the cross-sectional analysis results on a three-dimensional human body scan screen.
FIG. 8 is a diagram illustrating an embodiment of a case where a 3D scanned human body is displayed on a display screen for cross-sectional analysis. FIG.
FIG. 9 is a view showing an embodiment where a landmark is displayed on the human body shape of FIG. 8; FIG.
FIG. 10 is a view showing an embodiment of an execution button for calling up an interface screen for setting various data and performing a function for cross-sectional analysis on the screen of FIG. 8 or FIG. 9; FIG.
11 is a diagram illustrating an embodiment of an interface screen for setting various data and performing a function for cross-sectional analysis.
12 is a diagram illustrating an embodiment of an interface screen for setting various data and performing a function for cross-sectional analysis, and illustrates a screen for designating an object type.
FIG. 13 is a diagram illustrating an embodiment of an interface screen for setting various data and performing a function for cross-sectional analysis, and illustrates an example of setting a horizontal cross-section curve range and setting a cross-section central axis; FIG.
14 shows an embodiment of a cross-sectional analysis angular spacing input.
FIG. 15 is a diagram illustrating an embodiment of an interface screen for setting various data and performing a function for cross-sectional analysis. FIG. 15 is a diagram illustrating an embodiment of a case where a 'Create Slices' button is clicked among buttons for performing various functions.
FIG. 16 is a diagram illustrating an embodiment of an interface screen for setting various data and performing a function for cross-sectional analysis. FIG. 16 illustrates an example in which an Analysis Slices button is clicked among buttons for performing various functions.
FIG. 17 is a diagram illustrating an embodiment of an interface screen for setting various data and performing a function for cross-sectional analysis. FIG.
FIG. 18 is a diagram illustrating an embodiment of an interface screen for setting various data and performing a function for cross-sectional analysis. FIG.
19 is a view showing a cross-sectional measurement of the pore distance of each cross section of the body for each pants style.
20 is a view showing final generated cross-sectional analysis result data.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be interpreted in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined. Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

1 is a view showing a setting screen for measuring the gap distance and cross-sectional analysis of the human body cross-section according to the present invention.

In the window 10 shown in the figure, a human body shape 11 implemented from three-dimensional human body scan data, and a plurality of points (hereinafter, referred to as 'landmarks') 12 that can be selected by the user in the three-dimensional human body shape, 12. , A button 13 for selecting a part of each human body, an interface window 14 for setting various data and performing a function for cross-sectional analysis, and a plurality of horizontal cross-sectional curves 15 generated on the human body shape 11. ) Is included. Such details will be described later in detail with reference to FIGS. 2 to 15.

2 is a view showing the configuration of the three-dimensional human body type analysis and clothing combination analysis apparatus 100 according to the present invention.

The controller 110 controls each component of the three-dimensional human body type analysis and clothing combination analysis apparatus 100 to be described below to perform a series of processes for measuring the air gap distance between the human body and the clothing.

The data loading unit 120 may load body data such as 3D human body scan data and perform body shape analysis and clothing combination evaluation.

The cross-sectional curve generation unit 130 forms one or more horizontal cross-sectional curves of the human body within a predetermined range of the human body shape (hereinafter, referred to as a 'section setting range').

The air gap distance calculating unit 140 is a distance between the central axis of the human body shape and the horizontal cross-sectional curve (hereinafter referred to as an 'section angle for each angle') and a distance between the central axis and the garment (hereinafter referred to as an 'garment distance for each angle'). ) Is measured at regular angular intervals, and the void distance between the human body and clothing is obtained from this.

The data storage unit 150 includes the 3D human body scan data, reference information for forming the human body horizontal cross-sectional curve (hereinafter referred to as 'section setting information'), the central axis setting information, and the angle interval setting information. It stores various air gap measurement related data. In addition, the information on the landmark as described above can be stored. The central axis setting information may include information about a central axis setting position in the human body shape and information on whether to set the central axis as an axis perpendicular to the ground or an axis reflecting the inclination of the human body. The cross-sectional setting information may include the cross-sectional setting range, and the interval for generating the horizontal cross-sectional curve of the human body within the cross-sectional setting range, or information about the number of horizontal cross-sectional curves to be generated within the cross-sectional setting range. It may further include.

The display unit 160 displays a human body shape implemented by the 3D human body scan data to the user.

The interface providing unit 170 provides a user interface for setting various data and performing a function for cross section analysis.

The input unit 180 receives a user's data input when receiving specific information from a user among information stored in the data storage unit.

Measurement of the gap distance between the human body and the garment from the three-dimensional scan data, which is performed by the above-described configuration, will be described below with reference to FIGS. 3 to 15.

3 is a flow chart of a method for measuring the air gap between the human body and the garment from the three-dimensional scan data of the human body according to the present invention.

First, the 3D human body scan data is loaded at the user's request and the human body shape is implemented through the display apparatus (S310). On the human body shape, the user may further provide an indication of a plurality of points (hereinafter, referred to as 'landmarks') that the user can select from the human body shape. It is also possible to provide selection buttons for such landmarks on the display screen.

Thereafter, reference data for body type analysis are set (S320). Such reference data includes an upper and lower predetermined range (hereinafter referred to as a 'section setting range') for forming a horizontal cross-sectional curve in the human body shape, a central axis of the human body, and a distance between the central axis and the horizontal cross-section curve around the central axis. (Hereinafter referred to as 'cross-sectional distance by angle') includes the size of the angular interval to be measured. These data may be set to the default value set at the time of initial loading, and for each value, the user may adjust and set the desired value through the interface screen. The section setting range may be set to a range between upper and lower points selected by the user by the landmark. The central axis may be set based on a point selected by the user by the landmark. The central axis may be set as an axis perpendicular to the ground or may be set as an axis reflecting the inclination of the human body.

Thereafter, within the cross-sectional setting range, the human body horizontal cross-sectional curve is generated at predetermined predetermined intervals (S330). A method of generating such a horizontal cross section curve will be described later in detail with reference to FIG. 4.

For each generated horizontal cross-sectional curve, the cross-sectional distance for each angle is measured for each set angle interval (S340). The cross-sectional distance measuring method for each angle will be described later in detail with reference to FIGS. 5 and 6.

Subsequently, the distance between the central axis and the garment (hereinafter referred to as 'the garment distance for each angle') for each angle interval is obtained (S350), and the cross-sectional distance for each angle corresponding to the angle is calculated from each garment distance for each human body. The gap distance between the garment and the garment is obtained (S360). By doing so, the final analysis data of the human body shape as shown in FIG. 20 is calculated.

4 is a view for explaining a method for obtaining a cross-sectional point where the reference horizontal plane and the human body cross.

A detailed description of the step S330 is as follows. First, the human body surface within the cross-sectional setting range is divided into a plurality of dividing faces 41, and a reference horizontal plane 45 for forming a human body horizontal cross-section curve is set. Thereafter, a point at which the plurality of divided surfaces 41 and the reference horizontal plane 45 intersect (hereinafter referred to as a 'cross-section point') is extracted. In more detail, first, in each of the divided surfaces 41, , Three points v1, v2, and v3 (42, 43, 44) that exist on the dividing plane and are not in a straight line are extracted. If the three points v1, v2, and v3 (42, 43, 44) are all below the reference horizontal plane 45 or above the reference horizontal plane 45, this divided plane does not intersect the reference horizontal plane 45. If it does not cross, go to the next page. An intersection point is obtained by checking whether the edges formed by the three points v1, v2, and v3 (42, 43, 44) intersect the reference horizontal plane 45 with respect to the divided plane determined to intersect. The method of determining whether the sides intersect with the plane is to obtain a signed distance between the two points forming the side and the reference horizontal plane, and determine that the sides intersect if the signs of the two distances are opposite. In other words, a distance from the reference plane is obtained for the three points, and a distance having a sign of '+' or '-' of the distance (hereinafter, referred to as 'signed distance') is obtained as above or below the reference plane. . Of the three signed distances obtained from the two signed points, it is determined that the sides 46 and 47 connecting the two points intersect the reference horizontal plane. Accordingly, the two points are connected in a straight line to extract cross-sectional points 48 and 49 intersecting the reference horizontal plane. The cross-sectional points 48 and 49 thus obtained are aligned in an angular order, and these points are sequentially connected by two straight lines (hereinafter referred to as 'element line segments') to form a horizontal cross-sectional curve of the human body.

5 is a diagram illustrating an example of a display screen in which cross-sectional points are aligned by angle, and FIG. 6 is a diagram illustrating a method of measuring cross-sectional distances by angle.

A detailed description of the step S340 is as follows. 5 and 6, the x and z axes 51 and 52, which are the coordinate axes set in the horizontal cross-section curve 50, which are generated first, and the central axis 53 are illustrated. That is, the central axis 53 may be perpendicular to the above x-axis and z-axis, and may be an axis perpendicular to the ground. In this case, the central axis 53 may be the y axis. For each angular interval 54 set around the central axis 53, a straight line 62 corresponding to each cross-sectional angle is generated from the central axis. The intersection points (hereinafter referred to as 'section distance measurement points for each angle') 63 of the straight lines 62 and the element line segments (see description of FIG. 4) generated in this way are extracted, and the section distance measurement points for each angle are extracted. The cross-sectional distance 64 for each angle, which is the distance between the 63 and the central axis 53, is measured.

FIG. 7 is a diagram illustrating an example in which a cross-sectional analysis result is displayed on a 3D human body scan screen.

'(a)' 71 shows a plan view when the central axis 71.1 is set to a vertical axis perpendicular to the ground. Around it, a number of horizontal section curves 72.1 and angled section distances 71.3 are created.

'(b)' FIG. 72 shows a plan view when the central axis 72.1 is set to a body axis reflecting the inclination of the human body. A large number of horizontal section curves 72.2 and angled section distances 72.3 are created around them.

'(c)' FIG. 73 shows a perspective view of the generated screen in which the horizontal cross-section curve 75.1 is on the shape of the human body 72.3. A number of landmarks 73.3 are also shown.

FIG. 8 is a diagram illustrating an embodiment 81 in which a 3D scanned human body is displayed on a display screen for cross-sectional analysis.

A button 82 is shown to allow the user to select each part of the human body.

FIG. 9 is a diagram illustrating an embodiment in which a landmark 91 is displayed on the human body shape of FIG. 8.

Such a landmark 91 point can be directly clicked with a mouse, or one of the selection buttons 92 for each part of the human body can be clicked to select a portion desired for a specific operation.

FIG. 10 is a diagram illustrating an embodiment of an execution button for calling up an interface screen for setting various data and performing a function for cross-sectional analysis on the screen of FIG. 8 or 9.

When the mouse is placed or clicked on the 'Slice' button 1001, the 'Slice Option' button 1002 is popped up. When this button is clicked, an interface screen for setting various data and performing a function for an interface cross section analysis is displayed. An embodiment of an interface screen for setting various data and performing a function for such a cross-sectional analysis will be described with reference to FIGS. 11 to 18.

11 is a diagram illustrating an embodiment of an interface screen for setting various data and performing a function for cross-sectional analysis.

The embodiment of the figure is a program developed to extract the section by section using a three-dimensional human body shape, it was configured to set the central axis during the section extraction. That is, to facilitate the comparative study of cross-sectional polymerization, pore distance, etc., the torso part is configured to set the central axis by inputting the X-axis and Y-axis coordinate values. If the central axis of the lower part of the body is the same way as the trunk, the central axis cannot cover the entire leg due to the open legs during the scan. Therefore, if the central axis is three-dimensional, like the lower body, the X and Y axis values are input to the front axis (1120) to set the central axis to reflect the open angle of the leg.The coordinate values of the Y and Z axes are used for the side axis. It was configured to set the 3D axis by inputting 1110. An embodiment of the lower body center axis setting is shown in the lower figure 1130.

12 is a diagram illustrating an embodiment of an interface screen for setting various data and performing a function for cross-sectional analysis, and is a screen for designating an object type. This figure shows an embodiment 1210 in which 'Person, Leg, R', that is, the right leg portion is designated.

FIG. 13 is a diagram illustrating an embodiment of an interface screen for setting various data and performing a function for cross-sectional analysis. FIG. 13 illustrates embodiments of a horizontal cross-sectional curve generation range setting 1310 and a cross-sectional center axis setting 1320 and 1330. It is a figure which shows.

In this figure, in setting the horizontal cross-sectional curve generation range, the y-axis range for the cross-sectional analysis is set. That is, set the y range in 'Range'. One cross section can be analyzed, or several cross sections can be analyzed. In the case of multiple cross sections, an interval between sections can be set.

In the Center of Slice setting, when setting the center axis perpendicular to the ground, that is, one dimension parallel to the y axis, input 1320 of the x-axis z-axis of the 'vertical axis'. When setting the center axis in 3D, input the reference value of the part to be centered. The input values are 'Front Axis' and 'Side axis' of the 'Body axis'. 'Body axis' is the central axis is set by the input (1330) of the y-axis z-axis value of the 'Side Axis' and the x-axis y-axis value of the 'Front Axis'. At this time, each x, y, z value can be input by referring to the height of the reference landmark point.

14 is a diagram illustrating an embodiment of a cross-sectional analysis angle interval input.

The cross-sectional analysis angle interval may be set by inputting 1410 a desired analysis angle from 1 ° to 360 °.

FIG. 15 is a diagram illustrating an embodiment of an interface screen for setting various data and performing a function for cross-sectional analysis. FIG. 15 illustrates a case where a 'Create Slices' button 1511 is clicked among buttons 1510 for performing various functions. It is a figure which shows.

The 'Create Slices' button 1511 is a button for executing generation of a horizontal cross section curve according to the value set through FIGS. 11 to 14. The form 1520 of the horizontal cross-section curve executed is shown.

FIG. 16 is a diagram illustrating an embodiment of an interface screen for setting various data and performing a function for cross-sectional analysis. FIG. 16 illustrates a case in which an 'Analysis Slices' button 1512 is clicked among buttons 1510 for performing various functions. It is a figure which shows.

'Analysis Slices' button 1512 is a button for executing calculation of air gap distance and garment distance according to angle according to the cross-sectional analysis angle criteria.

FIG. 17 is a diagram illustrating an embodiment of an interface screen for setting various data and performing a function for cross-sectional analysis. FIG. 17 illustrates a case where an 'Export Slices' button 1513 is clicked among buttons 1510 for performing various functions. It is a figure which shows.

The 'Export Slices' button 1513 is a button for executing 1710 to generate the generated cross section as a '* .DXF' file.

FIG. 18 is a diagram illustrating an embodiment of an interface screen for setting various data and performing a function for cross-sectional analysis. FIG. 18 illustrates a case where an 'Export Analysis results' button 1514 is clicked among buttons 1510 for performing various functions. It is a figure which shows an example.

The 'Export Analysis results' button 1514 is a button for executing 1810 to generate the measurement pore distance for each cross-sectional analysis angle as a data file.

19 is a view showing a cross-sectional view of the pore distance measurement of each cross section of the human body by pants style.

In each drawing, the innermost line represents the human body cross section, and the plurality of outer lines represent cross-sectional views of pants of different styles (10). The top view shows the cross-section of the waist circumference (1910), the second view shows the cross-section of the hip circumference (1920), the third view shows the cross-section of the thigh circumference (1930), and the bottom view shows the circumference of the knee A cross section of 1940 is shown.

20 is a diagram illustrating final generated cross-sectional analysis result data.

'Section order' refers to the number of horizontal section curves at regular intervals, and 'Angle order' means the angle value to measure the cross-sectional distance by angle around the central axis for each horizontal section curve. The distance between the center and the cross section of each angle represents the cross-sectional distance for each angle as described above. Although not shown in the drawing, the distance between the center of the garment and the garment, that is, the distance of the garment according to the angle as described above, and the gap between the human body and the garment, which is the difference between the cross-sectional distance and the garment distance according to the angle, as described above. Distance values can also be output.

100: 3D human body type analysis and clothing combination evaluation device
110: control unit 120: data loading unit
130: section curve generation unit 140: void distance calculation unit
150: data storage 160: display
170: interface providing unit 180: input unit

Claims (17)

As a method of measuring the air gap between the human body and the garment from the three-dimensional scan data of the human body,
(a) loading the 3D human body scan data and providing a human body shape implemented by the display apparatus;
(b) an upper and lower predetermined range (hereinafter referred to as a 'section setting range') for forming a horizontal cross-section curve in the human body shape, a central axis of the human body, and a distance between the central axis and the horizontal cross-section curve (hereinafter, referred to as a 'cross-section setting range') Setting reference data including a magnitude of an angular interval to measure 'an angle cross-sectional distance';
(c) generating one or more human body horizontal cross-sectional curves within the cross-sectional setting range;
(d) measuring the cross-sectional distance for each angle with respect to each of the horizontal cross-sectional curves at each of the set angle intervals;
(e) obtaining a distance between the central axis and the garment for each angular interval (hereinafter, referred to as 'the garment distance for each angle'); And
(f) obtaining the air gap distance between the human body and the garment by subtracting the cross-sectional distance for each angle corresponding to the angle from the respective garment distances for each angle;
Method for measuring the air gap between the human body and the garment using a three-dimensional scan data comprising a. The method according to claim 1,
The step (c)
(c1) dividing the human body surface within the cross-sectional setting range into a plurality of dividing faces;
(c2) setting a reference horizontal plane for forming a horizontal cross-section curve of the human body;
(c3) extracting a point at which each of the plurality of divided planes and the reference horizontal plane intersect (hereinafter referred to as a 'cross-section point'); And
(c4) generating a horizontal cross-sectional curve of the human body by connecting each of the cross-sectional points with a straight line (hereinafter, referred to as 'element line segment')
Method for measuring the air gap distance between the human body and the garment using the three-dimensional scan data comprising a. The method according to claim 2,
Step (c3) is,
(c31) extracting, in each of the divided planes, three points which exist on the divided plane and which are not in a straight line;
(c32) If the three extracted points exist above or below the reference horizontal plane, it is determined that the divided plane does not intersect the reference horizontal plane, and the step (c31) is performed for the next divided plane. If it is determined that the divided plane intersects the reference horizontal plane, proceeding to step c33;
(c33) A distance from the reference horizontal plane is obtained with respect to the three points, and a distance having a sign of '+' or '-' as the distance exists above or below the reference horizontal plane (hereinafter referred to as 'signed distance'). To obtain; And
(c34) extracting the cross-section point intersecting the reference horizontal plane by connecting two points that form different distances among the three signed distances obtained in the step (c33) in a straight line;
Method for measuring the air gap distance between the human body and the garment using the three-dimensional scan data comprising a. The method according to claim 2,
Step (d) is,
(d1) generating a straight line corresponding to each cross-sectional angle from the central axis at each set angle interval;
(d2) extracting an intersection point (hereinafter referred to as an 'section angle measurement point for each angle') between the straight lines generated in the step (d1) and the respective element line segments; And
(d3) measuring a cross-sectional distance for each angle that is a distance between the cross-sectional distance measuring point for each angle and the central axis;
Method for measuring the air gap distance between the human body and the garment using the three-dimensional scan data comprising a. The method according to claim 1,
In the step (a)
Further providing an indication of a plurality of points (hereinafter referred to as 'landmarks') that the user can select from the anatomy on the anatomy.
Method for measuring the air gap between the human body and clothing using three-dimensional scan data, characterized in that. The method according to claim 5,
The cross section setting range,
Set to a range between the top and bottom points selected by the user by the landmark
Method for measuring the air gap between the human body and clothing using three-dimensional scan data, characterized in that. The method according to claim 5,
The central axis is,
Set based on a point selected by the user by the landmark
Method for measuring the air gap between the human body and clothing using three-dimensional scan data, characterized in that. The method according to claim 1,
The central axis is,
Set as an axis perpendicular to the ground
Method for measuring the air gap between the human body and clothing using three-dimensional scan data, characterized in that. The method according to claim 1,
The central axis is,
Set as an axis reflecting the inclination of the human body
Method for measuring the air gap between the human body and clothing using three-dimensional scan data, characterized in that. The method according to claim 1,
The human horizontal cross section curve,
It is generated at predetermined intervals within the section setting range.
Method for measuring the air gap between the human body and clothing using three-dimensional scan data, characterized in that. As a device for measuring the air gap between the human body and clothing from the three-dimensional scan data of the human body,
A data loading unit loading 3D human body scan data;
A display unit configured to display a human body shape implemented by the 3D human body scan data;
A cross-sectional curve generation unit forming one or more horizontal cross-sectional curves of the human body within a predetermined upper and lower predetermined range of the human body shape (hereinafter, referred to as a 'section setting range');
By measuring the distance between the central axis of the human body shape and the horizontal cross-sectional curve (hereinafter referred to as `` angular cross-sectional distance '') and the distance between the central axis and the garment (hereinafter referred to as `` clothing distance for each angle '') at every angular interval A gap distance calculation unit for calculating a gap distance between the human body and the garment;
The three-dimensional human body scan data, reference information for forming the human body horizontal cross-sectional curve (hereinafter referred to as 'section setting information'), central axis setting information, the angular interval for measuring the cross-sectional distance for each angle or the clothing distance for each angle A data storage unit for storing various air gap measurement-related data including information about the air gap; And
Control unit for performing a series of processes to control the respective components to measure the gap distance between the human body and clothing
3D human body type analysis and clothing combination evaluation device comprising a. The method of claim 11,
The information stored in the data storage unit,
Further comprising information about a plurality of points (hereinafter referred to as 'landmark') that the user can select from the human body shape
3D human body type analysis and clothing combination evaluation device characterized in that. The method of claim 11,
The central axis setting information,
Including information about the central axis setting position in the human anatomy
3D human body type analysis and clothing combination evaluation device characterized in that. The method of claim 11,
The central axis setting information,
Including information on whether to set the central axis as an axis perpendicular to the ground or as an axis reflecting the inclination of the human body
3D human body type analysis and clothing combination evaluation device characterized in that. The method of claim 11,
In the section setting information,
The cross section setting range; And
Information about the number of intervals for generating the human body horizontal cross-section curve within the cross-sectional setting range or the number of the human body horizontal cross-section curves to be generated within the cross-sectional setting range
3D human body type analysis and clothing combination evaluation apparatus comprising a. The method of claim 11,
Interface providing unit that provides a user interface for setting various data and performing functions for cross section analysis
3D human body type analysis and clothing combination evaluation device further comprising a. The method of claim 11,
An input unit for receiving a data input of the user, when the specific information is received from the user of the information stored in the data storage unit
3D human body type analysis and clothing combination evaluation device further comprising a.

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