阅读说明：本技术 测量板以及脚型创建系统 (Measurement board and foot shape creation system ) 是由 镜味佳奈 谷口宪彦 武市一成 于 2019-07-17 设计创作，主要内容包括：本发明的目的是提供具有简易结构的测量板。测量板(1)具备具有折叠结构的主体(6)。主体(6)具备：载置部,载置脚且具备测量用标记(8)；壁部(4),设置为靠近载置部且用于在测量时对脚进行定位；以及支承结构,支承壁部(4)。根据这样的构成,能提供简易结构的测量板。在不同形态中提供脚型创建系统,具备测量板和脚型创建部,测量板具备主体,主体具备：载置部,供测量者载置脚,且具备测量用标记；壁部,设置为靠近载置部,用于在测量时对脚进行定位；以及支承结构,支承壁部,脚型创建部使用壁部将脚定位至载置部,基于由信息处理终端拍摄出的图像数据和存储于数据存储部的学习完毕模型,来创建与拍摄出的脚相关的脚型数据。(The object of the present invention is to provide a measuring plate having a simple structure. The measurement plate (1) is provided with a main body (6) having a folded structure. The main body (6) is provided with: a placement part for placing the foot and having a mark (8) for measurement; a wall portion (4) which is arranged close to the placing portion and used for positioning the foot during measurement; and a support structure supporting the wall portion (4). With this configuration, a measuring plate having a simple structure can be provided. A foot shape creating system provided in different forms, comprising a measurement board and a foot shape creating unit, wherein the measurement board comprises a main body, and the main body comprises: a placement part for placing a foot of a measurer and having a mark for measurement; a wall portion provided near the placement portion for positioning the foot at the time of measurement; and a support structure for supporting the wall portion, wherein the foot shape creating unit positions the foot on the placement unit using the wall portion, and creates foot shape data relating to the captured foot based on the image data captured by the information processing terminal and the learned model stored in the data storage unit.)

1. A measuring board is provided with a main body which is provided with a folding structure,

the main body is provided with:

a placement part for placing a foot of a measurer and having a mark for measurement;

a wall portion provided near the placement portion for positioning a foot at the time of measurement; and

a support structure supporting the wall.

2. Measurement plate according to claim 1,

the measuring mark is a scale for measuring the length of the foot.

3. Measuring plate according to claim 1 or 2,

the measuring board is a measuring board for measuring the foot shape using a photographing device,

the measurement mark is a reference line extending in the front-rear direction of the measurement plate and indicating a position reference of the foot at the time of measurement.

4. Measurement plate according to claim 3,

the placing part comprises a placing area for placing the feet of the measurer and a calibration area arranged on the outer periphery of the placing area,

the placement area is a single color except for the reference line,

the calibration area is formed by a different color from the placement area.

5. Measurement plate according to claim 4,

the measurement mark includes a reference mark that is a reference dimension for measuring a foot shape, and the reference mark is provided in the calibration area.

6. Measurement plate according to claim 4,

the measurement mark includes a distortion correction mark for measuring a foot shape by correcting distortion of an image captured by the imaging device, and the distortion correction mark is provided in the calibration area.

7. Measurement plate according to any one of claims 1 to 6,

the body is paper.

8. Measurement plate according to any one of claims 1 to 7,

the measuring plate is provided with a reinforcing structure for reinforcing the wall portion.

9. Measurement plate according to any one of claims 1 to 8,

the carrying part is printed on the inner surface of the shoe box.

10. A foot shape creating system comprises a measuring board and a foot shape creating part,

the measuring board is provided with a main body which is provided with a folding structure,

the main body is provided with:

a placement part for placing a foot of a measurer and having a mark for measurement;

a wall portion provided near the placement portion for positioning a foot at the time of measurement; and

a support structure, which supports the wall sections,

the foot shape creating unit positions a foot on the mounting unit using the wall unit, and creates foot shape data relating to the captured foot based on image data captured by the information processing terminal and a learned model stored in the data storage unit.

11. A foot form creation system as recited in claim 10,

the foot shape creating unit is provided in a server provided separately from the information processing terminal, and the server receives the image data captured by the information processing terminal, creates the foot shape data therein, and transmits the foot shape data to the information processing terminal.

Technical Field

The invention relates to a measuring board and a foot form creating system.

Background

In the prior art, measuring boards for measuring the shape of a foot when shoes are purchased in a sales shop or the like are known. The measurement board is used to measure the length of the foot in the front-rear direction, the width of the foot, the size of the instep, and the like (for example, patent document 1).

Documents of the prior art

Patent document

Patent document 1: JP Japanese laid-open patent No. 2001-327304

Disclosure of Invention

(problems to be solved by the invention)

In recent years, along with the spread of the internet, there has been an increasing chance of purchasing shoes on the internet without visiting an actual sales shop when purchasing shoes. Since the size of the shoe varies depending on the shoe type and manufacturer, there is a case where shoes having an incorrect size are purchased on the internet. Therefore, there is a demand that the purchaser himself or herself can measure the size of the foot at home or the like.

The present invention has been made to solve the above problems, and an object thereof is to provide a measuring plate having a simple structure.

(means for solving the problems)

The present invention is provided with a main body having a folding structure, the main body including: a placement unit having a measurement mark for placing the foot thereon; a wall portion provided near the placement portion for positioning the heel at the time of measurement; and a support structure supporting the wall portion.

(effect of the invention)

As described above, according to the present invention, a measuring plate having a simple structure can be provided.

Drawings

Fig. 1 is a perspective view of a measurement plate.

Fig. 2 is an enlarged perspective view of the measurement plate.

Fig. 3 is a perspective view of a measurement plate according to a modification.

Fig. 4 is a perspective view of the shoe box.

Fig. 5 is an exploded top view of the measurement plate.

Fig. 6 is a diagram showing an assembly process of the measurement plate.

Fig. 7 is a view showing an assembly process of the measurement plate.

Fig. 8 is a diagram showing an assembly process of the measurement plate.

Fig. 9 is a view showing an assembly process of the measurement plate.

Fig. 10 is an exploded perspective view of a shoe box according to a modification.

Fig. 11 is a perspective view of the shoe box disassembled to assemble the measuring board.

Fig. 12 is a block diagram of a foot form creation system.

Fig. 13 is a plan view showing an example of the mounting portion.

Fig. 14 is a plan view showing an example of the mounting portion.

Detailed Description

Hereinafter, embodiments of the present invention will be described. In the following embodiments, terms such as the width direction, the height direction, and the front-rear direction may be used for the explanation of the direction. The width direction refers to the width direction of the foot when the foot is placed on the measuring board. The front-rear direction refers to the front-rear direction of the foot when the foot is placed on the measurement board. The height direction refers to the height direction under the viewpoint of the measurer when the feet are placed on the measuring board. For convenience of explanation, a three-dimensional orthogonal coordinate system is used, and the width direction of the measurement plate is sometimes referred to as the X-axis direction, the front-back direction is sometimes referred to as the Y-axis direction, and the height direction is sometimes referred to as the Z-axis direction.

Fig. 1 is a perspective view of a measurement plate. In the illustrated example, the measurement plate 1 includes a main body 6, and the main body 6 includes a placement portion 2 on which a foot is placed and a wall portion 4 for positioning the foot. The main body 6 is preferably formed by bending a plate into a given shape.

The main body 6 is preferably made of foldable paper having a thickness like corrugated cardboard. The main body 6 is formed by cutting a piece of paper into a predetermined shape and assembling the cut pieces to form each part including the mounting portion 2 and the wall portion 4.

The placement unit 2 is an area for placing a foot during measurement. The mounting part 2 has a plane along the XY plane. More specifically, the placement unit 2 has a rectangular shape with a short side longer than the length of the foot in the front-rear direction (e.g., 40 cm) and a long side having a size equal to or larger than the shoulder width of the person (e.g., 100 cm). A measurement mark 8 is provided on the upper surface (+ Z direction surface) of the mounting portion 2.

In the illustrated example, the measurement mark 8 is a reference line extending parallel to the Y axis, and notifies a reference position for positioning the foot at the time of measurement. The measurer stands with the reference line (measurement mark 8) overlapping the line connecting the center of the heel and the front end of the second toe. As the measurement mark 8, a scale for measurement or a foot shape may be used, and these may be provided together with the reference line. The measuring marks 8 are preferably printed on the body 6. As the measuring mark, a label-like mark may be attached.

The wall portion 4 stands almost perpendicular to the height direction (+ Z direction) from one long side of the placement portion 2. The height of the wall portion 4 may be 2cm or more for adults and 1.5cm or more for children, and the upper end is preferably a height to the extent of not contacting the calf of the foot. The wall portion 4 is a positioning structure for bringing the heel into contact at the time of measurement. Therefore, the foot shape as the mark 8 for measurement is depicted as: the heel is located on wall 4 and extends in the + Y direction from wall 4. In the case of using a scale as the measurement mark 8, the scale is given with the wall 4 as 0 and at equal intervals in the + Y direction from the wall 4, for example, in millimeters.

Fig. 2 is an enlarged perspective view of the measurement plate. As shown in fig. 2, the measuring plate 1 has a support structure for supporting the wall portion 4. The support structure has: a tongue portion 10 provided at the leading end of the paper constituting the wall portion 4; and a slit 12 formed at a position substantially at the root of the wall 4. When forming the wall portion 4, the paper is folded back 2 times around the X axis so that the tongue portion 10 fits into the slit 12, whereby the wall portion 4 can be supported vertically. In addition, the wall is a paper double structure by the support structure. Thus, even if the measurement plate 1 is formed of thin paper, the wall portion can be appropriately supported.

In use, a measurer stands on the mounting portion 2 with reference to the measurement mark 8 and with the heel in contact with the surface of the wall portion 4. The length of the foot can be measured by reference to a scale.

As described above, by using the measurement plate 1, the foot shape can be measured with a simple configuration. The measuring panel 1 may be formed by printing the measuring marks 8 on the surface of the corrugated cardboard or on a thin paper. The measurement plate 1 is not limited to paper, and may be folded, or may be a thin resin sheet. By forming the measurement plate 1 of such a thin material, the measurement plate 1 can be distributed as an appendix to magazines and the like, can be distributed by post or the like, or can be distributed via the internet. When the measurement board 1 is distributed as an appendix, an expanded view of the measurement board 1 in which a tear line indicating the outline of the placement portion 2, the wall portion 4, and the measurement board 1 is printed in one piece of paper is prepared, and a measurer cuts out the measurement board 1 along the tear line and assembles the measurement board. When distributing print data of the measurement plate 1 via the internet, image data including the outer shape of the main body 6, the position of the tongue 10, the position of the slit 12, and the measurement mark 8 is prepared and printed by the user. The user processes the printed matter and assembles the measuring board 1. Further, the printed matter may be stuck to a thick paper such as a corrugated cardboard. The foldable measuring board 1 can be folded when not in use to reduce the storage space.

Fig. 3 is a perspective view of a measurement plate according to a modification. The measuring plate shown in fig. 3 also doubles as a shoe box. More specifically, the measurement plate 21 is formed by printing the placement portion 22, the measurement mark 8, and the like on the inner surface of the shoe box. The measurement plate 21 includes a placement portion 22 and a wall portion 24. The measuring plate 21 is formed by disassembling, deforming and assembling the shoe box. In this case too, it is preferable that the shoe box is a shoe box assembled from a corrugated cardboard, and the measuring board 21 is assembled from a corrugated cardboard.

Fig. 4 is a perspective view of the shoe box. The shoe box 31 has a rectangular parallelepiped shape in which the cover 32 and the box main body 34 are integrally formed. The cassette main body 34 is a box body having an openable end face. The end face can be opened and closed around the X axis, and the opened and closed portion serves as a cover 32.

Fig. 5 is an exploded top view of the measurement plate. In the illustrated example, the measuring board 41 is a corrugated cardboard, and includes: a cover 32; 3 side portions 44, 46, 48 forming the sides of the cuboid; an upper surface portion 50 and a lower surface portion 52 respectively disposed between the 3 side surface portions 44, 46, 48; and an end face portion 54 forming an end portion of the side where the cover 32 is not formed. The 3 side surface portions 44, 46, and 48 are disposed so as to be separated from each other with the upper surface portion 50 and the lower surface portion 52 interposed therebetween, and each have a rectangular shape. The side portions 44, 46, and 48, the upper surface portion 50, and the lower surface portion 52 are arranged along the X axis such that the long sides of the side portion 44, the upper surface portion 50, the side portion 46, the lower surface portion 52, and the side portion 48 are in contact with each other in this order, and form 1 large rectangular shape. On the-Y side short sides of the upper surface portion 50 and the lower surface portion 52, substantially rectangular end surface portions 54 are formed. In addition, a substantially rectangular cover 32 is formed on the short side of the + Y side of the lower surface portion 52. In addition, a reinforcing portion 56 of the end surface portion 54 when forming the shoe box is formed at the short side of the-Y side of the side surface portion 46 located between the upper surface portion 50 and the lower surface portion 52.

The end surface portion 54 is also a portion forming the wall portion 4, and 2 tongues 10 are formed at the end portion. The 2 slits 12 are formed in the vicinity of the boundary between the end surface portion 54 and the upper surface portion 50 and the boundary between the end surface portion 54 and the lower surface portion 52, respectively. The tongue 10 has a size to fit into the slit 12, and the tongue 10 is fitted into the slit 12 by folding back the center of the end surface portion 54 in the Y-axis direction around the X-axis. Thereby, the wall portion 4 is formed.

The upper surface portion 50, the lower surface portion 52, and the side surface portion 46 therebetween form the placement portion 2. For example, in the case of forming a reference line as the measurement mark 8, the reference line for one foot is printed on the upper surface portion 50, and the reference line for the other foot is printed on the lower surface portion 52. Since the reference line 8 is formed along the Y direction which is the longitudinal direction of the upper surface portion 50 and the lower surface portion 52 of the shoe box 31, the left and right feet can be completely placed on the respective surfaces. There is a side portion 46 between the upper surface portion 50 and the lower surface portion 52. The side portions 46 of the shoe box have a width of about 8-15 cm, thereby ensuring a sufficient space between the right and left reference lines. As described later, when shooting feet by an information processing terminal or the like, it is possible to shoot the left and right feet simultaneously without interfering with each other in one shot. The shooting may be performed a plurality of times, for example, by separating one foot from the other, instead of simultaneously performing the shooting on the left and right.

In addition, wall reinforcing portions 58 for reinforcing the wall portion 4 are formed at the side surface portions 44, 48 at both ends. The wall reinforcing portion 58 has a rectangular shape, and the long sides of the wall reinforcing portion 58 are longer than the short sides of the upper surface portion 50 and the lower surface portion 52. When the wall reinforcing portion 58 is assembled, a reinforcing structure for reinforcing the wall portion 4 can be formed.

Fig. 6 to 9 are views showing an assembly process of the measurement plate. For clarity, fig. 6 to 9 show only a part of the measurement plate 41. To assemble the wall reinforcing portion 58, before the wall portion 4 is formed by the end surface portion 54, the side surface portions 44 at both ends are vertically erected, and the wall reinforcing portion 58 is arranged to extend along the boundary between the end surface portion 54 and the upper surface portion 50 and the boundary between the end surface portion 54 and the lower surface portion 52 (refer to fig. 6). In this state, the end surface portion 54 is folded back around the X axis to form the wall portion 4 (see fig. 7). Next, the tongue 10 of the end surface portion 54 is fitted into the slit 12 (see fig. 8). In this state, the front end of the wall reinforcing portion 58 protrudes from the side surface of the wall portion 4. Then, the front end of the wall reinforcing portion 58 is folded into a given shape. More specifically, in fig. 8, a portion of a one-dot chain line which is a proportional straight line in the XZ plane is convexly folded in the-Y direction, and a portion of a two-dot chain line parallel to the Z axis is concavely folded. Thus, the front end of the wall reinforcing portion 58 is arranged to extend along the XY plane, and can be inserted to the lower side of the reinforcing portion 56 of the cartridge (see fig. 9). In fig. 9, the reinforcing portion 56 of the case is omitted for clarity of explanation.

By assembling the measurement plate 41 from such a shoe box 31, not only the shoe box 31 can be reused, but also the measurement plate 41 can be easily distributed. In addition, the wall portion can be reinforced with a part of the shoe box 31. The shoe box 31 can be configured to be able to separate the measurement plate 21 after the shoe is purchased by providing a seam or a tear line at the boundary between the portion used as the measurement plate 21 and the portion other than the portion. In this case, the storage space can be further reduced when the measuring plate is not used. The boundary can be set appropriately in consideration of the shape at the time of storage.

Fig. 10 is an exploded perspective view of a shoe box according to a modification. In the example shown in fig. 10, 3 side portions, upper surface portions, and lower surface portions are formed by one cartridge main body 62, and a first end surface portion 64 and a second end surface portion 66 are formed separately from the cartridge main body 62, respectively. The first end surface portion 64 is formed of an upper side portion and a lower side portion. The shoe box is formed into a cylindrical shape having a rectangular cross section by bending a box main body 62 having 3 side portions, an upper surface portion, and a lower surface portion around the Y axis at the boundary line of each portion. Next, the first end surface portion 64 and the second end surface portion 66 are fitted to the end surfaces of the cylindrical opening, respectively, to form a shoe box. The second end portion 66 becomes a cover of the shoe box. A plurality of slits 68 are formed in the cylindrical box main body 62, and a tongue 70 fitted into the slits 68 is formed around the lid portion and the end surface portion. The box is made integral by inserting the tongue 70 into the slot 68.

Fig. 11 is a perspective view of the shoe box disassembled to assemble the measuring board. With respect to the measuring plate 81, the box main body 62 having 3 side portions, an upper surface portion and a lower surface portion is unfolded, and the tongue portions 70 formed at the upper side portion and the lower side portion of the end surface portion 64 are fitted into the slits 68 of the unfolded corrugated cardboard. Thereby, the upper and lower portions form the wall portion 4.

Fig. 12 is a block diagram of a foot form creation system. The foot shape creating system 101 photographs a foot on the measurement board 102, and creates foot shape data based on the photographed image. As shown in fig. 12, the foot shape creating system 101 includes a measurement board 102, an information processing terminal 104 having an imaging function, and a foot shape creating unit 106.

As the information processing terminal 104, for example, all terminals with an imaging function having a communication function such as a mobile phone with a camera can be used. The measurer places a foot on the placement part of the measurement board, and takes an image of the foot by the image taking part 108 and sends the image to the foot shape creating part 106.

The foot shape creating unit 106 is constituted by an external server or the like. The foot shape creating unit 106 includes a data storage unit 110, and the data storage unit 110 stores image data transmitted from a measurer or many other users in the past, foot shape data obtained as a result of analyzing the image data, and the like. The data storage unit 110 may store the pin type data held by the manufacturer, in addition to the pin type data described above. The foot shape creating unit 106 creates foot shape data with reference to the data set stored in the data storage unit 110.

In the case where the foot shape creating unit 106 is implemented by artificial intelligence, the foot shape creating unit 106 has a learning completion model in which teacher learning is performed on the data set stored in the data storage unit 110. When the image data from the measurer is input to the foot shape creating unit 106, the foot shape creating unit operates the learned model to create foot shape data relating to the newly captured foot. The foot shape creating unit 106 may perform weighting in creating the foot shape data by using information related to the foot shape such as the sex, age, and nationality of the measurer. The foot shape creating unit 106 is realized by artificial intelligence, and foot shape data can be transmitted to a measurer in almost real time. Thus, the measurer can obtain accurate foot shape data in near real time at his home.

The foot shape data includes at least information on the size (length) of the foot, and may include information on the width and height (3-dimensional data). The created foot shape data is transmitted to the information processing terminal 104. The data storage unit 110 may store data other than shoe sales data held by manufacturers, test data relating to hobbies of persons measuring shoes or other users, and foot shape data such as data relating to characteristics of shoes and usage environments, and may select shoes using various data. Therefore, information on the type and size of the shoe recommended based on the data and the foot shape data may be additionally transmitted. The footer creation unit 106 may be provided not in the server but in the information processing terminal 104.

Fig. 13 is a plan view showing an example of the mounting portion. When the mounting unit 112 is imaged by an information processing terminal, the distance from the mounting unit 112 at the time of imaging and the imaging angle vary from person to person. Therefore, by using the reference mark 114 as a measurement mark on the placing unit 112, the accuracy of image analysis can be improved. In this case, the mounting portion 112 includes a mounting area 112A on which the legs are mounted and an alignment area 112B formed around the mounting area 112A. The mounting area 112A and the calibration area 112B are formed in a single color and are given different colors from each other. In order to improve the image recognition accuracy, it is preferable to provide the mounting area 112A with a cold color containing a neutral color, particularly with a vivid or bright color, and to provide the calibration area 112B with a color darker than that of the mounting area 112A. The reference mark 114 is provided at an arbitrary position of the calibration region 112B, and is given a single color or a plurality of colors different from those of the placement region 112A and the calibration region 112B. In the case of fig. 13, the calibration regions 112B are provided on the outer peripheral side of the mounting region 112A on the 3 sides where the wall portion 4 is not provided. The alignment area 112B is not limited to this, and the outline can be freely set without interfering with the range of the placement foot. Similarly, the reference mark 114 may be provided in the placement area 112A if a recognizable color is added. The fiducial marks 114 are two-dimensional patterns, preferably graphics, text, or a combination thereof, having an extension in the XY plane. The reference mark 114 is used to calculate an imaging distance when analyzing an image obtained by the imaging placement unit 112. In this case, for example, when the placing unit 112 is imaged, the reference mark 114 is imaged together with the subject's foot by the information processing terminal. Since the size of the reference mark 114 is predetermined, the foot shape creating section 106 that has received the image calculates the shooting distance from the size of the reference mark 114 of the image. By calculating the shooting distance, the size of the foot in the image can be measured. By using the reference mark 114 in this manner, a highly accurate foot shape can be created by a simple measurement operation. The recognition state of the reference mark 114 may be a condition for allowing imaging.

Fig. 14 is a plan view showing another example of the placement portion. In the example shown in fig. 14, a distortion correction mark 118 as a measurement mark is printed on the mounting portion 116. The mounting portion 116 includes a mounting area 116A on which the legs are mounted and an alignment area 116B formed around the mounting area 116B. The mounting area 116A and the calibration area 116B are formed in a single color and are given different colors from each other. The distortion correction mark 118 is provided at an arbitrary position of the calibration area 116B, and the placement area 116A and the calibration area 116B are given different single or multiple colors. In the case of fig. 14, the calibration regions 116B are provided on the outer peripheral side of the mounting region 116A on the 3 sides where the wall portion 4 is not provided. The alignment area 116B is not limited to this, and the outline can be freely set without interfering with the range of the placement foot. Similarly, the distortion correction marks 118 may be provided in the placement area 116A if they are provided with a recognizable color. The distortion correction marks 118 are arranged at separate positions on the XY plane, and are at least 3 marks. If the distortion correction marks 118 have a shape that can be clearly imaged by the imaging function of the information processing terminal, all of the distortion correction marks 118 may have the same shape or different shapes, regardless of the shape. In the illustrated example, the distortion correction marks 118 are provided at positions corresponding to respective three sides of the mounting area 116B, but the positions of the distortion correction marks 118 are not limited to this. As shown in the figure, the 3 distortion correction marks 118 are not arranged linearly on the XY plane. At the time of imaging, imaging may be performed so that all the distortion correction marks 118 are included in the image.

By analyzing the image obtained by imaging the mounting unit 116 on which the distortion correction mark 118 is provided, the distance between the information processing terminal and the mounting unit 116 at the time of imaging and the angle of the information processing terminal at the time of imaging can be calculated from the position of the distortion correction mark 118. Therefore, the foot shape creating unit 106 calculates the distance between the information processing terminal and the mounting unit 116 at the time of imaging and the angle of the information processing terminal at the time of imaging from the position of the distortion correction mark 118, and corrects the size of the imaged foot based on the calculation result. Thereafter, the foot shape creating section 106 creates a foot shape based on the corrected foot size.

The present invention is not limited to the above-described embodiments, and the respective configurations of the embodiments may be appropriately modified within a range not departing from the gist of the present invention.

When the above embodiment is generalized, the following aspects are derived.

(form 1)

A measuring board is provided with a main body which is provided with a folding structure,

the main body is provided with: a placement part for placing a foot of a measurer and having a mark for measurement;

a wall portion provided near the placement portion for positioning a foot at the time of measurement; and

a measuring plate supporting the wall portion.

According to this configuration, a measuring plate having a simple structure can be provided.

(form 2)

In the measurement board according to embodiment 1, the measurement mark is a scale for measuring the length of the foot.

According to this configuration, the length of the foot can be measured without using a device other than the measurement board.

(form 3)

The measurement board according to aspect 1 or 2, which is a measurement board for measuring a foot shape using an imaging device,

the measurement mark extends in the front-rear direction of the measurement plate and is a reference line indicating a positional reference of the foot at the time of measurement.

According to this configuration, when a terminal having an imaging function is used in addition to the measurement plate, the size of the foot can be accurately calculated by using the reference mark by the terminal.

(form 4)

The measurement plate according to embodiment 3, wherein the placement unit includes: a loading area for loading the feet of the measurer; and a calibration area provided on an outer peripheral side of the mounting area,

the placement area is a single color except for the reference line,

the calibration area is formed by a different color from the placement area.

According to this configuration, the accuracy of image analysis can be improved.

(form 5)

In the measurement plate according to embodiment 4, the measurement mark includes a reference mark that is a reference dimension for measuring a foot shape, and the reference mark is provided in the alignment area.

According to this configuration, the resolution accuracy of the foot shape is improved.

(form 6)

In the measurement board according to mode 4, the measurement marks include distortion correction marks for correcting distortion of an image captured by the imaging device and measuring a foot shape, and the distortion correction marks are provided in the calibration area.

According to this configuration, the resolution accuracy of the foot shape is improved.

(form 7)

The measuring board according to any one of aspects 1 to 6, wherein the main body is paper.

According to this configuration, the entire measurement plate can be made thin, and thus can be easily stored. In addition, the measurement board can be used as an appendix to magazines and the like, or can be sent by mail or the like. In addition, by transmitting the image data of the measurement board via the network, the measurement board can be easily output by a home printer or the like.

(form 8)

The measurement plate according to any one of embodiments 1 to 7, further comprising a reinforcing structure for reinforcing the wall portion.

According to this configuration, the wall portion can be reinforced even when the strength of the main body itself is insufficient.

(form 9)

The measuring board according to any one of aspects 1 to 8, wherein the main body is printed on an inner surface of the shoe box.

According to this configuration, the measuring board can be distributed at the time of sale of the shoe.

(form 10)

A foot shape creating system comprises a measuring board and a foot shape creating part,

the measuring board is provided with a main body which is provided with a folding structure,

the main body is provided with:

a placement part for placing a foot of a measurer and having a mark for measurement;

a wall portion provided near the placement portion for positioning a foot at the time of measurement; and

a support structure, which supports the wall sections,

the foot shape creating unit positions a foot on the mounting unit using the wall unit, and creates foot shape data relating to the captured foot based on image data captured by the information processing terminal and a learned model stored in the data storage unit.

According to this configuration, the foot shape data can be created using a measurement board having a simple configuration.

(form 11)

In the foot shape creating system according to embodiment 10, the foot shape creating unit is provided in a server provided separately from the information processing terminal, and the server receives the image data captured by the information processing terminal, creates the foot shape data therein, and transmits the foot shape data to the information processing terminal.

According to this configuration, the foot shape data can be transmitted using a measurement board having a simple configuration.

(Industrial Applicability)

The present invention has industrial applicability as a foot-shaped measuring plate.

Description of the symbols

1 measuring board

2 placing part

4 wall part

6 main body

8 marks for measurement

10 tongue part

12 slit

21 measuring board

22 placing part

24 wall part

31 shoe box

41 measuring board

58 wall reinforcement

101-pin type creation system

102 measuring board

104 information processing terminal

106 foot type creation part

110 data storage section.