JP2019054901A - Drawing data generation device and drawing data generation method - Google Patents

Abstract

To provide a drawing device and a drawing method capable of applying a beautifully finished nail printing to a nail without performing a pretreatment such as polishing the surface of the nail.SOLUTION: A drawing data generation device comprises: an image projection section 60 for projecting an original image onto the surface of a nail T on which an image is drawn; an image-capturing section 50 for capturing a projected image by imaging the surface of the nail T onto which the original image is being projected by the image projection unit 60; a deformation acquisition section 814 for acquiring the degree of deformation of the projected image using the original image as a reference; and a drawing data generation section 815 for generating drawing data by correcting image data to be drawn on the surface of the nail T based on the deformation degree acquired by the deformation acquisition unit 814.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a drawing data generation apparatus and a drawing data generation method.

  2. Description of the Related Art Conventionally, a drawing apparatus (nail printing apparatus) that draws a favorite nail design on a fingernail is known (see, for example, Patent Document 1). If such an apparatus is used, a nail print can be easily enjoyed without using a nail salon or the like.

However, the nail of the person who is the drawing target of the nail printing apparatus has a rounded curved shape with the left and right ends in the width direction being low and the vicinity of the center being high. For this reason, at the end portion in the width direction, the density of the drawing portion varies depending on the inclination angle, and the drawn image (nail design) is stretched or distorted.
In addition, the surface of the nail, which is the drawing target surface, has various irregularities depending on the nail, such as downspout and dent.
When drawing without considering the various shapes and surface states of these nails, it is not possible to draw a beautiful image such as the drawn image unnaturally stretches or the image is distorted at the uneven part. .

Therefore, the curved shape of the conventional nail is classified into several patterns, and correction is performed to deform the drawing image data of the nail design according to the pattern of the shape that seems to be closest to the shape of the nail that is the drawing target, and drawing is performed. It is considered to do. In addition, when there is unevenness on the drawing target surface, the finish is improved by performing drawing after performing processing for eliminating the unevenness in advance.
For example, when drawing on the surface of the nail, the user performs a pretreatment of polishing with a special file or the like until the surface of the nail is free of irregularities.

Special table 2003-534083 gazette

However, since correction by pattern classification is only an approximate solution, for example, it is difficult to perform high-precision correction when the shape to be drawn is a shape that does not fit any pattern, etc. It is not a complete solution.
In addition, if there is unevenness on the surface of the drawing object, it takes time and effort to perform the pretreatment for removing the unevenness.
For this reason, it is troublesome to perform nail printing, and the user tends to avoid nail printing.
In addition, when the object to be drawn is a nail, if the nail is polished to remove surface irregularities, the thickness of the nail may become thin, and the nail may be easily broken or ill.

  The present invention has been made in view of the circumstances as described above, and a drawing data generation device and a drawing capable of performing a beautiful nail print on a nail without performing a pretreatment such as polishing the surface of the nail It is an advantage to provide a data generation method.

In order to solve the above problems, the drawing data generation apparatus of the present invention provides:
An image projection unit that projects the original image onto a drawing target surface to be drawn;
An imaging unit that acquires the projection image by imaging the drawing target surface in a state where the original image is projected by the image projection unit;
A deformation acquisition unit that acquires the degree of deformation of the projection image with respect to the original image;
A drawing data generation unit that generates data for drawing by correcting data of a drawing image to be drawn on the drawing target surface based on the degree of deformation acquired by the deformation acquisition unit;
It is characterized by having.

  According to the present invention, a nail print with a beautiful finish can be applied to the nail without performing a pretreatment such as polishing the surface of the nail.

It is a perspective view which shows the external appearance structure of the nail print apparatus in this embodiment. It is the principal part perspective view which removed the housing | casing from the nail print apparatus and showed the internal structure. It is explanatory drawing which shows typically a mode that it image | photographs, projecting an original image on a nail | claw. (A) is a top view which shows the example of the nail | claw in which the vertical streak entered, (b) is sectional drawing which follows the bb line | wire of the nail | claw width direction of the nail | claw shown to (a). It is a principal part block diagram which showed the control structure of the nail print apparatus in this embodiment. (A) is a top view which shows an example of the pattern image which is an original image, (b) is a top view which shows the state which projected the pattern image shown in (a) on the surface of the nail | claw. (A) is a top view which shows an example of a projection image, (b) is a top view which shows an example of the image based on the inverse transformation data of the projection image shown in (a), (c) is ( It is a top view which shows the state which projected the image based on the inverse transformation data shown to b) on the surface of a nail | claw. (A)-(f) is a schematic diagram explaining the example projected while rotating the pattern image which is an original image. It is a flowchart which shows the drawing process of the nail print apparatus in this embodiment.

An embodiment of a drawing data generation apparatus according to the present invention will be described with reference to FIGS.
The embodiments described below are given various technically preferable limitations for carrying out the present invention, but the scope of the present invention is not limited to the following embodiments and illustrated examples.
Further, in the following embodiment, a case where the drawing data generation device is a nail print device that draws a fingernail of a hand as a drawing target will be described as an example. The generation target is not limited to the fingernails of the hand, and for example, the toenails of the toes may be targeted. Moreover, it is good also considering objects other than a nail, such as a nail chip and the surface of various accessories.

As shown in FIG. 1, the nail print apparatus 1 in this embodiment has a housing 11 formed in a substantially box shape.
An operation unit 12 is installed on the upper surface (top plate) of the housing 11.
The operation unit 12 is an input unit on which a user performs various inputs.
The operation unit 12 includes, for example, a power switch button for turning on the power of the nail printing apparatus 1, a stop switch button for stopping the operation, a design selection button for selecting a design image to be drawn on the nail T, and a drawing start for instructing a drawing start. Operation buttons for performing various inputs such as buttons are arranged.

A display unit 13 is installed on the upper surface (top plate) of the housing 11.
The display unit 13 includes, for example, a liquid crystal display (LCD), an organic electroluminescence display, or other flat displays.
In the present embodiment, the display unit 13 includes, for example, an image such as a nail image obtained by photographing the finger U1 (a finger image including an image of the nail T) and a contour line of the nail T included in the nail image. An image in a state in which an original image described later is projected on the nail T, a design selection screen for selecting a design image to be drawn on the nail T, a thumbnail image for design confirmation, an instruction screen for displaying various instructions, etc. Is displayed.
Note that a touch panel for performing various inputs may be integrally formed on the surface of the display unit 13. In this case, the touch panel functions as the operation unit 12.

Further, on the front side of the housing 11 (front side in FIG. 1), in the almost central portion of the nail printing apparatus 1 in the X direction (X direction in FIG. 1), there is a drawing target when the nail printing apparatus 1 takes a picture. An opening 14 is formed for inserting a finger U1 corresponding to a certain nail T and setting the finger U1 at a shootable position where the shooter 50 can shoot.
Inside the opening 14, a finger fixing part 3 for fixing the nail T (finger U1 including the nail T) is arranged.

FIG. 2 is a perspective view of the main part showing the internal configuration of the nail print apparatus 1 with the casing 11 removed from the nail print apparatus 1 shown in FIG.
As shown in FIG. 2, a base 2 including a top plate 21 and a pair of legs 22 that support the top plate 21 is provided in the housing 11.
The finger fixing part 3 is disposed on the top surface of the top plate 21 at a position corresponding to the opening 14 of the housing 11.
The finger fixing part 3 is a box-like member having an opening 31 on the front side of the apparatus, and a finger fixing member 32 for fixing the finger U1 is arranged inside the finger fixing part 3.
The finger fixing member 32 pushes up and supports the finger U1 from below, and is formed of, for example, a flexible resin. The finger fixing member 32 is not particularly limited as long as it can support the finger U1 from the lower side. For example, it may be biased from below by an elastic member such as a spring. Further, for example, the finger fixing member 32 is configured to be able to expand and contract by changing the internal pressure, and may be configured to push up the finger U1 in the expanded state and fix its position.

The back side of the top surface of the finger fixing unit 3 is an opening window 33. From the window 33, the nail T of the finger U1 inserted into the finger fixing part 3 is exposed.
Further, the front side of the finger fixing unit 3 is a finger presser 34 that prevents the finger U1 from lifting and restricts the upward position of the finger U1. The finger U1 and the nail T thereof are supported by the finger fixing member 32 from the lower side, and the upper side of the finger U1 is pressed by the finger presser 34, whereby the position in the height direction is positioned at a predetermined position.
Moreover, in this embodiment, the nail | claw mounting part 35 which mounts the nail | claw T is provided in the back | inner side of the finger insertion direction.
By placing the tip of the claw T on the claw placement portion 35, the position of the claw T in the horizontal direction (that is, the X direction and the Y direction) is defined, and the position in the height direction is also regulated. .

As shown in FIG. 2, a drawing unit 40 for drawing on the drawing target surface is provided inside the housing 11. Here, the drawing target surface is the surface of the drawing target, and in this embodiment is the surface of the nail T of the finger U1.
The drawing unit 40 moves the drawing head 41 that is the drawing unit main body, the unit support member 42 that supports the drawing head 41, and the drawing head 41 in the X direction (the X direction in FIG. 1 and the like, the left and right direction of the nail printing apparatus 2). X-direction moving stage 45, X-direction moving motor 46, and Y-direction moving stage 47 for moving drawing head 41 in the Y direction (Y direction in FIG. 1 and the like, the front-rear direction of nail printing apparatus 1), Y-direction movement A motor 48 and the like are provided. In the present embodiment, a head moving unit 49 (see FIG. 5) that moves the drawing head 41 is configured by the X direction moving motor 46, the Y direction moving motor 48, and the like.

The drawing head 41 of this embodiment is an ink jet head that performs drawing by an ink jet method.
The drawing head 41 is, for example, an ink cartridge (not shown) corresponding to yellow (Y; YELLOW), magenta (M; MAGENTA), and cyan (C; CYAN) ink, and a drawing target (surface of the nail T) in each ink cartridge. This is an ink cartridge integrated head in which an ink discharge portion (not shown) provided on an opposing surface (in this embodiment, the lower surface in FIGS. 1 and 2) is integrally formed. The ink ejection unit includes a nozzle array including a plurality of nozzles that eject ink of each color, and the drawing head 41 atomizes the ink and draws the drawing target surface (that is, the nail) from the ink ejection unit. Drawing is performed by spraying ink directly on the surface of T). The drawing head 41 is not limited to the one that ejects the three colors of ink. You may provide the ink cartridge and ink discharge part which store another ink.

The unit support member 42 is fixed to an X-direction moving unit 451 attached to the X-direction moving stage 45. The X-direction moving unit 451 is moved in the X direction along a guide (not shown) on the X-direction moving stage 45 by driving the X-direction moving motor 46, and is thereby attached to the unit support member 42. The drawing head 41 is moved in the X direction (the X direction in FIG. 2, the left and right direction of the nail printing apparatus 1).
The X direction moving stage 45 is fixed to the Y direction moving portion 471 of the Y direction moving stage 47. The Y-direction moving unit 471 is moved in the Y-direction along a guide (not shown) on the Y-direction moving stage 47 by driving the Y-direction moving motor 48, and is thereby attached to the unit support member 42. The drawing head 41 is moved in the Y direction (the Y direction in FIG. 2, the front-rear direction of the nail printing apparatus 1).
In this embodiment, the X direction moving stage 45 and the Y direction moving stage 47 are configured by combining an X direction moving motor 46 and a Y direction moving motor 48 with a ball screw and a guide (not shown).
In the present embodiment, a head moving unit 49 as an XY driving unit that drives the drawing head 41 in the X direction and the Y direction is configured by the X direction moving motor 46, the Y direction moving motor 48, and the like.
The drawing head 41, the X direction moving motor 46, and the Y direction moving motor 48 in the drawing unit 40 are connected to a drawing control unit 816 (see FIG. 5) of the control device 80 described later, and are controlled by the drawing control unit 816.

As shown in FIG. 2, in the present embodiment, in addition to the drawing head 41, the photographing unit 50 and the image projection unit 60 are supported on the unit support member 42.
In FIG. 2, the photographing unit 50 is disposed on the side of the drawing head 41 (right side in the X direction in FIG. 2), and the image projecting unit 60 is located on the back side of the apparatus (back in the Y direction in FIG. 2). An example of arrangement is shown.
Note that the photographing unit 50 and the image projecting unit 60 may be arranged at positions that do not affect the drawing operation of the drawing head 41 during the drawing operation, and the specific arrangement is not limited to the illustrated example.

The photographing unit 50 is a photographing unit that photographs the nail T and acquires a nail image that is an image of the finger U1 including the nail T.
Further, in the present embodiment, the projection image is obtained by photographing the surface (drawing target surface) of the nail T in which the original image is projected by the image projection unit 60 described later.
The photographing unit 50 includes a photographing device 51 and a lighting device 52.
The imaging device 51 is, for example, a small camera configured to include a solid-state imaging element having about 2 million pixels or more, a lens, and the like.
The illumination device 52 is an illumination lamp such as a white LED. In the present embodiment, a plurality of illumination devices 52 are arranged so as to surround the imaging device 51. The number and arrangement of the lighting devices 52 are not limited to the illustrated example.
The positions of the photographing device 51 and the illumination device 52 are not limited to the illustrated example. In the case where the photographing unit 50 is configured to be movable by the moving means as in the illustrated example, it may be disposed at a position where it can move to the position above the nail T. Further, for example, the photographing device 51 and the illumination device 52 of the photographing unit 50 may be fixedly disposed at an upper position of the nail T.
The photographing unit 50 is connected to a photographing control unit 811 of the control device 80 described later, and is controlled by the photographing control unit 811.
Note that image data of an image photographed by the photographing unit 50 is stored in a nail image storage area 821 to be described later.

The image projecting unit 60 projects the original image onto the surface (drawing target surface) of the nail T.
In the present embodiment, the image projection unit 60 includes a display panel unit 61 that displays the original image based on the data of the original image, a light source 62 that irradiates the display panel unit 61 with light from behind, and light that is emitted from the light source 62. The projection lens 63 is arranged on the optical axis, and the mirror 64 is arranged between the display panel unit 61 and the projection lens 63. The angle of the mirror 64 can be adjusted by an angle adjusting unit 65 (see FIG. 5) described later.

The original image projected on the surface of the nail T by the image projecting unit 60 is preferably one that causes deformation such as distortion when projected onto a surface or curved surface with an uneven surface, and the degree of deformation is easy to detect. It is preferable that the image has a fine pattern or pattern on the entire image, such as a pattern image in which a repeated pattern is formed on the entire surface. If such a pattern image has a pattern repeatedly formed on the entire surface, correction information can be obtained uniformly over the entire surface, and even if this correction information is applied to drawing image data of various nail designs, it is stable. Can be corrected.
In the present embodiment, as will be described later, a pattern image (see FIG. 6A) having a uniform mesh pattern as a whole is used as an original image. The original image is not limited to the illustrated example, and may be, for example, an image having a vertical or horizontal stripe pattern.
Further, a nail design image drawn on the nail T may be used as an original image as it is.
When the nail design image drawn on the nail T is used as it is as the original image, the projection image obtained from the image projected on the nail T can be used as correction information only when the nail design is drawn. preferable. Depending on the nail design, there is a one-point design in which the pattern is not provided on the entire surface, and accurate correction information cannot be obtained for a portion without the pattern. For this reason, when other nail designs are drawn, if this is used as correction information, there is a possibility that a part that cannot be corrected occurs and the entire image cannot be corrected appropriately.

FIG. 3 schematically illustrates the positional relationship between the nail T fixed to the finger fixing unit 3, the imaging unit 50, and the image projection unit 60 when the surface of the nail T in a state where the original image is projected is imaged. FIG.
As illustrated in FIG. 3, the photographing unit 50 is disposed above the position where the nail T is disposed when the finger U <b> 1 is inserted into the finger fixing unit 3. In addition, the image projection unit 60 is disposed on the back side of the apparatus (the tip side of the nail T) from the photographing unit 50.
When photographing the surface of the nail T in a state where the original image is projected, the display panel unit 61 of the image projection unit 60 is irradiated with light from the light source 62, and the nail T as a drawing target surface is projected through the projection lens 63. An original image is formed on the surface. At this time, by adjusting the angle of the mirror 64 by the angle adjusting unit 65, even when the position of the nail T is slightly deviated, the original image can be accurately projected on the surface of the nail T which is the drawing target surface. it can.
In the example illustrated in FIG. 3, an original image is projected onto the surface of the nail T from the image projection unit 60 disposed on the back side of the apparatus with respect to the photographing unit 50, and the nail T is captured by the photographing unit 50 disposed directly above the nail T. The surface of the camera is photographed to obtain a projection image.

The display panel unit 61, the light source 62, and the angle adjustment unit 65 of the image projection unit 60 are controlled by a deformation acquisition unit 814 (see FIG. 5) described later.
Note that the image projection unit 60 is not limited to the configuration illustrated here, as long as it can project the original image onto the surface of the nail T (surface to be drawn).
For example, here, the image projection unit 60 includes a display panel unit 61 that displays the original image based on the data of the original image, and the image projection of the data method that projects the original image displayed on the display panel unit 61 onto the drawing target surface. For example, a sheet or the like on which the original image is drawn is held in the image projection unit 60, and the original image drawn on the sheet or the like is irradiated with light from the light source 62 on the surface of the nail T. You may project on (drawing object surface).

The photographing unit 50 and the image projecting unit 60 are configured to be movable in the X direction and the Y direction by a head moving unit 49 (see FIG. 5) including an X direction moving motor 46 and a Y direction moving motor 48. .
As described above, by allowing the head moving unit 49 to move, the photographing unit 50 is disposed above the nail T exposed from the window 33 of the finger fixing unit 3 when photographing the nail T to be drawn. Thus, at the time of drawing, the drawing head 41 can be appropriately moved so as to be disposed above the finger fixing unit 3.

FIG. 4A is a plan view illustrating an example of the nail T assumed as a drawing target in the present embodiment, and FIG. 4B is a line bb of the nail T illustrated in FIG. It is sectional drawing which follows.
As shown in FIGS. 4 (a) and 4 (b), the nail T of the present embodiment has a curved shape in which the central portion in the width direction is high and the height decreases as it approaches both ends.
In addition, a plurality of stripes are carved in the vertical direction on the surface of the nail T, and the stripe portions become a plurality of uneven portions Ta as shown in FIG.

The control device 80 is installed on, for example, a substrate (not shown) disposed on the lower surface side of the top surface of the housing 11 or the like.
FIG. 5 is a principal block diagram showing a control configuration in the present embodiment.
As shown in FIG. 5, the control device 80 includes a control unit 81 configured by a CPU (Central Processing Unit) (not shown), a ROM (Read Only Memory), a RAM (Random Access Memory), and the like (both not shown). And a storage unit 82 constituted by the computer.

The storage unit 82 stores various programs and various data for operating the nail printing apparatus 1.
Specifically, in the program storage area 820 constituted by a ROM or the like in the storage unit 82, various nail information such as the shape of the nail T, the contour of the nail T, the width of the nail, the area of the nail and the like from the nail image. Various programs, such as a nail information detection program for detecting the image, a deformation acquisition program for obtaining correction information, a drawing data generation program for generating drawing data, and a drawing program for performing drawing processing are stored. These programs are executed by the control device 80, whereby each unit of the nail print apparatus 1 is controlled in an integrated manner.
Further, in the present embodiment, the storage unit 82 stores the nail image of the nail T of the user's finger U1 acquired by the photographing unit 50, and the nail information detected by the nail information detection unit 813 ( A nail information storage area 822 for storing the contour of the nail T, an inclination angle of the nail T, a correction information storage area 823, a nail design storage area 824 for storing nail design image data drawn on the nail T, and the like. It has been.
In the present embodiment, the storage unit 82 functions as a registration unit that registers information for specifying a drawing target (nail T) and information indicating the shape of the drawing target (for example, a nail image storage area of the storage unit 82). 821, nail information storage area 822, correction information storage area 823).

  When functionally viewed, the control unit 81 includes an imaging control unit 811, a projection control unit 812, a nail information detection unit 813, a deformation acquisition unit 814, a drawing data generation unit 815, a drawing control unit 816, a display control unit 817, and the like. I have. In addition, the control unit 81 according to the present embodiment is configured such that a drawing target (nail T) on which drawing data is drawn by the drawing unit 40 is registered in the correction information storage area 823 that is a registration unit. It also functions as a determination unit that determines whether or not. The functions of the imaging control unit 811, projection control unit 812, nail information detection unit 813, deformation acquisition unit 814, drawing data generation unit 815, drawing control unit 816, display control unit 817, etc. This is realized by cooperating with a program stored in the program storage area 820 of the unit 82.

The imaging control unit 811 controls the imaging device 51 and the illumination device 52 of the imaging unit 50, and the image of the finger including the image of the nail T of the finger U <b> 1 fixed to the finger fixing unit 3 by the imaging device 51 (nail image). Shoot.
The image data of the nail image acquired by the imaging unit 50 is stored in the nail image storage area 821 of the storage unit 82.
In the present embodiment, the imaging control unit 811 captures the surface of the nail T onto which the original image has been projected by the image projection unit 60 with the imaging device 51, and acquires a projection image. Hereinafter, a projection image (for example, see FIG. 7A) is obtained by removing a portion of the nail T from an image obtained by photographing the surface of the nail T on which the original image is projected. The projection image may be stored in the correction information storage area 823.

The projection control unit 812 controls the operation of each unit of the image projection unit 60.
For example, the projection control unit 812 sets an original image to be projected onto the drawing target surface and causes the display panel unit 61 to display an image based on the original image data. Then, the light source 62 is turned on to project the original image onto the drawing target surface. At this time, the projection control unit 812 controls the angle adjustment unit 65 to adjust the angle of the mirror 64 so that the original image is appropriately projected onto the surface of the nail T even from the oblique rear side of the photographing unit 50.
The adjustment of the angle adjustment unit 65 may be automatically performed while determining whether or not the original image is correctly projected from the position and angle of the image while shooting by the shooting unit 50. The image may be displayed on the display unit 13 or the like while photographing by the unit 50, and the user may visually confirm the image displayed on the display unit 13 or the like, and then manually adjust from the operation unit 12 or the like.

The nail information detection unit 813 detects nail information about the nail T of the finger U1 based on the image of the nail T of the finger U1 fixed to the finger fixing unit 3 imaged by the imaging device 51.
Here, the nail information includes, for example, the contour of the nail T (nail shape, XY coordinates of the horizontal position of the nail T, etc.), the height of the nail T (the vertical position of the nail T, hereinafter “the vertical position of the nail T”). Or simply “the position of the nail T”).

In the present embodiment, the nail information detection unit 813 includes a deformation acquisition unit 814.
The deformation acquisition unit 814 acquires the degree of deformation of the projection image when the projection unit 50 acquires the projection image with reference to the original image.

FIG. 6A shows an example of the original image in the present embodiment, and FIG. 6B shows a state in which the original image shown in FIG. Yes.
As shown in FIG. 6A, the original image in the present embodiment is a pattern image in which a mesh-like pattern that is a repetitive pattern is formed on the entire surface.
When the original image of the mesh-like pattern is projected on the surface of the nail T as shown in FIGS. 4A and 4B having the uneven portion Ta and curved in the width direction, the projected image is as shown in FIG. As shown in FIG. 6B, the mesh pattern is distorted and deformed according to the shape of the nail T.
FIG. 7A shows a projection image which is a deformed image corresponding to the original image by removing the image of the nail T from the image captured by the imaging unit 50 (an image in which the projection image is superimposed on the nail T). An extracted example is shown.
As shown in FIG. 7A, when the original image is projected on the nail T having the uneven portion Ta on the surface, the mesh pattern of the original image shown in FIG. The part expands or contracts, causing distortion.

The deformation acquisition unit 814 compares the projected image after deformation (the image shown in FIG. 7A) with the original image before the deformation (the image shown in FIG. 6A) to determine which part of the original image is. Obtain the degree of deformation of how and how much it has been deformed.
In the present embodiment, when the original image is projected onto the surface of the nail T and photographed, and after obtaining the projection image, the deformation acquisition unit 814 compares the two and cannot detect deformation (displacement). The image projection unit 60 projects the original image onto the surface of the nail T while changing the angle in the in-plane direction, the imaging unit 50 acquires a plurality of projection images having different angles, and the deformation acquisition unit 814 For each of the plurality of projection images, the degree of deformation when the original image is used as a reference is acquired.
Specifically, the original image to be displayed on the display panel unit 61 is rotated by a predetermined angle in the in-plane direction, the original image after rotation is projected again on the surface of the nail T, and the projection image is acquired and deformed. Deformation (displacement) is detected by the acquisition unit 814.
Even when the deformation acquisition unit 814 can detect the deformation (displacement) by comparing the original image and the projected image, the original image is rotated a plurality of times by a predetermined angle, and a plurality of images captured at different angles are obtained. The projection image may be acquired. As a result, for example, even when using an original image such as a coarse lattice pattern or a stripe pattern, blank areas where correction information cannot be obtained can be reduced as much as possible, and more detailed and highly accurate correction information can be obtained. can do.
Note that it is not essential to acquire a plurality of projection images while rotating the original image in the in-plane direction, and correction information may be acquired from one projection image.
In addition, when rotating the original image, the rotation angle and the number of rotations are not particularly limited, and can be arbitrarily set.

The degree of deformation acquired by the deformation acquisition unit 814 may be any type of data. For example, data of which position in the projected image after deformation corresponds to each pixel constituting the original image (that is, how the coordinate value of each pixel has moved (displaced)) is acquired as deformation degree data. To do.
In addition, instead of acquiring the displacement of the coordinate values for all the pixels constituting the original image, for example, a predetermined point such as a point where the mesh pattern of the original image shown in FIG. The displacement of each coordinate value may be acquired and used as deformation degree data.
And the deformation | transformation acquisition part 814 will produce | generate reverse conversion data which eliminates the deformation | transformation from an original image to a projection image, if this deformation degree is acquired.

FIG. 7B shows an example of an image based on the inverse transform data.
As shown in FIG. 7B, an image based on the inverse transform data (image shown in FIG. 7B) is a projected image (image shown in FIG. 6A) based on the original image (image shown in FIG. 6A). The portion displaced (deformed) in the image shown in FIG. 7A is displaced (deformed) in the opposite direction to the projected image.
FIG. 7C illustrates how the image looks when an image based on the inverse transform data shown in FIG. 7B is projected onto the surface of the nail T.
As shown in FIG. 7C, when an image based on the inverse transformation data is projected onto the surface of the nail T, the mesh pattern in the original image (the image shown in FIG. 6A) is not directly distorted on the surface of the nail T. Projected. As described above, if the image data is an image that does not appear to be distortion when projected on the surface of the nail T, there is no apparent distortion even when the drawing is performed on the surface of the nail T based on the image data. An image can be drawn.

The nail information detected by the nail information detection unit 813 is stored in the nail information storage area 822 of the storage unit 82.
Further, the data of the degree of deformation from the original image to the projection image and the inverse transformation data acquired by the deformation acquisition unit 814 are stored as correction information in the correction information storage area 823 and the like.
The nail information stored in the nail information storage area 822 and the correction information stored in the correction information storage area 823 are referred to as correction data when the drawing data generation unit 815 described later generates drawing data.

In addition, when performing nail printing using the present nail printing apparatus 1, at least when using the apparatus for the first time, with respect to fingers that are scheduled to be drawn (for example, ten fingers from left and right thumbs to little fingers) Photographing is performed in a state in which the original image is sequentially projected on the nail T, information for identifying the acquired projected image and the user, information indicating each finger type (that is, the type of thumb, little finger, etc.) (finger type) Information and nail information indicating the shape of each nail T, nail images, and the like) may be stored in the correction information storage area 823 of the storage unit 82 and registered.
In this case, once registered correction information is stored until it is reset or updated, and in the second and subsequent drawing processing, if there is already registered information, this registered correction information is referred to as a default. You may make it do. In this way, it is not necessary to perform shooting or the like for obtaining correction information every time the drawing process is performed, and the drawing process can be performed more quickly without the labor and time required for this.

The drawing data generation unit 815 generates data for drawing applied to the nail T of the finger U1 by the drawing head 41 based on the nail information detected by the nail information detection unit 813 including the deformation acquisition unit 814.
Specifically, the drawing data generation unit 815 matches the shape of the nail T by enlarging, reducing, or cutting out nail design image data based on the shape of the nail T detected by the nail information detection unit 813. Align processing is performed.

In addition, the drawing data generation unit 815 appropriately performs correction corresponding to the curved surface shape or uneven shape of the nail T according to the correction information detected by the deformation acquisition unit 814.
Specifically, the drawing data generation unit 815 corrects the data of the drawing image to be drawn on the surface of the nail T, which is the drawing target surface, based on the degree of deformation acquired by the deformation acquisition unit 814, and generates the drawing data. Generate.
In the present embodiment, the drawing data generation unit 815 corrects drawing image data using the inverse transform data generated by the deformation acquisition unit 814.
For example, when the size of the projected image and the size of the drawn image are the same, the coordinate value of each pixel of the projected image and the image of the inversely transformed data obtained by inversely transforming the pixel, and each of the drawn image data The pixel coordinate values match.
For this reason, when the coordinate value of each pixel of the drawn image is converted in accordance with the coordinate value of each corresponding pixel of the image of the inverse conversion data, and is drawn on the surface of the nail T that is curved or has the uneven portion Ta In addition, it is possible to generate drawing data that looks the same as the original nail design.
When a plurality of shots are taken while changing the angle of the projection image and a plurality of projection images are acquired, the drawing data generation unit 815 draws the drawing target based on the degree of deformation of the plurality of projection images. The drawing image data to be drawn on the surface of the nail T which is a surface is corrected.

The drawing control unit 816 outputs a control signal to the drawing unit 40 based on the drawing data generated by the drawing data generation unit 815 and performs drawing according to the drawing data on the nail T. The control unit controls the 40 X-direction movement motors 46, the Y-direction movement motor 48, the drawing head 41, and the like.
In the present embodiment, the drawing control unit 816 controls the head moving unit 49 so that the photographing device 51 is disposed above (directly above) the nail T when photographing by the photographing unit 50 is performed.

  The display control unit 817 controls the display unit 13 to display various display screens on the display unit 13. In the present embodiment, the display control unit 817 includes, for example, a nail design selection screen, a thumbnail image for design confirmation, a nail image obtained by photographing the finger U1, an image obtained by projecting the original image on the nail T, and various instruction screens. An operation screen or the like is displayed on the display unit 13.

Next, a drawing data generation method and a drawing method using the drawing data according to the present embodiment will be described with reference to FIG.
When nail printing is performed by the nail printing apparatus 1, the display control unit 817 reads the nail design from the nail design storage area 824 and causes the display unit 13 to display a screen requesting the user to select a nail design (step S1). ). When the user selects one of the nail designs displayed on the display unit 13 by performing an input operation such as a touch operation, a desired nail design is selected as a design to be drawn on the nail T.
Further, the display control unit 817 displays an instruction screen for instructing to set the nail T to be drawn on the finger fixing unit 3 (step S2).
When set on the finger U1 finger fixing unit 3, the photographing control unit 811 controls the photographing unit 50 to photograph the nail T and obtain a nail image (step S3). Then, the nail information such as the contour of the nail T is detected by the nail information detection unit 813 (step S4).

Here, in the present embodiment, the control unit 81 determines, as a determination unit, whether or not it is a registered nail T from the nail information detected by the nail information detection unit 813 (step S5).
When the nail T is not already registered (step S5; NO), the projection control unit 812 controls the image projection unit 60, so that the surface of the nail T in the finger fixing unit 3 is shown in FIG. In this state, the nail T is photographed by the photographing unit 50, and a projection image as shown in FIG. 7A is acquired (step S6).
When the projection image is acquired, the deformation acquisition unit 814 compares the original image and the projection image to detect the degree of deformation (step S7). Then, the deformation acquisition unit 814 determines whether or not the degree of deformation has been detected (step S8), and if the deformation cannot be detected (step S8; NO), the image projection unit 60 projects an image projected onto the nail T. After rotating by a predetermined angle (step S9), the process returns to step S6 to repeat the process.

On the other hand, when the deformation can be detected (step S8; YES), the deformation acquisition unit 814 changes (displaces) the deformation degree data (that is, the coordinate value of each corresponding pixel in the original image and the projected image). )) Or inverse transformation data is generated and acquired as correction information (step S10), and the correction information is registered in the correction information storage area 823 (step S11).
When the nail T set on the finger fixing unit 3 is a registered nail T (step S5; YES), the drawing data generation unit 815 stores the nail registered in the correction information storage area 823. T correction information is read out (step S12).
Then, the drawing data generation unit 815 reads the drawing image data of the nail design selected by the user (step S13), and uses the drawing image data as correction information corresponding to the nail T and nail information including the nail design data. Based on the correction, drawing data is generated (step S14).
The drawing data generated by the drawing data generation unit 815 is sent to the drawing control unit 816, and the drawing control unit 816 outputs the drawing data to the drawing unit 40 to start the drawing process (step S15).
The drawing control unit 816 determines whether or not the drawing process has ended (step S16). If the drawing process has not ended (step S16; NO), the drawing control unit 816 returns to step S15 and continues the drawing process.
On the other hand, when the drawing of the nail design for the nail T is finished (step S16; YES), the drawing process in the present embodiment is finished.
When the drawing process is completed, a message to that effect may be displayed on the display unit 13 or the like.
When the drawing process ends, the user removes the finger U1 from the apparatus, and performs post-processing such as drying of the drawing part and application of an overcoat agent.

  Although not particularly described above, when drawing on the nail T with the nail printing apparatus 1 of the present embodiment, the user first applies a white or other undercoat agent to the nail region and then dries it. It is preferable to fix the finger U1 and its nail T to the finger fixing part 3 after performing the pretreatment.

As described above, according to the present embodiment, the projection image is acquired by photographing the surface of the nail T that is the drawing target surface in a state where the original image is projected by the image projection unit 60, and the original image is used as a reference. The degree of deformation of the projected image at this time is acquired, and based on this degree of deformation, the drawing image data drawn on the nail T, which is the drawing target surface, is corrected to generate drawing data.
As a result, even when there are irregularities Ta such as wrinkles and depressions on the surface of the nail T, it is possible to perform a beautifully finished nail print without distortion or deformation without pre-processing to trim the nail T and prepare the surface it can.
Therefore, it is possible to save time and labor for the user to perform pre-processing before nail printing, and to enjoy nail printing easily. Moreover, since it is not necessary to scrape the nail T as a pre-process, the thickness of the nail T is not reduced, and the risk of the cracking of the nail T and the occurrence of illness associated with the nail shaving can be avoided. .
Further, since the three-dimensional shape of the nail T can be grasped from the degree of deformation of the projected image when the original image is used as a reference, and the drawing data can be generated based on this, the nail that is curved in the width direction When drawing on T, it is not necessary to separately measure the shape of the nail T in the height direction. Further, since the three-dimensional shape of the nail T can be reflected in the drawing data, the shape of the nail T matches the shape of the nail T more than when the correction shape is determined by classifying the curved shape of the nail T into an existing pattern. In addition, accurate curved surface correction can be performed.

In this embodiment, the deformation acquisition unit 814 generates reverse conversion data that eliminates the deformation from the original image to the projection image, and the drawing data generation unit 815 uses the reverse conversion data to generate a drawing image. Correct the data.
As a result, accurate correction can be performed simply by applying the inverse transform data.

  In the present embodiment, since the original image projected by the image projection unit 60 is a pattern image in which a repetitive pattern is formed on the entire surface, correction information can be acquired over the entire surface of the nail T uniformly. it can.

  Further, as in the present embodiment, the image projection unit 60 projects the original image onto the surface of the nail T that is the drawing target surface while changing the angle in the in-plane direction, and the imaging unit 50 has a plurality of different angles. When the deformation acquisition unit 814 acquires the degree of deformation when the original image is used as a reference for each of the plurality of projection images, more detailed correction information is acquired for the entire surface of the nail T. can do. For this reason, the drawing data generation unit 815 performs correction with higher accuracy by correcting the data of the drawing image drawn on the nail T that is the drawing target surface based on the degree of deformation of the plurality of projection images. Is possible.

In the present embodiment, a storage unit 82 such as a correction information storage area 823 that functions as a registration unit that registers information for specifying a drawing target (nail T) and information indicating the shape of the drawing target, and a drawing unit A control unit that functions as a determination unit that determines whether or not the drawing target (nail T) on which drawing data is drawn by 40 is the drawing target (nail T) registered in the storage unit 82 that is a registration unit 81, and the image projecting unit 60 determines that the original image is not a drawing target (nail T) registered in the storage unit 82 that is a registration unit by the control unit 81 as a determination unit. Project to the drawing target surface (nail T).
For this reason, when an unregistered fingernail T is targeted, accurate correction information corresponding to the surface shape of the nail T can be acquired by projecting the original image, and the nail T is already registered. In the case where the information is already registered, the processing for obtaining the correction information can be omitted by using the already registered information, and a quick drawing process can be realized.

Further, the drawing target (nail T) drawn on the drawing target surface by the drawing unit 40 is not the drawing target registered in the storage unit 82 as the registration unit by the control unit 81 as the determination unit. In the storage unit 82 as a registration unit, information for specifying the drawing target (nail T) and information indicating the shape of the drawing target (nail T) are registered.
For this reason, the unregistered nail T can be simply and quickly drawn in the accurate nail T region by omitting various processes as the registered nail T from the next time.

  Although the embodiments of the present invention have been described above, the present invention is not limited to such embodiments, and various modifications can be made without departing from the scope of the present invention.

For example, in the present embodiment, the deformation acquisition unit 814 exemplifies the case of generating reverse conversion data that eliminates this deformation based on the degree of deformation from the original image to the projection image, but the deformation acquisition unit 814 performs reverse conversion. It is not essential to generate data.
For example, based on the degree of deformation data itself acquired by the deformation acquisition unit 814, the drawing data generation unit 815 applies correction to the drawing image data so as to eliminate the deformation from the original image to the projection image. Data may be generated.

In the present embodiment, the case where the nail design storage area 824 for storing the nail design image data is provided in the storage unit 82 of the nail print apparatus 1 is illustrated. However, the nail design image data is stored in the nail print apparatus 1. It is not limited to the case where it is preserve | saved in the memory | storage part 82.
For example, nail design image data may be stored in a server device or the like that can be connected via a network line or the like, and the nail design image data may be referred to by accessing the server device or the like.
In this way, it is possible to select a design to be drawn from among a larger number of nail designs.

In the present embodiment, the drawing head 41 of the nail printing apparatus (drawing apparatus) 1 includes the inkjet drawing head 41, but the configuration of the drawing head 41 is not limited to this.
For example, a pen holder that holds a drawing pen that performs drawing with a pen tip attached to the surface of the nail T may be provided, and drawing may be performed using the pen. Moreover, it is good also as a structure which comprises both the drawing head of an inkjet system like this embodiment, and the pen holder holding a drawing pen, and performs drawing using several drawing means.

  Further, the nail printing apparatus 1 may be provided with a drying unit including a heater and a fan for drying ink after drawing.

In the present embodiment, the case where the nail T of the finger U1 is fixed to the finger fixing unit 3 to perform shooting and drawing processing is illustrated, but the object that can be drawn in the nail printing apparatus (drawing apparatus) 1 is the finger U1. It is not limited to nail T.
For example, even a nail-like shape such as a nail chip used by being attached to the nail T can be a “nail” that can be drawn in the drawing system.

Although several embodiments of the present invention have been described above, the scope of the present invention is not limited to the above-described embodiments, but includes the scope of the invention described in the claims and equivalents thereof. .
The invention described in the scope of claims attached to the application of this application will be added below. The item numbers of the claims described in the appendix are as set forth in the claims attached to the application of this application.
[Appendix]
<Claim 1>
An image projection unit that projects the original image onto a drawing target surface to be drawn;
An imaging unit that acquires the projection image by imaging the drawing target surface in a state where the original image is projected by the image projection unit;
A deformation acquisition unit that acquires the degree of deformation of the projection image with respect to the original image;
A drawing data generation unit that generates data for drawing by correcting data of a drawing image to be drawn on the drawing target surface based on the degree of deformation acquired by the deformation acquisition unit;
A drawing data generation apparatus comprising:
<Claim 2>
The deformation acquisition unit generates inverse transformation data that eliminates deformation from the original image to the projection image,
The drawing data generation apparatus according to claim 1, wherein the drawing data generation unit corrects the data of the drawing image using the inverse transformation data.
<Claim 3>
The drawing data generation apparatus according to claim 1, wherein the original image projected by the image projection unit is a pattern image in which a repetitive pattern is formed on the entire surface.
<Claim 4>
The image projection unit projects the original image onto the drawing target surface while changing the angle in the in-plane direction,
The photographing unit acquires a plurality of the projection images having different angles,
The deformation acquisition unit acquires the degree of deformation when the plurality of projection images are based on the original image, respectively.
The drawing data generation unit according to any one of claims 1 to 3, wherein the drawing data generation unit corrects data of a drawing image to be drawn on the drawing target surface based on a degree of deformation of the plurality of projection images. Generator.
<Claim 5>
5. The drawing data generation apparatus according to claim 1, further comprising a drawing unit that performs drawing on the drawing target surface based on the drawing data generated by the drawing data generation unit.
<Claim 6>
A registration unit that registers information for specifying the drawing target and information indicating the shape of the drawing target;
A determination unit that determines whether or not the drawing target on which drawing data is drawn by the drawing unit is a drawing target registered in the registration unit;
The drawing data generation apparatus according to claim 5, wherein the image projection unit projects the original image onto the drawing target surface when the determination unit determines that the drawing target is not a drawing target registered in the registration unit.
<Claim 7>
The registration unit specifies the drawing target for the drawing target that is drawn on the drawing target surface by the drawing unit when the determining unit determines that the drawing target is not registered in the registration unit. The drawing data generation apparatus according to claim 5 or 6, wherein information to be registered and information indicating the shape of the drawing target are registered.
<Claim 8>
An image projection step of projecting the original image onto the drawing target surface;
A photographing step of photographing the drawing target surface in a state where the original image is projected in the image projecting step to obtain a projected image;
A deformation acquisition step of acquiring the degree of deformation of the projection image with reference to the original image;
A drawing data generation step of generating data for drawing by correcting data of a drawing image drawn on the drawing target surface based on the degree of deformation acquired in the deformation acquisition step;
A drawing data generation method including

DESCRIPTION OF SYMBOLS 1 Nail printing apparatus 40 Drawing part 41 Drawing head 50 Image | photographing part 60 Image projection part 81 Control part 82 Memory | storage part 811 Image | photographing control part 812 Projection control part 813 Nail information detection part 814 Deformation acquisition part T Nail U1 Finger

Claims (8)

An image projection unit that projects the original image onto a drawing target surface to be drawn;
An imaging unit that acquires the projection image by imaging the drawing target surface in a state where the original image is projected by the image projection unit;
A deformation acquisition unit that acquires the degree of deformation of the projection image with respect to the original image;
A drawing data generation unit that generates data for drawing by correcting data of a drawing image to be drawn on the drawing target surface based on the degree of deformation acquired by the deformation acquisition unit;
A drawing data generation apparatus comprising: The deformation acquisition unit generates inverse transformation data that eliminates deformation from the original image to the projection image,
The drawing data generation apparatus according to claim 1, wherein the drawing data generation unit corrects the data of the drawing image using the inverse transformation data.   The drawing data generation apparatus according to claim 1, wherein the original image projected by the image projection unit is a pattern image in which a repetitive pattern is formed on the entire surface. The image projection unit projects the original image onto the drawing target surface while changing the angle in the in-plane direction,
The photographing unit acquires a plurality of the projection images having different angles,
The deformation acquisition unit acquires the degree of deformation when the plurality of projection images are based on the original image, respectively.
The drawing data generation unit according to any one of claims 1 to 3, wherein the drawing data generation unit corrects data of a drawing image to be drawn on the drawing target surface based on a degree of deformation of the plurality of projection images. Generator.   5. The drawing data generation apparatus according to claim 1, further comprising a drawing unit that performs drawing on the drawing target surface based on the drawing data generated by the drawing data generation unit. A registration unit that registers information for specifying the drawing target and information indicating the shape of the drawing target;
A determination unit that determines whether or not the drawing target on which drawing data is drawn by the drawing unit is a drawing target registered in the registration unit;
The drawing data generation apparatus according to claim 5, wherein the image projection unit projects the original image onto the drawing target surface when the determination unit determines that the drawing target is not a drawing target registered in the registration unit.   The registration unit specifies the drawing target for the drawing target that is drawn on the drawing target surface by the drawing unit when the determining unit determines that the drawing target is not registered in the registration unit. The drawing data generation apparatus according to claim 5 or 6, wherein information to be registered and information indicating the shape of the drawing target are registered. An image projection step of projecting the original image onto the drawing target surface;
A photographing step of photographing the drawing target surface in a state where the original image is projected in the image projecting step to obtain a projected image;
A deformation acquisition step of acquiring the degree of deformation of the projection image with reference to the original image;
A drawing data generation step of generating data for drawing by correcting data of a drawing image drawn on the drawing target surface based on the degree of deformation acquired in the deformation acquisition step;
A drawing data generation method including

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