JP4826298B2 - Optically anisotropic medium creation system and method - Google Patents

Description

The present invention relates to a system for producing an optically anisotropic medium in which the reflection direction of light changes, and a method thereof.

Conventionally, by using optical anisotropy processing, a highly designable pattern is expressed, or the surface of a printed matter or the like is recognized three-dimensionally.
Optical anisotropic processing is a processing technology that realizes optical anisotropic reflection by forming directional irregularities on the substrate surface using processing methods such as printing and embossing. is there. Three-dimensional recognition is realized by changing the characteristics of the optical anisotropic reflection due to the fine unevenness according to the position.

For example, in Patent Document 1, a plurality of parallel line reflection shapes having different parallel line angles are prepared, and the parallel line reflection shape is selected according to the pixel position and pixel value of the two-dimensional image, A technique for reconstructing a two-dimensional image with a selected parallel line reflection shape to create an optically anisotropic two-dimensional image is disclosed. (Prior art 1)
Japanese Patent No. 3383004 (pages 5-7, FIGS. 1, 2, 5-8)

By the way, in the prior art 1, since the angle of each parallel line differs in the boundary of each parallel line reflection shape of an optical anisotropic two-dimensional image, the discontinuity of a parallel line angle arises in the boundary part of each reflection shape. As a result, the transition of anisotropic reflection cannot be recognized smoothly.

The present invention has been made in consideration of such prior art, and the object of the present invention is to make a design-preferable optically anisotropic medium by making the transition of anisotropic reflection more smoothly recognized. It is to provide a system to create.

The present invention solves the above problems by the following means. That is, the invention of claim 1
An optically anisotropic medium creating system comprising a CG image creating device, an optically anisotropic plate making device, a printing plate device, and an optically anisotropic medium creating device,
The CG image creation device includes:
Storage means for storing shape data and rendering data including shape color information and line-of-sight information;
CG image creation means for creating CG image data in which pixel normal vectors, pixel position information, pixel color information, and line-of-sight vectors are associated from shape data and rendering data;
Bei example a CG image data transmitting means for transmitting the CG image data to the optical anisotropic plate making apparatus, the,
The optical anisotropic plate-making apparatus is:
An optical anisotropic element data, storage means for storing the optically anisotropic image data, and
CG image data receiving means for receiving CG image data from the CG image creating device ;
And the projection surface angle accepting means for accepting the input of the projection surface angles,
For each pixel of the CG image plane, and obtains the pixel normal vector and a line-of-sight vector of the CG image data, sets the projection plane that intersects with the projection plane angle and the reference direction of the sight line vector and parallel CG image plane calculates the angle information and the projection normals Deki by projecting the pixel normal vector on the projection plane the CG image plane, and the pixel angle calculating means for the pixel angle,
Pattern data creating means for creating pattern data composed of optical anisotropic element data having the pixel angle;
Optical anisotropic image data creation means for associating the acquired pixel position information with the created pattern data and creating optical anisotropic image data including the pattern data;
Plate making data creating means for creating plate making data from CG image data;
Anisotropic plate making data creating means for creating anisotropic plate making data from optical anisotropic image data;
Bei example and a plate making data transmission means for transmitting the plate making data and an anisotropic plate making data to the printing plate device,
The plate apparatus is
Plate making data receiving means for receiving plate making data and anisotropic plate making data from the optical anisotropic plate making apparatus ,
A printing plate creating means for creating a color printing plate from the plate making data;
Bei example and anisotropic processing version creating means for creating an anisotropic processing version from the anisotropic plate making data, the,
The optically anisotropic medium creating device is:
Printing means for creating a print medium using a color printing plate;
Optical anisotropic medium processing means for creating an optical anisotropic medium from the created printing medium using an anisotropic processed plate,
An optical anisotropic medium production system comprising a Turkey provided with.

Here, the pattern data is prepared in advance as described in the prior art 1 in order to use optical anisotropy element data generated at each pixel position with an angle faithful to the pixel angle at the position. There is an effect of more smoothly recognizing the transition of anisotropic reflection compared to a method using the optically anisotropic element data having a plurality of angles, which is closest to the pixel angle at the position.

The invention of claim 2
Shape data, and the rendering data including shape color information and viewing information, the optical anisotropic element data, storage means for storing the optically anisotropic image data, and
CG image creation means for creating CG image data in which pixel normal vectors, pixel position information, pixel color information, and line-of-sight vectors are associated from shape data and rendering data;
And the projection surface angle accepting means for accepting the input of the projection surface angles,
For each pixel of the CG image plane, and obtains the pixel normal vector and a line-of-sight vector of the CG image data, sets the projection plane that intersects with the projection plane angle and the reference direction of the sight line vector and parallel CG image plane calculates the angle information and the projection normals Deki by projecting the pixel normal vector on the projection plane the CG image plane, and the pixel angle calculating means for the pixel angle,
Pattern data creating means for creating pattern data composed of optical anisotropic element data having the pixel angle;
Optically anisotropic image data creating means for associating the acquired pixel position information with the created optically anisotropic element data and creating optically anisotropic image data including the data,
Plate making data creating means for creating plate making data from CG image data;
Anisotropic plate making data creating means for creating anisotropic plate making data from optical anisotropic image data;
A printing plate creating means for creating a color printing plate from the plate making data;
Anisotropic plate making means for creating an anisotropic plate from anisotropic plate making data;
Printing means for creating a print medium using a color printing plate;
Optical anisotropic medium processing means for creating an optical anisotropic medium from the created printing medium using an anisotropic processed plate,
An optically anisotropic medium creating apparatus comprising:

The invention of claim 3
Storage means for storing CG image data, optical anisotropic element data, optical anisotropic image data, and plate making data in which a pixel normal vector, pixel position information, pixel color information, and a line-of-sight vector are associated with each other; ,
And the projection surface angle accepting means for accepting the input of the projection surface angles,
For each pixel of the CG image plane, and obtains the pixel normal vector and a line-of-sight vector of the CG image data, sets the projection plane that intersects with the projection plane angle and the reference direction of the sight line vector and parallel CG image plane calculates the angle information and the projection normals Deki by projecting the pixel normal vector on the projection plane the CG image plane, and the pixel angle calculating means for the pixel angle,
Pattern data creating means for creating pattern data composed of optical anisotropic element data having the pixel angle;
Optically anisotropic image data creating means for associating the acquired pixel normal information with the created pattern data and creating optical anisotropic image data including the pattern data;
Anisotropic plate making data creating means for creating anisotropic plate making data from optical anisotropic image data;
An optically anisotropic plate making apparatus comprising:

The invention of claim 4
An optically anisotropic medium creating system comprising a CG image creating device, an optically anisotropic plate making device, a printing plate device, and an optically anisotropic medium creating device,
The CG image creation device includes:
Storage means for storing shape data and rendering data including shape color information and line-of-sight information;
CG image creation means for creating CG image data in which pixel normal vectors, pixel position information, pixel color information, and line-of-sight vectors are associated from shape data and rendering data;
Bei example a CG image data transmitting means for transmitting the CG image data to the optical anisotropic plate making apparatus, the,
The optical anisotropic plate-making apparatus is:
Storage means for storing optically anisotropic element data and optically anisotropic image data;
CG image data receiving means for receiving CG image data from the CG image creating device ;
And the projection surface angle accepting means for accepting the input of the projection surface angles,
For each pixel of the CG image plane, and obtains the pixel normal vector and a line-of-sight vector of the CG image data, sets the projection plane that intersects with the projection plane angle and the reference direction of the sight line vector and parallel CG image plane calculates the angle information and the projection normals Deki by projecting the pixel normal vector on the projection plane the CG image plane, and the pixel angle calculating means for the pixel angle,
Pattern data creating means for creating pattern data composed of optical anisotropic element data having the pixel angle;
Optically anisotropic image data creating means for associating the acquired pixel position information with the created pattern data and creating optical anisotropic image data including the pattern data;
Anisotropic plate making data creating means for creating anisotropic plate making data from optical anisotropic image data;
Bei example a plate making data transmission means for transmitting an anisotropic plate making data to the printing plate device, a
The plate apparatus is
Plate making data receiving means for receiving anisotropic plate making data;
Bei example and anisotropic processing version creating means for creating an anisotropic processing version from the anisotropic plate making data, the,
The optically anisotropic medium creating device is:
Using anisotropic processing plate, optically anisotropic media processing means for creating an optical anisotropy medium, an optical anisotropic medium production system comprising a Turkey provided with.

The invention of claim 5
Shape data, rendering data including shape color information and line-of-sight information, CG image data in which pixel normal vectors, pixel position information, pixel color information, and line-of-sight vectors are associated, optical anisotropy element data, optical difference Storage means for storing anisotropic image data;
CG image creation means for creating CG image data from shape data and rendering data;
And the projection surface angle accepting means for accepting the input of the projection surface angles,
For each pixel of the CG image plane, and obtains the pixel normal vector and a line-of-sight vector of the CG image data, sets the projection plane that intersects with the projection plane angle and the reference direction of the sight line vector and parallel CG image plane calculates the angle information and the projection normals Deki by projecting the pixel normal vector on the projection plane the CG image plane, and the pixel angle calculating means for the pixel angle,
Pattern data creating means for creating pattern data composed of optical anisotropic element data having the pixel angle;
Optically anisotropic image data creating means for associating the acquired pixel position information with the created pattern data and creating optical anisotropic image data including the pattern data;
Anisotropic plate making data creating means for creating anisotropic plate making data from optical anisotropic image data;
Anisotropic plate making means for creating an anisotropic plate from anisotropic plate making data;
Optical anisotropic medium processing means for creating an optical anisotropic medium using an anisotropic processed plate,
An optically anisotropic medium creating apparatus comprising:

The invention of claim 6
Storage means for storing CG image data in which a pixel normal vector, pixel position information, pixel color information, and a line-of-sight vector are associated , optical anisotropic element data, and optical anisotropic image data;
And the projection surface angle accepting means for accepting the input of the projection surface angles,
For each pixel of the CG image plane, and obtains the pixel normal vector and a line-of-sight vector of the CG image data, sets the projection plane that intersects with the projection plane angle and the reference direction of the sight line vector and parallel CG image plane calculates the angle information and the projection normals Deki by projecting the pixel normal vector on the projection plane the CG image plane, and the pixel angle calculating means for the pixel angle,
Pattern data creating means for creating pattern data composed of optical anisotropic element data having the pixel angle;
Optically anisotropic image data creating means for associating the acquired pixel position information with the created pattern data and creating optical anisotropic image data including the pattern data;
Anisotropic plate making data creating means for creating anisotropic plate making data from optical anisotropic image data;
Plate making data transmission means for sending anisotropic plate making data;
An optically anisotropic plate-making apparatus comprising:

The invention of claim 7
Shape data, rendering data including shape color information and line-of-sight information, CG image data in which pixel normal vectors, pixel position information, pixel color information, and line-of-sight vectors are associated, optical anisotropy element data, optical difference An anisotropic optical medium creation method using anisotropic image data,
From the shape data and rendering data, and the CG image generation step of generating the CG image data,
And the projection surface angle acceptance step of accepting the input of the projection surface angles,
For each pixel of the CG image plane, and obtains the pixel normal vector and a line-of-sight vector of the CG image data, sets the projection plane that intersects with the projection plane angle and the reference direction of the sight line vector and parallel CG image plane calculates the angle information and the projection normals Deki by projecting the pixel normal vector on the projection plane the CG image plane, and the pixel angle calculation step of the pixel angle,
A pattern data creating step for creating pattern data composed of optical anisotropic element data having the pixel angle;
An optically anisotropic image data creating step of creating the optically anisotropic image data including the acquired pixel position information in association with the created pattern data;
Anisotropic plate making data creation step for creating anisotropic plate making data from optical anisotropic image data;
Anisotropic plate making step for creating an anisotropic plate from anisotropic plate making data;
An optically anisotropic medium processing step of creating an optically anisotropic medium using an anisotropic processed plate;
An optically anisotropic medium producing method, characterized in that it is performed by a procedure including:

According to an eighth aspect of the present invention, there is provided a plate making data creating step for creating plate making data from pixel information and pixel color information of CG image data, a printing plate creating step for creating a color printing plate from plate making data, and a color printing plate. Using the anisotropic processing plate, the optical anisotropic medium processing step is performed from the prepared printing medium using a anisotropic processing plate. The method for producing an optically anisotropic medium according to claim 7, wherein an optically anisotropic medium is produced.

The invention of claim 9, by incorporating in the computer, the computer,請 Motomeko 2, or a computer program for operating in an optically anisotropic medium production apparatus, according to claim 5.

The invention according to claim 10 is a computer program that causes a computer to operate as the optically anisotropic plate making apparatus according to claim 3 or claim 6 by being incorporated in the computer .

According to the present invention, it is possible to manufacture an optically anisotropic medium having excellent design properties by smoothly recognizing the transition of anisotropic reflection.

(Example)
Hereinafter, embodiments of the present invention will be described in more detail with reference to the drawings. FIG. 1 is a diagram illustrating an outline of an optically anisotropic medium creating system. The optically anisotropic medium creating system 1 includes a CG image creating apparatus 100, an optically anisotropic plate making apparatus 300, a printing plate apparatus 500, and an optically anisotropic medium creating apparatus 700 (for example, a printing processing apparatus). Composed.

The CG image creating apparatus 100 includes CG image shape data 191 (for example, three-dimensional CG model data), rendering data 193 including light source information, line-of-sight direction information, color information of each shape, pixel normal line information, and pixels. CG image data 199 (two-dimensional CG image data) in which position information, pixel color information, and line-of-sight information are associated with each other.

The optically anisotropic plate making apparatus 300 includes optically anisotropic image data in which optically anisotropic element data 391 (for example, rectangular data with rounded corners and elongated elliptical data), pixel position information, and pattern data are associated with each other. 393, plate-making data 398, and anisotropic plate-making data 399. Here, the pattern data is data composed of optical anisotropic element data 391 rotated by a predetermined angle.

The printing plate apparatus 500 includes plate making data 398, anisotropic plate making data 399, a color printing plate 599d, and an anisotropic processing plate 599a (for example, a foil stamping plate, an embossing plate, or a screen plate). Prepare. The optical anisotropic medium creation apparatus 700 includes a color printing plate 599d, an anisotropic processing plate 599a (for example, a foil stamping plate, an embossing plate, or a screen plate), and an optical anisotropic medium 799. .

The plate apparatus 500 may include only the anisotropic plate making data 399 and the anisotropic processed plate 599a (for example, a foil stamping plate, an embossed plate, or a screen plate).
Further, the optically anisotropic medium creating apparatus 700 may include only an anisotropic processed plate 599a (for example, a foil stamped plate, an embossed plate, or a screen plate) and only the optically anisotropic medium 799.

FIG. 2 illustrates a rough processing flow of the optically anisotropic medium creating system 1. The CG image creating apparatus 100 includes line-of-sight information (for example, line-of-sight vector) from shape data 191 (for example, three-dimensional CG model data) and rendering data 193 including color information and line-of-sight information (for example, line-of-sight vector). CG image data 199 including pixel coordinate information, pixel normal information (for example, normal vector), and pixel color information is created (FIG. 2 (1)). The CG image creating apparatus 100 transmits CG image data 199 ((2)).

The optically anisotropic plate making apparatus 300 receives the CG image data 199 ((3)). The optically anisotropic plate making apparatus 300 receives input of projection plane angle information ((4)). The optically anisotropic plate making apparatus 300 projects the pixel normal vector onto a projection plane that is parallel to the line-of-sight vector of the CG image data 199 and intersects the reference direction (for example, the horizontal direction) of the CG image plane at the projection plane angle. The angle information of the projection normal is calculated and set as the pixel angle ((5)).

Incidentally, the value of the pixel angle is a value in the range of “−90 °” to “+ 90 °”. After normalizing this by linearly converting from “−45 °” to “+ 45 °”, the following processing is performed.

The optically anisotropic plate making apparatus 300 rotates the pixel angle of the optically anisotropic element data 391 and arranges it in the pixel area to create pattern data ((6)).

At this time, the optical anisotropic element data 391 rotated by the pixel angle is adjusted in length so as not to contact the pixel region boundary when it is arranged in the pixel region. As a result, the optical anisotropy element data 391 of adjacent pixel regions do not touch each other and no inflection point is generated, so that individual flickers caused by microscopic anisotropic reflection are reduced, and human The eye has the effect that the anisotropic reflection changes smoothly.

The optically anisotropic plate making apparatus 300 creates optically anisotropic image data 393 including pattern data associated with pixel coordinates ((7)). The optical anisotropic plate making apparatus 300 creates anisotropic plate making data 399 from the optical anisotropic image data 393 ((8)). The optically anisotropic plate making apparatus 300 creates plate making data 398 from the CG image data 199 ((9)). The optically anisotropic plate making apparatus 300 transmits the plate making data 398 and the anisotropic plate making data 399 ((10)).

The plate making apparatus 500 receives the plate making data 398 and the anisotropic plate making data 399 ((11)). The printing plate apparatus 500 creates a color printing plate 599d from the plate making data 398 ((12)). The printing plate apparatus 500 creates an anisotropic processed plate 599a (for example, an embossed plate, a foil stamped plate, or a screen plate) from the anisotropic plate making data 399 ((13)).

The optically anisotropic medium creating apparatus 700 creates a print medium using the color printing plate 599d, and uses the anisotropic processed plate 599a (for example, an embossed plate, a foil stamping plate, or a screen plate) to print the print medium. Processing (for example, embossing using an embossing plate, foil pressing using a foil stamping plate, or screen printing processing using a screen plate) to create an optically anisotropic medium 799 (for example, an anisotropic reflective sheet) (Same as (14)).

3 and 4 are detailed configuration diagrams of the optically anisotropic medium creating system 1. The optically anisotropic medium creating system 1 includes a CG image creating apparatus 100, an optically anisotropic plate making apparatus 300, a printing plate apparatus 500, and an optically anisotropic medium creating apparatus 700 (printing processing apparatus). FIG. 3 is a detailed configuration diagram of the CG image creating apparatus 100 and the optically anisotropic plate making apparatus 300.

The CG image creation apparatus 100 includes a CG image data transmission unit 110, a CG image creation unit 120, and a storage unit 190. The storage unit 190 stores shape data 191, rendering data 193, and CG image data 199.

The rendering data 193 is data including shape color information and line-of-sight information (for example, line-of-sight vector). The CG image data 199 is data in which pixel normal line information, pixel position information, pixel color information, and line-of-sight information (for example, line-of-sight vector) are associated with each other.

The CG image creation unit 120 creates CG image data 199 from the shape data 191 and the rendering data 193. The CG image data transmission unit 110 transmits CG image data 199.

The CG image data transmission unit 110 and the CG image creation unit 120 are computer programs. The shape data 191, rendering data 193, and CG image data 199 are data that can be read by a computer program. The storage unit 190 is a memory.

The optical anisotropic plate making apparatus 300 includes a CG image data receiving unit 310, a projection plane angle receiving unit 320, a pixel angle calculating unit 330, a pattern data generating unit 355, an optical anisotropic image data generating unit 360, A plate making data creation unit 385, an anisotropic plate making data creation unit 380, a plate making data transmission unit 312, and a storage unit 390 are provided. The storage unit 390 stores optical anisotropic element data 391, optical anisotropic image data 393, CG image data 199, anisotropic plate making data 399, and plate making data 398.

The optical anisotropic element data 391 is data including a linear shape, for example. The optically anisotropic image data 393 is data data in which pixel position information and optically anisotropic element data 391 are associated with each other.

The CG image data receiving unit 310 receives CG image data. Projection plane angle receiving means 320 receives input of projection plane angle information. The pixel angle calculation unit 330 acquires the pixel normal line information and the line-of-sight information of the CG image data 199, is parallel to the line of sight, and intersects the reference direction (for example, the horizontal direction) of the CG image plane at a projection plane angle. The angle information of the projection normal obtained by projecting the pixel normal onto the projection plane to be calculated is used as the pixel angle. The turn data creation means 355 acquires the pixel angle, generates optical anisotropy element data obtained by rotating the optical anisotropy element by the pixel angle, and uses this to create pattern data. (Details will be described later.) The optically anisotropic image data creating unit 360 refers to the CG image data 199, acquires pixel position information corresponding to the pixel normal information, and the created pattern. Optical anisotropy image data 393 including pattern data associated with pixel position information is created in association with the data. The plate making data creating means 385 creates plate making data 398 from the pixel information and pixel color information of the CG image data 199. The anisotropic plate making data creating unit 380 creates anisotropic plate making data 399 from the optical anisotropic image data 393. The plate making data transmission means 312 sends the plate making data 398 and the anisotropic plate making data 399.

CG image data reception means 310, projection plane angle reception means 320, pixel angle calculation means 330, pattern data creation means 355, optical anisotropic image data creation means 360, plate making data creation means 385, anisotropic The characteristic plate making data creation means 380 and the plate making data transmission means 312 are computer programs. The optical anisotropic element data 391, the optical anisotropic image data 393, the anisotropic plate making data 399, and the plate making data 398 are data that can be read by a computer program. The storage unit 390 is a memory.

FIG. 4 is a detailed configuration diagram of the printing plate apparatus 500 and the optically anisotropic medium creating apparatus 700.

The plate apparatus 500 includes plate making data receiving means 512, printing plate creating means 585, anisotropic processed plate creating means 580, and storage means 590. The storage unit 590 stores plate making data 398 and anisotropic plate making data 399.

The plate making data receiving means 512 receives the plate making data 398 and the anisotropic plate making data 399. The printing plate creating means 585 creates a color printing plate 599d from the plate making data 398. The anisotropic processed plate creating means 580 creates an anisotropic processed plate 599a from the anisotropic plate making data 399.

The plate making data receiving means 512 is a computer program. The printing plate creating means 585 and the anisotropic processed plate creating means 580 are printing plate machines. The storage unit 590 is a memory.

The optically anisotropic medium creating apparatus 700 includes a printing unit 785 and an optically anisotropic medium processing unit 780. The printing unit 785 creates a print medium using the color printing plate 599d. The optical anisotropic medium processing means 780 uses the anisotropic processed plate 599a to generate the optical anisotropic medium 799 from the generated print medium.

The printing unit 785 is a printing machine. The optical anisotropic medium processing means 780 is a printing machine or a processing machine.

FIG. 5 shows the structure and example of the shape data 191. The item of the shape data 191 includes a shape object type 191a and a shape object coordinate value 191b. The shape object type 191a is a type of shape figure. The shape object coordinate value 191b is a coordinate value of the shape figure.

In FIG. 5, “shape object type 191a = cylindrical object” and “shape object coordinate value 191b = upper bottom circle center coordinate / upper bottom circle radius / cylinder height / lower bottom circle center coordinate / lower bottom circle radius”, “ Shape object type 191a = polygonal column object ”and“ shape object coordinate value 191b = upper bottom polygon vertex coordinate / polygonal column height / lower bottom polygon vertex coordinate ”,“ shape object type 191a = circular object ”and“ shape ” Object coordinate value 191b = center coordinate / radius / height ”,“ shape object type 191a = polygonal object ”and“ shape object coordinate value 191b = polygon vertex coordinate / height ”,“ shape object type 191a = planar object ” And “shape object coordinate value 191b = plane boundary point coordinate”, “shape object type 191a = curve Object "and" shape object coordinate value 191b = surface point coordinate / surface point interpolation formula ", etc. are exemplified.

FIG. 6 is a diagram for explaining the structure of the rendering data 193. The items of the rendering data 193 include “diffuse reflectance K”, “incident light intensity I”, “angle (incident angle) α between the incident direction of light and the surface normal”, and “specular reflectance”. “M”, “parameter N for controlling the highlight characteristic (sharpness)”, “angle γ between the viewpoint direction and the regular reflection direction”, “reflectance D with respect to ambient light”, and “intensity of ambient light” A ”.

FIG. 7 is an explanatory diagram of the structure and example of the CG image data 199. The CG image data 199 includes line-of-sight information 199a, pixel number 199b, pixel position information 199c, pixel normal line information 199d, and pixel color information 199e. The line-of-sight information 199a is a line-of-sight direction vector (x component, y component, z component). The pixel number 199b represents pixel array information (for example, array position on the two-dimensional CG image plane = value of x array position, value of y array position). The pixel position information 199c is an x coordinate value and a y coordinate value of the pixel. The pixel normal line information 199d is normal line information (elevation angle and azimuth angle with respect to the CG image plane) of shape data corresponding to the pixel. The pixel color information 199e is the RGB value of the pixel.

FIG. 7 shows an example in which the pixel arrangement of the CG image is “pixel ₁₁ ”, “pixel ₂₁ ”,..., “Pixel ₁₂ ”, “pixel ₂₂ ”,.

FIG. 8 is an explanatory diagram of the optical anisotropic element data 391. The optical anisotropic element data 391 is graphic data including a linear shape.

FIG. 8 illustrates rectangular data with rounded corners and elongated elliptical data.

FIG. 9 is a diagram for explaining the format and example of the optically anisotropic image data 393. The optically anisotropic image data 393 includes pixel numbers 393a, pixel position information 393b, and pattern data 393c. The pixel number 393a represents pixel arrangement information of the optically anisotropic image (for example, the arrangement position of the optically anisotropic image plane = the value of the x arrangement position, the value of the y arrangement position). The pixel position information 393b is an x coordinate value and a y coordinate value of the pixel. The pattern data 393c is data generated from the optical anisotropic element data 391 rotated by the pixel angle. (Details will be described later.)

FIG. 9 shows an example in which the pixel arrangement of the optically anisotropic image is “pixel ₁₁ ” “pixel ₂₁ ”..., “Pixel ₁₂ ” “pixel ₂₂ ”.

FIG. 10 is a diagram for explaining the format of the plate making data 398. The plate making data 398 is composed of a management data portion and an image data portion. The management data part has a plate making data ID and a plate making size. The image data portion has an image ID, layout data (for example, image coordinate values, image size, etc.), and image data (for example, halftone dot data of the printing color CMYK).

FIG. 11 is a diagram for explaining the format of the anisotropic plate making data 399. The anisotropic plate making data 399 includes a management data portion and an image data portion. The management data part has a plate making data ID and a plate making size. The image data portion has an image ID, layout data (for example, image coordinate value, image size, etc.), and image data (pattern data 391b).

Here, the pixel normal information 199d of the CG image data 199 will be described. FIG. 12 is an explanatory diagram of pixel normal lines of a CG image. The pixel normal of the CG image is a normal of a point in the shape data 191 corresponding to the pixel. For example, the pixel normal information of the pixel 199g of the CG image is the normal information 199d of the point of the cylinder 191g with respect to the two-dimensional CG image plane.

Next, pixel color information 199e of the CG image data 199 will be described. FIG. 13 is an explanatory diagram of an equation for calculating the pixel color information 199e of the CG image. The pixel color information 199e of the CG image data 199 is calculated by using the rendering data 193 to calculate the pixel color information by diffuse reflection, the pixel color information by specular reflection, and the pixel color information by ambient light, and the sum thereof. . Here, pixel color information by diffuse reflection is calculated by a diffuse reflection calculation formula “IK cos α”. Pixel color information by specular reflection is calculated by a specular reflection calculation formula “IMcos ^N γ”. Also, pixel color information by ambient light is calculated by the ambient light calculation formula “AD”.

Note that the CG image pixel color information calculation formula shown in FIG. 13 is a general shading calculation formula using Phong's specular reflection model.

FIG. 14 is an explanatory diagram of the angle of the projection normal obtained by projecting the pixel normal vector onto a predetermined projection plane. Projection plane 394 is parallel to line-of-sight vector 199a (generally, the line-of-sight vector is perpendicular to the two-dimensional CG image plane), and a reference direction (eg, horizontal direction) within two-dimensional CG image plane 199. ) And the projection plane angle 392 that received the input. The projection normal 396, two-dimensional CG image plane 199 of the pixel XY pixel normal vector 199d is a projected line on the projection surface. The angle formed by the projection normal 396 and the two-dimensional CG image plane 199 is projection normal angle information 397 (= pixel angle).

15 to 17 are explanatory diagrams of the pattern data 393c.

FIG. 15 is a diagram for explaining a procedure for creating the optical anisotropic image data 393. Optical anisotropy element data 391 (for example, element B) is rotated by a pixel angle 397 (FIG. 15 (1)). Here, the above-described pixel angle is obtained in a range from “−90 °” to “+ 90 °”, but is normalized in advance to a range such as “−45 °” to “+ 45 °” and the like as shown in FIG. It is desirable to apply the rotation shown in FIG.

The rotated optical anisotropic element data 391 is arranged in a predetermined area to create pattern data 393c ((2)). At this time, the optical anisotropy element data 391 that has been rotated is arranged with its length adjusted so as not to contact the region boundary of the pattern data 393c.

FIG. 16 is an example in which pattern data 393c using the optically anisotropic element data of element B is arranged at the pixel position. The adjacent pattern data 393c does not contact the rotated optical anisotropic element data 391, so that a bending point does not occur.

FIG. 17 shows an example in which pattern data 393c using the optically anisotropic element data of element A is arranged at the pixel position. Similar to FIG. 16, the adjacent pattern data 393c does not contact the rotated optical anisotropic element data 391, so that no bending point is generated.

The optical anisotropic medium creation system 1 may be a single device.

Here, an example of conventional pattern data will be described.
(Reference example)
FIG. 18 is an example of pattern data in which the optical anisotropic element data is a parallelogram.
The pattern data in which optical anisotropic element data 391 obtained by rotating the angle of the parallelogram side of the optical anisotropic element by the pixel angle 397 is arranged in a predetermined area is illustrated.

The rotated optically anisotropic element data 391 is in contact with a predetermined region and has a cut shape at the boundary line of the region. Therefore, because the discontinuity occurs in the angle of the parallelogram side of the optical anisotropic element at the boundary of the region, the size of the predetermined region is visually recognized, so that the discontinuity of the reflected light is visually recognized. The Furthermore, when the predetermined area is sufficiently large and the parallelogram parallel lines of the optically anisotropic element can be visually recognized, there is a problem that the discontinuity of the line segments themselves can be recognized.

As described above in detail, according to the present invention, an optically anisotropic medium having excellent design properties capable of smoothly recognizing the transition of anisotropic reflection can be produced.

Overall configuration of optical anisotropic medium creation system Rough processing flow of the optical anisotropic medium creation system 1 Detailed configuration diagram of optically anisotropic medium creation system 1 (1) Detailed configuration diagram of optically anisotropic medium creation system 1 (2) Shape data structure and examples Rendering data structure Structure and example of CG image data 199 Structure and example of optical anisotropic element data 391 Optical anisotropic image data 393 Format of plate making data 398 Format of anisotropic plate making data 399 Explanatory drawing of pixel normal of 2D CG image Formula for calculating pixel color information of CG image Angle information of the projection normal created by projecting the pixel normal vector onto the projection plane The figure explaining the creation procedure of optical anisotropic image data 393 Example in which pattern data using optical anisotropic element data of element B is arranged at a pixel position Example in which pattern data using optical anisotropy element data of element A is arranged at a pixel position (Reference example) Example of conventional pattern data

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Optical anisotropic medium production system 100 CG image production apparatus 110 CG image data transmission means 120 CG image production means 190 Storage means 191 Shape data 191a Shape object kind 191b Shape object coordinate value 193 Rendering data 199 CG image data 199a Gaze direction vector 199b Pixel number 199c Pixel position information 199d Pixel normal information 199e Pixel color information 300 Optical anisotropic plate making apparatus 310 CG image data receiving means 312 Plate making data sending means 320 Projection plane angle receiving means 330 Pixel angle calculating means 355 Pattern data creating means 360 Optical anisotropic image data creation means 380 Anisotropic plate making data creation means 385 Plate making data creation means 390 Storage means 391 Optical anisotropic element data 393 Optical anisotropic image data 393a Pixel number No. 393b Pixel position information 393c Pattern data
394 Projection plane
396 Projection normal 397 Angle information of projection normal 398 Plate making data 399 Anisotropic plate making data 500 Plate making apparatus 512 Plate making data receiving means 580 Anisotropic processed plate making means 585 Printing plate making means 590 Storage means 599d Color printing plate 599a Anisotropic processed plate 700 Optical anisotropic medium creation device 780 Optical anisotropic medium processing means 785 Printing means 799 Optical anisotropic medium

Claims (10)

An optically anisotropic medium creating system comprising a CG image creating device, an optically anisotropic plate making device, a printing plate device, and an optically anisotropic medium creating device,
The CG image creation device includes:
Storage means for storing shape data and rendering data including shape color information and line-of-sight information;
CG image creation means for creating CG image data in which pixel normal vectors, pixel position information, pixel color information, and line-of-sight vectors are associated from shape data and rendering data;
CG image data transmission means for transmitting CG image data to the optical anisotropic plate making apparatus,
The optical anisotropic plate-making apparatus is:
Storage means for storing optically anisotropic element data and optically anisotropic image data;
CG image data receiving means for receiving CG image data from the CG image creating device;
A projection plane angle receiving means for receiving an input of the projection plane angle;
For each pixel on the CG image plane, the pixel normal vector and the line-of-sight vector of the CG image data are acquired, and a projection plane that is parallel to the line-of-sight vector and intersects the reference direction of the CG image plane at the projection plane angle is set. Pixel angle calculation means for calculating angle information between a projection normal obtained by projecting the pixel normal vector onto the projection plane and the CG image plane,
Pattern data creating means for creating pattern data composed of optical anisotropic element data having the pixel angle;
Optical anisotropic image data creation means for associating the acquired pixel position information with the created pattern data and creating optical anisotropic image data including the pattern data;
Plate making data creating means for creating plate making data from CG image data;
Anisotropic plate making data creating means for creating anisotropic plate making data from optical anisotropic image data;
Plate making data transmitting means for sending plate making data and anisotropic plate making data to the plate making apparatus,
The plate apparatus is
Plate making data receiving means for receiving plate making data and anisotropic plate making data from the optical anisotropic plate making apparatus,
A printing plate creating means for creating a color printing plate from the plate making data;
Anisotropic plate making means for creating an anisotropic plate from anisotropic plate making data,
The optically anisotropic medium creating device is:
Printing means for creating a print medium using a color printing plate;
Optical anisotropic medium processing means for creating an optical anisotropic medium from the created printing medium using an anisotropic processed plate,
An optically anisotropic medium creating system comprising: Storage means for storing shape data, rendering data including shape color information and line-of-sight information, optical anisotropic element data, and optical anisotropic image data;
CG image creation means for creating CG image data in which pixel normal vectors, pixel position information, pixel color information, and line-of-sight vectors are associated from shape data and rendering data;
A projection plane angle receiving means for receiving an input of the projection plane angle;
For each pixel on the CG image plane, the pixel normal vector and the line-of-sight vector of the CG image data are acquired, and a projection plane that is parallel to the line-of-sight vector and intersects the reference direction of the CG image plane at the projection plane angle is set. Pixel angle calculation means for calculating angle information between a projection normal obtained by projecting the pixel normal vector onto the projection plane and the CG image plane,
Pattern data creating means for creating pattern data composed of optical anisotropic element data having the pixel angle;
Optically anisotropic image data creating means for associating the acquired pixel position information with the created optically anisotropic element data and creating optically anisotropic image data including the data,
Plate making data creating means for creating plate making data from CG image data;
Anisotropic plate making data creating means for creating anisotropic plate making data from optical anisotropic image data;
A printing plate creating means for creating a color printing plate from the plate making data;
Anisotropic plate making means for creating an anisotropic plate from anisotropic plate making data;
Printing means for creating a print medium using a color printing plate;
Optical anisotropic medium processing means for creating an optical anisotropic medium from the created printing medium using an anisotropic processed plate,
An optically anisotropic medium creating apparatus comprising: Storage means for storing CG image data, optical anisotropic element data, optical anisotropic image data, and plate making data in which a pixel normal vector, pixel position information, pixel color information, and a line-of-sight vector are associated with each other; ,
A projection plane angle receiving means for receiving an input of the projection plane angle;
For each pixel on the CG image plane, the pixel normal vector and the line-of-sight vector of the CG image data are acquired, and a projection plane that is parallel to the line-of-sight vector and intersects the reference direction of the CG image plane at the projection plane angle is set. Pixel angle calculation means for calculating angle information between a projection normal obtained by projecting the pixel normal vector onto the projection plane and the CG image plane,
Pattern data creating means for creating pattern data composed of optical anisotropic element data having the pixel angle;
Optically anisotropic image data creating means for associating the acquired pixel normal information with the created pattern data and creating optical anisotropic image data including the pattern data;
Anisotropic plate making data creating means for creating anisotropic plate making data from optical anisotropic image data;
An optical anisotropic plate making apparatus. An optically anisotropic medium creating system comprising a CG image creating device, an optically anisotropic plate making device, a printing plate device, and an optically anisotropic medium creating device,
The CG image creation device includes:
Storage means for storing shape data and rendering data including shape color information and line-of-sight information;
CG image creation means for creating CG image data in which pixel normal vectors, pixel position information, pixel color information, and line-of-sight vectors are associated from shape data and rendering data;
CG image data transmission means for transmitting CG image data to the optical anisotropic plate making apparatus,
The optical anisotropic plate-making apparatus is:
Storage means for storing optically anisotropic element data and optically anisotropic image data;
CG image data receiving means for receiving CG image data from the CG image creating device;
A projection plane angle receiving means for receiving an input of the projection plane angle;
For each pixel on the CG image plane, the pixel normal vector and the line-of-sight vector of the CG image data are acquired, and a projection plane that is parallel to the line-of-sight vector and intersects the reference direction of the CG image plane at the projection plane angle is set. Pixel angle calculation means for calculating angle information between a projection normal obtained by projecting the pixel normal vector onto the projection plane and the CG image plane,
Pattern data creating means for creating pattern data composed of optical anisotropic element data having the pixel angle;
Optically anisotropic image data creating means for associating the acquired pixel position information with the created pattern data and creating optical anisotropic image data including the pattern data;
Anisotropic plate making data creating means for creating anisotropic plate making data from optical anisotropic image data;
Plate making data transmitting means for sending anisotropic plate making data to the plate making apparatus,
The plate apparatus is
Plate making data receiving means for receiving anisotropic plate making data;
Anisotropic plate making means for creating an anisotropic plate from anisotropic plate making data,
The optically anisotropic medium creating device is:
An optically anisotropic medium creating system comprising: an optically anisotropic medium processing unit that creates an optically anisotropic medium using an anisotropically processed plate. Shape data, rendering data including shape color information and line-of-sight information, CG image data in which pixel normal vectors, pixel position information, pixel color information, and line-of-sight vectors are associated, optical anisotropy element data, optical difference Storage means for storing anisotropic image data;
CG image creation means for creating CG image data from shape data and rendering data;
A projection plane angle receiving means for receiving an input of the projection plane angle;
For each pixel on the CG image plane, the pixel normal vector and the line-of-sight vector of the CG image data are acquired, and a projection plane that is parallel to the line-of-sight vector and intersects the reference direction of the CG image plane at the projection plane angle is set. Pixel angle calculation means for calculating angle information between a projection normal obtained by projecting the pixel normal vector onto the projection plane and the CG image plane,
Pattern data creating means for creating pattern data composed of optical anisotropic element data having the pixel angle;
Optically anisotropic image data creating means for associating the acquired pixel position information with the created pattern data and creating optical anisotropic image data including the pattern data;
Anisotropic plate making data creating means for creating anisotropic plate making data from optical anisotropic image data;
Anisotropic plate making means for creating an anisotropic plate from anisotropic plate making data;
Optical anisotropic medium processing means for creating an optical anisotropic medium using an anisotropic processed plate,
An optically anisotropic medium creating apparatus comprising: Storage means for storing CG image data in which a pixel normal vector, pixel position information, pixel color information, and a line-of-sight vector are associated, optical anisotropic element data, and optical anisotropic image data;
A projection plane angle receiving means for receiving an input of the projection plane angle;
For each pixel on the CG image plane, the pixel normal vector and the line-of-sight vector of the CG image data are acquired, and a projection plane that is parallel to the line-of-sight vector and intersects the reference direction of the CG image plane at the projection plane angle is set. Pixel angle calculation means for calculating angle information between a projection normal obtained by projecting the pixel normal vector onto the projection plane and the CG image plane,
Pattern data creating means for creating pattern data composed of optical anisotropic element data having the pixel angle;
Optically anisotropic image data creating means for associating the acquired pixel position information with the created pattern data and creating optical anisotropic image data including the pattern data;
Anisotropic plate making data creating means for creating anisotropic plate making data from optical anisotropic image data;
Plate making data transmission means for sending anisotropic plate making data;
An optically anisotropic plate making apparatus comprising: Shape data, rendering data including shape color information and line-of-sight information, CG image data in which pixel normal vectors, pixel position information, pixel color information, and line-of-sight vectors are associated, optical anisotropy element data, optical difference An anisotropic optical medium creation method using anisotropic image data,
A CG image creation step of creating the CG image data from shape data and rendering data;
A projection plane angle receiving step for receiving an input of the projection plane angle;
For each pixel on the CG image plane, the pixel normal vector and the line-of-sight vector of the CG image data are acquired, and a projection plane that is parallel to the line-of-sight vector and intersects the reference direction of the CG image plane at the projection plane angle is set. Calculating a pixel angle by calculating angle information between a projection normal obtained by projecting the pixel normal vector on the projection plane and the CG image plane; and
A pattern data creating step for creating pattern data composed of optical anisotropic element data having the pixel angle;
An optically anisotropic image data creating step of creating the optically anisotropic image data including the acquired pixel position information in association with the created pattern data;
Anisotropic plate making data creation step for creating anisotropic plate making data from optical anisotropic image data;
Anisotropic plate making step for creating an anisotropic plate from anisotropic plate making data;
An optically anisotropic medium processing step of creating an optically anisotropic medium using an anisotropic processed plate;
A method for producing an optically anisotropic medium, comprising: A plate making data creating step for creating plate making data from pixel information and pixel color information of CG image data;
A printing plate creation step for creating a color printing plate from plate making data;
A printing step of creating a print medium using a color printing plate;
It is characterized by being done in a procedure that includes
The optically anisotropic medium creation method according to claim 7, wherein the optically anisotropic medium processing step creates an optically anisotropic medium from the created print medium using an anisotropic processed plate. By incorporating a computer, a computer,請 Motomeko 2, or optically anisotropic medium production apparatus according to claim 5, and to a computer program for operating. A computer program that causes a computer to operate as the optically anisotropic plate making apparatus according to claim 3 or 6 by being incorporated in the computer .

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