JP4671213B2 - 3D material image providing method, providing system, providing program, and storage medium storing provided program - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention provides, for example, a three-dimensional material image providing method, a providing system, a providing program, a storage medium storing a providing program, and a providing program for providing a material image such as an arrow to be used when creating a presentation material or the like The present invention relates to a transmission medium for transmitting a message.
[0002]
[Prior art]
For example, when creating materials for presentations, in order to make the materials easier to understand and beautiful, for example, arrows, computer bodies, buildings, plants, symbols, and other material images representing other objects are illustrated. It is often inserted into. Many of such material images are provided by a material image providing system. In the material image providing system, a server having a material image database provides material images via a network such as the Internet, or material images are provided by software operating on a terminal and a material image database without using a network. There is also. In the case of a material image providing system via the Internet, the user accesses the server from the home page via the Internet, and selects a desired material image from the material image database in which a plurality of material image data is registered. A material image is obtained by downloading from a server to its own terminal via the Internet, and is inserted into a presentation material or the like for use.
[0003]
Currently, most of the material image data provided by the material providing system is a two-dimensional material image composed of planes, as shown in FIG. 9, for example. After the two-dimensional material image is downloaded to the user's terminal, it is inserted into the material as it is without being processed. In addition, the two-dimensional material image can be visually divided into an object portion and a background portion, but the data is not distinguished and is used as a unit.
[0004]
However, the two-dimensional material image has the advantage that the amount of data is small and does not require time to download, but the user can only process the enlargement / reduction and color change, and cannot be processed in three dimensions. And the degree of freedom of processing was low. In particular, as shown in FIG. 9A, currently provided two-dimensional material images often have no sense of unity in the orientation of objects such as printers, servers, and terminals. Processing that changes the orientation of the object is impossible. For this reason, when a plurality of two-dimensional material images are used for the same material, as shown in FIG. 9B, there is a strong user's desire to align the objects in a uniform direction. Therefore, it was not possible to give a sense of unity to the direction of the object. In addition, in order to correct such inconvenience, it is necessary to prepare in advance a two-dimensional material image displayed from various directions for one object and register it in the database, which increases the amount of data. It was.
[0005]
Therefore, in recent years, three-dimensional material images composed of three-dimensional images have been provided. As shown in FIG. 10, the three-dimensional material image is composed of a three-dimensional space (object space) based on a three-dimensional coordinate system (X-axis, Y-axis, Z-axis) and a target object. It exists in the three-dimensional space as a mesh line connecting the coordinates. Note that at the time of being provided to the user, various processes are performed, and finally a three-dimensional material image with colors, gloss, and the like is applied. Since 3D material images can be freely rotated using existing 3D image processing software, the user downloads the material image to the terminal, and then the 3D material image is downloaded. Can be inserted and used after changing the orientation of the displayed object. Therefore, when multiple material data representing objects such as printers, servers, and terminals are used for the same material, the user unifies the objects displayed in the 3D material image by rotating the 3D material image. It can be used in the same orientation. In addition, since the user can freely change the direction of the object in the 3D material image, it is only necessary to register one material image for the object in the material image database, and the number of material images increases. There is nothing.
[0006]
Here, a rendering process for displaying a three-dimensional image on a display device will be described with reference to FIG. For convenience of explanation, the rectangular parallelepiped 7 will be described as an example of an object. When the user activates existing 3D image software and reads a 3D material image, the terminal performs rendering according to the existing 3D image processing software. Rendering is a process for projecting a three-dimensional image onto a projection plane to generate a two-dimensional projection image, and is a process for displaying the three-dimensional image as a two-dimensional image. When rendering a three-dimensional image on a computer, a “viewpoint” where the three-dimensional image is viewed from and a “attention point” indicating where the three-dimensional image is viewed are specified. Both “viewpoint” and “attention point” are three-dimensional coordinate values. When the user sets the coordinates of the viewpoint (x1, y1, z1) and the point of interest (x0, y0, z0) in the three-dimensional space of the three-dimensional material image, the three-dimensional material image is viewed from the viewpoint (x1, y1) by rendering. , Z1) is projected onto the projection surface in the direction from the point of interest (x0, y0, z0) to generate a two-dimensional projection material image. By rendering, a three-dimensional material image can be projected onto a two-dimensional world called a projection plane 8 and displayed on the display device as a two-dimensional projection material image.
[0007]
Next, processing for changing the direction of the object 7 will be described. When the user wants to change the direction of the object 7 in the projection material image displayed on the display device, the user changes the coordinates of the viewpoint by operating the mouse or the like. The terminal sequentially generates projection material images by rendering according to the change of the coordinates of the viewpoint, and outputs the projection material images to the display device. In other words, the user can change the orientation of the object 7 displayed in the projection material image by moving the viewpoint to rotate the object displayed around the attention point. When a user uses a material for presentation material or the like, a projection material image generated by rendering is inserted instead of inserting a three-dimensional material image. In addition, the projection material image is divided into a part in which the object is visually projected and a part (background part) in which the three-dimensional space is projected, but it is not distinguished as data and is integrated. used.
[0008]
[Problems to be solved by the invention]
However, in the three-dimensional material image, it takes time and effort to adjust the viewpoint of the three-dimensional space so that the orientations of the objects displayed in the projection material image are aligned. In other words, in order to adjust the viewpoint of the 3D space so that the orientations of the objects displayed in the projection material image are aligned, rendering is performed using existing 3D image processing software. A projection material image is generated for each original material image, output to a display device, and the projection material images are compared with each other. It was necessary to perform precise operations to adjust the temperature, which required a lot of labor and time. In particular, as shown in FIG. 12, there are many objects in which the front of the object is directed in a different direction for each three-dimensional material image registered in the database. There are some that are located inside and others that are located outside, and there is variation in the position of the point of interest with respect to the object for each three-dimensional material image. For this reason, even when the same coordinate value is used as the viewpoint for each three-dimensional material image, the orientation of the object in the projection material image is not uniform due to the difference in the front direction of the object and the position of the point of interest. Also, due to the difference in the center of rotation (attention point) for each 3D material image, the method of rotating the object displayed for each 3D material image is different, and the orientation of the object is aligned. Therefore, it is necessary to adjust the orientation of the object by operating the coordinates of the viewpoint for each three-dimensional material image while considering the position of the attention point for each three-dimensional material image. In addition, the conventional material providing system does not have a function of changing the direction of the object by inputting the viewpoint, and is displayed by changing the viewpoint (from the viewpoint of the user, rotating the three-dimensional material image). In order to align the orientation of the target object, it was necessary to use existing 3D image processing software. In order to use the existing 3D image processing software, the 3D material image must be downloaded to the user's terminal, but the 3D material image usually has a larger amount of data than the 2D material image. It took time to download.
[0009]
Furthermore, the projection material image generated from the three-dimensional material image by rendering is visually divided into a part where the object is projected (object part) and a part where the three-dimensional space is projected (three-dimensional space part). Although the data is divided, the object part and the three-dimensional space part are integrated as data without being distinguished. Therefore, if the user wants to use only the object part as the material, the user can use the existing image processing software function to trace the outline of the object part of the projection material image with the mouse and separate it from the 3D space part. I had to do it, and it took effort and time.
[0010]
Therefore, an object of the present invention is to provide a 3D material image providing method that can easily unify the orientation of the object of the projection material image and that can easily separate the object portion and the 3D space portion of the projection material image. It is to propose a system, a providing program, and a storage medium storing the providing program, and to provide such a method, system, program, and recording medium to support creation of presentation materials and the like.
[0011]
[Means for Solving the Problems]
The method for providing a three-dimensional material image according to claim 1, wherein a plurality of three-dimensional material images are stored in advance in a storage unit of a computer, and the computer selects any three-dimensional material designated from among the three-dimensional material images. By rendering the material image, the arbitrary three-dimensional material image is projected onto the two-dimensional projection plane in the direction from the coordinate value of the viewpoint for rendering to the coordinate value of the attention point for rendering, and the projection material image is projected. In the method for providing a three-dimensional material image for generating and displaying the projection material image, The three-dimensional material image stored in the storage means is adjusted so that the front of the object faces a predetermined coordinate direction, Each 3D material image includes all 3D material images. Commonly set A point of interest for rendering is set in the coordinate value, and a viewpoint coordinate input step for prompting input of the coordinate value of the viewpoint for rendering, and the input coordinate value of the viewpoint for rendering are stored in the storage means. A viewpoint coordinate value storing step, a three-dimensional material image specifying step for prompting specification of an arbitrary three-dimensional material image among the three-dimensional material images, and the arbitrary tertiary by rendering the specified arbitrary three-dimensional image A projection material image generation step for generating a projection material image obtained by projecting an original material image onto a projection plane in a direction from the stored viewpoint toward the attention point, and the viewpoint coordinate input step and the viewpoint coordinate storage After the step, the three-dimensional material image designation step and the projection material image generation step are repeated a plurality of times while the viewpoint coordinates are stored. The features.
[0012]
The system for providing a three-dimensional material image according to claim 4, wherein a plurality of three-dimensional material images are stored in advance in a storage unit of a computer, and the computer selects any three-dimensional material specified among the three-dimensional material images. By rendering the material image, the arbitrary three-dimensional material image is projected onto the two-dimensional projection plane in the direction from the coordinate value of the viewpoint for rendering to the coordinate value of the attention point for rendering, and the projection material image is projected. In a three-dimensional material image providing system for generating and displaying the projection material image, The three-dimensional material image stored in the storage means is adjusted so that the front of the object faces a predetermined coordinate direction, Each 3D material image includes all 3D material images. Commonly set A point of interest for rendering is set in the coordinate value, and a viewpoint coordinate input function that prompts input of the coordinate value of the viewpoint for rendering, and the input coordinate value of the viewpoint for rendering are stored in the storage means. A viewpoint coordinate value storage function, a three-dimensional material image designation function that prompts designation of an arbitrary three-dimensional material image among the three-dimensional material images, and the arbitrary third-order by rendering the specified arbitrary three-dimensional image A projection material image generation function that generates a projection material image obtained by projecting an original material image onto a projection plane in a direction from the stored viewpoint toward the attention point, and the viewpoint coordinates stored in the viewpoint coordinate storage function A function of repeating the three-dimensional material image designating function and the projecting material image generation function a plurality of times while holding the image is provided.
[0013]
The program for providing a three-dimensional material image according to claim 7, wherein a plurality of three-dimensional material images are stored in advance in a storage unit of a computer, and an arbitrary three-dimensional material image designated among the three-dimensional material images is rendered. By projecting the arbitrary three-dimensional material image on a two-dimensional projection plane in a direction from the coordinate value of the viewpoint for rendering to the coordinate value of the target point for rendering, a projection material image is generated, In a program for providing a three-dimensional material image that causes a computer to display a projection material image, The three-dimensional material image stored in the storage means is adjusted so that the front of the object faces a predetermined coordinate direction, Each 3D material image includes all 3D material images. Commonly set A point of interest for rendering is set in the coordinate value, and a viewpoint coordinate input function that prompts input of the coordinate value of the viewpoint for rendering, and the input coordinate value of the viewpoint for rendering are stored in the storage means. A viewpoint coordinate value storage function, a three-dimensional material image designation function that prompts designation of an arbitrary three-dimensional material image among the three-dimensional material images, and the arbitrary third-order by rendering the specified arbitrary three-dimensional image A projection material image generation function that generates a projection material image obtained by projecting an original material image onto a projection plane in a direction from the stored viewpoint toward the attention point, and the viewpoint coordinates stored in the viewpoint coordinate storage function The computer is allowed to realize a function of repeating the three-dimensional material image designating function and the throwing material image generating function a plurality of times while holding the same.
[0014]
The storage medium storing the three-dimensional material image providing program according to claim 10, wherein a plurality of three-dimensional material images are stored in advance in a storage means of a computer, and an arbitrary tertiary specified in the three-dimensional material image By rendering the original material image, the arbitrary three-dimensional material image is projected on the two-dimensional projection plane in the direction from the coordinate value of the viewpoint for rendering to the coordinate value of the target point for rendering, and the projection material image In a storage medium storing a program for providing a three-dimensional material image that causes a computer to realize the function of displaying the projection material image, The three-dimensional material image stored in the storage means is adjusted so that the front of the object faces a predetermined coordinate direction, Each 3D material image includes all 3D material images. Commonly set A point of interest for rendering is set in the coordinate value, and a viewpoint coordinate input function that prompts input of the coordinate value of the viewpoint for rendering, and the input coordinate value of the viewpoint for rendering are stored in the storage means. A viewpoint coordinate value storage function, a three-dimensional material image designation function that prompts designation of an arbitrary three-dimensional material image among the three-dimensional material images, and the arbitrary third-order by rendering the specified arbitrary three-dimensional image A projection material image generation function for generating a projection material image obtained by projecting an original material image on a projection plane in a direction from the stored viewpoint toward the attention point; and the viewpoint coordinates stored in the viewpoint coordinate storage function The program for causing the computer to realize the function of repeating the three-dimensional material image designating function and the throwing material image generating function multiple times while maintaining And characterized in that it Kutomo stored.
[0015]
According to the present invention, the storage means of the computer is stored in advance. Commonly set Since multiple 3D material images with the coordinate value as the point of interest are stored, the coordinates of the point of interest in each 3D material image are all the same (For example, the center of gravity of the object in each 3D image) It is. Further, when the user inputs the coordinate value of the viewpoint, the coordinate value of the viewpoint is stored in the storage means by the viewpoint coordinate value storing step / function, so that the coordinate value of the specific viewpoint is held in the computer. Next, when the user designates an arbitrary 3D material image from a plurality of 3D material images, the projection material image generation step / function retains the coordinate value of the specific viewpoint input from the user while maintaining the arbitrary viewpoint. A three-dimensional material image is rendered, and a projection material image obtained by projecting the arbitrary three-dimensional material image onto a projection plane in a direction from the coordinate value of the viewpoint toward the coordinate value of the attention point is generated. Then, after the viewpoint coordinate input step / function and the viewpoint coordinate value storage step / function, when the three-dimensional material image designation step / function and the projection material image generation step / function are repeated a plurality of times while maintaining the viewpoint coordinates, the viewpoint coordinate value A plurality of projection material images are generated while maintaining the coordinate values of the specific viewpoint stored in the storage step / function. For this reason, the coordinate values of the specific viewpoint stored in the viewpoint coordinate value storage step / function are reflected on all the three-dimensional material images designated by the user, That particular From the coordinates of the viewpoint, Commonly set for all 3D material images A projection material image is generated by projecting (rendering) the three-dimensional material image onto the projection plane in the direction toward the coordinate value of the target point. For all the stored 3D material images, the front of the object (the surface that is visually recognized as the front rather than the exact front) is adjusted so as to face the predetermined coordinate direction, and attention is paid in advance. By adjusting the position of the object in the three-dimensional space so that the coordinate value of the point is the center of gravity of the object (the point that is visually recognized as the center of gravity, not the exact center of gravity), the 3D material image becomes An object whose front is unified in the same direction is always rendered in a direction from the specified viewpoint toward the center of gravity. In other words, from the viewpoint of the user's operation, since the 3D material image rotates around the center of gravity of the object even if the coordinate value of the viewpoint is moved, all 3D material images stored in the computer are rotated. Are almost the same. Therefore, the user can easily obtain a projection material image in which the orientations of the objects are aligned by simply inputting the coordinates of the same viewpoint for each three-dimensional material image. When the user obtains this projection material image via the network, it is only necessary to download the generated 2D projection material image, and it is not necessary to download the 3D material image itself with a large amount of data. It does not take time.
[0016]
The method for providing a three-dimensional material image according to claim 2, wherein a plurality of three-dimensional material images are stored in advance in a storage unit of a computer, and the computer selects any three-dimensional material specified among the three-dimensional material images. By rendering the material image, the arbitrary three-dimensional material image is projected onto the two-dimensional projection plane in the direction from the coordinate value of the viewpoint for rendering to the coordinate value of the attention point for rendering, and the projection material image is projected. In the method for providing a three-dimensional material image for generating and displaying the projection material image, The three-dimensional material image stored in the storage means is adjusted so that the front of the object faces a predetermined coordinate direction, Each 3D material image includes all 3D material images. Commonly set A point of interest for rendering is set in the coordinate value, and a viewpoint coordinate input step for prompting input of the coordinate value of the viewpoint for rendering, and the input coordinate value of the viewpoint for rendering are stored in the storage means. A viewpoint coordinate value storing step, a three-dimensional material image specifying step for prompting specification of an arbitrary three-dimensional material image among the three-dimensional material images, and the arbitrary tertiary by rendering the specified arbitrary three-dimensional image A projection material image generation step for generating a projection material image obtained by projecting an original material image onto a projection plane in a direction from the stored viewpoint toward the attention point, and the three-dimensional material image designation step is performed a plurality of times. After the repetition, the viewpoint coordinate input step and the viewpoint coordinate storage step are performed, and the three-dimensional material image designation step is performed while the viewpoint coordinates are stored. The plurality of three-dimensional material image designated in-up and performs the projection material image generation step.
[0017]
The system for providing a three-dimensional material image according to claim 5, wherein a plurality of three-dimensional material images are stored in advance in a storage unit of a computer, and the computer selects any three-dimensional material specified among the three-dimensional material images. By rendering the material image, the arbitrary three-dimensional material image is projected onto the two-dimensional projection plane in the direction from the coordinate value of the viewpoint for rendering to the coordinate value of the attention point for rendering, and the projection material image is projected. In a three-dimensional material image providing system for generating and displaying the projection material image, The three-dimensional material image stored in the storage means is adjusted so that the front of the object faces a predetermined coordinate direction, Each 3D material image includes all 3D material images. Commonly set A point of interest for rendering is set in the coordinate value, and a viewpoint coordinate input function that prompts input of the coordinate value of the viewpoint for rendering, and the input coordinate value of the viewpoint for rendering are stored in the storage means. A viewpoint coordinate value storage function, a three-dimensional material image designation function that prompts designation of an arbitrary three-dimensional material image among the three-dimensional material images, and the arbitrary third-order by rendering the specified arbitrary three-dimensional image A projection material image generation function that generates a projection material image obtained by projecting an original material image onto a projection plane in a direction from the stored viewpoint toward the attention point, and the three-dimensional material image designation function are repeatedly executed a plurality of times. After that, the viewpoint coordinate input function and the viewpoint coordinate storage function are executed, and the plurality of points designated in the three-dimensional material image designation function while the viewpoint coordinates are stored Characterized in that the three-dimensional material image and a function of executing the projection material image generating function.
[0018]
The program for providing a three-dimensional material image according to claim 8, wherein a plurality of three-dimensional material images are stored in advance in storage means of a computer, and an arbitrary three-dimensional material image designated among the three-dimensional material images is rendered. By projecting the arbitrary three-dimensional material image on a two-dimensional projection plane in a direction from the coordinate value of the viewpoint for rendering to the coordinate value of the target point for rendering, a projection material image is generated, In a program for providing a three-dimensional material image that causes a computer to display a projection material image, The three-dimensional material image stored in the storage means is adjusted so that the front of the object faces a predetermined coordinate direction, Each 3D material image includes all 3D material images. Commonly set A point of interest for rendering is set in the coordinate value, and a viewpoint coordinate input function that prompts input of the coordinate value of the viewpoint for rendering, and the input coordinate value of the viewpoint for rendering are stored in the storage means. A viewpoint coordinate value storage function, a three-dimensional material image designation function that prompts designation of an arbitrary three-dimensional material image among the three-dimensional material images, and the arbitrary third-order by rendering the specified arbitrary three-dimensional image A projection material image generation function that generates a projection material image obtained by projecting an original material image onto a projection plane in a direction from the stored viewpoint toward the attention point, and the three-dimensional material image designation function are repeatedly executed a plurality of times. After that, the viewpoint coordinate input function and the viewpoint coordinate storage function are executed, and the plurality of points designated in the three-dimensional material image designation function while the viewpoint coordinates are stored A function of executing the projection material image generating function for three-dimensional material image, characterized in that to realize the computer.
[0019]
The storage medium storing the program for providing a three-dimensional material image according to claim 11 has a plurality of three-dimensional material images stored in advance in a storage means of a computer, and an arbitrary tertiary specified in the three-dimensional material image. By rendering the original material image, the arbitrary three-dimensional material image is projected on the two-dimensional projection plane in the direction from the coordinate value of the viewpoint for rendering to the coordinate value of the target point for rendering, and the projection material image In a storage medium storing a program for providing a three-dimensional material image that causes a computer to realize the function of displaying the projection material image, The three-dimensional material image stored in the storage means is adjusted so that the front of the object faces a predetermined coordinate direction, Each 3D material image includes all 3D material images. Commonly set A point of interest for rendering is set in the coordinate value, and a viewpoint coordinate input function that prompts input of the coordinate value of the viewpoint for rendering, and the input coordinate value of the viewpoint for rendering are stored in the storage means. A viewpoint coordinate value storage function, a three-dimensional material image designation function that prompts designation of an arbitrary three-dimensional material image among the three-dimensional material images, and the arbitrary third-order by rendering the specified arbitrary three-dimensional image A projection material image generation function that generates a projection material image obtained by projecting an original material image onto a projection plane in a direction from the stored viewpoint toward the attention point, and the three-dimensional material image designation function are repeatedly executed a plurality of times. After that, the viewpoint coordinate input function and the viewpoint coordinate storage function are executed, and the plurality of points designated in the three-dimensional material image designation function while the viewpoint coordinates are stored It characterized in that the three-dimensional material images are at least stores a program for realizing the function of executing the projection material image generating function on the computer.
[0020]
According to the present invention, the three-dimensional material image designating step / function is repeated a plurality of times before the viewpoint coordinate input step / function and the viewpoint coordinate storage step / function, but as in claim 1 or claim 4 or claim 10 The coordinate value of the specific viewpoint stored in the viewpoint coordinate value storage step / function is reflected on all the 3D material images specified by the user, That particular From the coordinates of the viewpoint, Commonly set for all 3D material images A projection material image is generated by projecting (rendering) the three-dimensional material image onto the projection plane in the direction toward the coordinate value of the target point.
[0021]
The three-dimensional material image providing method according to claim 3 is based on the premise of the three-dimensional material image providing method according to claim 1 or claim 2, and the projection material image generating step includes A masking step for masking a predetermined portion set in advance in the storage means is included.
[0022]
The three-dimensional material image providing system according to claim 6 is based on the three-dimensional material image providing system according to claim 4 or 5, and the projection material image generating function includes the generated projection material image. A masking function for masking a predetermined portion preset in the storage means is included.
[0023]
The three-dimensional material image providing program according to claim 9 is premised on the three-dimensional material image providing program according to claim 7 or claim 8, and the projection material image generating function includes the generated projection material image. A masking function for masking a predetermined portion preset in the storage means is included.
[0024]
A storage medium storing the three-dimensional material image providing program according to claim 12 is based on the assumption that the storage medium storing the three-dimensional material image providing program according to claim 10 or 11 is used. Includes a masking function for masking a predetermined portion set in advance in the storage unit for the generated projection material image.
[0025]
A three-dimensional material image is composed of a three-dimensional space (object space) based on a three-dimensional coordinate system (X-axis, Y-axis, Z-axis), and the target object is a mesh line that connects a plurality of feature points (coordinates) to each feature point. Exists in a three-dimensional space. For this reason, a projection material image generated by rendering a 3D material image is composed of a portion where a 3D space is projected (3D space portion) and a portion where an object is projected (object portion). Is done. Therefore, according to the present invention, the projection material image is distinguished into the three-dimensional space part and the object part by presetting the three-dimensional space part as a predetermined part and masking the part. Therefore, the user can easily extract only the object portion from the projection material image.
[0026]
DETAILED DESCRIPTION OF THE INVENTION
(First Embodiment) A first embodiment of the present invention will be described with reference to the drawings. In this embodiment, when a user creates a presentation material for computer system design, a plurality of material images representing servers, terminals, printers, etc. are downloaded from the material image data providing system and inserted into the material. Will be described.
[0027]
The material image data providing system according to the embodiment of the present invention includes a server SV using a computer, a workstation, or the like, and a terminal is connected to the server SV via a network such as the Internet (FIG. 1). .
[0028]
The storage means of the server SV stores a program P for causing the server SV to function as a three-dimensional material image providing system and a database in which a plurality of three-dimensional material images are registered (FIG. 2).
[0029]
In the database, for example, a plurality of three-dimensional material images D1 representing displays, printers, arrows, and other objects are registered. For example, as shown in FIG. 3, the three-dimensional material image D1 is composed of a three-dimensional space (object space) 6 based on a three-dimensional coordinate system (X axis, Y axis, Z axis), and an object 7 includes a plurality of coordinates. It exists in the three-dimensional space as a mesh line connecting the coordinates. For convenience of explanation, in the present embodiment, the three-dimensional material image D1 in which the object 7 is a rectangular parallelepiped with 7a in front is described as an example, but the database DB includes computer equipment such as a display and a printer. A plurality of three-dimensional material images D1 in which various objects such as arrows and buildings are the object 7 are registered. In the three-dimensional material image D1, the orientation of the object 7 in the three-dimensional space 6 is adjusted so that the front surface 7a of the object 7 faces in a predetermined direction in advance. Here, the front surface 7a is not a strict front surface of the object 7 in the three-dimensional space 6, but is a surface visually recognized as being substantially in front. The predetermined direction is a fixed direction for all the three-dimensional material images D1, and in the present embodiment, the three-dimensional material is preliminarily arranged so that the front surface of the object 7 faces the negative direction of the Z axis (front side in FIG. 3). The direction of the object 7 in the space 6 is adjusted. In addition, the coordinates of the point of interest are set in advance in the three-dimensional material image D1. The coordinates of the point of interest are constant coordinate values for all the three-dimensional material images D1, and in this embodiment, the point of interest is set as the coordinate value (0, 0, 0), and the coordinate value (0, 0) of the point of interest is set. The position of the object 7 existing in the three-dimensional space 6 is adjusted in advance so that (0, 0) is the center of gravity of the object 7. Here, the center of gravity is not the exact center of gravity of the object in the three-dimensional space, but the point that is visually recognized as the center of gravity. By adjusting the direction of the object 7 and the point of interest in advance, the three-dimensional material image D1 is obtained from a specified viewpoint with respect to the object whose direction is unified so that the front faces in the same direction. The material image D1 is rendered in a direction toward the center of gravity of the object 7 in the three-dimensional space 6.
[0030]
The program P is a program for causing the server SV to function as a three-dimensional material image providing system by realizing various functions. The program P1 for realizing the function F1 that prompts input of the coordinate value of the viewpoint, A program P2 for realizing a function F2 for storing the coordinate value of the viewpoint in the storage means, and a function F3 for prompting designation of an arbitrary three-dimensional material image D1 from the plurality of three-dimensional material images D1 registered in the database DB Projection obtained by projecting the arbitrary 3D material image D1 on the projection plane in a direction from the stored viewpoint to the attention point by rendering the program P3 to be realized and the arbitrary 3D material image D1 A program P4 for realizing the function F4 for generating the material image D2 and the projection material image D2 are set in advance. A program P5 for realizing a function F5 for masking a predetermined portion, and a program P6 for realizing a function F6 for displaying the masked projection material image D2 in the display area of the display screen, and downloading of the projection material image D2 to the user And a program P7 for realizing a function F7 for prompting the user.
[0031]
First, when the user accesses the server via the Internet, the server SV displays the display screen 1 on the display device of the terminal CA according to the program P. The display screen 1 is provided with at least a display area 2 for displaying the projection material image D2, a viewpoint coordinate value input field 3, a three-dimensional material image designation button 4, and a download button 5 (FIG. 4). FIG. 5 shows the steps of the present embodiment. Hereinafter, each step will be described with reference to FIG.
[0032]
(Step 1) Step 1 is a viewpoint coordinate input step that prompts input of coordinate values of the viewpoint for rendering. The server SV displays a viewpoint coordinate value input field on the display screen 1 according to the program P1, thereby fulfilling a function F1 that prompts the user to input a viewpoint coordinate value. The user determines which coordinate value in the three-dimensional space of the three-dimensional material image D1 is to be placed in the viewpoint, and inputs the coordinate value (x1, y1, z1) that becomes the viewpoint in the viewpoint coordinate value input field 3. .
[0033]
(Step 2) Step 2 is a viewpoint coordinate value storage step for storing the input coordinate value of the viewpoint for rendering in the storage means. The server SV stores the input viewpoint coordinate values (x1, y1, z1) in the storage means according to the program P2 for realizing the function F2 for storing the input viewpoint coordinate values in the storage means of the server SV. To do. By storing the coordinate values (x1, y1, z1) of the viewpoint, the same coordinate values (x1, y1, z1) can be set as the viewpoint for the three-dimensional material image D1 specified after Step 1.
[0034]
In step 1, the coordinate value of the viewpoint can be input by operating the display area 2 with a mouse without directly inputting it into the viewpoint coordinate value input field 3. In this case, before step 2, the user designates a reference three-dimensional material image D1 (for example, a three-dimensional material image of a rectangular parallelepiped in FIG. 3) by pressing the three-dimensional material image designation button 4. In the present embodiment, initial values (x2, y2, z2) are set in advance as the coordinates of the viewpoint, and the server SV follows the program P4, which will be described later, and becomes a reference three-dimensional material image D1 that is first designated by the user. To generate a projection material image D2 with the initial value (x2, y2, z2) as the viewpoint and the coordinates (0, 0, 0) set in advance in the three-dimensional material image D1 as the attention point. Then, the projection material image D2 is displayed in the display area 2 (see the display area in FIG. 4). The server SV displays the projection material image D2 by displaying the projection material image D2 with the initial value (x2, y2, z2) as the viewpoint in the display area 2 in accordance with the program P6 described later. At the same time, the function F1 that prompts the user to input the coordinate value of the viewpoint is realized. The user moves the coordinate value of the viewpoint in the three-dimensional material image D1 by dragging the display area 2 on which the projection material image D2 is displayed with the mouse. The server SV sequentially generates a projection material image D2 corresponding to the moved viewpoint according to the program P4 described later, and displays it in the display area 2. When the object 7 in the projection material image D2 displayed in the display area 2 is displayed from the viewpoint desired by the user, the user coordinates the viewpoint by stopping the mouse operation and determining the coordinate value of the viewpoint. Enter the values (x1, y1, z1). The server SV stores the input viewpoint coordinate values (x1, y1, z1) in the storage unit according to the program P2. The user does not select a reference three-dimensional material image as in the present embodiment, but a specific three-dimensional material image is registered in advance as a reference three-dimensional material image. The coordinates of the viewpoint may be determined based on a specific three-dimensional material image. In this case, a button for displaying a specific three-dimensional material image serving as a reference is separately provided on the display screen 1.
[0035]
(Step 3) Step 3 is a three-dimensional material image designation step that prompts designation of an arbitrary three-dimensional material image D1 from a plurality of three-dimensional material images D1 registered in the database DB. The server SV realizes a function F3 that prompts designation of an arbitrary 3D material image D1 from a plurality of 3D material images D1 registered in the database DB by displaying a 3D material image designation button 4 according to the program P3. is doing. In the present embodiment, in step 1, a 3D material image designation button 4 is provided in advance on the display screen 1 so that the coordinate value of the viewpoint can be input by operating the projection material image D2 displayed in the display area. In step 3, the same 3D material image designation button 4 as that used in step 1 is used to prompt the user to designate the 3D material image D 1. May be provided. After step 1, the user presses the 3D material image designation button 4 to designate a desired 3D material image D1 from the 3D material images D1 registered in a plurality of databases. The three-dimensional material image D1 is classified and hierarchized for each category, and the user designates the three-dimensional material image D1 while narrowing down by pressing a hierarchized selection button (not shown). In the present embodiment, the hierarchical selection buttons are displayed on the display screen 1 when the three-dimensional material image designation button 4 is pressed.
[0036]
(Step 4-1) Step 4 comprises Step 4-1 and Step 4-2. Step 4-1 is a projection material obtained by projecting the arbitrary 3D material image on the projection plane in a direction from the stored viewpoint to the attention point by rendering the specified arbitrary 3D image. This is a projection material image generation step for generating an image. When the server SV detects the designation of the three-dimensional material image D1, the server SV renders the designated three-dimensional material image D1 in accordance with the program P4 that realizes the function F4, thereby rendering the three-dimensional material image D1 the stored viewpoint. A projection material image D2 obtained by projecting onto the projection plane 8 in a direction from the coordinate value (x1, y1, z1) of the target point to the coordinate value (0, 0, 0) of the target point is generated. FIG. 6A is a conceptual diagram of rendering, and FIG. 6B is a diagram showing a projection material image D2 to be generated. The projection material image D2 always moves from the viewpoint coordinate values (x1, y1, z1) stored in step 2 toward the coordinates (0, 0, 0) of a certain point of interest in the three-dimensional material image D1. It is generated by projecting the three-dimensional material image D1 onto the projection plane 8.
[0037]
(Step 4-2) Step 4-2 is a masking step for masking a predetermined portion set in advance in the storage means for the generated projection material image. The server SV masks a predetermined portion of the projection material image D2 according to a program P5 that causes the server SV to realize the function F5. As shown in FIG. 6B, the projection material image D2 includes a part in which the three-dimensional space 6 is visually projected (three-dimensional space part 60) and a part in which the object 7 is projected (object part 70). However, the data are not distinguished and are integrated. Therefore, the three-dimensional space portion 60 and the object portion 70 are distinguished as data by masking the three-dimensional space portion 60 of the projection material image D2. In the present embodiment, the predetermined portion is set in advance in the program P5 as “a portion on which the three-dimensional space is projected (three-dimensional space portion 60)”. That is, the server SV masks the three-dimensional space portion 60 of the projection material image D2 by the function F5. Here, masking is one of the processes of graphics software, and refers to an operation in which a portion that is not to be processed is selected in advance and covered. On the application, bit information is left where selection is not made in the logical operation. In the present embodiment, the mask projection image D3 (FIG. 7A) obtained by inverting the bit information of the three-dimensional space portion 60 is superimposed on the back surface of the projection material image D2 (FIG. 7B). Thus, the three-dimensional space portion 60 is masked. Therefore, after the user downloads the projection material image D2 to the terminal, the user clicks on the object part 70 of the projection material image D2 with the mouse to leave the three-dimensional space portion 60 that is not desired to be processed. Only the portion onto which the object 7 is projected (object portion 70) can be extracted easily.
[0038]
(Step 5) Step 5 is a step of displaying the generated projection material image D2 in the display area 2 of the display screen 1. When step 4 ends, the server SV displays the projection material image D2 rendered in step 4-1 and masked in step 4-2 according to the program P6 for realizing the function F6 for displaying the projection material image in the server SV. It is displayed in the display area 2 of the screen 1. The user looks at the displayed projection material image D2 and confirms whether or not the object 7 has an angle viewed from a desired viewpoint. Note that the mask projection image D3 is pasted on the back surface of the projection material image D2, and is not displayed on the display screen 1.
[0039]
(Step 6) Step 6 is a step of downloading the generated projection material image D2 and mask projection image D3. The server SV displays the download button 5 on the display screen 1 in accordance with the program P7 for causing the server SV to implement the function F7 that prompts the download, thereby displaying the projection material image D2 and the projection material image D2 on the back of the user. The user is prompted to download the pasted mask projection image D3. By pressing the download button 5, the user downloads the projection material image D2 and the mask projection image D3 displayed in the display area 2 to the terminal CA via the Internet NET. Since the data to be downloaded is two-dimensional, the amount of data is small compared to the three-dimensional material image D1, and the download time can be shortened.
[0040]
(Step 3 to Step 6) When step 6 ends, the server SV repeats step 3 to step 6 a plurality of times. Steps 3 to 6 are repeated for each three-dimensional material image designated by the user. That is, the server SV, after step 1 (viewpoint coordinate input step) and step 2 (viewpoint coordinate storage step), stores the viewpoint coordinates, and then continues with step 3 (three-dimensional material image designation step) and step 4 (projection material). Image generation step), step 5 and step 6 are repeated by the number of three-dimensional material images D1 designated by the user. The user selects the 3D material image D1 for each 3D material image D1 for which the orientation of the object is to be aligned, and downloads the projection material image D2 and the mask projection image D3 pasted on the back of the projection material image D2. It will be. Since the server SV performs step 4 after step 2, the three-dimensional material images D1 specified in step 4 are retained while retaining the viewpoint coordinate values (x1, y1, z1) stored in step 2. Rendering and masking are performed, and even if a different three-dimensional material image D1 is selected every time Step 3 is repeated, the coordinate values of the viewpoints in each three-dimensional material image D1 do not change. Further, since a fixed point of interest (0, 0, 0) is set in advance in each three-dimensional material image D1, the coordinate value of the point of interest does not change. Further, with respect to all the three-dimensional material images D1, the front surface 7a faces in a certain direction, and the coordinate value (0, 0, 0) of the target point becomes the center of gravity of the object 7 of the three-dimensional material image. As described above, since the position of the object 7 in the three-dimensional space 6 is adjusted, the three-dimensional image is obtained from the viewpoint (x1, y1, z1) with the center of gravity (0, 0, 0) of the object 7 facing in the same direction. Rendered in the direction toward). For this reason, the user can specify a plurality of desired three-dimensional material images D1 without performing complicated operations such as adjusting the viewpoint for each of the three-dimensional material images D1, for example, a printer, a display, a building, or the like. A plurality of projection material images D2 in which the orientation of the object 7 is aligned are generated. Then, the user displays the projection material image D2 displayed for each three-dimensional material image D1 in step 5 and the mask projection image D3 pasted on the back of the projection material image D2 for each projection material image D2 in step 6. A plurality of projection material images D2 can be obtained by downloading to the terminal.
[0041]
When creating a material for presentation, the user inserts the downloaded projection material image D2 into the material. Accordingly, the user can easily create a material using the projection material image D2 having a sense of unity as if the object was viewed from the same viewpoint toward the same point of interest.
[0042]
The projection material image D2 finally generated is subjected to processing for adding surface characteristics of an object such as color and gloss, or is provided to the user by shading so that the surface looks smooth. This is optional depending on the implementation.
[0043]
Further, the object of the three-dimensional material image D1 is not limited to the exemplified printer and display, but various other objects are very good. For example, a three-dimensional material image D1 using three-dimensionally designed characters as materials is registered in the database, and the user combines three characters to create a three-dimensional title with a sense of unity in character orientation. You may be able to create it.
[0044]
(Application example of first embodiment) Each step is not limited to the order shown in the first embodiment. For example, step 4 is repeated after step 3 as shown in FIG. Thus, after all the three-dimensional material images D1 desired by the user can be designated collectively and prompted to designate a plurality of three-dimensional material images D1, step 4 is performed for each designated three-dimensional material image D1. Is repeated to render and mask the specified three-dimensional material images D1 and display the projection material images D2 generated in step 4 in step 5 in a form arranged in the display area 2 in a step. In step 6, a download button is displayed so that a plurality of projection material images D2 to be downloaded can be specified. You may be able to load.
[0045]
(Second Embodiment) As shown in FIG. 8B, in the present invention, the three-dimensional material image designation step may be repeated a plurality of times before the viewpoint coordinate input function and the viewpoint coordinate storage step. That is, before step 1, step 3 (three-dimensional material image designation step) is repeated a plurality of times so that all three-dimensional material images D1 desired by the user can be designated collectively, and a plurality of three-dimensional material images D1 are designated. In step 1 (viewpoint coordinate input step), input of the viewpoint coordinate value is prompted, and in step 2 (viewpoint coordinate storage step), the viewpoint coordinate value input is stored, and the viewpoint coordinates are stored. By repeating step 4 (projection material image generation step) for a plurality of 3D material images specified in step 3, the specified 3D material images D1 are rendered and masked together, and generated in step 4 in step 5. The projected projection material images D2 may be displayed together in a format that is arranged in the display area 2. .
[0046]
(Third Embodiment) In the third embodiment, a case where a storage medium storing the program P of the first embodiment is distributed to users will be described. The storage medium is a computer-readable medium such as a CD-ROM and stores the same program P as that in the first embodiment. Therefore, by distributing the storage medium storing the program P to the user, the user can cause the terminal to execute the program P and realize the same function as the first embodiment in the terminal. Note that the 3D material data used in the program P by being stored in the user's terminal may be distributed separately or created by each user himself / herself.
[0047]
As described above, the present embodiment has been described on the assumption that a presentation material is created. However, the present invention can also be applied to the case of creating a home page and other materials.
[0048]
【The invention's effect】
The material providing method and the providing system of the present invention store the viewpoint coordinates input by the user, and then render a plurality of three-dimensional material images D1 designated by the user from the same viewpoint coordinates. As a result, the three-dimensional material image D1 in the database is adjusted in advance so that the front of the object is directed to the predetermined coordinate direction, and the coordinate value of the target point is previously set to be the center of gravity of the object. By adjusting the position of the object in, the three-dimensional material image D1 is always rendered in the direction from the specified viewpoint toward the center of gravity for the object whose front is unified in the same direction. By simply inputting the coordinates of the same viewpoint for the original material image D1, it is possible to easily obtain the projection material image D2 in which the orientations of the objects are aligned. Further, the user only has to download the two-dimensional projection material image D2, and it does not take time to download. Further, by masking the three-dimensional space portion, the user can easily extract only the object portion from the projection material image D2. Therefore, by proposing the three-dimensional material image providing method and system of the present invention, it is possible to support the creation of presentation materials and the like.
[0049]
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration of a first exemplary embodiment of the present invention.
FIG. 2 is a diagram illustrating a configuration of a server according to the embodiment.
FIG. 3 is a diagram illustrating an example of a three-dimensional material image according to the embodiment.
FIG. 4 is a diagram showing a display screen of the server SV of the embodiment.
FIG. 5 is a diagram showing steps in the embodiment.
6A is a conceptual diagram of rendering according to the embodiment, and FIG. 6B is a diagram illustrating a projection material image D2 to be generated.
FIGS. 7A and 7B are conceptual diagrams of masking in the embodiment.
8A is a diagram showing steps of an application example of the first embodiment, and FIG. 8B is a diagram showing steps of the second embodiment.
9A is a diagram showing a two-dimensional material image in which the orientation of the object is different, and FIG. 9B is a diagram showing a two-dimensional material image in which the orientation of the object is aligned.
FIG. 10 is a diagram showing a three-dimensional material image composed of a three-dimensional space and an object.
FIG. 11 is a diagram showing a three-dimensional material image having different directions and points of interest.
FIG. 12 is a diagram illustrating a three-dimensional material image in which the direction of an object and the coordinates of a target point are different.
[Explanation of symbols]
SV server
CA terminal
NET internet
P program
F function
D1 3D material image
D2 projection material image
1 Display screen
2 display area
3 Viewpoint coordinate value input field
4 3D material image designation button
5 Download button
6 Three-dimensional space
7 Object
7a Front of the object
8 Projection plane
60 3D space
70 Object part

Claims (12)

A plurality of three-dimensional material images are stored in advance in the storage means of the computer, and the computer renders an arbitrary three-dimensional material image specified among the three-dimensional material images, thereby rendering the viewpoint coordinates for rendering. A three-dimensional material image that generates the projection material image by projecting the arbitrary three-dimensional material image on a two-dimensional projection plane in a direction from the value toward the coordinate value of the target point for rendering, and displays the projection material image In the providing method of
The three-dimensional material image stored in the storage means is adjusted so that the front of the object faces a predetermined coordinate direction,
In each of the three-dimensional material images, a point of interest for rendering is set at a coordinate value set in common to all three-dimensional material images,
A viewpoint coordinate input step for prompting input of coordinate values of the viewpoint for rendering;
A viewpoint coordinate value storage step of storing the input viewpoint coordinate value for rendering in the storage means;
A three-dimensional material image designation step for prompting designation of an arbitrary three-dimensional material image among the three-dimensional material images;
Projection that generates a projection material image obtained by projecting the arbitrary three-dimensional material image on the projection plane in a direction from the stored viewpoint to the attention point by rendering the specified arbitrary three-dimensional image A material image generation step,
After the viewpoint coordinate input step and the viewpoint coordinate storage step, the three-dimensional material image specifying step and the projection material image generation step are repeated a plurality of times while the viewpoint coordinates are stored. Method. A plurality of three-dimensional material images are stored in advance in the storage means of the computer, and the computer renders an arbitrary three-dimensional material image specified among the three-dimensional material images, thereby rendering the viewpoint coordinates for rendering. A three-dimensional material image that generates the projection material image by projecting the arbitrary three-dimensional material image on a two-dimensional projection plane in a direction from the value toward the coordinate value of the target point for rendering, and displays the projection material image In the providing method of
The three-dimensional material image stored in the storage means is adjusted so that the front of the object faces a predetermined coordinate direction,
In each of the three-dimensional material images, a point of interest for rendering is set at a coordinate value set in common to all three-dimensional material images,
A viewpoint coordinate input step for prompting input of coordinate values of the viewpoint for rendering;
A viewpoint coordinate value storage step of storing the input viewpoint coordinate value for rendering in the storage means;
A three-dimensional material image designation step for prompting designation of an arbitrary three-dimensional material image among the three-dimensional material images;
Projection that generates a projection material image obtained by projecting the arbitrary three-dimensional material image on the projection plane in a direction from the stored viewpoint to the attention point by rendering the specified arbitrary three-dimensional image A material image generation step,
After the three-dimensional material image designation step is repeated a plurality of times, the viewpoint coordinate input step and the viewpoint coordinate storage step are performed, and a plurality of three-dimensional images designated in the three-dimensional material image designation step while the viewpoint coordinates are stored A method for providing a three-dimensional material image, wherein the projection material image generation step is performed on the material image.   3. The tertiary according to claim 1, wherein the projection material image generation step includes a masking step of masking a predetermined portion set in advance in the storage unit for the generated projection material image. Providing original material images. A plurality of three-dimensional material images are stored in advance in the storage means of the computer, and the computer renders an arbitrary three-dimensional material image specified among the three-dimensional material images, thereby rendering the viewpoint coordinates for rendering. A three-dimensional material image that generates the projection material image by projecting the arbitrary three-dimensional material image on a two-dimensional projection plane in a direction from the value toward the coordinate value of the target point for rendering, and displays the projection material image In the provision system of
The three-dimensional material image stored in the storage means is adjusted so that the front of the object faces a predetermined coordinate direction,
In each of the three-dimensional material images, a point of interest for rendering is set at a coordinate value set in common to all three-dimensional material images,
A viewpoint coordinate input function for prompting input of coordinate values of the viewpoint for rendering;
A viewpoint coordinate value storage function for storing the input rendering viewpoint coordinate values in the storage means;
A three-dimensional material image designation function that prompts designation of an arbitrary three-dimensional material image among the three-dimensional material images;
Projection that generates a projection material image obtained by projecting the arbitrary three-dimensional material image on the projection plane in a direction from the stored viewpoint to the attention point by rendering the specified arbitrary three-dimensional image Material image generation function,
A system for providing a three-dimensional material image, comprising: a function of repeating the three-dimensional material image designating function and the projecting material image generation function a plurality of times while maintaining the viewpoint coordinates stored in the viewpoint coordinate storage function. A plurality of three-dimensional material images are stored in advance in the storage means of the computer, and the computer renders an arbitrary three-dimensional material image specified among the three-dimensional material images, thereby rendering the viewpoint coordinates for rendering. A three-dimensional material image that generates the projection material image by projecting the arbitrary three-dimensional material image on a two-dimensional projection plane in a direction from the value toward the coordinate value of the target point for rendering, and displays the projection material image In the provision system of
The three-dimensional material image stored in the storage means is adjusted so that the front of the object faces a predetermined coordinate direction,
In each of the three-dimensional material images, a point of interest for rendering is set at a coordinate value set in common to all three-dimensional material images,
A viewpoint coordinate input function for prompting input of coordinate values of the viewpoint for rendering;
A viewpoint coordinate value storage function for storing the input rendering viewpoint coordinate values in the storage means;
A three-dimensional material image designation function that prompts designation of an arbitrary three-dimensional material image among the three-dimensional material images;
Projection that generates a projection material image obtained by projecting the arbitrary three-dimensional material image on the projection plane in a direction from the stored viewpoint to the attention point by rendering the specified arbitrary three-dimensional image Material image generation function,
After the three-dimensional material image designation function is repeatedly executed a plurality of times, the viewpoint coordinate input function and the viewpoint coordinate storage function are executed, and the plurality of parts designated by the three-dimensional material image designation function are stored with the viewpoint coordinates stored. And a function of executing the projection material image generation function for the three-dimensional material image.   6. The projection material image generation function includes a masking function for masking a predetermined portion set in advance in the storage unit for the generated projection material image. A system for providing 3D material images. A plurality of three-dimensional material images are stored in advance in the storage means of the computer, and by rendering any specified three-dimensional material image among the three-dimensional material images, rendering is performed from the coordinate value of the viewpoint for rendering. A third order that realizes a function of generating a projection material image by projecting the arbitrary three-dimensional material image on a two-dimensional projection plane in a direction toward the coordinate value of the target point of the image, and displaying the projection material image. In the program for providing original material images,
The three-dimensional material image stored in the storage means is adjusted so that the front of the object faces a predetermined coordinate direction,
In each of the three-dimensional material images, a point of interest for rendering is set at a coordinate value set in common to all three-dimensional material images,
A viewpoint coordinate input function for prompting input of coordinate values of the viewpoint for rendering;
A viewpoint coordinate value storage function for storing the input rendering viewpoint coordinate values in the storage means;
A three-dimensional material image designation function that prompts designation of an arbitrary three-dimensional material image among the three-dimensional material images;
Projection that generates a projection material image obtained by projecting the arbitrary three-dimensional material image on the projection plane in a direction from the stored viewpoint to the attention point by rendering the specified arbitrary three-dimensional image Material image generation function,
A three-dimensional material image characterized in that a computer realizes a function of repeating the three-dimensional material image designating function and the throwing material image generation function a plurality of times while maintaining the viewpoint coordinates stored in the viewpoint coordinate storage function. Offer program. A plurality of three-dimensional material images are stored in advance in the storage means of the computer, and by rendering any specified three-dimensional material image among the three-dimensional material images, rendering is performed from the coordinate value of the viewpoint for rendering. A third order that realizes a function of generating a projection material image by projecting the arbitrary three-dimensional material image on a two-dimensional projection plane in a direction toward the coordinate value of the target point of the image, and displaying the projection material image. In the program for providing original material images,
The three-dimensional material image stored in the storage means is adjusted so that the front of the object faces a predetermined coordinate direction,
In each of the three-dimensional material images, a point of interest for rendering is set at a coordinate value set in common to all three-dimensional material images,
A viewpoint coordinate input function for prompting input of coordinate values of the viewpoint for rendering;
A viewpoint coordinate value storage function for storing the input rendering viewpoint coordinate values in the storage means;
A three-dimensional material image designation function that prompts designation of an arbitrary three-dimensional material image among the three-dimensional material images;
Projection that generates a projection material image obtained by projecting the arbitrary three-dimensional material image on the projection plane in a direction from the stored viewpoint to the attention point by rendering the specified arbitrary three-dimensional image Material image generation function,
After the three-dimensional material image designation function is repeatedly executed a plurality of times, the viewpoint coordinate input function and the viewpoint coordinate storage function are executed, and the plurality of parts designated by the three-dimensional material image designation function are stored with the viewpoint coordinates stored. A program for providing a three-dimensional material image, which causes a computer to realize a function of executing the projection material image generation function for the three-dimensional material image.   9. The projection material image generation function includes a masking function for masking a predetermined portion set in advance in the storage unit for the generated projection material image. A program for providing 3D material images. A plurality of three-dimensional material images are stored in advance in the storage means of the computer, and by rendering any specified three-dimensional material image among the three-dimensional material images, rendering is performed from the coordinate value of the viewpoint for rendering. A third order that realizes a function of generating a projection material image by projecting the arbitrary three-dimensional material image on a two-dimensional projection plane in a direction toward the coordinate value of the target point of the image, and displaying the projection material image. In the storage medium storing the original material image providing program,
The three-dimensional material image stored in the storage means is adjusted so that the front of the object faces a predetermined coordinate direction,
In each of the three-dimensional material images, a point of interest for rendering is set at a coordinate value set in common to all three-dimensional material images,
A viewpoint coordinate input function for prompting input of coordinate values of the viewpoint for rendering;
A viewpoint coordinate value storage function for storing the input rendering viewpoint coordinate values in the storage means;
A three-dimensional material image designation function that prompts designation of an arbitrary three-dimensional material image among the three-dimensional material images;
Projection that generates a projection material image obtained by projecting the arbitrary three-dimensional material image on the projection plane in a direction from the stored viewpoint to the attention point by rendering the specified arbitrary three-dimensional image Material image generation function,
At least a program for causing a computer to realize the function of repeating the three-dimensional material image designating function and the projecting material image generation function a plurality of times while holding the viewpoint coordinates stored in the viewpoint coordinate storage function is stored. A storage medium characterized by that. A plurality of three-dimensional material images are stored in advance in the storage means of the computer, and by rendering any specified three-dimensional material image among the three-dimensional material images, rendering is performed from the coordinate value of the viewpoint for rendering. A third order that realizes a function of generating a projection material image by projecting the arbitrary three-dimensional material image on a two-dimensional projection plane in a direction toward the coordinate value of the target point of the image, and displaying the projection material image. In the storage medium storing the original material image providing program,
The three-dimensional material image stored in the storage means is adjusted so that the front of the object faces a predetermined coordinate direction,
In each of the three-dimensional material images, a point of interest for rendering is set at a coordinate value set in common to all three-dimensional material images,
A viewpoint coordinate input function for prompting input of coordinate values of the viewpoint for rendering;
A viewpoint coordinate value storage function for storing the input rendering viewpoint coordinate values in the storage means;
A three-dimensional material image designation function that prompts designation of an arbitrary three-dimensional material image among the three-dimensional material images;
Projection that generates a projection material image obtained by projecting the arbitrary three-dimensional material image on the projection plane in a direction from the stored viewpoint to the attention point by rendering the specified arbitrary three-dimensional image Material image generation function,
After the three-dimensional material image designation function is repeatedly executed a plurality of times, the viewpoint coordinate input function and the viewpoint coordinate storage function are executed, and the plurality of parts designated by the three-dimensional material image designation function are stored with the viewpoint coordinates stored. A storage medium that stores at least a program for causing a computer to realize a function of executing the projection material image generation function for the three-dimensional material image.   12. The projection material image generating function includes a masking function for masking a predetermined portion set in advance in the storage unit for the generated projection material image. A storage medium that stores a program for providing three-dimensional material images.

Images