JPH11203499A - Information processor, information processing method and presentation medium - Google Patents

Abstract

PROBLEM TO BE SOLVED: To set a battle area in a shared virtual space by receiving a script from a server and controlling the display of a virtual life object based on the script. SOLUTION: A command for a prescribed event to be performed in a prescribed area existent in the shared virtual space corresponding to the virtual life object to be bred in the shared virtual space by a user is transmitted by the transmission means of a MODEM 39, and the script for controlling the action of the virtual life object corresponding to the result of the prescribed event transmitted from the server is received by the reception means of the MODEM 39 Based on the script, the display of the virtual life object is controlled by the display control means of a CPU 30. Thus, the battle area can be set in the shared virtual space and the virtual life objects can mutually compete.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an information processing apparatus and method, and a providing medium, and more particularly to an information processing apparatus and method capable of causing virtual life objects to compete with each other in a shared virtual space. It is related to the distribution medium.

[0002]

2. Description of the Related Art Conventionally, NIFTY-Serve (trademark) and US Compu
A plurality of users, such as Serve (trademark), connect their personal computers to the center host computer via a modem and a public telephone network, and access the host computer based on a predetermined communication protocol. In the field of so-called personal computer communication services, a cyberspace service called Habitat (trademark) is known.

[0003] Habitat was established in 1985 by LucasFilm of the United States.
Quark, a U.S. commercial network,
After operating for about three years at antumLink, the service was launched on NIFTY-Serve in February 1990 as Fujitsu Habitat (trademark). In this Habitat, “Populopolis” drawn in two-dimensional graphics
polis) "in a virtual city called avatar;
By sending in alternations of users called incarnations of God that appear in Indian mythology, users can chat with each other (Chat; text-based real-time dialogue by inputting and displaying characters). For a more detailed description of Habitat, see Cyberspace, Michael Benedict, March 20, 1994, first edition, NTT Publishing ISBN
4-87188-265-9C0010 (Original; Cyberspace: First Ste)
ps, Michael Benedikt, ed. 1991, MIT PressCambrige, MA
ISBN 0-262-02327-X) pp. 282-307.

In a conventional cyberspace system operated by this kind of personal computer communication service, a virtual cityscape or the inside of a room is drawn in two-dimensional graphics, and the avatar is moved in the depth or front direction. When moving, the avatar was simply moved up and down on the background of the two-dimensional graphics, and the simulated experience of walking and moving in the virtual space was poor in expressiveness on the display. In addition, since the virtual space in which the avatar of one's alter ego and the avatar of another person are displayed is viewed from the viewpoint of a third party, the sense of the simulated experience is impaired also in this point.

Therefore, as disclosed in Japanese Patent Application Laid-Open No. 9-81781, a function of displaying a virtual space in three-dimensional graphics so that a user can freely walk around from the viewpoint of an avatar has been proposed.
VRML (Virtual Reality Modeling Language) 3
This is realized by using a description language of dimensional graphics data. Regarding various cyberspaces where chats are performed using avatars on behalf of users, see Nikkei Electronics 1996.9.9 (no.670)
Pp. 151-159.

On the other hand, in recent years, breeding simulation games for growing tropical fish, breeding simulation games for growing virtual creatures with artificial intelligence living in a virtual world, and the like have been known as software programs for personal computers. . Also, there is known a product in which pseudo pets such as dogs and cats are displayed on an electronic organizer so that the growing process can be enjoyed (Nikkei Electronics 19
97.4.7 (no.686), pages 131 to 134). Furthermore,
Tamagotchi (trademark) developed and commercialized by Bandai Corporation is widely known as an egg-sized portable electronic pet incorporating this kind of breeding simulation game program.

This kind of portable electronic pet is a one-chip LS
CPU (Central Processing Unit), ROM, RAM for I (Large Scale Integrated Circuit)
A breeding simulation game program is stored in the ROM, and a virtual pet figure and state are displayed on an LCD (liquid crystal display device). The user operates the operation button to give an instruction such as “feed” or “clean” necessary for breeding a virtual creature as a pet. As a result, the virtual creature displayed on the LCD grows, and in the course of the growth, the appearance of the virtual creature becomes, for example, an egg,
Chickens gradually change to adults.

In addition, according to the user's button operation, it is programmed that the virtual creature grows smoothly if the instruction is appropriate, and becomes ill or dies if the instruction is inappropriate. Furthermore, the virtual creature is programmed to make various requests based on the elapsed time from the birth of the virtual creature obtained by the calendar timer incorporated therein. For example, in the night time zone, a request for sleep is made by the virtual creature, in the meal time zone, a meal request is made, and a request for a snack or play is made at random. If the user does not properly respond to these requests, the growth of the virtual creature is delayed or the character is deteriorated. On the other hand, if the user responds appropriately, the program is programmed to extend the life of the virtual creature.

[0009] For example, Japanese Patent Application Laid-Open No. 07-160853 discloses a technique applied to an electronic organizer or the like and displaying an image according to a growth process of an organism such as an animal or a plant. That is, a bitmap image of each stage of the growth process of the plant character is stored in the ROM, a plant character corresponding to the growth degree is displayed on the LCD, and the plant growth elements (water, light, etc.) stored in the ROM in advance are stored. , Fertilizer), and by keying in the dose of each growth element, the value of each growth element according to the dose is stored in RAM.
Are set in the water quantity register, light quantity register, and fertilizer quantity register, respectively, a new growth rate is calculated based on the values of these registers, and a plant character corresponding to the calculated growth rate is read from the ROM. Is displayed on the LCD. Thereby, the growth process of the plant according to the breeding situation of the user is displayed.

[0010]

As described above, a pseudo pet (hereinafter, also referred to as a virtual pet or a virtual life object) grows in various states according to the operation of the user who is the owner. By the way, in the conventional shared virtual space, a user competes against a virtual pet raised by himself / herself with a virtual pet raised by another user using a predetermined standard, or a predetermined growth set in the virtual pet. There was a problem that parameters could not be compared.

The present invention has been made in view of such a situation, and is intended to enable virtual life objects to compete with each other by setting a battle area in a shared virtual space.

[0012]

An information processing apparatus according to claim 1 provides a command for a virtual life object bred by a user in a shared virtual space at a predetermined event performed in a predetermined area existing in the shared virtual space. Transmitting means for transmitting a virtual life object, and receiving means for receiving a script transmitted from the server for controlling the behavior of the virtual life object corresponding to the result of the predetermined event, and controlling the display of the virtual life object based on the script. Display control means.

[0013] The information processing method according to a third aspect of the present invention includes a transmitting step of transmitting a command in a predetermined event performed in a predetermined area existing in the shared virtual space to a virtual life object raised by the user in the shared virtual space. Receiving a script transmitted from the server and controlling the behavior of the virtual life object corresponding to the result of the predetermined event, and a display control step of controlling display of the virtual life object based on the script. It is characterized by the following.

[0014] The providing medium according to claim 4 is a transmission step of transmitting a command to a virtual life object raised by the user in the shared virtual space in a predetermined event performed in a predetermined area existing in the shared virtual space; A computer, comprising: a receiving step of receiving a script transmitted from a server and controlling a behavior of a virtual life object corresponding to a result of a predetermined event; and a display control step of controlling display of the virtual life object based on the script. It is characterized by providing a program.

According to a fifth aspect of the present invention, there is provided an information processing apparatus comprising: a determination unit configured to determine a result of a predetermined event performed by a virtual life object bred by a user in a shared virtual space based on information transmitted from a client device; Transmitting means for transmitting, to the client device, a script for controlling the display of the behavior of the virtual life object in accordance with the determination result determined by the means.

According to a sixth aspect of the present invention, in the information processing method, a determining step of determining a result of a predetermined event performed by a virtual life object bred by the user in the shared virtual space based on information transmitted from the client device; Transmitting a script for controlling the display of the behavior of the virtual life object to the client device in accordance with the determination result determined in the step.

According to a seventh aspect of the present invention, in the providing medium, a determination step determines a result of a predetermined event performed by the virtual life object bred by the user in the shared virtual space based on information transmitted from the client device. Transmitting a script for controlling the display of the behavior of the virtual life object to the client device in accordance with the determination result determined in the step (a).

[0018] The information processing apparatus according to claim 1, and claim 3.
In the information processing method according to the item (4) and the providing medium according to the item (4), a command in a predetermined event performed in a predetermined area existing in the shared virtual space is transmitted to the virtual life object bred by the user in the shared virtual space Then, a script for controlling the behavior of the virtual life object corresponding to the result of the predetermined event transmitted from the server is received. Further, the display of the virtual life object is controlled based on the script.

An information processing apparatus according to claim 5, claim 6
In the information processing method according to the aspect of the invention and the providing medium according to the aspect, the result of the predetermined event performed by the virtual life object bred by the user in the shared virtual space is determined based on information transmitted from the client device. Then, a script for controlling the display of the behavior of the virtual life object in accordance with the determination result is transmitted to the client device.

[0020]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below. In order to clarify the correspondence between each means of the invention described in the claims and the following embodiments, each means is described. When the features of the present invention are described by adding the corresponding embodiment (however, an example) in parentheses after the parentheses, the result is as follows.

That is, the information processing apparatus according to the first aspect of the present invention transmits a command to a virtual life object bred by a user in a shared virtual space at a predetermined event in a predetermined area existing in the shared virtual space. Means (for example, the modem 39 in FIG. 4), and receiving means (for example, the modem 39 in FIG. 4) for receiving a script for controlling the behavior of the virtual life object corresponding to the result of the predetermined event transmitted from the server. And a display control unit (for example, CPU 30 in FIG. 4) for controlling the display of the virtual life object based on the script.

The information processing apparatus according to claim 5 is
The determination unit (for example, the shared server 12 in FIG. 3) determines the result of a predetermined event performed by the virtual life object bred in the shared virtual space by the user based on information transmitted from the client device, and the determination unit determines A transmission unit (for example, the shared server 12 in FIG. 3) for transmitting a script for controlling the display of the behavior of the virtual life object in accordance with the determination result to the client device is provided.

However, of course, this description does not mean that the means are limited to those described.

Prior to the description, the Internet (The Int) which is a computer network constructed on a worldwide scale
ernet) to provide a variety of information
VRML (virtual reality m) is a description language that can handle three-dimensional information in a unified manner using the framework of (web).
odeling language).

Here, as an information providing system that can be used on the Internet, Swiss CERN (European Center)
WWW developed by European Nuclear Physics Research Institute is known. This allows information such as text, images, and audio to be viewed in a hypertext format.In accordance with a protocol called HTTP (Hyper Text Transfer Protocol), information stored in a WWW server can be This is to perform asynchronous transfer to the terminal.

The WWW server is an HTTP daemon (HTTP: Hyper)
It consists of server software called Text Transfer Protocol (Hypertext Transfer Protocol) and HTML files that store hypertext information. Note that a daemon means a program that performs management and processing in the background when working on UNIX. Hypertext information is HTML (HyperText Ma
rkup Language (hypertext description language). In the description of hypertext in HTML, the logical structure of a sentence is expressed by a format specification called a tag surrounded by “<” and “>”. Description of a link to other information is made by link information called an anchor. When specifying the location where the information exists by the anchor, use URL (Uniform Re
source Locator) is used.

A file described in HTML is transferred to TCP / IP (Tra
The protocol for transferring data on a network (nsmission Control Protocol / Internet Protocol) is HTTP. It has a function to transmit the information request from the client to the WWW server and to transfer the hypertext information of the HTML file to the client.

A WWW browser (browser means browsing), Netscape Navigator (Netscape USA) is widely used as an environment using WWW.
Communications software) and other client software.

Using this WWW browser, it is possible to browse a file on a WWW server on the Internet corresponding to the URL, which is spread on a worldwide scale, a so-called homepage,
As it is called so-called Internet surfing, a wide variety of WWWs are traversed by linked home pages one after another.
Can access information sources.

In recent years, this WWW has been further extended to enable description of a three-dimensional space and setting of hypertext links for objects drawn with three-dimensional graphics, and to follow a WWW server while following these links. VR that displays a three-dimensional space described in a three-dimensional graphics description language called VRML that can be accessed one after another
An ML browser has been developed.

The details of this VRML are described in, for example, "Knowing VRML: Construction and Browsing of Three-Dimensional Cyberspace [by Mark Pessi, Koichi Matsuda, Teruhisa Kamachi, Shoichi Takeuchi, Yasuaki Honda, Junichi Korumoto, Masayuki Ishikawa, Translated by Ken Miyashita and Kazuhiro Hara, first edition published on March 25, 1996, Prentice Hall Publishing ISBN4-931356
-37-0] (Original; VRML: Browsing & Building Cyberspac
e, Mark Pesce, 1995 New Readers Publishing ISBN 1-5
6205-498-8)) ”and“ VRML latest trends and Cybe ”
rPassage [Koichi Matsuda and Yasuaki Honda, bit (Kyoritsu Shuppan) / 1996 Vol.28 No.7 pp29-pp36, No.8 pp5
7 to pp65, No.9 pp29 to pp36, No.10 pp49 to pp5
8] ”.

Also, The Virt in August 4, 1996
ual Reality Modeling Language Version 2.0, ISO / IE
The official and complete specification of CCD 14772 can be found at http: // webspac
It is published at e.sgi.com/moving-worlds/spec/index.html, and its Japanese version is http://www.webcity.co.jp/i
It is published at nfo / andoh / VRML / vrml2.0 / spec-jp / index.html.

Further, as a browser for VRML 2.0 and software for a shared server, for example, Sony Corporation, which is the applicant of the present invention, describes “Community Place Browser / Bure”.
au (trademark) "and commercialized it, and its beta version (trial version) is
It can be downloaded from /vs.sony co.jp.

When constructing a three-dimensional virtual space using such VRML 2.0, first, figure data representing the shape, motion, position, etc. of an object (model) in the virtual space is created by VRML. (Model creation), adding a switch (sensor) to the model that generates an event when the user clicks and points the model in the virtual space displayed on the screen (sensor addition),
Programming of scripts (script creation) to realize events that occur in response to pointing to sensors, operation of sensors and activation of scripts, graphic data and scripts (graphic data, scripts, lights defined in VRML, etc.) VR that expresses desired content by associating (routing) between common nodes etc.
Create an ML file.

For example, http://www.ses.co.jp/SES/STAFF
/kan/howto/howto1.html explains carefully how to write VRML 2.0 and sample data. Some of them are introduced below.

1. To see the world written in VRML2.0, H
Just as an HTML browser is required to view data written in TML format, a VRML browser that supports VRML 2.0 is required to view data written in VRML 2.0 format.
All VRML 2.0 data created on this page is SONY
This is being done at the Community Place Browser. To indicate that the file was written in VRML, the file extension was set to * .wrl (meaning world), and to indicate that the file was written in VRML 2.0, the first line of the file was #VRML V
2.0 It is necessary to write utf8.

2. Basic Structure of VRML2.0 Data VRML2.0 data is composed of nodes and fields, and is basically written in the following manner. Node {Field (s)} In this, Fields can be omitted, but Node and curly braces '{', '}' cannot be omitted. Fields pass variables to nodes and specify parameters for nodes.
If the field is omitted, the default value will be used. In addition, "single value field (SF)" which has only a single value in the field and "multivalue field which has multiple values"
(MF) ", where single-valued fields begin with" SF "and multi-valued fields begin with" MF ".

3. How to Write a Sphere VRML2.0 provides nodes for drawing basic figures such as a sphere, a rectangular parallelepiped, a cylinder, and a cone. As mentioned earlier, each node has a field for specifying parameters. For example, Sphere for drawing a sphere
The node has a radius field to specify the radius, and a sphere with a radius of 1 is displayed by writing as follows. The data type of the radius field is SFFloat
Therefore, the value of one floating point number is taken.

[0039]

Actually, it is not necessary to write the second, third and seventh and eighth lines. Only the first line and the fourth to sixth lines can display a sphere with a radius of 1 properly. The Transform node is one of the types of nodes called Group nodes, and is a node for literally grouping nodes. Refer to “Appendix1: VRML2.0 Node List” for detailed functions and fields of other nodes, including the Transform node, which will be described later.
The node for writing the sphere is Sphere, but this node is
This is one of the nodes called Geometry node. Geomet
The ry node is a shape node geo that defines the appearance and shape
Must be written in the measurement field.

4. Coloring the Sphere To color the sphere described above, write as follows. Sample2 1: #VRML V2.0 utf8 2: Transform {3: children [4: Shape {5: appearance Appearance {6: material Material {diffuseColor 1 0 0} 7:} 8: geometry Sphere {radius 1} 9:} 10:] 11:}

This sphere is displayed in red. Lines 5 to 7 are added. Since the data type of the diffuseColor field is SFColor, it has only one set of three single-precision floating-point numbers representing RGB colors. The Material node that defines the appearance is the mate of the Appearance node
It is to be written in the rial field. Also, Appear
The ance node is to be written in the appearance field of the shape node. Therefore, such a seemingly complicated structure is obtained.

5. Pasting Textures In addition to coloring objects, it is also possible to paste image files. File formats that can be used as textures in VRML 2.0 are JPEG, GI
F, and PNG. Here, a GIF texture is used. Sample3 1: #VRML V2.0 utf8 2: Transform {3: children [4: Shape {5: appearance Appearance {6: texture ImageTexture {url "image.gif"} 7:} 8: geometry Box {} 9:} 10:] 11:}

The sixth line applies the texture. ImageTexure node is the texture of Appearance node
This is how it is written because it is supposed to be written in the field. Note that the Box node on the eighth line is a node for drawing a rectangular parallelepiped.

6. Move the position of the object Next, move this red sphere to the right. Sample4 1: #VRML V2.0 utf8 2: Transform {3: translation 2 0 0 4: children [5: Shape {6: appearance Appearance {7: material Material {diffuseColor 1 0 0} 8:} 9: geometry Sphere { radius 1} 10:} 11:] 12:}

The object is translated in the translation field added to the third line. In the translation field, translation xyz is used to specify the amount of movement on the x-axis, y-axis, and z-axis, respectively. On the browser, the x-axis represents left and right (+ to the right), the y-axis represents up and down (+ to the top), and the z-axis represents depth (+ to the front). Thus, translation 2 0 0 translates 2 to the right.

7. Add an object Add a green cone to the left of the red sphere. Sample5 1: #VRML V2.0 utf8 2: Transform {3: translation 2 0 0 4: children [5: Shape {6: appearance Appearance {7: material Material {diffuseColor 1 0 0} 8:} 9: geometry Sphere { radius 1} 10:} 11:] 12:} 13: Transform {14: translation -2 0 0 15: children [16: Shape {17: appearance Appearance {18: material Material {diffuseColor 0 1 0} 19:} 20 : geometry Cylinder {} 21:} 22:] 23:}

The source added after the 13th line has the same structure as the source added before the 12th line. The difference is that the object moves from a sphere to a cone, the color moves from red to green, and the position moves to the left.

8. Writing with Polygons Although the above-described “How to Write VRML 2.0” uses primitive figures, polygons are used when writing complex figures. IndexedLineSet, Inde for displaying with polygons
Two nodes of xedFaceSet are prepared. IndexedLi
neSet represents a line, and IndexedFaceSet represents a face.

This sample represents a cube in six planes. To represent a polygon, first determine the coordinates of the vertices (lines 7 to 16). These coordinates are 0,1,2,
And numbered. That is, “1 0 1” on the 10th row is the “2” coordinate. Next, it is determined at what coordinates and at what coordinates the surface is configured (lines 18 to 25). 19
“0, 1, 2, 3, −1” on the line indicates that “a surface is to be created with coordinates 0, 1, 2, 3”.

9. Naming Nodes DEF and USE to reuse already defined nodes
There is a function called. For example, assume that two blue spheres with a radius of 2 are drawn. If you write in the conventional way, it will be as follows. Sample7 1: #VRML V2.0 utf8 2: Transform {3: children [4: Shape {5: appearance Appearance {6: material Material {diffuseColor 0 0 1} 7:} 8: geometry Sphere {radius 2} 9:} 10:] 11:} 12: Transform {13: translation 0 5 0 14: children [15: Shape {16: appearance Appearance {17: material Material {diffuseColor 0 0 1} 18:} 19: geometry Sphere {radius 2} 20:} 21:] 22:}

The twelfth and subsequent lines are exactly the same as before the eleventh line, except for the coordinate movement on the thirteenth line. It is clearly wasteful to describe the once defined "blue sphere with radius 2" in the same way. So we do the following.

Sample7 Kai 1: #VRML V2.0 utf8 2: Transform {3: children [4: DEF BlueSphere Shape {5: appearance Appearance {6: material Material {diffuseColor 0 0 1} 7:} 8: geometry Sphere { radius 2} 9:} 10:] 11:} 12: Transform {13: translation 0 5 0 14: children [15: USE BlueSphere 16:} 17:] 18:} Looking at the fourth line, it becomes DEF BlueSphere Shape ing. This is “Shape {……} replaced with“ BlueSphere ”
Name. From now on, simply writing USE BlueSphere will represent the same content as Shape {……}.

10. Reading WRL File When creating large VRML data, it is not a very good method to write all descriptions in one file. It is more convenient to divide each part so that it can be called up as needed. In such a case, use an Inline node. For example, read and display Sample1.wrl created in 1.

11. Linking a link It is also possible to link an object and jump to another page when the object is clicked.

An object to be linked is set as a child node and is bound by an anchor node. Anchor node is one of the Group nodes. Write the link destination file in the url field. The text you write in the description field is displayed while the mouse pointer is touching the object.

12. Light setting VRML2.0 uses Directional to set light in the world.
Light (parallel light), PointLigt (point light source), SpotLight
(Spotlight) Three nodes are prepared. Here, a PointLigt node will be described as an example. The object is rotated on the third line so that it is easy to see how the light hits.

The appearance of the object differs depending on the position of the light source in the sixth row. In this example, a light source is placed in front of the object.

13. World Environment (1) Although the description so far was mainly about the creation of an object, this time, how to use a node other than the creation of an object will be described. Although it is arbitrarily named as world environment, etc., it is not known whether such a term is common.
First, HeadLig provided by default in the browser
Try deleting ht. ON / OFF of HeadLight is
Can be changed with Option, but can also be set by writing in the file. Sample11 1: #VRML V2.0 utf8 2: NavigationInfo {3: headlight FALSE 4:} 5: Transform {6: children [7: Shape {8: appearance Appearance {9: material Material {diffuseColor 1 0 0} 10:} 11: geometry Sphere {} 12:} 13:] 14:}

Looking at the Option of the browser in this sample, the check of Headlight is unchecked. It can be seen that this sample is extremely darker than the previous samples. HeadLight is a light that always shines in the direction you are looking, and without it it looks like this.
Newly added NavigationInf on lines 2-4
o It is a node. Turn headlight ON / OFF by setting headlight field of this node to TRUE or FALSE
I do. By turning off HeadLight and setting an optional light, the brightness can be set effectively.

14. World Environment (2) The NavigationInfo node has several other fields. You can change the navigation method in the type field in it. By default
The navigation method set to WALK is FLY, which can move ignoring gravity, EXAMINE, which moves an object without moving itself, and NONE, which does not control anything. By the way, WALK is a navigation method that moves under the influence of gravity.

Sample12 1: #VRML V2.0 utf8 2: NavigationInfo {3: type EXAMINE 4:} 5: Transform {6: children [7: Shape {8: appearance Appearance {9: material Material {diffuseColor 1 0 0}} 10:} 11: geometry Box {} 12:} 13:] 14:} This sample uses EXAMINE. Dragging an object with the mouse rotates the object.

15. Adding a Title to a Scene In HTML, a title can be given by surrounding it with a <title> tag. If you do not specify this tag, the title will be displayed as [http: //ryo1.is.kochi-u…howto3.html]. The same goes for VRML. In the previous samples, the path is displayed because no title is specified. Use the WorldInfo node to specify a title in VRML.

Sample13 1: #VRML V2.0 utf8 2: WorldInfo {3: title "Spin Box" 4: info ["Autor H.Kan", "http://ryo1.is.kochi-u.ac.jp / "] 5:} 2: NavigationInfo {3: type EXAMINE 4:} 5: Transform {6: children [7: Shape {8: appearance Appearance {9: material Material {diffuseColor 1 0 0} 10:} 11: geometry Box {} 12:} 13:] 14:}

A WorldInfo node was added to the second to fifth lines. In this sample, the previous sample is called "Spin
(It was not displayed in the Plugin version.) The info field contains information other than the title, but does not change anything on the browser.

16. Change Viewpoint Position By default, the viewpoint is initially somewhere on the z-axis (depending on the placement of objects). Here, the initial viewpoint position can be changed to an arbitrary position.

Sample14 1: #VRML V2.0 utf8 2: Viewpoint {position xyz} 3: Transform {4: children [5: Shape {6: appearance Appearance {7: material Material {diffuseColor 1 0 0} 8:} 9 : geometry Sphere {} 10:} 11:] 12:} 13: Transform {14: translation -3 0 0 15: children [16: Shape {17: appearance Appearance {18: material Material {diffuseColor 0 1 0} 19: } 20: geometry Sphere {} 21:} 22:] 23:} 24: Transform {25: translation 3 0 0 26: children [27: Shape {28: appearance Appearance {29: material Material {diffuseColor 0 0 1} 30 :} 31: geometry Sphere {} 32:} 33:] 34:}

There is a red sphere at (0, 0, 0), a green sphere at (-3, 0, 0), and a blue sphere at (3, 0, 0). Viewpoint on line 2
If you specify specific coordinates in the node's position field, that will be the first viewpoint. However, the line of sight is always the direction of the z-axis.

17. Changing the direction of the line of sight In sample 14, only the coordinates of the viewpoint are changed, but the line of sight can of course be specified. Viewpoi when specifying direction
Use the nt node, but use the orientation field for the field. orientation field is SFRotation
This is a type field and has a point axis and a rotation angle as values.

18. Attach Sensors Among VRML2.0 nodes, there is a node called a sensor node. Nodes for sensing and judging various things in the scene. There are seven types in total. This Web
Community Place Brows whose operation is checked on the page
er does not yet support some Sensor nodes. Here, we attach a TouchSensor to the object to detect whether the mouse hits the object.

[0071]

Only the fourth line differs from the previous samples. Here, TouchSens named TS
or is attached to the Box. When the mouse cursor touches the Box (the browser you use is Community Place
It should change to a hand (in a Browser) (the cursor may not change in some other browsers). By the way, nothing happens when you click.

19. Add Motion (1) VRML2.0 is significantly different from VRML1.0 in that it can add motion to the scene. Java for movement
There is a method using a script such as VRMLScript (JavaScript) or a method using an Interplator node. Let's start with the method using Interplator nodes. I
nterplate means “insert” or “interpolate”. Interpolator node value, position, 3D
You can add motion to the scene by changing the coordinates, direction, normals, and color values. Here we interpolate the direction
Try rotating the object using the OrientationInterpolator node.

Sample 16 1: #VRML V2.0 utf8 2: DEF OBJ Transform {3: children [4: Shape {5: geometry Box {size 2 3 1} 6:} 7:] 8:} 9: DEF TS TimeSensor {10: cycleInterval 1 11: loop TRUE 12: stopTime -1 13:} 14: DEF OI OrientationInterpolator {15: key [0, 0.125, 0.25,0.375, 0.5, 16: 0.625, 0.75, 0.875, 1,] 17: keyValue (0 1 0 0, 0 1 0 0.785, 0 1 0 1.57, 18: 0 1 0 2.355, 0 1 0 3.14, 0 1 0 -2.355, 19: 0 1 0 -1.57, 0 1 0 -0.785, 0 1 0 0] 20:} 21: ROUTE TS.fraction_changed TO OI.set_fraction 22: ROUTE OI.value_changed TO OBJ.set_rotation

First, some nodes are given names. Lines 2, 9, and 14 define OBJ, TS, and OI, respectively. As will be described later, this is necessary when passing events. Look at lines 9-13. TouchSenso
r is a node that senses the passage of time, and can generate events at regular intervals as time passes. loop
The field is an SFBool field that takes TRUE or FALSE, and if TRUE, continues until stopTime. here
stopTime -1 and startTime (default is 0) and startTi
Since it is smaller than me, it will be continued forever. Cyc for slower rotation
Increase the value of leInterval.

Lines 14 to 20 correspond to OrientationI
This is an nterpolator node. Every Interpolator node has two fields, key and keyValue. key sets the animation time interval between 0 and 1. keyValue sets a specific field value (here, MFRotation) at the interval set by key.
Here, the rotation time is set around the y-axis by dividing the animation time interval into nine equal parts.

However, this alone cannot add motion to the scene. It is necessary to pass the event generated by TimeSensor node to OrientationInterpolator node. Look at lines 21,22. The event is passed on the line that starts with the keyword ROUTE. TimeS
When ensor TS starts, fraction_changed is evented out. If fraction_changed is out, set_fraction of OrientationInterplator OI
Event in. This is the operation of ROUTE on line 21. Line 22 is the set_fracti that was event-in
OrientationInterplator OI interpolates the value from the on value,
Put va in the translation field of Transform OBJ
Event out as lue_changed. Here is another sample.

20. Add movement (2) This is a sample that moves when the object is clicked with the mouse. Positio interpolating position to move
Use the nInterpolator node. Sample17 1: #VRML V2.0 utf8 2: DEF OBJ Transform {3: children [4: DEF TS TouchSensor {} 5: Shape {6: appearance Appearance {7: material Material {diffuseColor 1 0 0} 8:} 9: geometry Box {} 10:} 11:] 12:} 13: DEF TIS TimeSensor {cycleInterval 5} 14: DEF PI PositionInterpolator {15: key [0, 0.2, 0.4, 0.6, 0.8, 1.0] 16: keyValue [0 0 0, 0 0 -2, 0 2 -4, 0 4 -6, 2 4 -6, 4 2 -6] 17:} 18: ROUTE TS.touchTime TO TIS.set_startTime 19: ROUTE TIS.fraction_changed TO PI.set_fraction 20: ROUTE PI.value_changed TO OBJ.set_translation

Now, add a red cube named OBJ to T
ouchSenor TS is attached. When an object is clicked, the touchTime of TouchSenor TS changes to TimeSensor
Event is out at start time of TIS. The sample source has no startTime field in the TimeSensoe node, but defaults to startTime 0. The rest is the same as the previous sample. Objects are moved by these ROUTEs.

Here, a mechanism for realizing an autonomous movement (Behavior) in a VRML virtual space, which is a function newly added to the first generation VRML 2.0 in addition to the first generation VRML 1.0. Outline.

In VRML 2.0, an object autonomously responds to an event that occurs with an operation on an object placed in a three-dimensional virtual reality space or a timer event that occurs when a preset time has elapsed. Movement can be realized. This Behavior mechanism is realized by the cooperative operation of the three elements of sensor, routing, and script.

That is, a sensor node described as a VRML file, which is previously associated with a node such as an object arranged in a three-dimensional virtual reality space, is set to an external event based on a change in the value of the field. And generate an event in the VRML scene. The generated event is transmitted to an external script, which is a program that defines the behavior of the object, based on the routing described as a VRML file. A method called when a specific event arrives is described in the external script in advance, and the external script that receives the event transmitted by the routing executes a process based on the description, and then executes the process result. Then, the value of the field of the corresponding node in the VRML scene is changed based on the description of the routing.

In VRML 2.0, as a sensor node, for example, a TouchSensor that generates an event when a pointing device passes over a specified object or is clicked by a user, or a ViewPoint in a specified area. A ProximitySensor that generates an event when a (user's viewpoint) invades, and a TimeSensor that is generated at a given time or every time a predetermined time interval elapses are defined.

The mechanism of Behavior will be described in more detail. As mentioned earlier, the Behavior mechanism consists of sensors, events, routing, and scripts.

The sensor is divided into two functions. -A type that senses user operations-A type that senses changes in the system

The sensor of the type that senses the operation of the user is a software switch associated with an object or the like arranged in the three-dimensional virtual space. For a type of sensor that senses a change in the system, a timer in which the operation time is set in advance is activated.
The function of the sensor is to detect these external events and
Converting it to an event inside VRML.

An event refers to data for transmitting information between related nodes inside VRML. Actually, a change in a field value described in the VRML file is transmitted as an event.

The routing is a mechanism for specifying to which node the event detected by the sensor function is to be transmitted, and specifies the information transmission route by the event.

The script is an event input / output port, which can perform some calculation from the input event and output the result as an event. Scripts are not restricted to a particular language, but at this stage Java and Ja
vaScript, C language commonly used in ordinary systems, Tcl / Tk and PERL commonly used in UNIX, and Visual Basic language provided by Microsoft are supported. As described above, VRML 2.0 has specifications that do not depend on a specific script language. (While studying the VRML 2.0 specifications, VRMLScript was temporarily adopted as a specific language specification, but this concept has been canceled. T).

Next, with regard to the processing means of the Behavior, FIG.
This will be described with reference to FIG. If you diagram the behavior process,
As shown in FIG. Hereinafter, the flow of the processing signal will be described for each part.

Sensor Node As described above, sensor nodes are roughly classified into two systems. A type that senses user operations,
It is a type of sensor that senses changes in the system.

The former sensor includes a sensor node such as TouchSensor or PlaneSensor which senses when a mouse is clicked or passes through a three-dimensional object or its plane, and a set time comes as the latter sensor. And a TimeSensor that has a mechanism to generate an event is prepared.

In the example of FIG. 1, it is assumed that TouchSensor is attached to the sphere. At this time, when the user clicks the mouse on the ball, TouchSensor detects this event. This event is detected when the field value of the eventOut field of TouchSensor changes. Normally two events occur with a single mouse click. That is, the timing when the mouse button is pressed and the timing when the mouse button is released.

Next, this event is routed by the routing description part.

Routing "Route" as shown in FIG. 2 designates the routing of this event.

The event that occurred in the sensor description part is Ro
The event is passed to an external file by being transmitted to the eventOut field of the ute and further transmitted to the script node described below, and the Behavior function is executed.

Script node This node is a node that mediates the link between the VRML file and an external script. According to the description format of the script node, in what language it is described, to specify a file name, and to exchange events with external script files, use eventIn
Field and eventOut field are defined. At this time, the script files that can be used are Java, JavaScri
It covers a wide variety of languages, including pt, C, Tcl / Tk, PERL, and Visual Basic.

As an actual processing means, the process is transmitted to a script file in which a routed event is described in a script node, and an external script file is executed. An external script file is received at eventIn (event entrance) defined therein, and executes the processing described in the file.
After the processing is completed, the result is returned from the eventOut (exit of the event) to the routing of the VRML file. The VRML file executes the returned result and returns a series of Behavior
The process ends.

By using such a mechanism of Behavior realized by the cooperative operation of the sensor, the routing, and the script, for example, an object simulating a switch arranged in a three-dimensional virtual reality space is clicked with a mouse. By doing so, the appearance (shape, posture, size,
Color, etc.), and behavior sequence, etc., can be dynamically changed.

For a detailed description of this Behavior mechanism, see http://webspace.sgi.com/moving-worlds/sp
ec / part1 / concepts.html and its Japanese version, ht
tp: //www.webcity.co.jp/info/andoh/VRML/vrml2.0/spe
August published at c-jp / part1 / concepts.html
4, The Virtual Reality Modeling Langu in 1996
age Version 2.0, ISO / IEC CD 14772 Specification, 4. It is disclosed in the Concepts section. This section describes the key concepts in using the VRML specification. How to combine nodes into the scene graph, how nodes generate and receive events, how to create node types with prototypes, how to add node types to VRML and export them for external use,
General items about various nodes are described, such as how to incorporate scripts that operate as programs into VRML files.

Next, a virtual life object is created in a shared virtual space by applying such a mechanism for realizing the autonomous movement (Behavior) of VRML 2.0, and the virtual life object is generated according to the user's operation and time lapse. A growth parameter (appearance growth or internal growth (individuality)) that changes in response to the occurrence of a predetermined event is managed by a server, and based on the growth parameter transferred from the server, the appearance (shape, shape, (Posture, size, color, etc.) or one or both of the behavior sequence is interpreted and executed by a script program to dynamically change the display of virtual life objects according to the growth parameters. Details will be described below.

FIG. 3 is an overall system configuration diagram of an embodiment of the present invention.

In FIG. 3, client PCs (personal computers) 1-3 are a VRML browser and WWW
Browser installed and these are working,
IP (Internet connection service provider) 4-6
Is connected to the Internet 7 via the Internet.

A WWW server 1 is connected to a LAN (Local Area Network) 9 connected to the Internet 7 via a router 8.
0, WLS (World Location Server) 11, Shared server 1
2. AO (Application Object) servers 13 and 14, a mail server 15, and a communication server 16 are connected. Each of these servers 10 to 16 has
Hard disks (HDD) 10a, 10b, and 11a to 16a are provided, respectively.

The communication server 16 is connected to a telephone 18 and a facsimile machine 19 via a public telephone line network 17, and further has a PHS (Personal Handyphone System).
It is wirelessly connected to a PHS terminal 23 via a service provider 20 and wirelessly connected to a pager terminal 24 via a pager service provider 21.

The hardware configuration of the client PC 1 will be described with reference to FIG.

The CPU 30 of the client PC 1 controls each unit. HDD 31 is a VRML 2.0 file, Java (Sun
Stores VRML content, such as a shared virtual life growth script program by Microsystems (trademark), and owner data. The CD-ROM drive 32 is a CD-R
Read the VRML content stored in the OM disk 33. The ROM 34 stores a BIOS (Basic Input Output Systems) and the like. The microphone 3 is provided in the sound processing circuit 35.
6 and left and right speakers 37 and 38 are connected. MODE
The M39 connects to the Internet 7. I / O (input / output)
The interface 40 includes a mouse 41 and a keyboard 42
Is connected. The graphics processing circuit 43 has a VR
AM44 is built in. The CRT monitor 45 displays the image signal output from the graphics processing circuit 43.
The RAM 46 stores various computer programs.

[0108] The RAM 46 stores Windows 95 data at the time of execution.
Netscape Navigator, which is a WWW browser running on the Internet (trademark of MicroSoft, USA), a Java interpreter, and Community Place Browser, which is a VRML 2.0 browser developed by Sony Corporation, are read and executed by the CPU 30. State.

[0109] The VRML 2.0 browser includes a VR developed by the United States Silicon Graphics and released for free.
QvLib, a library for parsing ML (parser), RenderWare, a software renderer of Criterion Software Ltd. in the UK, or a parser or renderer with equivalent functions are implemented.

Then, as shown in FIG. 3, the Community Place Browser is a Netscape Naviga as a WWW browser.
NCAPI (Netscape Client Applicat
Various types of data are exchanged based on the ion programming interface (trademark).

Netscape Navigator is the Internet 7
When the HTML file and the VRML content (including the VRML file and the script program in Java) are supplied from the WWW server 10 via the
31 is stored. Netscape Navigator processes the HTML files and converts text and images to CRT.
While displaying on the monitor, Community Place Browser uses VR
The ML file is processed to display the 3D virtual space on the CRT monitor, and the behavior of objects in the 3D virtual space is changed according to the processing result of the script program by the Java interpreter.

Although not shown, the other client PCs 2 and 3 are also connected to the client PC 1.
It is configured similarly to.

Next, the operation of the above-described embodiment will be described.

First, a procedure from actually downloading VRML contents via the Internet to setting up a multi-user environment in which one virtual space is shared by a plurality of users will be described with reference to FIGS.

In FIG. 5, as shown by reference numeral 1, first, a home page of a Web site providing VRML content is browsed using a WWW browser. In this example, http://pc.sony.co.jp/sapari/ is browsed. Next, as indicated by the number 2, the users of the client PC1 and the client PC2 are required to store the VRML 2.0 file and the VRM
Each VRML content including a script program (a growth script program by Java) for realizing an autonomous movement (Behavior) in the L space is downloaded.

Of course, provided on the CD-ROM disk 33
VRML contents may be read by the CD-ROM drive 32.

Next, as shown in FIG.
The CML and the client PC 2 are respectively downloaded and temporarily stored in the local HDD 31.
le with the VRML 2.0 Browser Community Place Brow
ser interprets and executes, and as indicated by number 3, VSCP
The WLS 11 is inquired of the URL of the shared server 12 based on (Virtual Society Server Client Protocol). At this time, as shown by the number 4, the WLS 11 is the HDD 11a
Refer to the shared server URL management table stored in
For client PC1 and client PC2,
The URL of the shared server 12 is notified.

Using this URL, the client PC 1 and the client PC 2 connect to the shared server 12 as shown in FIG. As a result, as shown by the number 5, a shared message related to the position and movement of the shared 3D object is transmitted through the shared server 12, and the number 6 is transmitted.
As shown by, the transfer is performed, and a multi-user environment is realized.

For a detailed description of the above connection procedure, refer to JP-A-9-81781.

Next, the AO server 13 that manages universal objects, virtual object objects, and virtual life objects existing in the shared virtual space will be described. The AO server 13 exchanges data related to AO with the shared server 12 based on the VSAP. Also,
As shown in FIG. 7, the HDD 13a stores a growth parameter management table of the virtual life object.

The universal object is an AO that exists only once in the virtual space and covers the entire virtual space. Also, the universal object can monitor the login and logout of all users. A plurality of areas exist in the universal object. For example, in the battle area, virtual life objects can be made to fight each other (comparison of predetermined parameters set for the virtual life objects to determine a win or loss).

The virtual object is an object other than the virtual life object falling (placed) in the virtual space. When a virtual object object is picked up by a user, the virtual object object is managed as a property of the picked-up user.

As shown in FIG. 8, the data on the virtual life object in the growth parameter management table is roughly classified into virtual life data and owner data.

The virtual life data includes a 3D object ID for uniquely specifying a 3D object in one shared virtual space, three-dimensional coordinate values of the virtual life object in the shared virtual space, a monkey selected by the owner, The type of creature such as a cat, its gender, the nickname given by the owner, the date and time initialized by the owner, that is, the birthday of the virtual life object, the world name assigned to the virtual space where it was born (the real world name)
And the growth parameters of the virtual life object.

The growth parameters are roughly classified into physical parameters for defining the appearance growth of the virtual life object and mental parameters for defining the internal growth reflecting the character and the like.

Physical parameters are height (unit: cm),
It consists of body weight (unit: Kg), physique index, appetite index, health index, and remaining life time (unit time).

The mental parameters include an intelligence index, a language ability index, a social index, an independence index, an activity index, and a mood index.

These parameters include a timer event generated with the elapsed time from the date of birth initially set by the owner, an access event and an operation event generated with a call message and an operation message from the client PC. , Are sequentially updated to values calculated by a predetermined growth parameter calculation formula.

FIG. 9 shows the function of the action panel displayed adjacent to the main window of the VRML browser on the screen of the CRT monitor 45 of the client PC 1.

In this figure, A denoted by (Active) is a “call button”, which is clicked to call a virtual life object (hereinafter also referred to as a virtual pet) or to wake up a sleeping virtual pet. Is done.

[0131] B described as (Sleep) is a "sleeping button", which is clicked when the virtual pet is put to sleep.

C is a "meal button", which is clicked when a meal is given to the virtual pet.

D is a “praise button”, which is clicked when laughing and praising the virtual pet.

E is a “play button”, which is a button that is clicked when playing with a so-called tag game, in which the owner chases the virtual pet that runs away as an ogre and runs after chasing the virtual pet that collides with the wall and cannot escape. It is.

F is a "reward button", which is a button that is clicked when scolding a virtual pet that does not hear what to say and performing discipline.

G is a “clean button”, which is clicked when brushing and cleaning a virtual pet.

Then, as shown in FIG. 10, for example, the “call button” A is clicked on the client PC 1 (the action panel is operated), and the call message is transmitted via the shared server 12 to the AO server 1.
3 (step S1), a growth parameter updating process of the growth parameter management table is executed based on the access event (step S3). Based on this access event, the appetite index, health index, and mood index are incremented by 0.1 points from 1/10 to 10/10.

Further, for example, the “meal button” C is clicked, and the operation message is transmitted to the AO server 13 (step S2), and every time an operation event occurs, the weight of the growth parameter increases, and accordingly, Then, the physique index is incremented by 0.1 points from 1/10 to 10/10 (step S3).

Thereafter, when a timer event occurs with the lapse of time, the weight of the growth parameter decreases, and accordingly, the physique index is decremented by 0.1 point (step S3).

For example, every time the growth parameter including the physique index is updated, the other clients sharing the virtual space with the client PC1 of the original owner by the multicast processing (step S5) of the shared server 12. Transferred to PC2 (step S4).

On the client PC1, a growth script program describing a processing procedure for controlling an autonomous behavior accompanying the growth of the virtual pet is executed based on the returned growth parameters (step S6), and the VR is executed.
The value of the field of each node constituting the 3D object for expressing the virtual pet in the ML file is changed (step S7), and the virtual pet reflecting the changed field value is rendered (step S8).
It is displayed on the main window of the VRML browser on the screen of the CRT monitor 45 of the client PC 1.

The same processing as that of the client PC 1 is executed in the other client PCs 2 sharing the virtual space, whereby the virtual pet reflecting the field values changed with the growth of the virtual pet is rendered. Then, it is also displayed on the main window of the VRML browser on the CRT monitor screen of another client PC 2.

FIGS. 11 and 12 show the relationship between part0 to part5 corresponding to each node constituting the 3D object for expressing the virtual pet of the VRML file (FIG. 11) and a display example (FIG. 12). . part0 corresponds to the head of the virtual pet, part1 corresponds to the body of the virtual pet, and part2 and
part3 corresponds to the right and left arms of the virtual pet, and part4 and part
5 corresponds to the right and left feet of the virtual pet.

By changing the value of the field of each node corresponding to each of these parts 0 to 5, the appearance (shape, posture (direction), size, color, etc.) of each part of the virtual pet and the behavior sequence of each part are changed. Can be changed dynamically.
These are all realized by processing of a growth script program based on growth parameters. That is, it is realized by using the Behavior mechanism realized by the cooperative operation of the sensor, the routing, and the script defined in VRML2.0.

Therefore, unlike the conventional method of displaying the image of the virtual creature of the portable electronic pet, it is not necessary to previously store the bitmap image of each stage of the growth process of the character of the virtual creature in the ROM. The physique and behavior can be continuously and dynamically changed according to the progress of growth of the pet.

FIG. 13 is a conceptual diagram of dynamically changing and displaying the physique of the virtual pet in accordance with the growth of the virtual pet and the transition of the physique index. With aging, the face becomes an adult face and the physique increases, but if the physique index is small, the body becomes lean, and if it is large, the body becomes large.

FIG. 14 is a conceptual diagram of dynamically changing and displaying the expression of the virtual pet along with the transition of the mood index of the virtual pet. If the mood index is large, a laughing face will appear,
If you are small, you will get an angry face.

FIG. 15 is a conceptual diagram of dynamically changing and displaying the behavior sequence of each part of the virtual pet in accordance with the transition of the activity index of the virtual pet. When the activity index is small, only movement of the legs can be performed, but when it is large, the hand can shake or shake the head.

FIG. 16 is a conceptual diagram showing the display of the virtual pet with the addition of hair or glasses when the intelligence index of the virtual pet changes.

The intelligence index of the growth parameter is incremented by 0.1 point based on an access event associated with the operation of the “call button” A shown in FIG. 9, and affects the appearance of the virtual pet as shown in FIG.

The language index is represented by a “call button” A shown in FIG.
It is incremented by 0.1 point according to the age of the virtual pet based on the access event and timer event accompanying the operation of the operation of the virtual pet, and when executing the text-based chat text automatic generation processing according to the age increase of the virtual pet, the text is Affects the style. For example, a chat of a virtual pet with a small point is performed in hiragana or katakana, and a chat of a virtual pet with a large point is performed in characters including kanji.

The sociability index is incremented or decremented by 0.1 point according to the frequency of chatting with the owner, and the virtual pet is set so as to have an outward behavior when the frequency is high and an introvert behavior when the frequency is low. Affect the behavior of A virtual pet with a sociable, bright, positive character has a better posture and complexion, while a virtual pet with an introverted, darker, passive character has a worse posture and complexion.

The autonomy index is incremented by 0.1 points according to the age increase of the virtual pet based on the timer event, and affects the behavior of the virtual pet such that the owner gradually stops listening to what the owner says.

The activity index is determined based on the age, appetite index, health index, and the like, and affects the behavior of the virtual pet as shown in FIG. In addition, based on the occurrence of an operation event associated with the operation of the "play button" E shown in FIG. 9, the activity index is incremented by 0.1 point, thereby affecting the behavior of the virtual pet such that the escape foot becomes faster, The body weight of the virtual pet is reduced and the body mass index is decremented to dynamically change its appearance as shown in FIG.

The mood index is calculated using the “call button” A shown in FIG.
It is determined based on the access frequency based on the access event and the timer event associated with the operation of, and affects the expression of the virtual pet as shown in FIG.

On the other hand, the owner data in the growth parameter management table shown in FIG. 8 is composed of the owner's name, means of contacting the owner (contact method), and the contact information.

When the communication means is 0, the contact to the owner is
This is performed by a message sent by e-mail via the Internet 7. When the number of the communication means is 1, the communication server 16 converts the text data of the message into a voice using an automatic reading tool and notifies the telephone 18 of a normal analog voice. If the communication method is 2, PIAFS (PHS Internet Access Forum Standard)
The PHS terminal 23 is notified by a message using an e-mail service conforming to the data transmission method described above. If the communication means is 3, the facsimile 19 is notified in writing. If the communication method is 4, pager terminal 2
4 is notified by a message.

[0158] Such owner data is managed by:
This is for realizing a notification function to the owner using the existing communication infrastructure described later and a simple operation function for the virtual pet using the existing communication infrastructure.

The above system can be summarized as follows. That is, the growth parameter (appearance growth or internal growth (individuality)) of the virtual life object existing in the shared virtual space, which changes in response to the occurrence of a predetermined event (an event associated with a user operation or a lapse of time), is represented by AO. The client PCs 1, 2 are managed by the server 13 and based on the growth parameters transferred from the AO server 13.
Then, a script (program) for dynamically changing one or both of the appearance (shape, posture, size, or color) and behavior sequence of the virtual life object is interpreted, and the virtual life object corresponding to the growth parameter is interpreted. indicate.

The AO server 13, which manages the autonomous behavior of the virtual life object existing in the shared virtual space, changes the virtual life object in response to the occurrence of a predetermined event (an operation associated with a user operation or an elapse of time). A management table for managing growth parameters to be provided is provided, and a growth parameter read from the management table in response to a request from a client or occurrence of a predetermined event is returned to one or both of the request source and other clients. I do.

As described above, the growth parameter is a value indicating the appearance growth degree calculated based on the occurrence of a predetermined event (an event associated with a user operation or a lapse of time) from the birth of the virtual life object. is there. Therefore, for example, a change in the appearance of the virtual creature or the virtual pet (AO) according to the age from a toddler baby to a mature adult to an elderly person is defined by the appearance growth parameter.

The growth parameter is also a value indicating an internal growth degree (character) calculated based on the occurrence of a predetermined event (an event associated with a user operation or a lapse of time) with respect to the virtual life object. For example, a virtual life object with a sociable, bright and aggressive character has a better posture and complexion, while a virtual life object with an introverted, dark and passive character has a worse posture and complexion. Changes in living things and virtual pets (AO) are defined by internal growth parameters.

As the internal growth parameter, a different value is calculated according to the type of the event for the virtual life object, and the value of the internal growth degree is updated. When the personality of a virtual pet or the like is managed on the AO server 13 side, a predetermined index of a growth parameter is added by 0.1 point according to the type of a message transmitted from each client, for example, every time a user speaks in a chat. Each time the "praise button" D is pressed and praised, 0.2 points are added, and each time the "pick button" F is pressed and scolded,
It is calculated based on a predetermined addition / subtraction surplus growth formula such as subtraction of 0.2 points.

The AO server 13 that manages the autonomous behavior of the virtual life object in the shared virtual space is provided with a growth parameter management table indicating the growth degree of each virtual life object, and holds the birthday of each virtual life object. Based on the elapsed time from this point, a growth parameter corresponding to the age of each virtual life object is calculated, and the management table is updated.

AO for independently managing the autonomous behavior of a plurality of virtual life objects in a shared virtual space
A server 13 (a single AO server 13 may manage a plurality of growth parameter management tables, or a plurality of AO servers 13 and 14 may each manage the growth parameter management table) is provided, and indicates a growth degree of each virtual life object. By separately providing the growth parameter management tables, the growth parameters of each virtual life object can be managed independently.

In addition, various application examples can be considered.

For example, the AO server 13 for managing the autonomous behavior of the virtual life object in the shared virtual space
In addition, such management items may be added to the management table (growth management table) for managing the ID of the client that has accessed each virtual life object (such as the nickname of the virtual life object set by the user). A management table may be used. The same applies hereinafter), and an event indicating an intimate emotional expression may be activated in response to an access from a client having this ID. As described above, by maintaining the intimacy (the number of accesses and the contents thereof) on the AO server 13 side, the pet (virtual life) object approaching by the owner when entering the world (shared virtual space) can be saved. Can be realized.

The ID of the client that has set or reset the virtual life object is stored in the growth parameter management table as the owner of the virtual life object, and the ID is maintained until the life of the virtual life object expires.
May not be updated, and the ID may be erased at the end of the life. As a result, it is possible to realize a sincere pet that is loyal to the owner who created (sets) the virtual life object. Further, at the time when the life has expired (reset), a child of the virtual life object may be automatically born, and the child may be initialized with the same owner ID. As a result, the offspring of the virtual pet also become attached to the ancestor's owner.

A history management table for managing the history of the client that has set or reset the virtual life object is provided in the AO server 13.
A behavior sequence indicating a more intimate emotional expression can be activated. Conversely, if the access frequency is low, the intimacy level is weakened, and an afflicted pet whose intimacy level changes with the access frequency is realized.

If the movement of the virtual life object is controlled in accordance with the position of the client in the shared virtual space, when the client (owner) enters the shared virtual space, the virtual life object is immediately in front of him. Appears in
A virtual life object around the owner can be realized.

While the client is not accessing the shared virtual space, the virtual life object is periodically made to appear in the shared virtual space and prowl, and the event at that time (for example, when a meal is given by another client). By causing the virtual life object to report the experience, experience of picking up the virtual object, to the client through a text-based chat window, it is possible to express an intimate emotional expression.

An intimate emotional expression may be performed by reporting an event in the shared virtual space from the virtual life object to the client via voice chat. An analog voice message may be notified via a voice chat function by text / voice conversion by text-to-speech software, or several types of voice messages may be sampled and compressed in advance and compressed as digital voice compressed data into an HDD (AO server). 13 or the client PC 1), an appropriate voice message is selectively read out of the HDD from a plurality of voice messages, expanded, and then analog voice is transmitted via the voice chat function. You may make it notify as a message. For such conversion between text and voice, for example, a technique disclosed in Japanese Patent Application Laid-Open No. 7-105848 can be used.

Next, a notification function to the owner using the existing communication infrastructure and a simple operation function for the virtual pet using the existing communication infrastructure will be described.

For example, when the appetite index of the virtual life object increases or when the remaining life time falls below a predetermined value, the virtual life object (AO server 13) is set in the growth parameter management table in advance. Using the communication means (FIG. 8), the owner is notified of the change in the status via the mail server 15 or the communication server 16. As a result, the owner can confirm the request for the virtual pet that he / she is raising and communicate with him / her even if the owner cannot go to the personal computer immediately, such as when he is outdoors or the personal computer does not work well. Can be achieved.

On the other hand, for a service provider who profits by providing this kind of service for breeding virtual pets, a kind of motivation that the user must access the service provider can be encouraged. As a result, by securing regular access, it is possible to obtain a secondary effect that a more sound business condition can be maintained.

A specific example for realizing the function of notifying the owner using the existing communication infrastructure is as follows.

Among the servers that manage the autonomous behavior of the virtual life objects in the shared virtual space, the communication server 16 sends message notification means (notification method) to each user who is the owner of each virtual life object.
A communication management table (table corresponding to the owner data in the growth parameter management table in FIG. 8) for managing the type of the notification and the notification destination thereof is provided, and the state transition of the virtual life object (from the AO server 13 to the communication server 16 is notified). The message is transmitted to the notification destination using the notification means registered in the communication management table in advance. Thereby, the real world is actually contacted from the shared virtual world.

In this communication management table,
An ID for identifying each user who is the owner of each virtual life object and an access history from the user of the ID are managed, and based on the access history from each user,
For users who have not accessed for a certain period of time, for example,
"I'm not coming to see me recently, so I'm sorry ...."
And so on.

Furthermore, an appropriate message may be selected from a plurality of message examples based on the access history from each user, and the selected message may be transmitted. On the day after the user's access, the virtual life object sends the user a message such as "Thank you for playing yesterday. Let's play again." Occasionally, please come and play. "

A state transition of the virtual life object is detected based on the updated contents of the growth parameter management table,
An appropriate message text can be selected from a plurality of message text examples, and the selected message can be transmitted. For example, the day after a lot of meals,
My stomach is full ~ "
If there is no access for a week, a message such as "You are about to die because you are hungry." Assuming a scenario of one year old in one week, every week, when my birthday comes and I get older, "I'm 10 years old today. Please come and see my grown up." When the life span is running short, send a message such as "I have to travel to a distant place soon, come to see the end."

In the communication management table,
The mail server 15 stores the table relating to the electronic mail.
In the communication management table of the mail server 15, a text message can be transmitted to the e-mail address (also serving as an ID for identifying the user) of each user who is the owner of each virtual life object.

In addition to the e-mail via the Internet 7, a PHS terminal 23 which can receive an e-mail service with a PHS (PHS Internet Access Forum Standard) system or a PHS compatible with the αDATA32 system, a pager (pager terminal 2)
4) For example, a message may be notified from the communication server 16 via the public telephone network 17 and the message may be displayed on the LCD.

Alternatively, in the communication management table, the notification destination telephone number (also serving as an ID for specifying the user) of each user who is the owner of each virtual life object is managed, and the communication server 16 automatically transmits the telephone number to this telephone number. Then, a voice message can be transmitted. In this case, a normal telephone 8 or a mobile telephone (PHS terminal 23) is converted into an analog voice message by text / voice conversion by text-to-speech software
May be notified via a voice message.Also, some types of voice messages are sampled in advance, compressed and stored as digital voice compressed data in the HDD, and an appropriate voice message is selected from a plurality of voice messages. After selectively reading from the HDD and decompressing, it may be notified as an analog voice message.

In the communication management table, the notification facsimile telephone number of each user who is the owner of each virtual life object (also serves as an ID for specifying the user)
And the communication server 16 may automatically send a call to this telephone number to send a message to the facsimile 19.

Further, by using a terminal such as the telephone 18 which has received the notification of the message from the virtual pet, a simple operation is performed on the user's own virtual pet from this terminal, so that bidirectional communication is possible. Communication becomes possible.

A specific example for realizing a simple operation function for a virtual pet using an existing communication infrastructure is as follows.

For example, the shared server 12 sends a PH
Interpret the operation command returned with an ID for specifying the user (such as CallerID) via the S terminal 23, the telephone 18, or the like, recognize the message as a message to the corresponding virtual life object, and notify the AO server 13. And state transition of virtual life objects (update of growth parameters)
Can be reflected to

As the returned operation command, for example, a DTMF (Dual-tone Multifrequency) signal transmitted by operating a push button of the telephone 18 can be used.

In addition, various notifications can be given to the virtual pet by using, for example, a voice browser Web-On-Call of Dennet Phonic Communications. According to this voice browser, the server can be accessed by voice from the ordinary telephone 18. In addition, since this voice browser has a text-to-speech function, it is possible to listen to a mail from a virtual pet by voice. In addition, text can be sent by fax or e-mail.

The shared server 12, AO server 13,
The mail server 15, the communication server 16, and the communication server 16 share various functions and realize a service of providing a shared virtual space to each client PC as an overall system.

Next, a chat in the shared virtual space will be described. There are public chats and personal chats. In the public chat, the content of the chat generated by one client (user) located at a predetermined position in the shared virtual space is:
Propagated to other clients nearby (other users) or to all clients in the shared virtual space (all users).

On the other hand, in the personal chat, a target partner is specified. This designation operation is performed, for example, by clicking a mouse button while pressing the shift key of the keyboard 42 on a predetermined virtual life object. As described above, when the other party is specified, the chat generated by the client that has performed the click operation is transmitted only to the user of the specified virtual life object.

The content of the chat is transmitted by a voice signal in the case of a voice chat, and transmitted by text in the case of a text chat. In the case of voice chat, voice data captured via the microphone 36 is transmitted to a client (user) of a nearby or designated virtual life object, and output from speakers 37 and 38 of the client PC.

On the other hand, in the case of a text chat, the text input by operating the keyboard 42 is transmitted to the client PC of the client of the nearby or designated virtual life object. Then, the text is displayed on the CRT monitor 45 of the client PC.

The user can select whether to perform a voice chat or a text chat.

Next, a specific display example displayed on the CRT monitor of the client PC will be described. FIG.
For example, a bird's-eye view display example of a three-dimensional shared virtual space provided when the client PC 1 accesses the shared server 12 is shown. FIG. 18 illustrates a display example of an image in which a part of the three-dimensional shared virtual space is viewed from above the side surface.

When the client selects a virtual pet to be bred in such a shared virtual space, the client clicks the item “MultiUser” on the display screen. At this time, a menu bar is displayed as shown in FIG. The client selects "Select Pe
Select "t". Then, as shown in FIG.
The window of “et” is displayed, and images of various virtual pets are displayed in this window. The client selects a desired virtual pet from the virtual pets. The image of the virtual pet displayed at this time is an image in an initial state, that is, an image at the time of birth. As described above, the image of the virtual pet gradually changes with growth. Then, when the selection is completed, the client operates the mouse 41 to turn on the “SELECT” button.

When the selection of the virtual pet is completed in this way, a “Registration” window for registering information about the virtual pet is displayed as shown in FIG. The client now enters the virtual pet name "Pet
nickname ", the name of the owner (owner)" Owner nam
e "and the address and phone number" Address / TelephoneN
o. "by operating the keyboard 42.

Further, the communication tool “Communication to
ol ”for E-mail, Telephone, PHS-mail, Facsimile, Po
Select and specify from cketbell.

FIG. 22 shows a display example when a monkey is selected as a virtual pet in this way. As described above, this virtual pet (monkey) grows based on the growth parameters updated in response to various events. FIG. 23 shows a state of growth from the case shown in FIG. In the case shown in FIG. 23, the body is larger as a whole and the face has changed to an adult face in the case shown in FIG.

Next, the battle between virtual pets in the battle area provided in the shared virtual space will be described with reference to FIG.
This will be described with reference to the flowchart of FIG. In addition, winning or losing in the battle area is determined by so-called “Janken”.

In step S11, the client A
By the operation ₁ , the breeding virtual pet A ₂ enters the battle area. This battle area is a predetermined area predetermined by the shared server 12 in the shared virtual space.

[0203] In step S12, whether the battle area virtual pet B ₂ other than the virtual pet A ₂ is present is determined if the virtual pet is determined that there is no other than the virtual pet A _2, another virtual Wait for pets to enter. If the virtual pet B ₂ other than the virtual pet A ₂ is determined to exist, processing proceeds to step S13.

In step S13, the virtual pets A ₂ and B ₂ and the referee C are displayed on the ring D as shown in the main window MW of FIG. A battle panel BP that displays battle buttons is superimposed on the main window MW. Here, the battle button will be described. "Goo" button BPB ₁ of the battle button,
Click this button to make the virtual pet "goo" when clicked. Battle button “Choke” button BP
B ₂ is a button for Dasa a "scissors" to the virtual pet by clicking. Battle button "par"
Button BPB ₃ is a button to Dasa a "par" in the virtual pet by clicking.

At step S14, the client A
₁ , select any battle button and click. On the other hand, the client B ₁ similarly selects the Janken's hand to be put out to the virtual pet B ₂ . Client B ₁ ,
Data corresponding to the battle button selected by B ₂ is transmitted from each client PC to the shared server 12.

At step S15, shared server 12
Accordingly, the outcome of the virtual pet A ₂ is determined on the basis of the battle button selected at step S14. Note that FIG.
6 shows a display example of the main window MW during the win / loss determination.

In step S16, shared server 12
Outputs the determination result to the AO server 13 and each client PC. The AO server 13 controls each client PC so that each virtual pet takes a pose corresponding to the determination result.
Output data to Thereby, each client PC
In the main window, a predetermined pose corresponding to the result of the win / loss determination (for example, a guts pose with the forefoot raised when the battle is won, and a pose with the head down if the battle is lost) is taken. The virtual pets A ₂ and B ₂ are displayed.

In the present embodiment, the so-called “Janken” is used as the battle in the battle area. For example, by comparing the growth parameters set in the virtual pet using a predetermined standard, Win / loss may be determined.

[0209] In addition, a ranking table of the virtual pet may be displayed by adding an item indicating a result of determining a win or loss (for example, a streak record) to the parameters set for the virtual pet.

Further, a prize (for example, coins in a shared virtual space) may be given to the owner of the virtual pet who is the winner.

[0211] The program for executing the above various processes is provided by recording it on a magnetic disk, a CD-ROM disk, or another recording medium, or by transmitting it via the Internet or another network. be able to.

[0212]

As described above, according to the information processing apparatus according to the first aspect, the information processing method according to the third aspect, and the providing medium according to the fourth aspect, the user breeds in the shared virtual space. For transmitting a command in a predetermined event performed in a predetermined area existing in a shared virtual space to a virtual life object to be executed, and controlling the behavior of the virtual life object corresponding to the result of the predetermined event transmitted from the server And control the display of the virtual life object based on the script.

According to the information processing apparatus of claim 5, the information processing method of claim 6, and the providing medium of claim 7, the virtual life object bred by the user in the shared virtual space is The result of the predetermined event to be performed is determined based on the information transmitted from the client device, and a script for controlling the display of the behavior of the virtual life object is transmitted to the client device in accordance with the determination result. Therefore, it becomes possible to make virtual life objects compete with each other in the shared virtual space.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating the relationship among sensors, events, routing, and scripts.

FIG. 2 is a diagram illustrating routing.

FIG. 3 is a block diagram illustrating a configuration example of a shared virtual space providing system to which the present invention has been applied.

FIG. 4 is a block diagram showing a configuration example of a client PC 1 of FIG.

FIG. 5 is a photograph of a halftone image displayed on a display for explaining the operation of the system of FIG. 3;

6 is a photograph of a halftone image displayed on a display for explaining the operation of the system of FIG. 3;

FIG. 7 is a photograph of a halftone image displayed on a display for explaining the operation of the system of FIG. 3;

FIG. 8 is a diagram showing an example of a growth parameter management table.

FIG. 9 is a photograph of a halftone image displayed on a display explaining an action panel.

FIG. 10 is a diagram for explaining exchange of growth parameters.

FIG. 11 is a diagram illustrating nodes of a virtual life object constituting a 3D object.

12 is a photograph of a halftone image displayed on a display showing a display example corresponding to the node shown in FIG. 11;

FIG. 13 is a diagram illustrating a physique index of a virtual life object.

FIG. 14 is a diagram illustrating a mood index of a virtual life object.

FIG. 15 is a diagram illustrating an activity index of a virtual life object.

FIG. 16 is a diagram illustrating an intelligence index of a virtual life object.

FIG. 17 is a photograph of a halftone image displaying a shared virtual space on a display.

FIG. 18 is a photograph of a halftone image displaying a shared virtual space on a display.

FIG. 19 is a photograph of a halftone image displaying a shared virtual space on a display.

FIG. 20 is a photograph of a halftone image displaying a shared virtual space on a display.

FIG. 21 is a photograph of a halftone image displaying a shared virtual space on a display.

FIG. 22 is a photograph of a halftone image displaying a shared virtual space on a display.

FIG. 23 is a photograph of a halftone image displaying a shared virtual space on a display.

FIG. 24 is a flowchart illustrating a battle process in a battle area.

FIG. 25 is a photograph of a halftone image in which a battle area is displayed on a display.

FIG. 26 is a photograph of a halftone image in which a battle area is displayed on a display.

[Explanation of symbols]

1-3 client PC, 7 Internet,
10 WWW server, 12 shared server, 13, 14
AO server, 15 mail server, 16 communication server, 18 telephone, 19 facsimile, 23 PHS terminal, 24 pager terminal, 30 CPU, 31 hard disk, 39
Modem, 45 CRT monitor, 46 RAM

Claims (7)

[Claims] 1. An information processing apparatus connected to a server via a network together with another information processing apparatus and provided with a shared virtual space, wherein the shared virtual object for a virtual life object raised by the user in the shared virtual space is provided. Transmitting means for transmitting a command in a predetermined event performed in a predetermined area existing in a space; and receiving a script transmitted from the server for controlling a behavior of the virtual life object corresponding to a result of the predetermined event. An information processing apparatus comprising: a receiving unit that performs display; and a display control unit that controls display of the virtual life object based on the script. 2. The information processing apparatus according to claim 1, wherein the predetermined area is a battle area, and the predetermined event is Janken. 3. An information processing method for an information processing apparatus connected to a server via a network together with another information processing apparatus and provided with a shared virtual space, comprising: Transmitting a command for a predetermined event performed in a predetermined area existing in the shared virtual space; and controlling a behavior of the virtual life object corresponding to a result of the predetermined event, transmitted from the server. An information processing method, comprising: a receiving step of receiving a script to be executed; and a display control step of controlling display of the virtual life object based on the script. 4. A providing medium connected to a server via a network together with another information processing apparatus and providing a computer program used for an information processing apparatus to be provided with a shared virtual space, wherein: A transmitting step of transmitting a command in a predetermined event performed in a predetermined area existing in the shared virtual space for the virtual life object to be bred in, and transmitting the command corresponding to a result of the predetermined event transmitted from the server. A providing medium, comprising: a receiving medium for receiving a script for controlling a behavior of a virtual life object; and a display control step for controlling display of the virtual life object based on the script. 5. An information processing apparatus for providing a shared virtual space to a plurality of client devices connected via a network, wherein a result of a predetermined event performed by a virtual life object raised by the user in the shared virtual space is provided. Determining means for determining based on information transmitted from the client device; and transmitting means for transmitting to the client device a script for controlling display of behavior of the virtual life object in accordance with the determination result determined by the determining means. An information processing apparatus comprising: 6. An information processing method for an information processing apparatus for providing a shared virtual space to a plurality of client devices connected via a network, wherein a predetermined event performed by a virtual life object bred by the user in the shared virtual space A determination step of determining a result of the virtual life object based on information transmitted from the client device; and transmitting a script for controlling display of behavior of the virtual life object to the client device in accordance with the determination result determined in the determination step. And an information transmission method. 7. A providing medium for providing a computer program used for an information processing apparatus for providing a shared virtual space to a plurality of client devices connected via a network, wherein a virtual medium which a user breeds in the shared virtual space is provided. A determining step of determining a result of a predetermined event performed by the life object based on information transmitted from the client device; and controlling a display of behavior of the virtual life object in accordance with the determination result determined in the determination step. Providing a computer program comprising: transmitting a script to the client device.