JP2014136141A - Robot game system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a robot game system which can enhance interest as a game.SOLUTION: A robot game system includes: a plurality of game robots; a personal computer for outputting control signals to the game robots; operation controllers which are provided corresponding to the plurality of game robots and output control signals to the game robots via the personal computer or directly; a control program table which is provided in the personal computer and stores in advance a control program for controlling the plurality of game robots; and a card reader which is connected to the personal computer and reads information from a card that stores information for identifying an arbitrary control program inside the control program stored in the control program table in advance.

Description

  The present invention relates to a robot game system, and in particular, in a configuration in which a plurality of game robots are controlled by a personal computer or a controller, when a game operator selects a card and sets it in a card reader. The present invention relates to a device devised so that an arbitrary control program can be selected from control programs stored in advance, thereby increasing the fun of the game.

  An example of a conventional robot game system is described in Patent Document 1. In this case, first, there is a host computer, and two player computers are connected to the host computer. These player computers store a battle program in advance. Also, an external camera is installed, and image data captured by the external camera is sent to the two player computers via the host computer. Then, the two player computers determine the control contents based on the input imaging data and the battle program, and output a control signal to each self-propelled robot via the host computer.

JP 2008-71022 A

The conventional configuration has the following problems.
That is, in the case of the robot game system described in Patent Document 1, as described above, the self-propelled robot is automatically controlled by a battle program created in advance. However, the creation of the battle program is not easy, and only a limited number of people can create it. As a result, there is a problem that the number of people who can enjoy the robot game is limited. In response to this, it is conceivable that manual operation of the self-propelled robot can be performed, and even a person who cannot create a battle program can participate in the game.
However, in the case of the robot game system described in Patent Document 1, a configuration that enables such manual operation is not provided. It is also conceivable to add a controller that can be operated manually. In that case, a control signal is directly output from the controller to the self-propelled robot. There was a problem that it would be difficult to manage.

  Therefore, the present patent applicant has newly applied for a patent (Japanese Patent Application No. 2012-173383, unpublished).

The conventional configuration has the following problems.
That is, in the case of the soccer game robot described in the newly filed patent application (Japanese Patent Application No. 2012-173383, unpublished), the keeper robot is controlled fully automatically by the autonomous program. At that time, the operation of the keeper robot is monotonous and not necessarily timely, and there is a problem that the fun of the game is reduced.

  The present invention has been made based on such points, and an object thereof is to provide a robot game system capable of increasing the fun of the game.

In order to solve the above problems, a robot game system according to claim 1 is provided corresponding to a plurality of game robots, a personal computer that outputs a control signal to the game robots, and the plurality of game robots. An operation controller that outputs a control signal to the game robot via a computer or directly, a control program table that is provided in the personal computer and stores in advance a control program for controlling the plurality of game robots, A card reader that reads information from a card that is connected to a personal computer and stores information for specifying an arbitrary control program among control programs stored in advance in the control program table. With what That.
A robot game system according to claim 2 is the robot game system according to claim 1, wherein the control program table is operated by an autonomous program for controlling the game robot in a fully automatic manner and a control signal from the operation controller. An operation program for controlling the game robot is stored in advance, and the card has two types: a card for specifying the autonomous program and a card for specifying the operation program It is.
The robot game system according to claim 3 is the robot game system according to claim 2, wherein the operation controller is provided with a switch for operating the operation program.
The robot game system according to claim 4 is the robot game system according to claim 3, wherein control based on the operation program is executed only when the switch is operated, and control by the autonomous program is performed at other times. It is characterized by being configured.
A robot game system according to a fifth aspect is the robot game system according to any one of the first to fourth aspects, wherein the card reader reads information on a card by an image processing method, a magnetic method, and an optical method. It is what reads.
The robot game system according to claim 6 is the robot game system according to any one of claims 1 to 5, wherein the control program table includes an area for storing a control program created by a user. It is characterized by that.
The robot game system according to claim 7 is the robot game system according to claim 6, wherein the control program created by the user includes an autonomous program for controlling the game robot fully automatically and a control from the operation controller. There are two types of operation programs that operate by signals to control the game robot.
The robot game system according to claim 8 is the robot game system according to claim 6 or 7, wherein the personal computer is connected to a user control program input means for inputting a control program created by the user. It is characterized by that.
The robot game system according to claim 9 is the robot game system according to any one of claims 1 to 8, wherein the game robot is a battle game robot belonging to a different team. Is.

As described above, the robot game system according to claim 1 is provided so as to correspond to a plurality of game robots, a personal computer that outputs a control signal to the game robot, and the plurality of game robots. An operation controller that outputs a control signal to the game robot via the personal computer or directly, and a control program table that is provided in the personal computer and stores in advance a control program for controlling the plurality of game robots. A card reader that reads information from a card that is connected to the personal computer and stores information for specifying an arbitrary control program among control programs stored in advance in the control program table Because it is It is possible to control the competitive game robots using any control program in the control program table by to read the information of the card, thereby enhancing the game play or game.
According to the robot game system of claim 2, in the robot game system of claim 1, the control program table is operated by an autonomous program for controlling the game robot in a fully automatic manner and a control signal from the operation controller. Since the operation program for controlling the game robot is stored in advance, there are two types of cards: a card for specifying the autonomous program and a card for specifying the operation program. Can be operated by an autonomous program or an operation program, and any of the above-mentioned autonomous programs and the above-mentioned operation programs can be selected, thereby further enhancing the playability of the game.
According to the robot game system of claim 3, in the robot game system of claim 2, the operation controller is provided with a switch for operating the operation program. The above-mentioned operation program can be operated at the timing, thereby further enhancing the playability of the game.
The robot game system according to claim 4 is the robot game system according to claim 3, wherein control based on the operation program is executed only when the switch is operated, and control by the autonomous program is performed at other times. Therefore, it is easy to switch between the control by the autonomous program and the control by the operation program, and the playability of the game can be enhanced.
A robot game system according to a fifth aspect is the robot game system according to any one of the first to fourth aspects, wherein the card reader reads information on a card by an image processing method, a magnetic method, and an optical method. Since it is configured to read, a desired card reader can be provided with a relatively simple configuration.
The robot game system according to claim 6 is the robot game system according to any one of claims 1 to 5, wherein the control program table includes an area for storing a control program created by a user. Therefore, since the user can create and use another control program separately from the original control program, the playability of the game can also be improved.
The robot game system according to claim 7 is the robot game system according to claim 6, wherein the control program created by the user includes an autonomous program for controlling the game robot fully automatically and a control from the operation controller. Since there are two types of operation programs that operate according to signals to control the game robot, it is possible to improve the playability of the game.
The robot game system according to claim 8 is the robot game system according to claim 6 or 7, wherein the personal computer is connected to a user control program input means for inputting a control program created by the user. Therefore, it becomes easy to input a control program created by the user himself / herself.
The robot game system according to claim 9 is the robot game system according to any one of claims 1 to 8, wherein the game robot is a battle game robot belonging to a different team. Even in a battle type robot game system, the playability can be improved.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows one Embodiment of this invention, and is a schematic diagram which shows typically the structure of the whole robot game system by this Embodiment. FIG. 2A is a diagram illustrating an embodiment of the present invention, FIG. 2A is a diagram illustrating a surface of an autonomous program selection card used in the robot game system according to the present embodiment, and FIG. 2B is a robot according to the present embodiment. It is a figure which shows the back surface of the autonomous program selection card used for a game system. FIG. 3A is a diagram illustrating an embodiment of the present invention, FIG. 3A is a diagram illustrating the surface of an autonomous program selection card used in the robot game system according to the present embodiment, and FIG. 3B is a robot according to the present embodiment. It is a figure which shows the back surface of the autonomous program selection card used for a game system. FIG. 4A is a diagram illustrating an embodiment of the present invention, FIG. 4A is a diagram illustrating the surface of an autonomous program selection card used in the robot game system according to the present embodiment, and FIG. 4B is a robot according to the present embodiment. It is a figure which shows the back surface of the autonomous program selection card used for a game system. FIG. 5A is a diagram illustrating an embodiment of the present invention, FIG. 5A is a diagram illustrating a surface of an operation program selection card used in the robot game system according to the present embodiment, and FIG. 5B is a robot according to the present embodiment. It is a figure which shows the back surface of the operation program selection card | curd used for a game system. FIG. 6A is a diagram illustrating an embodiment of the present invention, FIG. 6A is a diagram illustrating the surface of an operation program selection card used in the robot game system according to the present embodiment, and FIG. 6B is a robot according to the present embodiment. It is a figure which shows the back surface of the operation program selection card | curd used for a game system. FIG. 7A is a diagram illustrating an embodiment of the present invention, FIG. 7A is a diagram illustrating a surface of an operation program selection card used in the robot game system according to the present embodiment, and FIG. 7B is a robot according to the present embodiment. It is a figure which shows the back surface of the operation program selection card | curd used for a game system. FIG. 8A is a diagram illustrating an embodiment of the present invention, FIG. 8A is a diagram illustrating a surface of an operation program selection card used in the robot game system according to the present embodiment, and FIG. 8B is a robot according to the present embodiment. It is a figure which shows the back surface of the operation program selection card | curd used for a game system. FIG. 9A is a diagram illustrating an embodiment of the present invention, FIG. 9A is a diagram illustrating a surface of an operation program selection card used in the robot game system according to the present embodiment, and FIG. 9B is a robot according to the present embodiment. It is a figure which shows the back surface of the operation program selection card | curd used for a game system. FIG. 10A is a diagram illustrating an embodiment of the present invention, FIG. 10A is a diagram illustrating a surface of an operation program selection card used in the robot game system according to the present embodiment, and FIG. 10B is a robot according to the present embodiment. It is a figure which shows the back surface of the operation program selection card | curd used for a game system. It is a figure which shows one Embodiment of this invention, and is the perspective view which looked at the striker robot used for the robot game system by this Embodiment from the front. It is a figure which shows one Embodiment of this invention, and is the perspective view which looked at the striker robot used for the robot game system by this Embodiment from back. It is a figure which shows one Embodiment of this invention, and is a bottom view of the striker robot used for the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a disassembled perspective view of the striker robot used for the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is the perspective view which looked at the robot main body of the striker robot used for the robot game system by this Embodiment from the front. It is a figure which shows one Embodiment of this invention, and is the perspective view which looked at the robot main body of the striker robot used for the robot game system by this Embodiment from back. It is a figure which shows one Embodiment of this invention, and is a bottom view of the robot main body of the striker robot used for the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a disassembled perspective view of the robot main body of the striker robot used for the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is an exploded perspective view which shows the attachment part of the apparatus assembly plate with respect to the gear box of the striker robot used for the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a front view which shows the state which attached the apparatus assembly plate to the gear box connected with one wheel of the striker robot used for the robot game system by this Embodiment. FIG. 21A is a cross-sectional view taken along the line XXI-XXI in FIG. 20, and FIG. 21B is an enlarged view of the XXIb portion in FIG. It is a figure which shows one embodiment of this invention, and is XXII-XXII sectional drawing in Fig.21 (a). FIG. 16 is a diagram showing an embodiment of the present invention, and is a side view of the robot body shown in FIG. It is a figure which shows one embodiment of this invention, and is XXIV-XXIV sectional drawing in FIG. It is a figure which shows one embodiment of this invention, and is XXV-XXV sectional drawing in FIG. It is a figure which shows one Embodiment of this invention, and is a perspective view of the apparatus assembly plate of the staggered arrangement type used for the robot of the robot game system by this Embodiment. FIG. 27A is a diagram showing an embodiment of the present invention, FIG. 27A is a plan view of a staggered arrangement type apparatus assembly plate used in the robot of the robot game system according to the present embodiment, and FIG. 27B is FIG. It is XXVIIb-XXVIIb sectional drawing in (a). It is a figure which shows one Embodiment of this invention, and is a perspective view of the apparatus assembly plate of the striped arrangement type used for the robot of the robot game system by this Embodiment. FIG. 29A is a diagram showing an embodiment of the present invention, FIG. 29A is a plan view of a striped arrangement type device assembly plate used for the robot of the robot game system according to the present embodiment, and FIG. 29B is a diagram. It is XXIXb-XXIXb sectional drawing in 29 (a). It is a figure which shows one Embodiment of this invention, and is an exploded perspective view which shows the attachment part of the exterior material of the striker robot used for the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a side view which shows the state which attached a part of exterior material of the striker robot used for the robot game system by this Embodiment. FIGS. 32A and 32B are views showing an embodiment of the present invention, in which FIG. 32A is a cross-sectional view along XXXIIa-XXXIIa in FIG. 31, and FIG. 32B is an enlarged view of a portion XXXIIb in FIG. It is a figure which shows one Embodiment of this invention, and is a perspective view of the state which removed a part of exterior material of the striker robot used for the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a disassembled perspective view which shows the ball | bowl holding | maintenance / kick mechanism of the striker robot used for the robot game system by this Embodiment. FIG. 35A is a diagram showing an embodiment of the present invention, FIG. 35A is a perspective view of a cam used for a ball holding / kick mechanism of a striker robot used in the robot game system according to the present embodiment, and FIG. The rear view of the cam used for the ball holding / kick mechanism of the striker robot used in the robot game system according to the present embodiment, FIG. 35 (c) is the ball holding / kick mechanism of the striker robot used in the robot game system according to the present embodiment. It is a side view of the cam used for. FIG. 36 (a) is a cross-sectional view of the striker robot used in the robot game system according to the present embodiment as viewed from the rear side of the cam, showing the ball holding / kick mechanism. The figure which shows a standby state, FIG.36 (b) is XXXVIb-XXXVIb sectional drawing in Fig.36 (a). FIG. 37 (a) is a diagram showing an embodiment of the present invention, and FIG. 37 (a) is a cross-sectional view of the striker robot used in the robot game system according to the present embodiment as viewed from the rear side of the cam. The figure which shows a ball | bowl holding | maintenance state, FIG.37 (b) is XXXVIIb-XXXVIIb sectional drawing in Fig.37 (a). FIG. 38 (a) is a cross-sectional view of the striker robot used in the robot game system according to the present embodiment as viewed from the rear side of the cam, and shows the ball holding / kick mechanism. The figure which shows a kick state, FIG.38 (b) is XXXVIIIb-XXXVIIIb sectional drawing in Fig.38 (a). BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows one Embodiment of this invention, and is the perspective view which looked at the keeper robot used for the robot game system by this Embodiment from the front. It is a figure which shows one Embodiment of this invention, and is the perspective view which looked at the keeper robot used for the robot game system by this Embodiment from back. It is a figure which shows one Embodiment of this invention, and is a bottom view of the keeper robot used for the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a disassembled perspective view of the keeper robot used for the robot game system by this Embodiment. 43A and 43B are diagrams showing an embodiment of the present invention, in which FIG. 43A shows a marker of a keeper robot of team A, FIG. 43B shows a marker of one striker robot of team A, and FIG. (C) is a diagram showing the marker of the other striker robot of Team A, FIG. 43 (d) is a diagram showing the marker of the keeper robot of Team B, and FIG. 43 (e) is the marker of one of the striker robots of Team B. FIG. 43 (f) is a diagram showing a marker of the other striker robot of team B. It is a figure which shows one Embodiment of this invention, and is the perspective view which looked at the controller for players used for the robot game system by this Embodiment from the front. It is a figure which shows one Embodiment of this invention, and is a front view of the controller for players used for the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a left view of the controller for players used for the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a functional block diagram of the personal computer used for the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a figure which shows the content of the image process part parameter storage part of the fixed data storage part of the personal computer in the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a figure which shows the content of the program table of the fixed data storage part of the personal computer in the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a functional block diagram of the player side controller used for the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a functional block diagram of the striker robot used for the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a figure which shows the transmission data transmitted to the striker robot from the personal computer used for the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a functional block diagram of the keeper robot used for the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a figure which shows the transmission data transmitted to a keeper robot from the personal computer used for the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a flowchart of the main process in the personal computer of the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a flowchart of the card | curd process in the personal computer of the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a flowchart of the image processing in the personal computer of the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a flowchart of the marker detection process in the personal computer of the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a flowchart of the robot control data generation process based on the autonomous program / operation program of the striker robot or keeper robot in the personal computer of the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a flowchart of the referee process in the personal computer of the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a flowchart of the action button process in the personal computer of the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is the top view which showed typically the field used by the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a flowchart of the communication process for robots in the player side controller of the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a flowchart of the communication process for personal computers in the player side controller of the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a flowchart of the main process in the striker robot and keeper robot of the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a flowchart of the initialization process in the striker robot and keeper robot of the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a flowchart of the reception interruption process in the striker robot and keeper robot of the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a flowchart of the transmission interruption process in the striker robot and keeper robot of the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a flowchart of the timer interruption process in the striker robot and keeper robot of the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a flowchart of the reception data determination process of the timer interruption process in the striker robot and keeper robot of the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a flowchart of the power supply voltage monitoring process of the timer interruption process in the striker robot and keeper robot of the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a flowchart of the motor drive process of the timer interruption process in the striker robot and keeper robot of the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a flowchart of the LED process of the timer interruption process in the striker robot and keeper robot of the robot game system by this Embodiment. It is a figure which shows one Embodiment of this invention, and is a flowchart of the cam drive unit automatic alignment process in the striker robot of the robot game system by this Embodiment.

Hereinafter, an embodiment of the present invention will be described with reference to FIGS. This embodiment shows an example in which the present invention is applied to a soccer game using a small robot as a toy.

First, an outline of the robot game system according to the present embodiment will be described with reference to FIGS.
A soccer game system 200 as a robot game system according to the present embodiment is as shown in FIG.
First, a field 201 is set on the plane. This field 201 is an area obtained by dividing the plane into rectangles. In addition, a goal 203a is installed on one side of the field 201, and a goal 203b is installed on the side of the field 201 opposite to the side where the goal 203a is installed.
The goals 203a and 203b are, for example, bowl-shaped installations that are open on the field 201 side (center side in FIG. 1).

On the field 201, a ball 204 is installed, and striker robots 1a, 1b, 1c, 1d and keeper robots 117a, 117b as battle game robots are installed. The ball 204 is colored in a predetermined color (for example, orange). The striker robots 1a and 1b and the keeper robot 117a belong to one team (hereinafter referred to as team A), and the striker robots 1c and 1d and the keeper robot 117b include other teams (hereinafter referred to as team B). It belongs to.).
The details of the striker robots 1a, 1b, 1c, and 1d and the keeper robots 117a and 117b will be described later.

  Each of the team A and team B has one operator (not shown), and each operator operates the player-side controllers 205a and 205b. The player-side controller 205a is a team A-side controller, and the player-side controller 205b is a team B-side controller.

In the present embodiment, the striker robot 1a is controlled by the player-side controller 205a, and the striker robot 1c is controlled by the player-side controller 205b. The other striker robots 1b and 1d are autonomously controlled by the personal computer 213 described later based on the autonomous program.
The keeper robots 117a and 117b are also autonomously controlled by the personal computer 213 described later based on an autonomous program. The keeper robot 117a is operated by the player-side controller 205a and the keeper robot 205b is operated by the player-side controller 205b. It is also possible to perform the operation 117b.

Further, above the field 201, cameras 207a and 207b as image pickup apparatuses are installed. By using both the camera 207a and the camera 207b, the entire field 201 and its periphery can be imaged.
A display device 209 is installed near the field 201. The display device 209 is provided with, for example, an LED matrix display unit 209a for displaying a score, a clock display unit 209b for displaying a game time, and the like.

  A referee controller 211 is also installed in the vicinity of the field 201. The referee controller 211 is operated by a referee (not shown), and gives instructions such as addition / subtraction of scores, stop of operations by the player side controllers 205a and 205b of the operator who violates the rules, and the like.

  The soccer game system 200 is also provided with a personal computer 213. Wireless communication units 215 and 217 are connected to the personal computer 213. From the player side controllers 205a and 205b, the referee controller 211, the striker robots 1a, 1b, 1c, and 1d, and the keeper robots 117a and 117b. Data can be received by wireless communication, and data can be transmitted by wireless communication to the player-side controllers 205a and 205b, the striker robots 1a, 1b, 1c, and 1d, and the keeper robots 117a and 117b. it can.

  In addition, the cameras 207a and 207b are connected to the personal computer 213, and image data captured by the cameras 207a and 207b can be processed by the personal computer 213. The display device 209 is also connected to the personal computer 213.

  The personal computer 213 only processes image data captured by the cameras 207a and 207b, and based on the results, performs control (autonomous control) of the striker robots 1b and 1d and keeper robots 117a and 117b. In addition, the keeper robots 117a and 117b are controlled based on signals received from the player-side controllers 205a and 205b. That is, the striker robots 1a and 1c are controlled by an operation of the player side controllers 205a and 205b by an operator, and the striker robots 1b and 1d are controlled by autonomous control of the personal computer 213. . The keeper robots 117a and 117b are normally autonomously controlled by the personal computer 213 based on an autonomous program. If there is an instruction from the player-side controllers 205a and 205b, the operation selected based on the instruction is performed. It is controlled by the program.

  As described above, in the case of the present embodiment, the striker robot 1a is controlled by the player-side controller 205a, and the striker robot 1c is controlled by the player-side controller 205b. The other striker robots 1b and 1d are autonomously controlled by the personal computer 213 based on the autonomous program. The keeper robots 117a and 117b are normally autonomously controlled by the personal computer 213 based on an autonomous program. The keeper robot 117a is selected based on an instruction from the player-side controller 205a if there is an instruction. The keeper robot 117b is configured to be controlled by the operation program selected on the basis of the instruction from the player-side controller 205b if there is an instruction from the player-side controller 205b.

  Further, the personal computer 213 manages the score based on the signal from the referee controller 211, stops the striker robots 1b and 1d and the keeper robots 117a and 117b, stops operation by the player side controllers 205a and 205b, and the like. Also do. The personal computer 213 also instructs the display device 209 to display the score, remaining time, and the like.

  The personal computer 213 includes a team A card installation table 911 as a card reader, a team A storage medium reader 913 as user control program input means, a team B card installation table 915 as a card reader, A team A storage medium reader 917 is connected as a user control program input means. The team A card installation table 911 and the team B card installation table 915 are each provided with a camera (not shown), and are autonomously set on the team A card installation table 911 and the team B card installation table 915. A QR (Quick Response) code (registered trademark) described in a program selection card 919 (shown in FIGS. 2 to 4) and an operation program selection card 921 (shown in FIGS. 5 to 10) is read. Then, the autonomous program selection card 919 and the operation program selection card 921 select the autonomous programs and operation programs (described later) of the keeper robots 117a and 117b used by the personal computer 213.

  In the case of the present embodiment, for example, as shown in FIG. 1, the A team card installation base 911 includes an autonomous program selection card installation unit 911a, a left operation program selection card installation unit 911b, and a right operation program selection. In addition to the card installation unit 911c, the B team card installation table 915 is also provided with an autonomous program selection card installation unit 915a, a left operation program selection card installation unit 915b, and a right operation program selection card installation unit 915c. For each A team card installation table 911 (B team card installation table 915), one autonomous program selection card 919 and two operation program selection cards 921 are set. That is, one autonomous program is selected by one autonomous program selection card 919 for one keeper robot, and two operation programs are selected by two operation program selection cards 921. The keeper robots 117a and 117b are normally autonomously controlled by the selected autonomous program, and are controlled by any one of the selected two operation programs if there is an instruction from the player side controllers 205a and 205b. Will be.

The autonomous program selection card 919 has a configuration as shown in FIGS. 2 to 4, for example. The autonomous program selection card 919 has an autonomous program name 923, basic operation content 925a, and conditional operation content on the front side as shown in FIGS. 2 (a), 3 (a), and 4 (a), for example. 925b and the like are displayed, and as shown in FIGS. 2 (b), 3 (b), and 4 (b), an autonomous program corresponding to the autonomous program selection card 919 is specified on the back side. A QR code (registered trademark) 927 indicating information is displayed.
In this embodiment, the QR code (registered trademark) 927 is used as the code. However, the present invention is not limited to this, and other types of codes (for example, image processing system, magnetic system, Those that can be read by an optical method) may be used.
When the autonomous program selection card 919 is installed on the team A card installation table 911 or the team B card installation table 915, the surface side is exposed, so that the operator selects the selected autonomous program. The program name 923, basic operation content 925a, conditional operation content 925b, and the like can be visually recognized.

The operation program selection card 921 has a configuration as shown in FIGS. 5 to 10, for example. The operation program selection card 921 includes, for example, as shown in FIGS. 5 (a), 6 (a), 7 (a), 8 (a), 9 (a), and 10 (a). On the front side, an icon 929 displaying operation contents and operation contents 931 are displayed, and FIG. 5B, FIG. 6B, FIG. 7B, FIG. 8B, FIG. b) As shown in FIG. 10 (b), QR codes (registered trademark) 933a and 933b indicating information for specifying an operation program corresponding to the operation program selection card 921 are displayed on the back side thereof. .
When the operation program selection card 921 is also installed on the team A card installation table 911 or the team B card installation table 915, the front side is exposed, and the selected operation program icon 929, operation content 931, etc. are confirmed. It can be done.

The QR code (registered trademark) 933a and the QR code (registered trademark) 933b are the same. That is, the operation program selection card 921 displays QR code (registered trademark) 933a and QR code (registered trademark) 933b having the same contents on both ends in the width direction. This is due to the following reason.
For example, looking at the card installation table 911 for Team A, one autonomous program selection card 919 is set there, and one operation program selection card 921 is set on each of the left and right sides thereof. In this state, it is necessary to image the QR code (registered trademark) 927 of the one autonomous program selection card 919 and the QR code (registered trademark) of the two operation program selection cards 921 at one time with one camera.
At that time, the range that can be imaged by one camera is limited to the periphery of the autonomous program selection card 919. Therefore, the QR code (registered trademark) of the operation program selection card 921 is at a position close to the autonomous program selection card 919 side. There must be.
However, whether the operation program selection card 921 is inserted into the left operation program selection card installation unit 911b or the right operation program selection card installation unit 911c is arbitrary.
Therefore, regardless of whether the operation program selection card 921 is inserted into the left operation program selection card installation unit 911b or the right operation program selection card installation unit 911c, the QR code (registered trademark) is located at the autonomous program selection card 919 side. Therefore, the operation program selection card 921 displays the same QR code (registered trademark) 933a and QR code (registered trademark) 933b on both ends in the width direction.

The team A storage medium reader 913 and the team B storage medium reader 917 are for reading a user program (described later) recorded in a storage medium (not shown) into the personal computer 213. In the present embodiment, an SD (Secure Digital) card is assumed as the storage medium, but other storage media may be used.
The personal computer 213 is also connected with an input keyboard 219 and an output display 221.
Details of the internal configuration and processing contents of the personal computer 213 will be described later.
The above is the outline of the soccer game system 200.

Next, the configuration of the striker robots 1a, 1b, 1c, and 1d used in the soccer game system 200 according to the present embodiment will be described with reference to FIGS.
In the description of this configuration, the striker robots 1a, 1b, 1c, and 1d will be described as the striker robot 1.
The striker robot 1 used in the soccer game system 200 according to the present embodiment is as shown in FIGS. The striker robot 1 is a kind of soccer game robot, and moves, holds the ball 204, kicks the held ball 204 (kick), and has a role as a field player in the soccer game.

As shown in FIGS. 11 to 14, the striker robot 1 includes a robot main body 3 as an apparatus main body and upper cover 5a, 5b, upper cover 5c, 5d, upper rear cover 5e, 5f, and side cover 5g as exterior materials. 5h, wheel covers 5i, 5j, a back cover 5k, a front cover 5m, and a lower back cover 5n are attached.
The attachment structure between the robot body 3 and the exterior material such as the top cover 5a will be described later.

  Of these exterior materials, a color panel 7a is detachably engaged and fixed to the upper cover 5c, and a color panel 7b is detachably engaged and fixed to the upper cover 5d, and the upper back cover 5e. The color panel 7c is detachably engaged and fixed, and the upper back cover 5f is detachably engaged and fixed. A marker for identifying the striker robot 1 is formed by the combination and arrangement of the color panels 7a, 7b, 7c, and 7d. In addition, the individual marker and the position / orientation of the striker robot 1 are determined by imaging the marker with the cameras 207a and 207b and performing image processing on the captured data.

Further, a ball holding / kick mechanism 9 that performs a holding operation of the ball 204 and a kicking operation (kick) of the held ball 204 is installed on the front surface side (lower side in FIG. 14) of the robot body 3. Details of the ball holding / kick mechanism 9 will be described later.
Further, as shown in FIGS. 11 and 14, an exterior material 8 is interposed between the upper surface covers 5a and 5b. The exterior material 8 is exposed to the outside on the front side (lower right side in FIG. 11).
As shown in FIG. 12, an LED cover 10 is installed on the back cover 5k. Inside the LED cover 10, LEDs 723a, 723b, and 723c mounted on a substrate 19 described later are arranged.
The above is the schematic configuration of the striker robot 1 according to the present embodiment. Hereinafter, the configuration of each unit will be sequentially described in detail.

First, the configuration of the robot body 3 will be described in detail.
As shown in FIGS. 15 to 24, the robot body 3 includes wheel units 11a and 11b, a cam drive unit 13 and a battery box unit 15 as device constituent units, an upper plate 17a, a side plate 17b, a side plate 17c, A central plate 17d, a front plate 17e, a back plate 17f, and a bottom plate 17g are attached and integrated. The back plate 17f is attached with a substrate 19 on which electronic components (not shown) and LEDs 723a, 723b, and 723c described later are mounted. A wireless communication substrate (not shown) is attached to the upper surface plate 17a. Further, support units 21 and 21 each having a steel ball 21b rotatably held by a sphere holding member 21a are attached to the bottom plate 17g.

The wheel unit 11a has a gear box 23 as shown in FIGS. The gear box 23 includes cases 25a and 25b. As shown in FIG. 22, the input side gears 27a, 27a and 27a, the first central gear 27b, the second central gear 27c, the third central gear 27d, and the fourth central gear. A gear 27e, a fifth central gear 27f, a sixth central gear 27g, and an output side gear 27h are internally provided.
Further, as shown in FIG. 22, the first central gear 27b is meshed with the input side gear 27a. The second central gear 27c is coaxially integrated with the first central gear 27b, and the third central gear 27d is engaged with the second central gear 27c. The fourth central gear 27e is coaxially integrated with the third central gear 27d, and the fifth central gear 27f is engaged with the fourth central gear 27e. The sixth central gear 27g is coaxially integrated with the fifth central gear 27f, and the output side gear 27h is engaged with the sixth central gear 27g.
The first central gear 27b, the third central gear 27d, and the fifth central gear 27f are spur gears larger in diameter than the second central gear 27c, the fourth central gear 27e, and the sixth central gear 27g. It is.

  Further, as shown in FIG. 18, a motor 29 is installed in the wheel unit 11a. As shown in FIGS. 21 and 22, the output shaft 26 of the motor 29 is press-fitted to any one of the input side gears 27a of the gear box 23 as shown in FIGS. The motor 29 is engaged and fixed to an engagement portion 30 formed on the case 25b corresponding to the positions of the input side gears 27a, 27a, 27a. As shown in FIG. 22, an omnidirectional wheel 31 is connected to the output side gear 27h via an output shaft 28. The rotation of the output shaft of the motor 29 includes the input side gear 27a, the first central gear 27b, the second central gear 27c, the third central gear 27d, the fourth central gear 27e, the fifth central gear 27f, and the sixth central gear. 27 g and the output side gear 27 h are decelerated and transmitted, and the omnidirectional wheel 31 is rotated.

  The case 25 b is formed with a nut storage portion 35 as a concave fitting portion, and a nut 37 is internally provided in each nut storage portion 35. The nut storage portion 35 is opened toward the outside of the gear box 23 (upper side in FIG. 18, front side in the vertical direction of the paper surface, lower side, rear side in the vertical direction of the paper surface). The screw part is exposed. Further, the nut housing portion 35 is narrower on the opening side than the inside, whereby the nut 37 is held inside.

  The omnidirectional wheel 31 includes a wheel body 39 and a plurality of (for example, 18 in the case of the present embodiment) substantially disc-shaped rollers 41 provided rotatably on the outer peripheral side of the wheel body 39. It is composed of A plurality of convex portions 42 are formed over the entire circumference of the outer peripheral surface of the roller 41. The wheel body 39 has roller grooves 43 corresponding to the rollers 41. As shown in FIG. 22, bearing holes 43a are formed on both side surfaces of the roller grooves 43, respectively. ing. On the other hand, as shown in FIG. 22, rotation shafts 44 and 44 are formed on both surfaces of the roller 41, and the rotation shaft is disposed in the bearing hole 43a. The rotary shafts 44 and 44 are rotatable.

The wheel body 39 is composed of two wheel members 45a and 45b. The wheel members 45a and 45b have a shape obtained by vertically dividing the wheel body 39 into a plurality of pieces, and as shown in FIGS. 19 and 22, a plurality of (this embodiment) inserted from the wheel member 45a side (right side in FIG. 22). In this case, for example, the wheel main body 39 is configured by integrating two fixing screws 47a into a nut 47b fitted to the wheel member 45b.
A wheel cap 48 is engaged and fixed on the side of the wheel body 39 opposite to the gear box 23 (right side in FIG. 22).

  The wheel unit 11b has the same configuration as the wheel unit 11a. However, the mounting position of the motor 29 on the wheel unit 11b side is a position that does not interfere with the motor 29 on the wheel unit 11a side.

  Next, the configuration of the cam drive unit 13 will be described. The cam drive unit 13 includes a gear box 49 as shown in FIG. The gear box 49 includes cases 51a and 51b. As shown in FIGS. 24 and 25, the input side gear 53a, the first central gear 53b, the second central gear 53c, the third central gear 53d, and the fourth central gear. 53e, a fifth central gear 53f, a sixth central gear 53g, a seventh central gear 53h, an eighth central gear 53i, a ninth central gear 53j, a tenth central gear 53k, and an output side gear 53m.

As shown in FIG. 25, the first central gear 53b is engaged with the input side gear 53a. The second central gear 53c is coaxially integrated with the first central gear 53b, and the third central gear 53d is engaged with the second central gear 53c. The fourth central gear 53e is coaxially integrated with the third central gear 53d, and the fifth central gear 53f is engaged with the fourth central gear 53e. The sixth central gear 53g is coaxially integrated with the fifth central gear 53f, and the seventh central gear 53h is engaged with the sixth central gear 53g. The eighth central gear 53i is coaxially integrated with the seventh central gear 53h, and the ninth central gear 53j is engaged with the eighth central gear 53i. The tenth central gear 53k is coaxially integrated with the ninth central gear 53j, and the output side gear 53m is engaged with the tenth central gear 53k.
The first central gear 53b, the third central gear 53d, the fifth central gear 53f, the seventh central gear 53h, and the ninth central gear 53j are the second central gear 53c, the fourth central gear 53e, and the sixth central gear. It is a spur gear having a larger diameter than 53g, the eighth central gear 53i, and the tenth central gear 53k.

Further, as shown in FIGS. 18 and 25, an output shaft 57 projects from the front side of the gear box 49 (the front side in the direction perpendicular to the paper surface in FIG. 18), and the output shaft 57 is connected to the output side gear 53m. Is connected on the same axis.
As shown in FIGS. 18 and 24, the cam drive unit 13 is provided with a motor 59. As shown in FIG. 24, the output shaft 61 of the motor 59 is connected to the input side gear 53 of the gear box 49 by press fitting. The motor 59 is engaged and fixed to an engaging portion 63 formed in the case 51b.
Then, the rotation of the output shaft 61 of the motor 59 causes the input side gear 53a, the first central gear 53b, the second central gear 53c, the third central gear 53d, the fourth central gear 53e, the fifth central gear 53f, The output shaft 57 is rotated by being decelerated through the sixth central gear 53g, the seventh central gear 53h, the eighth central gear 53i, the ninth central gear 53j, the tenth central gear 53k, and the output side gear 53m. It will be.

Also, the case 51b of the gear box 49 is formed with a nut storage portion 65 as a concave fitting portion, similar to the case 25b of the gear box 23 described above. Is equipped with a nut 67.
In addition, the case 51b of the gear box 49 holds a plurality of nuts (not shown) (for example, two in the case of the present embodiment) that protrude to the case 51a side (the front side in the vertical direction in FIG. 18). The part is formed. A nut 66 is installed in a recess provided on the tip surface of each nut holding portion (the front end surface in the direction perpendicular to the paper surface in FIG. 18). Further, the case 51a of the gear box 49 is formed with a plurality of (for example, two in this embodiment) through holes 64 corresponding to the nut 66, and the female screw of the nut 66 is formed. The part is exposed to the outside through the through hole 64.

Next, the configuration of the battery box unit 15 will be described with reference to FIGS. 16 to 18 and 25.
First, the battery box unit 15 includes cases 68a and 68b, and a battery 68h is accommodated therein. The case 68b is formed with a nut storage portion (not shown), and a nut (not shown) is housed inside the nut storage portion. Further, the female screw portion of the nut (not shown) is exposed on the back side of the battery box unit 15 (the back side in the direction perpendicular to the paper in FIG. 18). Also, as shown in FIGS. 16 and 18, electrodes 68c and 68d are projected and arranged on the back side of the battery box unit 15, and power from a battery (not shown) is taken out by the electrodes 68c and 68d. I have to. As shown in FIG. 17, an opening 68e is provided on the bottom side of the battery box unit 15, and the opening 68e is closed by a lid 68f. One end side (left side in FIG. 17) of the lid 68f is rotatably attached to the cases 68a and 68b, and the other end side is fixed by a screw 68g. By removing the screw 68g and rotating the lid 68f, the opening 68e can be opened, and the battery 68h can be taken out and stored.

Next, the configuration of the top plate 17a, side plate 17b, side plate 17c, center plate 17d, front plate 17e, back plate 17f, and bottom plate 17g will be described. First, the top plate 17a, the side plate 17b, the side plate 17c, and the back plate 17f are obtained by cutting and processing a device assembly plate 69 as shown in FIGS. 26 and 27 into a predetermined shape and size.
As shown in FIG. 27B, a plurality of through holes 69a are formed in the device assembly plate 69. A plurality of surface side concave fitting portions 69b are formed on one surface (the upper surface in FIG. 27B) of these through holes 69a. As shown in FIG. 27 (b), a plurality of back-side recessed fittings 69c are formed on the other surface (the lower surface in FIG. 27 (b)) side of the through hole 69a of the device assembly plate 69. Is formed.

Further, a plurality of linear grooves 69e and a plurality of linear grooves 69f orthogonal to the grooves 69e are formed on both surfaces of the device assembly plate 69. The grooves 69e and 69f are partitioned in a lattice shape. Moreover, it is comprised so that either one of the said surface side recessed fitting part 69b or the said back surface side recessed fitting part 69c may be formed for every division. Further, the device assembling plate 69 is thin at the portion where the grooves 69e and 69f are formed, and can be easily cut along the grooves 69e and 69f. The upper surface plate 17a and the like are formed by cutting the device assembly plate 69 along the grooves 69e and 69f.
A plurality of through holes 69g are formed at equal intervals in the grooves 69e and 69f. The through holes 69g are formed at both ends and the middle point of each side of the grid-like section formed by the grooves 69e and 69f.
Further, in the device assembling plate 69, the arrangement of the front surface side recessed fitting portions 69b and the back surface side recessed fitting portions 69c is a staggered arrangement. That is, as shown in FIG. 27 (a), the section in which the front-side concave fitting portion 69b is formed and the section in which the rear-side concave fitting portion 69c is formed are left and right in the vertical direction in FIG. They are also arranged alternately in the direction.

Further, the central plate 17d, the front plate 17e, and the bottom plate 17g are obtained by cutting and processing a device assembling plate 71 as shown in FIGS. 28 and 29 into a predetermined shape and size.
Similarly to the device assembly plate 69 described above, the device assembly plate 71 also has a through hole 71a, a front surface side recessed fitting portion 71b, a back surface side recessed fitting portion 71c, a plurality of linear grooves 71e, and is orthogonal to the groove 71e. A plurality of linear grooves 71f and a plurality of through holes 71g in the grooves 71e and 71f are formed.
However, the apparatus assembly plate 71 is different from the apparatus assembly plate 69 in the arrangement of the front surface side recessed fitting portions 71b and the back surface side recessed fitting portions 71c, and the front surface side recessed fitting portions 71b and the above described The back side concave fitting portions 71c are arranged in a striped pattern. That is, in the apparatus assembling plate 71, as shown in FIG. 29A, the section in which the front surface side recessed fitting portion 71b is formed and the section in which the rear surface side recessed fitting portion 71c is formed are shown in FIG. a) It is arranged in a line in the middle vertical direction, and the row in which the front side concave fitting portion 71b is formed and the row in which the back side concave fitting portion 71c is formed are alternately arranged in the horizontal direction in FIG. It will be arranged in.
The cutting / processing along the grooves 69e (71e) and 69f (71f) of the device assembly plate 69 (71) is performed by, for example, a nipper.

Next, referring to FIG. 19 and FIG. 21, the mounting structure of the center plate 17d, the front plate 17e, the back plate 17f, and the bottom plate 17g to the gear box 23, and the mounting structure of the back plate 17f to the battery box unit 15 are described. The gear box 23 on the wheel unit 11a side will be described as an example.
As shown in FIG. 19 and FIG. 21, first, the back plate 17f is brought into contact with the back surface (left surface in FIG. 21) of the gear box 23 at the right end side (right side in FIG. 19). At this time, the surface of the back plate 17f on the surface side recessed fitting portion 69b side is on the side opposite to the gear box 23 (left side in FIG. 21A), and the surface on the back surface side recessed fitting portion 69c side is on the gear box 23 side (see FIG. 21 (a) right side).
The back plate 17f is fixed by a screw 73 that passes through the front-side recessed fitting portion 69b and the through-hole 69a and is screwed into a nut 37 provided in the nut storage portion 35 of the gear box 23. . At this time, the head of the screw 73 is housed in the front side recessed fitting portion 69b of the back plate 17f.

Further, as shown in FIGS. 19 to 21, a front plate 17e is similarly attached to the front surface (right surface in FIG. 21) of the gear box 23, and the top surface (upper side in FIG. 21) of the gear box 23. The center plate 17d is similarly attached to the surface of the gear box 23, and the bottom plate 17g is similarly attached to the bottom surface of the gear box 23 (the lower surface in FIG. 21).
Similarly, a center plate 17d, a front plate 17e, a back plate 17f, and a bottom plate 17g are also attached to the gear box 23 on the wheel unit 11b side.
Similarly, the battery box unit 15 has a nut housed in a nut housing (not shown), and the back plate 17f is attached by a screw (not shown).
In the case of the mounting structure of the central plate 17d, the front plate 17e, and the bottom plate 17g, the screw 73 passes through the surface side recessed fitting portion 71b such as the central plate 17d and the through hole 71a, and the screw 73 The screw head is accommodated in the front surface side recessed fitting portion 71b.

Next, with reference to FIG. 24, the attachment structure of the top plate 17a, the side plate 17b, the side plate 17c, and the center plate 17d to the gear box 49 will be described.
The attachment structure of the top plate 17a, the side plate 17b, and the side plate 17c to the gear box 49 is the same as that of the gear box 23 described above. That is, as shown in FIG. 24, a nut 67 is also housed in the nut housing portion 65 of the case 51b of the gear box 49, and the upper surface plate 17a and the like brought into contact with the gear box 49 are connected to the upper surface. The plate 17a and the like are fixed by screws 75 that pass through the surface side recessed fitting portions 69b and the through holes 69a and are screwed into the nuts 67. The screw head of the screw 75 is accommodated in the front side recessed fitting portion 69b.

The central plate 17d is attached to the gear box 23 as well as the gear box 49. In this case, the screw 75 is connected to the back side recessed fitting portion 69c and the through hole 69a of the device assembly plate 17d. It penetrates, and the head of the screw 75 is accommodated in the back side recessed fitting portion 69c.
Further, as described above, the support units 21 and 21 are attached to the bottom surface plate 17g, and this attachment structure is the same as the attachment structure of the robot body 3 and the upper surface cover 5a described later.
Each of the apparatus assembly plates used in the robot body 3 has its front side concave fitting portions 69b and 71a directed to the outside of the robot main body 3, and its rear side concave fitting portions 69c and 71c. The robot body 3 is attached so as to be oriented inside.

Further, as shown in FIGS. 17 and 23, a spacer 86a obtained by processing the device assembly plate 71 is attached to the upper surface plate 17a. The spacer 86a is fixed by a screw 86b screwed to a nut (not shown) fitted in the front side concave fitting portion 69b of the upper surface plate 17a, and the head of the screw 86b is fixed to the spacer 86a. Is housed in the front surface side recessed fitting portion 71b.
A spacer 86c obtained by processing the device assembling plate 71 is also attached to the side plate 17c. The spacer 86c is also fixed by a screw 86e screwed to a nut 86d fitted in the front side recessed fitting portion 71b of the spacer 86c, and the head of the screw 86e is fixed to the side plate 17c. It is accommodated in the front side recessed fitting part 69b.
The above is the description of the configuration of the robot body 3.

Next, an exterior material mounting structure for the robot body 3 will be described with reference to FIGS.
The upper cover 5c is fixed to the side plate 17b of the robot body 3 as shown in FIGS. As shown in FIG. 32, a plurality of (for example, two in this embodiment) screw storage portions 77 are formed in the upper cover 5c. The screw storage portion 77 has a bottomed cylindrical shape that projects and is formed toward the robot body 3 side (lower side in FIG. 32A), and the outer side (upper side in FIG. 32A). A through hole 79 is formed at the bottom. On the other hand, a nut 81 is fitted into the back side recessed fitting portion 69c of the side plate 17b.
The nut 81 is screwed with a screw 83 that penetrates the through hole 79. The upper cover 5c is fixed to the side plate 17b by the screws 83. The head of the screw 83 is accommodated in the screw accommodating portion 77.

  Similarly, the upper cover 5d, the side covers 5g, 5h, the wheel covers 5i, 5j, the back cover 5k, the front cover 5m, and the lower back cover 5n are similarly attached to the corresponding device assembly plate of the robot body 3. ing. Similarly, the attachment of the substrate 19 to the back plate 17f and the attachment of a wireless communication substrate (not shown) to the top plate 17a are similarly performed by screws 83 screwed into nuts fitted in the back side recessed fitting portions 69c. Has been done.

Further, as shown in FIG. 11, the upper surface covers 5a and 5b are integrated with the exterior material 8 interposed therebetween, and are attached to the upper surface plate 17a in the same manner as the upper cover 5c described above. As shown in FIG. 14, a notch 85 is formed at each end of the top cover 5a (left end in FIG. 14) and end of the top cover 5b (right end in FIG. 14). A screw (not shown) used when fixing the upper surface covers 5a and 5b passes through the notch 85 and is screwed into a nut (not shown) fitted in the back surface side recessed fitting portion 69c of the upper surface plate 17a. . The head of the screw (not shown) is covered with the upper covers 5c and 5d.
Also, as shown in FIG. 12, the back cover 5e and the back cover 5f are engaged and integrated, and then the upper cover 5c and the above cover are formed on the back side of the striker robot 1 (lower left side in FIG. 12). It is inserted and attached between the upper cover 5d.

Next, the ball holding / kick mechanism 9 will be described with reference to FIGS.
The ball holding / kick mechanism 9 is attached to a gear box 49 of the cam drive unit 13 as shown in FIG.
First, the ball holding / kick mechanism 9 includes a base member 87. On the lower side of this base member 87 (lower side in FIG. 34), bearing mounting member engaging portions 87a and 87a are formed. The base member 87 is formed with through holes 87b and 87b. The base member 87 is fixed to the gear box 49 by a screw (not shown) that passes through the through hole 87b and the through hole 64 of the case 51a of the gear box 49 and is screwed to the nut 66 in the gear box 49. The The base member 87 is also provided with a cam storage portion 87c.

A bearing mounting member 89 is engaged and fixed to the bearing mounting member engaging portions 87 a and 87 a of the base member 87. Bearing mounting portions 89a and 89a are formed on the upper side (upper side in FIG. 34) of both ends of the bearing mounting member 89 (both sides in the direction from the lower left to the upper right in FIG. 34). Engaging protrusions 89b and 89b are formed on the lower side (lower side in FIG. 34) of both ends of the bearing mounting member 89 (both sides in the direction from the lower left to the upper right in FIG. 34). The bearing mounting member 89 is fixed to the base member 87 by engaging engaging projections 89 b and 89 b with bearing mounting member engaging portions 87 a and 87 a of the base member 87.
Further, bearing members 91 and 91 are attached to the bearing attaching member 89. The bearing member 91 is formed with a bearing portion 91a. The bearing member 91 has an engagement groove 91b.
The bearing member 91 is fixed to the bearing mounting member 89 by engaging the bearing mounting portion 89a of the bearing mounting member 89 with the engagement groove 91b.

  Further, the ball holding / kick mechanism 9 has a main shaft 93 as shown in FIG. The main shaft 93 includes a shaft portion 93a having both ends (in the left-right direction end in FIG. 34) having a substantially T-shaped cross-sectional shape, and a cam biasing projecting and formed on the outer peripheral side of the shaft portion 93a. It is comprised from the part 93b and the spring engaging part 93c. The main shaft 93 is rotatably supported by the bearing portions 91a of the bearing members 91 and 91.

  A ball holding coil spring 95 as a ball holding elastic member is installed on the main shaft 93 so as to penetrate the shaft portion 93a. The ball holding coil spring 95 is disposed on the left side in FIG. 34 of the cam urging portion 93b and the spring engaging portion 93c, and one end side thereof is engaged with the spring engaging portion 93c and the other end. The side is in contact with the front side (lower right side in FIG. 34) of the upper surface (upper surface in FIG. 34) of the bearing mounting member 89. The main shaft 93 is always urged by the ball holding coil spring 95 so as to be rotated in the clockwise direction in FIG.

Further, a kick coil spring 97 as a kick elastic member is installed on the main shaft 93 so as to penetrate the shaft portion 93a. The kick coil spring 97 is disposed on the right side in FIG. 34 of the cam biasing portion 93b and the spring engaging portion 93c of the main shaft 93. The main shaft 93 is rotatably installed with a kick arm 99 penetrating the shaft portion 93a. The kick arm 99 has a bearing portion 99a, a cam biasing portion 99b, and a spring engaging portion 99c formed on one end side (upper side in FIG. 34) and the other end side (lower side in FIG. 34). ) Is formed with a kick member attaching portion 99d. The kick arm 99 is disposed on the right side of the kick coil spring 97 in FIG. 34, and one end side of the kick coil spring 97 is engaged with the spring engaging portion 99c of the kick arm 99. The other end is in contact with the front side (lower right side in FIG. 34) of the upper surface (upper surface in FIG. 34) of the bearing mounting member 89. The kick arm 99 is always urged by the kick coil spring 97 so as to be rotated in the clockwise direction in FIG.
The kick member 101 is fixed to the kick member mounting portion 99d of the kick arm 99.

Further, the above-described bearing members 91 and 91 are installed outside the ball holding coil spring and outside the kick arm.
Also, ball holding arm bases 103 and 103 are fixed to both ends of the shaft 93a of the main shaft 93 (both sides in the direction from the lower left to the upper right in FIG. 34). One end side (upper side in FIG. 34) of the ball holding arm base 103 is formed with a through hole 103a corresponding to the cross-sectional shape of both end sides of the shaft part 93a (both sides in the direction from the lower left to the upper right in FIG. 34). In the through hole 103a, both end sides of the shaft portion 93a (both sides in the direction from the lower left to the upper right in FIG. 34) are press-fitted.

Further, the other end side (lower side in FIG. 34) of each of the ball holding arm base portions 103 is a connecting portion 103b, and the connecting portion 103b is connected to the tip end of the ball holding arm via a connecting block 105. The unit 107 is connected. One end side (upper side in FIG. 34) of the ball holding arm front end portion 107 is formed with a connection portion 107a connected to the connection block 105, and from the other end side (lower side in FIG. 34) in the width direction. (A direction from the lower left to the upper right in FIG. 34) Rotating shafts 107b and 107b are projected and formed on both sides.
The ball holding arm 108 is constituted by the ball holding arm base 103, the connection block 105, and the ball holding arm tip 107.

  A ball holding plate 109 is rotatably provided at each of the ball holding arm tip portions 107. A rotation shaft guide portion 110 is provided on the inner side (center side in FIG. 34) of the ball holding plate 109. The rotation shaft guide portion 110 is provided with the rotation shafts 107b and 107b of the tip end portion 107 of the ball holding arm. Are engaged so as to be slidable in the vertical direction (vertical direction in FIG. 34). Also, as shown in FIG. 36 (a), the rear end sides of the ball holding plates 109, 109 (the front side in the vertical direction in the middle of FIG. 36 (a)) are the inner sides of the wheel cover 5i and the wheel cover 5j ( It is slidably engaged with the ball holding plate guides 111 and 111 formed on the center side in FIG.

  A sensor substrate 113 is installed on the back surface of the base member 107 (the upper left surface in FIG. 34). A sensor switch 113a is installed on the lower end side (lower side in FIG. 34) of the sensor substrate 113. The sensor switch 113a is for stopping the rotation of the motor 59. Details will be described later.

The ball holding / kick mechanism 9 is provided with a cam 115 as a cam means that is a driving means. The cam 113 is fixed to the output shaft 57 of the cam drive unit 13 described above and is rotated by a motor 59. The cam 115 is disposed in the cam housing portion 87 c of the base member 87.
The cam 115 has a shape as shown in FIG. First, the outer peripheral surface of the cam 115 has a shape as shown in FIG. That is, an urging portion 115a having a maximum diameter, a release portion 115b having a minimum diameter, and a return operation portion 115c in which the diameter gradually changes from the minimum to the maximum are formed. A convex portion 115f is formed at the boundary between the release portion 115b and the return operation portion 115c. In addition, the diameter changes rapidly at the boundary between the urging portion 115a and the release portion 115b.
The convex portion 115f is for concentrating the force in the return direction during the return operation. That is, when there is no convex portion 115f, there is a concern that the kick arm 99 and the ball holding arm base portions 103 and 103 may slide in the lateral direction during the return operation, but once the convex portion 115f is provided, the return is temporarily performed. Since the force can be concentrated in the direction, the subsequent return operation becomes smoother.

A sensor switch urging portion 115d is formed on the rear side of the cam member 115 (left side in FIG. 35C). The sensor switch urging portion 115d is provided with a protruding portion 115d ′ that partially protrudes only in a predetermined radial direction (the lower side in FIG. 23B). The sensor switch 113a is energized. The rotation of the motor 59 is stopped at the timing when the sensor switch 113a is urged by the protrusion 115d ', and the urging of the sensor switch 113a by the protrusion 115d' is released. The rotation of the motor 59 is also stopped at the timing of shifting from the applied state to the energizing state.
The cam member 115 is provided with a through hole 115e, and the output shaft 57 of the cam drive unit 13 is press-fitted into the through hole 115e.
The above is the description of the configuration of the striker robot 1.

Next, the operation of the striker robot 1 will be described.
The striker robot 1 performs a movement, a ball holding / kicking operation in response to an instruction of a signal received by a wireless communication board (not shown) provided in the robot body 3.
First, the movement of the striker robot 1 will be described with reference to FIG. 11 and FIG. FIG. 23 shows only the robot main body 3 from which the exterior material and the ball holding / kick mechanism 9 are removed from the striker robot 1. The robot main body 3 will be described as the striker robot 1.
The striker robot 1 is provided with two wheel units 11 a and 11 b each having one omnidirectional wheel 31. Therefore, if both the omnidirectional wheels 31 of the wheel units 11a and 11b are rotated clockwise in FIG. 23, the striker robot 1 moves forward (moves to the lower right side in FIG. 11 and the left side in FIG. 23). It will be. If the omnidirectional wheels 31 of the wheel units 11a and 11b are both rotated counterclockwise in FIG. 23, the striker robot 1 moves backward (moves to the upper left in FIG. 11 and to the right in FIG. 23). It will be.

  Further, if the omnidirectional wheels 31 of the wheel units 11a and 11b are rotated in opposite directions, the striker robot 1 performs a turning operation on the spot. That is, when the omnidirectional wheel 31 of the wheel unit 11a is rotated counterclockwise in FIG. 23 and the omnidirectional wheel 31 of the wheel unit 11b is rotated clockwise in FIG. 23, the striker robot 1 A turn (turn in the clockwise direction in FIG. 11) is performed. Further, when the omnidirectional wheel 31 of the wheel unit 11a is rotated clockwise in FIG. 23 and the omnidirectional wheel 31 of the wheel unit 11b is rotated counterclockwise in FIG. 23, the striker robot 1 rotates counterclockwise. Turn (counterclockwise turning in FIG. 11).

In the turning operation, if only one of the wheel units 11a and 11b is rotated, a turning operation having a turning radius larger than the turning operation described above is performed. In addition, while the omnidirectional wheels 31, 31 of the wheel units 11a, 11b are both rotated in the same direction, a turning operation is performed while moving by relatively increasing / decreasing the rotational speed of both.
The movement speed and turning speed of the striker robot 1 are controlled by controlling the rotational speeds of the omnidirectional wheels 31 and 31.
The above is the description of the movement of the striker robot 1.

Next, the ball holding / kicking operation of the striker robot 1 will be described with reference to FIGS.
The ball holding / kick mechanism 9 of the striker robot 1 is normally in a standby state, but when it receives a signal for operating the ball holding / kick mechanism 9 in this normal state, it shifts to the ball holding state. Thereafter, when a signal for operating the ball holding / kick mechanism 9 is further received, an operation of returning to a standby state after performing a kick operation is performed.

  First, the standby state of the ball holding / kick mechanism 9 will be described with reference to FIG. In this standby state, as shown in FIG. 36 (a), the cam 115 has a state in which the protruding portions of the urging portion 115a and the sensor switch urging portion 115d are directed upward (upper side in FIG. 36 (a)). It has become. At this time, the urging portion 115 a causes the cam urging portion 93 b of the main shaft 93 and the cam urging portion 99 b of the kick arm 99 to move between the ball holding coil spring 95 and the kick coil spring 97 by the urging portion 115 a of the cam 115. By urging against the urging force, the kick arm 99 and the main shaft 93 are rotated counterclockwise in FIG.

  At this time, the ball holding arms 108 and 108 connected to the main shaft 93 are also turned counterclockwise in FIG. 36B, and the ball holding plates 109 and 109 are also The robot is housed on the robot body 3 side (the right side in FIG. 36B). The kick member 101 connected to the kick arm 99 is also housed on the robot body 3 side (the right side in FIG. 36B). At this time, the sensor switch urging portion 115d of the cam 115 urges the sensor switch 113a on the sensor substrate 113. Such a state is a standby state of the ball holding / kick mechanism 9.

Next, the ball holding state of the ball holding / kick mechanism 9 will be described with reference to FIG.
When a signal for operating the ball holding / kick mechanism 9 is received in the standby state described above, the cam 115 is rotated counterclockwise in FIG. At this time, the urging portion 115a of the cam 115 is located under the cam urging portion 99b of the kick arm 99 (lower side in FIG. 37B). The release portion 115b of the cam 115 is located below the portion 93b (the lower side in FIG. 37B). Accordingly, the kick arm 99 is biased by the cam 115, but the main shaft 93 is released from the bias by the cam 115. In such a state, the main shaft 93 and the ball holding arms 108 and 108 are rotated clockwise in FIG. 37B by the urging force of the ball holding coil spring 95, and the ball holding plate 109, 109 is projected forward of the striker robot 1 (left side in FIG. 37B) while being guided by the ball holding plate guides 111 and 111 of the wheel cover 5i and the wheel cover 5j. When the urging of the sensor switch 113a by the sensor switch urging portion 115d of the cam 115 is released, the rotation of the cam 115 is stopped.

  Until the next signal is received, the rotation of the cam 115 is stopped, and the ball holding plates 109 and 109 are projected to the front side of the striker robot 1 (left side in FIG. 37 (b)). At the same time, the state in which the kick member 101 is housed on the robot body 3 side (the right side in FIG. 37B) is maintained as in the standby state described above. At this time, the striker robot 1 can hold a ball (not shown) between the ball holding plates 109 and 109 in front of the kick member 101 (left side in FIG. 37B). Such a state is the ball holding state of the ball holding / kick mechanism 9. In this state, the dribbling operation is realized by the striker robot 1 moving forward, for example.

Next, the kick operation of the ball holding / kick mechanism 9 will be described with reference to FIG.
When a signal for operating the ball holding / kick mechanism 9 is received in the above-described ball holding state, the cam 115 is further rotated counterclockwise in FIG. Not only below the cam biasing portion 93b of the main shaft 93 (lower side in FIG. 38B) but also below the cam biasing portion 99b of the kick arm 99 (lower side in FIG. 38B). The release portion 115b of the cam 115 is positioned. In such a state, the bias of the kick arm 99 by the cam 115 is released, and the kick arm 99 is rotated clockwise in FIG. 38 (b) by the biasing force of the kick coil spring 97. And the kick member 101 kicks the ball (not shown) forward (left side in FIG. 38B). This operation is a kick operation.

After that, the cam 115 continues to rotate, and the return urging portion 115c urges the cam urging portion 93b of the main shaft 93 and the cam urging portion 99b of the kick arm 99, and the main shaft 93 and the kick The arm 99 is gradually rotated counterclockwise in FIG. The cam biasing portion 93b of the main shaft 93 and the cam biasing portion 99b of the kick arm 99 are again biased by the biasing portion 115a of the cam 115. As a result, the ball holding plates 109 and 109 and the kick member 101 are again housed on the robot body 3 side (the right side in FIG. 36B). In such a state, the sensor switch 113a of the sensor substrate 113 is biased by the sensor switch biasing portion 115d of the cam 115, and the rotation of the cam 115 is stopped. Through such an operation, the ball holding / kick mechanism 9 returns to the standby state shown in FIG.
The above is the description of the ball holding / kick operation of the striker robot 1.

Also, three LEDs 723a, 723b, and 723c, which will be described later, are installed inside the LED cover 10 of the striker robot 1.
These LEDs 723a, 723b, and 723c respectively indicate that the power of the striker robot 1 is turned on, that wireless communication is received, and that wireless communication is received. Further, these LEDs 723a, 723b, and 723c can be turned on in accordance with an instruction by wireless communication or a preset instruction.
The above is the description of the operation of the striker robot 1.

Next, the effect of the apparatus assembly plates 69 and 71 in this embodiment will be described.
A nut 37 or the like is housed in the nut storage portion 35 or the like of the gear box 23, and the rear plate 17 f or the like obtained by cutting and processing the device assembly plate 69 (71) is brought into contact with the outer peripheral surface of the gear box 23, thereby The back plate 17f and the like are fixed to the gear box 23 and the like by screws 73 and the like that pass through the plate 17f and are screwed into the nut 37 and the like. A back plate 17f or the like can be attached. Further, since the nut 37 and the like and the screw 73 and the like are used for fixing, the back plate 17f for the gear box 23 and the like is not formed without self-tapping the self-tapping of the gear box 23 and the like. And the like can be easily and repeatedly performed.

The back plate 17f and the like are obtained by cutting and processing the device assembly plate 69 (71). The device assembly plate 69 (71) has a front side concave fitting portion 69b (71b) and a back side concave portion. Since the fitting portion 69c (71c) is formed, the screw head such as the screw 73 is accommodated in the front surface side concave fitting portion 69b (71b) and the back surface side concave fitting portion 69c (71c) so as not to protrude outside. Can be.
The device assembling plate 69 (71) is partitioned in a lattice pattern by linear grooves 69e (71e) and 69f (71f), and the front surface side recessed fitting portion 69b (71b) and the back surface are formed in the partition. Only one of the side concave fitting portions 69c (71c) is formed. Therefore, while ensuring the depth of the front surface side recessed fitting portion 69b (71b) and the back surface side recessed fitting portion 69c (71c) enough to accommodate the screw head such as the screw 73 and the nut 81, the above device The assembly plate 69 (71) can be made thin.

Further, since the grooves 69e (71e) and 69f (71f) are formed on both surfaces of the apparatus assembly plate 69 (71), the apparatus assembly plate 69 (71) is inserted into the grooves 69e (71e) and 69f. It can be easily cut and processed along (71f).
Further, since the through holes 69g (71g) are formed along the grooves 69e (71e) and 69f (71f), this also facilitates the cutting and processing of the device assembly plate 69 (71). ing.

  Further, a nut 81 or the like can be fitted into the front surface side recessed fitting portion 69a (71a) or the back surface side recessed fitting portion 69c (71c) of the device assembly plate 69 (71). The upper cover 5c and the like can be easily attached to the device assembly plate 69 (71) by screwing the screws 83 and the like. In this case, since the nut 81 and the screw 83 are used, a female thread portion is not formed on the device assembly plate 69 (71) by self-tapping, and the device assembly plate 69 (71 The upper cover 5c and the like can be easily and repeatedly attached to and removed from the above.

  Further, in the device assembly plate 69, the arrangement of the front surface side recessed fitting portions 69b and the back surface side recessed fitting portions 69c is a staggered arrangement. In the device assembly plate 71, the front surface side recessed fitting portions 69c are arranged. The row | line | column in which any one of the part 71b or the said back surface side recessed fitting part 71c was formed is arranged alternately (striped arrangement). When the front-side concave fitting portion 69a (71a) and the rear-side concave fitting portion 69c (71c) are arranged in this way, the front-side concave portion has the same frequency at any place on the device assembly plate 69 (71). The fitting part 69b and the back side concave fitting part 69c appear, and the degree of freedom of the position of the fixed object fixed to the apparatus assembly plate 69 (71) is high.

  Further, since the device assembly plate 69 in a staggered arrangement and the device assembly plate 71 in a striped arrangement are used, a screw storage part (screw storage part 77 of the upper cover 5c, etc.) or a nut storage part for a fixed object. The degree of freedom of arrangement of the nut storage portion 35 of the gear box 23 and the degree of freedom of the position of the fixed object are high.

Next, the effect of the striker robot 1 according to the present embodiment will be described.
The striker robot 1 is configured using the above-described device assembly plates 69 and 71, the gear box 23 in which the nut 37 is housed, and the like. Therefore, the striker robot 1 can be easily assembled and disassembled. Can be repeated.
The striker robot 1 includes a ball holding / kick mechanism 9, and the ball holding / kick mechanism 9 includes two motors, that is, a ball, by one motor 59, one gear hox 49, and one cam 115. Since the holding arms 108 and 108 and the kick arm 99 are configured to be driven, the configuration of the ball holding / kick mechanism 9 is extremely simple. That is, a desired ball holding / kick mechanism 9 can be realized with a simple configuration.
Further, not only the kicking motion but also the movement after performing the ball holding motion, that is, dribbling can be performed, so that the playability as a soccer game can be improved.

Further, the ball holding operation and the kicking operation are sequentially performed only by the rotation of the cam 115 by the motor 59. Immediately after the ball holding operation is performed, the urging of the sensor switch 113a by the sensor switch urging portion 115d of the cam 115 is performed. Since the motor 59 is released and stopped, for example, by a simple operation of pressing the switch once, the transition to the ball holding state for performing the dribbling operation and the maintenance of the ball holding state are performed. be able to.
Further, after the cam 115 is further rotated from the ball holding state and the kick operation is performed, the cam 115 is returned to the standby state, and the sensor switch 113a is energized by the sensor switch energizing portion 115d of the cam 115, and the motor 59 is activated. Since it stops, for example, it is possible to perform an operation of returning to a standby state and stopping after a kick operation by a simple operation of pressing the switch once.

Further, since the ball is held between the ball holding plates 109 and 109 to perform the dribbling operation, the ball can be moved stably.
Further, since the kick member 101 is disposed between the ball holding plates 109, 109, the held ball is inevitably at a position where the kick member 101 can be kicked, and the kicking of the ball is prevented. It can be done easily.
Further, in the standby state, the ball holding plates 109 and 109 are housed on the robot body 3 side, so that obstruction of the progress of the game due to the interference between the ball holding plates 109 and 109 during the game is reduced. be able to.

Next, keeper robots 117a and 117b used in soccer game system 200 in the present embodiment will be described with reference to FIGS. In the description of this configuration, the keeper robots 117a and 117b will be described as the keeper robot 117.
The robot in this embodiment is a keeper robot 117 that is a kind of soccer game robot. The keeper robot 117 includes a robot main body 119 as the apparatus main body shown in FIGS. 39 to 41 and an exterior material (not shown) attached to the robot main body 119. In addition, the keeper robot 117 interferes with the progress of a ball (not shown) by moving or urges the ball to move, and has a role as a goal keeper in a soccer game. .
Further, for example, an operation mechanism for kicking a ball (not shown) may be attached to the keeper robot 117.
In the figure, the description of the exterior material is omitted.

  Further, a plurality of color panels (not shown) (for example, four in this embodiment) are mounted on the outside of the exterior material (not shown), similarly to the striker robot 1 in the embodiment described above. . As in the case of the above-described embodiment, these color panels constitute a marker for identifying the keeper robot 117. The marker is imaged by the cameras 207a and 207b, and the captured data is subjected to image processing, whereby the individual identification of the keeper robot 117 and the position / orientation are determined.

  The robot body 119 includes a wheel unit 121a, 121b, 121c, 121d, an operation unit 123, a battery box unit 125 as an apparatus constituent unit, an upper surface plate 127a, side plates 127b, 127c, a battery box unit fixing plate 127d, a center. The plate 127e and the bottom plate 127f are attached and integrated. Further, a substrate 129a on which an electronic component (not shown) is mounted is attached to the side plate 127b, and a substrate 129b on which an electronic component (not shown) is mounted is attached to the side plate 127c. A wireless communication substrate (not shown) is attached to the upper surface plate 127a.

The wheel units 121a, 121b, 121c, and 121d have the same configuration as the wheel units 11a and 11b in the above-described embodiment, and each wheel unit 121a, 121b, 121c, and 121d has one component. The same code | symbol as each component of the wheel units 11a and 11b in embodiment is attached | subjected, and the description is abbreviate | omitted.
Further, the operation unit 123 has the same configuration as the cam drive unit 13 in the above-described embodiment, and the same reference numerals are given to the same portions in the drawing, and the description thereof is omitted.

Further, for example, a kick operation mechanism (not shown) that can perform an operation of kicking the ball may be attached to the operation unit 123. As a kick operation mechanism (not shown) capable of kicking the ball, the ball holding arm 108 and the ball holding plate 109 are removed from the ball holding / kick mechanism 9 in the first embodiment described above. Such a thing that performs only such a kick action is conceivable.
The battery box unit 125 has the same configuration as that of the battery box unit 15 in the above-described embodiment, and the same portions are denoted by the same reference numerals in the drawings, and description thereof is omitted.

Further, the side plates 127b and 127c and the central plate 127e are obtained by cutting and processing an apparatus assembly plate having the same configuration as the apparatus assembly plate 69 in the above-described embodiment, and the same reference numerals are used for the same portions in the figure. The description is omitted.
Further, the top plate 127a, the battery box unit fixing plate 127d, and the bottom plate 127f are obtained by cutting and processing a device assembly plate similar to the device assembly plate 71 in the above-described embodiment, and the same parts in the figure. Are denoted by the same reference numerals and description thereof is omitted.

Further, the central plate 127e is attached to the upper surface (the upper surface in FIG. 42) of the wheel units 121a, 121b, 121c, and 121d, and the bottom surface (the lower side in FIG. 42) of the wheel units 121a, 121b, 121c, and 121d. The bottom plate 127f is attached to the surface. The center plate 127e and the bottom plate 127f are cut and processed into a cross shape as shown in FIGS. 41 and 42, and the wheel units 121a, 121b, 121c, 121d is installed. That is, the wheel unit 121a and the wheel unit 121d are installed in parallel, and the wheel unit 121b and the wheel unit 121c are installed in parallel, with respect to the wheel unit 121a and the wheel unit 121d. Thus, the wheel unit 121b and the wheel unit 121c are oriented in a direction orthogonal to each other.

  Further, the upper plate 127a is attached to the upper surface (upper surface in FIG. 42) of the operation unit 123, and the side plate 127b is attached to the left side surface of the operation unit 123 in FIG. A side plate 127c is attached to the right side surface of the operation unit 123 in FIG. 42, and a battery box unit fixing plate 127d is attached to the bottom surface (lower surface in FIG. 42) of the operation unit 123. ing. The battery box unit 125 is attached to the battery box unit fixing plate 127d. Further, connecting members 131 and 133 are attached to the battery box unit fixing plate 127d, and the connecting members 131 and 133 are also attached to the central plate 127e.

  The attachment structure of the center plate 127e to the wheel unit 121a is the same as the attachment structure of the center plate 17d, the front plate 17e, the back plate 17f, and the bottom plate 17g to the gear box 23 in the above-described embodiment. is there.

The attachment structure of the connection members 131 and 133 to the battery box unit fixing plate 127d and the central plate 127e is substantially the same as the attachment structure of the upper cover 5c as an exterior material to the robot body 3 in the above-described embodiment. belongs to. This will be described in detail below.
First, a mounting structure between the central plate 127e and the connection members 131 and 133 will be described. A concave fitting portion 131a is provided on the surface of the connecting member 131 on the battery box unit fixing plate 127d side (the upper surface in FIG. 42), and the surface of the connecting member 133 on the battery box unit fixing plate 127d side (FIG. 42). A concave fitting portion 133a is provided on the middle upper surface). Further, a through hole (not shown) is formed on the bottom surface (the lower surface in FIG. 42) of the concave fitting portion 131a of the connection member 131, and the bottom surface (the lower side in FIG. 42) of the concave fitting portion 133a of the connection member 133. A through hole (not shown) is formed on the surface. Further, a nut (not shown) is fitted into the back side recessed fitting portion 69c of the central plate 127e.

  And it penetrates the recessed fitting part 131a of the said connection member 131, the through-hole which is not shown in figure, the concave fitting part 133a of the said connection member 133, and the through-hole which is not shown in figure, and it is in the back surface side recessed fitting part 69c of the said center plate 127e. The connecting members 131 and 133 are attached to the central plate 127e by screws (not shown) that are screwed into the nuts (not shown) fitted therein. At this time, the head of the screw (not shown) is housed in the recessed fitting portion 131 a of the connecting member 131 or the recessed fitting portion 133 a of the connecting member 133.

  The attachment structure between the battery box unit fixing plate 127d and the connection members 131 and 133 is the same as the attachment structure between the center plate 127e and the connection members 131 and 133. That is, a concave fitting portion (not shown) is formed on the central plate 127e side (the lower surface in FIG. 42) of the connection members 131, 133, and a screw (not shown) is connected to the concave fitting portion (not shown) of the connection member 131. The through-hole 131b formed in the upper surface (upper surface in FIG. 42) of the concave fitting portion, the concave fitting portion (not shown) of the connection member 133 and the upper surface (upper surface in FIG. 42) of the concave fitting portion. The through hole 133b is threaded into a nut (not shown) fitted in the back side recessed fitting portion 71c of the battery box unit fixing plate 127d. Further, the screw heads (not shown) are accommodated in the recesses (not shown) of the connection members 131 and 133.

Next, the operation of the keeper robot 117 will be described with reference to FIG.
The keeper robot 117 can be moved in all horizontal directions (in all directions parallel to the paper surface in FIG. 41) by the wheel units 121a, 121b, 121c, and 121d. Each of the wheel units 121a, 121b, 121c, and 121d includes omnidirectional wheels 31, and the keeper robot 117 is driven by four omnidirectional wheels 31.

  For example, when the keeper robot 117 is moved forward (moved upward in FIG. 41), the wheel units 121a, 121b, 121c, and 121d are controlled as follows. In this case, the omnidirectional wheel 31 of the wheel unit 121a is rotated from the upper right to the lower left in FIG. 41, and the omnidirectional wheel 31 of the wheel unit 121b is rotated from the upper left to the lower right in FIG. The omnidirectional wheel 31 of the wheel unit 121c is rotated in the direction from the upper left to the lower right in FIG. 41, and the omnidirectional wheel 31 of the wheel unit 121d is rotated in the direction from the upper right to the lower left in FIG.

  For example, when the keeper robot 117 is moved backward (moved downward in FIG. 41), the wheel units 121a, 121b, 121c, and 121d are controlled as follows. In this case, the omnidirectional wheel 31 of the wheel unit 121a is rotated in the direction from the lower left to the upper right in FIG. 41, and the omnidirectional wheel 31 of the wheel unit 121b is rotated in the direction from the lower right to the upper left in FIG. The omnidirectional wheel 31 of the wheel unit 121c is rotated in the direction from the lower right to the upper left in FIG. 41, and the omnidirectional wheel 31 of the wheel unit 121d is rotated in the direction from the lower left to the upper right in FIG.

  For example, when the keeper robot 117 is moved in the right direction (moved in the left direction in FIG. 41), the wheel units 121a, 121b, 121c, and 121d are controlled as follows. In this case, the omnidirectional wheel 31 of the wheel unit 121a is rotated in the direction from the lower left to the upper right in FIG. 41, the omnidirectional wheel 31 of the wheel unit 121b is rotated in the direction from the upper right to the lower left in FIG. The omnidirectional wheel 31 of the wheel unit 121c is rotated in the direction from the upper right to the lower left in FIG. 41, and the omnidirectional wheel 31 of the wheel unit 121d is rotated in the direction from the lower left to the upper right in FIG.

  For example, when the keeper robot 117 is moved leftward (moved leftward in FIG. 41), the wheel units 121a, 121b, 121c, and 121d are controlled as follows. In this case, the omnidirectional wheel 31 of the wheel unit 121a is rotated in the direction from the upper right to the lower left in FIG. 41, and the omnidirectional wheel 31 of the wheel unit 121b is rotated in the direction from the lower right to the upper left in FIG. The omnidirectional wheel 31 of the wheel unit 121c is rotated in the direction from the lower right to the upper left in FIG. 41, and the omnidirectional wheel 31 of the wheel unit 121d is rotated in the direction from the upper right to the lower left in FIG.

  Further, for example, when the keeper robot 117 is moved in the front right direction (moved in the upper left direction in FIG. 41), the wheel units 121a, 121b, 121c, and 121d are controlled as follows. In this case, the omnidirectional wheels 31 and 31 of the wheel unit 121b and the wheel unit 121c are rotated in the direction from the upper left to the lower right in FIG. 41, and the omnidirectional wheels 31 of the wheel unit 121a and the wheel unit 121d are 31 is stopped.

  For example, when the keeper robot 117 is moved in the left front direction (moved in the upper right direction in FIG. 41), the wheel units 121a, 121b, 121c, and 121d are controlled as follows. In this case, the omnidirectional wheels 31, 31 of the wheel unit 121a and the wheel unit 121d are rotated in the direction from the upper right to the lower left in FIG. 41, and the omnidirectional wheels 31, 31 of the wheel unit 121b and the wheel unit 121c are rotated. Stop.

  Further, for example, when the keeper robot 117 is moved in the rear left direction (moved in the lower right direction in FIG. 41), the wheel units 121a, 121b, 121c, and 121d are controlled as follows. In this case, the omnidirectional wheels 31 and 31 of the wheel unit 121b and the wheel unit 121c are rotated in the direction from the lower right to the upper left in FIG. 41, and the omnidirectional wheels 31 of the wheel unit 121a and the wheel unit 121d are rotated. 31 is stopped.

  Further, for example, when the keeper robot 117 is moved rearward to the right (moved in the lower left direction in FIG. 41), the wheel units 121a, 121b, 121c, and 121d are controlled as follows. In this case, the omnidirectional wheels 31, 31 of the wheel unit 121a and the wheel unit 121d are rotated in the direction from the lower left to the upper right in FIG. 41, and the omnidirectional wheels 31, 31 of the wheel unit 121b and the wheel unit 121c are rotated. Stop.

  For example, when the keeper robot 117 is turned rightward (rotated counterclockwise in FIG. 41), the wheel units 121a, 121b, 121c, and 121d are controlled as follows. In this case, the omnidirectional wheel 31 of the wheel unit 121a is rotated in the direction from the lower left to the upper right in FIG. 41, and the omnidirectional wheel 31 of the wheel unit 121b is rotated in the direction from the upper left to the lower right in FIG. The omnidirectional wheel 31 of the wheel unit 121c is rotated in the direction from the lower right to the upper left in FIG. 41, and the omnidirectional wheel 31 of the wheel unit 121d is rotated in the direction from the upper right to the lower left in FIG.

  For example, when the keeper robot 117 is turned leftward (rotated clockwise in FIG. 41), the wheel units 121a, 121b, 121c, and 121d are controlled as follows. In this case, the omnidirectional wheel 31 of the wheel unit 121a is rotated in the direction from the upper right to the lower left in FIG. 41, and the omnidirectional wheel 31 of the wheel unit 121b is rotated in the direction from the lower right to the upper left in FIG. The omnidirectional wheel 31 of the wheel unit 121c is rotated in the direction from the upper left to the lower right in FIG. 41, and the omnidirectional wheel 31 of the wheel unit 121d is rotated in the direction from the upper right to the lower left in FIG.

Further, by controlling the rotational speed and the rotational direction of the omnidirectional wheel 31 of the wheel units 121a, 121b, 121c, 121d, respectively, the eight directions described above (front, rear, right, left, right front, left front, right rear, It is possible to move freely in all directions as well as (left rear).
Each roller 41 of the omnidirectional wheel 31 is rotatable in a direction orthogonal to the wheel body 39. Therefore, even when the rotation direction of the omnidirectional wheel 31 does not coincide with the traveling direction of the keeper robot 117, the rotation of the roller 41 causes the interaction between the installation surface (not shown) and the omnidirectional wheel 31. The force can be appropriately released, and the keeper robot 117 can be moved in any direction.

In this way, the keeper robot 117 moves and can also urge and move the ball, which obstructs the progression of the ball (not shown).
In addition, for example, when a kick operation mechanism (not shown) that can perform the operation of kicking out the ball is attached to the operation unit 123, the operation of kicking out the ball is also performed.

Next, the effect of the keeper robot 117 according to the present embodiment will be described.
The keeper robot 117 is configured using the above-described device assembly plates 69 and 71, the gear box 23 with the nut 37 installed therein, and the like, and is easy to assemble and disassemble. Can be repeated.
The keeper robot 117 is driven by wheel units 121a, 121b, 121c, and 121d each having an omnidirectional wheel 31. Therefore, by controlling the rotational speed and direction of the omnidirectional wheel 31 of each wheel unit, Can be easily moved in any direction.

Next, with reference to FIG. 43, the markers of the striker robots 1a, 1b, 1c and 1d and the keeper robots 117a and 117b used in the soccer game system 200 in the present embodiment will be described.
As described above, the striker robots 1a, 1b, 1c, and 1d and the keeper robots 117a and 117b are provided with markers by the color panel 7a and the like, and the markers are processed by image processing and position conversion processing of the personal computer 213. The arrangement and combination of colors of the color panel 7a and the like constituting the color panel 7a are specified and converted into a robot ID. In the processing in the personal computer 213, the striker robots 1a, 1b, 1c, and 1d and the keeper robots 117a and 117b are identified by the robot ID.

As shown in FIGS. 43 (a) to 43 (f), the marker is provided with a color panel 7a and the like.
First, FIG. 43A shows the marker 300 of the team A keeper robot 117a. The marker 300 includes a large main marker 300a formed by the color panels 7c and 7d adjacent to each other on the rear side (lower side in FIG. 43) and individual color panels 7a that are spaced apart on the front side (upper side in FIG. 43). , 7b and small sub-markers 300b, 300c.
The main marker 300a indicates which team the keeper robot 117a belongs to. The main marker 300a is red, which indicates that it belongs to the team A. The sub-markers 300b and 300c are both of the same color (both blue in this embodiment), and this indicates that the robot is a keeper robot.
The distance between the main marker 300a and the sub marker 300b and the distance between the main marker 300a and the sub marker 300c are set to the same predetermined values, respectively, and the distance between the sub markers 300b and 300c is also a predetermined distance. Is set to a value.

As for the striker robot 1a, as shown in FIG. 43B, the main marker 300a is the same as the keeper robot 117a, but the sub markers 300b and 300c are different colors, the sub marker 300b is blue, and the sub marker 300c is green. This indicates that the striker robot 1a is one striker robot of team A.
As for the striker robot 1b, as shown in FIG. 43 (c), the main marker 300a is the same as the keeper robot 117a, but the sub markers 300b and 300c are different colors, the sub marker 300b is green, and the sub marker 300c is blue. This indicates that the striker robot 1b is the other striker robot of the team A.

The above description of the marker is about the marker of the robot belonging to the team A, but the marker of the robot belonging to the team B is also shown in FIGS. 43 (d), (e), and (f). Are set in the same way.
First, FIG. 43D shows the marker 300 of the keeper robot 117b of team B. The main marker 300a of the marker 300 indicates to which team the keeper robot 117b belongs. The main marker 300a is blue, which indicates that it belongs to the team B. The sub-markers 300b and 300c are both of the same color (both red in the case of this embodiment), which indicates a keeper robot.

As for the striker robot 1c, as shown in FIG. 43 (e), the main marker 300a is the same as the keeper robot 117b, but the sub markers 300b and 300c are different colors, the sub marker 300b is red, and the sub marker 300c is green. This indicates that the striker robot 1a is one of team B's striker robots.
For the striker robot 1d, as shown in FIG. 43 (f), the main marker 300a is the same as the keeper robot 117b, but the sub markers 300b and 300c are different colors, the sub marker 300b is green, and the sub marker 300c is red. This indicates that the striker robot 1d is the other striker robot of the team B.
This completes the description of the markers of the striker robots 1a, 1b, 1c, and 1d and the keeper robots 117a and 117b.

Next, with reference to FIG. 44 to FIG. 46, the external configuration of the player-side controllers 205a and 205b used in the soccer game system 200 in the present embodiment will be described.
First, the player-side controllers 205a and 205b have a main body 400. The upper side (upper side in FIG. 44) of the main body 400 is an operation unit 401, and the lower side (lower side in FIG. 44) is a grip unit 403. Yes.

In the operation unit 401, a direction indication dial 405 is rotatably installed. This direction indication dial 405 is connected to, for example, a rotary encoder (not shown) in the main body 400, and is used to instruct a turning operation of the striker robot 1a and the like.
In addition, a throttle lever 407 is rotatably installed on the operation unit 401. The throttle lever 407 is connected to, for example, a variable resistor (not shown) in the main body 400, and is used to indicate the magnitude and direction of acceleration / deceleration of the striker robot 1a and the like.
In addition, a direction correction knob 409 is rotatably installed on the operation unit 401. The direction correction knob 409 is connected to, for example, a variable resistor (not shown) in the main body 400, and is used to instruct correction of a turning operation of the striker robot 1a and the like.
The operation unit 401 is provided with an operation correction knob 411 so as to be rotatable. The operation correction knob 411 is connected to, for example, a variable resistor (not shown) in the main body 400, and is used to instruct correction of an operation command of the striker robot 1a and the like.

The operation unit 401 is provided with an operation button 413. The operation button 413 is for energizing a switch (not shown) in the main body 400 to instruct a ball holding / kick operation of the striker robot 1a and the like.
The operation unit 401 is provided with an action button 415. The action button 415 is a seesaw type button, and is one of two switches (not shown) on the left side of the main body 400 (a left switch (not shown) on the left side in FIG. 45 and a right switch (not shown) on the right side in FIG. 45). Is selectively energized to instruct the keeper robots 117a and 117b to operate according to the operation programs assigned to the two switches.
As shown in FIG. 46, the operation unit 401 is also provided with a power switch 416.
The operation unit 401 is provided with a display unit 417. An LED (not shown), for example, is installed inside the display unit 417, and displays the power state of the player-side controllers 205a and 205b, the state of wireless communication, and the like.

A battery (not shown) is built in the grip part 403.
The above is the description of the external configuration of the player-side controllers 205a and 205b.
The internal configuration of the player side controllers 205a and 205b will be described later.

Next, the internal configuration of the personal computer 213 will be described with reference to FIGS. 47, 48, and 49. FIG. FIG. 47 is a functional block diagram of the personal computer 213.
First, the personal computer 213 is provided with a camera interface 501. The camera interface 501 is connected to the cameras 207a and 207b, and captures image data from the cameras 207a and 207b into the personal computer 213.
The personal computer 213 is provided with an image processing unit 503. The image processing unit 503 processes image data from the cameras 207a and 207b, and detects the ball 204 and markers of each robot by their colors.
The personal computer 213 is provided with a position information conversion processing unit 505. The position information conversion processing unit 505 performs position information conversion processing based on the data processed by the image processing unit 503 to calculate a robot ID, and determines the coordinates of the ball 204 and the coordinates and orientation of each robot. Is to be calculated.

The personal computer 213 is provided with a program processing unit 507. The program processing unit 507 controls each robot.
The term “control” used herein refers to the above-described image data captured by the personal computer 213 from the cameras 207a and 207b and an autonomous program stored in a program table 543 (to be described later) of the personal computer 213. The personal computer 213 performs autonomous control of the striker robots 1b and 1d and the keeper robots 117a and 117b, and the operation program selected from the program table 543 based on an instruction from the player-side controllers 205a and 205b. This is to control the keeper robots 117a and 117b.

  The personal computer 213 is provided with a COM port 509. The COM port 509 is connected to the wireless communication unit 217 and inputs / outputs data to / from the wireless communication unit 217. The personal computer 213 is provided with a reception buffer 511. The reception buffer 511 is for temporarily holding data input from the COM port 509. The personal computer 213 is provided with a transmission buffer 512. This transmission buffer 512 is for temporarily holding data output from the COM port 509.

The personal computer 213 is provided with a remote control processing unit 515. The remote control processing unit 515 determines whether the received data is transmitted from which controller (received data determination processing during main processing of the personal computer 213 described later), the player-side controller 205a, Based on the signal from 205b, a process of notifying the program processing unit 507 whether or not the control based on the operation program of the keeper robots 117a and 117b is performed (an action button process described later) is performed.
The personal computer 213 is provided with a remote command processing unit 516. The remote control command processing unit 516 performs processing for transmitting a signal for stopping the operation by the player side controllers 205a and 205b to the player side controllers 205a and 205b in response to an instruction from the referee command processing unit 519 described later. .

  In addition, the personal computer 213 is provided with a referee command determination processing unit 517. The referee instruction determination processing unit 517 determines whether or not the data in the reception buffer 511 includes a signal (referee signal) from the referee controller 211. The personal computer 213 is provided with a referee command processing unit 519. Based on the signal from the referee controller 211, the referee command processing unit 519 instructs to stop the operation by the player-side controllers 205a and 205b, and stops the striker robots 1b and 1d and the keeper robots 117a and 117b. Instructions for score addition / subtraction, instructions for increasing / decreasing the game time, and the like.

  The personal computer 213 is provided with a COM port 523. The COM port 523 is connected to the wireless communication unit 215, and outputs data to the wireless communication unit 215. The personal computer 213 is provided with a transmission buffer 525. The transmission buffer 525 is for temporarily holding data output from the program processing unit 507, the remote control processing unit 515, and the referee command processing unit 519 via the COM port 523.

  The personal computer 213 is provided with a time management unit 527. The time management unit 527 is provided with a clock (not shown), and manages the remaining time of the soccer game. The personal computer 213 is provided with a score management unit 529. The score management unit 529 performs processing such as addition / subtraction of scores in response to an instruction from the referee command processing unit 519.

  The personal computer 213 is provided with a display device processing unit 531. The display device processing unit 531 generates data to be output to the display device 209 according to instructions from the time management unit 527 and the score management unit 529. The personal computer 213 is provided with a display device interface 533. The display device interface 533 is connected to the display device 209, and outputs data to the display device 209.

  The personal computer 213 is provided with a fixed data storage unit 535. The fixed data storage unit 535 stores various data used for processing in the image processing unit 503, the position information conversion processing unit 505, the program processing unit 507, and the remote control / autonomous discrimination processing unit 513 described above.

  The fixed data storage unit 535 is provided with an image processing parameter storage unit 537. The image processing parameter storage unit 537 stores data used in the image processing unit 503. As shown in FIG. 48, the data stored in the image processing parameter storage unit 537 is a ball that is the hue, saturation, and lightness (hereinafter referred to as HSV value) of the pixel identified as the ball 204 in the image processing unit 503. HSV value 537a, HSV value 537b, Typ2HSV value 537c, Typ3HSV value 537d, which is the HSV value of the pixel identified as the color of each color panel, ball size 537e, which is the size of the set of pixels identified as the ball, main marker A main marker size 537f which is a size of a set of pixels identified as 300a, a sub marker size 537g which is a size of a set of pixels identified as sub-markers 300b and 300c, the main marker 300a and the sub-marker 300b, Distance between 300c There Meinsabu distance 537H, the sub marker 300b, the sub is the distance between 300c - has a sub-distance 537I.

  The fixed data storage unit 535 is provided with a coordinate conversion table 539. The coordinate conversion table 539 stores data used in the position information conversion processing unit 505. Specifically, a ball 204 on image data (described later) detected by the image processing unit 503 and data for converting the coordinates of each robot as coordinates on the field 201 are stored.

  The fixed data storage unit 535 is provided with a game management parameter storage unit 541. The game management parameter storage unit 541 stores data used in the program processing unit 507 and the remote control processing unit 515. That is, in the game management parameter storage unit 541, data indicating which striker robots 1a, 1b, 1c, 1d and keeper robots 117a, 117b belong to the A team and the B team, and the player side controllers 205a, 205b. Data such as a list of robot IDs of the robots to be controlled is stored. In the case of the present embodiment, the striker robots 1a and 1c are directly controlled by the player-side controllers 205a and 205b, and the striker robots 1b and 1d are controlled based on an autonomous program by the personal computer 213, and the keeper robot 117a, For 117b, autonomous control based on an autonomous program by the personal computer 213 is performed, and when there is an instruction from the player-side controllers 205a and 205b, control based on an operation program stored in the program table 543 is performed. Is set to

  The fixed data storage unit 535 is provided with a program table 543. As shown in FIG. 49, the program table 543 includes an autonomous program storage unit 1001, an operation program storage unit 1003, a team A user program storage unit 1005, and a team B user program storage unit 1007.

The autonomous program storage unit 1001 stores a plurality of autonomous programs used in the program processing unit 507. By this autonomous program, autonomous control of the striker robots 1b and 1d and the keeper robots 117a and 117b is performed. That is, the autonomous program storage unit 1001 includes a plurality of folders 1001a, 1001b, 1001c, and --1001n, and predetermined autonomous programs are stored in these folders 1001a, 1001b, 1001c, and --1001n, respectively. .
The QR code (registered trademark) 927 of the autonomous program selection card 919 already described stores information for specifying the folders 1001a, 1001b, 1001c, and --1001n.

The operation program storage unit 1003 stores a plurality of operation programs used in the program processing unit 507. That is, the operation program storage unit 1003 includes a plurality of folders 1003a, 1003b, 1003c, and --1003n, and predetermined operation programs are stored in these folders 1003a, 1003b, 1003c, and --1003n, respectively. .
Note that information for specifying the folders 1003a, 1003b, 1003c, and --1003n is stored in the QR code (registered trademark) 933a and 933b of the operation program selection card 921 described above.
The operation program controls the keeper robots 117a and 117b based on instructions from the player-side controllers 205a and 205b.

  The A team user program storage unit 1005 stores a plurality of autonomous programs and operation programs (A team user program) created by the user. That is, the A team user program storage unit 1005 includes a plurality of folders 1005a, 1005b, 1005c, and --1005n, and these folders 1005a, 1005b, 1005c, and --1005n each have predetermined autonomous programs and operations. The program is stored.

  The B team user program storage unit 1007 stores a plurality of autonomous programs and operation programs (B team user programs) created by the user. That is, the B team user program storage unit 1007 has a plurality of folders 1007a, 1007b, 1007c, --1007n, and these folders 1007a, 1007b, 1007c, and --1007n each have predetermined autonomous programs and operations. The program is stored.

The autonomous programs and operation programs created by these users can be used instead of the autonomous programs in the autonomous program storage unit 1001 and the operation programs in the operation program storage unit 1003.
The team A user program is read from the team A storage medium reader 913, and the team B user program is read from the team B storage medium reader 917.
In addition, there is a user program selection card (not shown) that has the same configuration as the autonomous program selection card 919 and the operation program selection card 921 described above, and a predetermined autonomous program created by the user by using these user program selection cards And an operation program can be selected.

The personal computer 213 includes a team A card interface unit 1009 and a team B card interface unit 1011.
The A team card interface 911 and the A team storage medium reader 913 are connected to the A team card interface unit 1009. The B team card interface unit 1011 is connected to the B team card installation base 915 and the B team storage medium reader 917 described above.

  The personal computer 213 is provided with a card recognition / discrimination processing unit 1013. The card recognition / discrimination processing unit 1013 uses the QR code (registration) described in the autonomous program selection card 919 or the operation program selection card 921 read by the A team card setting table 911 or the B team card setting table 915. Trademark) is used to identify information on the folder in which the autonomous program and the operation program are stored, and determine whether or not a predetermined autonomous program or operation program is stored in the folder.

  Based on the QR code (registered trademark) information of the autonomous program selection card 919 set on the A team card installation table 911, the autonomous program used in the control of the keeper robot 117a on the A team side is stored in the autonomous program storage. Part 1001. Also, the autonomous program used in the control of the keeper robot 117b on the B team side is stored in the autonomous program storage by the QR code (registered trademark) information of the autonomous program selection card 919 set on the B team card installation table 915. Part 1001.

  The left switch operation program used in the control of the keeper robot 117a on the A team side based on the QR code (registered trademark) information of the operation program selection card 921 set on the A team card installation base 911. An operation program for the right switch is selected from the operation program storage unit 1003. Further, depending on the contents of the operation program selection card 921 set on the B team card installation base 915, the left switch operation program and the right switch operation program used in the control of the B team side keeper robot 117b are provided. It is selected from the operation program storage unit 1003.

Also, the A team user program is read from the storage medium (not shown) installed in the A team storage medium reader 913 into the A team user program storage unit 1005 and installed in the B team storage medium reader 917. The B team user program is read into the B team user program storage unit 1007 from a storage medium (not shown).
The details of the internal configuration of the personal computer 213 have been described above.

Next, the internal configuration of the player-side controllers 205a and 205b will be described with reference to FIG.
First, the player-side controllers 205a and 205b are provided with an information processing device 601 such as a microcomputer. The information processing apparatus 601 is provided with a movement direction correction table 603 and an operation command conversion coefficient table 605. The moving direction correction table 603 and the operation command conversion coefficient table 605 store data used when correcting various input data. The data stored in the movement direction correction table 603 and the operation command conversion coefficient table 605 is based on inputs from the direction correction knob 409 and the operation correction knob 411, as will be described later.

The player controllers 205a and 205b are provided with a moving direction instruction input circuit 607. The movement direction instruction input circuit 607 receives data from a rotary encoder (not shown) or a variable resistor by operating the direction instruction dial 405 or the throttle lever 407, and these data are used for processing in the information processing apparatus 601. It is converted into a format and output.
The player-side controllers 205a and 205b are provided with a moving direction correcting input circuit 609. The movement direction correction input circuit 609 receives data from a variable resistor (not shown) from the direction correction knob 409, converts the data into a format used for processing in the information processing apparatus 601, and outputs the converted data. . The data output from the moving direction correction input circuit 609 is stored in the moving direction correction table 603.

The player controllers 205a and 205b are provided with an additional input circuit 611. The additional input circuit 611 receives data from a switch corresponding to the operation button 413 and data from a switch (not shown) corresponding to the action button 415, and converts the data into a format used for processing in the information processing apparatus 601. Convert and output.
The player-side controllers 205a and 205b are provided with an operation command conversion coefficient input circuit 613. The operation command conversion coefficient input circuit 613 receives data from a variable resistor (not shown) by the operation correction knob 411, converts the data into a format used for processing in the information processing apparatus 601, and outputs the converted data. is there. The data output from the operation command conversion coefficient input circuit 613 is stored in the operation command conversion coefficient table 605.

  The information processing apparatus 601 is provided with a communication processing unit 1017. The communication processing unit 1017 is provided with a robot communication processing unit 1019 and a PC (personal computer) communication processing unit 1021. In the robot communication processing unit 1019, transmission data to the striker robots 1a and 1c is created based on the operations of the player-side controllers 205a and 205b. Further, in the PC (personal computer) communication processing unit 1021, a process for a referee command transmission data to be described later transmitted from the personal computer 213 to the player-side controllers 205 a and 205 b, and when an action button 415 is pressed. The controller information transmitted to the personal computer 213 is processed.

The player controllers 205a and 205b are provided with a wireless communication circuit 615. The wireless communication circuit 615 transmits the output from the information processing apparatus 601 to the wireless communication unit 217 connected to the personal computer 213 by wireless communication.
The player controllers 205a and 205b are provided with a display circuit 617. The display circuit 617 performs display on the display unit 417 according to an instruction from the information processing apparatus 601.
The player controllers 205a and 205b are provided with a power supply circuit 619. The power supply circuit 619 supplies power from the battery (not shown) to the information processing apparatus 601 and the like.
The above is the description of the internal configuration of the player-side controllers 205a and 205b.

Next, with reference to FIG. 51 and FIG. 52, the configuration of the striker robots 1a, 1b, 1c, and 1d on the substrate 19 will be described. FIG. 51 is a functional block diagram of the striker robots 1a, 1b, 1c, and 1d.
First, the CPU 701 is mounted on the substrate 19 of the striker robot 1a or the like. The CPU 701 is provided with a communication processing unit 703. The communication processing unit 703 performs management of data input / output by wireless communication or temporary storage by a buffer via a wireless communication circuit 705 provided on a wireless communication board (not shown).

  The CPU 701 is provided with an input processing unit 705. The input processing unit 705 is connected to the sensor switch 113a of the sensor substrate 113, and the input from the sensor switch 113a is processed.

The CPU 701 is provided with a right motor drive processing unit 707. The right motor drive processing unit 707 performs PWM (Pulse Width Modulation, pulse width modulation) control of the motor 29 of the wheel drive unit 11 a via a motor drive circuit 709 provided on the substrate 19.
Further, the CPU 701 is provided with a left motor drive processing unit 711. The right motor drive processing unit 711 performs PWM control of the motor 29 of the wheel drive unit 11 b via the motor drive circuit 713 provided on the substrate 19.
Further, the CPU 701 is provided with a cam motor drive processing unit 715. The cam motor drive processing unit 715 performs PWM control of the motor 59 of the cam drive unit 13 via a motor drive circuit 717 provided on the substrate 19.

The CPU 701 is provided with LED lighting processing units 719a, 719b, and 719c. The LED lighting processing units 719a, 719b, and 719c control the turning on / off of the LEDs 723a, 723b, and 723c provided on the substrate 19 via the LED driving circuits 721a, 721b, and 721c provided on the substrate 19. To do.
Further, the CPU 701 is provided with a power supply monitoring processing unit 725. The power supply monitoring processing unit 725 monitors the voltage of the battery 68h in the battery box unit 15 via the power supply circuit 727 provided on the substrate 19, and supplies power to the motor drive circuits 709, 713, and 717. Is to control the supply of.
In addition, a battery connector 729 is provided on the substrate 19. Via the battery connector 729, the electrodes 68c and 68d of the battery box unit 15 and the power supply circuit 727 are connected.

Also, the robot control data 706 of the striker robots 1a, 1b, 1c, and 1d input from the personal computer 213 to the CPU 701 through the wireless communication circuit 705 is as shown in FIG. . The robot control data 706 is 6-byte data composed of 6 1-byte data, and the first byte (the leftmost in FIG. 52) is command data 706a, which indicates the type of control data. is there.
The data of the second byte is robot ID data 706b, which indicates which robot is controlled by this robot control data 706. The robot ID matches the robot ID converted from the marker 300 by image processing.
The third byte data is left motor drive command data 706c. The left 6 bits of the left motor drive command data 706c are a PWM (Pulse Width Modulation) pulse value 706d used for controlling the motor 29 of the wheel unit 11b, and the remaining 2 bits are used to turn on / off the LED 723b. LED instruction data 706e.

The fourth byte data is right motor drive command data 706f. The left 6 bits of the right motor drive command data 706g are a PWM command value 706g used for controlling the motor 29 of the wheel unit 11a, and the remaining 2 bits are LED instruction data 706h for instructing to turn on / off the LED 723c. .
The data of the fifth byte is cam drive command data 706i. The left 6 bits of the cam drive command data 706i are the PWM command value 706j used for controlling the motor 59 of the cam unit 13, and the remaining 2 bits are the operation instruction data 706k, which rotates the motor 59 of the cam drive unit 13. This is data on an instruction on whether or not to perform the ball holding operation or kick operation when the operation button 413 is pressed.
The 6th byte data is CRC (Cyclic Redundancy Check) data 706m, which is used for error check of the robot control data 706.
The above is the description of the configuration on the substrate 19 of the striker robots 1a, 1b, 1c, and 1d.

Next, with reference to FIG. 53 and FIG. 54, the configuration of the keeper robots 117a and 117b on the substrates 129a and 129b will be described. FIG. 53 is a functional block diagram of the keeper robots 117a and 117b.
First, the CPU 801 is mounted on the substrate 129a or the substrate 129b of the keeper robot 117a or the like. The CPU 801 is similar to the CPU 701 of the striker robots 1a, 1b, 1c, and 1d described above, the communication processing unit 803, the right front motor drive processing unit 805, the left front motor drive processing unit 807, the right rear motor drive processing unit 809, A motor drive processing unit 811, LED lighting processing units 813 a, 813 b and 813 c, and a power supply monitoring processing unit 815 are provided.
The communication processing unit 803 performs management of data input / output by wireless communication or temporary storage by a buffer via a wireless communication circuit 816 provided on a wireless communication board (not shown).
Since the keeper robots 117a and 117b are provided with the operation unit 123, it may be possible to provide a motor drive processing unit for controlling the motor 59 of the operation unit 123.

The right front motor drive processing unit 805 performs PWM (Pulse Width Modulation, pulse width modulation) control of the motor 29 of the wheel unit 121a via the motor drive circuit 817 provided on the substrate 129a or 129b.
The left front motor drive processing unit 807 performs PWM control of the motor 29 of the wheel unit 121b via the motor drive circuit 819 provided on the board 129a or 129b.
The left front motor drive processing unit 809 performs PWM control of the motor 29 of the wheel unit 121c via the motor drive circuit 821 provided on the board 129a or 129b.
The left front motor drive processing unit 811 performs PWM control of the motor 29 of the wheel unit 121b via the motor drive circuit 823 provided on the board 129a or the board 129b.

The LED lighting processing unit 813a controls turning on / off of the LED 827a provided on the substrate 129a or the substrate 129b via the LED driving circuit 825a provided on the substrate 129a or the substrate 129b.
The LED lighting processing unit 813b controls lighting / extinguishing of the LED 827b provided on the substrate 129a or the substrate 129b via the LED driving circuit 825b provided on the substrate 129a or the substrate 129b.
The LED lighting processing unit 813c controls lighting / extinguishing of the LED 827c provided on the substrate 129a or 129b via the LED driving circuit 825c provided on the substrate 129a or 129b.
The power supply monitoring processing unit 815 monitors the voltage of the battery 68h in the battery box unit 15 via the power supply circuit 829 provided on the substrate 129a or 129b, and the motor drive circuits 805 and 807. , 809 and 811 are controlled.
Further, a battery connector 831 is provided on the substrate 129a or the substrate 129b. Through the battery connector 831, the electrodes 68 c and 68 d of the battery box unit 15 and the power supply circuit 829 are connected.

Also, the robot control data 833 of the keeper robots 117a and 117b input from the personal computer 213 to the CPU 801 via the wireless communication circuit 816 is also input to the striker robot 1a and the like as shown in FIG. The robot control data 706 is substantially the same.
The robot control data 833 has command data 833a at the first byte and robot ID data 833b at the second byte. The command data 833a and robot ID data 833b are the same as the command data 706a and robot ID data 706b of the robot control data 706 described above.

The third byte is left front motor drive command data 833c, and the left front motor drive command data 833c is a PWM command value 833d for controlling the motor 29 of the wheel unit 121b by PWM (Pulse Width Modulation, pulse width modulation). And LED instruction data 833e for controlling the LED 827b. The left front motor drive command data 833c is the same as the left motor drive command data 706c of the robot control data 706 described above.
The fourth byte is front right motor drive command data 833f. This front right motor drive command data 833f is a PWM command value 833g for PWM control of the motor 29 of the wheel unit 121a and an LED for controlling the LED 827c. It consists of instruction data 833h. This right front motor drive command data 833f is also the same as the left motor drive command data 706c of the robot control data 706 described above.

The fifth byte is left rear motor drive command data 833i. This right front motor drive command data 833i is used to control the PWM command value 833j for PWM control of the motor 29 of the wheel unit 121d and the LED 827b. LED instruction data 833k. This right front motor drive command data 833i is also the same as the left motor drive command data 706c of the robot control data 706 described above.
The sixth byte is the right rear motor drive command data 833m. This right rear motor drive command data 833m is used to control the PWM command value 833n and the LED 827c for PWM control of the motor 29 of the wheel unit 121c. LED instruction data 833p. This right front motor drive command data 833m is also the same as the left motor drive command data 706c of the robot control data 706 described above.

The seventh byte is CRC (Cyclic Redundancy Check) data 833r, which is used for error check of the robot control data 833.
The above is the description of the configuration on the substrates 129a and 129b of the keeper robots 117a and 117b.

Next, processing performed by the personal computer 213 will be described with reference to FIGS. 55 to 62.
First, main processing performed by the personal computer 213 will be described with reference to FIG.
Step S1 in the flowchart of FIG. 55 is a step for performing image processing. In this step S1, data captured by the cameras 207a and 207b are processed to detect the coordinates of the ball 204 and the coordinates and orientation of each robot (striker robots 1a, 1b, 1c and 1d, keeper robots 117a and 117b). . The processing in step S1 is performed by the image processing unit 503 and the position information conversion processing unit 505. Details of the image processing will be described later.
Next, the process proceeds to step S2.

The next step S2 is a step for performing received data discrimination processing. In the received data discrimination process in step S2, the data received by the personal computer 213 is transmitted from the player A controller 205a on the team A side or transmitted from the player controller 205b on the team B side. It is discriminate | determined whether it is a thing or the thing transmitted from the controller 211 for judgment. This process is performed in the remote control processing unit 515.
Next, the process proceeds to step S3a.

  Next, in step S3a, it is determined whether or not each robot (striker robot 1a, 1b, 1c, 1d, keeper robot 117a, 117b) is manually operated by the player side controllers 205a, 205b. In the determination process in step S3a, data in the game management parameter storage unit 541 is used. That is, the process of step S3a is performed based on the list of robot IDs of the robots controlled by the player-side controllers 205a and 205b in the game management parameter storage unit 541. This processing is performed in the program processing unit 507.

The robots manually operated by the player-side controllers 205a and 205b (in this embodiment, the striker robots 1a and 1c) are directly controlled by the player-side controllers 205a and 205b. Is not done. For robots that perform autonomous control based on the autonomous program (in this embodiment, the striker robots 1b and 1d and the keeper robots 117a and 117b), the process proceeds to step S3c.
The keeper robots 117a and 117b are in principle subject to autonomous control based on the autonomous program. However, if the action buttons 415 of the player-side controllers 205a and 205b are exceptionally pressed and operated, the operation program It becomes the object of control by.

When the process proceeds from step S3a to step S3c, the program processing unit 507 performs robot control data generation processing based on the autonomous program / operation program. In this process, robot control data 706 for the striker robots 1b and 1d is generated based on the autonomous program. Further, robot control data 833 for the keeper robots 117a and 117b is generated based on the autonomous program / operation program. The robot IDs 706b and 833b of the robot control data 706 and 833 generated here use the robot IDs of the robots that are not the operation targets of the player-side controllers 205a and 205b.
Details of the robot control data generation processing based on the autonomous program / operation program will be described later.
When the generation of the robot control data 706 and the robot control data 833 is completed, the process proceeds to step S4.

In step S4, a referee process is performed. Details of the referee process will be described later. When the referee process ends, the process proceeds to step S5. In the next step S5, transmission data output processing is performed. The transmission data here includes both data transmitted by wireless communication such as the robot control data 706 and 833 and data transmitted by wired communication such as score data generated by a referee process described later. It is. In the transmission process of the robot control data 706 and 833, the robot IDs 706b and 833b are determined, and the robot control data 706 and 833 having the robot ID of the robot whose action is prohibited in the referee process described later is transmitted. This is not performed, and only the robot control data 706 and 833 having other robot IDs are transmitted.
Thereafter, the process proceeds to step S6.

In step S6, it is determined whether or not to end the soccer game system 200. If the process ends, the process ends. If the process continues, the process proceeds to step S1 again.
The above is the description of the main processing performed by the personal computer 213.

Next, card processing performed by the card recognition / discrimination processing unit 1013 and the program discrimination processing unit 1015 of the personal computer 213 will be described with reference to FIG.
The card processing is based on the contents of the autonomous program selection card 919 and the operation program selection card 921 read by the team A card installation table 911 and the team B card installation table 915, and the keeper robots 117a and 117b from the program table 543. The process which selects the autonomous program and operation program used for control of this, and the process which produces the control signal based on the selected autonomous program and operation program.

First, in step S80, card information acquisition processing is performed. Thereby, the QR code (registered trademark) information of the autonomous program selection card 919 and the QR code (registered trademark) of the operation program selection card 921 set on the A team card installation table 911 and the B team card installation table 915 are stored. The content is recognized.
In the case of the present embodiment, for example, one autonomous program selection card 919 and one operation program selection card 921 are provided for one A team card installation table 911 (B team card installation table 915). Two sheets are set.
Next, the process proceeds to step S81.

In step S81, a keeper program file path generation process is performed. This processing is performed by file path, that is, information on the folder specified by the QR code (registered trademark) of the autonomous program selection card 919, information on the folder specified by the QR code (registered trademark) of the operation program selection card 921. Is generated.
In this embodiment, one autonomous program file path and two operation program file paths are generated for each team.
Next, the process proceeds to step S82.

In step S82, it is determined whether an autonomous program or an operation program exists in the specified folder in the program table 543. If an autonomous program or an operation program exists in the specified folder, the process proceeds to step S83.
If there is no autonomous program or operation program in the specified folder, the process ends.

In step S83, a program reading process is performed. In this program reading process, a predetermined autonomous program is selected and read from the autonomous program storage unit 1001 of the program table 543, and a predetermined left switch operation program and right switch are selected from the operation program storage unit 1003 of the program table 543. Operation program is selected and loaded.
Next, the process proceeds to step S84.

  In step S84, it is determined whether or not it is notified that the action button 415 of the player-side controllers 205a and 205b is pressed by action button processing described later. If it is notified that the action button 415 is pressed, the process proceeds to step S85.

  In step S85, it is determined whether or not a left switch (not shown) is pressed by the action button 415. If the left switch is pressed, the process proceeds to step S86.

  In step S86, left switch operation program data transfer processing is performed. By the left switch operation program data transfer process, the read left switch operation program is transferred to the program processing unit 507.

  If it is determined in step S85 that the left switch has not been pressed, the process proceeds to step S87. In step S87, right switch operation program data transfer processing is performed. The read right switch operation program is transferred to the program processing unit 507 by the right switch operation program data transfer process.

If it is determined in step S84 that the action button 415 has not been pressed, the process proceeds to step S88. In step S88, an autonomous program data transfer process is performed. By this autonomous program data transfer process, the read autonomous program is transferred to the program processing unit 507. That is, in this embodiment, when the action button 415 is not pressed, the autonomous control by the autonomous program is always executed, and when the action button 415 is pressed. Is automatically executed by the corresponding operation program.
The above is the description of the card processing.

Thereafter, the program processing unit 507 generates robot control data 833 for the keeper robots 117a and 117b based on the transferred autonomous program and operation program. The generation process of the robot control data 833 is performed in step S3c of the main process described above.
The generated robot control data 833 is transmitted toward the keeper robots 117a and 117b by the transmission data output process in step S5 of the main process described above.

The card process is repeated.
Further, by this card processing, by exchanging the autonomous program selection card 919 and the operation program selection card 921 set on the A team card installation table 911 and the B team card installation table 915, even during the game, The autonomous program and the operation program to be used are changed.
Further, the processing of step S80 is performed by the card recognition / discrimination processing unit 1013, and the processing of steps S81 to S88 is performed by the program discrimination processing unit 1015.

Next, the image processing in step S1 will be described with reference to FIGS.
In the image processing, step S7 is first executed. In step S7, image data used for image processing is acquired from data captured by the cameras 207a and 207b.
FIG. 62 shows a field 201 imaged by the cameras 207a and 207b. The range imaged by the camera 207a is the range indicated by reference numeral 901a in FIG. 62 (the range indicated by the solid line in FIG. 62), and the range imaged by the camera 207b is the range indicated by reference numeral 901b in FIG. 62 is a range indicated by a broken line in FIG. As shown in FIG. 62, the range 901a and the range 901b overlap in the vicinity of the center in FIG. Therefore, when acquiring image data to be used for image processing, the overlapping range is removed from either the imaging data in the range 901a or the imaging data in the range 901b, and then the imaging data in the range 901a and the above range are acquired. 901b image data is connected.
Next, the process proceeds to step S8.

In step S8, a labeling process using HSV (hue, saturation, brightness) values is performed. Thereby, among the pixels of the image data, those corresponding to the ball HSV value 537a, the Typ1HSV value 537b, the Typ2HSV value 537c, and the Typ3HSV value 537d stored in the image processing parameter storage unit 537 of the personal computer 213 are adjacent to each other. A label is attached to what is to be performed, and a discrimination processing matrix used in later processing is created.
Next, the process proceeds to step S9.

In step S9, a main marker discrimination process is performed. In this determination processing, based on the main marker size 537f stored in the image processing parameter storage unit 537 of the personal computer 213, it corresponds to the Typ1HSV value 537b, the Typ2HSV value 537c, or the Typ3HSV value 537d in the determination processing matrix. A labeled area of a predetermined area is discriminated, and the label and the center coordinates on the discrimination processing matrix are obtained. This is the coordinates and color on the main marker discrimination processing matrix.
Next, the process proceeds to step S10.

In step S10, sub-marker discrimination processing is performed. In this determination processing, based on the sub marker size 537g stored in the image processing parameter storage unit 537 of the personal computer 213, it corresponds to the Typ1HSV value 537b, the Typ2HSV value 537c, or the Typ3HSV value 537d in the determination processing matrix. A labeled area having a predetermined area is discriminated, and the label and center coordinates on the discrimination processing matrix are obtained. This is the coordinates and color on the sub-marker discrimination processing matrix.
Next, the process proceeds to step S11.

In the next step S11, a ball color discrimination process is performed. In this discrimination processing, a region having a predetermined area labeled according to the ball HSV value 537a in the discrimination processing matrix based on the ball size 537e stored in the image processing parameter storage unit 537 of the personal computer 213 is obtained. It discriminate | determines and obtains the center coordinate on the label and the said matrix for discrimination | determination processes.
Next, the process proceeds to step S12.

In step S12, a robot marker detection process is performed. This robot marker detection process will be described later.
Next, the process proceeds to step S13.

In step S13, ball detection processing is performed. In this process, the center coordinates of the label determined in the above-described ball color determination process in step S11 on the determination processing matrix are converted into the coordinates on the field 201. By this process, the coordinates of the ball 204 on the field 201 are obtained. In this processing, data in the coordinate conversion table 539 is used.
Note that the processing in steps S7 to S11 is performed in the image processing unit 503, and the processing in steps S12 and S13 is performed in the position information conversion processing unit 505.
The above is image processing.

Next, the robot marker detection process in step S12 will be described with reference to FIG.
First, in step S14, a main-sub 1 distance determination process is performed. This process calculates the distance between the main marker and the sub marker from the coordinates on the main marker discrimination processing matrix and the coordinates on the sub marker discrimination processing matrix obtained in the image processing described above. The combination of the main marker and the sub marker is determined such that this distance becomes the main-sub distance 537 h stored in the image processing parameter storage unit 537 of the personal computer 213. The combination of the main marker and the sub marker as described above is a combination of the main marker 300a and the sub marker 300b in the marker 300 shown in FIG.
Next, the process proceeds to step S15.

In step S15, a main-sub 2 distance determination process is performed. This process calculates the distance between the main marker and the sub marker from the coordinates on the main marker discrimination processing matrix and the coordinates on the sub marker discrimination processing matrix obtained in the image processing described above. The combination of the main marker and the sub marker is determined such that this distance becomes the main-sub distance 537 h stored in the image processing parameter storage unit 537 of the personal computer 213. A combination of the main marker and the sub marker in such a combination is a combination of the main marker 300a and the sub marker 300c in the marker 300 shown in FIG.
Next, the process proceeds to step S16.

In step S16, a sub 1-sub 2 distance determination process is performed. In this processing, the distance between the sub-markers is calculated from the coordinates on the discrimination processing matrix of the sub-markers 300b and 300c obtained in the above-described image processing, and this distance is the image processing parameter storage unit 537 of the personal computer 213. The combination of the sub-markers is determined such that the sub-sub distance 537i is stored in the above. A combination of such sub-markers is a combination of the sub-marker 300b and the sub-marker 300c in the marker 300 shown in FIG. That is, since the combination of the main marker 300a and the sub marker 300b is already known in step S14, and the combination of the main marker 300a and the sub marker 300c is already known in step S15, the combination of the sub marker 300b and the sub marker 300c is determined. By determining the combination, the combination of the main marker 300a, the sub marker 300b, and the sub marker 300c constituting the marker 300 of each robot is determined.
Next, the process proceeds to step S17.

In step S17, ID identification processing is performed. In the ID specifying process, the robot ID of the marker 300 detected from the color combination of the main marker 300a, the sub marker 300b, and the sub marker 300c is determined.
Next, the process proceeds to step S18.

  In step S18, position / direction acquisition processing is performed. In the position / direction acquisition processing, the center coordinates of the main marker 300a in each detected marker 300 are set as the coordinates of the corresponding robot, and the positions of the main marker 300a, the sub marker 300b, and the sub marker 300c in the marker 300 are set. The angle of each robot is calculated from the relationship.

Calculation of the angle of each robot will be described with reference to FIGS. 43 and 62. FIG. As shown in FIG. 43, sub-markers 300b and 300c are arranged in front of the main marker 300a (upper side in FIG. 43), and the distance between the sub-markers 300b and 300c is larger than the width of the main marker 300a. Is getting bigger. Therefore, an isosceles triangle 903 as shown in FIG. 43A can be derived from the coordinates of the main marker 300a and the sub markers 300b and 300c. The base of the isosceles triangle 903 is directed to the front side of each robot.
Therefore, if the direction of a straight line connecting the center coordinates of the main marker 300a as shown in FIG. 43 (a) and the midpoint of the base of the isosceles triangle 903 on the field 201 shown in FIG. The orientation of each robot on the field 201 is required.
Further, the coordinates of each robot are converted from coordinates on the discrimination processing matrix to coordinates on the field 201. At that time, data in the coordinate conversion table 539 is used.
The above is the robot marker detection process.

Next, the robot control data generation process based on the autonomous program / operation program in step S3c will be described with reference to FIG. The robot control data generation processing based on the autonomous program / operation program is performed for each of the striker robots 1b and 1d and the keeper robots 117a and 117b, and is performed by the program processing unit 507.
First, in step S20, position information / robot state information acquisition processing is performed. In this process, the robot ID, the coordinates of the current position, the direction, and the operation state (ball holding state, kick state, standby state) are acquired for the striker robots 1b and 1d and the keeper robots 117a and 117b. (In the case of keeper robots 117a and 117b, the operation state is not acquired in this embodiment.)
Next, the process proceeds to step S21.
In the next step S21, an autonomous program / operation program selection process is performed. This process is performed by the autonomous program of the striker robot 1b or 1d used in the game, the autonomous program for the keeper robot 117a or 117b selected by the autonomous program selection card 919, or the keeper robot selected by the operation program selection card 921. The operation program for 117a and 117b is extracted from the program table 543.
Next, the process proceeds to step S22.

In step S22, a target / motion determination process is performed. In this process, the target position and action (ball holding state, kick state, standby state) are determined using the autonomous program / operation program selected in step S21. In the determination of the target position and the motion, the robot ID, coordinates, direction of the other robot obtained from the position information conversion processing unit 505, and the motion state (ball holding state, kick state, standby) transmitted from the other robot. State) and data indicating the coordinates of the ball are used. By the process of step S22, the movement target position data and the operation data are created.
Next, the process proceeds to step S23.

In the next step S23, a movement data creation process is performed. In this process, movement data is created based on the coordinates of the current position and the movement target position data. This movement data is data representing a movement course from the current position to the movement target position.
Next, the process proceeds to step S24.

In step S24, PWM data creation processing is performed. In this process, PWM (Pulse Width Modulation) pulse control data is generated based on the movement data. The data for PWM control is control data for the motors 29 of the wheel units 11a and 11b if the target of autonomous control is the striker robot 1a or the like, and is the case where the target of autonomous control is the keeper robot 117a or the like. For example, the control data for the motors 29 of the wheel units 121a, 121b, 121c, and 121d are obtained.
Next, the process proceeds to step S25.

In step S25, transmission data creation processing is performed. In this process, if the control target is the striker robot 1b, 1d, the robot control data 706 is created based on the control target robot ID, the PWM control data, and the operation data, and the control target is the keeper. In the case of the robots 117a and 117b, the robot control data 833 is created based on the robot ID to be controlled and the PWM control data. At this time, if necessary, LED instruction data 706e or the like is added to the left motor drive command 706c or the like of the robot control data 706, or LED instruction data 833e or the like is added to the left motor drive command 833c or the like of the robot control data 833. Is done.
The above is the description of the robot control data generation process based on the autonomous program / operation program.

Next, referring to FIG. 60, the trial process in step S4 will be described.
First, in step S91, a referee command acquisition process is performed. Through this process, the data transmitted from the referee controller 211 is acquired.
Next, the process proceeds to step S92.

In step S92, it is determined whether or not a referee command exists in the acquired data. The processing in step S93 is performed by the referee command discrimination processing unit 517.
If the referee command exists, the process proceeds to step S93.

In step S93, a referee command transmission data creation process is performed.
In this referee command transmission data creation process, first, a referee command discriminating process for discriminating what kind of referral command the data transmitted from the referee controller 211 is. Referee commands include, for example, those that stop operations by the player-side controllers 205a and 205b, those that stop the striker robots 1b and 1d and the keeper robots 117a and 117b, those that add one point to Team A, Those who deduct one point, those who add one point for Team B, those who deduct one point for Team B, those who reset their score, those who extend the game time, those who reset the game time, etc. Can be considered. This referee command discriminating process is also performed by the referee command discriminating unit 517.

Next, transmission data creation processing is performed.
In the transmission data creation process, transmission data is created based on the command determined in the referee command determination process. That is, instruction data for stopping each robot, instruction data for stopping the operation by the player side controllers 205a and 205b, data for increasing / decreasing the score / game time, and the like are created.
This transmission data creation process is performed by the referee command processing unit 519.
Next, the process proceeds to step S94.

In step S94, a command transmission process is performed. In this command transmission process, the data generated by the transmission data generation process is transmitted to the point management unit 529, the time management unit 527, the striker robots 1b and 1d, the keeper robots 117a and 117b, and the player-side controllers 205a and 205b. .
Then, according to the transmitted data, the score management unit 529 increases / decreases or resets the score, the time management unit 527 increases / decreases or resets the game time, and the display device 209 displays the score, game time, and the like. Display processing, stop processing of the striker robots 1b and 1d and keeper robots 117a and 117b, stop processing of operations by the player side controllers 205a and 205b, and the like.
The process of step S94 is also performed by the referee command processing unit 519.
The above is the description of the referee process.

  Next, action button processing will be described with reference to FIG. This action button process is performed in the remote control processing unit 515.

First, in step S95, controller information acquisition processing is performed. By this controller information acquisition processing, data transmitted from the player side controllers 205a and 205b to the personal computer 213 is acquired.
Next, the process proceeds to step S96.

  In step S96, it is determined whether or not the action button 415 of the player-side controllers 205a and 205b is pressed based on the data acquired by the controller information acquisition process. If it is determined that the action button 415 is pressed, the process proceeds to step S97.

In step S97, notification processing is performed. By this notification processing, the program determination processing unit 1015 is notified that the action button 415 has been pressed.
This completes the description of the action button process.

Next, processing in the player side controllers 205a and 205b will be described.
First, the processing in the robot communication processing unit 1019 of the player side controllers 205a and 205b will be described with reference to FIG.
First, in step S31, input circuit state acquisition processing is performed. In this input circuit state acquisition process, data from the movement direction instruction input circuit 607, the movement direction correction input circuit 609, the additional input circuit 611, and the operation command conversion coefficient input circuit 613 are input to the information processing apparatus 601. .
Next, the process proceeds to step S32.

In step S32, an internal data conversion process is performed. In the internal data conversion process, the data input in step S31 is converted into a format that can be easily used by the information processing apparatus 601 and the personal computer 213.
Further, the data from the movement direction correction input circuit 609 is converted and stored in the movement direction correction table 603, and the data from the operation command conversion coefficient input circuit 613 is converted and then the operation command conversion coefficient. It is stored in the table 605.
Next, the process proceeds to step S33.

In step S33, robot operation command conversion processing is performed. In this robot operation command conversion processing, PWM control of the motors 29 and 29 of the wheel units 11a and 11b of the striker robot 1a and the motor 59 of the cam drive unit 13 is performed based on the data input from the moving direction instruction input circuit 607. A signal is generated and becomes robot operation command data.
Next, the process proceeds to step S34.

In step S34, robot operation command correction processing is performed. In this robot operation command correction process, the robot operation command data generated in step 33 is corrected based on the data stored in the movement direction correction table 603.
Next, the process proceeds to step S35.

In step S35, additional input data addition processing is performed. This additional input data adding process is a process of adding motion data based on data input from the additional input circuit 611 to the robot motion command data. In the present embodiment, operation data for performing a ball holding operation and a kick operation is added.
Next, the process proceeds to step S36.

In step S36, a display output process is performed. This display output process is a process in which the display circuit 617 performs display according to, for example, robot operation command data.
Next, the process proceeds to step S37.

In step S37, a communication message generation process is performed. In this communication message generation process, robot control data 706 used to control the striker robot 1a or the striker robot 1c is generated based on the robot operation command data.
The robot operation command data includes not only data for instructing operations to the striker robots 1a and 1c by the direction indication dial 405, the throttle lever 407, and the operation buttons 413, but also correction data by the direction correction knob 409 and the operation correction knob 411. include.
The data from the direction indication dial 405 is corrected by the data from the direction correction knob 409 and used to generate the robot control data 706. The data from the throttle lever 407 is corrected by the data from the operation correction knob 411. After that, it is used to generate the robot control data 706.
Further, the robot ID 706b of the robot control data 706 generated here uses the robot ID of the robot to be operated by the player-side controllers 205a and 205b.
Next, the process proceeds to step S38.

In step S38, communication hear transmission processing is performed. In this communication transmission process, a process of wirelessly transmitting the generated robot control data 706 to the striker robot 1a or the striker robot 1c via the wireless communication circuit 615 is performed.
Next, the process proceeds to step S39.

In step S39, it is determined whether or not to end the processing in the robot communication processing unit 1019 of the player side controllers 205a and 205b.
If not completed, the process proceeds to step S31 again.
This completes the description of the processing in the robot communication processing unit 1019 of the player-side controllers 205a and 205b.

Next, processing in the PC (personal computer) communication processing unit 1021 of the player side controllers 205a and 205b will be described with reference to FIG.
First, in step S98, it is determined whether or not a signal from the personal computer 213 is received. The signal from the personal computer 213 may include data instructing stop of the operation by the player side controllers 205a and 205b by the referee process. In such a case, the operation by the player side controllers 205a and 205b is stopped. The operation of the striker robots 1a and 1c and the keeper robots 117a and 117b is prohibited.
Next, the process proceeds to step S99.

In step S99, a communication message generation process is performed. Through this communication message generation process, a communication message including data for notifying the personal computer 213 that the action button 415 of the player-side controllers 205a and 205b has been pressed is generated.
Next, the process proceeds to step S100.

In step S100, a communication message transmission process is performed. Thus, the communication message is transmitted to the personal computer 213, and the personal computer 213 is notified whether or not the action button 415 of the player-side controllers 205a and 205b has been pressed.
This completes the description of the processing in the PC (personal computer) communication processing unit 1021 of the player-side controllers 205a and 205b.

Next, processing of the striker robot 1a and the like and the keeper robot 117a and the like will be described with reference to FIGS.
First, with reference to FIG. 65, the overall processing in the striker robot 1a and the like, the keeper robot 117a and the like will be described.
In step S40, an initialization process is performed. This initialization process will be described later.
Next, the process proceeds to step S41.

In step S41, a timer start process is performed. By this timer start process, the operation of a timer used for a timer interrupt process to be described later is started.
The above is the description of the overall processing in the striker robot 1a and the like, the keeper robot 117a and the like.

Next, an initialization process in the striker robot 1a and the keeper robot 117a and the like will be described with reference to FIG.
First, in step S42, hardware setup processing is performed. In this hardware setup process, initialization processes of the CPUs 701 and 801 such as reading of firmware and various programs are performed.
Next, the process proceeds to step S43.

In step S43, an initial output setting process is performed. In this initial output setting process, initialization of each output pin of the CPU, initialization for the motor drive circuit 709, the motor drive circuit 817, the LED drive circuit 721a, and the LED drive circuit 825a is performed.
The above is the description of the initialization process in the striker robot 1a and the like and the keeper robot 117a and the like.

Next, a reception interrupt process in the striker robot 1a and the like, the keeper robot 117a and the like will be described with reference to FIG. This reception interrupt process is a process that occurs when wireless communication is received by each robot.
In the reception interrupt process, a reception data acquisition process is performed in step S44. Through this reception data acquisition process, robot control data 706 and 833 are input to the CPUs 701 and 801 via the wireless communication circuits 705 and 816.
The above is the description of the reception interrupt processing in the striker robot 1a and the like and the keeper robot 117a and the like.

Next, transmission interrupt processing in the striker robot 1a and the keeper robot 117a and the like will be described with reference to FIG. This transmission interrupt process is a process that occurs when wireless communication is transmitted in each robot.
First, in step S45, it is determined whether or not it is the last transmission byte (end byte) of the data to be transmitted. If it is the last transmission byte, the process proceeds to step S46. Otherwise, the process proceeds to step S47.

In step S46, a reception mode change process is performed, and the wireless communication circuits 705 and 816 are changed to the reception mode. On the other hand, in step S47, transmission data setting processing is performed, and transmission data is set in the wireless communication circuits 705 and 816.
The above is the description of the transmission interrupt processing in the striker robot 1a and the like and the keeper robot 117a and the like.

Next, timer interrupt processing in the striker robot 1a and the like, the keeper robot 117a and the like will be described with reference to FIG.
First, in step S48, received data determination processing is performed. This received data determination process will be described later.
Next, the process proceeds to step S49.

In step S49, a power supply voltage monitoring process is performed. This power supply voltage monitoring process will be described later.
Next, the process proceeds to step S50.

In step S50, motor drive processing is performed. This motor driving process will be described later.
Next, the process proceeds to step S51.

In step S51, an LED driving process is performed. This LED driving process will be described later.
The above is the description of the timer interruption process in the striker robot 1a and the like and the keeper robot 117a and the like.

Next, received data determination processing in the striker robot 1a and the like, the keeper robot 117a and the like will be described with reference to FIG.
First, in step S57, it is determined whether or not a prescribed number of data has been received. The prescribed number of data is 6 bytes of the total length if the robot control data 706, and 7 bytes of the total length if the robot control data 833. That is, it is determined whether or not all data constituting the robot control data 706 and 833 has been received.
If the prescribed number of data has been received, the process proceeds to step S58, and if the prescribed number of data has not been received, the process proceeds to step S61.

  In step S58, it is determined whether the CRC is correct. The CRC is added as CRC data to the last byte of the robot control data 706 and 833, and this is inspected. If the CRC data is correct, the process proceeds to step S59, and if the CRC data is not correct, the process proceeds to step S60.

In step S59, a command data acquisition process is performed. In this process, the command data 706a from the robot control data 706, the PWM command value 706d of the left motor drive command data 706c, the LED command data 706e of the left motor drive command data 706c, and the PWM command value 706g of the right motor drive command data 706f. LED command data 706h of right motor drive command data 706f, PWM command value 706j of cam drive command data 706i, operation instruction data 706k of cam drive command data 706i, command data 833a from robot control data 833, front left motor PWM command value 833d of drive command data 833c, LED command data 833e of left front motor drive command data 833c, PWM command value 833g of right front motor drive command data 833f, and right motor drive command data 833f ED command data 833h, PWM command value 833j of left rear motor drive command data 833i, LED command data 833k of left rear motor drive command data 833i, PWM command value 833n of right rear motor drive command data 833m, right rear motor drive command data The LED command data 833p of 833m is extracted.
When the extraction of the data is completed, the process proceeds to step S61.

On the other hand, if it is determined in step S58 that the CRC is not correct, a data discard process is performed in step S60. In this process, the received data is discarded. Next, the process proceeds to step S61.
Further, as described above, when it is determined in step S57 that the prescribed number of data has not been received, the process also proceeds to step S61.

  In step S61, it is determined whether or not data reception is periodically received. If the data is regularly received, the process proceeds to step S62. If the data is not regularly received, the process proceeds to step S63.

In step S62, reception timeout avoidance processing is performed. In this reception timeout avoidance process, a process is performed so that the striker robot 1a or the like or the keeper robot 117a or the like does not stop. Thereafter, the received data determination process ends.
In step S63, reception timeout processing is performed. In this reception timeout avoidance process, a process of stopping the motors 29 and 59 such as the striker robot 1a and the keeper robot 117a is performed. Thereafter, the received data determination process ends.
The above is the description of the received data determination process.

Next, the power supply voltage monitoring process in the striker robot 1a and the like and the keeper robot 117a and the like will be described with reference to FIG.
First, in step S52, it is determined whether or not the voltage of the battery 68h is equal to or lower than a preset specified voltage. If the voltage of the battery 68h is equal to or lower than the specified voltage, the process proceeds to step S53. If the voltage of the battery 68h is higher than the specified voltage, the power supply voltage monitoring process is terminated.

In step S53, a motor drive prohibition process is performed. In this motor drive prohibition process, power supply to the motor 29 or the like is stopped by the power supply circuits 727 and 829 so that the motor 29 or the like cannot be driven.
The above is the description of the power supply voltage monitoring process in the striker robot 1a and the like, the keeper robot 117a and the like.

Next, motor drive processing in the striker robot 1a and the like, the keeper robot 117a and the like will be described with reference to FIG.
First, in step S64, it is determined whether or not the motors 29 and 59 are energized. The determination in step S64 is determined based on the power supply voltage monitoring process described above.
If the motors 29 and 59 are energized, the process proceeds to step S65. If the motors 29 and 59 are not energized, the process proceeds to step S67.

  In step S65, it is determined whether or not the motors 29 and 59 are rotated forward. By this determination processing, the PWM command value 706d of the left motor drive command data 706c of the robot control data 706, the PWM command value 833d of the left front motor drive command data 833c of the robot control data 833, and the like cause the motors 29 and 59 to rotate forward. It is determined whether or not it is to be made. If the PWM command value 706d of the left motor drive command data 706c of the robot control data 706, the PWM command value 833d of the left front motor drive command data 833c of the robot control data 833, etc. are those that normally rotate the motor 29, etc. The process proceeds to step S66, and if not, the process proceeds to step S68.

In step S66, forward output output terminal setting processing is performed. In this processing, setting is made so that output is performed from a pin that normally rotates the motor 29 among the pins to which the CPU 701 and the motor driving circuit 709 are connected.
Thereafter, the motor driving process is terminated.

In step S68, reverse output terminal setting processing is performed. In this processing, setting is made such that output is performed from a pin that reversely rotates the motor 29 and the like among the pins connected to the CPU 701 and the motor drive circuit 709 and the like and the CPU 801 and the motor drive circuit 817 and the like.
Thereafter, the motor driving process is terminated.

On the other hand, in step S67, a stop output terminal setting process is performed.
At this time, a setting is made so that no output is performed for the pins to which the CPU 701 and the motor drive circuit 709 and the like and the CPU 801 and the motor drive circuit 817 and the like are connected.
Thereafter, the wheel unit motor driving process is terminated.
The above is the description of the wheel unit motor driving process.

Next, LED driving processing in the striker robot 1a and the like, the keeper robot 117a and the like will be described with reference to FIG.
First, in step S54, it is determined whether or not the LED lighting cycle is based on the LED instruction data 706e of the robot control data 706, the LED instruction data 833e of the robot control data 833, or the instructions from the CPUs 701 and 801. Is done. If it is determined that it is the LED lighting cycle, the process proceeds to step S55, and if it is determined that it is not the LED lighting period, the process proceeds to step S56.

In step S55, an LED lighting process is performed. In this LED lighting process, the LED 723a and the LED 827a are turned on by the LED drive circuit 721a and the LED drive circuit 825a and the like.
Thereafter, the LED driving process is terminated.

In step S56, an LED turn-off process is performed. In this LED turn-off process, the LED 723a and the LED 827a and the like are turned off by the LED drive circuit 721a and the LED drive circuit 825a and the like.
Thereafter, the LED driving process is terminated.

Next, cam drive unit automatic alignment processing in the striker robot 1a and the like will be described with reference to FIG.
First, in step S69, it is determined whether or not it is a stop mode. The stop mode indicates a state in which the motor 59 of the cam drive unit 13 is to be stopped, and the striker robot 1a and the like are in the stop mode when in a standby state or a ball holding state. Whether or not the stop mode is set is held by the CPU 701 as motor operation mode data.
If it is the stop mode, the process proceeds to step S70, and if it is not the stop mode, the process proceeds to step S72.

In step S70, a stop output terminal setting process is performed. This process is a process of setting the pins connected to the motor drive circuit 717 of the CPU 701 so that the motor 59 is stopped. Therefore, in this case, the motor 59 does not operate.
Thereafter, the process proceeds to step S71, where it is determined whether or not to end the process. If the process is not terminated, the process returns to step S69.

On the other hand, when the process proceeds from step S69 to step S72, it is determined whether or not the sensor switch rising detection mode is set. The sensor switch rising detection mode is an attempt to detect the rising of the sensor switch 113a urged by the sensor switch urging unit 115d of the cam 115, that is, the state where the urging is released from the released state. More specifically, this is a case where it is detected that a standby state is to be established after the kick operation.
There is also a sensor switch falling detection mode opposite to this sensor switch rising detection mode, but this is to detect that the sensor switch 133a has been released from the biased state. Specifically, it is a case where it is detected that the ball is held from the standby state.
If it is the sensor switch rising detection mode, the process proceeds to step S73, and if not, the process proceeds to step S76.

  In step S73, it is determined whether or not the rising of the sensor switch 113a has been detected. If the rising of the sensor switch 113a is detected, the process proceeds to step S74, and if not, the process proceeds to step S75.

In step S74, stop mode transition processing is performed together with stop output terminal setting processing. The stop output terminal setting process is a process of setting the pins connected to the motor drive circuit 717 of the CPU 701 so as to stop the motor 59. In step S72, since it is determined that the sensor switch rising detection mode is set, in step S74, the motor 59 is stopped after the kick operation, and the striker robot 1a and the like enter a standby state. The stop mode transition process refers to setting the motor operation mode data to the stop mode.
Thereafter, the process proceeds to step S71, where it is determined whether or not to end the process. If the process is not terminated, the process returns to step S69.

On the other hand, when the process proceeds from step S73 to step S75, forward output output terminal setting processing is performed. This process is a process for setting the pins connected to the motor drive circuit 717 of the CPU 701 so that the motor 59 rotates forward. In this case, normal rotation means that the motor 59 is rotated counterclockwise in FIG. Further, since the motor 59 is rotated by this process, the stop mode is not reached, and a process for canceling the stop mode (setting the motor operation mode data to the non-stop mode) is also performed.
Further, when the process proceeds to step S73, the striker robot 1a is performing a kick operation.
Thereafter, the process proceeds to step S71, where it is determined whether or not to end the process. If the process is not terminated, the process returns to step S69.

On the other hand, when the process proceeds from step S72 to step S76, it is determined whether or not the falling of the sensor switch 113a is detected. The case where the fall of the sensor switch 113a is detected means that the bias is released from the state where the sensor switch 113a is biased, and the striker robot 1a or the like performs the ball holding operation from the standby state. Immediately after doing it.
If the falling of the sensor switch 113a is detected, the process proceeds to step S77, and if not, the process proceeds to step S78.

In step S77, a stop output terminal setting process and a stop mode transition process are performed as in step S74. That is, the motor 59 is stopped and the striker robot 1a and the like are in a ball holding state.
Thereafter, the process proceeds to step S71, where it is determined whether or not to end the process. If the process is not terminated, the process returns to step S69.

On the other hand, when the process proceeds from step S76 to step S78, a process of setting the pins connected to the motor drive circuit 717 of the CPU 701 so that the motor 59 rotates normally by the normal rotation output terminal setting process as in step S75. Is done. In this case, since the motor 59 is rotating, the striker robot 1a and the like are in a state of shifting from the standby state to the ball holding state.
Thereafter, the process proceeds to step S71, where it is determined whether or not to end the process. If the process is not terminated, the process returns to step S69.
The above is the description of the cam drive unit automatic alignment process in the striker robot 1a and the like.

Next, the effect of the soccer game system 200 according to the present embodiment will be described.
First, an autonomous program used for autonomous control of the keeper robots 117a and 117b can be selected by the autonomous program selection card 919, and control based on the operation of the player side controllers 205a and 205b of the keeper robots 117a and 117b can be performed by the operation program selection card 921. Since the operation program to be used can be selected, the playability of the game is high.
In addition, by replacing the autonomous program selection card 919 and the operation program selection card 921 set on the A team card installation base 911 and the B team card installation base 915, the autonomous program used even during the game is used. And the operation program is changed. Therefore, this can further enhance the playability of the game.

In the case of the present embodiment, since the player side controllers 205a and 205b are provided so that the operator can directly operate the striker robots 1a and 1c and the keeper robots 117a and 117b, anyone can easily participate in the game. And enjoy it.
The striker robots 1b and 1d and the keeper robots 117a and 117b are controlled by robot control data 706 and robot control data 833 generated and output from the personal computer 213. Further, the operations by the player side controllers 205a and 205b used for the operations of the striker robots 1a and 1c can be stopped by an instruction from the referee command processing unit 519 of the personal computer 213. That is, the personal computer 213 centrally manages the striker robots 1a, 1b, 1c, and 1d, the keeper robots 117a and 117b, and the player-side controllers 205a and 205b, thereby facilitating game management. .
In addition, for example, it is possible to give a penalty (for example, stopping for a certain period of time) to the violated operator's robot, thereby improving the playability of the game.

Further, by operating the action buttons 415 of the player-side controllers 205a and 205b, it is possible to cause the keeper robots 117a and 117b to perform the action selected by the operation program selection card 921, thereby enhancing the playability of the game. Can do.
Further, when the action buttons 415 of the player side controllers 205a and 205b are not operated, the keeper robots 117a and 117b are controlled by an autonomous program, and when the action buttons 415 of the player side controllers 205a and 205b are operated. Since control by the program is performed, switching between the control by the autonomous program and the control by the operation program is easy, and the playability of the game can also be improved.

Further, the storage medium readers 913 and 917 read the autonomous program and operation program created by the user stored in the storage medium and register them in the program table 543, and instead of the prepared autonomous program and operation program. Therefore, the playability of the game can be further improved.
In addition, since the scoring and the game time are managed in the personal computer 213 by the referee signal transmitted from the referee controller 211, the game can be easily managed and the playability of the game can also be improved.

Note that the present invention is not limited to the above-described one embodiment or one embodiment.
In the above-described embodiment, one of the striker robots of each team is autonomously controlled and the other is manually operated. However, it is also conceivable that both striker robots are manually operated or autonomously controlled. In this case, the robot IDs of both striker robots may be designated as robot IDs for autonomous control.
In addition, it may be possible to switch whether the robot is autonomously controlled or manually controlled during the game. Switching between whether the robot is autonomously controlled or manually controlled depends on whether or not the robot ID of the robot is designated as a robot ID for manual control.

  Further, in the above-described embodiment, the surface of the autonomous program selection card and the operation program selection card set on the card installation base can be visually recognized, and thereby the selected autonomous program and operation program can be confirmed. However, the configuration for allowing the surface of the autonomous program selection card and the operation program selection card of the card installation table to be visually recognized and the configuration of the card installation unit are limited to the configuration shown in the above-described embodiment. Not. It is also conceivable to install a player display device separately and display information (name, number, etc.) of the autonomous program and the operation program selected by the player display device to the operator.

In the above-described embodiment, the autonomous program of the keeper robot of each team can be selected by the autonomous program selection card. However, the autonomous program of the autonomously controlled striker robot can be selected by the autonomous program selection card. It is also possible to do.
In the above-described embodiment, the user program created by the user is read from the storage medium into the program table in the personal computer, and the user program read into the program table is used. There may be a case where a user program on the storage medium is directly used without reading the program from the storage medium into the personal computer.
In the above-described embodiment, the information of the folder storing the autonomous program and the operation program is generated by the QR code (registered trademark) described in the autonomous program selection card or the operation program selection card. However, the present invention is not limited to such a case. For example, there may be a case where not only the location of the autonomous program or operation program but also the file name is generated by QR code (registered trademark) or the like.

Various combinations of colors constituting the markers of each robot can be considered.
Further, the number of robots used is not limited to the team formation as in the above-described embodiment, and various cases are conceivable.
Further, the present invention may be applied not only to soccer games but also to other game systems. Also, the game to which the present invention is applied is not limited to a battle game.

In the case of the above-described embodiment, the configuration in which one cam is attached to one motor has been described as an example. However, it is also conceivable that two motors are coaxially attached to one motor. .
Further, the shape of the cam is not limited to the illustrated shape, and various shapes are assumed.
In the case of the above-described embodiment, the cam means has been described as an example of the drive means. However, for example, an air cylinder mechanism, a hydraulic cylinder mechanism, a rack and pinion mechanism, etc. are driven in two stages. Various configurations can be considered.

Although the omnidirectional wheel 31 is used in the striker robot 1, the roller 41 is not attached to the wheel body 39 of the omnidirectional wheel 31, and a rubber tire, for example, is provided on the outer periphery of the wheel body 39. It is also conceivable that a normal wheel is constructed by covering the surface.
It is also conceivable that the striker robot 1 can be moved in the same manner as the keeper robot 117 by providing four wheel units including omnidirectional wheels 31. It is also conceivable that the keeper robot 117 is constituted by two wheel units such as the striker robot 1.

Further, in the case of the embodiment, the soccer game robot as a toy has been described as an example, but the scope of application of the apparatus assembly plate is not limited to such, and various object configurations are possible. Applicable as an element.
Various arrangements are conceivable for the arrangement of the front-side concave fitting portions 61b and 71b and the rear-side concave fitting portions 61c and 71c of the apparatus assembly plates 61 and 71.
In addition, the apparatus assembly plates 61 and 71 may be provided with only one of the front-side concave fitting portions 61b and 71b or the back-side concave fitting portions 61c and 71c. In this case, it is also conceivable that the front-side recessed fitting portions 61b and 71b or the rear-side recessed fitting portions 61c and 71c are formed over the entire surface of the apparatus assembly plates 61 and 71 or the entire rear surface.
Moreover, although the thickness of the apparatus assembly plate increases, the case where the front surface side recessed fitting parts 61b and 71b and the back surface side recessed fitting parts 61c and 71c are formed in the same partition is also considered.
In addition, the present invention is not limited to the illustrated configuration, and various modifications can be considered.

  The present invention relates to a robot game system, and in particular, in a configuration in which a plurality of competitive game robots are controlled by a personal computer or a controller, a game operator selects a card and inserts it into a card reader. For example, a soccer game using a small robot can be selected from among the control programs stored in advance in order to increase the fun of the game. It is suitable for this system.

1a Striker robot (matching game robot)
1b Striker robot (matching game robot)
1c Striker robot (matching game robot)
1d Striker robot (matching game robot)
117a Keeper robot (matching game robot)
117b Keeper robot (matching game robot)
117c Keeper Robot (Competitive Game Robot)
117d Keeper robot (matching game robot)
205a Player side controller (operation controller)
205b Player side controller (controller for operation)
213 Personal computer 415 Action button 543 Program table 911 Card installation table (card reader)
913 Storage medium reader 915 Card installation table (card reader)
917 Storage medium reader 919 Autonomous program selection card 921 Operation program selection card 1001 Autonomous program storage unit 1003 Operation program storage unit 1005 Team A user program storage unit 1007 Team B user program storage unit

Claims (9)

Multiple game robots,
A personal computer that outputs a control signal to the game robot;
An operation controller provided to correspond to the plurality of game robots and outputting a control signal to the game robot directly or via the personal computer;
A control program table in which a control program for controlling the plurality of game robots provided in the personal computer is stored in advance;
A card reader that reads information from a card that is connected to the personal computer and stores information for specifying an arbitrary control program among control programs stored in advance in the control program table;
A robot game system comprising: The robot game system according to claim 1,
In the control program table, an autonomous program for controlling the game robot fully automatically and an operation program for controlling the game robot by operating according to a control signal from the operation controller are stored in advance.
2. The robot game system according to claim 1, wherein the card has two types: a card for specifying the autonomous program and a card for specifying the operation program. The robot game system according to claim 2, wherein
A robot game system, wherein the operation controller is provided with a switch for operating the operation program. The robot game system according to claim 3, wherein
A robot game system, wherein control based on the operation program is executed only when the switch is operated, and control by the autonomous program is performed at other times. In the robot game system according to any one of claims 1 to 4,
A robot game system, wherein the card reader reads card information by an image processing method, a magnetic method, and an optical method. In the robot game system according to any one of claims 1 to 5,
A robot game system, wherein the control program table is provided with an area for storing a control program created by a user. The robot game system according to claim 6, wherein
There are two types of control programs created by the user: an autonomous program for controlling the game robot fully automatically and an operation program for controlling the game robot by operating with a control signal from the operation controller. Robot game system. The robot game system according to claim 6 or 7,
A robot game system, characterized in that a user control program input means for inputting a control program created by a user is connected to the personal computer. The robot game system according to any one of claims 1 to 8,
A robot game system, wherein the game robot is a battle game robot belonging to a different team.

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