KR102528946B1 - Non-face-to-face billiard match system - Google Patents

Abstract

The present invention relates to a non-face-to-face billiard game system, and more particularly, to a billiard game system in which two or more players share the position of a billiard ball on at least two billiard tables in a non-face-to-face manner.
To this end, the billiard table of the present invention includes a billiard table body; at least two electromagnetic force generating modules formed on a bottom surface of the billiard table body or at a set point on the billiard table body and generating magnetic force by power supplied from the outside; a first laser transmission module formed at a point spaced apart by a first distance upward from the billiard table body and emitting a laser toward the billiard table body; and a camera formed at a point spaced apart by a second distance upward from the billiard table body.

Description

Non-face-to-face billiard match system {Non-face-to-face billiard match system}

The present invention relates to a non-face-to-face billiard game system, and more particularly, to a billiard game system in which two or more players share the position of a billiard ball on at least two billiard tables and play a game non-face-to-face.

In the game of billiards, a ball made of ivory is placed on a rectangular billiard table covered with soft cloth and hit with a cue. Points are awarded according to whether another ball is hit according to the motion of the ball, or if another ball (object ball) is put into a pocket, points are awarded. It is a game that decides the winner by making it happen, and there are various game methods such as 3-ball, 4-ball, 6-ball, 9-ball, and pocket ball.

Most of those who want to learn such a billiard game learn directly from billiard game experts, and some billiard game beginners or intermediates learn through videos such as billiard game lectures.

However, due to COVID-19, we are currently practicing social distancing and avoiding contact with people. Due to this social distancing, sports involving at least two players are restricted.

That is, sports including soccer and baseball in which at least two players participate are subject to restrictions, and billiards are also subject to such restrictions. Therefore, a billiard game is also required to proceed non-face-to-face.

Korean Patent Registration No. 10-2044874 (Title of Invention: Billiard Room Video Management System) Korean Patent Registration No. 10-1938607 (Title of Invention: Image Analysis System and Method for Billiard Game)

The problem to be solved by the present invention is to propose a billiard game system capable of playing billiards with a player in a remote place non-face-to-face.

Another problem to be solved by the present invention is to propose a method by which a player can analyze the moving trajectory of a friend's billiard ball.

Another problem to be solved by the present invention is to propose a method of moving a billiard ball to a desired point within a billiard table.

To this end, the billiard table of the present invention includes a billiard table body; at least two electromagnetic force generating modules formed on a bottom surface of the billiard table body or at a set point on the billiard table body and generating magnetic force by power supplied from the outside; a first laser transmission module formed at a point spaced apart by a first distance upward from the billiard table body and emitting a laser toward the billiard table body; and a camera formed at a point spaced apart by a second distance upward from the billiard table body.

The non-face-to-face billiards game system according to the present invention can play real-time billiards matches with players or professional billiards players in other regions or countries, and has excellent scoring and foul judgment abilities that are accurate enough to be judged by referees in professional billiards matches. there is.

As such, the present invention can prevent infectious diseases caused by contact by playing billiards non-face-to-face, and has the advantage of being able to play the game with anyone if necessary.

In addition, the present invention can watch a billiard game non-face-to-face using a monitor, and the server can display automatically calculated scores using a monitor installed on a billiard table. In addition, the present invention can access a game through an application through an installed server or viewing terminal and manage personal history.

1 illustrates a billiard table constituting a non-face-to-face billiard game system according to an embodiment of the present invention.
2 shows images captured by 5 cameras formed on the top of the billiard table.
3 illustrates a non-face-to-face billiard game system according to an embodiment of the present invention.
4 illustrates an example of moving a billiard ball using an electromagnet generation module according to an embodiment of the present invention.
5 illustrates an example of moving a billiard ball using an electromagnet generating module according to another embodiment of the present invention.

The foregoing and additional aspects of the present invention will become more apparent through preferred embodiments described with reference to the accompanying drawings. Hereinafter, these embodiments of the present invention will be described in detail so that those skilled in the art can easily understand and reproduce them.

1 illustrates a billiard table constituting a non-face-to-face billiard game system according to an embodiment of the present invention. Hereinafter, a billiard table constituting a non-face-to-face billiard game system according to an embodiment of the present invention will be described in detail using FIG. 1 .

Referring to FIG. 1 , a pool table 100 includes a pool table body 102, a camera 104, a first laser transmission module 106, a second laser transmission module 108, and a laser reception module 110. Of course, other configurations other than the above configuration may be included in the billiard table proposed in the present invention, and although not included in the billiard table, an internal server controlling the billiard table may be included.

The billiard table main body 102 has the same or similar shape as a billiard table installed in an existing billiard room. The billiard table main body 102 may be implemented with marble to facilitate magnetic force transmission, and of course, other materials other than marble may be implemented as long as the magnetic force transmission is possible. An electromagnetic force generating module is installed on the bottom of the marble. The electromagnetic force generating module is installed after perforating the bottom of the marble. The electromagnetic force generating module is installed on the bottom surface of the billiard table main body 102 at regular intervals in the lateral and longitudinal directions, and the installation interval may vary depending on the specifications of the billiard table. Of course, the electromagnetic force generating modules may be installed in other ways other than being installed at regular intervals in the lateral and longitudinal directions. For example, the electromagnetic force generating module may be installed in various shapes such as a circular shape or an elliptical shape having different diameters.

The electromagnetic force generating module generates magnetic force by power supplied from the outside. The electromagnetic force generation module generates magnetic force having different magnitudes according to the magnitude of power supplied from the outside, and the generated magnetic force affects the top of the billiard table. The billiard ball located on the top of the billiard table body 102 includes a metal material therein and moves due to the magnetic force generated by the electromagnetic force generating module. In addition, the billiard ball may be made of phenol that responds to magnetic force, and may include a metal material or a magnetically responsive material therein, if necessary. The billiard ball has a large effect when the generated magnetic force is large, and a small effect when the generated magnetic force is small. Therefore, the billiard ball has a different moving distance, moving speed, and moving direction according to the generated magnetic force.

The electromagnetic force generation modules formed at regular intervals can be individually controlled, and the billiard balls located on the top of the billiard table main body 102 can be individually controlled to move by the individually controllable electromagnetic force generation modules.

The electromagnetic force generating module has been described as being installed at a perforated spot on marble, but is not limited thereto. When the material of the billiard table is made of a material other than marble, it can be formed at not only perforated points but also at non-perforated points, and installation in other forms besides perforations is possible. That is, the pool table body 102 is composed of two members, and the electromagnetic force generating module is installed between the two members. In addition, the electromagnetic force generating module may be installed in the billiard table body 102 in various forms.

The camera 104 is located at a point spaced apart from the upper end of the billiard table body by a predetermined distance, and captures an image (moving or still image) of a billiard ball moving on the billiard table body 102 . The camera 104 provides the captured image to the internal server. As shown in FIG. 1, not one camera is installed, but at least two cameras are installed at a point spaced apart from the top of the billiard table body by a certain distance. 1 is installed to be able to photograph the central part of the pool table, the corner part, the long cushion and the short cushion.

In particular, it is preferable that the camera 104 is installed so as to be concentrated near the corner so that an image of contact/non-contact of the billiard ball with the corner portion of the billiard table body 102 and the long cushion and short cushion can be captured. 1 illustrates five cameras installed at a point spaced apart from the top of the billiard table body by a predetermined distance, but is not limited thereto. The internal server analyzes the color or movement trajectory of the billiard ball from the image captured by the camera 104, and determines the position and movement trajectory of the billiard ball for each color.

2 shows images captured by five cameras installed at a point spaced a certain distance from the top of the billiard table. As shown in FIG. 2 , the images captured by the five cameras are different depending on the location where the cameras are installed. The video captured by the camera is provided to the internal server.

The first laser transmission module 106 is installed at a point spaced apart from the center of the billiard table body 102 by a predetermined distance from the upper end. The first laser transmission module 106 emits a laser to the top of the billiard table. The first laser transmission module 106 can receive a laser if necessary, and can also serve as a pointer to indicate a point where the billiard ball is to be moved.

The billiard ball located on the top of the billiard table body 102 includes a magnetic reactive phenolic resin or metal material inside, and a laser reactive material is applied to the outside. The billiard ball coated with the laser reactive material reacts to the laser emitted from the first laser transmission module 106 .

A laser receiving module 110 for receiving a laser is formed on the inside of the rim of the billiard table body 102, and the laser receiving module 110 receives the laser emitted from the first laser transmitting module and reflected by the billiard balls. The present invention analyzes the laser received by the laser receiving module 110 to calculate the distance and angle with respect to the billiard ball. Using the angle or distance at which the laser emitted from the first laser transmission module 106 is reflected by the billiard ball, the internal server analyzes the movement trajectory of the billiard ball after the player hits the billiard ball, or the moving billiard ball stops position in a state of being As such, the server proposed in the present invention calculates the distance and angle of the billiard ball using the laser emitted by the first laser transmission module 106, and calculates the position of the billiard ball using the calculated distance and angle of the billiard ball. figure out

In addition, a laser reactive paint is applied to the corner of the pool table body 102, and the size of the pool table body 102 is calculated using a laser emitted from the first laser transmission module.

The second laser transmission module 108 is installed on the billiard table including the corner of the billiard table body 102 . To elaborate, the first laser transmission module 106 is installed at a point spaced apart from the billiard table body 102 by a certain distance from the top, while the second laser transmission module 108 is installed on the billiard table body 102. . In addition, it is preferable that the second laser transmission module 108 is installed at at least four points including corners of the billiard table main body 102, rather than just one.

The second laser transmission module 108 detects the movement of the billiard ball on the billiard table body 102 . That is, the second laser transmission module 108 emits a laser onto a moving billiard table at a corner portion. The laser receiving module 110 provides the received distance and angle to the internal server after the laser emitted from the second laser transmitting module 108 is reflected by the billiard ball. The internal server analyzes the distance and angle of the billiard balls provided from the laser receiving module 110 to analyze the trajectory (position) of the billiard balls at the corner of the billiard table and whether or not the billiard balls collide. Of course, the internal server can analyze the movement trajectory, position, and collision of the billiard ball using the information provided from the laser receiving module 110, but for detailed analysis, the laser emitted from the second laser transmitting module 108 It can be used to analyze the movement trajectory, location, and collision of billiard balls.

Of course, it is described that the second laser transmission module is installed at the corner of the billiard table, but it is not limited thereto. A camera can be installed at the corner of the billiard table in addition to the second laser transmission module, and the moving trajectory, position, and collision of billiard balls can be analyzed by analyzing the image taken by the installed camera.

In addition, the present invention may include a display device, and various information on the current billiard game may be displayed using the display device. That is, according to the present invention, scores, player information, and various information necessary to proceed with a billiard game can be displayed using a display device.

In addition, the first laser transmission module 106 may display the position of a billiard ball on another billiard table. That is, the first laser transmission module 106 may display the position of the billiard ball of the other billiard table provided from the internal server.

3 illustrates a non-face-to-face billiard game system according to an embodiment of the present invention. Hereinafter, a non-face-to-face billiard game system according to an embodiment of the present invention will be described in detail with reference to FIG. 3 .

Referring to FIG. 3 , the non-face-to-face billiard game system 300 includes a first billiard table 310, a second billiard table 320, and a main server 330. As described above, the first pool table 310 includes the first pool table body 310a, the first camera 310b, the 1-1 laser transmission module 310c, the 1-2 laser transmission module 310d, the first It includes a laser reception module 310e and a first internal server 310f, and the second pool table 320 includes a second pool table body 320a, a second camera 320b, and a 2-1 laser transmission module 320c. , a 2-2 laser transmission module 320d, a second laser reception module 320e, and a second internal server 320f. In addition, the present invention may include a first internal server installed in the billiard room where the first billiard table is placed and a second internal server installed in the billiard room where the second billiard table is placed. can be included with

The first billiard table main body 310a, the first camera 310b, the 1-1 laser transmission module 310c, the 1-2 laser transmission module 310d, and the 1st laser reception constituting the first pool table 310 The module 310e, the first internal server 310f, and the second pool table main body 320a constituting the second pool table 320, the second camera 320b, the 2-1 laser transmission module 320c, and the second pool table 320c. The -2 laser transmission module 320d, the second laser reception module 320e, and the second internal server 320f operate as described above. Hereinafter, operations performed in the main server 330 will be mainly reviewed.

Hereinafter, a method in which the main server 330 provides the positions of billiard balls placed on the first billiard table 310 to the second billiard table 320 will be mainly reviewed.

In a game of billiards, two players take turns striking a billiard ball. That is, the first player and the second player alternately hit the billiard ball on the billiard table. However, in the present invention, the first player hits the billiard ball on the first billiard table 310, and the second player hits the billiard ball alternately on the second billiard table 320.

When the first player hits the billiard ball on the first billiard table 310, the billiard ball moves to a different position from before hitting the billiard ball. If the position of the billiard ball on the first billiard table 310 is different from before hitting the billiard ball, the position of the billiard ball on the second billiard table 320 must be changed to reflect the position of the billiard ball on the first billiard table. In this way, the present invention displays or moves the position of the billiard ball moved on the first billiard table 310 in the same way on the second billiard table 320, and moves the position of the billiard ball moved on the second billiard table 320 to the first billiard table. In 310, a method of displaying or moving the same is proposed.

The main server 330 calculates the image from the first camera 310b on the first pool table body 310a or the laser emitted from the 1-1 laser transmission module 310c and the 1-2 laser transmission module 310d. Distance and angle information with the billiard ball is received from the first internal server 310f. The main server 330 transmits an image on the first billiard table main body 310a from the first camera 310b or lasers emitted from the 1-1 laser transmission module 310c and the 1-2 laser transmission module 310d. By analyzing the distance and angle information reflected by the ball and received by the first laser receiving module 310d, the position of the billiard ball on the billiard table or whether the billiard ball collides with each other is calculated. The main server 330 provides the calculated position of the billiard ball to the second internal server 320f constituting the second billiard table 320 . The second internal server 320f controls the electromagnetic force generating module constituting the second billiard table to move the billiard balls on the second billiard table. Of course, the second internal server 320f additionally displays the position of the billiard ball of the first billiard table on the second billiard table so that the player can recognize the position of the billiard ball on the first billiard table.

As such, the present invention proposes a method of playing billiards non-face-to-face using a camera, a laser transmission module, a laser reception module, and an electromagnetic force generation module.

In addition, the main server proposed in the present invention analyzes all situations in the billiard game from the images captured by the camera.

That is, the main server 330 analyzes the stroke. It analyzes stroke classification such as long fallow shot, middle shot, and short shot, power, thickness, rotation, hit point (height) and speed. The main server performs precise analysis in real time on the number of cushions that fit the long and short axis of the billiard table and the measurement of the angle of reflection on the axis. The main server clearly distinguishes the automatic leader designation according to the ranking and the contact (collision) situation of the cue ball, the first object ball, and the second object ball, and the scoring situation.

In addition, the main server 330 analyzes the foul. The main server automatically judges fine fouls that occur during the game, such as Two Touch and water polo dribble. Due to such fine fouls that are difficult to determine with the naked eye during actual billiards games, disputes between players often occur. Simple video analysis alone cannot clearly determine the foul or score without error by itself. Based on this, it makes a clear judgment about fouls or goals.

In addition, the present invention implements various functions necessary for playing billiards. In particular, the present invention displays an area having a color different from that of the billiard ball so that it can be determined whether the billiard ball has accurately moved to the point indicated by the laser point. The main server 330 determines whether the billiard ball has moved to the point indicated by the laser point by analyzing the image captured by the camera and the distance and angle between the laser emitted from the laser transmission module and the billiard ball. That is, the main server 330 determines that the billiard ball has been moved normally when the laser point is displayed at a ratio greater than or equal to the set ratio in the corresponding area, and that the billiard ball has been moved abnormally when the laser point is displayed at a ratio less than the set ratio in the corresponding area. judge Accordingly, the main server 330 repeatedly determines whether the billiard ball has moved normally to the point indicated by the laser point. Of course, the operation can be performed on an internal server other than the main server.

In addition, the present invention includes a viewing terminal 340, and by using the viewing terminal 340, a viewer can watch a current billiard game. That is, the viewing terminal may display an image provided from the main server, and may receive information requested by the viewer from the main server and display the same.

Hereinafter, a method of moving a billiard ball located on a billiard table main body is proposed. As described above, the present invention moves the billiard ball located on the billiard table body by using the electromagnetic force generating module.

As described above, the electromagnetic force generation modules formed on the bottom of the billiard table body are arranged at regular intervals, and the internal server controls the movement of the billiard balls by controlling the amount of power supplied to the electromagnetic force generation module.

4 will look at a method of moving a billiard ball using an electromagnetic force generating module according to an embodiment of the present invention. In particular, FIG. 4 will look into how to move billiard ball B from point b to point c while fixing billiard ball A at point a. Hereinafter, for convenience of description, a point where magnetic force is generated by the electromagnetic force generating module on the bottom surface of the billiard table is referred to as a magnetic force point.

The electromagnetic force generation module supplies the largest power to the magnetic force point formed on the bottom of the billiard ball A to fix the billiard ball A at point a. When the relatively largest power is supplied to the magnetic point formed on the bottom of the billiard ball A (magnetic point 1 in FIG. 4), the billiard ball A remains fixed at point a.

Then, in order to move the billiard ball B from point b to point c, the closest magnetic force point from the bottom of billiard ball B is extracted in the direction from point b to point c. According to FIG. 4, in the direction from point b to point c, power one level lower than the relatively largest power is supplied to the magnetic force point closest to the bottom surface of billiard ball B (magnetic force point 2 according to FIG. 4).

Therefore, although the power supplied to magnetic point 2 is relatively lower than that of magnetic force point 1, billiard ball B moves to point c because the distance to magnetic point 2 is relatively close to that of magnetic force point 1. Of course, billiard ball A remains stationary.

When billiard ball B starts to move to point c, power is sequentially supplied to magnetic points located in the direction of the corresponding point so that billiard ball B moves toward point c. After billiard ball B starts moving toward point c, the speed of billiard ball B increases. Therefore, it is necessary to decrease the speed of billiard ball B.

When billiard ball B passes through the midpoint between points b and c, we decrease the speed of billiard ball B. To this end, the speed of the billiard ball is reduced by supplying power to the magnetic force point located at the rear end of the billiard ball's moving direction. As described above, the present invention proposes a method of moving a billiard ball by controlling power supplied to an electromagnetic force generating module formed on a bottom surface of a billiard table body.

In FIG. 4 described above, a method of moving billiard ball B in a state where billiard ball A and billiard ball B are separated to some extent has been described. However, it is difficult to apply the above method when the billiard ball A and the billiard ball B are in close contact.

When billiard ball A and billiard ball B are in close contact, electric power is supplied to a point of magnetic force formed at a point spaced apart from billiard ball A and billiard ball B to move billiard ball A and billiard ball B, thereby moving billiard ball A and billiard ball The above-described operation is performed while B is spaced apart.

In addition, the billiard ball may be moved in various ways.

5 will look at a method of moving a billiard ball using an electromagnetic force generating module according to an embodiment of the present invention. In particular, FIG. 5 will look at how to move billiard ball B from point b to point c while maintaining billiard ball A at point a.

4 assumes that the magnetic force point is located on the bottom surface of the billiard ball A, whereas FIG. 5 assumes that the magnetic force point is not located on the bottom surface of the billiard ball A.

In order to move the billiard ball B from point b to point c, the nearest point of magnetic force from the bottom of billiard ball B is extracted in the direction from point b to point c. The electromagnetic force generating module supplies power to the magnetic force point closest to the bottom surface of the billiard ball B in the direction from point b to point c (magnetic force point 2 according to FIG. 5). Not only the billiard ball B but also the billiard ball A are moved by the power supply. Of course, the moving speed of billiard ball B, which is relatively close to the magnetic force point 2, is faster than the moving speed of billiard ball A. When billiard ball B and billiard ball A start to move, the power supplied to magnetic force point 2 is cut off. Then, in order to move the billiard ball A to its original position, power is supplied to the magnetic force point 1 located in the opposite direction to the direction in which the billiard ball A moved. When power is supplied to the magnetic force point 1, billiard ball A moves to its original position, and billiard ball B also moves in the opposite direction or its moving speed is reduced. When the above-described operation is repeated, the distance between billiard ball A and billiard ball B increases, and billiard ball A and billiard ball B are separated to a distance that allows individual movement control. When they are separated to the distance where individual movement control is possible, billiard ball A and billiard ball B are moved to the position to be moved using the electromagnetic force generating module.

As described above, the present invention moves the two billiard balls to a desired position not only in a spaced state but also in a non-separated state. In addition, even when the magnetic force point is not formed on the bottom of the billiard ball, the billiard ball is moved to a desired point.

The present invention shows a method of moving a billiard ball using electromagnetic force, but is not limited thereto. The billiard ball may be moved using a mechanical means that grips and moves the billiard ball, and the billiard ball may be moved in various ways.

The present invention proposes an application through which a billiard player can check related information.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is only exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. .

100: billiard table 102: billiard table body
104: camera 106: first laser transmission module
108: second laser transmission module 110: laser reception module
300: billiard game system 310: first billiard table
320: second pool table 330: main server
340: viewing terminal 310a: first billiard table body
310b: first camera 310c: 1-1 laser transmission module
310d: first-second laser transmission module 310e: first laser reception module
310f: first internal server 320a: second pool table body
320b: second camera 320c: 2-1 laser transmission module
320d: 2-2 laser transmission module 320e: 2nd laser reception module
320f: second internal server

Claims (5)

billiard table body;
at least two electromagnetic force generating modules formed at regular distance intervals on the bottom surface of the billiard table main body or in the longitudinal and transverse directions of the billiard table main body and generating magnetic force by power supplied from the outside;
a camera formed at a point spaced apart by a second distance upward from the billiard table body;
a second laser transmission module installed on the pool table including the edge of the pool table body and emitting a laser;
a laser receiving module for receiving the laser emitted from the second laser transmitting module; and
Controls the amount of power supplied to the electromagnetic force generating module, and analyzes the movement of the billiard ball by analyzing the distance and angle received by the laser receiving module after the laser transmitted from the second laser transmission module is reflected by the billiard ball. including a server;
It includes a magnetic force point where magnetic force is generated by the electromagnetic force generating module,
The internal server moves the billiard ball B located on the top of the billiard ball body from point b to point c of the billiard table while the billiard ball A located on the top of the billiard table body is fixed at point a of the billiard table,
The largest power is supplied to magnetic force point 1, which is a magnetic force point formed on the bottom of the billiard table at point a,
In the direction from point b to point c, power 1 level lower than the largest power is supplied to the magnetic force point 2, which is the closest magnetic force point to the bottom of the billiard ball B,
a first laser transmission module positioned on the top of the billiard table body and performing a pointer function to display a point where the billiard ball is to be moved;
The billiard ball is coated with a laser responsive material to react to the laser transmitted from the first laser transmission module,
The pool table according to claim 1 , wherein the edge of the pool table body is coated with laser reactive paint to react to the laser transmitted from the first laser transmission module to calculate the size of the pool table body.
The method of claim 1, wherein the internal server,
When the billiard ball B moves in the direction of the magnetic force point 2, the billiard table characterized in that power is sequentially supplied to the magnetic force points formed in the direction from point b to point c.
The method of claim 2, wherein the internal server,
When the billiard ball B passes through the middle point between points b and c, the billiard table characterized in that power is supplied to the magnetic force point located at the rear end of the moving direction of the billiard ball B.
billiard table body;
at least two electromagnetic force generating modules formed at regular distance intervals on the bottom surface of the billiard table main body or in the longitudinal and transverse directions of the billiard table main body and generating magnetic force by power supplied from the outside;
a camera formed at a point spaced apart by a second distance upward from the billiard table body;
a first laser transmission module installed on the pool table including the edge of the pool table body and emitting a laser;
a laser receiving module for receiving the laser emitted from the first laser transmitting module; and
Controls the amount of power supplied to the electromagnetic force generating module, and analyzes the movement of the billiard ball by analyzing the distance and angle received by the laser receiving module after the laser transmitted from the first laser transmission module is reflected by the billiard ball. including a server;
It includes a magnetic force point where magnetic force is generated by the electromagnetic force generating module,
The internal server moves the billiard ball B located on the top of the billiard ball body from point b to point c of the billiard table while the billiard ball A located on the top of the billiard table body is fixed at point a of the billiard table,
In the direction from point b to point c, power is supplied to the magnetic force point 2, which is the closest magnetic force point to the bottom of the billiard ball B,
When billiard ball A and billiard ball B move due to the power supply of the magnetic point 2, the power supply to the magnetic point 2 is cut off and then power is supplied to the magnetic point located at the rear end of the moving direction of the billiard ball B,
a first laser transmission module positioned on the top of the billiard table body and performing a pointer function to display a point where the billiard ball is to be moved;
The billiard ball is coated with a laser responsive material to react to the laser transmitted from the first laser transmission module,
The pool table according to claim 1 , wherein the edge of the pool table body is coated with laser reactive paint to react to the laser transmitted from the first laser transmission module to calculate the size of the pool table body.
According to any one of claims 1 to 4,
The billiard ball A and the billiard ball B are billiard tables, characterized in that they include a metal material.

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