KR20200088712A - Broadcasting effect system and method using laser - Google Patents

Abstract

The present invention relates to a broadcasting effect system using a laser and a method for implementing a broadcasting effect through the same, and more specifically, to a system for visually providing a new effect to viewers who watch content through broadcasting by irradiating a laser with adjusted various parameter values on a surface of a back wall and photographing the back wall in which a series of patterns are formed by laser irradiation, and a method thereof. The broadcasting effect system comprises: a laser irradiation device; a control server; and a photographing device.

Description

Broadcast effect system using laser and method of realizing broadcast effect using the same{BROADCASTING EFFECT SYSTEM AND METHOD USING LASER}

The present invention relates to a system for realizing a broadcast effect using a laser and a method for realizing a broadcast effect through the laser, and specifically, irradiating a laser with various parameter values adjusted on a backwall surface, by laser irradiation The present invention relates to a system and method for visually providing new effects to viewers watching content through broadcasting by photographing a white wall with a series of patterns formed thereon.

Along with the growth of the broadcasting content industry, development of means for providing various sensory effects to viewers or audiences has also been actively conducted. Among them, the visual effect is one of the effects that can most effectively appeal to viewers who watch the content on TV, and recent content producers have shown how to provide a new form of visual effect to the audience through the screen. Interest continues to increase.

The part where the visual effect is especially used in the broadcast content is the participant's interview shooting part. Today, in a large number of broadcast content, logos, texts, images, etc. that can inform the identity of the broadcast content other than the performers in one screen We are exposing them together, and we are using new visual effects to make them more strongly imprinted on viewers, especially when exposing the above logos, texts, and images.

The so-called interview back wall (plane wall) for shooting is often used as a prop suitable for realizing the above visual effects. For example, various visual effects during interviews with performers Interviews of various materials and shapes are being used to be implemented on the surface.

In the visual effects that were implemented on the white wall in the previous interview, there were visual effects using electric wires that can emit light according to the shape to be expressed, projection mapping that projects an image made of light on the object surface, etc. Of these, the electrocution is clear and easy to control, but the shape can only be fixed to one, so there is a limit to using various shapes. The projection mapping can be animated, but it has relatively low clarity and the projection surface is very detailed. There has been a problem in that implementation is not easy because there is a need to adjust.

The present invention is intended to improve the problems of the system for implementing the conventional visual effect, and at the same time, to propose a visual effect of a new sensibility that has not been previously seen. It relates to a broadcast effect system and method.

Registered Patent 10-1367826 (registered on February 20, 2014)

An object of the present invention is to provide a visual effect of a new method that cannot be realized by a conventional electrophoresis or projection mapping method by utilizing a laser on a flat member such as an interview back wall.

In addition, an object of the present invention is to solve the flicker phenomenon that may occur when photographing a laser irradiation, so that a visual effect utilizing the laser can be stably provided to viewers.

In addition, the present invention aims to ensure that clear and clean shapes, that is, logos, text, images, etc., are stably maintained for a long time while recording broadcast content.

On the other hand, the problems to be solved by the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description to be described later.

In order to solve the above problems, the broadcast effect system according to the present invention includes a laser irradiation device that irradiates a back wall according to a shape set by a control server; A control server for generating an irradiation signal for controlling the laser irradiation device and controlling the output of the laser irradiation device by transmitting the irradiation signal to the laser irradiation device; And a photographing apparatus for photographing the white moon irradiated with a laser.

In addition, in the broadcast effect system, the irradiation signal generated by the control server includes at least one of shape, color, number of outputs per unit time of the laser, length of the shape, and one irradiation time of the shape. Is done.

In addition, in the broadcast effect system, the laser irradiation apparatus irradiates a laser on a white wall according to an irradiation signal received from the control server, but a pattern displayed by the laser irradiated on the white wall has a plurality of different spots on the surface of the white wall. It is characterized by being formed by the laser irradiated at the same time point.

In addition, in the broadcast effect system, the laser irradiation apparatus irradiates a laser on a white wall according to an irradiation signal received from the control server, but a pattern displayed by the laser irradiated on the white wall has a plurality of different spots on the surface of the white wall. It may be characterized by being formed by the laser irradiated for a predetermined time.

At this time, the pattern may be characterized in that it is formed according to the shape included in the irradiation signal, and furthermore, the pattern is composed of a set of a plurality of laser points corresponding to the number of outputs per unit time of the laser. It can be characterized as.

In addition, in the broadcast effect system, the number of outputs per unit time of the laser may be adjusted according to a frame rate or shutter speed of the photographing apparatus.

In addition, in the broadcast effect system, the white wall may include an area where irregularities are formed, and the laser irradiation apparatus may be characterized by irradiating a laser along the periphery of the irregularities.

On the other hand, the broadcast effect implementation method according to another embodiment of the present invention, the control server, generating an irradiation signal for controlling the laser irradiation device, and transmitting the generated irradiation signal to the laser irradiation device; And a laser irradiation apparatus receiving the irradiation signal and irradiating a laser to a back wall according to a shape included in the irradiation signal.

In addition, in the method of implementing the broadcast effect, after the laser irradiation device irradiates the laser to the white wall, the imaging device may further include photographing the laser pattern displayed on the white wall by the laser.

In addition, in the method of implementing broadcast effects, the generating of the irradiation signal by the control server includes: (a) loading an image file for an arbitrary shape; (b) obtaining the total line length of the shape and the time required to irradiate the shape once; (c) dividing the total line length of the shape by the time required to irradiate the shape once, and setting positions of a plurality of spots to be irradiated with the laser per unit time; It may include.

In this case, the step of irradiating the laser to the white wall by the laser irradiation device may be characterized in that the laser irradiation device emits a laser pattern on the white wall by irradiating the laser at the same time point to the plurality of spots. .

In addition, in the method of implementing the broadcast effect, the step of irradiating the laser to the white wall by the laser irradiation device, the laser irradiation device continuously irradiates the laser for a predetermined time to the plurality of spots to form a laser pattern on the white wall. It may be characterized by implementing.

Further, in the method of implementing the broadcast effect, the step of irradiating the laser to the white wall by the laser irradiation device may be characterized in that the laser irradiation device irradiates the laser along the periphery of the irregularities formed in the white wall.

According to the present invention, there is an effect capable of providing a clear shape implemented by a laser, particularly a clear shape implemented on an interview backwall, in broadcast content.

In addition, according to the present invention, there is an effect capable of stably realizing a visual effect using a laser even for a long time recording by allowing the content creator to continuously maintain a fixed shape or an animated moving shape.

In addition, according to the present invention, there is an effect of providing a clear laser pattern to viewers without shaking or shaking on broadcast content by minimizing the flicker phenomenon that occurs when shooting a laser directly.

1 shows the configurations of a broadcasting effect system according to the present invention.
Figure 2 shows an actual example of the interview back month.
3 shows an embodiment of the laser pattern expressed on the interview white wall.
4 shows a process of implementing the laser pattern according to the first embodiment.
5 is a view for explaining an example in which a laser pattern is implemented on the premise that a virtual coordinate system exists on an irradiation surface.
6 illustrates a process of implementing a laser pattern according to the second embodiment.
7 shows how the laser pattern is converted into various shapes.

The details of the object and technical configuration of the present invention and its operational effects will be more clearly understood by the following detailed description based on the accompanying drawings in the specification of the present invention.

The embodiments disclosed herein should not be interpreted or used as limiting the scope of the invention. It is natural that those skilled in the art, including the embodiments herein, have various applications. Accordingly, any of the embodiments described in the detailed description of the present invention are exemplary to better describe the present invention and are not intended to limit the scope of the present invention to the embodiments.

The functional blocks shown in the drawings and described below are only examples of possible implementations. Other functional blocks may be used in other implementations without departing from the spirit and scope of the detailed description. Further, although one or more functional blocks of the present invention are represented as individual blocks, one or more of the functional blocks of the present invention may be a combination of various hardware and software configurations that execute the same function.

In addition, the expression of including certain components is an expression of “open” and simply refers to the existence of the components, and should not be understood as excluding additional components.

Furthermore, when a component is said to be "connected" to or "connected" to another component, it should be understood that other components may be directly connected or connected to the other component, but may exist in the middle. do.

First, with reference to Figure 1 will be described with respect to the configuration of the broadcast effect system according to the present invention.

Figure 1 is a diagram showing the appearance of conducting the interview of the performers, the broadcast effect system to be proposed by the present invention when referring to the drawing basically includes a laser irradiation device, a control server, the laser on the surface of the interview white wall It can be irradiated, and further provided with a photographing device, so as to photograph the laser pattern irradiated on the interview white wall. Hereinafter, each configuration will be described individually.

First, the laser irradiation device will be described. The laser irradiation device is one of the core components of the system according to the present invention, and is a device that irradiates a laser on an interview backwall according to a control command from a preset control server and, in another term, an irradiation signal from the control server. The laser means light amplification by induced emission, and a substance in an excited state can be understood as a type of light generated by using a property capable of induced emission of radiation. The laser irradiation device may generate a laser beam by various implementations. For example, various implementation methods such as a ruby laser, a neodymium:yag laser, a neodymium:glass laser, a laser diode, an excimer laser, and a dye laser may exist. .

On the other hand, when referring to FIG. 1, it is shown that only one laser irradiation device is used in the broadcast effect system according to the present invention, but the number of laser irradiation devices may be increased as needed, and in particular, interviews When the size of the image or text to be expressed in the image is large or long, it is impossible to form a pattern with only one laser irradiation device. In order to simultaneously implement a steady state pattern and an animated pattern with movement, multiple The number of laser irradiation devices may be increased in cases where two laser irradiation devices are required.

In addition, the laser irradiation apparatus is not only capable of irradiating only one light beam (laser beam), and can irradiate a plurality of light beams at various angles at the same time. For example, the laser irradiation device may simultaneously irradiate a red (R) light beam to the first spot, a green (G) light beam to the second spot, and a blue (B) light beam to the third spot at the same time. In addition, the light beams may be irradiated with different brightness and width.

The laser irradiation device has its own control panel so that the user can directly adjust various parameters of the laser, but the laser irradiation device in the broadcast effect system according to the present invention is preferably controlled by a separate server computer called a control server. It can be characterized as being controlled. The control server will be described below.

The control server is a kind of computing device including a central processing unit capable of calculating and a memory capable of storing various commands and data, and the control server is based on a wired or wireless network connection with the laser irradiation device, but the laser In addition to the irradiation device, other components may be connected to the network to be implemented to control each component.

The control server performs a function of controlling the laser irradiation device by generating a control command for controlling the laser irradiation device, that is, an irradiation signal and transmitting it to the laser irradiation device.

The irradiation signal, as mentioned above, may be understood as a signal including information necessary for controlling the laser irradiation device, and the signal may be converted into a data packet and transmitted to the laser irradiation device through a network. have.

On the other hand, the irradiation signal may include a variety of information, for example, the shape (stroke), the color of the shape (color), the length of the shape (length of stroke) to express on the member of the interview white wall or other plane , It may include information about the shape and color to be exposed through the laser, such as one time per shape (duration), which is the time it takes to implement one shape once. In addition, the irradiation signal may further include various parameters related to the output of the laser, for example, the number of outputs per unit time, the intensity of the irradiated laser, and the diameter of the irradiated laser.

The control server may provide software with a user interface so that the user can easily operate the laser irradiation, and generate the irradiation signal based on the user input input through the software. Looking at an example of a process in which the control server transmits the irradiation signal, the control server adapts coordinate data for the outline of the shape (logo, text, image) set by the user according to the format of the International Laser Display Association (ILDA) protocol. The converted coordinate data is converted into the irradiation signal along with other parameters such as the number of outputs per second (number of outputs per unit time) of the laser, or the total length of the shape and one irradiation time of the shape. It can be included and communicated and transmitted to the laser irradiation device.

The laser irradiation device described above and the control server for controlling the same can be said to be a basic configuration for realizing a pattern of a certain shape by irradiating a laser in the broadcast effect system according to the present invention. Meanwhile, the broadcast effect system according to the present invention may further include a photographing apparatus for photographing a laser pattern implemented on an interview white wall, in addition to components for irradiating a laser.

The photographing device literally means a device capable of photographing a subject through an optical lens, and the photographing device in the present invention is characterized in that, when a laser is irradiated on an interview white wall. Referring to FIG. 1, the imaging device may be separately driven according to a user's manipulation to photograph a laser pattern implemented on an interview white wall, but this is not necessarily limited thereto. It is understood that it may be implemented to be controlled according to a user input from the control server in conjunction with the control server.

On the other hand, in the related art, since a flicker occurs when a laser is to be photographed with an optical camera, the use of the laser has been limited as a broadcast effect. The flicker phenomenon refers to a screen flicker phenomenon that occurs when the shutter speed and the frame rate of the photographing device do not match the output of the laser irradiated from the laser irradiation device, and more specifically, the laser implements a pattern. It refers to the flickering phenomenon that occurs due to the difference between the speed and the speed of light received through the lens of the imaging device.

In the broadcast effect system according to the present invention, in order to minimize the above flicker phenomenon, the shutter speed of the photographing device is adjustable within a range of 1/30 sec to 1/100 sec, and the frame rate of the photographing device is 30 Hz to 120 Hz. It was made possible to adjust within the range, and preferably, when the shutter speed of the photographing apparatus was set to 1/60 sec, and the frame rate of the photographing apparatus was set to 59.92 Hz, it was confirmed that the flicker phenomenon was significantly reduced. However, the adjustment range of the above parameters, or a specific value of the above parameters is only an example, and the above values may vary depending on the material of the interview backwall or other flat panel, additional environmental factors at the shooting site, and the like. It should be understood that it may change depending on the hardware properties of the photographing device, the transmission system, and the format.

In the above, the basic configurations for implementing the broadcast effect system according to the present invention, that is, the configurations for implementing the laser pattern and the configuration capable of photographing the above have been described.

On the other hand, the laser pattern implemented by the broadcast effect system can make a great difference in visual effect depending on what material and what shape of the panel where the laser pattern is expressed, that is, interview whitewall. The interview month mentioned in the description may preferably be the same as that shown in FIG. 2.

FIG. 2 shows an example of an interview back month used when implementing the broadcast effect system according to the present invention. Interview Baekwol may include irregularities forming a certain shape. In FIG. 2, “SMTM” and the number “777” can be seen as irregularities. At this time, it is preferable that the irregularities of the “SMTM” and “777” have a thickness of at least 3 mm from the plane, so that the shadow effect can be highlighted when the light shines on the irregularities. In addition, the interview backwall does not necessarily need to be a flat member, and the vertical lines may be formed of irregularities as shown in FIG. 2. For reference, the interview white wall mentioned in this detailed description implements a texture such as a concrete wall surface. In this way, the interview white wall can use various materials to express various types of texture as needed. have.

When the interview white wall is configured as shown in FIG. 2, the laser can be said to be a relatively advanced technology by irradiating a wall surface that has a relatively old sensibility, that is, a wall surface of a concrete texture, etc., thereby enhancing the pattern of laser irradiation. In addition, the combination of the device of the past emotion and the laser, which is the product of the advanced technology, enables the viewers to watch the broadcast to experience new visual effects, so that the viewer can feel the fun and emotion that was not felt before. have.

On the other hand, until now with reference to Figure 2 described the preferred embodiment of the interview whitewall, it should be understood that the surface (radiation) to which the laser is irradiated is not necessarily limited to this. For example, the surface irradiated with the laser may be the surface of another member other than the interview white wall, and the other member may be made of various physical properties such as plastic and metal. In addition, the surface of the another member may be a flat shape with no unevenness.

Hereinafter, the laser pattern irradiated on the interview white wall will be described in detail with reference to the drawings of FIG. 3 or less.

FIG. 3 shows some practical examples of implementing a laser pattern on an interview white wall using the above-described broadcast effect system. According to this, the laser irradiation apparatus may implement various patterns of patterns by simultaneously irradiating lasers according to an arbitrary shape (logo, text, image) or sequentially irradiating lasers for a predetermined time on an interview white wall. For reference, the laser pattern, which is a term referred to in this detailed description, may be understood as a comprehensive term including both the shape and animation expressed on the interview white wall, for example, a stationary shape formed on the surface of the interview white wall, or the interview white wall It can be understood that all moving images (animated images) formed on the surface are included in the term laser pattern.

4 is for explaining the process of implementing the laser pattern according to the first embodiment, and specifically relates to a process of implementing a text SMTM composed of lines with a laser.

First, FIG. 4(a) defines the entire text of “SMTM” as one shape, and shows a process of examining the shape once. The process of implementing one laser pattern is required for the control server to load a vector image file for an arbitrary shape, that is, SMTM text, to obtain the total line length of the shape, and to examine the shape once. Obtaining a time (one irradiation time of the shape), and dividing the total length of the line obtained previously by one irradiation time of the shape may be configured to set the position of a plurality of laser spots having a constant interval. . That is, the laser pattern implemented in the interview white wall is made by the laser irradiated by the laser irradiation device simultaneously or continuously irradiating the laser to several points (spots) on the surface of the interview white wall. After setting the points (spots) to which the laser is irradiated through the above process, the laser irradiation device is controlled. For reference, the step of setting the position of the plurality of laser points may be understood as a step of setting the position of the plurality of laser points by the control server receiving the user's input, for example, the laser pattern to be expressed by the user. After projecting the laser several times in an interview on a white wall in order to implement, the position of the finally determined laser points can be input through the input means of the control server, and the position of the laser points thus entered is controlled by the control server. It can be set as points (spots) to be irradiated with the laser.

On the other hand, the step of setting the position of the plurality of laser points, the control server itself is a plurality of laser points with reference to the loaded vector image file, the total line length of the shape, the irradiation time of the shape, etc. It can also be implemented by computing coordinates and setting coordinate values that are the results of the calculation.

Referring back to FIG. 4(a), for example, assuming that the total line length of the text SMTM is 32 cm, and that it takes 4 seconds to examine the text SMTM once, the SMTM text Can be implemented by continuously irradiating a laser with a length of 8 cm per second, and the control server receives a location of points (spots) to be irradiated by the laser per unit time in advance from a user, or the control server itself points ( By calculating the positions of the spots, it is possible to cause the laser irradiation apparatus to irradiate laser spots of a predetermined length at the corresponding time. Meanwhile, it is understood that the unit time may be defined in a shorter unit according to a user's need, and laser points may be determined in ms and us units. FIG. 4(a) shows a process in which the SMTM text is implemented for 4 seconds, and arrows 1 to ④ and dashed lines show paths through which the laser is irradiated per second.

On the other hand, Figure 4 (b) is an embodiment or a shape similar to that of (a) shows an example implemented by dividing into S, M, T, M, respectively. That is, in (a), if the text “SMTM” is seen as one shape, in (b) each letter of “S”, “M”, “T”, and “M” is viewed as a single shape, for a total of 4 It shows the case where the calculation process by the control server has occurred over time.

As described above, in the broadcast effect system according to the present invention, when a single shape is to be implemented as a laser pattern, a plurality of laser spots that can be irradiated per unit time are set, and the laser irradiation apparatus determines the corresponding spots. It will be appreciated that the investigation is made simultaneously or continuously over time.

Meanwhile, FIG. 5 shows that a virtual coordinate system can be set to implement a laser on the interview white wall, for example, after the control server sets an arbitrary virtual coordinate system on the interview white wall by presetting. By setting a plurality of arbitrary points (P(x,y); spots) to be irradiated with the laser on the virtual coordinate system, the laser irradiator can be irradiated with the laser at the corresponding position.

6 is for illustrating a process of implementing a laser pattern according to the second embodiment, and the second embodiment shows an example of implementing a SMTM text composed of a closed curve as a laser pattern. Since the rater pattern in FIG. 6 can also be made in the same manner as in FIG. 4, description of the process will be omitted to avoid duplication of the description.

In the second embodiment illustrated in FIG. 6, the portion where the laser is previously irradiated is indicated by a solid line, the portion where the laser irradiation is performed for a unit time is indicated by a two-dot chain line, and the portion where the laser irradiation has not been performed is indicated by a dotted line. , The order in which the laser was irradiated was indicated by I to III.

For reference, in the first embodiment described with reference to FIG. 4, the case where one shape is the entire SMTM text and the case where each of S, M, T, and M are completed letters have been described, but can be implemented by a laser pattern. The shape does not necessarily have to be the entire completed letter, and as shown in FIG. 5, may include only a portion of the corresponding text. For example, in implementing the T-shaped laser pattern, it is not necessary to irradiate the laser to reveal the entire letter shape T, and according to the user's design, the laser may be irradiated only on a portion of the T.

On the other hand, the second embodiment as shown in FIG. 6 may be more effective when implemented on an interview white wall including the uneven surface introduced in FIG. 2, and to be transmitted when irradiating a laser along only the outlines of letters formed by the unevenness There is an effect that can convey the shape (logo, text, image) to viewers more discriminatively.

7 is for explaining that the laser pattern implemented on the interview white wall can be converted into various types. The control server can continuously implement various laser patterns by continuously generating the irradiation signals for a plurality of shapes and controlling the laser irradiation device. For example, the top of FIG. 7 is static by the laser irradiation device irradiating the laser simultaneously. The in-text implementation, the middle of FIG. 7 implements a different laser pattern consisting only of a plurality of horizontal lines instead of the text SMTM, and the lower portion of FIG. 7 again implements the SMTM text by continuous laser irradiation over time. It shows the appearance. In this way, the control server according to the present invention can be implemented by continuously switching various laser patterns by controlling the laser irradiation device.

The above was the broadcast effect system using a laser and the implementation method thereof. The present invention is not limited to the specific embodiments and application examples described above, and various modifications can be implemented by those skilled in the art to which the present invention pertains without departing from the gist of the present invention as claimed in the claims. Needless to say, these modified embodiments should not be understood as being distinguished from the technical idea or prospect of the present invention.

10 laser patterns
100 laser irradiation device
200 control server
300 shooting device
500 interviews

Claims (14)

In the broadcast effect system using a laser,
A laser irradiation device irradiating a back wall according to a shape set by the control server;
A control server for generating an irradiation signal for controlling the laser irradiation device and controlling the output of the laser irradiation device by transmitting the irradiation signal to the laser irradiation device; And
An imaging device for photographing the white moon irradiated with a laser;
Containing,
Broadcasting effect system.
According to claim 1,
The irradiation signal generated by the control server,
Characterized in that it comprises at least one of the shape, color, the number of outputs per unit time of the laser, the length of the shape, the irradiation time of the shape,
Broadcasting effect system.
According to claim 1,
The laser irradiation device irradiates the laser in the white wall according to the irradiation signal received from the control server,
The pattern displayed by the laser irradiated to the white wall is characterized by being formed by a laser irradiated at the same time point to a plurality of different spots on the surface of the white wall,
Broadcasting effect system.
According to claim 1,
The laser irradiation device irradiates the laser in the white wall according to the irradiation signal received from the control server,
The pattern displayed by the laser irradiated on the white wall is characterized by being formed by the laser irradiated for a predetermined time on a plurality of different spots on the surface of the white wall,
Broadcasting effect system.
According to claim 4,
The pattern,
Characterized in that formed according to the shape included in the irradiation signal,
Broadcasting effect system.
The method of claim 5,
The pattern is characterized in that it consists of a set of a plurality of laser points corresponding to the number of outputs per unit time of the laser,
Broadcasting effect system.
According to claim 2,
Characterized in that the number of outputs per unit time of the laser is adjusted according to the frame rate or shutter speed of the photographing device,
Broadcasting effect system.
According to claim 1,
The white wall includes an area where irregularities are formed,
The laser irradiation device is characterized in that for irradiating the laser along the outer periphery of the,
Broadcasting effect system
In the method of implementing a broadcast effect using a laser,
A control server generating an irradiation signal for controlling the laser irradiation device, and transmitting the generated irradiation signal to the laser irradiation device; And
A laser irradiation apparatus receiving the irradiation signal and irradiating a laser to a back wall according to a shape included in the irradiation signal;
Containing,
How to implement the broadcast effect.
The method of claim 9,
After the laser irradiation device irradiates the laser to the white wall,
A photographing apparatus, photographing a laser pattern displayed on the white wall by a laser;
Further comprising,
How to implement the broadcast effect.
The method of claim 9,
The control server generating the irradiation signal,
(a) loading an image file for an arbitrary shape;
(b) obtaining the total line length of the shape and the time taken to irradiate the shape once;
(c) dividing the total line length of the shape by the time required to irradiate the shape once, and setting positions of a plurality of spots to be irradiated with the laser per unit time;
Characterized in that it comprises,
How to implement the broadcast effect.
The method of claim 11,
The step of the laser irradiation device irradiating the laser to the white wall,
Characterized in that the laser irradiation device emits a laser pattern on the white wall by irradiating a laser to the plurality of spots at the same time point,
How to implement the broadcast effect.
The method of claim 11,
The step of the laser irradiation device irradiating the laser to the white wall,
The laser irradiation device is characterized in that for implementing a laser pattern on the white wall by continuously irradiating the laser for a predetermined time to the plurality of spots,
How to implement the broadcast effect.
The method of claim 9,
The step of the laser irradiation device irradiating the laser to the white wall,
The laser irradiation device is characterized in that for irradiating the laser along the outer periphery formed in the white wall,
How to implement the broadcast effect.

Images