JP2021110789A - Optical representation device - Google Patents

Abstract

To provide an optical presentation device capable of automatically performing a desired optical representation according to music played in a concert hall and the like.SOLUTION: An optical representation device 1 is equipped with a tape deck 2 and a speaker 3, a frequency analysis device 4 that analyses an acoustic signal outputted from the speaker 3 and detects frequency components included in the acoustic signal, a projector 6 that projects representation light, and a control device 5 that collates a combination of the frequency components included in the acoustic signal detected in the frequency analysis device 4 and the combination of the frequency components respectively associated with a plurality of representation scenarios to read out the representation scenario, and changes the representation light projected by the projector 6 on the basis of the representation scenario.SELECTED DRAWING: Figure 1

Description

The present invention relates to a light effect device that projects light according to a musical piece.

For example, in an event venue, a theater, a concert hall, etc., an effect of projecting an image on a screen installed in the venue may be performed. In addition, in a concert hall, the lighting may be changed according to the music to be played. Conventionally, such a production has been performed manually. That is, the person in charge determines the timing to start and the timing to end the production, and the person in charge operates the projector or the lighting equipment.

On the other hand, in recent years, attempts have been made to automate the production by lighting or images. For example, Patent Document 1 discloses an optical effect device that includes a scenario reproduction means for switching effect information in time series, modulates an image according to a scenario reproduced by the scenario reproduction means, and projects the image onto a screen. Further, this light effect device is provided with a sound generator, and can generate sound in accordance with the effect of the image. Patent Document 2 discloses a fireworks production device that picks up the sound of a drum hit by an audience with a microphone, changes the appearance of a fireworks image according to the sound of the drum, and projects it on a screen.

JP-A-2009-146798 JP-A-2002-066163

According to the light effect device described in Patent Document 1, the image can be modulated according to a pre-recorded scenario. According to the fireworks effect device described in Patent Document 2, the appearance of the fireworks image can be changed according to the sound of the drum hit by the audience. However, none of the devices changes the appearance of the image, and does not have a function of selecting a specific image from a plurality of different images and projecting it on the screen. In addition, it does not have a function of selecting and executing a specific production scenario from a plurality of production scenarios. Therefore, there is a problem that a manual operation is required in order to produce a desired light effect according to the music to be played.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a light effect device capable of automatically performing a desired light effect according to a musical piece played at a concert hall or the like. do.

In order to achieve the above object, the optical effect device according to the first aspect of the present invention reads out the music and the control signal from the acoustic recording medium in which the music and the control signal are recorded, and outputs the control signal together with the music. An acoustic output means that outputs to the outside in the form of an acoustic signal, an acoustic signal analysis means that analyzes an acoustic signal derived from a control signal output from the acoustic output means, and detects a frequency component contained in the acoustic signal. The light projection means for projecting light, the effect scenario recording means for recording a plurality of effect scenarios in association with a combination of specific frequency components, and the frequency included in the acoustic signal detected by the acoustic signal analysis means, respectively. The combination of components and the combination of frequency components associated with each of the plurality of production scenarios are collated, and the production scenario associated with the combination of frequency components included in the acoustic signal is read from the production scenario recording means. , The effect light control means for changing the effect light projected by the light projecting means based on the effect scenario.

The effect light control means may change at least one of the color, brightness, and projection direction of the effect light projected by the light projection means with the passage of time.

The optical effect device according to the second aspect of the present invention reads music and control signals from an acoustic recording medium in which music and control signals are recorded, and outputs the control signals together with the music to the outside in the form of acoustic signals. An acoustic output means, an acoustic signal analysis means that analyzes an acoustic signal derived from a control signal output from the acoustic output means, and detects a frequency component included in the acoustic signal, and a plurality of optical image data, respectively. An optical image data recording means that records in association with a combination of specific frequency components and arbitrary optical image data recorded in the optical image data recording means are read out, an optical image is reproduced, and the optical image is used as an object. The combination of the frequency components contained in the acoustic signal detected by the optical image reproduction projection means and the acoustic signal analysis means and the combination of the frequency components associated with each of the plurality of optical image data are collated with each other. It is provided with an optical image control means for reproducing optical image data associated with a combination of frequency components included in the acoustic signal in an optical image reproduction projection means and projecting the optical image onto an object.

The acoustic signal analysis means may be provided with a frequency analysis means for detecting a frequency component included in a specific band of the acoustic signal.

The frequency analysis means may detect a set of frequency components constituting a remarkable peak in a frequency spectrum obtained by frequency analysis of a specific band of an acoustic signal.

In the frequency spectrum obtained by frequency analysis of a specific band of an acoustic signal by a frequency analysis means, a frequency component constituting each of a first peak showing the maximum signal strength and a second peak showing the signal strength next to it. You may try to detect the pair of.

The specific band analyzed by the frequency analysis means may be in the range of 17,700 to 19,300 Hz.

The control signal recorded on the acoustic recording medium is a data signal that is between the start signal indicating the start of the control signal, the finish signal indicating the end of the control signal, and the start signal and the finish signal, and is to be analyzed by the frequency analysis means. It may be composed of three elements.

According to the present invention, it is possible to automatically perform a light effect according to a musical piece played at a concert hall or the like.

It is a block diagram which shows the structure of the light effect device which concerns on embodiment of this invention. FIG. 3 is a control block diagram showing a configuration of a control device included in the light effect device shown in FIG. 1. FIG. 5 is a configuration diagram showing a configuration of music data and control signal data recorded on a magnetic tape used in a tape deck included in the optical effect device shown in FIG. 1. It is explanatory drawing explaining the frequency analysis performed by the frequency analysis apparatus included in the optical effect apparatus described in FIG. FIG. 5 is a flowchart illustrating a process executed by a control device included in the light effect device shown in FIG. 1. It is a block diagram which shows the structure of the light effect device which concerns on 1st modification of this invention. It is explanatory drawing which shows the structure of the control signal which concerns on the 2nd modification of this invention. It is a time chart which shows the change of the signal strength of the control signal which concerns on the 2nd modification of this invention.

Hereinafter, the configuration and operation of the light effect device according to the embodiment of the present invention will be described in detail with reference to the drawings. In each drawing, the same or equivalent parts are designated by the same reference numerals.

FIG. 1 is a configuration diagram showing a configuration of a light effect device 1 according to an embodiment of the present invention. As shown in FIG. 1, the light effect device 1 includes a tape deck 2, a speaker 3, a frequency analysis device 4, a control device 5, and a floodlight 6.

The tape deck 2 is a device that reads music data and control signal data from a magnetic tape 7 on which music data and control signal data are recorded in advance, converts the music data and control signal data into electrical signals, and outputs the data. The configuration and format of the music data and control signal data recorded on the magnetic tape 7 and the music and control signals reproduced on the tape deck 2 will be described later.

The speaker 3 is a device that converts an electric signal output from the tape deck 2 into sound and outputs the sound. Since the electric signal output from the tape deck 2 is configured by superimposing the electric signal related to the control signal on the electric signal related to the music, the sound obtained by superimposing the control signal sound on the music is emitted from the speaker 3. It is radiated toward stage 8. The relationship between the control signal sound and the music will be described later. The tape deck 2 and the speaker 3 are examples of specific configurations of the acoustic output means of the present invention. The magnetic tape 7 is an example of an acoustic recording medium.

The frequency analysis device 4 is a device that analyzes the sound output from the speaker 3, separates the control signal sound included in the sound output from the speaker 3, and further detects the frequency component included in the control signal sound. be. The separation of the control signal sound and the detection of the frequency component are performed by Fourier analysis of the sound output from the speaker 3. As will be described later, since the control signal sound uses a band near the upper limit of the human audible range, which is not used in the music, it is easy to separate the control signal sound from the sound output from the speaker 3. be. The frequency analysis device 4 is an example of a specific configuration of the acoustic signal analysis means of the present invention.

The control device 5 is a device that controls the floodlight 6 based on the control signal sound separated by the frequency analysis device 4, and is an example of the effect light control means of the present invention. The specific configuration and operation of the control device 5 will be described later.

The floodlight 6 is a device that projects directing light toward the stage 8. The floodlight 6 can be controlled by the control device 5 to change the color and brightness of the projected light. Further, the floodlight 6 includes a swivel rack 6a and a swing rack 6b, and can swing and swing around the X-axis and the Y-axis to project the effect light. The swivel rack 6a and the swing rack 6b include an electric motor controlled by the control device 5. Therefore, the floodlight 6 is controlled by the control device 5 to rotate and swing around the X-axis and the Y-axis. That is, the floodlight 6 can be controlled by the control device 5 to change the direction in which the effect light is projected. The floodlight 6 is an example of a specific configuration of the light projection means of the present invention.

FIG. 2 is a control block diagram showing the configuration of the control device 5. As shown in FIG. 2, the control device 5 includes a central processing unit (CPU) 5a, a storage unit 5b, and an input / output interface (I / O) 5c. The central processing unit 5a is an arithmetic unit that processes information by sequentially reading, interpreting, and executing programs installed in the storage unit 5b.

In the storage unit 5b, in addition to the program executed by the central processing unit 5a, a plurality of production scenarios, that is, data describing the color, brightness, and projection direction of the projected light projected by the floodlight 6 are stored. .. The color and brightness of the projected light and the projection direction described in the production scenario are generally dynamic data that change with the passage of time. In addition, the production scenario is recorded in a state of being linked to a set of frequency components described later. That is, a specific production scenario is recorded in a form corresponding to a specific set of frequency components.

The input / output interface 5c is an electric circuit that inputs / outputs data between an external device and the central processing unit 5a. The frequency component detected by the frequency analysis device 4 is input to the central processing unit 5a via the input / output interface 5c. Information that controls the floodlight 6, that is, information that controls the color, brightness, and projection direction of the projected light projected by the floodlight 6, is output from the central processing unit 5a to the floodlight 6 via the input / output interface 5c.

FIG. 3 is a configuration diagram showing the structure of music data and control signal data recorded on the magnetic tape 7. As shown in FIG. 3, the magnetic tape 7 includes a track 7a for recording music data and a track 7b for recording control signal data. The data recorded on the magnetic tape 7 is read out in order from the data on the left side in FIG.

As shown in FIG. 3, music data related to music A, B, and C is recorded on track 7a of the magnetic tape 7. Therefore, when the music data recorded on the magnetic tape 7 is read out by the tape deck 2, the music A, B, and C are reproduced in order. The control signals related to the control signals P and Q are recorded on the track 7b of the magnetic tape 7. The control signal data related to the control signal P is recorded prior to the music data related to the music B. Therefore, when the control signal P is reproduced on the tape deck 2, the reproduction of the song B is started thereafter. The control signal data related to the control signal Q is recorded prior to the music data related to the music C. Therefore, when the control signal Q is reproduced on the tape deck 2, the reproduction of the music C is started thereafter.

The upper limit of the human audible range is about 20,000 Hz, but the acoustic signal derived from the control signal uses the band of 17,700 to 19,300 Hz. In addition, this band is rarely used in musical music. Further, as will be described later, the acoustic signal is output only for an extremely short time. In this way, the acoustic signal uses a band near the upper limit of the audible range, and is output only for an extremely short time. Therefore, even if the sound signal related to the control signal P prior to the music B and the sound signal related to the control signal Q prior to the music C are output from the speaker 3, the audience in the vicinity of the stage 8 is notified. I can hardly hear it.

FIG. 4 is an explanatory diagram illustrating frequency analysis performed by the frequency analysis device 4. The sound waveform 9 output from the speaker 3 is input to the frequency analysis device 4. As described above, the waveform 10 of the control signal sound is superimposed on the music sound in the sound output from the speaker 3. The frequency analysis device 4 is a kind of FFT (Fast Fourier Analyze) device, and separates the waveform 10 of the control signal sound from the waveform 9 of the input sound. Further, the frequency analysis device 4 spectrum-analyzes the waveform 10 of the control signal sound to obtain the frequency spectrum 11 of the waveform 10 of the control signal sound. _{Further, the frequency components F 1} , F ₂ , ... F _n, which are included in the frequency spectrum 11 and show a remarkable peak, are obtained. The frequency analysis by the frequency analysis device 4 is always performed during the operation of the light effect device 1. When the frequency analysis device 4 detects the waveform 10 of the control signal sound, the frequency analysis device 4 outputs the frequency spectrum 11 of the waveform 10 of the control signal sound to the control device 5.

FIG. 5 is a flowchart illustrating a process executed by the control device 5. The processing is performed by the central processing unit 5a reading out the light effect program stored in the storage unit 5b of the control device 5 and sequentially executing the processing. The light effect program is always executed while the light effect device 1 is activated. Therefore, when the main power supply of the light effect device 1 is in the ON state (step 1: Yes), the process proceeds to step 2, and when the main power source of the light effect device 1 is not in the ON state (step 1: No), the process ends. .. When the input of the frequency spectrum 11 to the control device 5 is detected in step 2 (step 2: Yes), the process proceeds to step 3. If the frequency spectrum 11 is not input to the control device 5 (step 2: No), the process returns to step 1. In this way, the loop continues between step 2 and step 1 until the input of the frequency spectrum 11 to the control device 5 is detected.

_{In step 3, the frequency components F 1} , F ₂ , ... F _n included in the frequency spectrum 11 input to the control device 5 and showing a remarkable peak are collated with the effect scenario stored in the storage unit 5b. do. Then, if the effect scenario associated with the combination of the frequency components F ₁ , F ₂ , ... F _n is stored in the storage unit 5b (step 4: Yes), the effect scenario is read from the storage unit 5b. Then proceed to step 5. If the corresponding production scenario is not stored in the storage unit 5b (step 4: No), the process returns to step 1.

In step 5, the floodlight 6 is controlled and operated based on the specific effect scenario read from the storage unit 5b. That is, the light effect is performed by changing the color, brightness, and projection direction of the projected light projected by the floodlight 6 according to the specific effect scenario. When the light production is finished, return to step 1.

As described above, according to the light effect device 1, when a specific musical piece is output from the speaker 3 to the stage 8, the control signal sound is directed from the speaker 3 to the stage 8 prior to the output of the musical piece. It is output. Then, the floodlight 6 is controlled according to the effect scenario associated with the control signal sound, and the light effect is performed. Therefore, no manpower is required to carry out the light production. That is, it is not necessary for the person in charge to operate the control device 5 to start the light effect at the timing of starting the performance of the specific music. Alternatively, it is not necessary for the person in charge to select a production scenario according to the music to be played and let the control device 5 perform the light production by the production scenario.

In the above, since the signal sounds related to the control signals P and Q are output prior to the performance of the songs B and C, the light effect is started at the same time as the performance of the songs B and C is started. However, the light effect device 1 is not limited to the one in which the performance of the music and the light effect are started at the same time. In the light effect device 1, before and after the start of playing the music and the start timing of the light effect can be freely adjusted by adjusting the recording position of the control signal on the magnetic tape 7. In the light effect device 1, the light effect can be started prior to the start of playing the music. It is also possible to start the light production after the start of playing the music. In addition, the time for continuing the light effect can be arbitrarily set in the effect scenario.

Further, the number of frequency components constituting the set of frequency components collated by the control device 5 is arbitrary. The set of frequency components may be composed of one frequency component, or may be composed of two or three or more frequency components. Further, when the set of frequency components collated by the control device 5 is composed of two frequency components, the peak showing the maximum signal strength and the peak showing the maximum signal strength in the frequency spectrum 11 obtained by frequency analysis of the control signal sound. The frequency components constituting each of the peaks indicating the signal strength next to it may be detected, and the set of the two frequency components may be collated with the set of the frequency components associated with the production scenario.

(First modification)
The light effect device 1 includes a floodlight 6, and is not limited to a device that changes the color or brightness of the effect light projected from the floodlight 6 or the direction in which the effect light is projected. As shown in FIG. 6, instead of the floodlight 6, a projector 21 may be provided to project an optical image onto a screen 22 installed on the stage 8. In this modification, a plurality of optical image data are stored in the control device 5 instead of the effect scenario. Further, each of the optical image data stored in the control device 5 is associated with a combination _{of frequency components F 1} , F ₂ , ... F _n. The projector 21 is controlled by the control device 5 and can read the optical image data designated by the control device 5 from the control device 5 and project the optical image on the screen 22. The projector 21 is an example of the optical image reproduction projection means of the present invention.

Since it is configured in this way, according to the light effect device 1 according to the present modification, when a specific musical piece is output from the speaker 3 to the stage 8, a control signal is given prior to the output of the musical piece. Sound is output from the speaker 3 toward the stage 8. Then, the optical image data associated with the control signal sound is read out by the projector 21, reproduced, and projected on the screen. Therefore, no manpower is required to select and project an optical image. That is, it is not necessary for the person in charge to operate the control device 5 at the timing of starting the performance of the specific music to start the light effect by projecting the image. Alternatively, it is not necessary for the person in charge to select an image according to the music to be played and let the control device 5 perform the light effect by projecting the image.

In the above modification, the type of optical image projected by the projector 21 on the screen 22 is not limited. The optical image may be a still image or a moving image. Alternatively, a plurality of still images may be switched in a short time and continuously projected. The optical image may be a live-action image, or may be a handwritten or CG animation image.

The light effect device 1 may be provided with both a floodlight 6 and a projector 21 so that the light effect by the effect light and the light effect by the optical image can be switched simultaneously or sequentially.

(Second modification)
The control signal 31 recorded on the magnetic tape 7 may be the one shown in FIG. That is, as shown in FIG. 7, the control signal 31 is recorded on the magnetic tape 7 over a reproduction time of 600 ms. The control signal 31 is divided into three elements, a start signal 31S, a data signal 31D, and a finish signal 31F. The start signal 31S is a portion indicating the start of the control signal 31, and includes a specific frequency component indicating that the start signal 31S is the start signal 31S. The data signal 31D is a main body portion of the control signal 31, and includes a frequency component that is collated with a frequency component associated with the effect scenario stored in the storage unit 5b. The finish signal 31F is a portion indicating the end of the control signal 31, and includes a specific frequency component indicating that the finish signal 31F is the finish signal 31F.

Each of these signals is recorded on the magnetic tape 7 over a reproduction time of 200 ms. Further, the control signal 31 is recorded so as to fade in and fade out as a whole. That is, as shown in FIG. 8, the signal strength of the start signal 31S is set to 0 at the start and then gradually increased. In this way, the start signal 31S fades in. When the signal strength reaches the maximum value, the maximum value is maintained. This maximum value is maintained in the entire section of the data signal 31D, and is further maintained halfway through the finish signal 31F. After that, the signal strength of the finish signal 31F is gradually reduced to 0 at the end. In this way, the finish signal 31F fades out. If the control signal 31 is configured to fade in and fade out as a whole, the signal sound output from the speaker 3 fades in and out, making it more difficult for the audience to recognize the signal sound. On the other hand, since the signal strength of the data signal 31D is maximized, the occurrence of errors in the frequency analysis device 4 is suppressed.

Further, in the present modification, the control device 5 executes the light effect only when it recognizes that the control signal 31 includes the three elements of the start signal 31S, the data signal 31D, and the finish signal 31F. It is configured in. Therefore, according to this modification, it is possible to suppress the occurrence of malfunction due to noise.

As described above, according to the above-described embodiment and the light effect device 1 according to each modification, the light effect can be automatically performed according to the performance of the musical piece. Further, since the timing adjustment of the light effect does not require manual operation or judgment, the light effect can be labor-saving.

However, the technical scope of the present invention is not limited by the above-described embodiment and each modification. The present invention can be freely modified, applied, or improved within the scope of the technical ideas described in the claims.

In the above embodiment, the band of 17,700 to 19,300 Hz is exemplified as the band used for the acoustic signal, but the technical scope of the present invention is to use the band of 17,700 to 19,300 Hz. Not limited to. A band that is not used for the music output from the speaker 3 and is close to the upper limit of the human audible band can be arbitrarily selected. If the output from the speaker 3 is possible, a band exceeding the upper limit of the human audible band may be used for the acoustic signal.

In the above-described embodiment and the first modification, an example in which the light effect device 1 is installed in a place where the stage 8 is provided is shown, but the light effect device according to the present invention is installed in a place where the stage 8 is provided. It is not limited to things. The light effect device according to the present invention can be installed anywhere in a place where light effect is performed according to the performance of a musical piece.

In the first modification described above, an example is shown in which a screen 22 is provided at a place where the light effect device 1 is installed and an optical image is projected. However, the light effect device according to the present invention displays the light image on the screen 22. It is not limited to what is projected. The object on which the light effect device according to the present invention projects an optical image may be any object as long as it is in place. The object on which the optical image is projected may be, for example, a wall of a facility or a stage set temporarily installed on the spot. The object on which the light effect device according to the present invention projects an optical image is not limited to the one physically fixed on the spot. For example, an optical image may be projected onto a mist or smoke that is temporarily generated on the spot.

In the above-described embodiment and the first modification, an example in which the tape deck 2 and the speaker 3 form an acoustic output means is shown, but the acoustic output means of the present invention is not limited to the one provided with the tape deck 2. .. Further, in the above-described embodiment and the first modification, the magnetic tape 7 is exemplified as a specific example of the acoustic recording medium, but the acoustic recording medium of the present invention is not limited to the magnetic tape 7. In the acoustic output means of the present invention, various acoustic recording media can be arbitrarily selected and used. In short, it is sufficient for the acoustic recording medium to be able to record and read an acoustic signal, and the principle or configuration thereof is not limited. The principle or configuration of the acoustic output means is also not limited.

In the first modification described above, an example of storing the optical image data in the storage unit 5b of the control device 5 is shown, but the device for storing the optical image data is not limited to the storage unit 5b. The device for storing the optical image data may be externally attached to the control device 5. The optical image data may be recorded on a medium, and the optical image data may be read out from the medium.

The genre or composition of the music output by the optical effect device according to the present invention is not limited. The light effect device according to the present invention is not limited to the device that outputs all the components of the music. The light effect device according to the present invention may output a part of the components of the music. The light effect device according to the present invention may be used in combination with the performance of the live band, for example, and may add an accompaniment to the performance of the live band.

As described above, according to the light effect device 1 according to the above-described embodiment and each modification, the light effect can be automatically performed according to the performance of the musical piece. Further, since the timing adjustment of the light effect does not require manual operation or judgment, the light effect can be labor-saving.

1 Optical effect device, 2 Tape deck, 3 Speaker, 4 Frequency analyzer, 5 Control device, 5a Central processing unit (CPU), 5b Storage unit, 5c Input / output interface (I / O), 6 Floodlight, 6a Swivel rack 6a , 6b rocking rack, 7 magnetic tape, 7a, 7b track 7b, 8 stages, 9,10 waveform, 11 spectrum, 21 projector, 22 screen, 31 control signal, 31S start signal, 31D data signal, 31F finish signal

Claims (8)

An acoustic output means that reads out the music and the control signal from an acoustic recording medium on which the music and the control signal are recorded, and outputs the control signal together with the music to the outside in the form of an acoustic signal.
An acoustic signal analysis means that analyzes the acoustic signal derived from the control signal output from the acoustic output means and detects a frequency component included in the acoustic signal.
Light projection means that projects directing light,
A production scenario recording means for recording a plurality of production scenarios in association with a combination of specific frequency components, respectively.
The combination of the frequency components contained in the acoustic signal detected by the acoustic signal analysis means is collated with the combination of the frequency components associated with each of the plurality of production scenarios, and the frequency components included in the acoustic signal are collated. The effect light control means that reads the effect scenario associated with the combination of the above from the effect scenario recording means and changes the effect light projected by the light projection means based on the effect scenario.
A light production device equipped with. The effect light control means changes at least one of the color, brightness, and projection direction of the effect light projected by the light projection means with the passage of time.
The light effect device according to claim 1. An acoustic output means that reads out the music and the control signal from an acoustic recording medium on which the music and the control signal are recorded, and outputs the control signal together with the music to the outside in the form of an acoustic signal.
An acoustic signal analysis means that analyzes the acoustic signal derived from the control signal output from the acoustic output means and detects a frequency component included in the acoustic signal.
An optical image data recording means for recording a plurality of optical image data in association with a combination of specific frequency components, respectively.
An optical image reproduction projection means that reads out arbitrary optical image data recorded in the optical image data recording means, reproduces an optical image, and projects the optical image onto an object.
The frequency contained in the acoustic signal is collated with the combination of the frequency components contained in the acoustic signal detected by the acoustic signal analysis means and the combination of the frequency components associated with each of the plurality of optical image data. An optical image control means that reproduces optical image data associated with a combination of components in the optical image reproduction projection means and projects the optical image onto an object.
A light production device equipped with. The acoustic signal analysis means includes a frequency analysis means for detecting a frequency component included in a specific band of the acoustic signal.
The light effect device according to any one of claims 1 to 3. The frequency analysis means detects a set of frequency components constituting a remarkable peak in a frequency spectrum obtained by frequency analysis of the specific band of the acoustic signal.
The light effect device according to claim 4. The frequency analysis means constitutes each of a first peak showing the maximum signal strength and a second peak showing the signal strength next to the first peak in the frequency spectrum obtained by frequency analysis of the specific band of the acoustic signal. Detect the set of frequency components to be used,
The light effect device according to claim 5. The specific band is in the range of 17,700 to 19,300 Hz.
The light effect device according to any one of claims 4 to 6. The control signal recorded on the acoustic recording medium is between the start signal indicating the start of the control signal, the finish signal indicating the end of the control signal, and the start signal and the finish signal, and is analyzed by the frequency analysis means. Consists of three elements of the target data signal,
The light effect device according to any one of claims 4 to 7.

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