JP2006288572A - Brain wave induction device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a brain wave induction device which achieves the accurate induction of brain waves in a shorter time and enables the outputting of ultralow-frequency sounds optimal for the brain wave induction despite the required adjustment of the sound pressure level of audible sounds, for example, when the audible sounds are overlapped on the ultralow-frequency sounds outputted to human beings. <P>SOLUTION: The brain wave induction device has an ultralow-frequency signal generation part 3 which gets an electric signal inputted into an output part 5. The electric signal outputted by the ultralow-frequency signal generation part has a frequency within an range of 7-12 (Hz) outputted from the output part while corresponding to a sound wave with its sound pressure level within a range of 60-95 (dB). <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an electroencephalogram induction device used in an apparatus for inducing a human electroencephalogram to an α (alpha) wave.

It is said that when a human brain wave is in an alpha wave state of 7 to 12 (Hz), the human brain wave becomes relaxed and strengthens concentration, memory, thinking, and the like. Therefore, conventionally, an apparatus for guiding an electroencephalogram to an α wave has been considered. In such a device, a signal having the same frequency as that of the α wave is given to a person to induce the brain wave to the α wave.
For example, the device of Patent Document 1 outputs a very low frequency sine wave signal, such as an α wave or a θ wave, that is the same as an electroencephalogram component to be induced as an ultra low frequency sound through a plane wave speaker. Then, the brain is directly stimulated by the ultra-low frequency sound to induce an electroencephalogram.
It is also considered that a signal such as music is superimposed on the ultra-low frequency sound and output so that a person can be stimulated by the ultra-low frequency sound while listening to the music.
JP-A-9-51952

When using the device as described above to output ultra-low frequency sound and induce brain waves to alpha waves, the time taken by the subject to be induced to alpha waves varies greatly, and depending on the person Sometimes, I couldn't guide at all.
For this reason, in order to induce brain waves into α waves, the ultra-low frequency sound for stimulating the brain does not have to be in the region where the frequency is only α waves, but requires a certain amount of energy. Can be predicted.

However, the apparatus of Patent Document 1 does not focus on the output energy of ultra-low frequency sound, that is, the sound pressure level. When super-low frequency sound is superimposed on music or the like and output, the superimposed sound is amplified by an amplifier and output.
When a user listens to music or the like using this apparatus, the magnitude of music that is sound in the audible area can be adjusted to a desired level. However, along with the adjustment of the sound pressure level in the audible region, the sound pressure level of the very low frequency sound is also adjusted at the same time. Therefore, for example, when listening to music or the like with a small sound, it can be predicted that the sound pressure level of the ultra-low frequency sound will be lowered and the stimulation to the brain will be insufficient.

  An object of the present invention is to provide an electroencephalogram induction device capable of reliably inducing an electroencephalogram in a shorter time. In addition, for example, when an audible sound is superimposed on an ultra-low frequency sound output to a person, even if the sound pressure level of the audible sound is adjusted, an ultra-low frequency sound optimal for brain wave induction can be output. Is to do.

  1st invention is equipped with the ultra-low frequency signal generation part which inputs an electrical signal to an output part, and the electrical signal which this ultra-low frequency signal generation part outputs is 7-12 (Hz) output from the said output part And an electrical signal corresponding to a sound wave having a sound pressure level within a range of 60 to 95 (dB).

The second invention is premised on the first invention, and the ultra-low frequency signal generator is characterized in that 1 / f fluctuation is given to the electric signal.
A third invention is based on the first or second invention, and a sound data storage unit for storing sound data, a reproduction unit for reproducing sound data, and sound data reproduced through the reproduction unit are stored. The present invention is characterized in that it includes a superimposing unit that superimposes the electrical signal output from the ultra-low frequency signal generating unit.

The electric signal corresponding to the sound wave of the predetermined frequency and sound pressure is the sound signal of the predetermined frequency and sound pressure from the output unit when the electric signal is input to the output unit that outputs the sound wave. An electrical signal that is output.
Moreover, the sound wave in this invention is a vibration, and it does not matter whether it is an audible sound for human beings.

  The sound pressure level (dB (decibel)) is an index of the vibration energy of the sound wave calculated based on the sound pressure of the minimum sound wave of the sound wave in the human audible region. It matches the senses. The sound wave corresponding to the ultra-low frequency electric signal is a sound wave in a non-audible region, but the vibration pressure corresponding to the ultra-low frequency sound is also sound pressure using the same standard as the sound pressure level of the audible sound. It shall be expressed by level.

According to the first to third inventions, the brain wave can be reliably induced to the α wave in a short time.
According to the second invention, the electroencephalogram-inducing effect can be sustained even when used for a long time.

  According to the third aspect of the invention, it is possible to induce an electroencephalogram to an α wave while listening to music or learning materials. For example, in combination with music having a healing effect, the brain wave induction effect can be further enhanced. In addition, since learning can be performed in a state where comprehension and memory are improved by brain wave induction, the learning effect can be improved.

An embodiment of the present invention will be described with reference to FIGS.
FIG. 1 is a configuration diagram of an electroencephalogram guidance apparatus 1 which is an electroencephalogram guidance device according to the present invention. The electroencephalogram guidance apparatus 1 reproduces the sound data, an ultra-low frequency signal generating unit 2 that outputs an ultra-low frequency electric signal, a sound data storage unit 3 that stores sound data such as music and English conversation teaching materials, and the like. A reproduction unit 4 and an output unit 5 that superimposes the sound data reproduced by the reproduction unit 4 and the electrical signal output from the ultra-low frequency signal generation unit 2 and outputs the sound wave as a sound wave are provided.

The output unit 5 is a means for converting an electric signal into a sound wave, that is, vibration, such as a speaker.
Here, headphones are used as the output unit 5, and the user wears these headphones and listens to the sound output from the electroencephalogram guidance apparatus 1. In this embodiment, the output unit 5 has the function of the superimposing unit of the present invention, but an output unit that outputs an electrical signal as a sound wave and a superimposing unit may be provided separately.

The electrical signal output from the ultra-low frequency signal generator 2 is based on the sound wave output from the output unit 5 having a frequency of 8 (Hz) and a sound pressure of 70 (dB). Such an electrical signal. That is, the output unit 5 outputs an α wave that is a very low frequency sound having a sound pressure of 70 (dB).
However, the ultra-low frequency sound has a 1 / f fluctuation with 8 (Hz) as a fundamental frequency. For this purpose, the very low frequency signal generator 2 outputs an electrical signal of 8 (Hz) having 1 / f fluctuation. The above-mentioned 8 (Hz) signal having 1 / f fluctuation has an average frequency of 8 (Hz), but more precisely, all waves are not 8 (Hz) but 8 (Hz). Is a signal combining waves having a frequency shifted by several (Hz) before and after the center. And the intensity ratio of each frequency wave is 1 / f. It is known that sound waves having such 1 / f fluctuations feel comfortable.

  The reproduction unit 4 that reproduces the sound data stored in the sound data storage unit 3 has a function of adjusting the sound pressure level of the reproduced sound data. The size of the audible sound output from the output unit 5 can be adjusted. Therefore, sound pressure adjusting means (not shown) is provided.

As described above, the electrical signal from the ultra-low frequency signal generator 2 and the sound data from the playback unit 4 are input to the output unit 5. Since a signal is input, regardless of the sound data input from the playback unit 4, the ultra-low frequency component of the sound wave output from the output unit 5 is a frequency of 8 (Hz) and a sound pressure of 70 (dB). .
Therefore, when the user listens by adjusting the sound data output from the output unit 5 to a desired sound pressure level, the sound data includes an ultra-low frequency sound having a constant sound pressure level of 70 (dB). Are superimposed. Accordingly, stimulation of ultra-low frequency sound of 8 (Hz) and 70 (dB) acts on the brain of the user wearing the headphones connected to the electroencephalogram guidance apparatus 1.

When the subject's brain waves were measured in the state in which the above-mentioned brain wave guidance device 1 was outputting the ultra-low frequency sound, it was confirmed that the brain waves of all subjects were induced to α waves of 7 to 12 (Hz). It was.
In the electroencephalogram guidance apparatus 1, the ultra-low frequency signal generator 2 outputs an electrical signal corresponding to a sound wave having a frequency of 8 (Hz) output from the output unit 5. The output unit 5 outputs the electrical signal. The very low frequency sound to be performed is not limited to 8 (Hz) as long as it is 7 to 12 (Hz). It has been confirmed that the ultra-low frequency sound in the range of 7 to 12 (Hz) can efficiently induce brain waves to α waves.
The sound pressure level of the ultra-low frequency sound is not limited to 70 (dB). The sound pressure level may be a sound pressure within the range of 60 to 95 (dB). When an ultra-low frequency sound with a sound pressure level in this range is applied as a stimulus to the brain, the brain wave can be induced to an α wave.

Since it has been confirmed through experiments that the sound pressure range of 60 to 95 (dB) effectively acts on electroencephalogram induction, the experimental results will be described below.
In this experiment, an ultra-low frequency sound having a frequency of 8 (Hz) is output by changing its sound pressure level in a range of 40 to 90 (dB), and each of 20 subjects is connected with headphones. It acted on the human brain. Moreover, it was measured whether alpha wave was detected from a test subject's brain wave, while making the said ultra-low frequency sound act.

Then, the time from when the ultra-low frequency sound is output through headphones until the α wave is induced is measured, and the result is shown in the grab of FIG.
In the graph of FIG. 2, the horizontal axis is the induction time (seconds) to the α wave, and the vertical axis is the sound pressure level (dB), and the measurement results for each subject are indicated by circles “◯”.
That is, at sound pressure levels of 90 (dB), 75 (dB), and 65 (dB), all subjects were within 30 (seconds), and brain waves were induced to α waves. Moreover, when the sound pressure level is 50 (dB), the induction time of most subjects is 90 (seconds) or more, and there are some subjects who are not induced to α waves even after 180 (seconds) after a few. When the sound pressure level was further reduced to 40 (dB), the brain waves of the majority of subjects were not induced by α waves within 180 (seconds).

From this result, it was found that the sound pressure level induced by the α wave within 30 (seconds) of the brain waves of all subjects was 60 (dB) or more.
On the other hand, from another experiment, it was confirmed that the threshold value of the ultra-low frequency sound of 8 (Hz) was 105 (dB). The threshold value is a boundary value of a stimulus amount to which a person reacts. In the case of vibration of 8 (Hz), if the threshold value 105 (dB) is exceeded, the person feels vibration and is conscious. Therefore, although it cannot be heard as a sound, if a very low frequency sound exceeding the threshold value is continuously given, the person who receives the sound may feel nauseous, such as nausea.
Therefore, in the electroencephalogram guidance device of the present invention, the sound pressure level of the very low frequency sound output as a sound wave from the output unit is set within a range of 60 to 95 (dB). As a result, the brain wave can be efficiently induced into the α wave in a short time, and the mood is not deteriorated beyond the threshold value.

  Further, in the electroencephalogram guidance apparatus 1, 1 / f fluctuation is given to the electrical signal output from the ultra-low frequency signal generator 2 and output. As a result, the very low frequency sound output from the output unit 5 also has 1 / f fluctuation. Hearing audible sounds with 1 / f fluctuations has been shown to help people relax, but this was also true for very low frequency sounds. It can be confirmed that if the ultra-low frequency sound output from the electroencephalogram guidance apparatus 1 is given 1 / f fluctuation, the induction effect on the α wave lasts longer than when the ultra-low frequency sound without fluctuation is given. It was.

Since the brain wave guidance device 1 outputs the sound data together with the ultra-low frequency sound from the output unit 5, the brain wave can be guided to the α wave while listening to music or learning materials.
For example, by combining with sound data having a healing effect, it becomes possible to relax more. In addition, by inducing brain waves into α waves, learning can be performed with improved comprehension and memory, so the learning effect can be improved.
Furthermore, a terminal for connecting an external sound source may be provided in the sound data storage unit 3 so that sound data output from another device can be stored in the sound data storage unit 3 and used.

In the above embodiment, the electroencephalogram guidance apparatus 1 shown in FIG. 1 constitutes the electroencephalogram guidance device of the present invention, but only the ultralow frequency signal generator 2 constitutes the electroencephalogram guidance device of the present invention. May be.
If the electroencephalogram guidance device comprising the ultra-low frequency signal generator 2 is provided with a connection terminal for connecting to an output unit such as a speaker or a headphone, an arbitrary output unit can be connected to the connection terminal. it can.

Such an electroencephalogram guidance device can also be used by being incorporated in an apparatus that outputs sound. For example, if it is incorporated in a telephone handset and connected to a speaker, the stimulation of ultra-low frequency sound acts while listening to the voice of the other party, and the brain wave can be induced to α waves.
When using the electroencephalogram induction device of the present invention, it is not necessary to listen to sound data other than ultra-low frequency sound at the same time, but there is no sound data, and the state of wearing silence headphones is uncomfortable. is there. Therefore, if appropriate sound data is superimposed, the brain wave can be induced more naturally.

  Moreover, in the said embodiment, in order to make the frequency and sound pressure of the ultra-low frequency sound output from the output unit 5 constant, the frequency and amplitude of the electrical signal output from the ultra-low frequency signal generator 2 are made constant. However, the frequency and sound pressure of the sound wave output from the output unit 5 need not be constant.

For example, the electrical signal may change so that the frequency of the ultra-low frequency sound changes within a range of 7 to 12 (Hz), and the sound pressure output from the output unit 5 is also the sound pressure. May vary within the range of 60 to 95 (dB). Further, an adjusting means for the ultra-low frequency sound may be provided so that the user can adjust the frequency and sound pressure of such an ultra-low frequency sound. (Hz), 60-95 (dB) must not be exceeded.
However, as in the above-described embodiment, fixing the electrical signal output from the ultra-low frequency signal generator 2 can simplify the configuration of the device and reduce the manufacturing cost.

It is a block diagram which shows embodiment of invention. It is a graph of the experimental result which confirmed the relationship between a sound pressure level and an electroencephalogram induction time.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Electroencephalogram guidance apparatus 2 Very low frequency signal generation part 3 Sound data storage part 4 Reproduction part 5 Output part

Claims (3)

  An ultra-low frequency signal generation unit that inputs an electrical signal to the output unit is provided, and the electrical signal output by the ultra-low frequency signal generation unit has a frequency within a range of 7 to 12 (Hz) output from the output unit. An electroencephalogram induction device that is an electrical signal corresponding to a sound wave having a sound pressure level within a range of 60 to 95 (dB).   The electroencephalogram induction device according to claim 1, wherein the ultra-low frequency signal generation unit gives 1 / f fluctuation to the electrical signal.   A sound data storage unit that stores sound data, a reproduction unit that reproduces sound data, and a superimposition unit that superimposes the sound data reproduced via the reproduction unit on the electrical signal output from the ultra-low frequency signal generation unit The electroencephalogram guidance device according to claim 1 or 2.

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