KR102220738B1 - Brainwave activity device for the treatment of depression and dementia and brainwave activity method using the same - Google Patents

Abstract

According to a heart rate according to the present invention, a brainwave activation device includes: a sensor unit which measures data on a user′s heart rate in real time and transmits the data; a processing module for receiving the data, generating and transmitting an output value determined in a preset frequency table according to the data; and an input unit for receiving the output value and inputting a binaural beat, corresponding to the output value, generated from a frequency of 20 Hz or more and 20,000 Hz or less to a user.

Description

Brainwave activity device for the treatment of depression and dementia and brainwave activity method using the same}

The present invention relates to an EEG stimulation apparatus for the treatment of depression and dementia, and an EEG stimulation method using the same, and more particularly, induction to generate a certain EEG (particularly effective alpha wave for treatment of depression and dementia) in conjunction with the user's heart rate. It relates to an EEG stimulation apparatus and a EEG stimulation method using the same.

The brain emits different frequencies according to each state, and it is known that if a signal of a certain frequency is continuously transmitted from the outside, such as sound or light, the brain waves also have the effect of synchronizing to the input frequency.

In general, brain waves between 13Hz and 21Hz are called beta waves, and they appear mainly in all conscious activity states when awake. EEG waves between 7Hz and 13Hz are called alpha waves, and they appear mostly in meditation or resting states, and are generally known as beneficial brain waves for humans. Brain waves between 4H and 7Hz are called theta waves and are mainly observed in sleep states, states that induce high creativity, and the like. In addition, brain waves of less than 4 Hz are called delta waves, and are known to be generated mostly in deep sleep.

EEG control technology is a technology that allows the constant EEG to be tuned to a desired frequency, and in the conventional case, there is a problem of artificially controlling EEG according to a user's manipulation.

The present invention relates to a device for inducing a specific brain wave to be generated naturally according to a certain sequence, not artificial brain wave control in conjunction with a user's heart rate.

Korean Patent Publication No. 10-0941135

The present invention is an invention conceived to solve the problems of the prior art described above, and is to provide an EEG activation device according to a heart rate.

In addition, it is to provide an EEG activation method using an EEG activation device according to a heart rate.

The problems of the present invention are not limited to the problems mentioned above, and other problems that are not mentioned will be clearly understood by those skilled in the art from the following description.

The brainwave activation device according to the heart rate of the present invention for achieving the above object is a sensor unit that measures data on a user's heart rate in real time, transmits the data, receives the data, and is preset according to the data. A processing module that generates and transmits an output value determined in a frequency table, and an input unit that receives the output value and inputs a binaural beat corresponding to the output value and generated from a frequency of 20 Hz to 20,000 Hz to the user Can include.

In this case, the frequency table comprises at least one of a first frequency of 13 Hz or more and 21 Hz or less, a second frequency of 7 Hz or more and less than 13 Hz, a third frequency of 4 Hz or more and less than 7 Hz, and a fourth frequency of 0.5 Hz or more and less than 4 Hz. You can do it.

Alternatively, the processing module compares the average value of the data for a certain time received from the sensor unit with the average value of the data for a certain time previously received, and the output value determined in the frequency table according to the average value of the compared data It may be characterized in that to generate.

And it may further include a display unit for providing the information of the frequency table to the user as an image.

Or a memory unit for storing a sound source, receiving the output value, and transmitting the sound source set to correspond to the output value to the input unit, wherein the input unit inputs the sound source transmitted from the memory unit to the user It can be characterized by that.

And it may further include a manipulation unit formed to enable the user to set the output value.

In the EEG activation method of the present invention for achieving the above object, in the EEG activation method using the EEG activation device according to the heart rate, the sensor unit measures data on the user's heart rate in real time and transmits the data. Step, an output value transmission step of receiving the data in a processing module, generating and transmitting an output value set in a preset table according to the data, and receiving the output value from an input unit, corresponding to the output value, and a frequency of 20 Hz or more and 20,000 Hz or less An output value input step of inputting a binaural beat generated from the binaural beat to the user may be included.

In this case, the output value transmission step includes a data comparison step of comparing the average value of the data for a certain time received from the sensor unit with the average value of the data for a certain time previously received, and the frequency according to the average value of the compared data. It may include an output value generation step of generating an output value determined in the table.

The brain wave activation device according to the heart rate of the present invention for solving the above problems and the brain wave activation method using the same have the following effects.

First, it is possible to induce adaptation naturally by activating an appropriate brain wave in conjunction with the user's heart rate rather than artificial manipulation.

Second, it is convenient to activate the set EEG in conjunction with the user's heart rate through the automatic mode.

Third, the user can maintain a comfortable state by the activated specific brain waves.

The effects of the present invention are not limited to the effects mentioned above, and other effects that are not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 is a system configuration diagram of an EEG activation device according to a heart rate of the present invention.
And Figure 2 is a flow chart for the brain wave activation method using the brain wave activation device according to the heart rate of the present invention.

Hereinafter, preferred embodiments of the present invention in which the object of the present invention can be realized in detail will be described with reference to the accompanying drawings. In the description of the present embodiment, the same names and the same reference numerals are used for the same components, and additional descriptions thereof will be omitted.

In addition, in describing an embodiment of the present invention, it is stated in advance that components having the same function are only used with the same names and symbols, and are not substantially identical to those of the related art.

In addition, terms used in the embodiments of the present invention are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise.

In addition, in the embodiments of the present invention, terms such as "include" or "have" are intended to designate the existence of features, numbers, steps, actions, components, parts, or a combination thereof described in the specification. It is to be understood that the possibility of the presence or addition of other features, numbers, steps, actions, components, parts, or combinations thereof, or further other features, is not excluded in advance.

With reference to FIG. 1, a device for activating an EEG according to a heart rate of the present invention will be described. 1 is a system configuration diagram of an EEG activation device according to a heart rate according to the present invention.

The brainwave activation device according to the heart rate of the present invention may include a sensor unit 100, a processing module 300, and an input unit 500.

The sensor unit 100 may measure data on a user's heart rate in real time and transmit the data.

Specifically, the sensor unit 100 is provided on one side of the brain wave activation device according to the heart rate of the present invention, and may measure the user's heart rate. The heart rate may vary according to the user's activity state or amount of activity, and the sensor unit 100 may measure it in real time and transmit related data to the processing module 300.

In addition, the sensor unit 100 may transmit a variable data value to the processing module 300 when a value of data on the user's heart rate changes. That is, when the sensor unit 100 compares the data obtained from the user with the data transmitted to the processing module 300 and falls within a preset range for the data transmitted to the processing module 300 In this case, data may not be transmitted to the processing module 300. In addition, if the data transmitted to the processing module 300 is out of a preset range, it is considered to have changed, and the data for this may be transmitted to the processing module 300. The preset range of the above-described example may be set to 5% to 10% according to the user's usage environment. However, of course, it is not limited thereto.

The sensor unit 100 may acquire data related to the user's heart rate by interworking with a smartwatch or the like. In this case, as a method of transmitting to the processing module 300, various short-range wireless communication methods such as Bluetooth and Wi-Fi may be adopted.

The processing module 300 receives data related to the user's heart rate measured and transmitted by the sensor unit 100, and generates an output value determined in a preset frequency table 310 according to the data, and the input unit 500 ) Can be sent.

Specifically, the processing module 300 may interlock with the sensor unit 100 to receive data on the user's heart rate measured in real time by the sensor unit 100 in real time. In addition, the data may be analyzed and matched with a preset frequency table 310 to generate an output value, and may be transmitted to the input unit 500.

Through this, it is possible to induce adaptation naturally by activating an appropriate brain wave in conjunction with the user's heart rate, not artificial manipulation.

At this time, the frequency table 310 is at least one of a first frequency of 13Hz or more and 21Hz or less, a second frequency of 7Hz or more and less than 13Hz, a third frequency of 4Hz or more and less than 7Hz, and a fourth frequency of 0.5Hz or more and less than 4Hz. It can be characterized by being made.

In general, the region of the first frequency is a beta wave, which is a type of brain wave, and is said to occur when a state of conscious activity or tension is present. The second frequency region is an alpha wave, which is a type of brain wave, and is known to be activated when meditating, resting, or concentrating. The region of the third frequency is theta wave, which is a type of brain wave, and it is reported that it is easy to obtain creative inspiration when the theta wave is activated. In addition, the fourth frequency region is a delta wave, which is a type of brain wave, and is said to occur in a deep sleep state.

Accordingly, the processing module 300, which received the data from the sensor unit 100, interlocks with the frequency table 310 from the user's three beats to receive an output value generated so as to activate a specific brain wave. I can send it to 500.

The input unit 500 receives a specific output value generated according to the data transmitted from the sensor unit 100 by the processing module 300, and is formed at a frequency of 20 Hz or more and 20,000 Hz or less corresponding to the output value. It is possible to create a binaural beat and input it to the user.

In addition, the input unit 500 may include an audio amplifier or earphone to generate a binaural bit to correspond to an output value transmitted from the processing module 300 and input it to the user.

The binaural beat is a sound produced when resonating different frequencies, and by simultaneously outputting a plurality of sound sources formed with different frequencies, some of them are canceled through the overlapping phenomenon, and the remaining vibrations are stimulated to the brain to activate brain waves. Known as a principle.

For example, when the processing module 300 generates an output value of 7 Hz or more and less than 13 Hz as an output value corresponding to the second frequency and transmits it to the input unit 500, the input unit 500 has a (Hz ), and a frequency from a-13 (Hz) to a-7 (Hz) on the other side, or from a+7 (Hz) to a+13 (Hz). I can.

At this time, the processing module 300 compares the average value of the data for a certain time received from the sensor unit 100 with the average value of the data for a certain time previously received, and according to the average value of the compared data. It may be characterized in that the output value determined in the frequency table 310 is generated.

The processing module 300 may derive an average value for a predetermined period of time with respect to data received from the sensor unit 100 in real time and compare the average value with a previous average value to automatically generate an output value according to the difference.

For example, when the user starts to use the EEG activation device according to the heart rate of the present invention, the average value of the data received from the sensor unit 100 for 10 minutes is 70. When the average value for 10 minutes decreases to 60, the processing module 300 may determine that the user is in a stable state and generate an output value for the second frequency or the third frequency.

Through such an automatic mode, a set brain wave can be activated in conjunction with the user's heart rate, so that the user can conveniently use it.

In addition, in consideration of the average value of the data acquired from the sensor unit 100 and the time to be used, the processing module 300 determines that the user is in a sleep state, the processing module 300 is By generating an output value for, it is possible to induce the user to reach a deep sleep state.

With respect to the above example, with respect to data related to the user's heart rate acquired through the sensor unit 100 in order to provide an activated brain wave more suitable for the user, the processing module 300 may learn or use the data. An output value may be generated in conjunction with time and transmitted to the input unit 500.

When the user is in a comfortable state, the average value is set, and when the heart rate changes rapidly, the range of the average value can be predicted by confirming it to the user.

For example, if the average value of the user's heart rate in a comfortable state is 70, and increases to 80 during use, whether the user is in a comfortable state or an exercise state is transmitted as an image state, and in a comfortable state according to the input transmitted by the user. You can adjust the average heart rate.

The brainwave activation device according to the heart rate of the present invention may include a display unit 600, a memory unit 700, an operation unit 800, or a charging unit 900.

The display unit 600 may provide the information of the frequency table 310 to the user as an image.

The display unit 600 is formed on one surface of the EEG activation device according to the heart rate of the present invention, so that the user can increase the convenience of operating the device. The display unit 600 may output various information related to the above-described example including the frequency table 310 as an image to the user.

The memory unit 700 may store a sound source, receive the output value, and transmit the sound source set to correspond to the output value to the input unit 500, and the input unit 500 includes the memory unit 700 The sound source transmitted from) may be input to the user.

That is, the memory unit 700 may store a sound source stored by a user or a sound source suitable for each situation, and transmit a specific sound source to the input unit 500 in association with the output value.

For example, the memory unit 700 stores so-called natural sounds such as the sound of a forest or water flowing as a sound source, and the output value from the processing module 300 corresponds to a second frequency, a third frequency, or a fourth frequency. In this case, the stored sound source may be transmitted to the input unit 500, and the input unit 500 may input the sound source to the user together with a binaural bit corresponding to an output value from the processing module 300.

Therefore, the user can maintain a comfortable state by the activated specific brain waves.

In addition, the manipulation unit 800 may be formed so that the user can set the output value.

That is, the user can set to arbitrarily output any one of the frequency tables 310 through the manipulation unit 800. In addition, the user may control the EEG activation device according to the heart rate of the present invention through the manipulation unit 800.

For example, the manipulation unit 800 may be provided in the form of a button to enable mode, volume control, sound source selection, and the like. However, it is obvious that the manipulation unit 800 is not limited thereto, and may be variously formed according to a configuration method of the device.

The charging unit 900 is formed so that a secondary battery or a general battery having a USB type can be inserted, and can supply power to each component.

With reference to FIG. 2, an EEG activation method using an EEG activation device according to a heart rate of the present invention will be described. 2 is a flow chart for a method of activating EEG using an EEG activating device according to the heart rate of the present invention. It can be understood that the same configuration in the EEG activation method using the EEG activation device according to the heart rate of the present invention to be described later has the same or similar purpose as the EEG activation apparatus according to the above-described heart rate.

The brainwave activation method using the brainwave activation device according to the heart rate of the present invention may include a data transmission step (S100), an output value transmission step (S300), and an output value input step (S500).

The data transmission step (S100) is a step in which the sensor unit 100 measures data on the user's heart rate in real time and transmits the data.

That is, the data transmission step (S100) is a step in which the sensor unit 100 measures data related to a heart rate that varies according to the user's activity state or activity amount in real time and transmits the data to the processing module 300. .

The output value transmission step (S300) is a step of receiving the data from the processing module 300, generating and transmitting an output value determined in a preset table 310 according to the data.

That is, in the output value transmission step (S300), the processing module 300 interworking with the sensor unit 100 receives data on the user's heart rate measured in real time by the sensor unit 100 in real time, and In this step, the data is analyzed and matched with a preset frequency table 310 to generate an output value and transmit it to the input unit 500.

In this case, the output value transmission step (S300) may include a data comparison step (S310) and an output value generation step (S330).

The data comparison step (S310) is a step of comparing the average value of data for a certain time received from the sensor unit 100 with the average value of data for a certain time previously received.

The processing module 300 may calculate an average value for a certain period of time with respect to the data acquired by the sensor unit 100 and calculate an average value for the same period of time for newly acquired data. In addition, the data comparison step (S310) is a step of comparing them to each other in order to derive an appropriate output value.

In addition, the output value generation step (S330) is a step of generating an output value determined in the frequency table 310 according to an average value of the compared data.

That is, the output value generation step S330 may generate an output value suitable for the user's use environment according to the comparison result of the average value obtained in the data comparison step S310.

The output value input step (S500) is a step of receiving the output value from the input unit 500 and inputting a binaural beat corresponding to the output value and generated from a frequency of 20 Hz or more and 20,000 Hz to the user. to be.

That is, the output value input step (S500) is a step of generating a binaural bit corresponding to the output value received from the processing module 300 in the input unit 500 and inputting it to the user.

By transmitting the data acquired and processed by the linkage between the sensor unit 100 and the processing module 300 to the input unit 500, it is possible to activate a suitable brain wave rather than an artificial manipulation to the user. Can induce you to adapt

As described above, preferred embodiments according to the present invention have been examined, and the fact that the present invention can be embodied in other specific forms without departing from its spirit or scope in addition to the above-described embodiments is known to those skilled in the art. This is obvious to them. Therefore, the above-described embodiments should be regarded as illustrative rather than restrictive, and accordingly, the present invention is not limited to the above description and may be modified within the scope of the appended claims and equivalents thereof.

100: sensor unit
300: processing module
310: frequency table
500: input
600: display unit
700: memory unit
800: control panel
900: live part
S100: data transmission step
S300: Output value transmission step
S310: Data comparison step
S330: Output value generation step
S500: Output value input step

Claims (8)

A sensor unit that measures data on a user's heart rate in real time and transmits the data;
A processing module for receiving the data and generating and transmitting an output value determined in a preset frequency table according to the data;
An input unit for receiving the output value and inputting a binaural beat corresponding to the output value and generated from a frequency of 20 Hz to 20,000 Hz to the user;
A display unit that provides the information of the frequency table to the user as an image;
A memory unit for storing a sound source, receiving the output value, and transmitting the sound source set to correspond to the output value to the input unit; And
An operation unit configured to allow the user to set the output value;
Including,
The sensor unit,
When the data is out of a preset range with respect to the data transmitted to the processing module, the data is transmitted to the processing module,
The processing module,
A specific output value is generated from the frequency table in consideration of the average value of data for a certain time received from the sensor unit and the time used, and a specific image is presented to the user through the display unit to check the current state of the user. And transmitting to the input unit according to the input transmitted by the user,
The frequency table,
Characterized in that consisting of at least one of a first frequency of 13 Hz or more and 21 Hz or less, a second frequency of 7 Hz or more and less than 13 Hz, a third frequency of 4 Hz or more and less than 7 Hz, and a fourth frequency of 0.5 Hz or more and less than 4 Hz,
The input unit,
The sound source transmitted from the memory unit is input to the user,
The operation unit,
The brain wave stimulation apparatus according to the heart rate, characterized in that formed so that the user can selectively output any one of the frequencies of the frequency table. delete delete delete delete delete delete delete

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