KR20240049995A - An Apparatus for Curing a Body Condtion by Generating a Soundtrack Based on a Peculiar Frequency - Google Patents

Abstract

The present invention relates to a device for treating human conditions by generating natural frequency basic sound sources. A treatment device that treats human conditions by measuring and analyzing natural frequencies and generating sound sources includes a natural frequency measurement module 11 that measures natural frequencies generated in the human body by the heart; A sound source generation module 12 that generates a sound source matching the measured natural frequency; and a biofeedback module 13 that feeds back the generated sound source to the human body.

Description

Apparatus for treating human condition by generating natural frequency basic sound source {An Apparatus for Curing a Body Condition by Generating a Soundtrack Based on a Peculiar Frequency}

The present invention relates to a device for treating human body conditions by generating natural frequency basic sound sources. Specifically, the present invention relates to a device for treating human body conditions by analyzing natural frequencies generated in the heart and generating matching sound sources in real time to induce changes in the human body condition for treatment. This relates to a device for treating human conditions by generating sound sources.

Natural frequencies are generated in the heart depending on the state of the human body, and the natural frequencies can be confirmed by measuring pulse waves. Pulse waves are waves that appear as the pulse is transmitted to the peripheral nerves. Cardiovascular conditions can be diagnosed using pulse waves, and pulse waves can change depending on stress, fatigue, sleep, tension, or similar human conditions. In relation to the diagnosis of physical condition using pulse waves, patent registration number 10-0954817 discloses a vascular health and stress test system and method using pulse wave signal analysis. Additionally, Patent Registration No. 10-1033035 discloses a health diagnosis control method of a pulse wave analysis device. However, prior art or known art does not disclose a treatment device that can improve the physical condition according to the results of such analysis. Depending on the analysis of the pulse wave or natural frequency, it is necessary to induce the pulse wave or natural frequency to change to a state favorable to the human body in real time, in the short term, or in the long term. However, the known technology does not disclose such technology.

The present invention is intended to solve the problems of the prior art and has the following purposes.

Prior art 1: Patent registration number 10-0954817 (Biosense Creative Co., Ltd., announced on April 28, 2010) Vascular health and stress test system and method using pulse wave signal analysis Prior art 2: Patent registration number 10-1033035 (Duruwell Co., Ltd., announced on May 3, 2011) Health diagnosis control method of pulse wave analysis device

The purpose of the present invention is to provide a human body condition treatment device by generating a natural frequency basic sound source that analyzes the natural frequency generated in the heart and generates a matching sound source in real time to induce changes in the human body condition and treat it.

According to a preferred embodiment of the present invention, a treatment device for treating a human body condition by measuring and analyzing natural frequencies and generating a sound source includes a natural frequency measurement module that measures natural frequencies generated in the human body by the heart; A sound source generation module that generates a sound source matching the measured natural frequency; and a biofeedback module that feeds back the generated sound source to the human body.

According to another suitable embodiment of the present invention, the natural frequency is measured by a pulse wave measurement module.

According to another suitable embodiment of the present invention, it further includes a pitch matching module for matching natural frequencies, a tone selection module, and an environmental sound selection module.

According to another suitable embodiment of the present invention, it further includes an LF/HF control module for balancing the sympathetic and parasympathetic nerves.

The human body condition treatment device using a natural frequency basic sound source according to the present invention analyzes the natural frequency of the heart, such as pulse waves, and based on that, generates a sound source that produces a beneficial effect on the human body, thereby improving the human body condition by creating a biological feedback. Let it improve. In addition, the treatment device according to the present invention relieves stress by restoring the balance between the low-frequency sympathetic nerve and the high-frequency parasympathetic nerve by feedback from the generated sound source. The treatment device according to the present invention generates various types of sound sources based on the heart's natural frequency or pulse wave analysis to restore the balance of the sympathetic, parasympathetic, or autonomic nervous system, improve immunity, and promote metabolism to prevent depression. Let it decrease. The treatment device according to the present invention can be combined with various treatment regimens, such as craniosacral therapy, for example, but is not limited thereto.

Figure 1 shows an embodiment of a human body condition treatment device by generating a natural frequency basic sound source according to the present invention.
Figure 2 shows an example of a structure in which a sound source becomes a biological feedback in the treatment device according to the present invention.
Figure 3 shows an example of a structure in which a sound source is generated in the treatment device according to the present invention.
Figure 4 shows an example of a process in which a sound source is created and becomes a biological feedback in the treatment device according to the present invention.
Figure 5 shows an example in which the treatment device according to the present invention is applied.

Below, the present invention will be described in detail with reference to examples shown in the attached drawings, but the examples are for clear understanding of the present invention and the present invention is not limited thereto. In the description below, components having the same reference numerals in different drawings have similar functions, so unless necessary for understanding the invention, the description will not be repeated, and well-known components will be briefly described or omitted, but the present invention It should not be understood as being excluded from the embodiments.

Figure 1 shows an embodiment of a human body condition treatment device by generating a natural frequency basic sound source according to the present invention.

Referring to Figure 1, the human body condition treatment device by generating a natural frequency basic sound source includes a natural frequency measurement module 11 that measures the natural frequency generated in the human body by the heart; A sound source generation module 12 that generates a sound source matching the measured natural frequency; and a biofeedback module 13 that feeds back the generated sound source to the human body.

The natural frequency measurement module 11 can measure the natural frequency according to the heartbeat generated in the human body, for example, pulse waves can be measured. Natural frequencies can be measured by various means, and can be various types of waves that occur in the human body, including pulse waves. The waveform measured by the natural frequency measurement module 11 may be analyzed, and a sound source may be generated by the sound source generation module 12 based on the analyzed waveform. Waveform analysis includes, for example, Beats Per Minute, waveform, amplitude, period uniformity, pulse duration or similar analysis. Additionally, waveform analysis includes the slope curve characteristics of the wave obtained by first-order differentiation or the curve displacement characteristics obtained by second-order differentiation. And waveform analysis includes sympathetic nerve characteristics corresponding to low frequency or parasympathetic nerve characteristics corresponding to high frequency. When the natural frequency obtained by the natural frequency measurement module 11 is analyzed in this way, a sound source can be generated by the sound source generation module 12 based on the analysis result. The sound source generation module 12 can store sound sources corresponding to various natural frequencies. The sound source generation module 12 may function to relax, amplify, or maintain the natural frequency measured by the natural frequency measurement module 11. A wave with a natural frequency such as a pulse wave measured by the natural frequency measurement module 11 may flow into the sound source generation module 12. With the inflow of waves, the sound source generation module 12 can automatically generate the corresponding sound source based on the analysis results, and can generate it in real time. When a sound source is generated in this way, it can be fed back into the human body by the biofeedback module 13. The biological feedback module 13 may include earphones, headphones, or similar means for listening to sound sources. Optionally, the biofeedback module 13 may include means for determining an input period control means, an input pattern control means, a volume control means, or a similar feedback type. The biological feedback means 13 may include various means for controlling the feedback pattern, including a sound source listening means, and the present invention is not limited thereby.

Figure 2 shows an example of a structure in which a sound source becomes a biological feedback in the treatment device according to the present invention.

Referring to FIG. 2, the pulse wave can be measured by the pulse wave measurement module 21, and the pulse wave can be, for example, in the form of a band-type measuring device worn on the wrist, or connected to a mounted body and worn on the wrist. It can be in the form of pincers or various similar forms. When the pulse wave is measured by the pulse wave measurement module 21, the low-frequency waveform corresponding to the sympathetic nerve and the high-frequency waveform corresponding to the parasympathetic nerve may be classified by the LF/HF waveform classification module 22. And the classified low-frequency waveform (LF) and high-frequency waveform (HF) can be analyzed by the waveform analysis module 23. The waveform analysis module 23 can analyze the characteristics of each low-frequency waveform (LF) and high-frequency waveform (HF). Additionally, the frequency characteristics, period characteristics, curve slope characteristics, or curve displacement characteristics of natural frequencies such as pulse waves may be analyzed by the waveform analysis module 23. When the waveform is analyzed by the waveform analysis module 23, a sound source can be generated by the sound source generation module. The sound source generation module includes a height matching module 24a that matches the height of the sound or the length of each sound according to the analyzed waveform; A tone matching module (24b) that changes the tone according to the change in waveform; and an environmental sound selection module 24c that selects environmental sounds according to high-frequency characteristics or low-frequency characteristics. The height of the sound can be created based on various types of melodies prepared in advance, and the length of each sound can be appropriately adjusted according to the period of the waveform. The height matching module 24a sets the height of the sound according to the waveform, and the length of each sound can be appropriately adjusted according to the slope of the waveform, the curve displacement or period of the waveform. The tone matching module 24b can select an appropriate tone from various types of instruments. For example, guitar, piano, cello, violin, viola, flute, trumpet, horn, drum, or various other types of instruments can be selected by the sound source selection module 24b. Various types of instruments can be classified in advance according to high-frequency characteristics corresponding to the parasympathetic nerve or low-frequency characteristics corresponding to the parasympathetic nerve, and can be matched based on this by the tone matching module 24b. An environmental sound may be selected by the environmental sound selection module 24c, and the environmental sound may be, for example, the sound of wind, the sound of birds, the sound of waves, the sound of waves, the sound of flowing water, the sound of scenery, the sound of insects, or similar sounds. It can include a variety of sounds occurring in nature. Such a height matching module (24a); Tone selection module 24b; And when the sound pitch matching, timbre, or environmental sound selection process is completed by the environmental sound selection module 24c, the related information may be transmitted to the matching sound source forming module 25. The matching sound source forming module 25 may generate a complete sound source by referring to the period of a natural frequency such as a pulse wave according to the matching and selection results. And the generated sound source can be fed back to the person through the sound source feedback module 26. The sound source feedback module 26 may include listening means such as earphones, headphones, or speakers, and may inject sound sources generated by various methods into a person, but the present invention is not limited thereto.

Figure 3 shows an example of a structure in which a sound source is generated in the treatment device according to the present invention.

Referring to FIG. 3, a natural frequency 32 may be generated due to the beating of the heart 31, and for example, a pulse wave may be measured. The natural frequency 32 generated from the heart 31 can exhibit various wave forms depending on the state of the human body, and the state waveform 33 can be analyzed in real time by the measurement module. When the state waveform is analyzed, a plurality of sound heights may be matched by the height matching module 34 according to the waveform. At the same time, the length of each sound can be determined, and the length of multiple sounds can be determined according to the period of the natural frequency 32. Once the pitch or length of the sound is determined by the height matching module 34, the tone can be selected by the tone selection module 35. Tones may be displayed in red, orange, yellow, green, blue, indigo, purple, or similar colors, and a color table may be created. Each color value may be determined in the color table, and the sound of each instrument for expressing the tone may be determined in advance to correspond to the color table. And the tone may be selected based on the analysis results of the sympathetic or parasympathetic nerves. Once the pitch, length, or timbre of the sound is determined in this way, the environmental sound can be selected. Once the environmental sound is determined, a sound source corresponding to the natural frequency 32 is generated, which can serve as a biological feedback. The natural frequency 32 is measured in real time, and based on this, a sound source can be generated in real time and serve as a feedback.

Figure 4 shows an example of a process in which a sound source is created and becomes a biological feedback in the treatment device according to the present invention.

Referring to FIG. 4, the pulse wave can be measured in real time by the pulse wave measuring device 41, the measured pulse wave can be searched in the wave pattern database 42a where the wave pattern of various pulse waves is stored, and the low frequency related to the sympathetic nerve Patterns and high-frequency patterns related to the parasympathetic nerves can be analyzed by the LF/HF pattern analysis module 42b. Additionally, the state index may be generated by the state index generation module 42c from the waveform pattern of the waveform natural frequency or the LF/HF pattern. For example, a state of lethargy, fatigue, anxiety, depression, or similar mental or physical state of the human body can be expressed as a numerical value by the state index. In particular, the stress state can be displayed by a state index, and the state index can be displayed as a value between 0 and 100. For example, the closer it is to 100, the more stressed it is, and the closer it is to 0, the less stressed it is. Such a condition index can be generated based on, for example, a test of the sympathetic and parasympathetic nerves (Heart Rate Variability Test), and the stress level can be evaluated thereby. When a waveform pattern is selected, the patterns of low and high frequencies are analyzed, and a state index is generated, a waveform that reduces the value of the state index is selected from the sound wave database 43a, a suitable tone is selected from the tone database 43b, and When an environmental sound is selected from the environmental sound database 43c, the waveform, tone, and Environmental sounds can be appropriately combined. Additionally, a sound source can be generated by the matching sound source generation module 45, and a feedback pattern can be created by the feedback pattern generation module 46. The feedback pattern creation module 46 can create a feedback pattern such as the number of repetitions, time, feedback interval, and size of the sound source in each repetition process at which the sound source is fed back. When a feedback pattern is created in this way, it can be fed back by the sound source feedback module 47, and the sound source feedback module 47 includes a hearing means such as earphones, headphones, or speakers. Optionally, the state detection module 48 may be attached to the human body, and the state detection module 48 may have a function of detecting the state of the human body, for example. For example, the state of the human body, such as pulse rate or brain waves, may be detected by the state detection module 48. Additionally, changes in natural frequency according to the feedback of the sound source can be detected by the state detection module 48. The detection result by the state detection module 48 may be transmitted to the pattern control module 49, and the pattern control module 49 adjusts the feedback pattern based on the result detected by the state detection module 48. Control pattern data can be generated and transmitted to the feedback pattern generation module 46. The feedback pattern creation module 46 can adjust the feedback pattern according to the control pattern data. The feedback pattern can be created in a variety of ways and is not limited to the presented embodiment.

Figure 5 shows an example in which the treatment device according to the present invention is applied.

Referring to FIG. 5 , the pulse wave measuring device 11 may be connected to the sound source generating device 52 to enable communication. The pulse wave measured by the pulse wave measuring device 11 may be transmitted to the sound source generating device 52 in real time, and a sound source corresponding to the pulse wave transmitted in real time may be generated by the sound source generating device 52. The sound source generating device 52 includes various sound source generating means described above and is capable of generating sound sources in real time. The generated sound source may be transmitted to the sound source pattern data module 53, and the sound source pattern data module 53 may have a function of processing the generated sound source so that it can be listened to easily and comfortably. The pattern sound source processed by the sound source pattern data module 53 is transmitted to the hearing means 54, so that people can listen in various ways. Changes in pulse waves can be detected by the pulse wave detection module 55a, and various human body states can be detected by the state detection module 55b. For example, pulse stability, brain wave changes, respiratory stability, muscle relaxation, or similar human body states may be detected by the state detection module 55b and transmitted to the state analysis module 56. Analysis information by the state analysis module 56 may be transmitted to the pattern data adjustment module 57, and the sound source pattern may be adjusted by the pattern data adjustment module 57. Specifically, sound source pattern control data may be generated by the pattern data control module 57 and transmitted to the sound source pattern data module 53. And the sound source pattern data module 53 can transmit sound source data adjusted by the sound source pattern adjustment data to the hearing means 54.

The sound source generating device 52 may generate a sound source based on the relief of chronic stress, short-term stress, or similar stress, but may also generate a sound source that may induce anxiety, depression, lethargy, airport disturbance, or similar changes in the human body condition. can be produced, and the present invention is not limited thereby.

Although the present invention has been described in detail above with reference to the presented embodiments, those skilled in the art will be able to make various variations and modifications without departing from the technical spirit of the present invention by referring to the presented embodiments. . The present invention is not limited by such variations and modifications, but is limited by the claims appended below.

11: Natural frequency measurement module 12 Sound source generation module
13: Biofeedback module 21: Pulse wave measurement module
24a: Pitch matching module 24b: Tone selection module
24c: environmental sound selection module 44a: LF/HF control module

Claims (4)

In a treatment device that measures and analyzes natural frequencies to generate sound sources to treat human conditions,
A natural frequency measurement module 11 that measures the natural frequency generated in the human body by the heart;
A sound source generation module 12 that generates a sound source matching the measured natural frequency; and
A treatment device including a biofeedback module (13) that feeds back the generated sound source to the human body. The treatment device according to claim 1, wherein the natural frequency is measured by a pulse wave measurement module (21). The treatment device according to claim 1, further comprising a pitch matching module (24a), a tone selection module (24b) and an environmental sound selection module (24c) for matching to natural frequencies. The treatment device according to claim 1, further comprising an LF/HF regulation module (44a) for balancing the sympathetic and parasympathetic nerves.