TWI524880B - Biological Control System and Method for Biological Resonance - Google Patents

Description

Biological resonance wave acting on biological control system and method

The present invention relates to a biological resonance wave acting on a biological control system and method, and more particularly to a biological resonance wave corresponding to a variability according to physiological information of a living body, and the biological resonance wave is applied to the living body by resonance The role of the wave to achieve the purpose of regulating or transforming the biological resonance wave of the living organism.

Since everything has a fixed physical composition and structure, everything has its own specific resonant frequency. Any object that receives external energy with a resonant frequency for a period of time, such as mechanical vibration, electric field fluctuations, or radio waves, can accumulate these energies. Any fluctuation, no matter what form of energy, as long as it has a specific intensity and resonant frequency, can be called a resonant wave. A single organism, as small as a bacterium, as large as a human; at different levels, it may be cells (hepatocytes), tissues (muscle tissue), organs (lung), or even physiological systems (lymphatic system), because they have a certain complete boundary With the composition of the structure, the same kind of organisms will have similar resonance wave bands. Of course, different kinds of organisms may also have similar resonance wave bands. Any of the aforementioned biological levels, external magnetic energy waves, such as mechanical fluctuations (slap massage), electric field fluctuations (resonance wave health instrument) or radio waves (base metal far infrared rays), etc., under sufficient contact time. , has a clear reaction. Any fluctuation with a specific intensity and resonance frequency, which has an effect on a particular biological level, can be called this fluctuation as a biological resonance wave.

Furthermore, according to the theory of quantum medicine, all living organisms and living organisms have their own wave frequency (ie, biological resonance wave). When the human body is healthy, the biological resonance wave exhibited by the body is a coordinated fluctuation frequency. Conversely, when the biological resonance wave exhibited by the human body is an imbalance of the fluctuation frequency, it indicates that the organism is pathologically affected by functional deterioration, disease or harmonic interference of the virus. In general, the wavelength of human biological waves is between 3 and 45 micrometers (um). Because the human body can easily absorb the same radiant energy as its frequency or wavelength, the developer R. Rife of Canada Resonance Light Company The natural frequency of the human body has developed a resonance wave human health instrument, model "ProGen II 4024" instrument, the agent of which is Taiwan Resonance Wave Research and Development Co., Ltd. The wavelength of the generated electrical energy reflected by the instrument is between 4 and 20 micrometers (um), which is similar to the wavelength of human biological waves of 3 to 45 micrometers (um). When the electric energy wave is introduced into the human body, since the frequency of the electric energy wave is consistent with the cell movement frequency in the human body, the human body easily absorbs the electric energy wave and resonates with the cells in the body. There are also many studies that use electromagnetic fields to treat diseases such as cancer. However, because those studies are only looking for the stage of electromagnetic fields that are useful for certain diseases, there is no more specific and feasible product. The possible reasons should be It is these studies that do not have a control mechanism for the frequency or waveform of the mutated resonance wave, so that a more effective effect cannot be produced.

Furthermore, although the conventional resonant wave technique can resonate with the body tissue or cells of the human body by the electric energy wave, the human body can once again restore the originally coordinated fluctuation frequency; however, the conventional structure still has the following defects:

1. The resonant frequency of the conventional structure acts on the biological process, and the frequency of action is fixed and cannot be modulated. Therefore, only the experimental example-based inference can be used to set the frequency of the resonant wave. Therefore, the resonant wave emitted There must be a certain gap between the frequency and the biological fluctuation frequency, which makes it difficult for the resonance wave to form a resonance with the biological resonance wave, thereby affecting the effect of biological healing.

2. The conventional structure does not have the function of waveform modulation, so it is impossible to randomly combine two or more waveforms, so that the waveform of the resonance wave is a single waveform combination, so that the waveform change is lacking and the better feasible resonance waveform cannot be found. Therefore, the resonant wave emitted by it is more difficult to resonate with the biological resonance wave of the living being.

In view of the above-mentioned deficiencies caused by the conventional structure, the present inventors have actively worked on research and development, and finally developed a set of the present invention which can improve the aforementioned structural loss, and the effects achieved by the present invention are not effective in the above-mentioned conventional structures. In order to ensure the legal rights and interests of the invention, a patent application is filed in accordance with the law.

A first object of the present invention is to provide a control system and method for biological resonance waves acting on a living body. On the one hand, an analysis inference based on an experimental example can be used to set a frequency of action of a resonance wave, and on the other hand, a periodicity is applied to a frequency of action. Modulation correction, in order to find a better feasible frequency band, so that the organism can achieve the expected recovery or inhibition effect. To achieve the foregoing first object of the invention, the technical means adopted by the present invention includes a demand signal input unit, a control drive unit and a resonance wave transmitting unit. The demand signal input unit generates a demand signal based on physiological information of a living being. The control driving unit generates a driving command signal according to the demand signal. The resonant wave transmitting unit generates at least one resonant wave having variability according to the driving command signal, and causes the resonant wave to act on a living body having the same physiological information as the physiological information.

A second object of the present invention is to provide a control system and method for a biological resonance wave to act on a living body. On the one hand, an analysis inference based on an experimental example can be used to set an action frequency of a resonance wave, and on the other hand, a modulation frequency is applied to the action frequency. In order to find a better and feasible frequency band, the biological fluctuation frequency can be restored to a harmonious tone, thereby improving the effect of biological healing and health care. To achieve the foregoing second object of the invention, the technical means adopted by the present invention includes a demand signal input unit, a control drive unit and a resonance wave transmitting unit. The demand signal input unit generates a demand signal based on physiological information of a living being. The control driving unit generates a driving command signal according to the demand signal. The resonant wave transmitting unit generates at least one resonant wave having variability according to the driving command signal, so that the resonant wave acts on a living body having the same physiological information as the physiological information, wherein the frequency of the resonant wave follows Change with time.

A third object of the present invention is to provide a biological resonance control system and method for a biological resonance wave having a waveform modulation function, which mainly combines two or more waveforms in a random manner, and the waveform of the resonance wave includes two or more waveforms. Therefore, a better and feasible resonance waveform can be obtained, so that the emitted resonance wave can easily resonate with the biological fluctuation frequency to enhance the biological healing and health care effects. To achieve the foregoing third object of the invention, the technical means employed by the present invention is such that the variability resonance wave includes at least one wave in each period, and each of the waves is superposed by at least two waveforms.

A fourth object of the present invention is to provide a biological resonance control system and method for constructing a biological resonance wave, which is mainly used for establishing a plurality of physiological information such as biological organs and tissues, diseases and viruses in a database; or It is a parameter such as frequency modulation, waveform modulation and amplitude modulation of the resonance wave, so that the physiological information is corresponding to each demand signal, and is used as a basis for driving the command signal. In order to achieve the foregoing fourth object of the present invention, the technical means adopted by the present invention, in addition to the foregoing demand signal input unit, the control driving unit and the resonance wave transmitting unit, is such that the control driving unit is coupled to a database, and the information base can be used to establish a plurality of databases. The physiological information, when the demand signal is generated, can be obtained from the database by the control driving unit, and the driving instruction signal corresponding to the physiological information is generated.

A fifth object of the present invention is to provide a biological resonance control system and method for sensing biological information of a living body, which can be used as a frequency, amplitude or waveform correction of a resonance wave by instant sensing. The basis is that the resonant wave can easily resonate with the biological wave forming frequency of the biological, and can form a loop of carrier signal input with the living body, thereby carrying the resonant wave emitted by the resonant wave transmitting unit to the living body, thereby lifting the living body. For the receiving performance of the resonant wave. In order to achieve the foregoing fifth object, the technical means adopted by the present invention includes a sensing unit, a control unit and a resonant wave transmitting unit, and a carrier unit electrically connected to the living body. An input unit, the sensing unit is configured to sense the physiological information of the living body to generate a sensing signal for correcting the driving instruction signal, and the carrier input unit is configured to form a carrier between the biological and carrier input unit A circuit for inputting a signal to carry the resonance wave emitted by the resonance wave transmitting unit.

one. First embodiment of the present invention

Please refer to the first to third and seventh figures. The specific embodiment of the present invention includes a demand signal input unit 10, a control driving unit 20 and a resonance wave transmitting unit 30. . The demand signal input unit 10 generates a demand signal according to the physiological information of the living body. The control driving unit 20 generates a driving command signal according to the demand signal. The resonant wave transmitting unit 30 can generate at least one resonant wave having variability according to the driving command signal, so that the variant resonant wave can be applied to the living body having the same physiological information as the physiological information. The variability resonance wave can be a frequency variation or a waveform variation, and it is easier to find an effective resonance wave acting on the living body due to its variability. As shown in the first figure, a specific embodiment of the resonant wave emitting unit 10 of the present invention is a light source emitter capable of emitting light waves of a specific frequency, which comprises a light emitting diode and a long light guiding member, and emits light. The diode emits a plurality of light waves, and the plurality of light waves are distributed on the peripheral surface of the light guide member and are emitted outward. As shown in the second figure, another specific embodiment of the resonant wave transmitting unit 10 of the present invention is a radio wave transmitter which can emit electromagnetic waves of a specific frequency. As shown in the third figure, another specific embodiment of the resonant wave transmitting unit 10 of the present invention is a combination of an audio amplifier and a speaker which can emit sound waves of a specific frequency.

two. Second embodiment of the invention

Referring to the first to third and seventh figures, this embodiment is a specific embodiment for achieving the second object of the present invention, except that the demand signal input unit 10, the control driving unit 20, and the resonance as in the first embodiment described above are included. The wave emitting unit 30 is outside. The specific embodiment of the variability resonance wave of the present invention is such that the frequency of the resonance wave changes with time during the action period, and a more specific embodiment thereof is as follows.

As shown in the eleventh (d), the frequency of the variability resonance wave changes gradually as the time increases. As shown in the figure (d) of the tenth figure, the frequency variation mode of the variability resonance wave gradually increases in frequency with time, and the relationship between the frequency and the time is wavy in at least one time period in the action period. shape.

As shown in Fig. 11(b), the frequency of the variability resonance wave changes gradually as the time increases. As shown in the figure (b) of the tenth figure, the frequency variation mode of the variability resonance wave gradually decreases with increasing time, and the relationship between the frequency corresponding time and the time is at least for a time period in the action period. shape.

As shown in the eleventh (a), (c) and twelfth (c), the frequency of the variability resonance wave changes first and then decreases with time. As shown in the tenth (a), (c) and twelfth (c), the frequency of the variability resonance wave changes first and then decreases with time, and there is at least one during the action period. In the time zone, the relationship diagram of the frequency corresponding time is wavy, as shown in the figure (a) of the tenth figure, which is wavy in the section with decreasing frequency; as shown in the figure (c), it is at the frequency. The incremental segments are wavy; as shown in the tenth (c), the segments are frequency-increasing and the frequency decreasing is wavy.

As shown in the twelfth figure (a), the frequency variation mode of the variability resonance wave first decreases and then increases the frequency with time, and the frequency corresponds to the time relationship in at least one time period in the action period. The figure is wavy, as shown in Fig. 12(a), which is wavy in the sections of increasing frequency and decreasing frequency.

As shown in Fig. 12(b) and (d), the frequency variation of the variability resonance wave is an increasing and decreasing frequency of alternating with time. As shown in the twelfth figure (b), the frequency variation of the variability resonance wave increases first, then decreases, then increments the frequency, and the frequency corresponds to at least one time period in the action period. The time diagram is wavy, as shown in Fig. 12(b), which is wavy at least in a frequency increment and a frequency decreasing section. As shown in the twelfth figure (d), the frequency variation of the variability resonance wave decreases first, then increases, then decreases, and then decreases the frequency, and the frequency corresponds to at least one time period in the action period. The time diagram is wavy, as shown in Fig. 12(d), which is wavy at least in a frequency increment and a frequency decreasing section.

As shown in (a), (b), (c) and (d) of the thirteenth figure, the frequency variation of the variability resonance wave is an increasing and decreasing alternating frequency as time increases, and during the action period The relationship between the frequency and the time is at least one wave in at least one time zone. As shown in the thirteenth (a) and (b), the frequency is first decremented. As shown in Figures 13 (c) and (d), the time starts with the frequency increasing first.

Participation. Third embodiment of the present invention

Referring to the first to third and seventh figures, this embodiment is an embodiment of the third object of the present invention, including a demand signal input unit 10, a control drive unit 20, and a resonance wave transmitting unit 30. And other technical features. The demand signal input unit 10 generates a demand signal according to the physiological information of the living body. The control driving unit 20 generates a driving command signal according to the required signal, wherein the varisive resonant wave can include at least one wave in each period, and each of the waves is superposed by at least two waveforms. The waveform can be a sine wave, a square wave or a triangular wave, so that the waveform of the resonance wave is a superimposed combination or a multiplied combination of two or more waveforms, as shown in the sixth figure, so that a better viable resonance can be found. The waveform allows the emitted resonance wave to easily resonate with the biological fluctuation frequency to enhance the biological healing and health care effects.

Hey. Fourth embodiment of the invention

Please refer to the first to third and seventh figures. In this embodiment, an embodiment of the fourth object of the present invention includes a demand signal input unit 10, a control drive unit 20, a database 24, and a Technical characteristics such as the resonance wave transmitting unit 30. The demand signal input unit 10 generates a demand signal according to the physiological information of the living body. The control driving unit 20 generates a driving command signal according to the demand signal. The resonant wave transmitting unit 30 can generate at least one resonant wave having variability according to the driving command signal, so that the resonant wave can act on the biological information having the same physiological information as the physiological information. The control driving unit 20 is connected to the database 24, and the database 24 establishes a plurality of physiological information including different organs and tissues, diseases and viruses of the living body; or the frequency, waveform and amplitude of the resonance wave. Variable parameter, the above physiological information refers to the fluctuation frequency generated by the tissue parts of various organs of the living body; for example, the physiological information may be the amplitude information of the fluctuation frequency corresponding to the internal organs of the human body (ie, the biological resonance wave) and the amplitude of the fluctuation frequency Such information; or information such as high frequency harmonics caused by diseases and viruses. When the demand signal input unit 10 generates the demand signal, after the control driving unit 20 interprets the physiological information, the physiological information can be obtained from the database 24 to generate a corresponding driving command signal, thereby controlling the resonant wave transmitting unit 30. The frequency, waveform, or amplitude of the resonant wave.

Wu. Fifth embodiment of the present invention

Please refer to the first to third and fifth and seventh embodiments. In this embodiment, an embodiment of the fifth object of the present invention includes a demand signal input unit 10, a control driving unit 20, and a sensing unit 40. Technical features such as a carrier input unit 50 and a resonant wave transmitting unit 30. The demand signal input unit 10 generates a demand signal according to the physiological information of the living body. The control driving unit 20 generates a driving command signal according to the demand signal. The resonant wave transmitting unit 30 can generate at least one resonant wave having variability according to the driving command signal, so that the resonant wave can act on the biological information having the same physiological information as the physiological information. The sensing unit 40 of the present invention is configured to sense physiological information of the living body to generate a sensing signal that can be used as a basis for correcting the driving command signal. Moreover, the sensing unit 40 outputs a weak electrical signal to the living body through the feeding end 41, and then places the sensing end 42 of the sensing unit 40 on the part of the biological tissue to be detected, thereby forming a feedback sensing. The loop, in turn, produces a pair of sensing signals for the desired portion. The carrier input unit 50 is in a state of being electrically connected to the living body, that is, the carrier input unit 50 has a positive electrode end 51 and a negative electrode end 52 for outputting a single frequency or variable frequency carrier signal to the living body, and The biological device can form a grounded state through a grounding device 53, so that the positive electrode terminal 51 and the negative electrode terminal 52 of the biological and carrier input unit 50 form a carrier signal input loop, thereby carrying the resonant wave emitted by the resonant wave transmitting unit 30. In vivo, to enhance the biological performance of the resonance wave, as shown in the fifth figure.

In the embodiment, the specific embodiment of the demand signal input unit 10 includes a display 11 and an operation interface 12, as shown in the first to third figures, so that the user can display the operation interface 12 displayed on the display 11. Control the options to generate a demand signal, such as entering one of the organs of the body. Referring to FIG. 7 , the specific embodiment of the control driving unit 20 includes a signal conversion circuit 21 for converting the sensing signal of the sensing unit 40 into a digital signal, and a waveform generator 22 . And a driving circuit 23, the driving circuit 23 can be driven by the waveform generator 22 to drive the resonant wave transmitting unit 30 to generate a resonant wave. The waveform generator 22 can be compared with the database 24 when the demand signal is interpreted. Corresponding physiological information corresponding to the demand signal, and simultaneously outputting a driving command signal corresponding to the physiological information, the driving command signal may be composed of a single waveform such as a sine wave, a square wave or a triangular wave, as shown in the sixth figure, and the waveform is , frequency and amplitude can be modified according to actual needs. When the drive circuit 23 is triggered by the waveform generator 22, the drive command signal is transmitted to the resonance wave transmitting unit 30.

land. Implementation of the specific operation of the present invention

Referring to the first to third figures, when the user wants to perform energy therapy or health care of the resonance wave, the user can control the tissue part of the health care organ in the operation interface 12 displayed on the display 11, thereby generating a demand. The signal, when the control driving unit 20 interprets the demand signal, can compare the physiological information corresponding to the demand signal (such as the fluctuation frequency information of each organ tissue part) in the database 24, and modulate the required information according to the physiological information. The driving command signal of the waveform, the frequency and the amplitude, the type of the waveform may be a sine wave, a square wave or a triangular wave, as shown in the sixth figure; at the same time, the resonant wave transmitting unit 30 can be driven by the driving command signal. The resonance wave corresponding to the above demand signal can adjust or convert the fluctuation frequency of the organ tissue portion of the human body. When the resonance wave is converted into light, sound or electromagnetic waves by the energy ions and penetrates into the tissue parts of the human body, it will form a resonance with the tissue part of the human body, so that the organ tissue part of the human body obtains a relatively uniform fluctuation frequency, and further A health benefit that is extremely beneficial to the human body.

On the other hand, as shown in the seventh figure, the sensing unit 40 can output a weak electrical signal to the user through the feeding end 41, and then place the sensing end 42 of the sensing unit 40 on the user to be detected. A sensing circuit is formed on the part of the organ tissue to generate a sensing signal of a pair of parts, and the control driving unit 20 converts the sensing signal into a digital signal, and performs Fourier transform on the digital signal. It is a waveform signal of a frequency domain, and is compared with the corresponding physiological information in the database 24 (such as the spectrum information of the selected organ tissue part), and then the driving command signal to be output is corrected according to the comparison result, so that the resonance can be corrected. The waveform, frequency, or energy amplitude of the resonant wave emitted by the wave transmitting unit 30. Moreover, when the comparison result determines that the organ tissue site has a disease or a harmonic interference of the virus, the control driving unit 20 controls the resonance wave emitted by the resonance wave transmitting unit 30 to be inverted with the disease or the virus harmonic. The waveform is used to neutralize the frequency of weakening the disease or the virus. When the disease or the fluctuation frequency of the virus is neutralized and weakened, the control driving unit 20 outputs a driving command signal corresponding to the physiological information of the organ tissue portion, and drives the resonance wave emitting unit 30 to emit physiological information corresponding to the organ tissue portion. The resonance wave can thus adjust or transform the fluctuation frequency of the organ tissue of the human body.

Specifically, when the demand signal is generated, the control program built in the control driving unit 20 sets an active frequency range of the resonant wave based on an experimental example-based analysis inference. As shown in the fourth figure, the operating frequency range is The spectrum is defined between the A (Hz) band and the B (Hz) band, and the active frequency range is divided into high frequency band, middle frequency band and low frequency band, and is further divided into high frequency HHF, high intermediate frequency HMF and high in the high frequency band. Low-frequency HLF; further divided into medium-high frequency MHF, medium-intermediate frequency MMF and medium-low frequency MLF in the middle frequency band; and low-frequency LHF, low-intermediate frequency LMF and low-low frequency LLF in the low frequency band, thereby forming nine frequency options, The nine frequency options can be regarded as the corresponding physiological information, that is, each physiological information includes nine sets of frequency options, so that the control driving unit 20 can generate a corresponding driving command signal. As for the frequency option combination, it can be preset according to the user's needs or experimental examples.

Further, the control program can combine nine sets of frequency options to gradually change toward a high frequency along a time axis. For example, according to low-low frequency LLF-low intermediate frequency LMF-low-high frequency LHF-medium-low frequency MLF-medium frequency MMF-medium high frequency MHF-high and low frequency HLF-high intermediate frequency HMF-high frequency HHF, etc. Drive command signal; or combine nine sets of frequency options to gradually change to a low frequency along a time axis, for example, according to high-frequency HHF-high intermediate frequency HMF-high and low frequency HLF-medium high frequency MHF- Medium intermediate frequency MMF-medium-low frequency MLF-low-high frequency LHF-low-intermediate frequency LMF-low-low frequency LLF, etc. sequentially output driving command signals of different frequencies, so that the driving command signal can drive the resonant wave transmitting unit 30 to emit as described above. Frequency-modulated variability resonance wave. Of course, the frequency options do not have to be combined in the manner described above, or they can be combined in a random mix.

Hey. Experimental example of the present invention

Please refer to the attached figure shown in Figure 1, which is the principle analysis diagram of bioresonance wave, in which the frequency Frequency (F) is the core concept of resonance; the intensity Amplitude (A) is the necessary condition for forming the resonance wave, which is enough to drive the organ. In terms of minimum energy; duty cycle Dutycycle(D) is the necessary condition for forming a resonance wave, and provides a minimum period that can generate fluctuations; the impulse frequency Pulserate(P) is a low-frequency resonance frequency of a physiological level. Please refer to the attached FIG. 2, which is an experimental example of the resonance wave of Escherichia coli according to the present invention. It is known from the experimental results that the level of bacteria performing resonance wave control is significantly lower than that of the unresonant wave control (experiment). Therefore, the resonance wave can effectively control the bacterial level of E. coli. The invention also carries out experiments on resonance wave of breast cancer cells, and it is known from the experimental results that the cell level of the breast cancer cells subjected to resonance wave control is significantly lower than that of the breast cancer cells not controlled by the resonance wave, and therefore, the resonance wave can indeed Effectively control the cell level of breast cancer cells, thereby demonstrating that the resonance wave can indeed regulate or transform the fluctuation frequency of the organ tissue of the human body, thereby improving the health of the human body.

As shown in the eighth figure, it is a schematic diagram of the operation of the resonance wave frequency modulation of the diabetic patient in the present invention. First, in the I time section, the action frequency is gradually decreased from 20000 Hz to 3000 Hz, and the action time of the resonance wave is about 3 minutes; in the II time zone, the frequency of action is gradually reduced from 3000Hz to 1000Hz, the action time of the resonant wave is about 3 minutes; in the III time zone, the frequency of action is gradually reduced from 1000Hz to 500Hz, the resonance wave The action time is about 9 minutes; in the IV time zone, the action frequency is gradually decreased from 500 Hz to 100 Hz, and the action time of the resonance wave is about 10 minutes; in the V time zone, the action frequency is gradually decreased from 100 Hz to 0 Hz, and the resonance The action time of the wave is about 10 minutes, the total time spent is about 35 minutes, and the curve of the overall connection is as shown in the eighth figure.

Furthermore, as shown in the ninth figure, it is a schematic diagram of the manipulation of the resonance wave frequency modulation of the patient infected with mold in the present invention. First, in the I time zone, the frequency of action gradually decreases from 23000 Hz down to After the low position of 1700 Hz, the frequency is increased upwards to 3000 Hz, and the resonance wave action time in this section is about 3 minutes. In the II time zone, the frequency of action decreases from 3000 Hz down to 850 Hz. After the low position, the frequency is increased up to 1500 Hz, and the resonance wave action time is about 4 minutes. In the III time zone, the action frequency gradually decreases from 1500 Hz down to the low point of 150 Hz, then it is reversed. Turn to the upper incremental frequency to 700Hz, the resonance wave action time is about 6 minutes; in the IV time zone, the action frequency gradually decreases from 700Hz down to the low point of 100Hz, the resonance wave action time is about 9 minutes; In the time zone, the action frequency gradually decreases from the 100Hz down to the lowest point. The resonance wave action time is about 11 minutes, and the total time is about 33 minutes. The overall connected curve is as shown in the ninth figure.

eight. in conclusion

Therefore, with the above-described structural arrangement, the present invention does have the following features:

1. On the one hand, the invention can set the frequency of the resonance wave according to the inference analysis based on the experimental example, and on the other hand, perform periodic modulation correction on the action frequency, thereby finding a better feasible frequency band to make the biological The frequency of fluctuations can be restored to a harmonious tone, thereby enhancing the effects of biological healing and health care to enhance human health and health benefits.

2. The invention has a waveform modulation function, so that two or more waveforms can be randomly combined, and the waveform of the resonance wave includes two or more waveforms, so that it is possible to find a better and feasible resonance waveform and let the emitted resonance Waves are more likely to resonate with biological fluctuation frequencies to enhance biological healing and health care.

3. The invention has a database for establishing physiological information including multiple organs, diseases and viruses of different organs, or frequency modulation, waveform modulation and amplitude modulation of the resonance wave, etc. The physiological information is corresponding to each demand signal, and serves as a basis for driving the command signal.

4. The invention can not only be used as the basis for the frequency, amplitude or waveform correction of the resonance wave by the instant sensing, so that the resonance wave can easily resonate with the biological wave forming frequency of the biological body, and can form with the living body. The input loop of a carrier signal is used to carry the resonance wave emitted by the resonant wave transmitting unit to the living body, thereby improving the receiving performance of the living body for the resonant wave.

The above is only one of the possible embodiments of the present invention, and is not intended to limit the scope of the patents of the present invention, and the equivalent implementations of other changes according to the contents, features and spirits of the following claims are It should be included in the scope of the patent of the present invention. The invention is specifically defined in the structural features of the request item, is not found in the same kind of articles, and has practicality and progress, has met the requirements of the invention patent, and has filed an application according to law, and invites the bureau to approve the patent according to law to maintain the present invention. The legal rights of the applicant.

10. . . Demand signal input unit

11. . . monitor

12. . . Operation interface

20. . . Control drive unit

twenty one. . . Signal conversion circuit

twenty two. . . Waveform generator

twenty three. . . Drive circuit

twenty four. . . database

30. . . Resonant wave launching unit

40. . . Sensing unit

41. . . Feed end

42. . . Sensing end

The first figure is a schematic diagram of the implementation of the resonant wave of the present invention as a light wave energy pattern.

The second figure is a schematic diagram of the implementation of the resonant wave of the present invention as an electromagnetic wave energy pattern.

The third figure is a schematic diagram of the implementation of the resonant wave of the present invention as an acoustic energy pattern.

The fourth figure is a schematic diagram of the spectral range division of the resonant wave frequency of the present invention.

The fifth figure is a schematic diagram of an implementation architecture of the carrier input organism of the present invention.

The sixth figure is a schematic diagram of an implementation architecture of the mode modulation of the resonant wave of the present invention.

The seventh diagram is a schematic diagram of the control block of the basic architecture of the present invention.

The eighth figure is a schematic diagram showing the relationship between the frequency of action and time of the present invention.

The ninth diagram is a schematic diagram showing another relationship between the frequency of action and time of the present invention.

The tenth figure is a first implementation diagram of the frequency modulation of the present invention.

The eleventh figure is a second implementation diagram of the frequency modulation of the present invention.

The twelfth figure is a third implementation diagram of the frequency modulation of the present invention.

The thirteenth drawing is a fourth implementation diagram of the frequency modulation of the present invention.

Attachment: Fig. 1 is a schematic diagram of the analysis of the resonance wave and the biological resonance wave; Fig. 2 is a schematic diagram of the control action of the resonance wave control and the uncontrolled control of the present invention.

10. . . Demand signal input unit

11. . . monitor

12. . . Operation interface

20. . . Control drive unit

30. . . Resonant wave launching unit

Claims (10)

A biological resonance wave acts on a biological control system, comprising: a demand signal input unit, generating a demand signal according to physiological information of a living body; a control driving unit, generating a driving command signal according to the demand signal; and a resonance wave a transmitting unit, configured to generate at least one resonant wave having a variability according to the driving command signal, wherein the resonant wave acts on a living body having the same physiological information as the physiological information during a working period, and the resonant wave system is The energy form of the electromagnetic wave, the variability resonance wave is in the action period, the frequency of the resonance wave changes with time, and further includes a sensing unit, and a carrier that is electrically connected to the biological body An input unit, configured to sense a physiological information of the living being, to generate a sensing signal for correcting the driving command signal, where the carrier input unit is configured to form a carrier signal between the biological and carrier input unit The input circuit is configured to carry the resonant wave emitted by the resonant wave transmitting unit. The bioresonant wave according to claim 1 acts on a biological control system, wherein the variability resonance wave system includes at least one wave in each period, and each of the waves is superposed by at least two waveforms. The bioresonant wave of claim 1 is applied to a biological control system, wherein the control driving unit is coupled to a database, the information base is configured with the physiological information, and when the demand signal is generated, the control driving unit is The database obtains the physiological information to generate the driving command signal, and the control driving unit converts the sensing signal into a frequency domain waveform signal, and compares the corresponding physiological information in the database, when When the result of the comparison determines that the organism has a disease or a harmonic interference of the virus, the control driving unit controls the resonance wave emitted by the resonance wave transmitting unit to be a waveform inverted from the disease or the virus harmonic. When the disease or the fluctuation frequency of the virus is neutralized and weakened, the control driving unit outputs the driving instruction signal corresponding to the physiological information of the creature. The biological resonance wave according to claim 1 or 3 is applied to a biological control system, wherein the physiological information includes physiological information of different organ tissues, diseases, viruses, and the like of the living body; or the frequency and waveform of the resonance wave. Modulation parameters such as amplitude and amplitude. The biological resonance wave according to claim 4 acts on a biological control system, wherein the disease is selected from one of breast cancer and diabetes. The biological resonance wave according to claim 4 acts on a biological control system, wherein the virus is selected from one of Escherichia coli and mold. The biological resonance wave according to claim 4 acts on the biological control system, wherein the resonant frequency of the resonant wave includes a high frequency band, a middle frequency band, and a low frequency band, and is further divided into a high frequency HHF and a high intermediate frequency in the high frequency band. HMF and high and low frequency HLF; further divided into medium and high frequency MHF, medium and medium frequency MMF and medium and low frequency MLF in the middle frequency band; and divided into low frequency high frequency LHF, low intermediate frequency LMF and low frequency low frequency LLF in the low frequency band, thereby forming nine kinds of Frequency of action option. A biological resonance wave acting on a biological control method, comprising: providing a system according to claim 1, wherein the demand signal input unit generates a demand signal according to physiological information of a living body; The control driving unit generates a driving command signal according to the demand signal; and the resonant wave transmitting unit generates at least one resonant wave having the variability and the energy of the electromagnetic wave according to the driving command signal, so that the resonant wave acts on In an organism having the same physiological information as the physiological information, the variability resonance wave is in the action period, and the frequency of the resonance wave changes with time, wherein the sensing unit further includes a sensing unit, and a a carrier input unit electrically connected to the living body, the sensing unit is configured to sense the physiological information of the living body to generate a sensing signal for correcting the driving instruction signal, and the carrier input unit is configured to enable the biological A loop of a carrier signal input is formed with the carrier input unit to carry the resonant wave emitted by the resonant wave transmitting unit. The method of claim 8, wherein the variability resonance wave system comprises at least one wave in each period, and each of the waves is superposed by at least two waveforms. The method of claim 8, wherein the control driving unit is coupled to a database, wherein the information library establishes the physiological information, and when the demand signal is generated, the control driving unit can obtain the physiological information from the database. The drive command signal is generated.