TWI627949B - Adjustable low-frequency physiological adjustment system - Google Patents

Abstract

The invention provides an adjustable frequency low-frequency physiological adjustment system for generating a plurality of frequency modulation waveforms, wherein the frequency modulation waveforms respectively correspond to a plurality of different organ parts, and the low-frequency physiological adjustment system comprises a server, a signal processor and a signal. The responder has a database for storing the aforementioned FM waveform, and the FM waveform stored by the server output database, the signal processor is connected with the server signal, and one of the FMs is stored in the selected database. The waveform is downloaded and converted, and the downloaded FM signal is converted into a low-cycle drive signal. The signal responder is connected to the signal processor signal and receives the low-cycle drive signal, and generates a corresponding oscillating response according to the low-cycle drive signal. Provide to each organ site.

Description

Adjustable frequency low cycle physiological adjustment system

The invention relates to a frequency-adjustable low-frequency physiological adjustment system, in particular to a low-frequency physiological adjustment system for adjusting the frequency of various organ parts.

Modern people have a lot of stress in life, and their living conditions are not normal. It is easy to cause fatigue and abnormalities in human organs, which in turn causes various diseases. In order to understand the difference between normal organs and abnormal organs, it has been discovered by scientific research that each organ of the human body has a unique waveform after being measured, and depending on whether the organ is normal or not, it will affect the waveform change.

Therefore, if the organ is normal, the waveform measured by the normal organ can be used as a reference standard. When the waveform measured by the same organ of the subject is different from the waveform measured by the normal organ, the organ measured by the subject is very There may have been problems, and the subject can go to the hospital for further precision inspections to achieve early warning.

However, the above inspection methods only know that the organ of the subject may be ill, and can only achieve early warning, but can not further adjust and improve, so that the waveform of the organ returns to normalization.

On the other hand, when the subject is tested, the relevant data obtained are not properly managed, or further tracked, even if the subject is treated, or after improving the living, the organ is re-tested. When the waveforms are different, it is not clear what the strain of the waveform changes.

It is an object of the present invention to provide a low cycle physiological adjustment system that provides low frequency oscillations to the organ site.

Another object of the present invention is to provide an adjustable frequency low cycle physiological adjustment system that oscillates an organ site in response to oscillating.

Still another object of the present invention is to provide a low-cycle physiological adjustment system that records a waveform measured by a subject for further tracking.

The invention provides an adjustable frequency low-frequency physiological adjustment system for generating a plurality of frequency modulation waveforms, wherein the frequency modulation waveforms respectively correspond to a plurality of different organ parts, and the low-cycle physiological adjustment system comprises a server and a signal processing. And a signal responder, the server has a database for storing the aforementioned FM waveform, and the FM waveform stored by the server output database, the signal processor is connected with the server signal, and the data is selected. The library stores one of the FM waveforms and downloads it, and converts the downloaded FM signal into a low-cycle drive signal. The signal responder is connected to the signal processor signal and receives the low-cycle drive signal, and is driven according to the received low-cycle. The signal produces a corresponding oscillating response to provide to each of the organ sites.

The adjustable frequency low-frequency physiological adjustment system proposed by the invention is based on the normal waveform corresponding to each different organ, and is controlled as a low-cycle oscillation frequency, and the user can connect to the server by itself and download the normal corresponding to the organ. The waveform is then oscillated by the signal responder, and the oscillation is transmitted to the organ. Since the organ receives the oscillation corresponding to the normal waveform, the organ can be shaken and conditioned to the normal waveform, and the waveform of the organ is returned to normalization. The database can store the waveforms measured by the user for further tracking in the future, or provide corresponding low-cycle driving signals according to the measured waveforms.

According to the present invention, a frequency-adjustable low-cycle physiological adjustment system is provided for generating a plurality of frequency modulation waveforms, each of which corresponds to a plurality of different organ parts, as shown in FIG. 1. The low-frequency physiological adjustment system of the embodiment includes a server. 1. The signal processor 2 and the signal responder 3, the server 1 has a database 11 for storing and storing the above-mentioned FM waveform, and the FM 1 is stored by the server 1 output database 11 The waveform, wherein the above-mentioned FM waveform can be referred to FIG. 2, the signal processor 2 is connected with the signal of the server 1 (the connection method can be network, WiFi or Bluetooth), and one of the FMs stored in the selected database 11 is stored. The waveform is downloaded and converted, and the received FM signal is converted into a low-cycle drive signal. The signal responder 3 is connected to the signal processor 2 signal (the connection method can be network, WiFi or Bluetooth), and is used to receive the low cycle. Driving the signal and generating a corresponding oscillating response according to the received low-frequency driving signal. In this example, the signal responder 3 includes an oscillating massaging unit 31, which is driven according to low frequency. The signal produces a corresponding massage frequency.

For example, when a certain part of the body of the user needs to be conditioned, and the waveform of the organ is returned to normalization, the frequency modulation waveform corresponding to the normal organ is first downloaded by the signal processor 2, and then the shock massage unit 31 is attached to the body, so that the basis is low. The Zhoubo drive signal produces the corresponding massage frequency (the massage frequency can be 860-960MHZ), and the vibration is transmitted to the body organs, so that the waveform after the organ responds to the shock returns to normalization.

On the other hand, the oscillating massage unit 31 can be a resonant wafer and can be attached to any part of the human body. The resonant wafer can be designed to have a length of 11 mm and a width of 8 mm, and is designed to match the human body micro-wave inductive coupling. Oscillation occurs within a range of less than 3 to 6 cm from the human body.

Since each person's age, physical fitness, gender, or condition is different, the frequency modulation waveform corresponding to each person's organs is not the same. Therefore, another adjustable frequency low-frequency physiological adjustment system according to the present invention is shown in FIG. In this example, the low-frequency physiological adjustment system further includes a sensor 4, and the sensor 4 is connected to the server 1 signal (the connection method may be network, WiFi or Bluetooth), and may be based on the user's Depending on the age, physique, gender, or condition, a corresponding physiological waveform is sensed and provided to the server 1 for storage by the database. When the user wants to download the FM waveform through the signal processor 2, the server will The corresponding FM waveform stored in the database 11 is output according to the exclusive physiological waveform, so that the user can download the FM waveform suitable for himself.

In this example, the signal responder 3 includes a sounding unit 32, such as a headphone or an audio, which generates a corresponding oscillating audio according to the low-cycle driving signal. When the user wants to adjust the emotion, the emotional waveform of the brain is returned. In normalization, the corresponding frequency modulation waveform is first downloaded by the signal processor 2, and then the corresponding oscillation audio is sent out by the sounding unit 31, and transmitted to the ear to smooth out the emotions, and the emotional waveform of the brain is returned to normalization.

According to the present invention, another adjustable frequency low-frequency physiological adjustment system, as shown in FIG. 4, further includes a controller 5, in this example, the signal processor 2 is connected to the server 1 through the controller 5 signal, and the signal The degree of oscillating response of the processor 2 is controlled by the controller 5, for example, the controller 5 controls the time or intensity of the oscillating response of the signal processor 2, and the controller 5 of the present example can be exemplified as a smart phone. And including a display unit 51 and a memory unit 52, the display unit 51 is for outputting the low-cycle driving signal of the display signal processor 2, such as the output time or the remaining time, and the memory unit 52 is for storing the signal. The number of outputs of the low-cycle drive signal of processor 2 for use as a reference for future reference.

In this example, the signal responder 3 includes a light-emitting unit 33, and the light-emitting unit 33 generates corresponding shock pulse light according to the low-cycle drive signal. When the user wants to adjust the skin, the waveform of the skin is returned to normalization. At the same time, the corresponding frequency modulation waveform is first downloaded by the signal processor 2, and then the corresponding oscillation pulse light is emitted by the light-emitting unit 33, and is irradiated to the skin, so that the skin feels the sense of wave massage and returns the waveform of the skin to normalization.

The signal responder 3 of this example can further be provided with a memory card 34, and the memory card 34 can be replaced and installed to the signal responder 3. The different memory cards 34 can respectively store a plurality of different low-cycle drive signals. For the user to install the corresponding memory card 34 to the signal responder 3 according to the current normalized position, the stored memory card 34 provides the stored low-cycle drive signal to the signal responder 3, or, in memory A plurality of different low-cycle drive signals are stored in the card 34, and the user selects the desired low-cycle drive signal.

The adjustable frequency low-frequency physiological adjustment system proposed by the invention is that the user can connect to the server by itself and download the normal waveform corresponding to the organ as the control of the low-cycle oscillation frequency, so that the signal responder responds. Concussion, therefore, when the shock is transmitted to the organ, because the organ receives the shock corresponding to the normal waveform, the organ can be oscillated to normal waveform, and the waveform of the organ can be further normalized. Moreover, the database of the case can be further Receiving and storing the waveforms of the current organs of the user measured by the sensor for further tracking, or when the user provides a corresponding low-cycle driving signal according to the measured current waveform, increasing the organ conditioning There is a degree after.

1‧‧‧Server
11‧‧‧Database
2‧‧‧Signal Processor
3‧‧‧Signal Responder
31‧‧‧ shock massage unit
32‧‧‧ Sounding unit
33‧‧‧Lighting unit
34‧‧‧ memory card
4‧‧‧ sensor
5‧‧‧ Controller
51‧‧‧Display unit
52‧‧‧ memory unit

1 is a block diagram of an adjustable frequency low-frequency physiological adjustment system according to an embodiment of the present invention; FIG. 2 is a schematic diagram of a frequency modulation waveform of the low-cycle physiological adjustment system of FIG. 1; FIG. 3 is an adjustable frequency according to another embodiment of the present invention. A block diagram of a low-cycle physiological adjustment system; and FIG. 4 is a block diagram of a frequency-adjustable low-cycle physiological adjustment system in accordance with yet another embodiment of the present invention.

Claims (9)

An adjustable frequency low-frequency physiological adjustment system for generating a plurality of frequency modulation waveforms respectively corresponding to a plurality of different organ parts, the low-cycle physiological adjustment system comprising a server, the server having a database The database is used for storing the FM waveforms, and the server outputs the FM waveforms stored in the database; a signal processor is connected to the server signal and is selected for storage in the database. One of the FM waveforms is downloaded and converted, and the downloaded FM signal is converted into a low-cycle drive signal; a signal responder is coupled to the signal processor signal and receives the low-cycle signal Driving a signal, and generating a corresponding oscillating response according to the received low-cycle driving signal to provide to each of the organ parts; and a sensor coupled to the server signal and sensing the foregoing a specific physiological waveform corresponding to the organ part, and provided to the server; wherein the server is based on the exclusive physiological wave Outputting a corresponding FM waveform stored in the database, and downloading the corresponding FM waveform by the signal processor to convert the corresponding low frequency driving signal, so that the signal responder generates the corresponding oscillating response to each of the The organ site is such that each of the organs returns to normalization in response to the FM waveform. The low-frequency physiological adjustment system of claim 1, wherein the signal responder comprises an oscillating massage unit, and the oscillating massage unit generates a corresponding massage frequency according to the low-cycle driving signal. The low-frequency physiological adjustment system according to claim 1, wherein the The signal responder includes a sounding unit that generates corresponding oscillating audio according to the low frequency driving signal. The low-frequency physiological adjustment system of claim 1, wherein the signal responder comprises an illumination unit, and the illumination unit generates corresponding oscillation pulse light according to the low-cycle drive signal. The low-frequency physiological adjustment system according to claim 1, further comprising a controller, wherein the signal processor is connected to the server through the controller signal, and the controller controls the oscillation response of the signal processor. . The low-frequency physiological adjustment system of claim 5, wherein the control module comprises a display unit for displaying an output progress of the low-cycle drive signal of the signal processor. The low-frequency physiological adjustment system of claim 5, wherein the control module comprises a memory unit for storing the number of times of outputting the low-cycle drive signal of the signal processor. The low-frequency physiological adjustment system of claim 5, wherein the controller is a smart phone. The low-frequency physiological adjustment system of claim 1, wherein the signal responder further comprises an alternatively installed memory card for storing the low-cycle drive signal and providing the low storage The cycle drives the signal to the signal responder.