TW201938222A - Bio-energy signal capturing and converting device capable of enhancing the intensity of the raw bio-energy signal and greatly reducing the noise ratio - Google Patents

Abstract

Provided is a bio-energy signal capturing and converting device, which includes a signal capturing module for strengthening a bio-energy signal generated by a raw bio-energy body, and then performing signals capturing; a signal processing module for receiving the captured raw bio-energy signal and performing a filtering and amplifying process on the signal so as to generate an output energy signal; and a signal output unit in conjunction with a magnetic substance for enhancing the signal outputting function, so as to outputting energy signals to a bio-energy carrier. By shortening the distance between the raw bio-energy body and the signal receiving unit, and using the magnetic substance to perform an enhanced excitation on the raw bio-energy body, the intensity of the received captured raw bio-energy signal can be enhanced so as to greatly reduce the noise ratio, thereby reducing the technical complexity and cost of the back-end signal processing, and improving the efficacy of bio-energy signal.

Description

Bioenergy signal acquisition and conversion device

A signal acquisition and conversion device, especially a bioenergy signal acquisition and conversion device.

A bioenergy signal acquisition and conversion device is to capture and enhance the energy signal of an original bioenergy body to be transmitted, and directly send it to a device to receive the bioenergy carrier for signal reception and conversion. MORA Super + bio-energy resonance electronic equipment. In 2013, Lingling Liu, Zheng Fang and others proposed a journal article in the European Journal of Integrative Medicine (Effectiveness of MORA electronic homeopathic copies of remedies for allergic rhinitis: A short-term, randomized, placebo-controlled PILOT study). A research report on the effective treatment of allergic rhinitis with the use of MORA Super + bioenergy resonance electronic devices is also proposed.

However, the energy signal of the original bioenergy body to be transmitted is very low in energy, so there is a lot of unnecessary environmental noise signals in the acquisition of the signal, and some circuit noise is also involved in the enhancement processing, so the biological energy is to be received. The energy signal received by the carrier is not only from the original biological energy to be transmitted, but also to receive unrelated noise signals. The proportion of noise signals is even larger than the original original biological energy to be transmitted, so the energy to be received is greatly reduced. The carrier receives the effect of the bio-energy characteristic signal.

In order to solve the problem of non-relevant clutter signals when acquiring signals, a complex signal processing circuit must be further set after the signals are acquired to process various bioenergy characteristic signals. Some even connect to a computer and use software to perform signal-assisted processing, which causes the complexity of the technical architecture and greatly increases the cost. Therefore, the prior art bioenergy signal acquisition and conversion device must be further improved.

In view of the poor design of the front-end signal acquisition processing of the prior art bioenergy signal acquisition and conversion device, the back-end signal processing method is complicated and the cost is increased. This creation provides a bioenergy signal acquisition and conversion device, including a A signal acquisition module, a signal processing module and a signal output unit. The signal acquisition module is used to enhance and stimulate the bioenergy signal generated by a primitive bioenergy body, and capture an enhanced and stimulated raw bioenergy signal. Primitive bioenergy bodies include organisms (all or part of their tissues) and their derivatives (such as biological fluids, secretions, excreta, and their normal or pathological biological derivatives, such as blood, sputum, snot, urine, or Pus, etc .; epidermal keratin of normal, hoarding or infected related pathological substances, such as hair, nails, dander, etc., and energy carriers and bioenergy carriers (their energy signals can be captured for processing, such as duplication, totalization Or filtering). The signal processing module is electrically connected to the signal acquisition unit to receive the original biological energy signal and filter and amplify the original biological energy signal to generate an output energy signal. The signal output unit is electrically connected to the signal processing module to receive the output energy signal and output the output energy signal to a bioenergy carrier, and propose a better conversion method to enhance the efficiency of the carrier carrying the converted bioenergy signal.

The signal acquisition module is designed to greatly reduce noise and improve the signal acquisition method, and then receives the enhanced and stimulated bioenergy signal, so that the original bioenergy signal acquired by the signal acquisition module The proportion of middle noise is greatly reduced, reducing the signal processing complexity of the back-end signal processing module, and further achieving the purpose of simplifying the technical cost and operating difficulty of the overall device.

The signal output unit proposes a better-designed conversion structure to shorten the distance between the bioenergy carrier and the signal output unit, so as to enhance the receiving efficiency of the bioenergy carrier, and maximize the efficiency of the bioenergy carrier in converting the bioenergy signal.

Please refer to FIG. 1 and FIG. 2. In view of the poor design of the front-end signal acquisition processing of the prior art bioenergy signal acquisition and conversion device, the back-end signal processing method is complicated and the cost is increased. This creation provides a biological The energy signal acquisition and conversion device includes a signal acquisition module 10, a signal processing module 20, and a signal output unit 30. The signal acquisition module 10 is used to acquire a bioenergy signal generated by an original bioenergy body, and the signal acquisition module 10 first performs an enhanced activation on the original bioenergy body, and then receives an enhanced activation The original bioenergy signal. The signal processing module 20 is electrically connected to the signal acquisition module 10 to receive the original biological energy signal and filter and amplify the original biological energy signal to generate an output energy signal. The signal output unit 30 is electrically connected to the signal processing module 20 to receive the output energy signal and output the output energy signal to a bioenergy carrier.

Please refer to FIG. 3 together. In a first preferred embodiment of the present invention, the signal acquisition module 10 includes a carrier box 11, a first magnetic unit 12, and a signal receiving unit 13. The carrying box 11 includes a base 111 and an upper cover 112. One side of the upper cover 112 is pivotally connected to the base 111 and can be pivotally closed with the base 111. The first magnetic unit 12 is disposed on an inner surface of the upper cover 112, and the signal receiving unit 13 is disposed on an upper surface of the base 111 for carrying an original bioenergy body and receiving the original bioenergy body. A primitive biological energy signal. When the upper cover 112 and the base 111 are pivotally closed, there is an accommodation space 110 between the first magnetic unit 12 and the signal receiving unit 13. The signal processing module 20 is disposed in the internal space of the base 111 and is electrically connected to the signal receiving unit 13. The signal processing module 20 receives the original biological energy signal from the signal receiving unit 13 and performs a process on the original biological energy signal. The filtering and amplification process generates an output energy signal. The signal output unit 30 is electrically connected to the signal processing module 20 to receive the output energy signal, and outputs the output energy signal to a bioenergy carrier.

After the upper cover 112 and the base 111 are closed, the original bioenergy body is located in the accommodation space 110 and between the signal receiving unit 13 and the first magnetic unit 12. The first magnetic unit 12 can Approach the original bioenergy body at a similar short distance, use the magnetic field distance physical properties of the magnetic substance, and stimulate the original bioenergy body to produce the largest bioenergy signal with the maximum magnetic field formed by the short distance of the first magnetic unit 12, The signal receiving unit 13 directly receives the enhanced and stimulated original biological energy signal, so that the proportion of the original biological energy signal in the signal received by the signal receiving unit 13 is increased, and the proportion of noise from the surrounding environment is greatly reduced. In short, by shortening the distance between the signal receiving unit 13 and the original biological energy body, and further stimulating the original biological energy body with the first magnetic unit 12, the original biological energy received by the signal receiving unit 13 is enhanced. Signal strength and significantly reduce the proportion of noise in it.

In addition, the original bioenergy body is placed in the carrying box body 11 and protected by the upper cover 112, and is not easily affected by external force collision. In this way, by improving the structure of the carrier box 11 and the first magnetic unit 12 to stimulate the original bioenergy body, the quality of the signal received by the front-end signal receiving unit 13 is greatly improved, so the back-end signal processing is further reduced. Required technical difficulties and costs. The primitive bioenergy body includes all or part of the tissues of the organism, or derivatives of the organism, such as biological fluids, secretions, excreta, and normal or pathological biological derivatives such as blood, sputum, snot, urine , Or pus, etc .; epidermal keratin, which is normal, hoarded or infected related pathological substances, such as hair, nails, dandruff and other energy bodies. The original bioenergy body may also be a bioenergy carrier. For example, the bioenergy carrier that has received the bioenergy signal in this creation can be processed by re-capturing its energy signal, such as copying, summing, or filtering.

In a first preferred embodiment of the present invention, the signal output unit 30 includes a coil 31 which is electrically connected to the signal processing module 20 to receive the output energy signal and send the output energy signal. Preferably, the coil 31 is electrically connected to the signal processing module 20 disposed in the internal space of the base 111 through a wire.

Please refer to FIG. 4 and FIG. 5 together. Preferably, an output terminal 1111 is provided on a side wall of the base 111 of the carrier box 11. The output terminal 1111 is electrically connected to the signal processing module 20 to output the output. Energy signal. The signal output unit 30 further includes a pipe body 32, preferably a hollow pipe body. The pipe body 32 has a carrier accommodating space 320, and an opening is formed at one of two opposite ends of the pipe body 32. An input terminal 321 is provided at the other end. The input terminal 321 is electrically connected to the output terminal 1111 of the base 111 through the wire. The opening of the tube body 32 communicates with the carrier receiving space 320 of the tube body 32. The coil 31 is wound around the pipe body 32 and is electrically connected to the input terminal 321 to receive the output energy signal output by the signal processing module through the wire and the output terminal 1111 of the base 111. The carrier accommodating space 320 is used for placing a bioenergy carrier, and the bioenergy carrier receives the output energy signal of the coil 31. Please refer to FIG. 6, the bioenergy carrier is preferably a bottled liquid 40 such as wine, vinegar or water, or a solid such as quartz, crystal, salt, sugar or magnetic substance.

In another embodiment, the carrier accommodating space 320 of the tube body 32 may not contain a carrier. At this time, the coil 31 is used to directly send the output energy signal through the opening of the tube body 32 to external organisms within a certain distance. Energy carrier. This bioenergy carrier includes animals or humans.

Preferably, the signal receiving unit 13 is a metal plate, for example, a metal plate made of gold, silver, or copper.

In more detail, the inner surface of the upper cover 112 is recessed to form a fitting groove 1121, and the first magnetic unit 12 is disposed in the fitting groove 1121, and is preferably bolted, adhered or fitted in the fitting groove 1121. In the fitting groove 1121. The signal receiving unit 13 is disposed corresponding to the fitting groove 1121, and the thickness of the signal receiving unit 13 plus the thickness of the first magnetic unit 12 is smaller than a depth of the fitting groove 1121. Therefore, when the upper cover 112 and the base 111 are closed, the signal receiving unit 13 will be accommodated in the fitting groove 1121 and will not contact the first magnetic unit 12 and form a short distance, so that the signal The receiving unit 13 and the first magnetic unit 12 form the accommodating space 110 with a fixed height for accommodating the bioenergy body.

Please refer to FIG. 7. In a second preferred embodiment of the present invention, the signal processing module 20 includes a filtering unit 21 and an amplifying unit 22. The filtering unit 21 is electrically connected to the signal receiving unit 13 for receiving. This original bioenergy signal will greatly attenuate and remove relevant noise that is not in the range of the intended bioenergy signal, such as filtering low frequency 50 / 60Hz AC power waves, high frequency mobile phones or radio wave environmental noise, etc. Generates a filtered signal. The amplifying unit 22 is electrically connected to the filtering unit 21 and receives the filtered signal and performs an amplification conversion to generate the output energy signal. The output terminal 1111 is electrically connected to the amplifying unit 22 for outputting the output energy signal.

Preferably, the signal processing module 20 includes a power supply unit 23 disposed in the internal space of the base 111. The power supply unit 23 is configured to provide the power required by the filtering unit 21 and the amplification unit 22. The power supply unit 23 is, for example, a battery.

In another embodiment, the signal processing module 20 includes a power conversion unit 24, which is electrically connected to the filter unit 21 and the amplification unit 22, and is electrically connected to an external power source to convert the external power source and provide power to the filter. Unit 21 and the amplifying unit 22.

Please refer to FIG. 5 again. In a third preferred embodiment of the present invention, the signal output unit 30 further includes a second magnetic unit 33, and the second magnetic unit 33 may be disposed on the carrier body 32 of the tube body. The space 320 is placed to enhance the effectiveness of the coil 31. The second magnetic unit 33 can also be based on the type or structure of the bioenergy carrier. It uses the physical characteristics of the magnetic field distance of the magnetic substance and is placed around the coil 31 or other locations inside the tube body or around the outside of the tube body and close to the coil. , And other locations around or inside the bioenergy carrier 40.

The above is only the preferred embodiment of the creation, and does not limit the creation in any form. Although the creation has been disclosed as above with the preferred embodiment, it is not intended to limit the creation. Any technology that is familiar with the profession Personnel, without departing from the scope of this creative technical solution, can use the technical content disclosed above to make a few changes or modify the equivalent embodiment of equivalent changes, but any content that does not depart from this creative technical solution, based on this creative Any simple modifications, equivalent changes, and modifications made to the above embodiments by the technical essence of the invention still fall within the scope of this creative technical solution.

10‧‧‧Signal Acquisition Module

11‧‧‧ Carrying Box

111‧‧‧base

110‧‧‧accommodation space

1111‧‧‧Output terminal

112‧‧‧ Upper cover

1121‧‧‧fit groove

12‧‧‧The first magnetic unit

13‧‧‧Signal receiving unit

20‧‧‧Signal Processing Module

21‧‧‧Filter unit

22‧‧‧ Magnification Unit

23‧‧‧ Power Supply Unit

30‧‧‧Signal output unit

31‧‧‧coil

32‧‧‧ tube body

320‧‧‧accommodation space

321‧‧‧input terminal

33‧‧‧Second magnetic unit

40‧‧‧Bioenergy carrier

FIG. 1 is a schematic perspective view of the appearance of the creative biological energy signal acquisition and conversion device.

FIG. 2 is a block diagram of the creative biological energy signal acquisition and conversion device.

FIG. 3 is a schematic cross-sectional view of a carrying box body of the creative biological energy signal acquisition and conversion device.

FIG. 4 is a schematic perspective view of the appearance of the carrying box of the bioenergy signal acquisition and conversion device of this creative device.

FIG. 5 is a perspective view of the appearance of a signal output unit of the creative biological energy signal acquisition and conversion device.

FIG. 6 is a perspective view of the application of the creative biological energy signal acquisition and conversion device.

FIG. 7 is a schematic block diagram of a second preferred embodiment of the creative biological energy signal acquisition and conversion device.

Claims (10)

A bioenergy signal acquisition and conversion device includes: A signal acquisition unit for enhancing a biological energy signal that excites an original biological energy body, and acquiring an original biological energy signal; A signal processing module electrically connected to the signal acquisition unit to receive the original biological energy signal and filter and amplify the original biological energy signal to generate an output energy signal; A signal output unit is electrically connected to the signal processing module to receive the output energy signal and output the output energy signal to a bioenergy carrier. The biological energy signal acquisition and conversion device according to claim 1, wherein the signal acquisition unit includes: A carrying box body; A signal receiving unit disposed in the carrier box and receiving the original bioenergy signal; A first magnetic unit is disposed in the carrier box and corresponding to the signal receiving unit, and there is an accommodation space between the first magnetic unit and the signal receiving unit; The signal processing module is disposed in the carrier box and electrically connected to the signal receiving unit. The biological energy signal acquisition and conversion device according to claim 1, wherein the signal output unit includes: A coil is electrically connected to the signal processing module to receive the output energy signal. The bioenergy signal acquisition and conversion device according to claim 2, wherein: The carrying box body is provided with an output terminal, and the output terminal is electrically connected to the signal processing module; The signal output unit further includes: A pipe body having a carrier accommodating space, and an opening is formed at one of opposite ends of the pipe body, and an input terminal is provided at the other end, and the input terminal is electrically connected to an output terminal of the processing module through a wire. The opening of the body communicates with the carrier receiving space of the pipe body; the coil is wound around the pipe body and is electrically connected to the input terminal. The biological energy signal acquisition and conversion device according to claim 1, wherein the signal processing module includes: A filtering unit electrically connected to the signal receiving unit to receive the original biological energy signal, and performing a filtering process on the original biological energy signal to generate a filtered signal; An amplification unit is electrically connected to the filtering unit to receive the filtering signal. The amplification unit performs an amplification process on the signal to generate the output energy signal. The biological energy signal acquisition and conversion device according to claim 4, wherein the signal output unit further includes: A second magnetic unit is disposed in the carrier accommodating space of the pipe body, in the pipe body or around the outside of the pipe body, and is close to the coil. The biological energy signal acquisition and conversion device according to claim 5, wherein the signal processing module further includes: A power supply unit is electrically connected to the filter circuit and the amplifying unit, so as to generate electric power to be supplied to the filter unit and the amplifying unit. The bioenergy signal acquisition and conversion device according to claim 1, wherein: The original biological energy system is a normal or pathological organism, an energy body composed of a biological derivative, or the biological energy carrier. The bioenergy signal acquisition and conversion device according to claim 8, wherein: Derivatives of this organism are body fluids, secretions, excreta, and epidermal keratin of normal or pathological organisms. The bioenergy signal acquisition and conversion device according to claim 1, wherein: The bioenergy carrier is a bottled liquid, a solid or magnetic substance with a crystalline structure.