TWI850183B - Energy signal transceiver device - Google Patents

Abstract

At least one resistor combination unit of an energy signal transceiver device has a plurality of resistors and a connecting wire; each resistor has a resistor body, and an antenna wire and an inductor wire are at opposite ends of each resistor. One end of the antenna wire is an open circuit, and the other end of the antenna wire is connected to each resistor body respectively, and the inductor wire is electrically connected between the resistor body and the connecting wire. When each resistor receives a wireless signal from the antenna wire, the complex filtered signals formed by the resistors and the inductor wires are outputted through inductor wires to the connecting wire, and the connecting wire receives the filtered signals and generates a resonant state signal. The invention is compact and cheap to produce, and a user can adjust the resistance values of the resistor bodies to configure resonant frequencies of the resonant state signal.

Description

Energy signal transceiver

An energy signal transceiver can filter and output the received energy as a resonant signal.

When you want to generate a specific frequency point or a specific band of energy waveform combination, the traditional approach is to use an arbitrary waveform generator to generate an electromagnetic wave of arbitrary waveform. The above-mentioned arbitrary waveform generator is a signal generator used to generate various forms of radio waves on a wide frequency range of signals. The frequency range can be set or the waveform digital file to be generated can be directly input. However, setting the frequency range can only generate specific types of waveforms, and if you want to generate a complex waveform, you must directly input a special custom-generated waveform digital file. However, the steps for custom-designing waveform digital files are complicated, and the arbitrary waveform generator instrument is large in size and has a high procurement cost, so it is inconvenient for general users.

Please refer to the MORA bioenergy resonance instrument of Med-Tronik GmbH in Germany. The MORA instrument can store up to about 15,000 kinds of digitalized matter wave electronic frequency signals, including herbs, bacteria, viruses, environmental toxins, food, drugs, allergens, nutritional health foods, homeopathic therapy, pathological preparations, organ preparations, etc. These digitalized matter wave electronic frequency signals are recorded by Med-Tronik GmbH and then digitally stored in the memory of the instrument. When the MORA instrument detects that the subject resonates with that kind of matter wave frequency, MORA will play these matter wave signal files on the computer to test the subject. When using MORA to understand which frequency signals of matter waves resonate with the subjects, doctors can accurately measure and prescribe appropriate homotherapeutic preparations for each subject. However, even though the MORA instrument has outstanding performance and can play a wide variety of signals, the MORA instrument is still large in size and expensive to purchase, making it inconvenient for general users to use (https://mmchwellness.com/健康促進/mora/).

The Rayonex Biomedical GmbH of Germany has developed a bioenergetic resonance system that incorporates the ingenious discovery of the company's founder, Paul Schmidt. It uses a dipole antenna system to generate a harmonic decimal frequency spectrum and stimulates the coordination and balance of human or animal organisms without consuming electricity. This device has a unique mother-child machine design: it automatically scans the 200 basic frequency values of the whole body, measures the individual heart rate parameters of the body, and only takes about 12-16 minutes to tailor the harmonious resonance frequency required by the body. Then, download all the frequency information files that need to be resonated and harmonized to the memory card through the main unit Rayonex PS1000, insert the memory card directly into the slave unit PS10, and then use the slave unit to play the frequency signals that need to be resonated and harmonized for personalized physiological adjustment courses. Although Rayonex instruments can also play a variety of frequency signals, they are still large in size and expensive to purchase, so they are inconvenient for general users (https://www.rayonex.tw/homepage-about.html).

In summary, a good energy signal transceiver used for energy signal simulation transmission must be able to easily allow users to set the frequency energy characteristics of the electromagnetic energy signal emitted by the energy transmitter to be simulated and transmit it. However, the energy signal simulation transmission device must be equipped with many electronic components, such as receiving antennas, transmitting antennas, filters, etc., in order to accurately simulate the energy frequency set by the user. However, the installation of these electronic components makes the equipment manufacturing cost of the energy signal simulation device high and the size is quite large. Therefore, the existing energy signal simulation transmission method is not convenient for users to use, so it is indeed necessary to propose a better solution for the above situation.

In view of the above problems, the present invention provides an energy signal transceiver device, which has a small size and can receive energy signals, filter them and send them out to simulate energy signals of specific frequencies.

The energy signal transceiver of the present invention comprises: At least one resistor combination unit, including multiple resistors and a connecting wire; Each resistor has a resistor body and an antenna wire and an inductor wire located at two opposite ends of the resistor body, and one end of the antenna wires of the resistors is open-circuited, and the other ends of the antenna wires of the resistors are respectively connected to each resistor body, and the inductor wires of the resistors are electrically connected between the resistor body and the connecting wire; When each resistor receives a wireless signal from the antenna wire, the wireless signals form multiple filter signals through the resistors and the inductor wires, and the inductor wires output the filter signals to the connecting wire; The connecting wire receives the filter signals and generates a resonant signal.

The antenna wire of each resistor of the present invention is equivalent to an antenna, and the inductor wire of each resistor is equivalent to an inductor. Therefore, the resistor body of each resistor and the inductor wire are connected to form an RL filter circuit. When the antenna wires of the resistors receive the wireless signal, the wireless signal passes through the resistors and the inductor wires to form a complex filter signal, and the filter signals are output from the inductor wires to the connecting wire. The complex filter signals output to the connecting wire are combined into the resonant state signal output by the connecting wire. A user using the present invention can simply adjust the resistance value of each resistor body by replacing the resistor body, thereby adjusting the filter signal output by each inductor wire, that is, adjusting the frequency and waveform characteristics of the resonant state signal output by the connecting wire. The user uses the resonant state signal output by the present invention as an energy frequency signal emitted by the simulated energy transmitter. Since the resistor combination unit of the present invention only has the resistors and the connecting wire, the resistor combination unit is extremely small in size and has a low manufacturing cost, so it can improve the problems of the prior art.

Referring to FIG. 1 , the present invention provides an energy signal transceiver device, which includes at least one set of resistor combination units. In one embodiment, the energy signal transceiver device includes a first resistor combination unit 100. The first resistor combination unit 100 includes a plurality of resistors 110 and a connecting wire 120. Each resistor 110 further includes a resistor body 111 and an antenna wire 112 and an inductor wire 113 located at opposite ends of the resistor body 111. One end of the antenna wires 112 of the resistors 110 is open-circuited, and the other end of the antenna wires 112 of the resistors 110 is connected to each resistor body 111 , respectively. The inductor wires 113 of the resistors 110 are electrically connected between the resistor body 111 and the connecting wire 120 .

In one embodiment, the inductor wire 113 of each resistor 110 is a wire line with an inductance effect in the circuit, so the inductor wire 113 can be regarded as an inductor. The antenna wire 112 of each resistor 110 of the present invention is equivalent to an antenna, and the resistor body 111 and the inductor wire 113 of each resistor 110 are equivalent to an RL filter circuit.

When each resistor 110 receives an electromagnetic energy wave 10 from the antenna wire 112, the electromagnetic energy wave 10 is filtered into a filter signal by the resistor body 111 and the inductor wire 113 which is equivalent to an RL filter circuit, and the inductor wire 113 transmits the filter signal to the connecting wire 120, so that the connecting wire 120 receives the filter signals to generate a resonant state signal and outputs the resonant state signal.

The filter signals outputted from the inductance wires 113 of the present invention are integrated into the resonant state signal outputted by the connection wire 120. A user using the present invention can simply adjust the resistance value of each resistor body 111 by replacing the resistor body 111, thereby adjusting the filter signal outputted by each inductance wire 113, that is, adjusting the frequency and waveform characteristics of the resonant state signal outputted by the connection wire 120. The user uses the resonant state signal outputted by the present invention as an energy frequency signal simulating the energy transmitter. Since the first resistor combination unit 100 of the present invention only has the resistors 110 and the connecting wires 120, the first resistor combination unit 100 is extremely small in size and has a low manufacturing cost, thereby improving the problems of the prior art.

Please refer to FIG. 2 , in one embodiment of the present invention, the energy signal transceiver device includes a plurality of resistor combination units, such as the first resistor combination unit 100, a second resistor combination unit 200 and a third resistor combination unit 300. The second resistor combination unit 200 and the third resistor combination unit 300 both have the resistors 110 and the connecting wires 120 as the first resistor combination unit 100, but the number of the resistors 110 in the second resistor combination unit 200 and the third resistor combination unit 300 may be different. For example, in this embodiment, the first resistor combination unit 100 has three resistors 110, the second resistor combination unit 200 has two resistors 110, and the third resistor combination unit 300 has four resistors 110. The number of the resistors 110 of the first resistor combination unit 100, the second resistor combination unit 200, and the third resistor combination unit 300 can be arbitrarily combined as required.

The first resistor combination unit 100, the second resistor combination unit 200 and the third resistor combination unit 300 are combined to form an energy signal transceiver module. In the energy signal transceiver module, the connecting wires 120 of the first resistor combination unit 100, the second resistor combination unit 200 and the third resistor combination unit 300 send signals toward the same first axis X. Further, the antenna wire 112 of each resistor 110 in the first resistor combination unit 100, the second resistor combination unit 200 and the third resistor combination unit 300 is extended toward a second axis Y, and the second axis Y is perpendicular to the first axis X. When each of the connecting wires 120 outputs the resonant state signal, each of the connecting wires 120 can be placed under the connecting wire 120 of another resistor combination unit to overlap the waveform and mode of each of the resonant state signals to ultimately output a final resonant state signal having a specific waveform type, mode and frequency.

In this embodiment, the resistors 110 of the first resistor combination unit 100, the second resistor combination unit 200 and the third resistor combination unit 300 have the same specifications. For example, the lengths of the inductor wires 113 of the resistors 110 are equal, the lengths of the resistor bodies 111 are equal and the lengths of the antenna wires 112 are equal, so that electromagnetic waves of the same band can be received. For example, the lengths of the inductor wires 113 of the resistors 110 are 2 mm, the lengths of the resistor bodies 111 are 1 mm and the lengths of the antenna wires 112 are 3 mm. In other embodiments, the length of the inductor wire 113 of the resistors 110, the length of the resistor body 111, and the length of the antenna wire 112 may also be other values, so the length of the inductor wire 113 is not limited to 2 mm, the length of the resistor body 111 is not limited to 1 mm, and the length of the antenna wire 112 is not limited to 3 mm. For example, in one embodiment, the lengths of the inductor wire 113, the lengths of the resistor body 111, and the lengths of the antenna wire 112 of the resistors 110 of the same resistor combination unit are equal, while the lengths of the inductor wire 113, the lengths of the resistor body 111, and the lengths of the antenna wire 112 of any two different resistor combination units may be unequal.

In addition, the resistor body 111 of each resistor 110 has a resistance value, and the resistance values of the resistor bodies 111 of the first resistor combination unit 100, the second resistor combination unit 200 and the third resistor combination unit 300 can be different from each other to facilitate matching the different resistance values of each resistor 110, thereby forming a circuit in which multiple groups of RL circuits are connected in parallel and have the effect of filtering different frequencies.

At least one magnet 130 is disposed above the antenna wire 112 of each resistor 110 along the second axis Y. In the embodiment shown in FIG. 2 , one magnet 130 is disposed on a first support plate 140, and the first support plate 140 is spaced apart from the antenna wire 112 of each resistor 110 by a distance. The magnet 130 has two opposite magnetic poles, and the two opposite magnetic poles are disposed along the second axis Y. In one embodiment, the magnet 130 is provided with an auxiliary structure 131, which can be a wire or a sheet iron or an elliptical iron ring made of a wire or a sheet iron, and the wire or the sheet iron or the elliptical iron ring is placed under one of the two magnetic poles of each magnet 130. The iron wires or iron sheets can also completely surround the two magnetic poles of the magnet 130 to increase the magnetic strength of the magnetic poles. Therefore, the iron wires or iron sheets or elliptical iron rings can increase the magnetic strength sensed by each of the inductor wires 113, thereby increasing the signal strength of the electromagnetic energy wave 10 sensed by each of the resistor combination units. The shape of the iron sheets can be a thin and long iron sheet. The aforementioned iron wires or iron sheets can be hollow and form a surrounding structure.

Please refer to FIG. 3 , in another embodiment, the energy signal transceiver device also includes a fourth resistor combination unit 400. The first resistor combination unit 100, the second resistor combination unit 200, the third resistor combination unit 300 and the fourth resistor combination unit 400 have the same number of resistors 110. The connecting wire 120 of the fourth resistor combination unit 400 also sends signals toward the first axis X together with the other aforementioned connecting wires 120. In addition, the plurality of magnets 130 are disposed on the first supporting plate 140, and the positions of the magnets 130 in the first axial direction X correspond to the positions of the first resistor combination unit 100, the second resistor combination unit 200, the third resistor combination unit 300 and the fourth resistor combination unit 400 in the first axial direction X, and the auxiliary structure 131, that is, the aforementioned iron wires or iron sheets or elliptical iron rings, is placed under the magnets 130. The so-called under the magnets 130 refers to between the at least one group of resistor combination units and the magnets 130.

Furthermore, the first resistor combination unit 100, the second resistor combination unit 200, the third resistor combination unit 300 and the fourth resistor combination unit 400 each include a wire base 150, and the connecting wires 120 are respectively disposed in the corresponding wire base 150 and extend from the wire base 150, and the resistors 110 are inserted into the corresponding wire base 150 to electrically connect the connecting wires 120 in the wire base 150. The wire base 150 of the first resistor combination unit 100 and the wire base 150 of the fourth resistor combination unit 400 are misaligned in the position of the first axis X. Thus, the resistors 110 of the fourth resistor combination unit 400, which is misaligned with the first resistor combination unit 100, are distributed between the resistors 110 of the first resistor combination unit 100 along the first axial direction X. In one embodiment, the wire bases 150 may be disposed on the same plane, and in another embodiment, the wire bases 150 may also be disposed on different planes.

In this embodiment, the wire bases 150 are all rectangular parallelepipeds, and the specifications of the magnets 130 can be different. For example, one of the magnets 130 can be relatively large and have strong magnetism, and provide magnetism for the first resistor combination unit 100 and the fourth resistor combination unit 400. In other embodiments, even if the wire base 150 is not provided, the resistor combination units of the present invention can still operate to generate signals. In other embodiments, the wire bases 150 can also be other shapes.

In addition, the present invention also has an output unit, which is electrically connected to the terminal of the connecting wire 120, and converts the resonant state signal output by the connecting wire 120 into other forms of energy signals. For example, the output unit can be a sound wave or ultrasonic transducer.

In addition, the present invention also has a processing unit. In this embodiment, the processing module aligns the connecting wires 120 of the first resistor combination unit 100, the second resistor combination unit 200, the third resistor combination unit 300 and the fourth resistor combination unit 400 on the first axial direction X to receive signals sent by all the connecting wires 120 of the first resistor combination unit 100, the second resistor combination unit 200, the third resistor combination unit 300 and the fourth resistor combination unit 400. When the processing unit receives the final resonant state signal from the connecting wires 120, the processing unit analyzes a waveform analysis result based on the final resonant state signal generated by superimposing the multiple resonant state signals output by the connecting wires 120. For example, the processing unit can be a computer or an oscilloscope. After the processing unit generates the waveform analysis result, the waveform analysis result can be directly or indirectly displayed for the user's reference, so that the user can immediately understand the state of the energy signal transceiver receiving and filtering the electromagnetic energy wave 10, and know the state of the final resonant state signal emitted by the energy signal transceiver of the present invention. The user of the present invention can further utilize the final resonance state signal output by the present invention to simulate the energy wave of the energy transmitter with a specific waveform, mode and frequency to make more subsequent applications. The energy transmitter, for example, can be a drug.

Even in the aforementioned embodiment, with respect to a single resistor combination unit, the wire base 150 is provided between the connecting wire 120 and the corresponding resistors 110, and the magnet 130 correspondingly provided on the first supporting plate 140 is provided above the resistors 110. With reference to the length of the inductor wire 113 of the aforementioned embodiment plus the length of the resistor body 111 plus the length of the antenna wire 112, the total length is only 6 mm, that is, a length of the order of millimeters or centimeters. The resistors 110, the connecting wire 120, the magnet 130, the first supporting plate 140 and the wire base 150 of the present invention are generally much smaller than the size of the MORA bioenergy resonance instrument or the Rayonex bioenergy resonance system contained in the prior art. Furthermore, the overall structure of the present invention is simple, which facilitates the user to simply operate and replace different components to quickly change the characteristics of the desired output signal, such as setting the resonant frequency of the resonant state signal, or adjusting the waveform, mode and frequency of the final resonant state signal output after filtering.

10: electromagnetic energy wave 100: first resistor assembly unit 110: resistor 111: resistor body 112: antenna wire 113: inductor wire 120: connecting wire 130: magnet 131: auxiliary structure 140: first support plate 150: wire base 200: second resistor assembly unit 300: third resistor assembly unit 400: fourth resistor assembly unit X: first axis Y: second axis

FIG1 is a schematic diagram of an energy signal transceiver device of the present invention. FIG2 is another schematic diagram of the energy signal transceiver device of the present invention. FIG3 is another schematic diagram of the energy signal transceiver device of the present invention.

10: Electromagnetic energy waves

100: First resistor combination unit

110:Resistance

111: Resistor body

112: Antenna wire

113: Inductor wire

120: Connecting wires

150: Wire base

X: First axis

Y: Second axis

Claims (10)

An energy signal transceiver device comprises: At least one resistor combination unit, comprising a plurality of resistors and a connecting wire; Each resistor has a resistor body and an antenna wire and an inductor wire located at two opposite ends of the resistor body, and one end of the antenna wires of the resistors is open-circuited, and the other ends of the antenna wires of the resistors are respectively connected to each resistor body, and the inductor wires of the resistors are electrically connected between the resistor body and the connecting wire; When each resistor receives a wireless signal from the antenna wire, the wireless signals form a plurality of filter signals through the resistors and the inductor wires, and the inductor wires output the filter signals to the connecting wire; The connecting wire receives the filter signals and generates a resonant signal. An energy signal transceiver device as described in claim 1, wherein the energy signal transceiver device comprises a plurality of the resistor combination units, and the resistor combination units are combined to form an energy signal transceiver module; wherein the connecting wires of the resistor combination units of the energy signal transceiver module are arranged together in a first axial direction. The energy signal transceiver device as described in claim 2, wherein the antenna wires of the resistors of the resistor combination units of the energy signal transceiver module are extended along a second axial direction, and the second axial direction is perpendicular to the first axial direction. The energy signal transceiver device as described in claim 1 further comprises: an output unit electrically connected to the terminal of the connecting wire, converting the resonant state signal output by the connecting wire into an energy signal of another form; a processing unit aligned with the connecting wire of the resistor combination unit; wherein, when the processing unit receives the resonant state signal from the connecting wire of the resistor combination unit, the processing unit generates a waveform analysis result based on the resonant state signal. An energy signal transceiver as described in claim 1, wherein the antenna wires of the resistors are arranged to extend along a second axial direction, and at least one magnet is arranged along the second axial direction, two opposite magnetic poles of the at least one magnet are arranged along the second axial direction and have a gap between the antenna wires, and an auxiliary structure is placed under one of the magnetic poles of the magnets, and the auxiliary structure is an iron wire or an iron sheet. An energy signal transceiver as described in claim 5, wherein the iron wire or the iron sheet of the auxiliary structure forms an elliptical iron ring. The energy signal transceiver device as described in claim 1, wherein the at least one resistor combination unit is a plurality of resistor combination units; wherein the lengths of the inductance wires, the lengths of the resistor bodies and the lengths of the antenna wires of the resistors of the same resistor combination unit are equal, and the lengths of the inductance wires, the lengths of the resistor bodies and the lengths of the antenna wires of two different resistor combination units are unequal. An energy signal transceiver device as described in claim 1, wherein the resistor body of each resistor has a resistance value, and the resistance values of the resistor bodies are different from each other. An energy signal transceiver device as described in claim 1, wherein the resistor combination unit further includes a wire base, the connecting wire is arranged in the wire base and extends from the wire base, and the resistors are inserted into the wire base to electrically connect the connecting wire in the wire base. An energy signal transceiver as described in claim 9, wherein the conductor base is a rectangular parallelepiped.

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