CN214750542U - Control circuit of miniaturized low-frequency array type resonance wave generating device - Google Patents
Control circuit of miniaturized low-frequency array type resonance wave generating device Download PDFInfo
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- CN214750542U CN214750542U CN202022279080.2U CN202022279080U CN214750542U CN 214750542 U CN214750542 U CN 214750542U CN 202022279080 U CN202022279080 U CN 202022279080U CN 214750542 U CN214750542 U CN 214750542U
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Abstract
The utility model provides a miniaturized low frequency array formula resonance wave produces control circuit of device. The control circuit includes: the control circuit is formed by connecting a frequency wave generating unit, a driving circuit amplifying unit, more than three electromagnetic wave antenna units and a power supply unit, the control circuit generates a low-frequency fluctuation mode by using oscillation wave frequency generated by a logic chip, a fluctuation signal is amplified by the circuit driving amplifying unit, alternating waveform current is input into one electromagnetic wave antenna unit, an electromagnetic wave field is emitted by the antenna unit, and meanwhile, the array type resonance wave generating equipment is formed by using more than 3 antennas of the electromagnetic wave antenna units, and the field emitting device has directivity and addition effect.
Description
Technical Field
The utility model relates to a low frequency resonance generating device's control circuit, concretely relates to control circuit with the device that digital array formula low frequency ripples produces the unit and improves the transmission effect.
Background
The utility model discloses an aim at the transmission improvement of low frequency signal, because the transmission wide application of low frequency signal is in many important fields, if: for example, in the research provided by 7.83HZ, the frequency resonance device can generate biological resonance (Bioresonance), and when the vibration characteristics generated by the frequency resonance device are the same as the vibration frequency of the human body, the resonance can be generated, so that the brain waves can be adjusted to a relaxed and relaxed state, and the frequency of the human body can achieve a harmonious effect.
However, the conventional low frequency generating device has very low efficiency, because the generation of low frequency wave needs to be transmitted through a very large antenna theoretically, taking 100Hz low frequency wave as an example, the radio wave speed is calculated by 30 kilometers, theoretically, it is most ideal to optimize the unit of element length of 1/2 wavelengths, i.e. 1500 kilometers long antenna is needed for transmission, and this length of antenna is practically infeasible, so the general practice in the industry is to reduce the length of antenna by half in multiple stages, but this also causes the problem of great attenuation of the low frequency wave transmission efficiency.
SUMMERY OF THE UTILITY MODEL
It is well known that all objects, except dark substances, whose temperature is greater than absolute zero, can emit electromagnetic radiation, and therefore all objects are subjected to electromagnetic radiation at all times. Electromagnetic waves interact with electric or magnetic fields, as described by the principles of the faraday effect, kerr effect, etc. The voltage applied on the antenna is a high frequency voltage, and the electric field and the magnetic field generated by the positive half wave and the negative half wave of each period can change closely because the electric field and the magnetic field can not follow the frequency of the oscillation source, so that the residual electric field and the residual magnetic field which are not lost are continuously expelled by the newly generated electric field and magnetic field to generate radiation.
Therefore, in general, the antenna is made of an element length unit of 1/4 wavelength or 1/2 wavelength, and the most practical antenna is made of conductor elements each having 1/4 wavelength connected to both sides thereof. This is the simplest and most basic antenna, and many other antenna forms are equivalent to the deformation and superposition of dipole antennas.
In order to increase the intensity of electromagnetic waves radiated from the antenna, it is necessary to make the high-frequency current flowing through the antenna conductor as strong as possible. When the antenna circuit is in the resonance state, the current in the circuit is the largest, and the radiation of the antenna is the strongest when the antenna circuit is in the resonance state. Meanwhile, in order to reduce the limited space for installing the antenna in the equipment, the antenna still can accurately generate resonance under the condition that the size of the antenna needs to be reduced.
The utility model discloses a low frequency array formula resonance wave produces control circuit of device, the design includes: a frequency wave generating unit, a driving circuit amplifying unit, more than three electromagnetic wave antenna units, and a power supply unit. The control circuit generates a low-frequency fluctuation mode by the oscillation wave frequency generated by a logic chip, after a fluctuation signal is amplified by a circuit driving amplification unit, alternating waveform current is input to an antenna unit generated by a frequency wave, an electromagnetic wave field is emitted by the antenna unit, and meanwhile, a digital resonance wave generating device is formed by using more than 3 antennas of the electromagnetic wave antenna unit, and the digital resonance wave generating device has directivity and added field emission efficiency. The antenna of the electromagnetic wave antenna unit has the following structure: loading an inductor at the bottom of a terminal on the antenna to enable the antenna to generate resonance so as to obtain better effect; using a helical form antenna to increase the size; and thirdly, the antenna with more than 3 electromagnetic wave antenna units is used to form a plurality of groups of resonance wave generating devices, so that the antenna generates resonance, and the field emission device has directivity and addition effect.
The antenna type can be adjusted and selected according to the use state as follows: the antenna can be matched with an onboard PCB (printed circuit board) antenna, an SMT (surface mount technology) patch type ceramic antenna, an external rod antenna and an FPC (flexible printed circuit) antenna, and is used for products with high performance requirements and sufficient shell space.
Further, the control circuit of the generating device may be provided with a wireless transmission unit, and a user device issues control commands to each device through a mobile phone, a tablet computer, a remote controller and the like by means of wireless communication technology, such as bluetooth, WiFi, Zbee, infrared and the like.
Drawings
The present invention will become more readily understood from the following detailed description, taken in conjunction with the accompanying drawings which are included by way of illustration only, and the invention is not limited thereto.
Fig. 1 is a system architecture diagram of a control circuit of a miniaturized low frequency array type resonance wave generating device according to the present invention.
Reference numerals:
1. a control circuit of the low-frequency array type resonance wave generating device;
2. a frequency wave generating unit;
3. a drive circuit amplification unit;
4. an electromagnetic wave antenna unit;
5. a power supply unit;
6. array type resonance wave generation area.
Detailed Description
The present invention will be described below with reference to examples. The description of the embodiments is illustrative, and the invention is not limited thereto.
Referring to fig. 1, a control circuit of a low frequency array type resonance wave generating device according to the present invention includes: a frequency wave generating unit 2, a driving circuit amplifying unit 3, more than three electromagnetic wave antenna units 4, and a power unit 5. The control circuit generates low-frequency wave mode by oscillation wave frequency generated by logic chip, after wave signal is amplified by drive circuit amplification unit 3, the alternating waveform current is inputted into an electromagnetic wave antenna unit 4, and the electromagnetic wave field is emitted by the antenna unit, at the same time, more than 3 antennas of the electromagnetic wave antenna unit are used to form a array type resonance wave generation area 6 with directivity and additive field emission efficiency. The antenna of the electromagnetic wave antenna unit has the following structure: loading an inductor at the bottom of a terminal on the antenna to enable the antenna to generate resonance so as to obtain better effect; using a helical form antenna to increase the size; and thirdly, the antenna using more than 3 electromagnetic wave antenna units forms a device of a plurality of groups of resonance wave generating areas 6, so that the antenna generates resonance and the field emission device has directivity and addition effect.
The antenna type can be adjusted and selected according to the use state as follows: the antenna can be matched with an onboard PCB (printed circuit board) antenna, an SMT (surface mount technology) patch type ceramic antenna, an external rod antenna and an FPC (flexible printed circuit) antenna, and is used for products with high performance requirements and sufficient shell space.
Further, the control circuit of the generating device may be provided with a wireless transmission unit, and a user device issues control commands to each device through a mobile phone, a tablet computer, a remote controller and the like by means of wireless communication technology, such as bluetooth, WiFi, Zbee, infrared and the like.
In summary, the above-mentioned technical principles are applied to the implementation of the present invention, and if the functions of the present invention are changed according to the conception of the present invention, the functions of the present invention should be understood to be within the scope of the present invention.
Claims (5)
1. A control circuit for a miniaturized low frequency array type resonance wave generating device, comprising: a frequency wave generating unit, a driving circuit amplifying unit, more than three electromagnetic wave antenna units, and a power supply unit; the control circuit generates low-frequency wave mode by the oscillation wave frequency generated by the logic chip, generates various types of low-frequency wave mode under the control of the control circuit, generates a low-frequency wave generating unit, uses a array type resonance wave generating device formed by more than 3 antennae, generates frequency oscillation wave form generated by the logic chip, drives an amplifying unit by the control circuit, inputs the wave form into the low-frequency wave generating unit, emits a wave magnetic field by the low-frequency wave generating unit, and forms the array type resonance wave generating device by using the antennae of more than 3 electromagnetic wave antenna units, thereby having directivity and additive field emission efficiency.
2. The control circuit of a miniaturized low frequency array type resonance wave generating device as claimed in claim 1, wherein said antenna of said electromagnetic wave antenna unit has a field emission device for generating resonance by loading an inductance at a bottom of a terminal on the antenna and for increasing a size by using a helical form antenna.
3. The control circuit of a miniaturized low frequency array type resonance wave generating device as claimed in claim 1, wherein the antenna of said electromagnetic wave antenna unit can be used in combination with one of an on-board PCB type antenna, an SMT patch type ceramic antenna, an external rod antenna, and an FPC antenna.
4. The control circuit of a miniaturized low frequency array type resonance wave generating device as claimed in claim 1, wherein the antenna of said electromagnetic wave antenna unit can be used in combination with one or more of an on-board PCB type antenna, an SMT patch type ceramic antenna, an external rod antenna, and an FPC antenna.
5. A control circuit of a miniaturized low frequency array type resonance wave generating device as claimed in any one of claims 1 to 4, comprising: a wireless transmission unit issues control commands to each device through a user device via a mobile phone, a tablet computer, a remote controller and the like by means of wireless communication technology such as Bluetooth, WiFi, Zbee, infrared and the like remote control.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN202022279080.2U CN214750542U (en) | 2020-10-14 | 2020-10-14 | Control circuit of miniaturized low-frequency array type resonance wave generating device |
Applications Claiming Priority (1)
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CN202022279080.2U CN214750542U (en) | 2020-10-14 | 2020-10-14 | Control circuit of miniaturized low-frequency array type resonance wave generating device |
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CN214750542U true CN214750542U (en) | 2021-11-16 |
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2020
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