CN111157514A - Energy detection device based on GDV - Google Patents
Energy detection device based on GDV Download PDFInfo
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- CN111157514A CN111157514A CN201911369516.2A CN201911369516A CN111157514A CN 111157514 A CN111157514 A CN 111157514A CN 201911369516 A CN201911369516 A CN 201911369516A CN 111157514 A CN111157514 A CN 111157514A
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- G—PHYSICS
- G01—MEASURING; TESTING
- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N21/00—Investigating or analysing materials by the use of optical means, i.e. using sub-millimetre waves, infrared, visible or ultraviolet light
- G01N21/62—Systems in which the material investigated is excited whereby it emits light or causes a change in wavelength of the incident light
- G01N21/66—Systems in which the material investigated is excited whereby it emits light or causes a change in wavelength of the incident light electrically excited, e.g. electroluminescence
- G01N21/67—Systems in which the material investigated is excited whereby it emits light or causes a change in wavelength of the incident light electrically excited, e.g. electroluminescence using electric arcs or discharges
Abstract
The invention provides an energy detection device based on GDV, comprising: the upper side surface of the transparent discharge platform is in contact with a human body; the pulse high-voltage generation module is arranged below the transparent discharge platform and is electrically connected with the transparent discharge platform, and the pulse high-voltage generation module is used for outputting high-voltage pulses to the transparent discharge platform; the main control module is electrically connected with the pulse high-voltage generation module and is used for outputting a high-voltage pulse generation instruction; the image acquisition module is arranged below the transparent discharge platform and electrically connected with the main control module, and the image acquisition module is used for acquiring the glow images of the human body and outputting the glow images to the main control module. The variable-frequency high-voltage pulse generation technology and the low-illumination high-definition image acquisition technology are applied to high-voltage glow image acquisition, the high-voltage pulse frequency and the high-voltage pulse voltage can be accurately controlled, and meanwhile, the high-voltage pulse generation time and the low-illumination camera acquisition time are synchronized through the main control module, so that a clear high-voltage glow image of a human body can be obtained.
Description
Technical Field
The invention relates to the technical field of human body biological signal measurement, in particular to an energy detection device based on GDV.
Background
The earliest physical scientist of the soviet union, krigan in 1976, invented a camera which could shoot the glow of the human body by means of an electromagnetic technique. Modern biophotonic studies have shown that the human body can spontaneously emit electrons and photons, producing a glow that is invisible to the naked eye. Scientists view electrons and photons emitted by the human body as an expression of the energy of the human body. This spontaneous glow is difficult to measure, however, when the human body is in a strong electromagnetic field, the emission of the electrons is excited and can be photographed. GDV (Gas Discharge Visualization) photography allows observation of photon energy emitted from the human body, and changes in the human energy field under different conditions. How to obtain clear human body glow images becomes a problem which needs to be solved urgently.
Disclosure of Invention
In view of this, the invention provides an energy detection device based on a GDV, and aims to solve the problem of how to obtain a clear human body glow image.
In one aspect, the present invention provides a GDV-based energy detection apparatus, including: the upper side surface of the transparent discharge platform is in contact with a human body; the pulse high-voltage generation module is arranged below the transparent discharge platform and is electrically connected with the transparent discharge platform, and the pulse high-voltage generation module is used for outputting high-voltage pulses to the transparent discharge platform; the main control module is electrically connected with the pulse high-voltage generation module and is used for outputting a high-voltage pulse generation instruction; the image acquisition module is arranged below the transparent discharge platform and electrically connected with the main control module, and the image acquisition module is used for acquiring the glow images of the human body and outputting the glow images to the main control module.
Further, still include: and the control module is electrically connected with the main control module and is used for performing human-computer interaction.
Further, the main control module comprises a processing unit, the processing unit is electrically connected with the image acquisition module, and the processing unit is used for receiving the glow images and outputting human health assessment indexes based on a traditional Chinese medicine human body channel theory.
Further, the transparent discharge platform comprises transparent glass, and the upper side face of the transparent glass is in contact with the human body.
Further, the transparent discharging platform comprises a transparent conducting layer, the transparent conducting layer and the transparent glass are arranged side by side, and the transparent conducting layer is electrically connected with the pulse high-voltage generating module.
Further, the transparent conductive layer comprises transparent conductive glass.
Furthermore, the main control module further comprises a control panel, and the control panel is respectively electrically connected with the pulse high voltage generation module and the image acquisition module.
Further, the control panel comprises an android control panel.
Furthermore, the image acquisition module comprises a CCD image acquisition unit, and the CCD image acquisition unit is electrically connected with the main control module.
Further, the image acquisition module still includes low light level high definition digtal camera, low light level high definition digtal camera with the host system electricity is connected.
Compared with the prior art, the invention has the advantages that the transparent discharge platform, the main control module, the pulse high-voltage generation module and the image acquisition module are arranged to acquire the glow image of the human body energy field, the variable-frequency high-voltage pulse generation technology and the low-illumination high-definition image acquisition technology are applied to high-voltage glow image acquisition, the high-voltage pulse frequency and the high-voltage can be accurately controlled, and meanwhile, the high-voltage pulse generation time and the low-illumination camera acquisition time are synchronized through the main control module, so that the clear human body high-voltage glow image can be acquired.
Drawings
Various other advantages and benefits will become apparent to those of ordinary skill in the art upon reading the following detailed description of the preferred embodiments. The drawings are only for purposes of illustrating the preferred embodiments and are not to be construed as limiting the invention. Also, like reference numerals are used to refer to like parts throughout the drawings. In the drawings:
fig. 1 is a schematic structural diagram of a GDV-based energy detection device according to an embodiment of the present invention;
FIG. 2 is a schematic structural diagram of a GDV-based energy detection device according to an embodiment of the present invention;
fig. 3 is a functional schematic diagram of a GDV-based energy detection device according to an embodiment of the present invention.
Detailed Description
Exemplary embodiments of the present disclosure will be described in more detail below with reference to the accompanying drawings. While exemplary embodiments of the present disclosure are shown in the drawings, it should be understood that the present disclosure may be embodied in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art. It should be noted that the embodiments and features of the embodiments may be combined with each other without conflict. The present invention will be described in detail below with reference to the embodiments with reference to the attached drawings.
Referring to fig. 1 and 2, the present embodiment provides a GDV-based energy detection apparatus, including: the device comprises a transparent discharge platform 2, a pulse high voltage generation module 3, a main control module 1 and an image acquisition module 4, wherein the upper side surface of the transparent discharge platform 2 is in contact with a human body; the pulse high-voltage generation module 3 is arranged below the transparent discharge platform 2 and is electrically connected with the transparent discharge platform 2, and the pulse high-voltage generation module 3 is used for outputting high-voltage pulses; the main control module 1 is electrically connected with the pulse high-voltage generation module 3, and the main control module 1 is used for outputting a high-voltage pulse generation instruction; the image acquisition module 4 is arranged below the transparent discharge platform 2 and electrically connected with the main control module 1, and the image acquisition module 4 is used for acquiring glow images of a human body and outputting the glow images to the main control module 1.
Specifically, the pulse high voltage generation module 3, the main control module 1 and the image acquisition module 4 are arranged in the shell 5, the transparent discharge platform 2 is arranged on one side surface of the shell 5, and the pulse high voltage generation module 3, the main control module 1 and the image acquisition module 4 are all located below the transparent discharge platform 2.
Specifically, the human body is placed on the upper side of the transparent discharge platform 2, a working instruction is sent to the pulse high-voltage generation module 3 through the main control module 1, a high-voltage pulse signal is generated instantaneously on the lower side of the transparent discharge platform 2, the human body generates a glow image under the action of an electric field, the glow image formed by the human body tip under the high-voltage electric field is collected through the image collection module 4, and the main control module 1 outputs human body health assessment indexes according to the glow image.
Specifically, the main control module 1 is further configured to receive the glow image and output a health assessment index.
Specifically, the main control module 1 comprises a processing unit, the processing unit is electrically connected with the image acquisition module 4, and the processing unit is used for receiving the glow images and outputting human health assessment indexes based on the traditional Chinese medicine human body meridian theory.
Specifically, the energy detection device further comprises a control module, wherein the control module is electrically connected with the main control module 1 and is used for human-computer interaction.
Specifically, the control module comprises a display screen for displaying the human health assessment index data.
Preferably, the control module is a computer, and may also be a control panel, a notebook, a mobile phone, or the like.
Specifically, the pulsed high voltage generation module 3 includes a variable frequency high voltage controller and a high voltage package.
Specifically, the transparent discharge platform 2 includes a transparent glass 21, and an upper side of the transparent glass 21 is in contact with a human body.
Preferably, the transparent glass 21 is preferably a glass having high light transmittance.
Specifically, the transparent discharge platform 2 includes a transparent conductive layer 22, the transparent conductive layer 22 is disposed in parallel with the transparent glass 21, and the transparent conductive layer 22 is electrically connected to the pulse high voltage generation module 3.
Specifically, the transparent glass 21 and the transparent conductive layer 22 are closely attached together.
Specifically, the transparent conductive layer 22 may be transparent conductive glass, a transparent conductive film, or the like. The transparent conductive glass can be AZO zinc oxide based coated glass, FTO glass, ITO glass or TCO glass and the like. The transparent conductive film may be a metal film, an oxide film, another compound film, a polymer film, a composite film, or other conductive film.
Preferably, the transparent conductive layer 22 is preferably an ITO glass or a TCO glass, i.e. the transparent conductive glass is preferably an ITO glass or a TCO glass.
Specifically, the main control module 1 further comprises a control board, and the control board is electrically connected with the pulse high voltage generation module 3 and the image acquisition module 4 respectively. Preferably, the processing unit is disposed on the control board.
In particular, the dashboard includes an android dashboard.
Specifically, the image acquisition module 4 includes a CCD image acquisition unit, and the CCD image acquisition unit is electrically connected to the main control module 1. The CCD image acquisition unit is preferably a CCD image sensor.
Particularly, the image acquisition module 4 further comprises a low-illumination high-definition camera, the low-illumination high-definition camera is electrically connected with the main control module 1, and the low-illumination high-definition camera is used for acquiring glow images.
Particularly, the main control module 1 synchronously controls the pulse high-voltage generation module 3 and the low-illumination high-definition camera, so that when the pulse high-voltage generation module 3 generates high-voltage pulses, the low-illumination high-definition camera synchronously collects glow images, and further avoids the energy waste caused by the asynchronism between the low-illumination high-definition camera and the pulse high-voltage generation module, thereby saving energy, further improving the image collection efficiency and improving the working efficiency.
Specifically, the human body includes four limbs and a trunk of the human body, the four limbs mainly include arms, palms, fingers, legs, soles, toes and the like of the human body, and the trunk mainly includes the head, the chest, the back and the like of the human body. The transparent discharge platform 2 is respectively contacted with the limbs, the trunk and other parts of the human body, so as to collect glow images of the corresponding parts.
Specifically, the limbs, the trunk, and the like of the human body include information of channels, collaterals, acupuncture points, and the like of the human body, and the main control module 1 can output human body health assessment indexes of the human body based on the human body channel theory according to the collected glow image information of the limbs, the trunk, and the like of the human body.
In the specific implementation, the glow image of a finger of a human body is collected as an example and will be described in detail with reference to fig. 3. The fingers of a human body are stably placed on the upper side of the transparent discharge platform 2, a gas discharge area is formed on the upper side of the transparent glass 21 of the transparent discharge platform 2, meanwhile, after each finger is ensured to be stably contacted with the transparent glass 21 of the transparent discharge platform 2, the control module and the control circuit in the main control module 1 carry out man-machine interaction, a measurement starting button on a man-machine interface on the control module is clicked, the control circuit in the main control module 1 corresponds to a control instruction output by the control module, the control circuit outputs a high-voltage module working signal, the pulse high-voltage generation module 3 is electrically connected with the transparent conductive layer 22, pulse high voltage is generated on the lower side of the transparent conductive layer 22, meanwhile, the fingers generate glow in a high-voltage field, after a CCD image acquisition unit in the image acquisition module 4 captures a glow image of the finger, a low-illumination high-definition camera shoots, the main control module 1 processes the glow image, analyzes data based on the traditional Chinese medicine human body meridian theory, outputs human body health assessment indexes, and simultaneously transmits the human body health assessment indexes to the control module for display through the main control module 1.
Specifically, the high voltage pulse of the pulsed high voltage generation module 3 is preferably 13kV900 Hz.
It can be seen that by arranging the transparent discharge platform 2, the main control module 1, the pulse high-voltage generation module 3 and the image acquisition module 4, glow images of a human body energy field are acquired, the variable-frequency high-voltage pulse generation technology and the low-illumination high-definition image acquisition technology are applied to high-voltage glow image acquisition, the high-voltage pulse frequency and the high-voltage pulse voltage can be accurately controlled, and meanwhile, the high-voltage pulse generation time and the low-illumination camera acquisition time are synchronized through the main control module 1, so that clear human body high-voltage glow images can be acquired.
Specifically, when glow images of 10 fingers of the left hand and the right hand of a human body are collected, the left hand and the right hand are respectively collected, after two glow image photos are collected, the two collected glow image photos are transmitted to the main control module 1, an analysis algorithm is arranged in the main control module 1, the position of each finger is located according to the glow images, marking is carried out, decomposition and feature extraction are carried out on the glow images of each finger, then image information interpretation is carried out according to a meridian theory, a health report is generated according to the interpreted result, and therefore the human health assessment index is obtained.
Specifically, the main control module 1 embeds an analysis algorithm of an image based on the human body meridian theory, and the main control module 1 analyzes the glow image through the image analysis algorithm so as to output human body health assessment indexes.
Specifically, after the analysis algorithm built in the main control module 1 performs deep learning algorithm calculation through a large number of glow images, the calculation precision is gradually improved, so that the accuracy of the output human health assessment index is improved.
Specifically, when the main control module 1 performs deep learning, the analysis calculation model is established, training and learning are performed continuously, the analysis algorithm can improve the analysis calculation model continuously, and the glow images acquired in real time are analyzed and calculated according to the calculation model to obtain the human health assessment index.
Specifically, the theory of human meridians mainly includes the records of Ling Shu in Huangdi's Canon and other traditional Chinese medical classics.
Specifically, the main control module 1 is specifically configured to calculate various feature values of an image according to a finger glow image, and then calculate different health information according to relationships between fingers and meridians, acupuncture points and viscera in traditional Chinese medical classics, so as to obtain human health assessment indexes.
Specifically, the human health assessment index comprises a human body total energy value, a mental pressure value, a twelve meridian energy value and left and right balance state information.
Specifically, the glow images of the limbs, trunk, and the like of the other human body may be acquired and the human health evaluation index may be output in a manner of acquiring the glow images of the fingers and outputting the human health evaluation index. When glow images of the arms, the palms, the fingers, the legs, the soles, the toes and the like of the human body and the positions of the heads, the chests, the backs and the like of the human body are collected, all the parts are only required to be in contact with the transparent discharge platform 2, and the glow images of all the parts, namely the positions, are collected through the image collection module 4.
Specifically, after the glow information of the limbs, trunk and other parts of the human body is collected, the main control module 1 is specifically configured to calculate various characteristic values of the image according to the finger glow image, and then calculate different health information according to the relationship between the fingers and the meridians, the acupuncture points and the viscera in the traditional Chinese medical classical book, so as to obtain the human health assessment index.
Specifically, the main control module 1 is specifically configured to calculate various feature values of the image according to glow images of parts of the human body, such as limbs and trunk, and then calculate different health information according to relationships between the parts of the human body, such as limbs and trunk, and meridians, acupuncture points and viscera in traditional Chinese medical classics, so as to obtain human health assessment indexes.
It can be seen that the transparent discharging module, the main control module 1, the pulse high voltage generating module 3 and the image collecting module 4 are arranged to collect the GDV image information of the human body energy field, the health condition information of the human body is obtained through the processing and analysis of the GDV image information of the human body energy field, the health condition of the human body is assessed at any time, and the health consciousness of people is improved.
Furthermore, the invention crosses the gap that the traditional Chinese medicine thinking mode is incompatible with the modern science, provides a new technical means for evaluating and detecting the qi field and the energy field in the Chinese medicine theory, and promotes the development of the Chinese medicine by applying the modern scientific and technical means.
It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.
Claims (10)
1. A GDV-based energy detection device, comprising:
the upper side surface of the transparent discharge platform is in contact with a human body;
the pulse high-voltage generation module is arranged below the transparent discharge platform and is electrically connected with the transparent discharge platform, and the pulse high-voltage generation module is used for outputting high-voltage pulses to the transparent discharge platform;
the main control module is electrically connected with the pulse high-voltage generation module and is used for outputting a high-voltage pulse generation instruction;
the image acquisition module is arranged below the transparent discharge platform and electrically connected with the main control module, and the image acquisition module is used for acquiring the glow images of the human body and outputting the glow images to the main control module.
2. The GDV-based energy detection device of claim 1, further comprising: and the control module is electrically connected with the main control module and is used for performing human-computer interaction.
3. The GDV-based energy detection device of claim 1,
the main control module comprises a processing unit, the processing unit is electrically connected with the image acquisition module, and the processing unit is used for receiving the glow images and outputting human health assessment indexes based on the traditional Chinese medicine human body meridian theory.
4. The GDV-based energy detection device of claim 1,
the transparent discharging platform comprises transparent glass, and the upper side face of the transparent glass is in contact with the human body.
5. The GDV-based energy detection device of claim 4,
the transparent discharging platform comprises a transparent conducting layer, the transparent conducting layer and the transparent glass are arranged side by side, and the transparent conducting layer is electrically connected with the pulse high-voltage generating module.
6. The GDV-based energy detection device of claim 5,
the transparent conductive layer comprises transparent conductive glass.
7. The GDV-based energy detection device of claim 1,
the main control module further comprises a control panel, and the control panel is electrically connected with the pulse high voltage generation module and the image acquisition module respectively.
8. The GDV-based energy detection device of claim 7, wherein the control board comprises an android control board.
9. The GDV-based energy detection device of claim 1,
the image acquisition module comprises a CCD image acquisition unit, and the CCD image acquisition unit is electrically connected with the main control module.
10. The GDV-based energy detection device of claim 9,
the image acquisition module further comprises a low-illumination high-definition camera, and the low-illumination high-definition camera is electrically connected with the main control module.
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| CN112603261A (en) * | 2020-11-30 | 2021-04-06 | 新绎健康科技有限公司 | System and method for predicting abnormal blood lipid value based on gas discharge imaging technology |
| CN112690787A (en) * | 2020-11-30 | 2021-04-23 | 新绎健康科技有限公司 | Noninvasive blood glucose screening system based on gas discharge imaging technology |
| CN113628743A (en) * | 2021-07-01 | 2021-11-09 | 新绎健康科技有限公司 | Uric acid abnormity screening method and system based on gas discharge imaging technology |
| CN114138130A (en) * | 2021-10-20 | 2022-03-04 | 新绎健康科技有限公司 | Finger limiting touch device based on GDV technology |
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Application publication date: 20200515 |