Artificial field imaging technology
By using artificially controlled field imaging technology, electromagnetic field generators are converted into gravitational fields to achieve radiation-free, long-distance material scanning and detection. This overcomes the limitations of traditional detection methods and is suitable for material detection and imaging in complex environments.
Patent Information
- Authority / Receiving Office
- WO · WO
- Patent Type
- Applications
- Current Assignee / Owner
- YE RUIJUN
- Filing Date
- 2024-12-26
- Publication Date
- 2026-07-02
AI Technical Summary
Traditional detection methods such as electromagnetic waves, sound waves, and nuclear magnetic resonance have limitations such as safety concerns, detection distance limitations, and environmental interference, making it difficult to meet the needs of specific application scenarios.
By using artificial field imaging technology, a changing electromagnetic field is generated by an electromagnetic field generator and converted into a gravitational field. Combined with an imaging system and an artificial intelligence detection module, it is possible to achieve radiation-free, long-distance scanning and imaging, as well as detection of the state of matter.
It achieves radiation-free, long-distance material scanning and detection, can penetrate complex environments, and is suitable for underground structure detection and deep-sea resource exploration. It has significant safety and environmental advantages, reducing potential harm to the detected objects and operators.
Smart Images

Figure CN2024142628_02072026_PF_FP_ABST
Abstract
Description
Artificial field imaging technology TECHNICAL FIELD
[0001] The present application relates to the cutting-edge field of unified field technology, focusing on an innovative technology that precisely controls the field to achieve accurate imaging. BACKGROUND
[0002] Traditional detection methods such as electromagnetic waves, sound waves, and nuclear magnetic resonance, while showing important application value in their respective professional fields, also come with multiple challenges such as safety concerns, detection distance limitations, radiation effects, and environmental interference. These limitations greatly restrict their effectiveness in specific application scenarios, and in some extreme cases, may even cause potential safety risks.
[0003] In view of the above limitations, the emergence of unified field technology provides a new perspective and possibility to solve these problems. It not only hopes to overcome the various difficulties faced by traditional detection methods, but also may open up a new path for the innovation and development of detection technology. Through the application of unified field technology, we hope to promote technological innovation in related fields and promote the overall progress of detection technology, thereby meeting more extensive and in-depth detection needs. TECHNICAL PROBLEM
[0004] The present application proposes an artificial field imaging technology that uses electromagnetic field generators to transform and manipulate gravitational fields, achieving non-radiation, long-distance scanning, perspective, and material state detection functions. TECHNICAL SOLUTION
[0005] To achieve the above technical objectives, the present application adopts the following technical solutions: The present application relates to an artificial field imaging technology that integrates a driving circuit, an electromagnetic field generator, a vacuum system, a gas system, a heat dissipation system, a signal receiving and processing circuit, an imaging system, and an artificial intelligence detection module. The driving circuit excites the electromagnetic field generator, causing positive and negative charges to move and produce a changing electromagnetic field under certain conditions. This changing electromagnetic field is further transformed into a gravitational field, which is used for non-radiation, long-distance scanning and perspective. Finally, the imaging system captures and processes image information. At the same time, the artificial intelligence detection module analyzes the imaging results to achieve accurate detection of the material state.
[0006] Preferably, in this invention, the signal amplification and driving circuit is designed to generate a precise output corresponding to the desired electromagnetic field. This circuit includes an input voltage rectification section to ensure voltage stability and applicability. To improve the electric field strength, this invention employs specific methods, including but not limited to adjusting circuit parameters and optimizing structural design. The electromagnetic field generator, based on specific principles and circuit design, can efficiently convert electrical energy into an electromagnetic field. The accompanying sensing components have carefully selected and designed internal structures and types to ensure stable and accurate reception and processing of signals from the electromagnetic field. Regarding the anode shape and filament position of the electromagnetic field generator, this invention proposes an optimized design scheme to improve the efficiency and stability of charge movement. Simultaneously, to guide the charges in a specific curved motion, this invention also designs a magnetic field scheme that can precisely control the trajectory of the charges. During the ionization of gas, if the power is insufficient, this invention also provides supplementary solutions, including increasing power supply and optimizing the ionization chamber design, to ensure the smooth progress of the ionization process and thus meet imaging requirements.
[0007] Preferably, the digital signals in this invention first undergo an encoding stage and necessary preprocessing steps to ensure that the signal format meets the specific requirements for transmission and driving. Subsequently, these preprocessed digital signals are transmitted to a power amplifier circuit. In the power amplifier circuit, the signal amplitude is significantly increased to provide sufficient driving force to activate subsequent circuit components or devices. The power-amplified digital signals continue to the driver board, which integrates decoding and logic processing modules. These modules can accurately analyze the signal content and generate corresponding control commands accordingly. These control commands are then passed to a boost circuit, whose main function is to further adjust the voltage or current levels of the signals to ensure they perfectly match the operational requirements of the electromagnetic field generator. Finally, the precisely processed signals from the boost circuit are applied to the electromagnetic field generator, which generates an electromagnetic field corresponding to the original digital signals, providing the necessary physical basis for the subsequent imaging system.
[0008] Preferably, the rectifier circuit used in this invention is a circuit structure for converting alternating current (AC) to direct current (DC). The main types of rectifier circuits include half-wave rectifier circuits, full-wave rectifier circuits, bridge rectifier circuits, and voltage doubler rectifier circuits. The main function of the rectifier circuit is to convert the AC power supplied by the AC power source into unidirectional pulsating DC power, providing a stable DC voltage or current for subsequent circuits. This conversion process is crucial for the stable operation of the electromagnetic field generator and the accurate imaging of the imaging system.
[0009] Preferably, the present invention employs multiple methods to improve the electric field strength of the electromagnetic field generator. These methods include: adding capacitor banks to the circuit to store and release more electrical energy; increasing the power supply to provide a more sufficient energy supply for the electromagnetic field generator; for gas-type electromagnetic field generators, enhancing the ionization effect by increasing the pressure or flow rate of the working gas; and simultaneously improving the secondary coil of the transformer, including increasing the number of turns to increase the voltage output and thickening the coil diameter to reduce energy loss, thereby further enhancing the electric field strength. These measures work together to significantly improve the performance of the electromagnetic field generator.
[0010] Preferably, this invention describes a unique physical phenomenon: an electromagnetic field can be transformed into a gravitational field with the opposite direction under specific conditions. When the polarities of the electromagnetic fields are reversed, the directions of these two fields (electromagnetic and gravitational fields) change simultaneously. Furthermore, when a charge moves in a curved path within an electromagnetic field, not only is a corresponding electromagnetic field distribution generated, but a corresponding gravitational field state is also produced. This interaction and transformation between electromagnetic and gravitational fields provides new perspectives and possibilities for exploring and understanding the physical laws of nature.
[0011] Preferably, the electromagnetic field generators in this invention can be classified into two basic types based on their operating efficiency: vacuum type and gas type. Further, according to differences in their operating structures, these electromagnetic field generators can be subdivided into five specific types. Specifically, vacuum type electromagnetic field generators include: a point-line-plane integrated operating structure, a structure focused on surface operation, and a structure with three-dimensional operating capabilities. Gas type electromagnetic field generators are divided into: a surface divergence operating structure, which mainly focuses on the diffusion effect of gas on a plane; and a three-dimensional divergence operating structure, which focuses on the diffusion and control of gas in three-dimensional space. This classification not only helps in understanding the different working principles of electromagnetic field generators but also provides clear guidance for selection in practical applications.
[0012] Preferably, in embodiments of the present invention, the electromagnetic field generator is preferably configured with a support system matching its type to meet its specific operational requirements. Specifically: for vacuum-type electromagnetic field generators, a vacuum system is preferably provided, which can provide and maintain the required vacuum environment to ensure stable operation of the electromagnetic field generator at a predetermined vacuum level; for gas-type electromagnetic field generators, a gas system is preferably provided, which can accurately provide and regulate the required gas medium, including key parameters such as gas type, flow rate, and pressure, to meet the working requirements of the electromagnetic field generator. With such configuration, the electromagnetic field generator in the present invention can automatically adapt to the corresponding support system according to its type, thereby ensuring that artificial field imaging technology is carried out under the most suitable working conditions, improving imaging quality and system stability.
[0013] Preferably, the electromagnetic field generator in this invention features a flexible design. When the anode is designed on one side, its shape can be arbitrary, while the filament is located on the opposite side of the anode. In vacuum-type electromagnetic field generators, the housing is typically made of high-temperature resistant glass or ceramic materials to ensure stable operation in vacuum and high-energy particle environments. For gas-type electromagnetic field generators, the housing must be resistant to high temperatures and high pressures to withstand the extreme conditions during gas discharge. When the anode is designed as a hollow cube structure, its external shape can be customized according to the specific needs of the application. Based on this, the filament position exhibits different configurations under different conditions: in a vacuum environment, to ensure the uniformity of electron emission and the stability of discharge, the filament is precisely positioned at the centroid of the hollow cube anode. In a gas discharge environment, the filament position is more flexible. It can remain at the centroid to maintain the uniformity and stability of the discharge; or it can be adjusted to the other side of the anode cube according to specific application requirements, such as guiding the direction of electron flow or optimizing discharge performance. Whether it's a vacuum-type or gas-type electromagnetic field generator, its construction requires ensuring that the anode material and the filament sealing area possess high-temperature and high-pressure resistance. This choice of conductive materials is to maintain the stability and durability of the equipment in complex electromagnetic environments. This design not only meets the performance requirements of the electromagnetic field generator in different application scenarios but also provides strong assurance for its flexibility and adaptability in practical use.
[0014] Preferably, the methods for changing the direction of charge movement in this invention primarily rely on different types of magnetic fields. These methods include: using a constant magnetic field generated by a permanent magnet to guide the charge's directional deflection through its stable magnetic pole direction; employing a pulsed magnetic field to rapidly switch the charge's direction of movement through rapidly changing magnetic field strength over a short period; using an alternating magnetic field, whose direction changes periodically with time, thereby periodically changing the charge's trajectory; and using a direct current magnetic field, whose direction remains constant, but whose strength and direction can also effectively control the charge's path. These methods provide diverse means for precisely manipulating charge movement, contributing to the realization of more complex electromagnetic field control and imaging technologies.
[0015] Preferably, when the filament power of the electromagnetic field generator cannot meet the requirements for ionization gas, this invention proposes several methods for supplementing the ionization gas. These methods include: using microwave technology to excite gas molecules to achieve ionization; promoting gas ionization through high-voltage discharge generated by a Tesla coil; using high-voltage arcing technology to generate a strong electric field in the gas to induce ionization; and using laser or ultraviolet radiation to directly act on gas molecules, causing them to absorb energy and ionize. When selecting the type of ionization gas, safety and efficiency are two crucial considerations. Therefore, in practical applications, safety testing should be conducted first to ensure that the selected gas does not pose a threat to equipment or operators during ionization. After ensuring safety, the ionization efficiency of the gas should then be considered to select the gas type most suitable for the current application scenario. This design approach ensures the stability of the ionization process and improves the overall safety and reliability of the electromagnetic field generator.
[0016] Preferably, the power supply used in this invention is an adjustable power supply, whose output can be precisely adjusted according to actual needs, and it has a monitoring function that can monitor the power supply's operating status in real time. This power supply achieves good matching with the driver board, transformer, and electromagnetic field generator, ensuring efficient energy transmission and conversion. Simultaneously, to ensure the safety and stability of the filament power supply circuit, this invention specifically designs an isolation high-voltage transformer. This design effectively isolates the filament power supply circuit from the main circuit, avoiding direct impact of high voltage on the filament circuit, thereby extending the filament's lifespan and improving the overall operational safety of the electromagnetic field generator. Through these series of optimization measures, this invention not only improves the performance of the electromagnetic field generator but also provides strong support for its stable operation in complex environments.
[0017] Preferably, the monitoring system of this invention covers real-time monitoring of multiple key parameters to ensure the stable operation and high efficiency of the electromagnetic field generator. These monitoring items include, but are not limited to: voltage, current, and power, which directly reflect the output characteristics of the power supply and the energy consumption of the electromagnetic field generator; electric field strength and magnetic field strength, which are important indicators for evaluating the performance of the electromagnetic field generator; temperature, used to monitor the operating temperature of the equipment and prevent performance degradation or damage caused by overheating; pressure, especially in gas-type electromagnetic field generators, used to monitor the pressure state of the internal gas; velocity and acceleration, used to track physical changes in dynamic processes; radiation, to ensure that electromagnetic radiation is within a safe range and to protect operators from potential harm; coordinates, used to accurately locate the position of the electromagnetic field generator; flow rate and velocity, which are particularly important in systems involving gas or liquid flow; displacement, to monitor changes in the position of objects; and vibration and noise, used to assess the mechanical stability of the equipment and the comfort of the operating environment. By comprehensively monitoring these parameters, this invention can achieve precise control over the operating status of the electromagnetic field generator, thereby ensuring its efficient and safe operation.
[0018] Preferably, in a preferred embodiment of the present invention, the mentioned gravitational field exhibits a unique property: the ability to drive the motion of all types of matter. This characteristic gives the gravitational field broad application potential in the field of physics. More advancedly, the present invention discloses an innovative mechanism through which specific states or changes of the gravitational field can be effectively converted into electromagnetic signals. This conversion process not only broadens the application scope of the gravitational field but also provides a new way to realize the interaction and conversion between the gravitational field and the electromagnetic field. In the context of artificial field imaging technology, this characteristic is particularly crucial because it allows us to indirectly detect and analyze the existence and dynamic changes of the gravitational field by monitoring and analyzing the electromagnetic signals converted from the gravitational field. In summary, the gravitational field mentioned in the present invention not only has the basic ability to drive the motion of matter but also possesses an innovative conversion mechanism that can transmit and analyze the information of the gravitational field in the form of electromagnetic signals, thereby greatly enhancing its value in scientific research and practical applications.
[0019] Preferably, the gravitational field mentioned in this invention possesses the ability to drive the motion of all matter and is the fundamental driving force of matter motion. Within the framework of unified field theory, the gravitational field, as the parent field, plays a core role and has the ability to further induce the sensing components to convert into electromagnetic signals. The matching sensing components exhibit extremely high flexibility and diversity. These sensing components can include, but are not limited to: various types of antennas for receiving and converting electromagnetic signals; various coils that utilize the principle of electromagnetic induction to achieve energy conversion and transmission; various conductors that serve as carriers of current and charge flow; various insulators that, although not conductive themselves, can serve as shielding or supporting materials for electromagnetic fields under specific conditions; and various semiconductors whose conductivity lies between that of conductors and insulators, which can be used to construct complex electronic circuits and sensors. By selecting and combining these different types of sensing components, this invention can achieve precise sensing and response to gravitational and electromagnetic fields, thereby meeting the needs of various application scenarios. This flexibility and diversity not only improves the performance of the electromagnetic field generator but also provides unlimited possibilities for its application in a wider range of fields.
[0020] Preferably, this invention employs flexible analog signal amplification circuits for signal processing. These circuits can be simple single-transistor amplifiers or complex multi-transistor amplifiers to meet the amplification requirements of different signal strengths. In the analog-to-digital signal conversion process, this invention particularly emphasizes optimizing three key stages: sampling, quantization, and encoding, to ensure signal accuracy and integrity. Specifically, the sampling process must ensure accurate capture of information at key points of signal change to avoid information loss; the quantization process must convert continuously changing analog signals into discrete digital signals while minimizing quantization errors; and the encoding process converts the quantized digital signals into a format suitable for storage or transmission. Furthermore, this invention has also carefully optimized the circuit design to improve the efficiency and stability of signal conversion. Through these measures, this invention not only improves the accuracy and speed of signal processing but also provides a solid foundation for subsequent digital signal processing and analysis.
[0021] Preferably, the imaging system of this invention integrates artificial intelligence technology, using intelligent algorithms to perform in-depth analysis and optimization of imaging data. This combination not only improves the accuracy and clarity of imaging but also enables the imaging system to automatically identify and analyze key information in the image, providing strong support for subsequent decision-making and judgment. Through the introduction of artificial intelligence technology, the performance of the imaging system is significantly improved, bringing users a more intelligent and efficient imaging experience.
[0022] Preferably, in a preferred embodiment of the present invention, the imaging system is cleverly equipped with a heat dissipation system. This design aims to ensure that the key components of the system—the chip and the electromagnetic field generator—maintain stable performance during continuous operation. The heat dissipation system prevents overheating by effectively removing the heat generated by these components during operation, thereby extending their operating time and lifespan. Specifically, the heat dissipation system may include, but is not limited to, highly efficient heat dissipation components such as fans, radiators, heat pipes, thermoelectric coolers, water cooling, and intelligent control units. These components work together to rapidly dissipate the heat generated by the chip and the electromagnetic field generator to the surrounding environment, ensuring that the system maintains stable imaging quality and performance under long-term, high-intensity operating conditions. Therefore, by introducing a heat dissipation system, the imaging system of the present invention not only improves the stability and reliability of the system but also provides users with a more durable and efficient imaging experience. Beneficial effects
[0023] In summary, the technical effects and advantages of this invention are as follows;
[0024] This invention utilizes a changing electromagnetic field to generate a gravitational field for scanning and imaging of matter. It can scan and detect remotely without radiation or obstructions, representing another major advancement following electromagnetic wave, sound wave, and nuclear magnetic resonance imaging.
[0025] The core of this invention lies in exploring and applying a novel coupling mechanism between electromagnetic and gravitational fields. By precisely controlling and varying the frequency, intensity, and spatial distribution of the electromagnetic field, a weak gravitational effect can be induced. Although this effect is small, it is sufficient to be captured by precision detection equipment and transformed into a three-dimensional image of the internal structure of matter. This theoretical innovation provides a completely new physical basis for non-contact, radiation-free scanning imaging technology. To realize the application of the above theory, this invention designs a high-precision gravitational detection system. Through algorithm optimization and data processing, these fluctuations are transformed into high-precision images of the material structure. After acquiring the gravitational fluctuation data, this invention employs advanced image reconstruction algorithms and analytical techniques to transform the raw data into intuitive, high-resolution images of the internal structure of matter. These algorithms not only consider the physical characteristics of gravitational fluctuations but also incorporate machine learning and artificial intelligence algorithms to improve image quality and recognition accuracy. Thanks to the penetrating power of the gravitational field and the long-distance propagation characteristics of the electromagnetic field, this invention can perform long-distance scanning without regard to obstacles. Neither solid obstacles, liquids, nor gaseous media can block the propagation of gravitational fluctuations. This makes the technology particularly suitable for material detection and imaging in complex environments, such as underground structure detection and deep-sea resource exploration. Compared with traditional electromagnetic wave, acoustic wave, or nuclear magnetic resonance imaging technologies, this invention has significant safety and environmental advantages. It does not require the use of radioactive materials or strong magnetic fields, thus posing no potential harm to the object being inspected or personnel. Furthermore, the technology does not require contact with the object being inspected, reducing the risk of physical damage and contamination. Attached Figure Description
[0026] To more clearly illustrate the technical solutions in the embodiments of the present invention or the prior art, the accompanying drawings referenced in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below represent only some embodiments of the present invention. Those skilled in the art can derive other related drawings based on these drawings without creative effort.
[0027] Figure 1 shows a schematic diagram of the overall structural layout of the present invention.
[0028] Figure 2 presents a mind map diagram illustrating the conceptual idea and components of this invention.
[0029] Figure 3 shows a schematic diagram of the electrical connections and circuit layout of the present invention.
[0030] Figures 4 to 8 show schematic diagrams of five different structural designs of the electromagnetic field generator in this invention.
[0031] Figure 9 shows a schematic diagram of the anode structure type used in the electromagnetic field generator of this invention.
[0032] Figure 10 shows a schematic diagram of the type of housing structure employed in the electromagnetic field generator of the present application.
[0033] Figure 11 presents a schematic diagram of the type of structure employed in the inductive assembly of the present application.
[0034] Figure 12 presents a schematic diagram of the core theoretical formulae and their generalised representation upon which the present application is based.
[0035] In Figures 1, 3 to 11, the meanings of each label are as follows: Computer and Server (1): As the control center of the entire system, it is responsible for data processing, instruction issuance, and communication with other modules. The computer and server receive data from various sensors and circuit modules, perform real-time analysis, processing, and storage, and generate control instructions according to preset algorithms and models, which are then sent to various execution modules through the communication circuit. Adjustable Power Supply Circuit and Related Circuit Components (2): Adjustable Power Supply Circuit: Provides a stable and adjustable power supply to meet the power requirements of different components. By adjusting the output voltage and current, it ensures that various modules such as the electromagnetic field generator and signal processing circuit can work normally. Communication Circuit: Enables data transmission and instruction exchange between the computer and server and other circuit modules. It adopts a high-speed and reliable communication protocol to ensure the real-time performance and accuracy of the data. Signal Amplification Circuit: Amplifies the received weak signal to improve the signal-to-noise ratio and anti-interference capability. Drive Circuit: Converts the amplified signal into a power signal that can drive subsequent loads (such as step-up transformers). Boost circuit: The voltage level is increased by a boost transformer (201) to meet the high voltage requirements of the electromagnetic field generator. At the same time, an isolation transformer (202) is used to isolate the high voltage circuit from the low voltage circuit to ensure the safety of the system. Rectifier circuit: Converts AC to DC to provide a stable DC power supply for the electromagnetic field generator. Monitoring circuit: Monitors the working status of the power supply circuit in real time, including parameters such as voltage and current, to ensure the safe and stable operation of the system. Once an abnormality is detected, the protection mechanism is triggered immediately to prevent the fault from escalating. Capacitor bank: Used for energy storage and filtering to improve the stability and anti-interference ability of the power supply. By reasonably selecting the capacity and type of capacitors, the performance of the power supply can be further improved. Vacuum system or gas system: The vacuum system creates the required vacuum level for the vacuum type electromagnetic field generator, while the gas system supplies the necessary gas to the gas type electromagnetic field generator. Electromagnetic field generator (3): As the core component of the system, it is responsible for generating and controlling the generation and change of the electromagnetic field. By adjusting parameters such as the accelerating voltage, current and magnetic field scheme of the electron beam, precise control of the electromagnetic field can be achieved. Filament (301): As the source of the electron beam, it generates the electron beam through heating. The temperature and current of the filament determine the emission density and velocity of the electron beam. Anode Type (302): The anode is connected to the positive terminal of the power supply. When the electron beam is emitted from the cathode (i.e., the filament) and hits the anode, the electrons are accelerated and collide with the anode due to the potential difference between the electrons and the anode. In this process, the kinetic energy of the electrons is converted into electromagnetic energy, thereby generating a changing electromagnetic field near the anode. This changing electromagnetic field is key to the subsequent imaging or detection process. Magnetic Field Scheme (303): The core of the magnetic field scheme is to make positive and negative charges move in a curved path in the electromagnetic field. By carefully designing the direction, intensity, and distribution of the magnetic field, positive and negative charges can be guided to move with specific trajectories and velocities, thereby forming the required electromagnetic field distribution and intensity.This curvilinear motion not only enhances the complexity and diversity of the electromagnetic field, but also enables the electromagnetic field to more precisely meet specific imaging or detection needs. By adjusting the parameters of the magnetic field, we can achieve precise control of the electromagnetic field, thereby optimizing the imaging or detection effect. Housing type (304): Protects the internal structure of the electromagnetic field generator, while providing necessary heat dissipation and shielding functions. The material and structure of the housing should be selected according to the specific application scenario and requirements. Perforated lampshade (305): Used to adjust the diffusion and focusing of the electron beam, affecting the shape and range of the electromagnetic field. By changing the aperture and shape of the lampshade, precise control of the shape of the electromagnetic field can be achieved. Horizontal deflection coil (3061-3064): Achieves precise control of the electromagnetic field in the horizontal and vertical directions by changing the trajectory of the electron beam. The design of the horizontal deflection coil should meet specific imaging or detection needs to ensure the stability and accuracy of the electromagnetic field. Object or space (4): As the object being monitored or imaged, its position, shape, material and other characteristics will change under the action of the changing electromagnetic field. These changes will be captured by the system and used for subsequent analysis and imaging. The object or space can be different types of substances such as solid, liquid, and gas. Sensing component type (5): Used to receive and convert signals from the object or space. These signals reflect changes in the object or space under the influence of an electromagnetic field. The sensing component can be different types of devices such as sensors and detectors; its selection should be based on the specific application scenario and requirements. Signal processing circuit (6): Further processes and converts the signals output by the sensing component. The signal processing circuit includes signal amplification circuits, analog-to-digital signal conversion circuits, and communication circuits. Through the signal processing circuit, weak analog signals can be converted into digital signals and transmitted to computers and servers for subsequent data processing and analysis. Heat dissipation system (7): Responsible for heat dissipation of the chip and the electromagnetic field generator. The best embodiment of the present invention
[0036] The technical solutions in the embodiments of the present invention will be clearly and comprehensively described below with reference to the accompanying illustrations. It should be understood that the presented embodiments are only a part of the many possible implementations of the present invention, and not an exhaustive list of all examples. Any other implementations that can be deduced by those skilled in the art based on the embodiments disclosed in this invention without creative effort should be considered to fall within the protection scope claimed by this invention.
[0037] Example: This example relates to an artificial field imaging technology. This technology, through a series of carefully designed components and processes, realizes a complete process from signal processing to gravitational field conversion, and then to the monitoring and signal reception of objects and space. The following is a detailed description of each part of this technology, referring to the schematic diagrams, circuit diagrams, type classifications, and mind maps shown in Figures 1 to 12. As shown in Figure 1, the core components of this technology system and their functions are as follows: Signal Processing and Triggering Module 1: This module is responsible for receiving external input signals, performing necessary preprocessing, and triggering subsequent processes. It ensures that the entire system can respond accurately and promptly to external commands or events. Electromagnetic Field Generation Module 2: Based on the output of the signal and triggering modules, it generates a corresponding electromagnetic field and is equipped with a vacuum or gas system to support the electromagnetic field generator. This module is the core of the artificial field imaging technology, laying the foundation for the conversion of electromagnetic fields into gravitational fields. Changing Electromagnetic Field to Gravitational Field Module 3: This module utilizes physical principles to convert changes in the electromagnetic field into a gravitational field. This conversion process is the core innovation of this technology, enabling the system to use gravitational fields to influence or monitor objects and space. Object and Space Monitoring Module 4: This section is responsible for placing or containing the object to be monitored and covering its surrounding space environment. Under the influence of a gravitational field, certain characteristics of the object or space environment (such as position, shape, density, etc.) may change. These changes are subsequently captured by the system and used for subsequent analysis. Receiver Type Module 5: This module provides various types of receivers for receiving signals fed back by the object and space monitoring object. These receivers can selectively receive and process signals according to different application scenarios and needs. Signal Processing and Conversion Module 6: Finally, this module is responsible for receiving signals from the receiver type module, performing further processing and conversion to obtain the final imaging results or monitoring data. Heat Dissipation System 7: Responsible for cooling the chip and electromagnetic field generator. By integrating the above seven parts, the artificial field imaging technology of this embodiment realizes a complete process from signal processing to gravitational field conversion, and then to monitoring and receiving signals from objects and space. This technology not only has high flexibility and scalability but can also adapt to a variety of complex application scenarios and needs. Meanwhile, by referring to the detailed schematic diagrams, circuit diagrams, type classifications, and mind maps shown in Figures 1 to 12, we can gain a deeper understanding of the working principle and implementation method of this technology. Embodiments of the present invention
[0038] Specifically, it should be noted that the power supply circuit, signal circuit, drive circuit, and input voltage rectification circuit are all constructed based on existing technologies. The operating principles of these components also follow the framework of existing technologies; therefore, their operating principles will not be described in detail here to avoid redundancy. In use, the computer first generates and outputs digital signals. These digital signals then pass through an amplifier circuit, which amplifies the signal amplitude sufficiently to drive subsequent circuits. The amplified signal enters the drive circuit, which is powered by the power supply circuit. The drive circuit not only receives the amplified digital signals but also converts them into a form suitable for the boost circuit input. The boost circuit further adjusts the voltage or current level of the signal to meet the input energy requirements of the electromagnetic field generator. At the output of the boost circuit, the signal may need to be rectified to ensure its stability and reliability. The rectified signal enters a capacitor bank, which acts as a smoothing and energy storage unit, providing a stable and continuous power supply to the electromagnetic field generator. An electromagnetic field generator is a key component that converts input electrical energy into a changing electromagnetic field, and further into a gravitational field. When this gravitational field strikes an object or space, it produces specific physical effects. To detect and record these effects, a sensing component is also required. This component receives signals generated by the gravitational field and converts them into electrical signals. These electrical signals are then amplified by an amplification circuit to ensure accurate detection and recording. The amplified signals then enter a conversion circuit, which transforms them into a form suitable for computer processing. Finally, the processed signals are transmitted back to the computer, which uses artificial intelligence algorithms to detect and analyze these signals and stores the relevant data. Simultaneously, this data can be used by an imaging system to generate visual images or charts, helping users to more intuitively understand and analyze the physical effects of the gravitational field.
[0039] Specifically, in this embodiment, as shown in the circuit diagram of Figure 3, the computer and server 1 jointly undertake the tasks of signal processing, imaging system operation, and artificial intelligence detection. The signal undergoes a series of processing steps in circuit 2, including amplification and driving, before finally being transmitted to transformer 201 to output power matching the demand. It is worth noting that this power supply must be processed by a rectifier circuit before being supplied to the electromagnetic field generator 3. The core function of the rectifier circuit is to convert alternating current (AC) to direct current (DC), making it an indispensable part of the power supply circuit. Rectifier circuits are mainly divided into four types based on their design: half-wave rectifier circuits, full-wave rectifier circuits, bridge rectifier circuits, and voltage doubler rectifier circuits. These circuits convert AC into DC with unidirectional pulsating characteristics, providing stable DC energy for subsequent circuits. When the DC current passes through the capacitor bank, it is stored and released to the electromagnetic field generator 3 when needed. In this process, the capacitor bank not only serves as an energy storage unit but also ensures that the electromagnetic field generator 3 receives a stable and sufficient power supply. Furthermore, the filament 301 in the electromagnetic field generator 3 also requires power, which is provided by the isolation transformer 202 in circuit 2. The main function of the isolation transformer 202 is to achieve electrical isolation between the high-voltage and low-voltage circuits, effectively preventing leakage current in the high-voltage circuit from posing a potential threat to the low-voltage circuit, thereby ensuring the safe and stable operation of the entire system. In summary, the circuit design in this embodiment not only achieves accurate signal processing and stable power output, but also ensures that the electromagnetic field generator 3 can obtain a safe, stable, and efficient power supply through the application of rectifier circuits and isolation transformers.
[0040] Specifically, the step-up transformer 201 primarily provides alternating current (AC), while the electromagnetic field generator 3's specific design requires it to use direct current (DC) as its operating power. To meet this requirement, rectification is necessary, converting AC to DC. The rectification process utilizes electronic devices with unidirectional conductivity (such as diodes and rectifier bridges), which allow current to flow in only one direction, thus altering the directionality of the AC. When AC passes through these unidirectional conductive devices, its negative and positive half-cycles are cut off, retaining only the positive portion or, after appropriate processing, obtaining smooth DC. Specifically, AC waveforms are sinusoidal, constantly changing between positive and negative. Through rectification, we can remove the fluctuating portion of AC, retaining only its unidirectional flow to form DC. In this process, rectifier devices play a crucial role, selectively allowing or blocking current flow based on its direction, thereby achieving the conversion from AC to DC. Therefore, the AC provided by the step-up transformer 201, after rectification, can meet the DC requirements of the electromagnetic field generator 3, ensuring the normal operation and performance of the equipment.
[0041] Rectifier circuits are also divided into four types. The first type is half-wave rectification. Half-wave rectification utilizes the unidirectional conduction characteristic of diodes, allowing current to flow through the load only for half a cycle of the AC current, while the diode blocks the flow for the other half. Therefore, the output voltage is approximately half of the original voltage. The second type is full-wave rectification. Full-wave rectification utilizes both half-waves of the AC current for rectification, thereby improving rectification efficiency and making the output voltage smoother. Full-wave rectification circuits can be further divided into two types: 1. Transformer center-tapped full-wave rectification: This circuit requires a center tap on the secondary winding of the transformer to divide the AC voltage into positive and negative half-cycles. During the positive half-cycle, one diode conducts, and current flows through this diode to the load; during the negative half-cycle, the other diode conducts, and current also flows through this diode to the load. Therefore, current flows through the load in both the positive and negative half-cycles of the AC voltage. 2. Bridge full-wave rectification: This circuit consists of a rectifier bridge composed of four diodes, each diode responsible for rectifying one half-wave. When the positive half-cycle of a sinusoidal alternating current arrives, two diodes conduct while the other two are cut off; when the negative half-cycle arrives, the other two diodes conduct while the previously conducting diodes are cut off. In this way, the current flowing through the load always flows in the same direction, resulting in a smoother output voltage. The third type is the full-wave bridge rectifier. A full-wave bridge rectifier circuit is actually a special type of full-wave rectifier circuit that uses a rectifier bridge composed of four diodes to achieve full-wave rectification. The fourth type is the voltage doubler rectifier. A voltage doubler rectifier circuit is a special type of rectifier circuit that uses the rectification of diodes and the energy storage of capacitors to convert a lower AC voltage into a higher DC voltage.
[0042] Specifically, the electromagnetic field generator 3 is designed with five different internal structures to adapt to diverse application scenarios. These structures are shown in Figures 4 to 8, each meticulously designed to achieve a specific function. Circuit 2, as the core power supply component of the electromagnetic field generator, provides a stable and reliable power input. In the structure shown in Figure 4, the electromagnetic field generator is configured for precise point, line, and surface operations. Its unique design enables high precision and controllability during operation. The structures in Figures 5 and 7 focus more on surface operations. They optimize the distribution and intensity of the electromagnetic field to ensure the desired effect in surface operation scenarios. For applications requiring three-dimensional operation, the structures in Figures 6 and 8 provide a more comprehensive solution. These structures achieve precise control in three-dimensional space through carefully designed electromagnetic field distribution and charge movement trajectories. In the electromagnetic field generator 3, the filament 301 and the magnetic field 303 play crucial roles. The filament 301 is responsible for releasing negative charges (i.e., electrons), which are deflected under the influence of the magnetic field 303 and move along a curved trajectory. Simultaneously, the magnetic field 303 also acts on the positive charges on the anode, causing them to also undergo curvilinear motion. This design ensures the orderly and controllable movement of charges in the electromagnetic field. This design not only simplifies the structure of the anode 302 (eliminating the need for coils) but also improves the overall performance and efficiency of the electromagnetic field generator. Figure 9 shows various shapes of the anode 302, designed to meet the needs of various application scenarios. Correspondingly, Figure 10 shows the housing design of the electromagnetic field generator, which protects the internal structure from interference from the external environment. In the structures of Figures 4 and 5, the perforated lampshade 305 is used to control the amount of negative charge. In Figure 4, the perforated lampshade 305 achieves precise operation based on a single point by precisely controlling the release of negative charge. In Figure 5, the perforated lampshade 305 achieves precise control based on a surface by adjusting the distribution and intensity of negative charge. Furthermore, 3061, 3062, 3063, and 3064 in Figure 4 are horizontal deflection coils, which are used to control the relative motion coordinates of the negative charges. This design allows the electromagnetic field generator to adjust the trajectory of negative charges as needed, enabling more complex operations. The movement of positive and negative charges generates a changing electromagnetic field, which is further converted into a gravitational field, irradiating matter. This gravitational field has a wide range of influence, affecting the movement of all matter. Figure 11 shows various types of sensing components 5, including display coil induction and antenna mode induction. These sensing components can receive signals generated by the gravitational field and convert them into electrical signals for further processing. In addition, there are semiconductor and insulator type sensing components, which also operate based on the principle that gravitational fields can cause all matter to move. Finally, the signal 6 shown in Figure 3, after amplification and conversion, is communicated to computer 1 for further processing and analysis.Computer 1 uses artificial intelligence technology to detect and analyze the received signals and stores the relevant data in the server for later use and research.
[0043] Specifically, the vacuum-type equipment in electromagnetic field generator 3 relies on the vacuum system integrated in circuit 2 for support. This system includes key components such as a vacuum pump, vacuum pipes, and vacuum valves, which together form a complete vacuum environment. The gas-type equipment, on the other hand, is supported by the gas system integrated in circuit 2. This system consists of components such as a gas tank, a pressurization pump, pipes, valves, a gas flow meter, an intake pressure sensor, and a throttle body, and is responsible for providing and regulating the required gas medium.
[0044] Specifically, in the electromagnetic field generator 3, the positions of the filament 301 in the vacuum-type and gas-type electromagnetic field generators have both similarities and unique characteristics. Specifically: In the vacuum-type electromagnetic field generator, when the anode is designed as a single-sided structure, the filament 301 is typically located opposite the anode 302; if the anode 302 is constructed as a hollow cube, the filament 301 is placed at the geometric center of the anode 302. This layout aims to optimize charge emission and collection efficiency. In the gas-type electromagnetic field generator, the position of the filament 301 is relatively flexible. When the anode 302 is also a single-sided design, the position of the filament 301 is similar to that of the vacuum type, i.e., opposite the anode 302. However, when the anode 302 is a hollow cube, due to the influence of the density distribution after gas ionization, the position of the filament 301 can be more flexible. It can be placed at the geometric center of the anode 302 to ensure uniform charge distribution, or it can be placed on the other side of the anode 302 to adapt to specific ionization requirements and operating conditions. It is worth noting that, regardless of whether the electromagnetic field generator is vacuum-type or gas-type, the filament seal uses high-temperature and high-pressure resistant materials, such as glass, ceramic, or rubber. The selection of these materials not only helps maintain the stability of the vacuum or gas seal but also ensures that the filament seal will not leak or be damaged due to high temperature or pressure under prolonged, high-intensity electromagnetic field conditions. This design further enhances the stability and durability of the electromagnetic field generator.
[0045] Specifically, in a gas-type electromagnetic field generator, after the gas is ionized, positive charges (usually ions or positive ion clusters) are attracted and move towards the positive electrode (anode) under the influence of a strong electric field, while negative charges (mainly electrons) move towards the filament under the guidance of a relatively weak electric field. It's important to note that although the electric field distribution may vary, the movement of electrons is not directly driven by the "weak electric field," but rather determined by the overall electric field distribution and any potential space charge effects. Subsequently, when these moving positive and negative charges enter the region of magnetic field 303, they are subjected to the Lorentz force, causing their trajectories to bend, forming curvilinear motion. This curvilinear motion not only enhances the interaction between charges but also promotes the generation of the electromagnetic field. The electromagnetic field itself is a dynamically changing field, constantly changing with the movement of charges, and accordingly generating corresponding magnetic and electric field components. More importantly, according to the principles of relativity, a changing electromagnetic field is accompanied by a gravitational field, although this gravitational effect is usually ignored in conventional electromagnetic applications because it is much weaker than the electromagnetic force. However, under specific conditions (such as high-intensity, high-frequency electromagnetic field variations), this gravitational field can have observable effects on matter. Therefore, in a gas-type electromagnetic field generator, a dynamic electromagnetic field can be generated and maintained by ionizing the gas, guiding charge movement, applying a magnetic field, and using the Lorentz force to make charges move in curvilinear motion. This electromagnetic field not only has direct electromagnetic effects but may also generate a gravitational field through its variations, thereby irradiating or influencing surrounding matter.
[0046] Specifically, in the design of the electromagnetic field generator 3, the construction scheme of the magnetic field 303 covers various types, including using permanent magnets to generate a stable magnetic field, pulsed magnetic fields to achieve rapidly changing magnetic field effects, alternating magnetic fields to simulate periodically changing electromagnetic environments, and direct current magnetic fields to provide a continuous and stable magnetic force. These magnetic field types can all influence the trajectory of positive and negative charges, thereby generating corresponding electromagnetic field effects. When the power of the filament 301 in the electromagnetic field generator 3 is insufficient to support the conditions required for ionization, various methods can be used to supplement the ionization gas to ensure the continuous progress of the ionization process. Figures 7 and 8 show methods such as microwave excitation, Tesla coil discharge, high-voltage arc discharge, laser irradiation, and ultraviolet radiation. The selection of these methods aims to improve ionization efficiency while ensuring the safety and stability of the ionization process. When selecting the ionization gas, factors such as its ease of ionization, safety, corrosiveness to the anode, and compressibility must be considered. Therefore, inert gases are chosen due to their stable chemical properties and ease of ionization. These gases not only effectively support the ionization process but also reduce corrosion to the equipment and improve the overall reliability of the system. The monitoring system of Circuit 2 encompasses real-time monitoring of multiple key parameters, including but not limited to voltage, current, power, electric field strength, magnetic field strength, temperature, pressure, velocity, acceleration, radiation level, position coordinates, flow rate and velocity, displacement, and vibration and noise. Comprehensive monitoring of these parameters helps to promptly identify and address potential problems, ensuring the stable operation of the electromagnetic field generator 3. To improve the electric field strength in the electromagnetic field generator 3, various measures can be taken. For example, increasing the capacitor bank to store more electrical energy, increasing the power supply to increase input energy, and for gas-type electromagnetic field generators, improving ionization efficiency by increasing gas pressure or changing gas composition. Furthermore, increasing the number of turns in the transformer secondary coil and thickening the coil diameter can enhance the output capability of the electromagnetic field. The combined application of these methods can significantly improve the performance indicators of the electromagnetic field generator 3, meeting the needs of various application scenarios.
[0047] Specifically, the heat dissipation system plays a crucial role. It is specifically designed for the critical components of the system, such as the chip and the electromagnetic field generator, to ensure their heat dissipation requirements are met. In a preferred embodiment of the invention, the imaging system is meticulously equipped with an advanced heat dissipation system designed to ensure that the chip and electromagnetic field generator maintain stable performance output under continuous high-load operation. By efficiently removing the heat generated by these critical components during operation, the heat dissipation system effectively prevents overheating, thereby extending their service life and improving the overall reliability of the system. The heat dissipation components that may be used in this system include, but are not limited to, fans, radiators, heat pipes, thermoelectric coolers, and water cooling devices. These efficient heat dissipation components work together to rapidly dissipate the heat generated by the chip and electromagnetic field generator to the surrounding environment, ensuring that the system maintains excellent imaging quality and stable performance even under long-term, high-intensity operating conditions. Therefore, by introducing this meticulously designed heat dissipation system, the imaging system of the present invention not only significantly improves the stability and reliability of the system but also provides users with a more durable and efficient imaging experience, ensuring excellent performance in various application scenarios. Industrial applicability
[0048] The working principle of this technology is based on fundamental principles of physics: the movement of positive and negative charges generates a changing electromagnetic field, which can then be further transformed into a gravitational field. This transformation process strictly follows physical laws, with the gravitational field acting as the driving force, influencing the motion of matter. In unified field theory, the gravitational field, as the parent field, can further drive the sensing component to convert into electromagnetic signals. Figure 12 illustrates the mathematical expression of this principle in detail. Positive and negative charges move in space according to certain laws, and this movement leads to continuous changes in the electromagnetic field. According to fundamental theories of electromagnetism such as Maxwell's equations, the changing electromagnetic field produces changes in the magnetic field, which in turn forms the propagation of electromagnetic waves. However, in the specific context of this technology, we focus on how these changing electromagnetic fields are transformed into a gravitational field through some mechanism (such as those described by theories like spacetime curvature in general relativity). As a ubiquitous physical field, the gravitational field has the ability to attract and drive the motion of matter. In the application of this technology, by precisely controlling the movement of positive and negative charges, we can consciously generate and adjust the gravitational field, thereby achieving precise control over the motion of matter. It is important to emphasize that the proposal and verification of this working principle are based on a deep understanding and experimental verification of fundamental principles of physics. Although some transformation processes (such as the conversion from electromagnetic to gravitational fields) are not yet fully explained in existing physics theories, this technology, through practical exploration and theoretical innovation, has initially achieved this goal and is expected to drive the development of physics and related fields in the future. Furthermore, the principle formula in Figure 12 is not only a mathematical description of this working principle but also an important basis for technical design and experimental verification. By continuously optimizing and adjusting the parameters and variables in the formula, we can further improve the performance and reliability of the technology, providing strong support for a wider range of application scenarios. Sequence List Free Content
[0049] Finally, it must be emphasized that the above content is merely a preferred embodiment of the present invention and is not intended to limit the scope of the invention. Although the present invention has been described in detail based on the foregoing embodiments, those skilled in the art are fully capable of making necessary adjustments or equivalent substitutions to some technical features based on the technical solutions presented in the foregoing embodiments. Any modifications, equivalent substitutions, or optimizations implemented while adhering to the core concepts and basic principles of the present invention should be considered to fall within the protection scope of the present invention.
Claims
1. An artificial field imaging technology, characterized in that: This technology utilizes the movement of positive and negative charges to generate a changing electromagnetic field, and then converts this changing electromagnetic field into a gravitational field for imaging. The technology includes, but is not limited to, the following components and characteristics: an electromagnetic field generator: used to generate a changing electromagnetic field, its operating principle being based on the movement of positive and negative charges. This generator has a specific circuit design and principle, capable of generating an electromagnetic field of the desired frequency and intensity. Signal Receiving and Processing Circuit: This circuit includes a sensing component to receive electromagnetic signals generated by the electromagnetic field generator and convert them into processable electrical signals. The type and characteristics of the sensing component are matched to the characteristics of the electromagnetic field to ensure accurate signal reception and conversion. Signal Amplification and Driving Circuit: This circuit amplifies the signal received by the sensing component and drives the electromagnetic field generator to produce an electromagnetic field corresponding to the input signal. This step ensures accurate signal amplification and transmission, as well as stable electromagnetic field generation. Input Voltage Rectifier Circuit: This circuit provides a stable DC voltage to the electromagnetic field generator to ensure its normal operation. The type and characteristics of the rectifier circuit are selected based on the characteristics and requirements of the input voltage to achieve optimal rectification effect and efficiency. Electric Field Intensity Enhancement Methods: To increase the intensity of the electromagnetic field, this technology employs specific methods, such as increasing the charge amount and optimizing the electric field distribution. These methods are selected and combined according to actual needs to achieve the best electric field intensity enhancement effect. Magnetic Field Control Scheme: To control the trajectory of the charge, this technology designs a specific magnetic field control scheme. By adjusting the strength and direction of the magnetic field, the charge moves in a curved path within the electromagnetic field, thereby changing the distribution and characteristics of the electromagnetic field. Ionized gas power supplementation scheme: When ionized gas power is insufficient, this technology employs specific supplementation schemes, such as adding ionization sources and optimizing ionization conditions, to ensure a stable supply of ionized gas and power output. Vacuum system or gas system: The vacuum system provides vacuum for the vacuum-type electromagnetic field generator, while the gas system provides gas for the gas-type electromagnetic field generator. Multi-mode heat dissipation system: Water-cooled module: includes a coolant circulation pump, radiator, coolant pipes, and coolant storage tank, forming a closed-loop coolant circulation system to remove internal heat from the equipment through circulating coolant; Air-cooled module: includes at least one fan, heat dissipation fins, and optimized airflow design to improve airflow efficiency and further accelerate heat dissipation; Semiconductor cooling module: utilizes the thermoelectric effect to achieve rapid local cooling, suitable for precise temperature control of specific components; Intelligent control unit: has a built-in temperature sensor and processor, capable of dynamically adjusting the heat dissipation strategy according to a preset algorithm, including but not limited to switching heat dissipation modes and adjusting the operating frequency. The intelligent control unit automatically adjusts the operating status of at least one heat dissipation mode based on the real-time temperature of the equipment. Anode shape and filament position design: In an electromagnetic field generator, the shape of the anode and the position of the filament have a significant impact on the distribution and characteristics of the electromagnetic field. Therefore, this technology carefully designs the anode shape and filament position to achieve optimal electromagnetic field distribution and imaging effect. The above-mentioned parts and their characteristics are interconnected and work synergistically to constitute the artificial field imaging technology described in this invention.
2. The artificial field imaging technology according to claim 1, characterized in that: The technology describes the conversion characteristics from electromagnetic fields to gravitational fields. Specifically, when the polarity of an electromagnetic field changes, not only does the direction of the electromagnetic field reverse, but the direction of the resulting gravitational field also reverses accordingly. This conversion characteristic ensures a consistent polarity correspondence between the electromagnetic and gravitational fields. Regarding the relationship between charge motion and field state: by controlling the trajectory of charges in an electromagnetic field, particularly by making them move in curvilinear motion, an electromagnetic field with specific distribution and characteristics can be generated. Simultaneously, this specific electromagnetic field further transforms into a corresponding gravitational field state. Therefore, there is a direct correlation and correspondence between the state of charge motion and the resulting electromagnetic and gravitational field states. These features further enhance the artificial field imaging capabilities of this technology, enabling more precise control over the distribution and characteristics of electromagnetic and gravitational fields, thereby achieving higher-quality imaging results. These features not only enrich the content of this technology but also provide a solid foundation for its widespread application in practical applications.
3. The artificial field imaging technique of claim 1, wherein: The types and classification methods of electromagnetic field generators are as follows: By efficiency: Vacuum electromagnetic field generators: These generators operate in a vacuum environment and have high energy conversion efficiency and stable electromagnetic field output characteristics. Gas electromagnetic field generators: These generators operate in a gas environment and may generate electromagnetic fields through methods such as gas ionization. Their efficiency may be affected by factors such as gas state and degree of ionization. By structure: Vacuum-type point-line-surface operating structure electromagnetic field generators: This type of generator has three operating structures: point, line, and surface, capable of generating point, line, and surface electromagnetic fields respectively, suitable for imaging requirements of different precisions. Vacuum-type surface operating structure electromagnetic field generators: This type of generator focuses on generating surface electromagnetic fields, with a large operating area and uniform electromagnetic field distribution. Vacuum-type three-dimensional operating structure electromagnetic field generators: This type of generator can generate three-dimensional electromagnetic fields, suitable for imaging tasks of complex spatial structures. Gas-type surface divergence operating structure electromagnetic field generators: This type of generator operates in a gas environment and controls the distribution and intensity of the electromagnetic field by adjusting the divergence of the gas, suitable for applications requiring flexible adjustment of electromagnetic field characteristics. Gas-type stereo divergence manipulator electromagnetic field generator: This type of generator combines the characteristics of gas-type generators with the advantages of stereo divergence manipulation, enabling the generation of complex three-dimensional electromagnetic field distributions. It is suitable for high-precision and highly complex imaging tasks. The above classification not only covers the efficiency characteristics of electromagnetic field generators but also describes their structural features in detail, providing diverse options for the practical application of artificial field imaging technology. These features collectively constitute an important component of the electromagnetic field generator in this technology and provide a solid foundation for its application in the imaging field.
4. The artificial field imaging technique of claim 1, wherein: The gravitational field's ability to drive the motion of matter. The gravitational field generated by this technology has the ability to drive the motion of all matter. This means that under the influence of the gravitational field, both macroscopic objects and microscopic particles can undergo changes in position or state. This characteristic provides a broad scope for the application of artificial field imaging technology in the fields of matter manipulation and matter transport. Diversity of sensing components: The sensing components in this technology are diverse, including but not limited to various antennas, coils, conductors, insulators, and semiconductors. These different types of sensing components can selectively receive, convert, and transmit electromagnetic signals according to different application scenarios and needs, thereby achieving precise perception and control of electromagnetic and gravitational fields. The diversity of sensing components not only enhances the flexibility and adaptability of the technology but also ensures its stable operation in complex environments. The above features further reveal the unique properties of the gravitational field and the wide applicability of the sensing components in this technology, providing a solid theoretical foundation and technical support for the application of artificial field imaging technology in multiple fields. These features together constitute the core innovation of this technology and lay a solid foundation for its widespread promotion and in-depth development in practical applications.
5. The artificial field imaging technology according to claim 1, characterized in that: The process of digital signal processing and electromagnetic field generation is as follows: Digital signal processing and amplification: First, the digital signal to be processed is input into a power amplifier circuit. The power amplifier circuit amplifies the input digital signal to ensure that the signal has sufficient energy to drive subsequent circuit components. The amplified signal is then sent to the driver board. The driver board generates control signals: After receiving the amplified digital signal, the driver board generates corresponding control signals based on the specific content of the signal (such as frequency, amplitude, phase, etc.) through internal logic circuits or microprocessors. These control signals are the basis for the subsequent operation of the boost circuit, guiding how the boost circuit generates the corresponding electromagnetic field based on the input digital signal. Boost circuit outputs the electromagnetic field: Finally, after receiving the control signals from the driver board, the boost circuit boosts the input voltage according to the instructions of the control signals and outputs an electromagnetic field corresponding to the digital signal. This electromagnetic field is the key to artificial field imaging technology; it can achieve functions such as detection, manipulation, and imaging of the state or motion of matter through interaction with matter. The aforementioned features detail the entire process of digital signal processing and electromagnetic field generation in this technology. From the input, amplification, and processing of digital signals to the output of the electromagnetic field, each step has been meticulously designed and optimized to ensure the stability and accuracy of the technology. These features collectively constitute the core of this technology and provide strong support for its widespread application and in-depth development in practical applications.
6. The artificial field imaging technology according to claim 1, characterized in that: The rectifier circuit configuration and its function are described below. Definition and function of the rectifier circuit: This technology integrates a rectifier circuit whose main function is to convert alternating current (AC) into direct current (DC). Through a specific circuit structure, the rectifier circuit effectively separates the positive and negative half-cycles of the AC waveform, thereby outputting unidirectional pulsating DC. Types of rectifier circuits: In this technology, the specific implementation forms of the rectifier circuit mainly include four types: half-wave rectifier circuit, full-wave rectifier circuit, bridge rectifier circuit, and voltage doubler rectifier circuit. Half-wave rectifier circuit: Only one half-cycle of the AC is used for rectification, and the output is half-wave DC. Full-wave rectifier circuit: Both half-cycles of the AC are used for rectification, but this requires a center-tapped transformer or a dual-diode configuration, and the output is full-wave DC. Bridge rectifier circuit: Using a bridge structure composed of four diodes, full-wave rectification can be achieved without a center-tapped transformer, and the output is also full-wave DC, with higher efficiency. Voltage multiplier rectifier circuit: By connecting multiple diodes and capacitors in series, the output voltage is multiplied, making it suitable for applications requiring higher DC voltage output. The role of rectifier circuits in artificial field imaging technology: The stable DC power supply provided by rectifier circuits is crucial for driving various electronic components and maintaining stable electromagnetic field generation in artificial field imaging technology. By precisely controlling the output of the rectifier circuit, it is possible to ensure that parameters such as the intensity and frequency of the electromagnetic field meet imaging requirements, thereby improving imaging accuracy and stability. The above characteristics detail the configuration, types, and key roles of rectifier circuits in artificial field imaging technology, providing the necessary theoretical foundation and technical support for the practical application of the technology.
7. The artificial field imaging technology according to claim 1, characterized in that: Several strategies are described below to enhance the electric field strength of an electromagnetic field generator. Capacitor bank enhancement: This technique involves adding a capacitor bank to the circuit of the electromagnetic field generator. Utilizing the energy storage and discharge characteristics of capacitors, a larger current can be provided in a short time, thereby enhancing the electric field strength. The configuration of the capacitor bank needs to be rationally designed according to the specific parameters of the electromagnetic field generator and application requirements to ensure that the system's stability and safety are maintained while increasing the electric field strength. Power supply enhancement: Increasing the power supply connected to the electromagnetic field generator is another direct method to enhance the electric field strength. By increasing the output voltage or current of the power supply, more energy can be provided to the electromagnetic field generator, thus generating a stronger electromagnetic field. However, increasing the power supply power requires simultaneous consideration of the electromagnetic field generator's capacity and the system's heat dissipation to avoid equipment damage or overheating. Gas-type electromagnetic field generator optimization: For gas-type electromagnetic field generators, by increasing the type, concentration, or pressure of the working gas, the degree of ionization and collision frequency of gas molecules can be changed, thereby enhancing the electric field strength. Furthermore, optimizing the structural design of gas-type electromagnetic field generators, such as increasing the area of the discharge electrodes or improving the gas flow state, also helps to improve the electric field strength. Transformer secondary coil optimization: In the power supply circuit of an electromagnetic field generator, the number of turns and diameter of the transformer secondary coil are important factors affecting the electric field strength. By increasing the number of turns in the secondary coil, the output voltage can be increased, thereby enhancing the electric field strength. Simultaneously, increasing the diameter of the secondary coil can reduce the coil resistance, reduce energy loss, and improve the stability of the electric field strength. However, increasing the number of turns and increasing the diameter need to be reasonably adjusted according to the overall design of the transformer and the actual needs of the electromagnetic field generator to avoid excessive size and weight. The above features describe in detail various strategies for improving the electric field strength of electromagnetic field generators. These methods can be selected and combined according to specific needs and conditions in practical applications to achieve the best imaging effect and performance. These features together constitute the core innovation of this technology regarding improving the electric field strength of electromagnetic field generators.
8. The artificial field imaging technology according to claim 1, characterized in that: The method employs various magnetic field types to control the direction of charge movement. The methods include:
1. Static magnetic field generation using permanent magnets: This technique utilizes a static magnetic field generated by permanent magnets to guide the direction of the charge. The configuration and strength of the permanent magnet poles can be precisely adjusted according to the charge's movement path and imaging requirements, allowing the charge to move along a predetermined trajectory within the magnetic field, thereby enhancing or altering the imaging effect.
2. Dynamic control using pulsed magnetic fields: Pulsed magnetic fields generate an instantaneous Lorentz force on the charge through rapidly changing magnetic field strength, thus changing its direction of movement. Parameters such as the frequency, amplitude, and duration of the pulsed magnetic field can be flexibly set according to the characteristics of the charge and imaging requirements to achieve precise control of the charge's direction of movement.
3. Periodic control using alternating current magnetic fields: Alternating current magnetic fields, with their periodic variation, generate a periodic Lorentz force on the charge, thereby achieving periodic control of the charge's direction of movement. By adjusting the frequency and amplitude of the alternating current magnetic field, the trajectory of the charge within the magnetic field can be precisely controlled, further affecting the resolution and sharpness of the image.
4. Stable control using direct current magnetic fields: Direct current magnetic fields, with their stable magnetic field strength, provide a constant Lorentz force to the charge, thereby achieving stable control of the charge's direction of movement. The strength and direction of the DC magnetic field can be precisely adjusted according to imaging requirements to ensure that charges move stably along a predetermined trajectory within the magnetic field, thereby improving the stability and accuracy of imaging. The above features describe in detail the specific methods for controlling the direction of charge movement using different types of magnetic fields. In practical applications, these methods can be selected and combined according to specific imaging needs and charge characteristics to achieve optimal imaging effects and performance. These features collectively constitute the core innovation of this technology regarding the use of magnetic fields to change the direction of charge movement.
9. The artificial field imaging technology according to claim 1, characterized in that: When the filament power of the electromagnetic field generator cannot meet the energy requirements for ionizing the gas, the following methods are used to supplement the ionized gas, emphasizing that the choice of gas type must be based on a comprehensive consideration of safety and efficiency. Microwave ionization supplementation method: Utilizing the high-frequency vibration characteristics of microwaves, electron transitions are excited within gas molecules, thereby achieving ionization. Microwave ionization has advantages such as high energy conversion efficiency and uniform ionization, but safety precautions against microwave radiation must be taken. Tesla coil ionization supplementation method: The high-frequency, high-voltage electric field generated by a Tesla coil ionizes gas molecules under the influence of the electric field. Tesla coil ionization has advantages such as fast ionization speed and high degree of ionization, but electrical safety must be ensured during operation. High-voltage arc ionization supplementation method: The high temperature and strong electric field generated by high-voltage arc discharge ionize gas molecules. High-voltage arc ionization has advantages such as significant ionization effect and simple equipment, but safety risks and energy loss during arc discharge must be considered. Laser ionization supplementation method: The high energy density of lasers is used to directly act on gas molecules, causing them to ionize. Laser ionization offers advantages such as high ionization accuracy and strong controllability, but the cost and operational complexity of laser equipment must be considered. Ultraviolet (UV) ionization supplementation, on the other hand, achieves ionization by exciting electron transitions within gas molecules through UV radiation. UV ionization is simple to operate and easy to implement, but the impact of UV radiation on humans and the environment must be considered. Regarding gas selection, this technology prioritizes gas safety, ensuring that the gas does not harm humans or the environment during ionization. Simultaneously, factors such as ionization efficiency, stability, and cost must be comprehensively considered to select the most suitable gas type. The above features detail various methods for supplementing ionized gas in electromagnetic field generators when filament power is insufficient, as well as the principles for gas type selection. These methods can be selected and combined in practical applications based on specific imaging requirements and equipment conditions to achieve optimal imaging effects and performance. These features collectively constitute the core innovations of this technology regarding electromagnetic field generator ionization gas supplementation methods and gas type selection.
10. The artificial field imaging technology according to claim 1, characterized in that: The anode design and related component configuration of the electromagnetic field generator are as follows: Single-sided anode design: When the anode of the electromagnetic field generator is designed as single-sided, this single-sided anode can be of any shape to adapt to different imaging requirements and equipment structures. In this case, the filament is positioned on the other side of the anode, opposite to the single-sided anode, to ensure that the electrons emitted by the filament can effectively bombard the anode surface to generate the required electromagnetic field. Vacuum-type housing material: When the electromagnetic field generator is used in a vacuum environment, its housing must be made of high-temperature resistant glass or ceramic materials. These materials can withstand the thermal stress under high-temperature conditions, ensuring stable operation of the equipment. Simultaneously, the glass or ceramic housing also has good sealing performance, preventing external air or impurities from entering the vacuum cavity and affecting the imaging effect. Gas-type housing material: When the electromagnetic field generator is used in a gaseous environment, its housing must also be made of high-temperature and high-pressure resistant glass or ceramic materials. These materials can not only withstand the thermal stress under high-temperature conditions but also maintain structural stability under high-pressure conditions, preventing gas leakage or pressure imbalance. Furthermore, the high-temperature and high-pressure resistant housing can effectively isolate the high-voltage electric field inside the electromagnetic field generator, ensuring the safety of the operator. Hollow Cube Anode Design: When the anode of the electromagnetic field generator is designed as a hollow cube, this cube anode can also be of any shape to adapt to different application scenarios. In a vacuum, the filament is positioned at the center of the particle of the cube anode, i.e., at the intersection of the cube's diagonals, to ensure that electrons bombard the anode surface uniformly, generating a uniform electromagnetic field. In a gas discharge environment, given the various properties of the gas and their significant influence on the discharge process, the filament position can be designed with considerable flexibility. Specifically, depending on the specific application requirements and the characteristics of gas discharge, the filament can be cleverly positioned either at the exact center of the anode or adjusted to the opposite side of the anode. The logic behind this design is as follows: Centering the anode: Placing the filament at the center of the anode ensures that electrons emitted from the filament are evenly and effectively distributed throughout the electric field region, thus contributing to a stable and uniform discharge effect. This configuration is particularly suitable for applications requiring high discharge stability and uniformity. Opposite side of the anode: Under certain specific application conditions, adjusting the filament to the opposite side of the anode may be more appropriate. For example, when it is necessary to guide the electron flow in a specific direction, or to optimize discharge efficiency and performance, this positional adjustment provides additional flexibility and adaptability. Anode material: Regardless of whether the electromagnetic field generator is used in a vacuum or gas environment, its anode must be made of a high-temperature and high-pressure resistant conductive material. These materials can withstand the heat and electric field forces generated by electron bombardment, ensuring stable operation of the anode. Simultaneously, the high-temperature and high-pressure resistant conductive material also maintains good conductivity, ensuring the stable generation and transmission of the electromagnetic field. The above features describe in detail the specific design of the anode structure, filament position, and housing material of the electromagnetic field generator. These designs can be selected and adjusted according to specific imaging requirements and equipment conditions in practical applications to achieve the best imaging effect and performance. These features together constitute the core innovation of this technology in the design of electromagnetic field generators.
11. The artificial field imaging technology according to claim 1, characterized in that: The technology comprises two independent support systems to accommodate different types of electromagnetic field generators: a vacuum support system, specifically designed to provide and maintain the required vacuum level for vacuum-type electromagnetic field generators, ensuring stable operation in low-pressure or pressureless environments; and a gas support system, specifically configured for gas-type electromagnetic field generators, responsible for providing and precisely controlling the required gas environment, including gas type, flow rate, pressure, and other parameters, to meet the operational requirements of gas-type electromagnetic field generators. Within this technical framework, the vacuum support system and the gas support system, as two independent components, are selected and activated according to the specific type of electromagnetic field generator (vacuum-type or gas-type) to ensure that artificial field imaging technology can be implemented under the most suitable operating conditions.
12. The artificial field imaging technology according to claim 1, characterized in that: The system employs a highly adjustable and monitorable power supply system. This system is precisely matched with the driver board, transformer, and electromagnetic field generator to ensure a stable and controllable energy supply during the imaging process. Specific features include: Adjustable Power Supply System: The power supply system is adjustable, capable of adjusting the output voltage and current according to the specific needs of the electromagnetic field generator to adapt to the different energy requirements of different imaging tasks. This adjustability ensures precise energy control during imaging, contributing to improved image quality and stability. Power Monitoring System: The power supply system has a built-in monitoring module that can monitor key parameters such as output voltage, current, and power in real time, ensuring the power supply system operates within safe limits. Upon detecting an anomaly, the monitoring system will immediately take measures, such as cutting off the power supply or issuing an alarm, to protect equipment and personnel safety. Matching with Driver Board, Transformer, and Electromagnetic Field Generator: The power supply system is carefully designed to ensure complete electrical parameter matching with the driver board, transformer, and electromagnetic field generator. This matching relationship not only improves energy transmission efficiency but also reduces energy loss and electromagnetic interference, ensuring the overall performance and stability of the imaging system. Isolation of the filament power supply circuit: Considering that the filament power supply circuit needs to withstand high voltage and current, an isolation high-voltage transformer was specially designed to protect the circuit and personnel safety. This transformer isolates the filament power supply circuit from the main power supply system, effectively preventing current leakage and short-circuit risks, and ensuring stable filament operation. The above features describe in detail the configuration of the power supply system and its matching relationship with key components. These features together constitute the core innovation of the power supply system design in this technology. In practical applications, these designs ensure a stable, controllable, and safe energy supply during the imaging process, providing a strong guarantee for high-quality artificial field imaging.
13. The artificial field imaging technology according to claim 1, characterized in that: The monitoring system can monitor and record the following key parameters in real time to ensure precise control of the imaging process and stable operation of the equipment: Electrical parameters: including voltage, current, and power. These parameters directly reflect the operating status and energy output of the electromagnetic field generator, and are crucial for ensuring imaging quality and equipment safety. Electromagnetic field parameters: electric field strength and magnetic field strength are key indicators for evaluating the performance of the electromagnetic field generator. Real-time monitoring of these parameters allows for accurate understanding of the distribution and intensity of the electromagnetic field, providing a basis for optimizing imaging effects. Physical environment parameters: environmental parameters such as temperature and pressure have a significant impact on the imaging process. Monitoring these parameters allows for timely detection and adjustment of the equipment's operating environment, ensuring the stability and accuracy of the imaging process. Motion parameters: motion parameters such as velocity and acceleration reflect the motion state of objects during imaging, and are important for applications such as dynamic imaging and trajectory tracking. Radiation parameters: parameters such as radiation intensity and frequency are crucial for evaluating the radiation safety and compliance of the electromagnetic field generator. Real-time monitoring of these parameters ensures that the equipment will not cause harm to personnel or the surrounding environment during use. Position and flow parameters: Parameters such as coordinates, flow rate and velocity, and displacement provide information on the position and flow of an object during the imaging process, which has wide application value in fields such as spatial imaging and fluid analysis. Vibration and noise parameters: Vibration and noise are common physical phenomena during equipment operation. By monitoring these parameters, equipment faults or anomalies can be detected in a timely manner, ensuring stable equipment operation and imaging quality. The above features describe in detail the monitoring items covered by this technology. These items together constitute comprehensive monitoring of the imaging process and equipment status, providing strong support for optimizing imaging effects and ensuring safe and stable equipment operation. In practical applications, these monitoring items can be selected and combined according to specific imaging needs and equipment conditions to achieve the best monitoring effect.
14. The artificial field imaging technology according to claim 1, characterized in that: The multi-mode heat dissipation system includes a water-cooling module (comprising a coolant circulation pump, radiator, coolant pipes, and coolant storage tank, forming a closed-loop coolant circulation system), an air-cooling module (comprising at least one fan, heat dissipation fins, and an optimized airflow design to improve airflow efficiency), a semiconductor refrigeration module (utilizing the thermoelectric effect to achieve rapid local cooling, suitable for precise temperature control of specific components), and an intelligent control unit (built with a temperature sensor and processor, capable of dynamically adjusting heat dissipation strategies, including heat dissipation mode switching and operating frequency adjustment, according to a preset algorithm). The intelligent control unit automatically adjusts the operating status of at least one heat dissipation mode based on the real-time temperature of the device.
15. An artificial field imaging technique according to claim 1, characterized in that: The analog signal processing and conversion system described in this technology possesses the following optimized characteristics: Analog signal amplification circuit: This circuit can be flexibly configured according to actual needs. It can be a single-transistor amplification circuit to achieve basic signal amplification, or a multi-transistor amplification circuit to improve signal gain and stability through multi-stage amplification. This design allows the amplification circuit to adapt to imaging requirements with different signal strengths and noise levels, ensuring signal quality during transmission and processing. Optimized analog-to-digital signal conversion: In the process of converting analog signals to digital signals, this technology particularly emphasizes the optimization of the sampling process, quantization process, encoding process, and circuit design. Specifically, the sampling process employs high-precision sampling technology to ensure signal integrity and accuracy; the quantization process reduces information loss during signal conversion through fine quantization level division; and the encoding process uses efficient encoding algorithms to improve the compression rate and transmission efficiency of digital signals. Simultaneously, the circuit design uses low-power, highly integrated components to ensure the stability and reliability of the conversion system. The above features describe in detail the optimization measures of this technology in analog signal processing and conversion. These measures collectively constitute an important guarantee for signal quality during imaging. In practical applications, these optimized features can significantly improve the resolution, sharpness, and stability of imaging, providing strong support for the application of artificial field imaging technology. At the same time, these optimization measures also demonstrate the innovation and advancement of this technology in the field of signal processing and conversion.
16. The artificial field imaging technology according to claim 1, characterized in that: The imaging system innovatively integrates artificial intelligence (AI) technology, enabling in-depth analysis and optimization of imaging data. Specific features are as follows: AI Integration: This imaging system not only possesses traditional imaging functions but also integrates advanced AI algorithms and models. These algorithms and models can automatically receive, process, and analyze data acquired by the imaging system, achieving intelligent interpretation and efficient utilization of the data. Imaging Data Optimization and Analysis: Through AI technology, the imaging system can perform in-depth mining and analysis of the acquired image data. This includes extracting image features, assessing image quality, and identifying potential information within the image. Through these analyses, the system can automatically optimize imaging parameters, improve image clarity and resolution, while reducing noise and artifact interference, ensuring the accuracy and reliability of imaging results. Intelligent Decision Support: Combined with AI technology, the imaging system can also provide intelligent decision support for users. Through the analysis of imaging data, the system can automatically identify and classify target objects, providing information about the object's properties, location, and motion state. This information can provide important references and basis for users in scientific research, medical treatment, industrial inspection, and other fields. The above features describe in detail the specific methods and advantages of combining the imaging system with AI in this technology. By introducing artificial intelligence technology, the imaging system achieves in-depth analysis and optimization of imaging data, which not only improves image quality but also provides users with a more intelligent and convenient imaging experience. These features together constitute the important innovations of this technology in the field of imaging, providing new ideas and directions for the development and application of artificial field imaging technology.