Forwarded from Azazel News (Aries)
Scalar Interferometer Part 2
Material based on T. Bearden, Fer de Lance
Understanding the basics of electromagnetism
#SCALARELECTRODYNAMICS101
#SCALARELECTROMAGNETICS101
#SCALARELECTRODYNAMICS101
#SCALARELECTROMAGNETICS101
#scalarelectromagneticwarfare #scalarelectromagneticfield
#scalarelectromagneticwaves
#scalarelectrodynamics
#scalarelectromagneticweapons
CREATING AN INERTIAL FIELD (ANTIGRAVITY)
Material based on T. Bearden, Fer de Lance
Understanding the basics of electromagnetism
#SCALARELECTRODYNAMICS101
#SCALARELECTROMAGNETICS101
#SCALARELECTRODYNAMICS101
#SCALARELECTROMAGNETICS101
#scalarelectromagneticwarfare #scalarelectromagneticfield
#scalarelectromagneticwaves
#scalarelectrodynamics
#scalarelectromagneticweapons
CREATING AN INERTIAL FIELD (ANTIGRAVITY)
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Zero vectors:
Imagine you're playing with a bunch of arrows, each pointing in different directions. In math, if you add up all these arrows and they perfectly balance out to point nowhere (resulting in what's called a "zero vector"), math says, "Okay, there's nothing here." It's as if all these arrows cancel each other out, leaving an empty space.
But when we move from the neat world of math into the messy reality of physics, these "nothing here" situations are actually quite something. Imagine that balancing these arrows doesn't really make them disappear but rather creates a tension or stress in the space where they are. It's like stretching a rubber band – you can't see the stress, but you feel it. This tension is what we call "internal stress" in a zero vector, and it's a real, physical thing, not just a mathematical abstraction.
Imagine you're playing with a bunch of arrows, each pointing in different directions. In math, if you add up all these arrows and they perfectly balance out to point nowhere (resulting in what's called a "zero vector"), math says, "Okay, there's nothing here." It's as if all these arrows cancel each other out, leaving an empty space.
But when we move from the neat world of math into the messy reality of physics, these "nothing here" situations are actually quite something. Imagine that balancing these arrows doesn't really make them disappear but rather creates a tension or stress in the space where they are. It's like stretching a rubber band – you can't see the stress, but you feel it. This tension is what we call "internal stress" in a zero vector, and it's a real, physical thing, not just a mathematical abstraction.
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In the real world of physics, especially when we talk about electromagnetic forces, this balancing act can create stress or tension in the medium around them, like in the vacuum of space. This means that even though mathematically it looks like everything cancels out to zero, physically, there's a lot going on under the surface. There's a kind of hidden pattern of stress that's unique in every situation.
To really understand what's happening, we need to tweak the rules of math a bit:
1. Consider the potential energy hidden in these balanced situations.
2. Look at the specific pattern and arrangement of forces that cause this balance.
3. Think about how these patterns change over time and how they're arranged.
4. Recognize that the timing of these changes matters, affecting how we perceive time in these situations.
5. Understand that even individual forces can have their own complex inner structures based on these principles.
To really understand what's happening, we need to tweak the rules of math a bit:
1. Consider the potential energy hidden in these balanced situations.
2. Look at the specific pattern and arrangement of forces that cause this balance.
3. Think about how these patterns change over time and how they're arranged.
4. Recognize that the timing of these changes matters, affecting how we perceive time in these situations.
5. Understand that even individual forces can have their own complex inner structures based on these principles.
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This gets us into a whole new level of complexity, like a Russian doll situation with vectors within vectors, going on forever. For practical applications, especially when dealing with electromagnetic and gravitational forces, we're talking about needing at least five dimensions to make sense of it all – the three dimensions of space we live in, plus time, and another dimension to account for these complex interactions.
In essence, when we talk about zero vector summations in physics, we're not talking about nothing. We're talking about a hidden world of tension and potential energy that could have huge implications for understanding the universe, including how electromagnetic forces and gravity interact. This could unlock new ways to think about energy and perhaps even new technologies.
In essence, when we talk about zero vector summations in physics, we're not talking about nothing. We're talking about a hidden world of tension and potential energy that could have huge implications for understanding the universe, including how electromagnetic forces and gravity interact. This could unlock new ways to think about energy and perhaps even new technologies.
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A POTENTIAL IS A CHANGE IN THE STRESS OF VACUUM.
Imagine the vacuum of space not as empty, but as a bubbling, energetic soup filled with tiny, invisible particles that appear and vanish in the blink of an eye. This chaotic activity is what we might call "unzipped" energy, invisible and scattered.
Now, picture a spinning particle, like an electron, acting as a "zipper." When it spins, it pulls some of this wild energy together, making it "zipped" and thus observable to us. Essentially, what we can see and measure as energy in the universe comes from this process of zipping together the vacuum's hidden, frantic energy on particles with mass.
Imagine the vacuum of space not as empty, but as a bubbling, energetic soup filled with tiny, invisible particles that appear and vanish in the blink of an eye. This chaotic activity is what we might call "unzipped" energy, invisible and scattered.
Now, picture a spinning particle, like an electron, acting as a "zipper." When it spins, it pulls some of this wild energy together, making it "zipped" and thus observable to us. Essentially, what we can see and measure as energy in the universe comes from this process of zipping together the vacuum's hidden, frantic energy on particles with mass.
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This energetic soup is under constant "stress," behaving much like a highly active gas or plasma. It's this stressed state of the vacuum that forms the fabric of spacetime, a modern take on the old concept of the "ether." In this view, spacetime itself is a dynamic, fluctuating entity, filled with energy fluxes.
When we talk about flat or "uncurved" spacetime, we mean this energetic stress is consistent everywhere. In curved spacetime, however, the stress varies, leading to the curving of spacetime, which affects objects and light, akin to gravity's effects in Einstein's theory of General Relativity.
The idea extends to five dimensions in advanced theories, like Kaluza's, offering a more comprehensive understanding of how gravity and electromagnetism might emerge from this energetic, stressed vacuum of spacetime.
When we talk about flat or "uncurved" spacetime, we mean this energetic stress is consistent everywhere. In curved spacetime, however, the stress varies, leading to the curving of spacetime, which affects objects and light, akin to gravity's effects in Einstein's theory of General Relativity.
The idea extends to five dimensions in advanced theories, like Kaluza's, offering a more comprehensive understanding of how gravity and electromagnetism might emerge from this energetic, stressed vacuum of spacetime.
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A POTENTIAL EXTENDS TO INFINITY AND INVOLVES THE ENTIRE UNIVERSE.
We may consider the vacuum to be made of an infinite number of virtual state layers or levels.
The basic "speed" of the first layer is c, the speed of light.
The basic "speed" of the second layer is c2.
And so on.
This is interesting. We may directly engineer the virtual state by means of the vector zero (scalar electromagnetics) approach. By nesting vector zeros inside other vector zeros, we may directly engineer the deeper layers of virtual state, and consequently hyperdimensions.
Scalar electromagnetics thus is virtual state engineering and hyperspatial engineering at one and the same time.
Superluminal communications systems, hyperspace drive, and materialization and dematerialization are all hypothetically possible, using scalar electromagnetics. As the technology develops, we should see the development of many of the systems long thought impossible except in science fiction.
We may consider the vacuum to be made of an infinite number of virtual state layers or levels.
The basic "speed" of the first layer is c, the speed of light.
The basic "speed" of the second layer is c2.
And so on.
This is interesting. We may directly engineer the virtual state by means of the vector zero (scalar electromagnetics) approach. By nesting vector zeros inside other vector zeros, we may directly engineer the deeper layers of virtual state, and consequently hyperdimensions.
Scalar electromagnetics thus is virtual state engineering and hyperspatial engineering at one and the same time.
Superluminal communications systems, hyperspace drive, and materialization and dematerialization are all hypothetically possible, using scalar electromagnetics. As the technology develops, we should see the development of many of the systems long thought impossible except in science fiction.
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AN ARTIFICIAL POTENTIAL.
An artificial potential by definition has a substructure composed of deterministic observable vector components, summed to an overall zero vector. Coherence as a function of distance can be maintained over enormous macroscopic distances -- even hundreds of thousand of kilometers -- by simultaneous transmission of the entire cluster of substructure components as a coherent "zero" group.
An artificial potential by definition has a substructure composed of deterministic observable vector components, summed to an overall zero vector. Coherence as a function of distance can be maintained over enormous macroscopic distances -- even hundreds of thousand of kilometers -- by simultaneous transmission of the entire cluster of substructure components as a coherent "zero" group.
An artificial potential is essentially a carefully arranged pattern of stress in the fabric of space and time, crafted by using opposing electric (E-fields) and magnetic fields (B-fields) in such a way that their combined effect cancels out, creating a pattern where the sum of these forces equals zero.
To an observer from the outside, this setup appears to have no electromagnetic (EM) force field because the electric and magnetic components balance each other perfectly. Despite this, the individual components of the electric and magnetic fields are still present and active; they're just arranged to always cancel out.
To an observer from the outside, this setup appears to have no electromagnetic (EM) force field because the electric and magnetic components balance each other perfectly. Despite this, the individual components of the electric and magnetic fields are still present and active; they're just arranged to always cancel out.
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The simplest way to change this setup is to adjust the strength of all the fields together, keeping their balance so the overall effect still equals zero. This action creates what's known as an "EM wave." Yet, because the sum of these fields still appears as zero to an outside observer, what's actually being observed is a wave of pure, structured spacetime stress. This structured stress wave is called a scalar EM wave, or an electrogravitational wave, behaving like an alternating pattern of this structured stress.
Altering the stress in a localized area of spacetime causes it to curve there, challenging the usual understanding that spacetime in small areas (a Lorentz frame) is flat and uncurved.
Altering the stress in a localized area of spacetime causes it to curve there, challenging the usual understanding that spacetime in small areas (a Lorentz frame) is flat and uncurved.
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IF NO OBSERVABLE MASS FLOWS.
In the vacuum of space, no mass particles are observable, nor are any conventional electromagnetic (EM) force fields. However, the vacuum contains virtual force fields due to the presence of virtual particles.
An observable electric field (E-field) doesn't manifest in the vacuum around a charged point until an observable charged particle, such as an electron, interacts with the virtual E-field. This interaction produces an observable E-vector force on the charged particle.
This concept challenges the traditional view held by electrical engineers and physicists that E and B fields exist in the vacuum. Following E. T. Whittaker's work, any vector field can be mathematically represented by two scalar fields, suggesting that vacuum contains only virtual or "unzipped" E-fields until an electron, acting as a "dynamo flux pump," couples with them, forming an observable E-field.
In the vacuum of space, no mass particles are observable, nor are any conventional electromagnetic (EM) force fields. However, the vacuum contains virtual force fields due to the presence of virtual particles.
An observable electric field (E-field) doesn't manifest in the vacuum around a charged point until an observable charged particle, such as an electron, interacts with the virtual E-field. This interaction produces an observable E-vector force on the charged particle.
This concept challenges the traditional view held by electrical engineers and physicists that E and B fields exist in the vacuum. Following E. T. Whittaker's work, any vector field can be mathematically represented by two scalar fields, suggesting that vacuum contains only virtual or "unzipped" E-fields until an electron, acting as a "dynamo flux pump," couples with them, forming an observable E-field.
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Detection of these fields involves the interaction of free electrons within a probe or antenna with Whittaker's scalar fields, leading to measurable disturbances not in the vacuum itself but within the electron gas of the detecting device. Essentially, conventional detectors measure disturbances in their internal electron gas caused by interactions with the vacuum's virtual particle flux.
Moreover, potentials extend to infinity, decreasing in intensity with distance, creating a gradient in the virtual particle flux. This gradient can be visualized as a "river" of virtual particles, with its flow determined by the potential's nature. Artificial potentials, unlike natural ones, impose coherent substructures onto this virtual particle flux, enabling the transmission of structured virtual patterns across space.
Moreover, potentials extend to infinity, decreasing in intensity with distance, creating a gradient in the virtual particle flux. This gradient can be visualized as a "river" of virtual particles, with its flow determined by the potential's nature. Artificial potentials, unlike natural ones, impose coherent substructures onto this virtual particle flux, enabling the transmission of structured virtual patterns across space.
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POTENTIAL: A CONGLOMERATE OF STRESS TYPES.
Essentially, all electromagnetic (EM) potentials are components of a larger, five-dimensional gravitational potential. The idea of a single, uniform gravitational potential doesn't hold up; instead, what we call gravitational potential is made up of various types of stresses and patterns, each named after the action causing it.
For instance, electromagnetic potentials arise from the movement of charged particles and manifest in the vacuum as flows of virtual particles. The vacuum isn't empty but teems with a wide array of these virtual particles, including photons, electrons, positrons, protons, pions, and neutrinos.
The collective stress created by the interactions of all these virtual particles forms what we perceive as the gravitational potential, illustrating a complex interplay between electromagnetism and gravity within a multidimensional framework.
Essentially, all electromagnetic (EM) potentials are components of a larger, five-dimensional gravitational potential. The idea of a single, uniform gravitational potential doesn't hold up; instead, what we call gravitational potential is made up of various types of stresses and patterns, each named after the action causing it.
For instance, electromagnetic potentials arise from the movement of charged particles and manifest in the vacuum as flows of virtual particles. The vacuum isn't empty but teems with a wide array of these virtual particles, including photons, electrons, positrons, protons, pions, and neutrinos.
The collective stress created by the interactions of all these virtual particles forms what we perceive as the gravitational potential, illustrating a complex interplay between electromagnetism and gravity within a multidimensional framework.
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SCALAR Ø-WAVE PRODUCTION.
In exploring the concept of waves that represent pure stress within the fabric of spacetime (the vacuum), various terms emerge to describe these phenomena: scalar electromagnetic (EM) waves, Tesla waves, electrogravitational waves, longitudinal EM waves, electrostatic waves, and zero-vector EM waves. These terms all refer to the same underlying principle.
To understand these waves, consider a thought experiment featuring two single-frequency EM sine waves. These waves have identical frequencies, travel in the same direction, and are superimposed in such a way that their electric field (E-field) components cancel each other out, resulting in vector zeros at any point in space. This setup might suggest the absence of any wave activity; however, if we examine the stress induced in the spacetime medium by these waves, we find a sine wave pattern of alternating compressive and tensile stress.
In exploring the concept of waves that represent pure stress within the fabric of spacetime (the vacuum), various terms emerge to describe these phenomena: scalar electromagnetic (EM) waves, Tesla waves, electrogravitational waves, longitudinal EM waves, electrostatic waves, and zero-vector EM waves. These terms all refer to the same underlying principle.
To understand these waves, consider a thought experiment featuring two single-frequency EM sine waves. These waves have identical frequencies, travel in the same direction, and are superimposed in such a way that their electric field (E-field) components cancel each other out, resulting in vector zeros at any point in space. This setup might suggest the absence of any wave activity; however, if we examine the stress induced in the spacetime medium by these waves, we find a sine wave pattern of alternating compressive and tensile stress.
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This pattern is indicative of a "longitudinal" EM wave, akin to what Tesla described as a "sound wave in the nonmaterial ether." Furthermore, this wave can be understood as a gravitational wave since it embodies changes in spacetime curvature (vacuum nonlinearity) itself. The wave alternates between positive and negative curvature, correlating with changes in the virtual particle flux intensity of the vacuum.
These alterations in vacuum stress, mirroring changes in spacetime curvature, also represent oscillations in electrical charge - with one half-cycle symbolizing negative charge and the other positive charge. This dynamic is illustrative of how an electromagnetic photon can be seen as a "positron-electron pair," encapsulating one wavelength of these scalar EM waves.
These alterations in vacuum stress, mirroring changes in spacetime curvature, also represent oscillations in electrical charge - with one half-cycle symbolizing negative charge and the other positive charge. This dynamic is illustrative of how an electromagnetic photon can be seen as a "positron-electron pair," encapsulating one wavelength of these scalar EM waves.
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Moreover, these waves affect the flow of time, causing it to decelerate and accelerate relative to the ambient rate of time flow across different half-cycles. Thus, scalar waves also embody "tempic" waves, as termed by Wilbur Smith, signifying oscillations in the rate of time flow itself. Since these temporal oscillations are essentially variations in spacetime curvature, they can exert force when interacting with mass, just as any other form of spacetime curvature would.
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In summary, scalar waves are identified as zero-vector waves, where patterned electric (E) and magnetic (B) fields align in such a manner that their cumulative effect results in a vector sum of zero. The electromagnetic character of a scalar wave's "envelope" is defined by this zero-sum interaction of distinct, finite electromagnetic force vectors.
Key concepts such as phasing, beaming, frequency, superposition, interference, resonance, and Fourier expansion constitute the foundational of scalar electromagnetic engineering. Constructing a scalar beam involves adapting the electromagnetic wave transmitter to emit multiple, synchronized transmissions that, when combined, achieve a vector sum of zero. This process effectively involves the simultaneous transmission of multiple, phase-locked electromagnetic force-field beams in a manner that their sum is neutralized.
With minimal adjustments, standard beaming antennas and traditional electronic circuits can be adapted for scalar electromagnetic applications.
Key concepts such as phasing, beaming, frequency, superposition, interference, resonance, and Fourier expansion constitute the foundational of scalar electromagnetic engineering. Constructing a scalar beam involves adapting the electromagnetic wave transmitter to emit multiple, synchronized transmissions that, when combined, achieve a vector sum of zero. This process effectively involves the simultaneous transmission of multiple, phase-locked electromagnetic force-field beams in a manner that their sum is neutralized.
With minimal adjustments, standard beaming antennas and traditional electronic circuits can be adapted for scalar electromagnetic applications.
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