Январь 15, 2017

(Donation to the project MGEF. Please join us in showing your support).fig-67Unusual gyroscope MGEF (Module Generator of Entropic Forces).

«What’s in the optical hologram is a real: film or a three-dimensional image?»

 

Today, the Holographic Principle — is hundreds of theoretical works by famous world-class physicists: G. ‘t Hooft, L. Susskind, J.D. Bekenstein, E. Verlinde, J.M. Maldacena, R. Bousso …. It is a theory that unites incompatible, but in fact, it is the most accurate reflection of the current state of science when scientific discoveries and their practical applications are so incredible in terms of ordinary human perception, that in them hard to believe. Already there are experimental studies confirming the operation of the Holographic Principle [30], [32]. Since 1997, more than 10,000 works have been published supporting this idea.

Understanding of the emergent nature of space-time and gravity comes from the laws of black hole thermodynamics and the Holographic Principle was born after the discovery of the laws thermodynamics on their surface. Bekenstein [7] and Hawking [8] have suggested a deep connection between gravity and thermodynamics. Through several decades of research and experimentation, physicists have brought forth a unified theory of the Universe that is based on information theoretic principles. The Holographic Principle states that the entropy of ordinary mass (not just black holes) is also proportional to surface area and not volume; that volume itself is illusory and the Universe is really a hologram which is isomorphic to the information «inscribed» on the surface of its boundary — this holographic screen.

Commensurate in scale with the Holographic Principle was the discovery of the anisotropy of the Universe in 1992 (anisotropy of cosmic microwave background (CMB) — (this the difference of temperature in different directions on the sky) [5] Experimentally confirmed by the anisotropy of the CMB and the discovery of coherent acoustic waves in the early Universe is of great importance not only for cosmology but for the whole of natural science as a whole. It can be said that large-scale three-dimensional sound coherent oscillations act before recombination period and ended after 379,000 years, but did not disappear completely, and recorded big scale on the sky. As a result, the temperature anisotropy of the Universe, according to the Holographic Principle, may be projected on its holographic screen. It is experimentally confirmed the fact that coherent oscillation of the elements of mass can be projected without any loss of information to the specific locations of the holographic screen. All calculations and experimental data in the modern cosmological model, in particular, explain the observed anisotropy of the Universe are connected with the speed of sound three-dimensional coherent oscillations of the primary plasma. the discovery of CMB confirmed the theory of the hot Universe and is now one of the most important facts supporting the theory of the Big Bang and the expanding Universe. We can say that experimentally is not confirmed equipartition of temperature on the cosmological horizon of the inflationary Universe. Investigating thermodynamics on the holographic screen, we must take into account the impact of it’s of global temperature anisotropy on the dynamics the projections of phenomena. The dominance of gravity, on a large scale, in particular, and existence all four known forces a whole can be explained by the influence of a large-scale thermal anisotropy Universe.

 

The CMB dipole anisotropy. The color scale shows a spread of ±3.5 mK.

For experimental verification of the Holographic Principle is offered unusual gyroscope MGEF. It is assumed that MGEF can generate and control the direction of gravitational forces, can be used as a propulsion system and can easily be reprogrammed to work as a device for measuring the geometry and dynamics of the Universe in the real time (without limiting the speed of light). Let us consider in detail how it works.

To demonstrate the possibilities of generating artificial gravity forces we define that is very important: Although the bits of information are encoded on a two — dimensional screen the observed images appear three dimensional since their nature is holographic.

«Usually, holography is studied in relativistic contexts. However, the gravitational force is also present in our daily non-relativistic world» [25] [page 3. 5].

«we will argue that the central notion needed to derive gravity is information» [25] [page 2. 23].

Motivated by Bekenstein’s argument, let us postulate that the change of entropy associated with the information.

The relationship between entropy and information is that the change in information ΔI is represented by a negative change in the entropy ΔS.

ΔI = — ΔS.

On the other hand, gradients of temperature, entropy, and force  are associated with acceleration and the resulting mass:

«We can express the entropy change in terms of the acceleration»  [25] [page 11. 14]. «Thus, we conclude that acceleration is related to an entropy gradient. This will be one of our main principles». [25] [page 11. 22].

ΔS ∼ α

To shorten the text, we mean that the temperature, entropy, and entropic forces are on the holographic screen — the cosmological horizon of the Universe.

Let’s start with the postulate of Holographic Principle:

1. «In the limit of a very large region, the bounding surface can be taken to be a flat plane at infinity. In some way, the phenomena taking place in three-dimensional space can be projected onto a distant «viewing screen» with no loss of information» [3] [page. 3. 18]. This means that all the information, the receiver, the transmitter, and the observer is on the holographic surface the cosmological horizon of the Universe. For us, it is very important not to forget and this greatly simplifies the exchange and processing of information for the observer.

2. Unusual gyroscope MGEF is that the cycle of its spherical rotor makes one complete revolution around the three axes. The movement of the rotor in a vacuum is controlled by a computer control system.

3. Since the spherical motion (forced coherent oscillations) of the spherical rotor is made around the three orthogonal axes, then there we have are six areas (groups) of angular accelerations elements of mass. All elements mass of the rotor moves over the surfaces of concentric spheres around a fixed point — the center of mass. Nodes and anti-nodes of angular accelerations create a stationary interference pattern. Thus, we are dealing with the cooperative a quantum phenomenon.

4. According to the Holographic Principle, we can make this projection the six groups of angular accelerations (αCi) elements of mass (gradient entropy) on a holographic screen — the cosmological horizon of the Universe without losing information. Actually, the projection and is not required, if you understand the essence of the Holographic Principle. In the presence of horizons, it is natural to define on the horizon global gradient temperature ΔTgl.

5. We have the stationary interference pattern of the six groups of angular accelerations (gradient entropy) is on diametrical sections of the holographic screen. rotor control system produces shifts of the rotor (any the pairs (4 of 6) projections, reverses the rotation of the half-line). Gradients entropy of αEi — angular accelerations (they emerge at displacement elements of mass) by moving on the screen part of the projections are experiencing the different entropic force as they interact with a certain dipole global gradient temperature. Thus we are able to control the position of the on-screen projections of two angular accelerations αCi and αEi. The center of projections angular accelerations is displaced under the action of the forces of entropy associated with a temperature gradient. therefore, the center of accelerations of the rotor is attached to the entropic force «F» — this is a long-range gravitational force.

6. Let us consider.

 The thermodynamics on the holographic screen (hs) with the dimension of «2 + 1» (2D).

 

Let us leave only the physical body outside the center (inside) of the spherical holographic screen (screen) of the Universe with area A, and place the observer in the center of the screen. Then the screen can be presented as a memory device for storing information related only to our physical body. Consider the experimentally established temperature of the Universe, projected without losing information on its  screen:

(1)

where Tpr— temperature on the screen, ΔT — positive or negative temperature difference at two points per unit distance between them a vector quantity — Δx. The minimum limit Δx is Planck length. The max limit Δx is the distance between the two central points of petals of global temperature dipole anisotropy of the Universe.  T is the projected temperature on the holographic screen without loss of information (therefore, further as the temperature T on the screen), Δx is the vector value (according to Conclusions of thermodynamics, the direction of the vector from high to lower temperature). 

Considering that the entropy of a system depends on the distance ∆x, an entropic force Fentr could arise from the thermodynamical conjugate of the distance as  [25] [page 7. (3.7)]

(2)

The fundamental entropic force may be regarded as an indication that is realized on the screen in the range ∆x. Substitute (1) in (2).

(3)

where «ΔT» — global gradient temperature, «ΔS» — gradient entropy caused by the acceleration projections of the matter.

 

Assume that for an entropy force in three-dimensional space as for any of the four forces, it is necessary to supplement it with a vector factor Δx perpendicular to the screen, and the screen temperature (in the classical approximation) is assumed constant. Then:

 

(4)

where T temperature of the screen, «ΔS» — gradient entropy caused by the acceleration either projections of the matter.

 

The product Fentr Δx can be considered as the energy that should be applied to the system in order to withdraw it from the equilibrium state. The existence of a vector factor Δx (perpendicular to the screen) is the reason that the world seems to us to be three-dimensional. Space occurs on a macroscopic level only after discretization. Consequently, with each configuration of matter, the final entropy is connected. This entropy measures the microscopic amount of information that is invisible to a macroscopic observer. In general, this amount of information will depend on the distribution of matter. This information will be processed by entering the microscopic evolution of the screen, which seems random from a macroscopic point of view. Such an assumption goes back to Bekenstein’s thought experiment in the derivation of his famous formula for entropy. He considered a particle with a mass m that approaches the horizon of a black hole. Directly near the horizon, the particle merges with it. As a consequence of the infinite redshift, the mass of the particle increases the mass and area of the horizon by some small (classical) value. As soon as the particle is at a distance of the Compton wavelength Δx from the horizon, it can be regarded as part of a black hole. Then it increases the mass and area of the black hole horizon by a small amount that Beckenstein associated with one bit of information, which led him to the law of correspondence between the area of the black hole’s horizon and its entropy.

Verlinde considered the situation, not alongside a black hole, but with a flat non-relativistic space, ie, next to a small plate — a holographic screen, and a particle of mass m that approaches it. Eventually, the microscopic degrees of freedom of the particle merge with the screen, but just before that, some amount of information is transmitted to the screen. Thus, a holographic direction appears perpendicular to the screen. Guided by Bekenstein’s considerations, Verlinde wrote down the formula for the entropy increment associated with the mass [25] [page 4] (3.6):

 

 

Where c is the speed of light in a vacuum, ħ is the Planck constant.

(5)

How does entropic force arise?

Each cell of the screen by definition contains one bit. Assuming the fulfillment of the holographic principle, let us write down that the information capacity of a spherical screen is proportional to the area of the shell:

 

(6)

Where N is the number of bits on the screen

In our closed system, the energy E is equivalent to the mass of the physical body M, which is concentrated in the part of the space surrounded by the screen. Since temperature and acceleration are closely related and have a direction in a three-dimensional space perpendicular to the screen, then, in accordance with the holographic principle, we can project them without loss of information. Unruh showed that the observer in the accelerated reference system has a temperature T:

 

(7)

Where α is the acceleration, kB is the Boltzmann constant. As will be shown below, using this formula, we can display the temperature associated with the bits on the screen.

We have chosen the usual position of the center of mass of the physical body when it is displaced relative to the center of the screen. According to the proposed method of projecting the phenomena on the screen, suggested by L. Susskind, the memory cells of the screen with the temperature projected on it, connected with the physical body, occupy one hemisphere of the screen, this is what we call the global temperature gradient. Nevertheless, the energy equivalent to matter and uniformly distributed across the cells of the screen must, subject to the holographic principle, carry information about the mass and coordinates of the physical body in three-dimensional space without loss. Note that these conditions are contradictory. In the classical approximation, the total energy that is associated with the physical body can not be uniformly distributed across the screen, otherwise, information about its coordinates will be lost. To solve this problem, it is required to break up the total energy equal to the mass of the physical body into kinetic and potential and, only then it can be assumed that the total energy tends to be uniformly distributed among the memory cells. Thus, we come to the important conclusion that, for any physical body, there is its own global temperature gradient on the half of the screen, which carries information about its mass and coordinates (potential energy), and the displacement of the global temperature gradient under the action of entropy gradient displacements (kinetic Energy) complements the associated energy E to the full. Then we can assume that the entropic force arises from the movement of the global temperature gradient on the inflation screen, which leads to a shift in the center of the projections of the accelerations of the mass elements or the coordinates of the physical body in the three-dimensional space. In full accordance with the conclusions of Verlinde, the emerging entropic force in the three-dimensional space acquires the appearance of a gravitational force.

Obeying the holographic principle, complete information about the physical body and its coordinates, related to the kinetic and potential energy, tends to spread evenly across the screen. This means that any physical body has inexhaustible energy from the source of kinetic energy necessary to move its global temperature gradient across the screen. Kinetic energy is the result of inflation — the accelerated expansion of the screen itself (the continuation of the Big Bang).

If our assumptions are correct, then thermodynamics on the surface of the screen must inevitably lead to the conclusion of fundamental laws, in particular, to the Law of World Gravitation. Let’s consider more in detail

So, we assert that the potential plus kinetic energy on the screen is equal to the total energy (Ek + Ep = E). Then the total energy equal to the mass of the physical body tends to be evenly distributed between bits of the screen N (by ½kBT for each bit).

 

(8)

Where kBT is the temperature of one cell. We use the well-known formula for energy.

 

(9)

Where M is the mass of a physical body enclosed in a part of the space bounded by a spherical screen. The surface area of the spherical screen is A.

 

(10)

Where R is the radius of the screen.

 

If we now introduce a second physical body of mass m into consideration, the position and magnitude of the global temperature gradient on the screen will cease to be the same. In the general case, it will no longer be given the same rule. Entropy will change and a new entropy force will appear for two bodies, compensating for the difference in position on the screen of global temperature gradients for each body. In the formula for the entropy force, we see the product of the masses of two bodies, but before it is necessary to introduce a new constant G, which may turn out to be equal to Newton’s gravitational constant for our Universe.

Using formulas (8) and (9), excluding E. we substitute the expression for the number of bits N (6) that determine the temperature T (7). To determine the force in (4) we use the expression for entropy change (5), finally substitute (10) and G, we get:

 

(11)

Thus, the force of gravitational interaction of two bodies arises as a result of a holographic scenario, which explains its long-range action.

We use formula (4) and replace the temperature by (7), the entropy gradient by (5) and obtain the second Newton law.

(12)

Since each bit carries an energy of 1/2 kBT, then their number N is determined from the relation:

(13)

When we substitute this equation in (5) and use (7), we can express the entropy increments through acceleration:

(14)

 

Combining equations (4), (14) and (13), expressing the temperature through the mass, and the entropy gradient through acceleration, we again arrive at the equation F = mα for the entropy force. However, by entering the number of bits associated with the energy on the screen, we demonstrate that the constant c and ħ fall out of the ratio, which corresponds to expectations. This conclusion means a lot to us, for example, that the entropy (gravitational force) can be artificially created with the help of a hybrid of a classical and quantum device for generating accelerations (an unusual gyroscope) without using exotic masses and energies. The kinetic energy of accelerated screen expansion associated with the mass of the rotor of an unusual gyroscope can be used in the recovery mode and used as an inexhaustible source of clean energy.

Applying the formula for the entropy increment associated with the acceleration (14) and substituting it in (4) for the entropy force, using (7), (10), we obtain the entropy force on the screen surface with radius R:

(15)

Where 𝒂 are equal accelerations associated with the temperature and entropy on the screen of radius R.

The absence of mass in the equation may seem unobvious. But this equation is on the surface of the Universe, and all mass/energy is information on a holographic screen that has no thickness. This equation tells us about two massless one-dimensional vibrating strings and their interaction on the emerging surface, the coding of information by the phases of string vibrations, the appearance of: fractals — the structure of space / time (spatial bundles), all known and not yet discovered particles, and the most entropic (Super) force responsible for the appearance of mass and gravity.

Using (13) and substituting (6), (10), and (7) into it, we obtain an equation for the mass on the screen:

(16)

Combining (15) and (16), we again arrive at the equation F = mα .

Then, at the level of apples, applied to a hybrid of a classical and quantum device (an unusual gyro-controlled accelerator), the mass can be represented by the elements of the rotor mass and artificial accelerations of its coherent oscillations projected without losing information on the holographic screen. Displacements of accelerations associated with an artificial mass relative to the center of mass of the rotor lead to the appearance of a directed gravitational force:

 

Fgrav=ηmα²

(17)

where Fgrav — gravitational force. The emergent laws of gravity contain gravitational force describing the ‘elastic’ response due to the entropy displacement of the projection.

η — order parameter (η > 0) (the inverse of the thermodynamic effect of the external environment),

m — the mass of rotor,

α² = αCiαEi ⁄ 6  gravity accelerations (when αCi = αEi), 6-the number of projections.

αCi — angular accelerations (they emerge at forced a coherent oscillations elements of mass).

αEi – angular accelerations  — the entropy displacement (they emerge at displacement elements of mass).

This means that to obtain long-range gravitational forces do not require exotic masses and energies.

Holographic Principle concludes that: gravity is explained as an entropic force. The equivalence principle leads us to conclude that it is actually this law of inertia whose origin is entropic. This thermodynamics on 2D, arising from the statistical behavior of microscopic degrees of freedom associated with a global temperature anisotropy and localized on the holographic screen of the Universe. Thus the force of gravity and his long-range is not postulated but derived from a holographic scenario.

In contrast to the entropy change when a particle approaches the screen equidistribution temperature, the entropy change when each of the projections of particles (elements of mass) moving on the screen interacts with the gradient of temperature and carries more information than when artificially introduced the equipartition of temperature on screen. As a result of the interaction of the gradient of the entropy projections particle arising entropic force applied to the geometric center of the particle. Therefore, this mechanism is maybe responsible for the appearance of a mass. A result of the encoding information on the holographic screen appears mass/energy, gravity, and space-time itself. Unusual gyroscope MGEF can be used for a detailed study of this assumption.

The series generated in MGEF directed long-range gravitational forces leads us to be able to control gravity.
MGEF device can answer the question: Does the Holographic Principle is valid, according to which the physics of our 3D n-dimensional space-time is equivalent to the physics of the hypersurface with the dimension of 2D. In addition, we get the information directly from the surface of the cosmological horizon in real time and without limiting the speed of light

Gravity — ordered action entropic forces on the projection of the phenomena on a 2D the holographic screen. As a result, the centers of the projections are changing their position in 3D. Entropic (gravity) force — is the result of the interaction of the entropy gradient on the holographic screen caused by the acceleration of matter and the global temperature gradient, known as anisotropy of the Universe. Thus, the movement of information on the 2D holographic screen leads to the long-range directional gravity force in 3D.

After transformation in 3D away quite easily possible to deduce the fundamental laws of Newton (in particular the Second Law). This means that to obtain long-range gravitational forces do not require exotic masses and energy (see below Formalism Verlinde in the emerging space-time (the physics of 3D on the border of 2D).

Newton’s third law is not violated since the size of a closed system is increased to the cosmological horizon of the Universe. Series directed long-range gravity forces leads us to manipulate gravity. Note that the computer of the rotor motion control system has received information on the situation of the global dipole temperature anisotropy of the Universe without limiting the speed of light.

Global temperature gradient Universe and projection on a holographic screen interference pattern of the six groups of angular accelerations αCi (respectively, gradients of entropy). Arrows indicate the possible direction of the angular acceleration displacement αEi.

According to the proposed method of projecting the phenomena on the screen, suggested by L. Susskind [3], the memory cells of the screen with the temperature projected on it, connected with the physical body, occupy one hemisphere of the screen, this is what we call the global temperature gradient.

Where F_grav is the gravitational force, y is the order parameter, the value lying between zero and unity, m is the mass of the rotor of the unusual gyroscope, and a is the product of two equal accelerations. One of which is the rotational acceleration caused by artificial coherent oscillations of the rotor and, second, is caused by a controlled displacement (one of 60 variants).

Obtaining a directed gravitational force in an unusual gyroscope does not contradict the law of conservation of momentum since the size of a closed system is the holographic screen of the Universe.

If our assumptions are correct, then the prospects are opened with the use of an unusual gyro MGEF for:

  1. Artificially creating coherent vibrations of the rotor of an unusual gyro, controlling the direction of the acceleration of the elements of mass, we can create entropy (gravitational) forces on the screen in any chosen direction and, therefore, control gravity.

2. Generating the gravitational force and determining its direction, we can build a hybrid of the classical and quantum device for measuring the parameters of the Universe in real time.

3. There is the possibility of using the inexhaustible energy of the accelerated expansion of the holographic screen.

4. Unusual gyroscope MGEF can be used to transmit and receive information directly from a holographic screen without limiting the speed of light.

If there are intelligent civilizations in the Universe, they will use this communication channel.

 

 

 

 

MGEF

fig-03b

  1. Base.
  2. Enclosure.
  3. The Stator (diameter front section).
  4. Frame
  5. Rotor.
  6. Magnets (100 pcs.).
  7. Magnetic point.
  8. Optical point.
  9.  Induced coils (66 pcs.).
  10.  Sensors (magnetic and infrared).
  11.  Slave controllers and drivers of induced coils.
  12.  Computer.
  13.  Accumulators.
  14.  Solar batteries.
  15.  Retaining bolts.

Let us discuss the concept of the MGEF design, ‘a thick-walled sphere with the magnets in a vacuum inside another sphere with induced coils’. The design allows for three-dimensional oscillations of the balanced ceramic rotor 5 (hereinafter, the rotor) with the magnets pressed into it around its center of mass. Such gyroscope without mechanical axes can be obtained by a master electromagnetic suspension that acts based on the principle of the rotor levitation with magnets in the magnetic field. The rotor displacement from a predetermined equilibrium position is measured by the position sensors. The signals from the sensors are processed by a multi-core microprocessor control system which regulates the currents pulse in the induced windings of the stator so that the magnetic forces return the rotor to the predetermined position and can simultaneously produce full angular rotations of the rotor in any direction under computer control. The control program is provided with the possibility of stabilizing the cyclic rotor speed.

Thus, we are able to rotate the balanced ceramic sphere in a vacuum around one fixed point in any direction under computer control.


Forced coherent fluctuations of a rotor to make angular accelerations (αCi) of each element of mass. On multiple concentric spherical surfaces, angular accelerations take constant positions in space, in a time of a cycle and create an interferential system.

In full accordance with the Holographic Principle, one of the most important properties of coherent fluctuation of a rotor is to concentrate the gradients entropy displacement by its angular accelerations round each of semiaxis of motionless Cartesian coordinates on a «remote» holographic surface of the Universe and angular accelerations may be projected with no loss of information and travel on it without time delay.

Further, we will discuss the holographic dynamics as applied to the spherical rotor in a vacuum. Such closed dynamic system, as we will see below, has central and translational symmetry. It will include (along with the rotor and stator) concentric spherical holographic screens with the entropy associated with the local space occupied by the rotor, its local temperature, and its dynamics.

Let’s receive the parametrical equations of coherent fluctuation from the principle of the smallest action (Hamilton’s principle) for angular displacements of its points.

Let us start with the definition of a coherent oscillation of a classical body (6DoF).

“The motion of a physical body when only one its point О remains fixed all the time is called the rigid body motion (rotation) around a fixed point О. In this case, all points of the physical body move along the surface of concentric spheres, the centers of which are located in the point О. Therefore, such motion is called the spherical motion of the body. Based on the definition of the spherical motion, we obtain parametric equations of the coherent oscillation of the elements of mass from the principle of least action”.

«Coherent oscillations of the elements of mass are the spherical motion of a physical body, the forced full harmonic oscillations of which are successively shifted by 90° or 180° and which are produced in a cycle by angular displacements of its points around the fixed axes of Cartesian coordinates associated with the accelerating observer.»

fig-01

(10)

Then angles: θx- roll, θy — pitch, θz — yaw and parameters θ= πt and -1 ≤ t ≤ 1; where is geometrical angle admeasured by arbitrary clockwise or anticlockwise direction, starting from the relevant semiaxis, and t sets the needed accuracy of angular rotations. The motion formula (10) is given parametrically, and it is applicable for any rotor radius. When Δt → 0, we have small-angle.

“The small-angle approximation is a useful simplification of the basic trigonometric functions which is approximately true in the limit where the angle approaches zero. They are truncations of the Taylor series for the basic trigonometric functions to a second-order approximation.” [33].

sin(θ)≅ θ

“In the limit of a very large region, the bounding surface can be taken to be a flat plane at infinity».  [1] [page 3. 18].  Then рrojections on holographic screen H = A=∞,  S — Arc length — the path of the projected point and  O — Line segment on a holographic screen.  Then S = O and

sin(θ)= θ.

           Thus, the number of directions of coherent oscillations (Number trajectories of apex) can be calculated:

 

The table shows four variants from all (64) that do not fall under the definition of coherent oscillations (there is no phase shift).

The table shows all (60) variants coherent oscillations of rotor unusual gyroscope MGEF around the fixed axes of the Cartesian coordinates X, Y, Z.

According to the definition of a coherent oscillation, all elements of mass of a physical body move along the surface of concentric spheres around one fixed point. If we compare all the points of the physical body with the elements of its mass, we can conclude that we are dealing with a cooperative quantum phenomenon. The complementary accelerations of the elements of mass that are directedly associated with directed the fixed Cartesian coordinates, nodes and antinodes, make a fixed interference pattern that reflects the known geometric structure. Other ways of describing coherent oscillations (not parametric) can lead to loss of information. For example, the task of finding the final coordinate of point a system can be performed on two legs or one hypotenuse, in the second case it leads to loss of information, although the end result is the same. Recall that the main law of conservation for the Holographic Principle is the law of information preservation. The Holographic Principle, although driven by quantum computation, may be revealed to us the existence of a universal computational mechanism that is capable of representing high dimensional problems using a relatively low number = 60 of model parameters.

 Slow simulation of coherent fluctuations of a spherical rotor on parametrical formulas

 

The coherent fluctuations of the rotor occur in a vacuum. Such thermodynamic isolation of the rotor from the nearest external environment is crucial because it eliminates the possible influence of the temperature and entropy changes on the rotor surface. Thus, in a vacuum, the rotor acquires local temperature and entropy when matter (particles) is displaced.

Moreover, such rotor oscillations are characterized by central and translational symmetry, along with mutual orthogonality, as they occur around each of the axis (x¡).

fig-00bb-1

The Graph shows six zero — angular speeds of revolutions of the rotor, when the rotary acceleration (αС) becomes zero, for each of the Cartesian coordinate semiaxes.

αС (x+), αС (x-) — accelerating along the X-axis, αС (y+), αС (y-) — Y-axis, αС (z+), αС (z-) — Z-axis.

It is important to note that, according to the above formula (10), the arising acceleration (αСi) of all points – the electrons (we will treat them as rigidly bound point particles in the atoms, as the elements of the rotor mass) is distributed in space and in cycle time. The phases of the oscillations around each of the axes are a shift in cycle time to 90° and, therefore, the extremes of harmonic functions, due to which the angular shift of the rotor electrons occurs, are distributed in space and in cycle time; see Figure 1. The harmonic functions of the angular movement of the points (the rotor mass elements) are periodic relative to both time t, and to the (x¡). Thus, equipartition of the extremes of harmonic functions of speed (when αСi = 0) in cycle time and in space leads the dynamic system isolated from the external environment to the spatial and temporal coherence.

Relying on the above discussion, let us define the scale gravitational force. Due to the gyroscope property to acquire stability in an effort to save its determined direction relative to the world space and as a result of the rigid connection between all material points (the electrons) of the rotor, they all get the rotary acceleration (αCi).

It doesn’t have an outside or an inside. It just has the rubber surface. You have to learn to think of the surface of the balloon as being all there is. It’s all there is». L. Susskind.

The projections acceleration the surface are possible because: «… have determined that, to high precision, space in our cosmos is flat» [5] [page 1371].

fig-02b

fig-01b

Red and purple are conditionally shown temperature gradients Tu — dipole lobes (on the surface anisotropy) [5]. For a case of coherent fluctuation of a rotor the entropy gradients associated with its angular accelerations: αCX+ =0, αCX-=0, αCY+ =0, αCY- =0, αCZ+ =0, αCZ- =0 concentrate around motionless semiaxis (x¡) on surface of (fig. at the left). For a rotation case (incoherent fluctuation) of a rotor around the main axis, gradients of entropy are making displacement on all surface of (fig. on the right). On two spheres by white color, the arrangement of gradients of entropy on a surface is conditionally shown. For the generation of the directed gravitational force, the program of management of the coherent fluctuation of a rotor makes the displacement of its points round two of three axes of motionless Cartesian coordinates. This results in the acceleration of displacement (αEi). Options are presented in Tab. A, B, C, and D

fig-00a

fig-00d

The scaling and directed gravitational force can be artificially obtained by displacement the position of coherent fluctuations matter relative to two of the three fixed Cartesian coordinate axes, which causes changes in the local entropy on the holographic screen. This can be regarded as a cooperative quantum phenomenon. Thus, the directed scale gravitational force can be generated during the reverse transition of the system to more probable (realized by the greater number of microstates) macro state at the moment of the translational symmetry violation. The fixation of the occurrence of gravitational force can be carried out on a torsion balance. Torsion balance is a compact instrument for measuring the gravitational force and verifying the cooperative quantum effect in unusual gyroscope MGEF based on an elaborately designed Cavendish balance. It uses a reflected laser beam.

See more: http://isan.com.ua/articles/

 

References

[1]J. M. Bardeen, B. Carter and S. W. Hawking, “The Four laws of black hole mechanics,” Commun. Math. Phys. 31, 161 (1973).
[2] G. ’t Hooft, “Dimensional reduction in quantum gravity” (1993) [arXiv:gr-qc/9310026].
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