The Great Pyramid Of Giza, A New Interpretation Of The Data - Alternative View

The Great Pyramid Of Giza, A New Interpretation Of The Data - Alternative View
The Great Pyramid Of Giza, A New Interpretation Of The Data - Alternative View

Video: The Great Pyramid Of Giza, A New Interpretation Of The Data - Alternative View

Video: The Great Pyramid Of Giza, A New Interpretation Of The Data - Alternative View
Video: 360° Travel inside the Great Pyramid of Giza - BBC 2024, March
Anonim

In the light of the new interpretation of the known data about the Great Pyramid of Cheops, the version of the purpose of this pyramid was changed from the tomb of the pharaoh to a gravitational device, probably used for interplanetary communication by a civilization unknown to us.

In the light of the new interpretation of the known data about the Great Pyramid of Cheops, the version of the purpose of this pyramid was changed from the tomb of the pharaoh to a gravitational device, probably used for interplanetary communication by a civilization unknown to us.

It is generally accepted that the Great Pyramid was built in 2560-2580s BC as a tomb for the reigning Pharaoh of the 4th dynasty Cheops (Khufu). Despite some difficulties in explaining the possibility of building it in the required time frame and the equipment available at that time, this version is nevertheless considered the main one.

The Pyramid of Cheops is the largest of the Egyptian pyramids.

  • Height (today): ≈ 138.75 m.
  • Angle: 51 ° 50 ′.
  • Side face length (now): about 225 m.
  • The length of the sides of the base of the pyramid: south - 230.454 m; north - 230.253 m; west - 230.357 m; east - 230.394 m.
  • Perimeter: 922 m.
  • The total weight of the pyramid is estimated to be about 6.25 million tons.

On the weirdness of camera design:

To make it convenient for the reader to familiarize himself with the material, I will quote verbatim quotes by V. Kulikov:

“So the vaulted wedges in the queen's chamber work like cantilever beams.

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Thereby reducing to a minimum the spacer force to the sides. All the load from the vault will be concentrated on the edge of the wall, while the far ends of the beam, on the contrary, will be unloaded.

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(this is how a cantilever beam works)"

It is about intentionally concentrating the load on the side walls. And then the "unloading chambers" on the contrary become "LOADING chambers".

In the “king's” chamber, the walls do not rest on the floor and thus the load from above is not distributed to the floor.

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Fig. 1

Fig. 1.

They dug a broken line companion.

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Fig 2

Fig 2.

They dug a large pyramid.

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Fig 3.

Probably, they cut a hole in the rocky base, then covered it with blocks, covered it with sand, made the floor of the chamber and built the chamber. Then several million tons were loaded onto the walls of the cell.

Petrie described that the bottom of the wall is about 6 inches below floor level.

This is clearly seen from the pit in the “king's” chamber (Fig. 2). Surprisingly, vertical stripes are visible on the polish of the wall, this only indicates that repeated movement (vibration) has created these vertical stripes.

Are there any facts about the periodicity, wave nature of the pyramid structure? For example, a large pyramid (the most studied).

Fig 4
Fig 4

Fig 4.

Periodicity in layers is visible - an approximate period of 15 meters.

What we have? Fixed floor of the chambers (filled with sand) and vibrating walls with a wavelength of 15 meters.

Fig 5
Fig 5

Fig 5.

The pyramid is built in layers, the thickness of the layers is different and varies from 60 cm to one and a half meters.

It is very similar to a damped wave, such as a sound wave.

Fig 6
Fig 6

Fig 6.

To explain the operation of the Great Pyramid, the concept of an acoustic maser is introduced. This picture shows how the acoustic maser works.

Fig 7
Fig 7

Fig 7.

The queen's chamber pumps the limestone medium with wave energy. There is a standing wave in the large gallery. This is clearly seen in the section of the pyramid, where there are wave peaks of the limestone medium, in relation to the standing wave. The pumping with the energy of the standing wave occurs. A standing wave can be thought of as a stretched string with zero vibrations at the ends of this string.

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The standing wave must be inside the ramp.

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It is necessary to analyze the nature of the damage to the large step.

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The nature of the damage to the step is such that it is difficult to say whether it is from multiple slippings of the string, or one that slipped in the wrong way.

The break in the antechamber should probably be considered in conjunction with the break of a large step.

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This is probably one wrong wave slippage.

Detailed drawing of the breakout of a large step.

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It can be seen in the drawing that the damage is located on the axis of the wave propagation, therefore the damage is associated with a change in the position of the nodes of the standing wave.

Most likely this is due to the destruction of the bridge.

This means there must be damage at the bottom of the large gallery too.

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In the grooves, spatial stabilizers of the points of the standing wave with zero amplitude were attached.

If there are 27 pairs in the large gallery, the distance between the grooves is 1.58 m, the wavelength is 3.16 m, the speed of sound is 340 m per second, respectively, we divide the speed by the wavelength and get the oscillation frequency equal to 100.8 hertz.

Translated, this means that the intensity of the sound wave shows how much energy passes through a unit area (1m2) per unit of time (1 s). If the frequency is 100.8 Hertz, the speed of sound is 343 m / s, the air density at 20 degrees is 1.2 kg / m3, the amplitude of the sound wave is 0.5 m, then the intensity of the acoustic wave, according to the equation, is 22.16 MW / m2

In order for the wave to enter the king's chamber, there must be a granite mirror directly in front of the passage, located at a distance of 1.58 m from the beginning of the large step.

Examining the Laz Big Gallery - Antechamber, we see that the length of the passage is 1.56 m and corresponds to half the wavelength of the acoustic maser.

At the beginning of the passage, a granite mirror (granite insert) should have been attached, but not a cork.

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The supposed granite mirror, in front of the access door to the antechamber, was not mounted in the center, but shifted to the right, which means that the wave was shifted to the left, which ensured multiple reflections from the walls of the main chamber.

The discovery of a concave granite slab in Abu Roash with a high quality polish confirms the version of the acoustic wave.

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Perhaps this plate was a reflector and a damper at the same time.

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The difference is in the polishing of the lower row of the wall of the king's chamber.

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The specularity of the polishing creates conditions for multiple reflection of the wave, where each time, when the wave is reflected, part of the wave energy will be transferred to the wall, which is why it was necessary to partially polish the chamber walls

The wave should be directed into the king's chamber at a small angle to form a triangle (a multiple of the half waves - hypotenuse, the width of the chamber is the leg, and the angle of inclination between them), then conditions will arise in the chamber for a standing wave with multiple reflection of the wave, without destroying the cameras.

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It turns out that 4 half waves (4 multiplied by 1.58m) break in from wall to wall, with an inclination angle of 33 degrees.

The reflection from the end walls occurs exactly in the middle, with two half waves (2 times 1.58m).

To prevent the wave from slipping into the passage, there should be 15 mirrored protrusions in the walls (two for each point of reflection).

What is most interesting, having looked at the Encyclopedia, I learned that there are 15 hewn bosses within the walls. The wave enters the camera through one such boss and changes the angle of inclination.

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It turns out that this is the interior of a huge mechanism, completely not intended for the presence of a person. In the large gallery, the temperature of the atmosphere may have been over 100 degrees. The fact is that air is a wave medium and adiabatically contracts and expands, respectively, work is done and the air heats up.

Everything that accidentally falls into the wave channel will be atomized.

Waves are constantly reflected from the ceiling of the large gallery (the ceiling is made of polished granite). After reaching a wave of a certain energy, the shutters open and the wave rushes into the king's chamber. The walls of the chamber absorb this energy and the entire mass (6.25 million tons) of the pyramid begins to vibrate. It simply has to resonate with the rotation of the earth and affect gravity.

Probably enough about the wave, there is too much of everything, and all at once, put in its place. I decided to check scientific articles, gravitational phenomena on our planet.

It was then that one phenomenon came to light that was never explained.

It is a continuous background oscillation (constant amplitude 0.4 ngal with a frequency of 3mHz and 4mHz).

The Germans have created 9 tracking stations to identify the source of vibrations and approximate sources are located in the North Pacific and South Atlantic, almost on the surface.

www.geophys.uni-stuttgart.de/~widmer…g06.pdf

According to the article, ftp://www.quake.geo.berkeley.edu/outgoin…e04.pdf this vibration is generated by winter storms in the southern and northern hemispheres, when waves interact with the bottom.

According to another article https://www.eri.u-tokyo.ac.jp/knishida/Baro.pdf this is the influence of acoustic waves.

When there are many versions, there is no single theory.

Gravitational anomalies are changes in gravity that cannot be explained by ordinary processes, such as ocean level (ebbs and flows), precipitation (rain, snow), groundwater level, atmospheric pressure (pressure drops). the change in gravity due to earthquakes is the most powerful parameter.

The phenomenon discussed here cannot be explained by any of the above-named processes.

The article ftp://quake.geo.berkeley.edu/outgoing/peggy/Papers… (editor's note: not working link) shows the spectrogram of the earth oscillation with all harmonics.

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Of course, seismologists and geophysicists have no other way of using wind and storm to explain this wobble.

What is interesting in the higher frequency range are ocean wave microseisms and they are indeed subject to seasonal modulations. It turns out, according to Toshiro Tanimoto, earthquakes above 5.7 magnitude add amplitude to the existing wobble, anything below that has no effect on this free wobble.

All microseisms associated with storms form a noise background, the amplitude of which is modulated by the season and the level of this background is lower than the amplitude of the earth's vibrations. Accordingly, something else with a moment of 10 to the power of 18 newtons per meter should affect our planet.

The sun has millions of vibration peaks in the 2-4 millihertz range, the earth has the lowest fundamental vibration frequency of 3 millihertz, that is, the sun resonates with all planets and stars.

What is the story of the discovery of a vibration peak 160 minutes worth!

This peak was found in almost every star, and near the earth in particular.

Perhaps this vibrational resonance belongs to a black hole in the center of our galaxy?

Synchronous manifestation of 160-min pulsations of the ground pressure and Z-component of geomagnetic field at Moscow, Apatity, Oulu, Yakutsk and Tixie

It turns out that the alleged gravitational device, which was hypothetically located in a large pyramid, and now possibly in Antarctica or at the bottom of the ocean, can enter into resonance with the earth and through resonances, with the sun, another star, another planet, a gravitational inductive connection can be created.

Australia, Melbourne.

Author: S. PERSHIN