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In the antigravitational experiment, time sometimes pauses


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Talking about the dark energy in the universe, one may think of antigravitation.

 

In the antigravitational experiment, time shown on a stopwatch sometimes pauses.

 

1 Steps of the experiment

 

(1) Prepare three identical quartz stopwatches (chronograph capabilities: dive watch, 1/100 second precision to 24 hours). Let them be Stopwatch A, Stopwatch B and Stopwatch C respectively.

 

(2) Start Stopwatch A and Stopwatch B simultaneously. In the experiment stated in Section 1.2 of the Antigravitation Engine Site (hereafter called the Site), lay Stopwatch B in front of the rotation part of the antigravitation engine, at the head of the boat (without the washbasin). The boat (without the washbasin) is put horizontally on the water in a bathtub.

 

In order to make the speed of the boat not equal to zero, the water in the bathtub should be fresh and clean, the batteries should be newly charged, and the weather should be clear.

 

Turn on the motor. Put Stopwatch A on a table in another room.

 

After 16 hours, turn off the motor. Place Stopwatch A and Stopwatch B side by side. Shoot a video of the readings of the two stopwatches, and take at least 10 photos of them. When the photos are taken, the shutter speed is 1/1000 s.

 

(3) Start Stopwatch A and Stopwatch C simultaneously. Lay Stopwatch C in front of the rotation part of the antigravitation engine, at the head of the "boat". Put the boat on a stool. Turn on the motor. Since the frictional resistance of the stool surface is large, the antigravitation is zero according to Eq. (2) in Section 1.2 of Chapter 1 of the Site. Put Stopwatch A on a table in another room.

 

After 16 hours, turn off the motor. Place Stopwatch A and Stopwatch C side by side. Shoot a video of the readings of the two stopwatches, and take at least 10 photos of them. When the photos are taken, the shutter speed is 1/1000 s.

 

2 The result of the experiment

 

(1) The video playing in slow motion and playing step by step shows that, compared with the time shown on Stopwatch A and that shown on Stopwatch C, the time shown on Stopwatch B sometimes pauses.

 

(2) When Stopwatch A is close to Stopwatch B, Stopwatch A will be affected by Stopwatch B and hence the uncertainty in the time shown on Stopwatch A will slightly increase.

 

3 Theory

 

3.1 (1) In the antigravitational field, a different antigravitational quantum of action corresponds to a different uncertainty in the spacetime, and hence corresponds to a different spacetime.

 

In the antigravitational field, when the mass and the velocity of a particle vary due to the uncertainty relation of quantum mechanics and due to the change in the quantum state, the particle has different antigravitational quanta of action (see Eq. (3) below), and hence it is in different spacetimes.

 

Hence in the antigravitational field, different quantum states often belong to different spacetimes.

 

Therefore, in the antigravitational field, at some moments Stopwatch B is in a quantum state of another spacetime, and hence the time shown on the stopwatch pauses.

 

When it has left the antigravitational field, Stopwatch B will keep the above feature for a short time.

 

3.2 According to mechanics,

 

Delta E = (1/2) m v v . ( 1 )

 

According to Equation ( 2 ) of Section 7.10.1 of the Site,

 

m = M v v / (c c) , ( 2 )

 

where m is the mass of the gfm (gravitational field matter) ball particle of the rotation part of the antigravitation engine.

 

According to Equation ( 3 ) of Section 7.10.1 of the Site,

 

h' = 0.27 G M M v / (c c) , ( 3 )

 

where h' is the antigravitatioinal quantum of action.

 

According to Equation ( 2 ) of Section 6.8 of the Site,

 

(Delta t) (Delta E) ≥ h' / (4 Pi) . ( 4 )

 

Substitution of Equations ( 1 ), ( 2 ) and ( 3 ) into Equation ( 4 ) yields

 

Delta t ≥ 0.135 G M / (Pi v v v) ,

 

(v is not equal to zero), ( 5 )

 

where Delta t is the uncertainty in the time, G is Newton's gravitational constant, M is the mass of the rotation part of the antigravitation engine, and v is the speed of the boat moving due to the antigravitational field.

 

In the above experiment, M is 0.00315 kg, v is about 0.00004 m/s , and Delta t is about 0.14 s .

 

If the load on the boat is not too heavy, the carrying device had better not include the washbasin. Instead, put the foam plastic board directly on the water surface. In this way the antigravitational effect is easier to occur.

This is because in the antigravitational experiment described in Chapter 4, the uncertainty in the time of a water molecule can be as large as

Delta t = 239 days .

(See Section 6.21 in Chapter 6 of the Site). So water is the catalyst for change in spacetime.

 

For more information (e.g. the video), please see Chapter 7 of the Antigravitation Engine Site

(http://xczhx.c59.zgsj.com/indexEnglish.htm).

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So yeah, that site does not make any sense at all.

 

The power device behind the motor of the rotation device serves as the disturbance device, which disturbs the current of the gravitational field...

 

What? "disturbes the current of the gravitational field? What does this even mean? How can a gravitational field have a current?

 

Gravitational field matter can be called "gfm" for short. The definition of the antigravitational field is the moving gfm. The current of the gfm of a body causes waves in the local gfm of the universe. Under certain conditions, such currents and waves can drag spacetime and drag the inertial frame, and can cause microscopic and macroscopic quantum phenomena. The definition of antigravitation is the effect of inertial frame dragging of the moving gfm.

 

"Gravitational field matter"? "local gfm of the universe"? The definition of antigravitation? Thats not a definiton, not with these terms.

 

a = 16π3 m r4 / ( c h T4 )

 

 

Where did that equation come from, how do we know it works?

 

the acceleration of the boat is not related to the total mass of the boat as far as classical physics is concerned, and this shows the antigravitational effect

 

Why isn't the acceleration of the boat "related" to the total mass?

 

Because of the macroscopic quantum effect, when being controlled by the gfm current, the boat is in uncertain spacetime, and hence it moves now fast, now slow, now forward, now backward, and sometimes it stops for a while.

 

How does being in an "uncertain spacetime" (another thing that is not defined) mean the boat will go fast, slow, forward, backward, and sometimes stop? Forward backward. Fast slow. Stop. What other things can a boat do? You dont seem to be able to predict the movement at all.

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I want to know the mechanics of this antigravity and how it fits into our current understanding in the standard model that antigravity can't exist. And that dark energy is something rather complex we havn't thought about.

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(1) The video playing in slow motion and playing step by step shows that, compared with the time shown on Stopwatch A and that shown on Stopwatch C, the time shown on Stopwatch B sometimes pauses.

 

Crappy stopwatches, perhaps?

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the pictures from this guys site look mighty familiar(including the agonisingly slow download times).

 

i'm sure that he's been here before and got proven to be a crack pot. i'll go have a little search just now.

 

okay after a token search i haven't found anything but i'm still 100% sure i seen them somewhere before(maybe on the bad astronomy boards where i used to visit regularly or orbitersim boards)

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