Gravity Relativity

Relativity of gravity

To define the relativity of gravity, we need first to define what relativity is.
When an observer on B position sees a light source on A position, independent of its velocity, he will see this source always on A₀ position.

If v = 0, in other words, the source is stopped on A₀.

The photon emitted from A, on the A₀ position, which will arrive at a receiver B, on the B position, will be that one emitted in direction of B with velocity c, it will reach B in a time t₀, where D = c x t₀.

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If v ≠ 0, approaching to the position A₀.

The photon which will arrive at an B observer will come out from A₁ position, with velocity c₂, where c₂ = c + v, and, when it arrives at an B observer, it will look like it came from A₀ position, with velocity c. Thus, independent of velocity v of source A, it will always be seen on A₀ position.
One of light’s proprieties is that it is possible to an observer on B creates virtual right-angled triangle when it sees a source A, since he knows the velocity v of the source A and the A₀ position. This virtual triangle will be the right-angled triangle B A₀A₂, where the A₂A₀ side is perpendicular to A₀B side

- The side A₂A₀ = E, where E = v x t;
- The side A₂B = L₂, where L₂ = c x t;
- The side A₀B = D, where D = c x t₀.

v = velocity of source A;
t = Time that a photon goes from A₂ position to B position, with velocity c, and the body goes from A₂ position to A₀ position, with velocity v;
t₀ = Time that a photon goes from the source stopped on A₀ to the observer on B, with velocity c.

This is the Camila effect of light
Due to this effect we can apply the formula of the time of relativity in this triangle and we can compare the time t₀ with time t which the photon goes from the source on A₀ position if it is stopped or with a velocity v, where

As we have already reminded what relativity of time is, we can define the relativity of gravity.

Relativity of Gravity

It is the comparison of the force of gravity that A body exerts on a B body when it exists a relative velocity v between them and when they are stopped.

If v = 0, the force of gravity will be F₀, where

[1]

If v ≠ 0, the gravity force will be Fv, where

[2]

Dividing [1] by [2], we will have

[3]

In the formula of relativity of time, we have

[4]

Substituting [4] in [3], we have

Thus,
[5]

This is the formula of relativity of gravity which compares the modulus of the force of gravity between two bodies when it exists a relative velocity v between them and when they are both stopped, in other words, v = 0.
Thus, when we know the relativity velocity between two bodies A and B and their positions, we can apply the gravity relativity and we can define the force of gravity Fv in both modulus and direction, which creates an angle a with the AB axle, as it follows.

or

where

as tang a = .

Both relativity of time and relativity of gravity were deducted of a virtual right-angled triangle. Thus, they just can be applied in right-angled triangles. And, due to both Camila effect of light and gravity is possible to create a virtual right-angled triangle when the observer knows the position of a source or a body and the relative velocity v of the position of this observer.

The Science have been wrongly applying the formula of relativity of time being out of the existence of this virtual right-angled triangle, because, it also deduced this formula, that is equal to Logical Deductions´ formula, of a right-angled triangle and it applies it in any triangle.

Camila Effect