Cosmological Balancing of the Stars having Multiple Planets
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Though until now it is believed that the celestial bodies also follow all basic rules of physics — our such belief, gets shattered if we believe that the Sun and its planets may be balancing each other in the manner as has been shown in the following diagram which has been pulled out from https://spaceplace.nasa.gov/barycenter/en/.
Though the Sun and its planets may be balancing each other in this manner but if so, it straightaway implies that the rule of physics relating to the first-class levers does not apply to the Sun and its planets, as explained below.
In normal course, the Sun and its planets could have behaved like a first-class lever only if they would have been also sitting over some sort of solid plank which, in turn, would have been resting over some fulcrum analogous to the type of plank and the fulcrum of a regular seesaw.
But as we know, it is not so.
Nonetheless if the Sun and its planets really balance each other, we have to admit that if it is so — it abrogates the existing rules of the physics relating to the first-class levers.
But if the Sun and its planets behave like a first-class lever, we should be also able to assume that the barycenters should be also carrying the mass of the Sun and its planets the same way as the fulcrums of the regular carry the weights of the children sitting over a seesaw, which can be verified in the following manner.
The manner in which we may verify whether the barycenters are akin to the fulcrums or not
If the barycenters are akin to fulcrums it should be possible to calculate the position of the centre of gravity of the entire solar system in the following manner.
N.B.: In this diagram, CG-1 stands for the first centre of gravity, CG-2 stands for the second centre of gravity and so on.
After calculating the position of the centre of gravity of all planets in this manner, it should be possible to calculate the position of the barycenter of the solar system in the following manner.
Alternatively, we may calculate the position of the barycenter of the solar system, even in the following manner.
The other method of calculating the position of the barycenter of the solar system
First of all, we may calculate the position of the barycenter of the Sun and the Mercury in the following manner.
After calculating the position of the barycenter of Mercury, we may calculate the position of the barycenter of the entire solar system as follows.
N.B.: In this diagram, BC-1 stands for the barycenter of the first seesaw, BC-2 stands for the barycenter of the second seesaw and so on.
Let me make it clear all planets of the Sun also revolve around BC-8 — the barycenter around which the Sun revolves.
Now, as we know the astronomers have ascertained the precise location of the barycenter of the whole solar system, around which the Sun is supposed to revolve along with its all planets, as has been mentioned in the article https://www.sciencealert.com/astronomers-have-located-the-centre-of-the-solar-system-to-within-100-metres/, it should be possible to check whether there is any difference in such location and the location as may be calculated in the proposed manners.
If we may use the term “Master Barycenter” for the barycenter of the entire solar system and discover that the calculated location of the “Master Barycenter” is same as its actual location — fine!
It will substantiate the assumption that even though the Cosmic Seesaws do not look like first-class levers they, anyway, function just like “first-class levers” in abrogation of the established laws of physics.
But what if we find that the position of the calculated “Master Barycenter” is not same as the position of the actual “Master Barycenter”?
In that case, though it will falsify the assumption that the Sun balances its planets just like seesaws; we can reason out that the axis of the Sun wobbles due to a different reason which has been explained through the following diagram.
Though each planet balances itself in its orbit because the centrifugal force acting on it gets balanced by the gravitational pull exerted by the Sun on it but it is also true that the axis of the Sun may be wobbling simply because the gravitational pull exerted by it on each planet is not same as shown in this diagram.
