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The concept of orbit |
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| We now know the Earth orbits around the Sun and that the moon orbits around the Earth. Unfortunately, orbits have largely been taken as a "given", an "understood" concept which does not necessarily require further investigation. | ||
| 6.16.1 | The concept of orbit is the fundamental key to greater form being created | |
| The concept of orbit is the reason why more complex forms take shape and why for instance, humans eventually die. With some further investigation, we discover that not only have we failed to understand the nature of orbit, but we have also forgotten a fundamental rule about orbit- that it is always plural- never singular in form- that is, orbits are always pairs, not singular. | ||
| 6.16.2 | What creates orbit? | |
| We have now explained the concept of attraction, of the desire of all matter to create. We now also know the features of creation that prevent the whole Universe from turning into a giant blob, thanks to the unique and special characteristics of destructive attractors. | ||
| The concept of orbit comes about, simply from the relative kinesis of different structures and their different densities, giving them either a similar or disproportionate aggregate spin. | ||
| For instance, the moon is attracted to the Earth and wishes to bond. Yet the motion of the Moon is much faster than the Earth, as the Moon is less dense. Similarly, the Earth wishes to bond with the Moon, yet at a lower attraction level and is moving slower than the Moon because it is larger and more dense. | ||
| What happens is the moon reaches a point whereby it "overshoots" the Earth and tries to self correct its path, while the Earth in its own attempt tries to bond with the moon taking into account the greater attraction of the Sun. The result is an elliptical orbit by the moon, rather than a circular orbit. | ||
| The Moon, locked into attraction, continues to "fall in" on the Earth at a 90 degree angle, never to have its wish as the Earth is trying to do exactly the same thing (to a lesser degree). | ||
| 6.16.3 | The forgotten orbit | |
| Talking about the Earth orbiting the Moon may sound a bit like returning to the days of middle age astronomy. But it is this very 2nd orbit, that is missed so often in science. Simply, if the Earth did no shift to attempt to bond with the moon, then the result would be collision rather than orbit. | ||
| 6.16.4 | Orbits as pairs | |
| When we look at two objects - one large and one small, we are able to identify the smaller ones behaviour in motion relatively easily. We see the smaller object orbiting the larger object. However, the larger object unless in the same aggregate kinesis to bond, will orbit around the smaller object as well, only in a large orbit. | ||
| 6.16.5 | Rules of orbit | |
| These are the following rules of orbit, on which all particles bond. | ||
| (1) Only particles with same spin configuration can bond at a ratio of 1:1. | ||
| (2) Only particles with spin configuration of at least 2:1 or above can form strong orbits, where large objects orbit = 0 | ||
| (3) Only particles with spin configurations of at least greater than 1 to 1 can form weak orbits, where large objects orbit is larger than the smaller objects orbit. | ||
| 6.16.6 | Different orbit paths for destructive attractors and creators | |
| Most importantly, when we consider the nature of orbit being a result of the individual nature of objects, we see that different orbit paths and angles must necessarily exist for combinations of destructive attractors as well as creators. | ||
| In the next chapter (7- Atomic particles), this understanding will be critically important in understanding how smaller particles combine to form 3-dimensional atomic shapes, and the particular orbit angles of certain objects. | ||
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