Post by Pincho Paxton on Aug 22, 2020 7:33:30 GMT
What is a gravity node?
The Universe is built like a spherical stacking system. In spherical stacking systems of the same sized sphere you can get 6 sphere around 1 sphere which creates an hexagon, you call that a kissing number. Space is divided up in such a way that kissing numbers are nodes for gravity to collide. Nature takes advantage of those nodes. From a structure like that you get fractals.
But the Universe isn't exactly a spherical stacking system, it is a toroidal stacking system where each torus can rotate around a point which creates a spherical stacking system... with poles. And each torus isn't exactly a torus, it's a spin around a negative mass holes. And the hole isn't exactly a hole it is where gravity rebounds from a central point. And the rebound isn't always a rebound, sometimes gravity escapes through the hole to create a tube leading up towards another hole.
From all of that you get gravity nodes that create intricate fractals. But an important thing about those nodes is that they will feed that point in space. So if you can capture gravity nodes, then you can capture energy. Which means to arrange a structure in a certain way will take advantage of certain gravity nodes.
A simple example is a queen bee. Bees arrange their hives taking advantage of a hexagonal stacking system. Some of those hexagonal channels will find a gravity node, and so one of the bees will take advantage of that extra energy.
1/ A queen bee is the evolution of gravity nodes.
2/ The hairs on our body
3/ A pattern of trees
4/ Tree Branches
5/ Grass
OK so the arrangement of plant life we see as capturing light from the canopy, but the actual hidden physics are that light is using the rotational torus holes, and atoms are built from gravity collisions. So the physics still match trees finding light by spacing out their canopy.
6/ Galaxies along the pathway of filaments.
7/ Stars
8/ Planets
You can break these down into the physics of gravity nodes as well... steering gravity towards collisions in a fractal landscape.
Pincho Paxton
The Universe is built like a spherical stacking system. In spherical stacking systems of the same sized sphere you can get 6 sphere around 1 sphere which creates an hexagon, you call that a kissing number. Space is divided up in such a way that kissing numbers are nodes for gravity to collide. Nature takes advantage of those nodes. From a structure like that you get fractals.
But the Universe isn't exactly a spherical stacking system, it is a toroidal stacking system where each torus can rotate around a point which creates a spherical stacking system... with poles. And each torus isn't exactly a torus, it's a spin around a negative mass holes. And the hole isn't exactly a hole it is where gravity rebounds from a central point. And the rebound isn't always a rebound, sometimes gravity escapes through the hole to create a tube leading up towards another hole.
From all of that you get gravity nodes that create intricate fractals. But an important thing about those nodes is that they will feed that point in space. So if you can capture gravity nodes, then you can capture energy. Which means to arrange a structure in a certain way will take advantage of certain gravity nodes.
A simple example is a queen bee. Bees arrange their hives taking advantage of a hexagonal stacking system. Some of those hexagonal channels will find a gravity node, and so one of the bees will take advantage of that extra energy.
1/ A queen bee is the evolution of gravity nodes.
2/ The hairs on our body
3/ A pattern of trees
4/ Tree Branches
5/ Grass
OK so the arrangement of plant life we see as capturing light from the canopy, but the actual hidden physics are that light is using the rotational torus holes, and atoms are built from gravity collisions. So the physics still match trees finding light by spacing out their canopy.
6/ Galaxies along the pathway of filaments.
7/ Stars
8/ Planets
You can break these down into the physics of gravity nodes as well... steering gravity towards collisions in a fractal landscape.
Pincho Paxton