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A greater explanation on the concept of motion of particles |
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In Chapter 5, we explained a number of vitally important understandings in relation to the behaviour and structure of matter principally centered around the concept of motion ( particles or points of UCA changing from one position to another). | |
| (1) | For a Unita to exist, 6 points of UCA (plus anchors) must be in perpetual motion. | |
| (2) | The maximum rate of change of position (motion) of a point of UCA is 1. No point of UCA can travel faster than its maximum rate of change and/or interaction. For a Unita, this means a maximum rate of motion of 1/2 x 8. | |
| (3) | There is a direct relationship between the distance between particles and their relative velocities and kinesis ( spin rates). When particles are far away, kinesis rates are their lowest and velocity is at its highest. When particles are close, their kinesis levels are highest and velocities are lowest. | |
| (4) | The presence of other Unita will always influence a particular Unita in some kind of motion. | |
| (5) | As direction and velocities of Unita change, this affects the balance of attraction and repulsion on other Unita also causing them to change position (motion with direction). | |
| (6) | The result of all these rules is that all particles in the Universe are in constant motion and changing velocities, spin rates and direction | |
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| 6.7.1 | The importance of understanding motion | |
| The profound importance of understanding motion is what we have just stated is that all matter in the Universe ( not matter how complex) is essentially made up of different sized particle groups in motion. | ||
| Combined motion is what keeps them together ( as discussed later in this chapter under the Concept of Orbits). And it is kinesis rates( spin rates) that can break those combined motions. | ||
| From now on, when we look at a nuclear explosion or a laser beam cutting through skin or a human body digesting proteins, we can see that the breaking of form unleashes smaller particles with higher kinesis rates (lower rates of motion initially) that in turn can set off a chain reaction- a chain reaction of motion. | ||
| We therefore have a powerful set of understandings from which to investigate the specific behaviour of particles in the following chapters and understand exactly why certain reactions occur in matter and how. | ||
| 6.7.2 | The strength of classification in locking down meanings | |
| As we stated in the previous chapter, Kinesis is the measurement of levels of vibration/spin of a particular form by its density to establish its ability to influence other larger forms of matter (the forces of attraction and repulsion). The higher the Kinesis, the greater the influence over larger and larger forms. | ||
| The point to remember about spin rates is that they are weakened by orbits and cancelled out by the proportion of different spin by destructive attractors. Therefore, very few structures at the sub-atomic and atomic level have very high kinesis, even when they are made up of ten or more particles. | ||
| Relative Potential Kinesis (potential to move other objects) = density of the relative form of an object by the relative maximum frequency rate of the same level of particles minus the current frequency rate of those same particles. | ||
| Relative Maximum Kinesis ( maximum ability to move other objects) of an object = density of the relative form of an object by the relative maximum rate of vibration/spin of the same level of particles. | ||
| Relative Minimum Kinesis ( minimum ability to move other objects) of an object = density of the relative form of an object by the relative minimum rate of vibration/spin of the same level of particles. | ||
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