Time
Time is the perception of the interaction of overlapping energy in the space of the cosmic tetrahedron.
This phenomenon plays an important and irreplaceable role in this space.
If we consider the related phenomenon of mass, particularly Einstein's theory of relativity, we observe the dependence of a body's mass change on its speed. According to this theory, a massive body moving at the speed of light would have infinite mass. This would imply that, for example, Earth would be bombarded by particles, such as neutrinos, with infinite mass.
Science has cleverly avoided this problem by labeling neutrinos as particles with zero mass. However, this leaves unresolved the question of the result of multiplying zero by infinity.
This situation would disturb the balance between matter and energy in the Universe, as also implied by Einstein's theory of relativity. And this is where the irreplaceable role of time comes into play.
Note: If we imagine that any material object is moving at the speed of light, this object would have a mass greater than the mass of the Universe, meaning an infinite mass. This would not only conflict with engineering principles, where infinity is an empty concept, but also with several fundamental laws of nature.
For example, if the Universe had infinite mass, then every point within it would have to have infinite gravity. Particles of matter, such as gravitons, quarks, or neutrinos (regardless of what we call them), which move at the speed of light, would then have to have infinite mass because they would be light itself. This would be entirely impossible in engineering disciplines.
One cannot even imagine the consequences if myriad particles of matter, each with infinite mass, were constantly impacting us.
Some scientific hypotheses in contemporary science avoid these problems by asserting that a material body (according to current definitions) cannot reach the speed of light. This is true under the assumption that their current understanding of the nature of matter holds.
Before Albert Einstein derived his theory of relativity (which we will call FCE Einst.), physicist Hendrik Lorentz derived the so-called Lorentz time transformation (which we will call FCE Lor.) by measuring the speed of light.
The derivation of the Lorentz time transformation is described in various physics textbooks and can be derived similarly to the chapter on mass, where we discussed assessing the mass of a body moving within the cosmic tetrahedron.
It is clear that if a certain law existed that violated the equilibrium in the Universe, it would have serious consequences.
Albert Einstein noticed this problem and concluded that if such a law were valid, then the theory of relativity should also be in effect, describing how the mass of a body changes with its speed. This theory is now generally accepted as correct, although it is interpreted in various ways and some may find it difficult to understand.
In reciprocal physics, however, we do not focus on relative motion. Instead, we concentrate on the speed of a body in the space we call the Cosmic Tetrahedron, where all events take place. This approach allows us to understand various aspects and possibilities of how this speed and space can interact with each other.
For illustration, consider the case where the mass of a body changes with its speed in space. This phenomenon can be described by the formula:
m = mo.FCE Einst. x FCE Lor. = mo
Where m is the mass of the body at a certain speed, mo is the mass of the body at rest, FCE Einst. refers to Einstein's theory of relativity, and FCE Lor. relates to Lorentz's transformation. This formula indicates that at any speed of the body in space, the mass mo, which is the rest mass, remains valid.
Note that Einstein's formula for the theory of relativity does not include time, and Lorentz's time transformation does not include mass. Each of these theories contains only a part of the actual laws. Using only part of the formula can lead to incorrect and often absurd conclusions, which appear in the realm of science fiction and some scientific theories.
Without the discovery of Lorentz's time transformation, even the current understanding of the universe would encounter unexplained excesses of mass, as any velocity of a body according to contemporary science increases its mass. By not acknowledging that Einstein's theory of relativity is just a part of a broader formula from the chapter on mass, one can reach bizarre conclusions that appear in speculative literature, which is often mistakenly presented as scientific.
Recap of the mentioned formula from the chapter on mass:
Changes in the phenomenon of mass during motion
When a body is set in motion at velocity "v" from point "B" towards point "A," changes occur in the phenomenon of mass as described in the figure. The essence of this change is the difference in the energy's response to the body in different directions of motion.
The energy response opposite to the direction of motion is higher, while the response in the direction of motion is lower. In Reciprocal physics, which functions as an engineering system, it is inconceivable that velocity alone alters the phenomenon of mass in the way current science assumes.
From the Lorentz transformation of time, it follows that time is independent of the existence of bodies. However, bodies are the only substance of energy in the Universe capable of perceiving and evaluating the phenomenon of time. Where there is no motion of energy, the phenomenon of time does not arise.