This is one of the original and fascinating applications of the theory of relativity developed by the physicist Albert Einstein
Alluvial container, Galileo
Relativistic systems, in which objects move at speeds close to the speed of light, exist in many different areas of physics, and especially in particle physics. In such systems it is necessary to refer to the special theory of relativity, which describes how factors such as time, space, mass and more will change from the point of view of the moving body. When performing calculations dealing with relative systems, the calculations can be simplified by switching to a more convenient reference system; For example, a collision of two particles may become simpler for human perception (and mathematical calculations) if it is described from the point of view of one of the colliding particles, rather than from the point of view of a stationary observer observing the collision from the side.
Such transitions between reference systems are acceptable and legitimate according to the theory of special relativity, and are carried out by a simple mathematical transformation known as the Lorentz transformation. Using the Lorentz transformation, the process can be described from any reference system moving at a constant speed, and the results can be translated to any other reference system. No information concerning the process is lost when moving from one frame of reference to another, and thus the process can be described from the point of view of one of the colliding particles, then "translate" the information using the Lorentz transformation and know how the process will also look to the eyes of the stationary observer.
When the analysis of relational processes is carried out by a computer, there is a special problem. When a computer analyzes a process numerically, it must divide the longest relevant length (e.g., the length of the track in the particle accelerator) into the shortest relevant segments (e.g., the length of the particle pulse fired in the accelerator), and perform the calculation as it progresses through each move in one segment. However, at relative speeds a difficulty arises due to a phenomenon known as "length contraction": observers moving at different speeds see the same segment as having a different length. A meter rod, as it appears in the laboratory, will appear shorter to an observer passing by at a relative speed, and as the speed increases, so will the difference in the perception of length. Because of the relative changes in the perception of length, different particles in the system may perceive the distances in the system as very different. Therefore, the ratio between the largest length relevant for the purpose of the calculation and the smallest length may be enormous, and running computer simulations of relativistic processes requires a lot of time.
Physicist Jean-Luc Vay (Vay), a researcher at the Accelerator Laboratory in Berkeley, found a simple but brilliant way to reduce the time needed for simulations of relativistic systems: one must calculate and find the reference system from which the ratio between the largest and the smallest length will be reduced. This way, the computer will have to work for a shorter time, since it analyzes a smaller overall length, and divides it into longer segments. Moreover, such a transition sometimes makes it possible to use mathematical approximations, which assume that the system is simpler than it is without detracting significantly from the accuracy of the physical description. Wei used this method for his work, and assumed that scientists all over the world were doing the same, but he was surprised to find that even though the theory of special relativity and the Lorentz transformation have been known to science for over a hundred years, no one had yet applied them in this way. Wei published several examples of calculations summarized in this way; In one of the examples, the calculation time was a thousand times shorter when a more suitable reference system was chosen for it. Scientists were surprised to hear about the simple and effective method, since the calculation time is considered an indication of the complexity of the system, and it is clear that the complexity of the system does not change when moving between reference systems.
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In my opinion, writing on scientific topics must excel in precision of expression. Punctuality is especially important in writing popular science, because then it also appeals, and perhaps mainly, to laypeople whose knowledge of scientific subjects is deficient and perhaps also somewhat questionable. In this regard, I have two comments:
1. The changing factors mentioned at the beginning of the article - time, space and mass - will not change from the point of view of the moving body but from the point of view of the observer in relation to whom it is moving.
2. The wording of the following sentence (which appears near the end of the article) is incorrect: "One must calculate and find what is the reference system from the point of view of which the ratio between the largest length and the smallest will be reduced." I assume that there are more than one system in which this ratio is reduced, and probably (I'm not sure) it means the system in which this ratio is reduced to the greatest extent (in order to achieve the maximum saving of computer time).
Response to the point The unknown rotates at a speed of approximately 1700 km/h and humans are the most advanced in the history of this world from an evolutionary point of view, so you don't need 3d software to understand that software for understanding the world is in every person because from an evolutionary point of view it is the most advanced in the world, so my friend examined the world from the point of view your world
You will learn and read books on the subject as long as you like and massage it!
Is there any 3D software that simulates what the world looks like at high speeds? which also takes into account the final speeds of the light rays we see when we look at the world.