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In the model of Complete and Incomplete Coordinate Systems, there is no upper limit on the velocity of a moving coordinate system. In order to explain why this is the case, we have to first understand the reasons behind the belief that Einstein’s equation limit velocity. Einstein presents his final equations as:

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There are several similarities and differences between the models established by Einstein, Newton, and Bryant. The following table illustrates some of the differences for each with respect to their Fixed Point, Wave Front, and One-Half Oscillation equations.

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In the model of Complete and Incomplete Coordinate Systems, length contraction does not occur.

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In order to understand why the twin paradox goes away, I first have to highlight a point of confusion with Einstein’s transformation equations. In the model of Complete and Incomplete Coordinate Systems, there are four time equations; one for the time to travel along each of the 3 axes, and one for the amount of time that the coordinate system has been in motion.

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In the model of Complete and Incomplete Coordinate Systems, the velocity of the wave is represented by the value w. This variable can take on any value to represent the velocity of wave and medium under consideration. For example, when considering light waves traveling through a vacuum, we replace w with the value 299,792,458 meters per second, or by convention c. When considering light through air, its velocity decreases with increased density. In this case, we would first compute the new velocity and replace w with that value.

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In the model of Complete and Incomplete Coordinate Systems, the behavior of the phenomena is determined by the characteristics of the coordinate systems.

Consider three different types of coordinate system “spaces”;

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