Quantum Relativity Theory

The Euclidean geometry was developed as a mathematical system due to generalizing thousands years of measurements on the plane and spherical surfaces. The development of celestial mechanics and stellar astronomy confirmed its validity as mathematical principles of natural philosophy, in particular for studying the Solar System bodies’ and Galaxy stars motions. In the non-Euclidean geometries by Lobachevsky and Riemann, the third axiom of modern geometry manuals is substituted. We show that the third axiom of these manuals is a corollary of the Fifth Euclidean postulate. The idea of spherical, Riemannian space of the Universe and local curvatures of space, depending on body mass, was inculcated into celestial mechanics, astronomy and geodesy along with the theory of relativity. The mathematical apparatus of the relativity theory was created from immeasurable quantities

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Lost Time

10.1093/oso/9780198797302.003.0002 ◽

2017 ◽

Author(s):

Craig Callender

Keyword(s):

Relativity Theory ◽

Lost Time

None of our physical theories have ever employed a distinguished present. Until relativity theory, however, it was always easy to imagine taking some structure, treating it as the present, and then “animating” it so it flows. This chapter shows that buried within relativity there isn’t structure suitable for “animation” á la manifest time; there are not good relativistic candidates for a flowing now. An informal dilemma seems to hold: the better a structure represents manifest time, the “less” relativistic it is; the “more” relativistic it is, the worse it represents manifest time.

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The Conceptual Foundations of Contemporary Relativity Theory. J. C. Graves

Philosophy of Science ◽

10.1086/288612 ◽

1974 ◽

Vol 41 (4) ◽

pp. 431-433

Author(s):

Jeffrey Bub

Keyword(s):

Relativity Theory ◽

Conceptual Foundations

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Multifractality through Non-Markovian Stochastic Processes in the Scale Relativity Theory. Acute Arterial Occlusions as Scale Transitions

Entropy ◽

10.3390/e23040444 ◽

2021 ◽

Vol 23 (4) ◽

pp. 444

Author(s):

Nicolae Dan Tesloianu ◽

Lucian Dobreci ◽

Vlad Ghizdovat ◽

Andrei Zala ◽

Adrian Valentin Cotirlet ◽

...

Keyword(s):

Stochastic Processes ◽

Standard Form ◽

Momentum Conservation ◽

Relativity Theory ◽

Horizontal Pipe ◽

Scale Transition ◽

Theory Of Motion ◽

Multifractal Theory ◽

Scale Relativity ◽

Specific Momentum

By assimilating biological systems, both structural and functional, into multifractal objects, their behavior can be described in the framework of the scale relativity theory, in any of its forms (standard form in Nottale’s sense and/or the form of the multifractal theory of motion). By operating in the context of the multifractal theory of motion, based on multifractalization through non-Markovian stochastic processes, the main results of Nottale’s theory can be generalized (specific momentum conservation laws, both at differentiable and non-differentiable resolution scales, specific momentum conservation law associated with the differentiable–non-differentiable scale transition, etc.). In such a context, all results are explicated through analyzing biological processes, such as acute arterial occlusions as scale transitions. Thus, we show through a biophysical multifractal model that the blocking of the lumen of a healthy artery can happen as a result of the “stopping effect” associated with the differentiable-non-differentiable scale transition. We consider that blood entities move on continuous but non-differentiable (multifractal) curves. We determine the biophysical parameters that characterize the blood flow as a Bingham-type rheological fluid through a normal arterial structure assimilated with a horizontal “pipe” with circular symmetry. Our model has been validated based on experimental clinical data.

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