General Gravity in the Transversal Physics
Mathematica Moravica, Tome 17 (2013) no. 2.

Voir la notice de l'article dans eLibrary of Mathematical Institute of the Serbian Academy of Sciences and Arts

From the abstract mathematical point of view, modern new transversal physics is based on transversal sets theory. In this sense, we shall show that the translation and rotation plays an important role in modern new physics. A first culminating point was the discovery of the laws of planetary motions by the Prague astronomer and mathematician Johannes Kepler (1571-1639) during the years from 1609 to 1619. Newton based his work on Kepler’s results and G a l i l e i ’ s (1564-1642) observation that all bodies fall at the same rate, i.e., receive a constant acceleration. Already in 1802 Newton’s theory of gravity was a great triumph. One year earlier Piazzi, in Palermo, discovered the planetoid Ceres as a star of magnitude eight and was able to follow its orbit for 9 degrees before losing it. The young Gauss (1777-1855) then computed the entire orbit by employing new methods of the calculus of observations; and using this result, Olbers rediscovered Ceres in 1802. Today we know that the motion of the perihelion cannot be explained with Newton’s theory of gravity, but is a consequence of the general theory of relativity, which was developed by Einstein in 1915. From this theory the above value follows very accurately. In this sense I give an affirmative answer that velocities bigger than the velocity of light c by Nikola Tesla in 1932 - exist. In the preceding sense I based the general transversal gravity theory on a new transversal min-max theory which I give in the last part of the paper. First fact of Transversal Physics: There exist in some spaces of physics some velocities which are bigger of the velocity of the light c. Main facts of transversal physics are gravitational uneven functions and equations of the general transversal gravity.
Mots-clés : Gravity, general gravity, Kepler’s results, Newton’s theory of gravity, Einstein’s equations, results by Nikola Tesla, forms of the second Kepler’s law (on the sides of the space), gravity in the general convex (concave) algebra, gravity in the middle algebra, n-body problem, basic uneven equations of the transversal physics, Nonlinear relativistic physics 
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Milan Tasković. General Gravity in the Transversal Physics. Mathematica Moravica, Tome 17 (2013) no. 2. https://geodesic-test.mathdoc.fr/item/MM3_2013_17_2_a7/