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written by
Kostas Papamichalis
In this simulation, we solve the Kepler problem in the context of two theories: a) the Special Theory of Relativity and b) the Newtonian Mechanics. We simulate the motion of a particle according to the predictions of each model, for the same initial conditions. We observe and calculate the precession of the perihelion and the aphelion of the orbit for the case of the relativistic model and the closed-elliptic path in the Newtonian model. We check our calculations and the virtual measurements, by implementing several activities in the environment of the simulation.
Released under a Creative Commons Attribution-Share Alike 4.0 license.
Last Modified September 28, 2021
This simulation describes the Kepler problem in the context of two theories: a) the Special Theory of
Relativity and b) the Newtonian Mechanics. We simulate the motion of a particle according to the
predictions of each model, for the same initial conditions. We observe and calculate the precession
of the perihelion of the orbit for the case of the relativistic model and the closed-elliptic path in the
Newtonian model. We check our calculations and the virtual measurements, by implementing several
activities in the environment of the simulation.
Last Modified September 28, 2021
The EJS JavaScript source code for the Newtonian and Relativistic Kepler Problem simulation.
Last Modified September 28, 2021