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A Formulation of the Gravitational Equation of Motion: Difference between revisions

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==Abstract==
==Abstract==


According to Einstein's principle of equivalence, inertial forces in an accelerated reference system are equivalent to the existence of a gravitational field. In order to formulate the gravitational force as well as inertial forces in explicit form, we introduce two conditions into the 4-D line element and transformations. As a consequence, the equation of motion for gravitational force or inertial force has a form similar to the equation of Lorentz force on a charge in electrodynamics. The inertial forces in non-inertial systems are calculated for two special cases: a uniformly accelerated system, and a uniformly rotating system.[[Category:Scientific Paper]]
According to Einstein's principle of equivalence, inertial forces in an accelerated reference system are equivalent to the existence of a gravitational field. In order to formulate the gravitational force as well as inertial forces in explicit form, we introduce two conditions into the 4-D line element and transformations. As a consequence, the equation of motion for gravitational force or inertial force has a form similar to the equation of Lorentz force on a charge in electrodynamics. The inertial forces in non-inertial systems are calculated for two special cases: a uniformly accelerated system, and a uniformly rotating system.
 
[[Category:Scientific Paper|formulation gravitational equation motion]]


[[Category:Gravity]]
[[Category:Gravity]]

Revision as of 12:55, 1 January 2017

Scientific Paper
TitleA Formulation of the Gravitational Equation of Motion
Read in fullLink to paper
Author(s)T Chang
Keywordsprinciple of equivalence, inertial forces, gravitational field
Published1994
JournalApeiron
Volume1
Number20
No. of pages3
Pages32-35

Read the full paper here

Abstract

According to Einstein's principle of equivalence, inertial forces in an accelerated reference system are equivalent to the existence of a gravitational field. In order to formulate the gravitational force as well as inertial forces in explicit form, we introduce two conditions into the 4-D line element and transformations. As a consequence, the equation of motion for gravitational force or inertial force has a form similar to the equation of Lorentz force on a charge in electrodynamics. The inertial forces in non-inertial systems are calculated for two special cases: a uniformly accelerated system, and a uniformly rotating system.