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==Abstract==
==Abstract==


'''Summary: '''Beckmann makes the case that light speed is constant with respect to the gravitational field. His model, however, does not specify how the speed varies with such things as the mass of the locally dominant body and its distance from the point of interest. In the present paper, we derive the result from the conservation of energy, and use it to predict the reflection of starlight. The results agree with those of General Relativity Theory, and more importantly with measurement.[[Category:Scientific Paper]]
'''Summary: '''Beckmann makes the case that light speed is constant with respect to the gravitational field. His model, however, does not specify how the speed varies with such things as the mass of the locally dominant body and its distance from the point of interest. In the present paper, we derive the result from the conservation of energy, and use it to predict the reflection of starlight. The results agree with those of General Relativity Theory, and more importantly with measurement.
 
[[Category:Scientific Paper|light speed function gravitational potential]]


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

Revision as of 13:38, 1 January 2017

Scientific Paper
TitleLight Speed as a Function of Gravitational Potential
Author(s)Howard C Hayden
Keywordslight speed, gravitational potential, GRT, mass, distance, point of interest, atarlight
Published1990
JournalGalilean Electrodynamics
Volume1
Number2
Pages15-17

Abstract

Summary: Beckmann makes the case that light speed is constant with respect to the gravitational field. His model, however, does not specify how the speed varies with such things as the mass of the locally dominant body and its distance from the point of interest. In the present paper, we derive the result from the conservation of energy, and use it to predict the reflection of starlight. The results agree with those of General Relativity Theory, and more importantly with measurement.