A Stocastic Explination of Newtonas Law and Coulombsa Law

A Stocastic Explination of Newtonas Law and Coulombsa Law

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John Laurence Haller Jr.

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A Stocastic Explination of Newtonas Law and Coulombsa Law

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Abstract

Assuming that a particle follows the discrete Bernoulli process with a step size proportional to one over twice its mass and that the vacuum is made up of particles with the reduced Planck mass, one can derive both Newton’s Law of Gravitation and Coulomb’s Law of Electric Force using slightly different parameters of the process. Two classes of experiments, which could affirm the hypothesis, would indicate a preferred reference frame.

References

13 Cites in Article

Reference Format

J Haller (2014). Measuring a Quantum System's Classical Information.
J Haller (2013). Dark Particles Answer Dark Energy.
S Chandrasekhar (1943). Stochastic Problems in Physics and Astronomy.
Reif (1965). Fundamentals of Statistical and Thermal Physics.
R Kubo (1966). The fluctuation-dissipation theorem.
J Haller (2013). Entropy Rate of Thermal Diffusion.
Edward Nelson (1966). Derivation of the Schrödinger Equation from Newtonian Mechanics.
P Dirac (1958). The Principles of Quantum Mechanics.
Ronald Bracewell (1986). The Fourier Transform and Its Applications 2nd.
R Feynman (1965). Lectures on Physics.
H Lorentz (1916). The theory of electrons and tis application to the phenomena of light and radiant heat.
T Cover,J Thomas (1991). Elements of Information Theory.
A Einstein (1953). The Meaning of Relativity.

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Funding

No external funding was declared for this work.

Conflict of Interest

The authors declare no conflict of interest.

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No ethics committee approval was required for this article type.

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How to Cite This Article

John Laurence Haller Jr.. 2014. \u201cA Stocastic Explination of Newtonas Law and Coulombsa Law\u201d. Global Journal of Science Frontier Research - A: Physics & Space Science GJSFR-A Volume 14 (GJSFR Volume 14 Issue A2): .

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GJSFR Volume 14 Issue A2
Pg. 43- 47

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Journal Specifications

Crossref Journal DOI 10.17406/GJSFR

Print ISSN 0975-5896

e-ISSN 2249-4626

Keywords

bernoulli process black hole dark particle diffusion discrete space discrete time discrete vacuum quantum gravity stochastic process

Submission ReceivedApril 3, 2014
Peer Review Double Blind
Handling Editor
Accepted May 1, 2014
Published May 16, 2014

Version of record

v1.2

Issue date

July 6, 2014

Language

en

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Article Matrices

Total Score: 131

Country: United States

Subject: Global Journal of Science Frontier Research - A: Physics & Space Science

Authors: John Laurence Haller Jr. (PhD/Dr. count: 0)

View Count (all-time): 154

Total Views (Real + Logic): 4478

Total Downloads (simulated): 2277

Publish Date: 2014 07, Sun

Monthly Totals (Real + Logic):

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Total Views: 4478

Total Downloads: 2277

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Published Article

Assuming that a particle follows the discrete Bernoulli process with a step size proportional to one over twice its mass and that the vacuum is made up of particles with the reduced Planck mass, one can derive both Newton’s Law of Gravitation and Coulomb’s Law of Electric Force using slightly different parameters of the process. Two classes of experiments, which could affirm the hypothesis, would indicate a preferred reference frame.

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