We propose a new thermodynamic, relativistic relationship between information
and entropy, which is closely analogous to the classic Maxwell electro-magnetic
equations. Determination of whether information resides in points of
non-analyticity or is more distributed in nature therefore relates directly to
the well-known wave-particle duality of light. At cosmological scales our
vector differential equations predict conservation of information in black
holes, whereas regular and Z-DNA correspond to helical solutions at microscopic
levels. We further propose that regular and Z-DNA are equivalent to the
alternative words chosen from an alphabet to maintain the equilibrium of an
information transmission system.
%0 Generic
%1 citeulike:1455923
%A Parker, Michael C.
%A Walker, Stuart D.
%D 2004
%K entropy information
%T A Dynamic Theory of Information and Entropy
%U http://arxiv.org/abs/physics/0405027v1
%X We propose a new thermodynamic, relativistic relationship between information
and entropy, which is closely analogous to the classic Maxwell electro-magnetic
equations. Determination of whether information resides in points of
non-analyticity or is more distributed in nature therefore relates directly to
the well-known wave-particle duality of light. At cosmological scales our
vector differential equations predict conservation of information in black
holes, whereas regular and Z-DNA correspond to helical solutions at microscopic
levels. We further propose that regular and Z-DNA are equivalent to the
alternative words chosen from an alphabet to maintain the equilibrium of an
information transmission system.
@misc{citeulike:1455923,
abstract = {We propose a new thermodynamic, relativistic relationship between information
and entropy, which is closely analogous to the classic Maxwell electro-magnetic
equations. Determination of whether information resides in points of
non-analyticity or is more distributed in nature therefore relates directly to
the well-known wave-particle duality of light. At cosmological scales our
vector differential equations predict conservation of information in black
holes, whereas regular and Z-DNA correspond to helical solutions at microscopic
levels. We further propose that regular and Z-DNA are equivalent to the
alternative words chosen from an alphabet to maintain the equilibrium of an
information transmission system.},
added-at = {2007-08-18T13:22:24.000+0200},
author = {Parker, Michael C. and Walker, Stuart D.},
biburl = {https://www.bibsonomy.org/bibtex/282d8deb997781beb9c53c8f0cd6c67fa/a_olympia},
citeulike-article-id = {1455923},
description = {citeulike},
eprint = {physics/0405027v1},
interhash = {ea804446b5fa429b31d683000ac144d8},
intrahash = {82d8deb997781beb9c53c8f0cd6c67fa},
keywords = {entropy information},
month = May,
priority = {2},
timestamp = {2007-08-18T13:22:25.000+0200},
title = {A Dynamic Theory of Information and Entropy},
url = {http://arxiv.org/abs/physics/0405027v1},
year = 2004
}