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Advances in Unconventional ComputingThe Ideal Energy of Classical Lattice Dynamics

Advances in Unconventional Computing: The Ideal Energy of Classical Lattice Dynamics [We define, as local quantities, the least energy and momentum allowed by quantum mechanics and special relativity for physical realizations of some classical lattice dynamics. These definitions depend on local rates of finite-state change. In two example dynamics, we see that these rates evolve like classical mechanical energy and momentum.] http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png

Advances in Unconventional ComputingThe Ideal Energy of Classical Lattice Dynamics

Part of the Emergence, Complexity and Computation Book Series (volume 22)
Editors: Adamatzky, Andrew
Margolus, Norman
Advances in Unconventional Computing — Jul 19, 2016
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12 pages

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Publisher
Springer International Publishing
Copyright
© Springer International Publishing Switzerland 2017
ISBN
978-3-319-33923-8
Pages
59 –71
DOI
10.1007/978-3-319-33924-5_3
Publisher site
See Chapter on Publisher Site

Abstract

[We define, as local quantities, the least energy and momentum allowed by quantum mechanics and special relativity for physical realizations of some classical lattice dynamics. These definitions depend on local rates of finite-state change. In two example dynamics, we see that these rates evolve like classical mechanical energy and momentum.]

Published: Jul 19, 2016

Keywords: Cellular Automaton; Ideal Energy; Cellular Automaton Model; Integer Time; Classical Mechanical System

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