Fractal Physiology [electronic resource] /

Fractal Physiology [electronic resource] /

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This volume delineates the use of fractal patterns and measures of fractal dimensions in describing and understanding general aspects of biology, particularly human physiology. After describing the ubiquitous nature of fractal phenomena, the authors give examples of the properties of fractals in space and time. Proceeding from mathematical definitions, they develop detailed practical methods for assessing the fractal characteristics of wave forms varying with time, tissue density variation, and surface irregularities. Most importantly, the authors show how fractal variation defines internal spatial or temporal correlations within the fractal system or object. Simple, recursively applied rules can give rise to complex biological structures by a variety of methods. This suggests that genetic rules govern the general structuring of an organism, while rules implied by interactions at the biochemical, cellular, and tissue levels govern ontogenic development and therefore play the major role in the growth of an organism. Chaos, or non-linear dynamics, is introduced as a stimulating way to examine biological behavior at the cellular and whole animal levels, even though proof of the chaotic nature of normal physiologic events is as yet meager. The later chapters give sets of examples of structural and behavioral fractal phenomena in nerve and muscle, in the cardiovascular and respiratory systems and in growth processes. Why molecular interactions and complex systems give rise to fractals is explored and related to the ideas of emergent properties of systems operating at high levels of complexity.

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Main Authors: Bassingthwaighte, James B. author., Liebovitch, Larry S. author., West, Bruce J. author., SpringerLink (Online service)
Format: Texto biblioteca
Language:eng
Published: New York, NY : Springer New York : Imprint: Springer, 1994
Subjects:Medicine., Human physiology., Biomedicine., Human Physiology.,
Online Access:http://dx.doi.org/10.1007/978-1-4614-7572-9
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id KOHA-OAI-TEST:193158
record_format koha
institution COLPOS
collection Koha
country México
countrycode MX
component Bibliográfico
access En linea
En linea
databasecode cat-colpos
tag biblioteca
region America del Norte
libraryname Departamento de documentación y biblioteca de COLPOS
language eng
topic Medicine.
Human physiology.
Biomedicine.
Human Physiology.
Medicine.
Human physiology.
Biomedicine.
Human Physiology.
spellingShingle Medicine.
Human physiology.
Biomedicine.
Human Physiology.
Medicine.
Human physiology.
Biomedicine.
Human Physiology.
Bassingthwaighte, James B. author.
Liebovitch, Larry S. author.
West, Bruce J. author.
SpringerLink (Online service)
Fractal Physiology [electronic resource] /
description This volume delineates the use of fractal patterns and measures of fractal dimensions in describing and understanding general aspects of biology, particularly human physiology. After describing the ubiquitous nature of fractal phenomena, the authors give examples of the properties of fractals in space and time. Proceeding from mathematical definitions, they develop detailed practical methods for assessing the fractal characteristics of wave forms varying with time, tissue density variation, and surface irregularities. Most importantly, the authors show how fractal variation defines internal spatial or temporal correlations within the fractal system or object. Simple, recursively applied rules can give rise to complex biological structures by a variety of methods. This suggests that genetic rules govern the general structuring of an organism, while rules implied by interactions at the biochemical, cellular, and tissue levels govern ontogenic development and therefore play the major role in the growth of an organism. Chaos, or non-linear dynamics, is introduced as a stimulating way to examine biological behavior at the cellular and whole animal levels, even though proof of the chaotic nature of normal physiologic events is as yet meager. The later chapters give sets of examples of structural and behavioral fractal phenomena in nerve and muscle, in the cardiovascular and respiratory systems and in growth processes. Why molecular interactions and complex systems give rise to fractals is explored and related to the ideas of emergent properties of systems operating at high levels of complexity.
format Texto
topic_facet Medicine.
Human physiology.
Biomedicine.
Human Physiology.
author Bassingthwaighte, James B. author.
Liebovitch, Larry S. author.
West, Bruce J. author.
SpringerLink (Online service)
author_facet Bassingthwaighte, James B. author.
Liebovitch, Larry S. author.
West, Bruce J. author.
SpringerLink (Online service)
author_sort Bassingthwaighte, James B. author.
title Fractal Physiology [electronic resource] /
title_short Fractal Physiology [electronic resource] /
title_full Fractal Physiology [electronic resource] /
title_fullStr Fractal Physiology [electronic resource] /
title_full_unstemmed Fractal Physiology [electronic resource] /
title_sort fractal physiology [electronic resource] /
publisher New York, NY : Springer New York : Imprint: Springer,
publishDate 1994
url http://dx.doi.org/10.1007/978-1-4614-7572-9
work_keys_str_mv AT bassingthwaightejamesbauthor fractalphysiologyelectronicresource
AT liebovitchlarrysauthor fractalphysiologyelectronicresource
AT westbrucejauthor fractalphysiologyelectronicresource
AT springerlinkonlineservice fractalphysiologyelectronicresource
_version_ 1756266430332928000
spelling KOHA-OAI-TEST:1931582018-07-30T23:17:54ZFractal Physiology [electronic resource] / Bassingthwaighte, James B. author. Liebovitch, Larry S. author. West, Bruce J. author. SpringerLink (Online service) textNew York, NY : Springer New York : Imprint: Springer,1994.engThis volume delineates the use of fractal patterns and measures of fractal dimensions in describing and understanding general aspects of biology, particularly human physiology. After describing the ubiquitous nature of fractal phenomena, the authors give examples of the properties of fractals in space and time. Proceeding from mathematical definitions, they develop detailed practical methods for assessing the fractal characteristics of wave forms varying with time, tissue density variation, and surface irregularities. Most importantly, the authors show how fractal variation defines internal spatial or temporal correlations within the fractal system or object. Simple, recursively applied rules can give rise to complex biological structures by a variety of methods. This suggests that genetic rules govern the general structuring of an organism, while rules implied by interactions at the biochemical, cellular, and tissue levels govern ontogenic development and therefore play the major role in the growth of an organism. Chaos, or non-linear dynamics, is introduced as a stimulating way to examine biological behavior at the cellular and whole animal levels, even though proof of the chaotic nature of normal physiologic events is as yet meager. The later chapters give sets of examples of structural and behavioral fractal phenomena in nerve and muscle, in the cardiovascular and respiratory systems and in growth processes. Why molecular interactions and complex systems give rise to fractals is explored and related to the ideas of emergent properties of systems operating at high levels of complexity.I Overview -- 1. Introduction: Fractals Really Are Everywhere -- II Properties of Fractals and Chaos -- 2. Properties of Fractal Phenomena in Space and Time -- 3. The Fractal Dimension: Self-Similar and Self-Affine Scaling -- 4. Fractal Measures of Heterogeneity and Correlation -- 5. Generating Fractals -- 6. Properties of Chaotic Phenomena -- 7. From Time to Topology: Is a Process Driven by Chance or Necessity? -- III Physiological Applications -- 8. Ion Channel Kinetics: A Fractal Time Sequence of Conformational States -- 9. Fractals in Nerve and Muscle -- 10. Intraorgan Flow Heterogeneities -- 11. Fractal Growth -- 12. Mechanisms That Produce Fractals -- 13. Chaos? in Physiological Systems -- Works Cited.This volume delineates the use of fractal patterns and measures of fractal dimensions in describing and understanding general aspects of biology, particularly human physiology. After describing the ubiquitous nature of fractal phenomena, the authors give examples of the properties of fractals in space and time. Proceeding from mathematical definitions, they develop detailed practical methods for assessing the fractal characteristics of wave forms varying with time, tissue density variation, and surface irregularities. Most importantly, the authors show how fractal variation defines internal spatial or temporal correlations within the fractal system or object. Simple, recursively applied rules can give rise to complex biological structures by a variety of methods. This suggests that genetic rules govern the general structuring of an organism, while rules implied by interactions at the biochemical, cellular, and tissue levels govern ontogenic development and therefore play the major role in the growth of an organism. Chaos, or non-linear dynamics, is introduced as a stimulating way to examine biological behavior at the cellular and whole animal levels, even though proof of the chaotic nature of normal physiologic events is as yet meager. The later chapters give sets of examples of structural and behavioral fractal phenomena in nerve and muscle, in the cardiovascular and respiratory systems and in growth processes. Why molecular interactions and complex systems give rise to fractals is explored and related to the ideas of emergent properties of systems operating at high levels of complexity.Medicine.Human physiology.Biomedicine.Human Physiology.Springer eBookshttp://dx.doi.org/10.1007/978-1-4614-7572-9URN:ISBN:9781461475729

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