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* Aerodynamic limit-cycle oscillations<ref>{{citation | last =Thomas| first =Jeffrey P.| last2 =Dowell| first2 =Earl H.| last3 =Hall| first3 =Kenneth C.| title =Nonlinear Inviscid Aerodynamic Effects on Transonic Divergence, Flutter, and Limit-Cycle Oscillations| journal =AIAA Journal| volume =40| issue =4| pages =638| publisher =American Institute of Aeronautics and Astronautics| url=https://mems.duke.edu/files/mems/thomas/downloads/hblco.pdf| access-date = December 9, 2019 | bibcode =2002AIAAJ..40..638T| year =2002| doi =10.2514/2.1720}}</ref> 空气动力学极限环振荡
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* Aerodynamic limit-cycle oscillations<ref>{{citation | last =Thomas| first =Jeffrey P.| last2 =Dowell| first2 =Earl H.| last3 =Hall| first3 =Kenneth C.| title =Nonlinear Inviscid Aerodynamic Effects on Transonic Divergence, Flutter, and Limit-Cycle Oscillations| journal =AIAA Journal| volume =40| issue =4| pages =638| publisher =American Institute of Aeronautics and Astronautics| url=https://mems.duke.edu/files/mems/thomas/downloads/hblco.pdf| access-date = December 9, 2019 | bibcode =2002AIAAJ..40..638T| year =2002| doi =10.2514/2.1720}}</ref> 空气动力学极限环振荡<ref>{{citation | last =Thomas| first =Jeffrey P.| last2 =Dowell| first2 =Earl H.| last3 =Hall| first3 =Kenneth C.| title =Nonlinear Inviscid Aerodynamic Effects on Transonic Divergence, Flutter, and Limit-Cycle Oscillations| journal =AIAA Journal| volume =40| issue =4| pages =638| publisher =American Institute of Aeronautics and Astronautics| url=https://mems.duke.edu/files/mems/thomas/downloads/hblco.pdf| access-date = December 9, 2019 | bibcode =2002AIAAJ..40..638T| year =2002| doi =10.2514/2.1720}}</ref>
    
* The [[Hodgkin–Huxley model]] for [[action potential]]s in [[neuron]]s.
 
* The [[Hodgkin–Huxley model]] for [[action potential]]s in [[neuron]]s.
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* The Sel'kov model of [[glycolysis]].<ref>{{Cite journal|last=Sel'kov|first=E. E.|date=1968|title=Self-Oscillations in Glycolysis 1. A Simple Kinetic Model|journal=European Journal of Biochemistry|language=en|volume=4|issue=1|pages=79–86|doi=10.1111/j.1432-1033.1968.tb00175.x|pmid=4230812|issn=1432-1033}}</ref>  
 
* The Sel'kov model of [[glycolysis]].<ref>{{Cite journal|last=Sel'kov|first=E. E.|date=1968|title=Self-Oscillations in Glycolysis 1. A Simple Kinetic Model|journal=European Journal of Biochemistry|language=en|volume=4|issue=1|pages=79–86|doi=10.1111/j.1432-1033.1968.tb00175.x|pmid=4230812|issn=1432-1033}}</ref>  
'''<font color="#ff8000">糖酵解 glycolysis</font>'''的塞尔科夫模型。
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'''<font color="#ff8000">糖酵解 glycolysis</font>'''的塞尔科夫模型<ref>{{Cite journal|last=Sel'kov|first=E. E.|date=1968|title=Self-Oscillations in Glycolysis 1. A Simple Kinetic Model|journal=European Journal of Biochemistry|language=en|volume=4|issue=1|pages=79–86|doi=10.1111/j.1432-1033.1968.tb00175.x|pmid=4230812|issn=1432-1033}}</ref>。
    
* The daily oscillations in gene expression, hormone levels and body temperature of animals, which are part of the [[circadian rhythm]].<ref>{{Cite journal|last=Leloup|first=Jean-Christophe|last2=Gonze|first2=Didier|last3=Goldbeter|first3=Albert|date=1999-12-01|title=Limit Cycle Models for Circadian Rhythms Based on Transcriptional Regulation in Drosophila and Neurospora|journal=Journal of Biological Rhythms|language=en|volume=14|issue=6|pages=433–448|doi=10.1177/074873099129000948|pmid=10643740|issn=0748-7304}}</ref><ref>{{Cite journal|last=Roenneberg|first=Till|last2=Chua|first2=Elaine Jane|last3=Bernardo|first3=Ric|last4=Mendoza|first4=Eduardo|date=2008-09-09|title=Modelling Biological Rhythms|journal=Current Biology|volume=18|issue=17|pages=R826–R835|doi=10.1016/j.cub.2008.07.017|pmid=18786388|issn=0960-9822}}</ref>  
 
* The daily oscillations in gene expression, hormone levels and body temperature of animals, which are part of the [[circadian rhythm]].<ref>{{Cite journal|last=Leloup|first=Jean-Christophe|last2=Gonze|first2=Didier|last3=Goldbeter|first3=Albert|date=1999-12-01|title=Limit Cycle Models for Circadian Rhythms Based on Transcriptional Regulation in Drosophila and Neurospora|journal=Journal of Biological Rhythms|language=en|volume=14|issue=6|pages=433–448|doi=10.1177/074873099129000948|pmid=10643740|issn=0748-7304}}</ref><ref>{{Cite journal|last=Roenneberg|first=Till|last2=Chua|first2=Elaine Jane|last3=Bernardo|first3=Ric|last4=Mendoza|first4=Eduardo|date=2008-09-09|title=Modelling Biological Rhythms|journal=Current Biology|volume=18|issue=17|pages=R826–R835|doi=10.1016/j.cub.2008.07.017|pmid=18786388|issn=0960-9822}}</ref>  
动物基因表达、激素水平和体温的日常变化,这些都是'''<font color="#ff8000">昼夜节律 circadian rhythm</font>'''的一部分。
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动物基因表达、激素水平和体温的日常变化,这些都是'''<font color="#ff8000">昼夜节律 circadian rhythm</font>'''的一部分<ref>{{Cite journal|last=Leloup|first=Jean-Christophe|last2=Gonze|first2=Didier|last3=Goldbeter|first3=Albert|date=1999-12-01|title=Limit Cycle Models for Circadian Rhythms Based on Transcriptional Regulation in Drosophila and Neurospora|journal=Journal of Biological Rhythms|language=en|volume=14|issue=6|pages=433–448|doi=10.1177/074873099129000948|pmid=10643740|issn=0748-7304}}</ref><ref>{{Cite journal|last=Roenneberg|first=Till|last2=Chua|first2=Elaine Jane|last3=Bernardo|first3=Ric|last4=Mendoza|first4=Eduardo|date=2008-09-09|title=Modelling Biological Rhythms|journal=Current Biology|volume=18|issue=17|pages=R826–R835|doi=10.1016/j.cub.2008.07.017|pmid=18786388|issn=0960-9822}}</ref>。
    
* The [[Cell migration|migration]] of [[cancer cell]]s in confining micro-environments follows limit cycle oscillations.<ref>{{Cite journal|last=Brückner|first=David B.|last2=Fink|first2=Alexandra|last3=Schreiber|first3=Christoph|last4=Röttgermann|first4=Peter J. F.|last5=Rädler|first5=Joachim|last6=Broedersz|first6=Chase P.|date=2019|title=Stochastic nonlinear dynamics of confined cell migration in two-state systems|journal=Nature Physics|language=en|volume=15|issue=6|pages=595–601|doi=10.1038/s41567-019-0445-4|issn=1745-2481|bibcode=2019NatPh..15..595B}}</ref>  
 
* The [[Cell migration|migration]] of [[cancer cell]]s in confining micro-environments follows limit cycle oscillations.<ref>{{Cite journal|last=Brückner|first=David B.|last2=Fink|first2=Alexandra|last3=Schreiber|first3=Christoph|last4=Röttgermann|first4=Peter J. F.|last5=Rädler|first5=Joachim|last6=Broedersz|first6=Chase P.|date=2019|title=Stochastic nonlinear dynamics of confined cell migration in two-state systems|journal=Nature Physics|language=en|volume=15|issue=6|pages=595–601|doi=10.1038/s41567-019-0445-4|issn=1745-2481|bibcode=2019NatPh..15..595B}}</ref>  
'''<font color="#ff8000">癌细胞 cancer cell</font>'''在局限微环境中的'''<font color="#ff8000">迁移 migration</font>'''遵循极限环振荡。
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'''<font color="#ff8000">癌细胞 cancer cell</font>'''在局限微环境中的'''<font color="#ff8000">迁移 migration</font>'''遵循极限环振荡<ref>{{Cite journal|last=Brückner|first=David B.|last2=Fink|first2=Alexandra|last3=Schreiber|first3=Christoph|last4=Röttgermann|first4=Peter J. F.|last5=Rädler|first5=Joachim|last6=Broedersz|first6=Chase P.|date=2019|title=Stochastic nonlinear dynamics of confined cell migration in two-state systems|journal=Nature Physics|language=en|volume=15|issue=6|pages=595–601|doi=10.1038/s41567-019-0445-4|issn=1745-2481|bibcode=2019NatPh..15..595B}}</ref> 。
    
* Some non-linear [[Electrical Circuit|electrical circuits]] exhibit limit cycle oscillations,<ref>{{Cite journal|last=Ginoux|first=Jean-Marc|last2=Letellier|first2=Christophe|date=2012-04-30|title=Van der Pol and the history of relaxation oscillations: Toward the emergence of a concept|journal=Chaos: An Interdisciplinary Journal of Nonlinear Science|volume=22|issue=2|pages=023120|doi=10.1063/1.3670008|pmid=22757527|issn=1054-1500|arxiv=1408.4890|bibcode=2012Chaos..22b3120G}}</ref> which inspired the original [[Van der Pol oscillator|Van der Pol model]].  
 
* Some non-linear [[Electrical Circuit|electrical circuits]] exhibit limit cycle oscillations,<ref>{{Cite journal|last=Ginoux|first=Jean-Marc|last2=Letellier|first2=Christophe|date=2012-04-30|title=Van der Pol and the history of relaxation oscillations: Toward the emergence of a concept|journal=Chaos: An Interdisciplinary Journal of Nonlinear Science|volume=22|issue=2|pages=023120|doi=10.1063/1.3670008|pmid=22757527|issn=1054-1500|arxiv=1408.4890|bibcode=2012Chaos..22b3120G}}</ref> which inspired the original [[Van der Pol oscillator|Van der Pol model]].  
一些非线性'''<font color="#ff8000">电路 electrical circuits</font>'''表现出极限环振荡,这启发了最初的'''<font color="#ff8000">范德波尔模型 Van der Pol model</font>'''。
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一些非线性'''<font color="#ff8000">电路 electrical circuits</font>'''表现出极限环振荡<ref>{{Cite journal|last=Ginoux|first=Jean-Marc|last2=Letellier|first2=Christophe|date=2012-04-30|title=Van der Pol and the history of relaxation oscillations: Toward the emergence of a concept|journal=Chaos: An Interdisciplinary Journal of Nonlinear Science|volume=22|issue=2|pages=023120|doi=10.1063/1.3670008|pmid=22757527|issn=1054-1500|arxiv=1408.4890|bibcode=2012Chaos..22b3120G}}</ref>,这启发了最初的'''<font color="#ff8000">范德波尔模型 Van der Pol model</font>'''。
    
== See also ==
 
== See also ==
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