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第1行: − 此词条暂由Henry翻译。{{Refimprove|date=November 2008}}+ − 此词条由Miyasaki审校 + + − An '''adaptive system''' is a set of interacting or interdependent entities, real or abstract, forming an integrated whole that together are able to respond to environmental changes or changes in the interacting parts, in a way analogous to either continuous physiological [[homeostasis]] or evolutionary [[adaptation]] in [[biology]]. [[Feedback loops]] represent a key feature of adaptive systems, such as [[ecosystems]] and individual [[organisms]]; or in the human world, [[communities]], [[organizations]], and [[families]]. − An adaptive system is a set of interacting or interdependent entities, real or abstract, forming an integrated whole that together are able to respond to environmental changes or changes in the interacting parts, in a way analogous to either continuous physiological homeostasis or evolutionary adaptation in biology. Feedback loops represent a key feature of adaptive systems, such as ecosystems and individual organisms; or in the human world, communities, organizations, and families.+ − <font color="#ff8000"> 适应系统adaptive system</font>是一组相互作用或相互依存的实体,它们或真实或抽象,形成一个能够共同响应环境的变化或相互作用部分的变化的综合整体,类似于生物学中持续的生理稳态或进化适应。反馈循环代表了适应系统的一个关键特征,例如生态系统和个体有机体; 或者在人类世界中的社区、组织和家庭。+ − − − − − − Artificial adaptive systems include [[robots]] with [[control system]]s that utilize [[negative feedback]] to maintain desired states. − − Artificial adaptive systems include robots with control systems that utilize negative feedback to maintain desired states. − − 人工自适应系统包括具有控制系统的机器人,这些机器人利用负反馈来维持想要的状态。 − − − − − − ==The law of adaptation== − − ==The law of adaptation== − − 适应法则 − − − − − The law of adaptation can be stated informally as: − − The law of adaptation can be stated informally as: − − 适应法则可以非正式地被阐释为: − − − − − − − Formally, the law can be defined as follows: − − Formally, the law can be defined as follows: − + − − − Given a system <math>S</math>, we say that a physical event <math>E</math> is a stimulus for the system <math>S</math> if and only if the probability <math>P(S \rightarrow S'|E)</math> that the system suffers a change or be perturbed (in its elements or in its processes) when the event <math>E</math> occurs is strictly greater than the prior probability that <math>S</math> suffers a change independently of <math>E</math>: − − Given a system <math>S</math>, we say that a physical event <math>E</math> is a stimulus for the system <math>S</math> if and only if the probability <math>P(S \rightarrow S'|E)</math> that the system suffers a change or be perturbed (in its elements or in its processes) when the event <math>E</math> occurs is strictly greater than the prior probability that <math>S</math> suffers a change independently of <math>E</math>: − − − − − − − − <math>P(S \rightarrow S'|E)>P(S \rightarrow S') </math> − − − − − − − ''Let <math>S</math> be an arbitrary system subject to changes in time <math>t</math> and let <math>E</math> be an arbitrary event that is a stimulus for the system <math>S</math>: we say that <math>S</math> is an adaptive system if and only if when t tends to infinity <math>(t\rightarrow \infty)</math> the probability that the system <math>S</math> change its behavior <math>(S\rightarrow S')</math> in a time step <math>t_0</math> given the event <math>E</math> is equal to the probability that the system change its behavior independently of the occurrence of the event <math>E</math>. In mathematical terms:'' − − Let <math>S</math> be an arbitrary system subject to changes in time <math>t</math> and let <math>E</math> be an arbitrary event that is a stimulus for the system <math>S</math>: we say that <math>S</math> is an adaptive system if and only if when t tends to infinity <math>(t\rightarrow \infty)</math> the probability that the system <math>S</math> change its behavior <math>(S\rightarrow S')</math> in a time step <math>t_0</math> given the event <math>E</math> is equal to the probability that the system change its behavior independently of the occurrence of the event <math>E</math>. In mathematical terms: − − 假设<math>S</math>是一个随时间变化的任意系统,<math>t</math>是一个随时间变化的系统,<math>e</math>是一个随时间变化的事件,是系统<math>s</math>的一个刺激: 我们说<math>S</math>是一个适应性系统,当且仅当 t 趋向于无穷时(t→∞),给定事件E的系统<math>S</math>在时间步长t0改变其行为(S→S′)的概率等于系统改变其行为独立于事件的发生的概率,用数学术语来表达如下: + − − - <math> P_{t_0}(S\rightarrow S'|E) > P_{t_0}(S\rightarrow S') > 0 </math> − − − - <math> \lim_{t\rightarrow \infty} P_t(S\rightarrow S' | E) = P_t(S\rightarrow S')</math> − − − − − − Thus, for each instant <math>t</math> will exist a temporal interval <math>h</math> such that: − − Thus, for each instant <math>t</math> will exist a temporal interval <math>h</math> such that: − − 因此,对于每一个即时<math>t</math>,都会存在一个时间间隔<math>h</math>,这样: − + − − <math> P_{t+h}(S\rightarrow S' | E) - P_{t+h}(S\rightarrow S') < P_t(S\rightarrow S' | E) - P_t(S\rightarrow S')</math> + − + − ==Benefit of self-adjusting systems== − 自动调节系统的好处+ − In an adaptive system, a parameter changes slowly and has no preferred value. In a self-adjusting system though, the parameter value “depends on the history of the system dynamics”. One of the most important qualities of ''self-adjusting systems'' is its “[[edge of chaos|adaptation to the edge of chaos]]” or ability to avoid [[chaos theory|chaos]]. Practically speaking, by heading to the [[edge of chaos]] without going further, a leader may act spontaneously yet without disaster. A March/April 2009 Complexity article further explains the self-adjusting systems used and the realistic implications.<ref>Hübler, A. & Wotherspoon, T.: "Self-Adjusting Systems Avoid Chaos". Complexity. 14(4), 8 – 11. 2008</ref> Physicists have shown that [[adaptation]] to the [[edge of chaos]] occurs in almost all systems with [[feedback]].<ref>{{cite journal|last1=Wotherspoon|first1=T.|last2=Hubler|first2=A.|title=Adaptation to the edge of chaos with random-wavelet feedback|journal=J Phys Chem A|volume=113|issue=1|pages=19–22|doi=10.1021/jp804420g|pmid=19072712|year=2009|bibcode=2009JPCA..113...19W}}</ref>+ − − In an adaptive system, a parameter changes slowly and has no preferred value. In a self-adjusting system though, the parameter value “depends on the history of the system dynamics”. One of the most important qualities of self-adjusting systems is its “adaptation to the edge of chaos” or ability to avoid chaos. Practically speaking, by heading to the edge of chaos without going further, a leader may act spontaneously yet without disaster. A March/April 2009 Complexity article further explains the self-adjusting systems used and the realistic implications. Physicists have shown that adaptation to the edge of chaos occurs in almost all systems with feedback. − − 在自适应系统中,参数变化缓慢,没有优先值。然而,在一个自调整系统中,参数值“取决于系统动力的历史”。自调节系统最重要的特性之一是它能“适应混乱的边缘”或避免混乱的能力。实际上来讲,通过朝着混乱的边缘出发但是不走的太远,领导者就可以在避免灾难的情况下自发地行动。Complexity期刊2009年3/4月一期的一篇文章进一步解释了自我调节系统的使用和现实意义。<ref>Hübler, A. & Wotherspoon, T.: "Self-Adjusting Systems Avoid Chaos". Complexity. 14(4), 8 – 11. 2008</ref>物理学家已经证明,对混沌边缘的适应几乎发生在所有具有反馈的系统中。<ref>{{cite journal|last1=Wotherspoon|first1=T.|last2=Hubler|first2=A.|title=Adaptation to the edge of chaos with random-wavelet feedback|journal=J Phys Chem A|volume=113|issue=1|pages=19–22|doi=10.1021/jp804420g|pmid=19072712|year=2009|bibcode=2009JPCA..113...19W}}</ref> − − − − − − ==Practopoiesis== − − ==Practopoiesis== − − 拓扑实践 − − − + − − − − − − ''evolution'' (i) → ''gene expression'' (ii) → ''non gene-involving homeostatic mechanisms (anapoiesis)'' (iii) → ''final cell function'' (iv) − − evolution (i) → gene expression (ii) → non gene-involving homeostatic mechanisms (anapoiesis) (iii) → final cell function (iv) − − 进化(i) → 基因表达(ii) → 非基因参与的稳态机制(anapoiesis) (iii) → 最终细胞功能(iv) − + 第165行:
第61行: − 随着层级结构向更高级别的组织发展,适应的速度也在加快。进化是最慢的,最后的细胞功能是最快的。最终,实践拓扑学挑战当前的神经科学学说,认为心理活动主要发生在稳态,非生物水平上。也就是说,意识和想法从快速的稳态机制中产生,从而控制了细胞功能。这与人们普遍认为的思考是神经活动的同义词(也就是说,与第四级的“最终细胞功能”)形成了鲜明对比。+ − − − − Each slower level contains knowledge that is more general than the faster level; for example, genes contain more general knowledge than anapoietic mechanisms, which in turn contain more general knowledge than cell functions. This hierarchy of knowledge enables the anapoietic level to directly activate concepts, which are the most fundamental ingredient for the emergence of the mind. − − Each slower level contains knowledge that is more general than the faster level; for example, genes contain more general knowledge than anapoietic mechanisms, which in turn contain more general knowledge than cell functions. This hierarchy of knowledge enables the anapoietic level to directly activate concepts, which are the most fundamental ingredient for the emergence of the mind. 第179行:
第69行: − − − ==See also== − − ==See also== − − 参见 − − {{Portal|Evolutionary biology}} + − + − + − + − + − 适应免疫系统+ − + − + − + − 人工神经网络+ − − − − 复杂适应系统 − − − − 创新扩散 − − − − 生态系统 − − − − 盖亚假说 − − − − 基因表达式编程算法 − − − − 基因算法 − − * [[Learning]] − − 学习 − − − − 神经适应 − − + − − − − − − − ==Notes== − − 注释 第257行:
第97行: − + − + − ==References== − − 参考资料 − − − − − − | last = Martin H. | first = Jose Antonio. | authorlink = Jose Antonio Martin H. − − | last = Martin H. | first = Jose Antonio. | authorlink = Jose Antonio Martin H. − − − | author2 = [[Javier de Lope]]; [[Darío Maravall]] − − | author2 = Javier de Lope; Darío Maravall − − | author2 = Javier de Lope; Darío Maravall − − | title = Adaptation, Anticipation and Rationality in Natural and Artificial Systems: Computational Paradigms Mimicking Nature − − | title = Adaptation, Anticipation and Rationality in Natural and Artificial Systems: Computational Paradigms Mimicking Nature − − 自然和人工系统中的适应、预测和理性: 模仿自然的计算模式 − − | journal = Natural Computing − − | journal = Natural Computing − − 自然计算杂志 − − | volume = 8 | issue = 4 − − | volume = 8 | issue = 4 − − 第八卷,第四期 − − | pages = 757–775 − − | pages = 757–775 − − 第757-775页 − − | date = 2009 − − | date = 2009 − − 2009年 − − | doi = 10.1007/s11047-008-9096-6 − − | doi = 10.1007/s11047-008-9096-6 − − 10.1007 / s11047-008-9096-6 − − }} − }} − + − − − − ==External links== − − 外部链接 − − {{Wiktionary | anapoiesis}} − − − − {{Wiktionary | practopoiesis}} − − − − − − − − 第354行:
第117行: − + − + − Category:Control engineering+ − − 类别: 控制工程 − − − − Category:Cybernetics − − 类别: 控制论 − − − − Category:Systems theory − − 范畴: 系统论 − − <noinclude> − − <small>This page was moved from [[wikipedia:en:Adaptive system]]. Its edit history can be viewed at [[自适应系统/edithistory]]</small></noinclude> − [[Category:待整理页面]]+
无编辑摘要
此词条暂由Henry翻译。此词条由Miyasaki审校
'''适应系统 adaptive system'''是一组相互作用或相互依存的实体,它们或真实或抽象,形成一个能够共同响应环境的变化或相互作用部分的变化的综合整体,类似于生物学中持续的生理稳态或进化适应。'''反馈循环'''代表了适应系统的一个关键特征,例如生态系统和个体有机体;或者在人类世界中的社区、组织和家庭。
'''人工自适应系统 Artificial adaptive systems'''包括具有控制系统的机器人,这些机器人利用[[负反馈]]来维持想要的状态。
==适应法则==
适应法则可以非正式地被阐释为:
{{quote|Every adaptive system converges to a state in which all kind of stimulation ceases.<ref>José Antonio Martín H., Javier de Lope and Darío Maravall: "Adaptation, Anticipation and Rationality in Natural and Artificial Systems: Computational Paradigms Mimicking Nature" Natural Computing, December, 2009. Vol. 8(4), pp. 757-775. [https://dx.doi.org/10.1007/s11047-008-9096-6 doi]</ref>}}
{{quote|Every adaptive system converges to a state in which all kind of stimulation ceases.<ref>José Antonio Martín H., Javier de Lope and Darío Maravall: "Adaptation, Anticipation and Rationality in Natural and Artificial Systems: Computational Paradigms Mimicking Nature" Natural Computing, December, 2009. Vol. 8(4), pp. 757-775. [https://dx.doi.org/10.1007/s11047-008-9096-6 doi]</ref>}}
正式地,该法则可以定义如下:
正式地,该法则可以定义如下:
给定一个系统<math>S</math>,我们说物理事件 <math>E</math>是<math>S</math>的刺激物,当且仅当数学<math>P(S \rightarrow S'|E)</math>,即当事件<math>E</math>发生时系统发生变化或(其组成元素或过程)被干扰的概率严格大于<math>S</math>独立于<math>E</math>而发生改变的概率为:
给定一个系统<math>S</math>,我们说物理事件 <math>E</math>是<math>S</math>的刺激物,当且仅当数学<math>P(S \rightarrow S'|E)</math>,即当事件<math>E</math>发生时系统发生变化或(其组成元素或过程)被干扰的概率严格大于<math>S</math>独立于<math>E</math>而发生改变的概率。
:<math>P(S \rightarrow S'|E)>P(S \rightarrow S') </math>
:<math>P(S \rightarrow S'|E)>P(S \rightarrow S') </math>
假设<math>S</math>是一个随时间变化的任意系统,<math>t</math>是一个随时间变化的系统,<math>E</math>是一个随时间变化的事件,是系统<math>S</math>的一个刺激: 我们说<math>S</math>是一个适应性系统,当且仅当 t 趋向于无穷时(<math>(t\rightarrow \infty)</math>),给定事件<math>E</math>的系统<math>S</math>在时间步长<math>t_0</math>改变其行为( <math>(S\rightarrow S')</math> )的概率等于系统改变其行为独立于事件的发生的概率,用数学术语来表达如下:
#- <math> P_{t_0}(S\rightarrow S'|E) > P_{t_0}(S\rightarrow S') > 0 </math>
#- <math> P_{t_0}(S\rightarrow S'|E) > P_{t_0}(S\rightarrow S') > 0 </math>
#- <math> \lim_{t\rightarrow \infty} P_t(S\rightarrow S' | E) = P_t(S\rightarrow S')</math>
#- <math> \lim_{t\rightarrow \infty} P_t(S\rightarrow S' | E) = P_t(S\rightarrow S')</math>
因此,对于每一个即时<math>t</math>,都会存在一个时间间隔<math>h</math>,使得:
:<math> P_{t+h}(S\rightarrow S' | E) - P_{t+h}(S\rightarrow S') < P_t(S\rightarrow S' | E) - P_t(S\rightarrow S')</math>
:<math> P_{t+h}(S\rightarrow S' | E) - P_{t+h}(S\rightarrow S') < P_t(S\rightarrow S' | E) - P_t(S\rightarrow S')</math>
==自动调节系统的优点==
==Benefit of self-adjusting systems==
在自适应系统中,参数变化缓慢,没有优先值。然而,在一个自调整系统中,参数值“取决于系统动力的历史”。自调节系统最重要的特性之一是它能“适应混乱的边缘”或避免混乱的能力。实际上来讲,通过朝着[[混沌边缘 edge of chaos]]出发但是不走的太远,领导者就可以在避免灾难的情况下自发地行动。Complexity期刊2009年3/4月一期的一篇文章进一步解释了自我调节系统的使用和现实意义。<ref>Hübler, A. & Wotherspoon, T.: "Self-Adjusting Systems Avoid Chaos". Complexity. 14(4), 8 – 11. 2008</ref>物理学家已经证明,对混沌边缘的适应几乎发生在所有具有反馈的系统中。<ref>{{cite journal|last1=Wotherspoon|first1=T.|last2=Hubler|first2=A.|title=Adaptation to the edge of chaos with random-wavelet feedback|journal=J Phys Chem A|volume=113|issue=1|pages=19–22|doi=10.1021/jp804420g|pmid=19072712|year=2009|bibcode=2009JPCA..113...19W}}</ref>
==拓扑实践 Practopoiesis==
How do various types of adaptations interact in a living system? ''Practopoiesis,'' a term due to its originator Danko Nikolić, is a reference to a hierarchy of adaptation mechanisms answering this question. The adaptive hierarchy forms a kind of a self-adjusting system in which [[autopoiesis]] of the entire ''organism'' or a ''cell'' occurs through a hierarchy of [[allopoiesis|allopoietic]] interactions among ''components''.This is possible because the components are organized into a [[poiesis|poietic]] hierarchy: adaptive actions of one component result in creation of another component. The theory proposes that living systems exhibit a hierarchy of a total of four such adaptive poietic operations:
How do various types of adaptations interact in a living system? ''Practopoiesis,'' a term due to its originator Danko Nikolić, is a reference to a hierarchy of adaptation mechanisms answering this question. The adaptive hierarchy forms a kind of a self-adjusting system in which [[autopoiesis]] of the entire ''organism'' or a ''cell'' occurs through a hierarchy of [[allopoiesis|allopoietic]] interactions among ''components''.<ref name=Nikolic2015>{{cite journal|title=Practopoiesis: Or how life fosters a mind. |author=Danko Nikolić|date=2015|doi=10.1016/j.jtbi.2015.03.003|pmid = 25791287|volume=373|journal=Journal of Theoretical Biology|pages=40–61|arxiv=1402.5332}}</ref> This is possible because the components are organized into a [[poiesis|poietic]] hierarchy: adaptive actions of one component result in creation of another component. The theory proposes that living systems exhibit a hierarchy of a total of four such adaptive poietic operations:
How do various types of adaptations interact in a living system? Practopoiesis, a term due to its originator Danko Nikolić, is a reference to a hierarchy of adaptation mechanisms answering this question. The adaptive hierarchy forms a kind of a self-adjusting system in which autopoiesis of the entire organism or a cell occurs through a hierarchy of allopoietic interactions among components. This is possible because the components are organized into a poietic hierarchy: adaptive actions of one component result in creation of another component. The theory proposes that living systems exhibit a hierarchy of a total of four such adaptive poietic operations:
How do various types of adaptations interact in a living system? Practopoiesis, a term due to its originator Danko Nikolić, is a reference to a hierarchy of adaptation mechanisms answering this question. The adaptive hierarchy forms a kind of a self-adjusting system in which autopoiesis of the entire organism or a cell occurs through a hierarchy of allopoietic interactions among components. This is possible because the components are organized into a poietic hierarchy: adaptive actions of one component result in creation of another component. The theory proposes that living systems exhibit a hierarchy of a total of four such adaptive poietic operations:
在一个生命系统中,各种类型的适应性是如何相互作用的?<font color="#ff8000"> 拓扑实践Practopoiesis</font>,这个术语源于它的发明者 Danko nikoli,指向了能回答这个问题的一个适应机制层次结构。这种适应性层次结构形成了一种自我调节系统,其中整个生物体或细胞的自创生是通过各组分<ref name=Nikolic2015>{{cite journal|title=Practopoiesis: Or how life fosters a mind. |author=Danko Nikolić|date=2015|doi=10.1016/j.jtbi.2015.03.003|pmid = 25791287|volume=373|journal=Journal of Theoretical Biology|pages=40–61|arxiv=1402.5332}}</ref>之间的异体生成相互作用而发生的。这之所以可能是因为组件被组织成一个极端层次结构: 一个组件的自适应操作导致另一个组件的创建。该理论提出,生命系统展示了一个由四个这样的适应性极化操作组成的层级结构:
在一个生命系统中,各种类型的适应性是如何相互作用的?'''拓扑实践 Practopoiesis'''这个术语源于它的发明者 Danko nikoli,指向了能回答这个问题的一个适应机制层次结构。这种适应性层次结构形成了一种自我调节系统,其中整个生物体或细胞的自创生是通过各组分<ref name=Nikolic2015>{{cite journal|title=Practopoiesis: Or how life fosters a mind. |author=Danko Nikolić|date=2015|doi=10.1016/j.jtbi.2015.03.003|pmid = 25791287|volume=373|journal=Journal of Theoretical Biology|pages=40–61|arxiv=1402.5332}}</ref>之间的异体生成相互作用而发生的。这之所以可能是因为组件被组织成一个极端层次结构:一个组件的自适应操作导致另一个组件的创建。该理论提出,生命系统展示了一个由四个这样的适应性极化操作组成的层级结构:
'''进化 evolution'''(i) &rarr;'''基因表达 gene expression'''(ii) &rarr;'''非基因参与的稳态机制non gene-involving homeostatic mechanisms(anapoiesis)''' (iii) &rarr;'''最终细胞功能 final cell function'''(iv)
As the hierarchy evolves towards higher levels of organization, the speed of adaptation increases. Evolution is the slowest; the final cell function is the fastest. Ultimately, practopoiesis challenges current neuroscience doctrine by asserting that mental operations primarily occur at the homeostatic, anapoietic level (iii) — i.e., that minds and thought emerge from fast homeostatic mechanisms poietically controlling the cell function. This contrasts the widespread belief that thinking is synonymous with neural activity (i.e., with the 'final cell function' at level iv).
As the hierarchy evolves towards higher levels of organization, the speed of adaptation increases. Evolution is the slowest; the final cell function is the fastest. Ultimately, practopoiesis challenges current neuroscience doctrine by asserting that mental operations primarily occur at the homeostatic, anapoietic level (iii) — i.e., that minds and thought emerge from fast homeostatic mechanisms poietically controlling the cell function. This contrasts the widespread belief that thinking is synonymous with neural activity (i.e., with the 'final cell function' at level iv).
随着层级结构向更高级别的组织发展,适应的速度也在加快。进化是最慢的,最后的细胞功能是最快的。最终,实践拓扑学挑战当前的神经科学学说,认为心理活动主要发生在稳态,非生物水平上。也就是说,意识和想法从快速的稳态机制中产生,从而控制了细胞功能。这与人们普遍认为的思考是神经活动的同义词(也就是说,与第四级的“最终细胞功能”)形成了鲜明对比。
每一个较慢的层次包含的知识比较快的层次包含的知识更一般性; 例如,基因包含的一般知识比无生殖机制多,而无生殖机制又比细胞功能包含更多的一般知识。这种知识的层次结构使得无生命层次能够直接激活概念,而这些概念是意识出现的最基本的原料。
每一个较慢的层次包含的知识比较快的层次包含的知识更一般性; 例如,基因包含的一般知识比无生殖机制多,而无生殖机制又比细胞功能包含更多的一般知识。这种知识的层次结构使得无生命层次能够直接激活概念,而这些概念是意识出现的最基本的原料。
==参见==
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{{div col|colwidth=22em}}
* [[适应免疫系统 Adaptive immune system]]
* [[人工神经网络 Artificial neural network]]
* [[Adaptive immune system]]
* [[复杂适应系统 Complex adaptive system]]
* [[创新扩散 Diffusion of innovations]]
* [[生态系统 Ecosystems]]
* [[盖亚假说 Gaia hypothesis]]
* [[Artificial neural network]]
* [[基因表达式编程算法 Gene expression programming]]
* [[基因算法 Genetic algorithms]]
* [[神经适应 Neural adaptation]]
* [[Complex adaptive system]]
* [[Diffusion of innovations]]
* [[Ecosystems]]
* [[Gaia hypothesis]]
* [[Gene expression programming]]
* [[Genetic algorithms]]
* [[Neural adaptation]]
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{{div col end}}
==注释==
==Notes==
{{Reflist}}
{{Reflist}}
==References==
==参考文献==
* {{cite journal | last = Martin H. | first = Jose Antonio. |author2 = Javier de Lope; Darío Maravall | title = Adaptation, Anticipation and Rationality in Natural and Artificial Systems: Computational Paradigms Mimicking Nature | journal = Natural Computing | volume = 8 | issue = 4 | pages = 757–775 | date = 2009 | doi = 10.1007/s11047-008-9096-6
* {{cite journal
}}
}}
==其他链接==
==External links==
* Funny [https://www.youtube.com/watch?v=WIzsz03X8qc animated video] explaining the theory of practopoiesis, made by Mind & Brain.
* Funny [https://www.youtube.com/watch?v=WIzsz03X8qc animated video] explaining the theory of practopoiesis, made by Mind & Brain.
* Practopoiesis offers solutions to [http://www.danko-nikolic.com/long-standing-problems-solved-by-practopoiesis/ nine long-standing problems] in neuroscience and philosophy of mind
* Practopoiesis offers solutions to [http://www.danko-nikolic.com/long-standing-problems-solved-by-practopoiesis/ nine long-standing problems] in neuroscience and philosophy of mind
* [https://sapienlabs.co/?s=danko+nikol Blog series on practopoiesis]
* [https://sapienlabs.co/?s=danko+nikol Blog series on practopoiesis]
[[Category:Control engineering]]
[[Category:控制工程]]
[[Category:控制论]]
[[Category:系统论]]
[[Category:Cybernetics]]
[[Category:Systems theory]]
此词条暂由Henry翻译。此词条由Miyasaki审校