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In [[applied physics]], the concept of '''controlling self-organized criticality''' refers to the control of processes by which a [[self-organized]] system dissipates [[energy]]. The objective of the control is to reduce the probability of occurrence of and size of [[energy dissipation]] bursts, often called ''avalanches'', of self-organized systems.  Dissipation of energy in a [[self-organized criticality|self-organized critical]] system into a lower energy state can be costly for society, since it depends on avalanches of all sizes usually following a kind of [[power law]] distribution and large avalanches can be damaging and disruptive.

In [[applied physics]], the concept of '''controlling self-organized criticality''' refers to the control of processes by which a [[self-organized]] system dissipates [[energy]]. The objective of the control is to reduce the probability of occurrence of and size of [[energy dissipation]] bursts, often called ''avalanches'', of self-organized systems.  Dissipation of energy in a [[self-organized criticality|self-organized critical]] system into a lower energy state can be costly for society, since it depends on avalanches of all sizes usually following a kind of [[power law]] distribution and large avalanches can be damaging and disruptive.

In applied physics, the concept of controlling self-organized criticality refers to the control of processes by which a self-organized system dissipates energy. The objective of the control is to reduce the probability of occurrence of and size of energy dissipation bursts, often called avalanches, of self-organized systems.  Dissipation of energy in a self-organized critical system into a lower energy state can be costly for society, since it depends on avalanches of all sizes usually following a kind of power law distribution and large avalanches can be damaging and disruptive.

In applied physics, the concept of controlling self-organized criticality refers to the control of processes by which a self-organized system dissipates energy. The objective of the control is to reduce the probability of occurrence of and size of energy dissipation bursts, often called avalanches, of self-organized systems.  Dissipation of energy in a self-organized critical system into a lower energy state can be costly for society, since it depends on avalanches of all sizes usually following a kind of power law distribution and large avalanches can be damaging and disruptive.

在应用物理学中，<font color="#ff8000"> 控制自组织临界性Controlling self-organized criticality</font>的概念是指对自组织系统耗散能量的过程的控制。这种控制的目的是减少自组织系统发生能量耗散爆发(通常称为雪崩)的概率和规模。将一个自我组织的临界系统中的能量耗散转变到较低的能量状态对社会来说可能是代价高昂的，因为它依赖于各种规模的雪崩，这些雪崩通常遵循一种<font color="#ff8000"> 幂律分布Power law distribution</font>，大规模雪崩可能具有破坏性和破坏性。

在应用物理学中，<font color="#ff8000"> 自组织临界控制Controlling self-organized criticality</font>的概念是指对自组织系统能量耗散过程的控制。这种控制的目的是减少自组织系统发生能量耗散爆发(通常称为雪崩)的概率和规模。一个自组织临界系统中转变到较低的能量状态时的能量耗散对社会来说可能是代价高昂的，因为它取决于各种规模的雪崩，这些雪崩的规模通常遵循<font color="#ff8000"> 幂律分布Power law distribution</font>，而大规模雪崩具有伤害性和破坏性。

   

   

Several strategies have been proposed to deal with the issue of controlling self-organized criticality:

Several strategies have been proposed to deal with the issue of controlling self-organized criticality:

有人提出了几个策略来处理控制自组织临界性的问题:

已经有一些策略被提出用于处理自组织临界状态的控制问题:

#''The design of controlled avalanches.'' [[Daniel O. Cajueiro]] and [[Roberto F. S. Andrade]] show that if well-formulated small and medium avalanches are exogenously triggered in the system, the energy of the system is released in a way that large avalanches are rarer.<ref name="cajand10a" /><ref name="cajand10b" /><ref name="cajand10c" />

#''The design of controlled avalanches.'' [[Daniel O. Cajueiro]] and [[Roberto F. S. Andrade]] show that if well-formulated small and medium avalanches are exogenously triggered in the system, the energy of the system is released in a way that large avalanches are rarer.

The design of controlled avalanches. Daniel O. Cajueiro and Roberto F. S. Andrade show that if well-formulated small and medium avalanches are exogenously triggered in the system, the energy of the system is released in a way that large avalanches are rarer.

The design of controlled avalanches. Daniel O. Cajueiro and Roberto F. S. Andrade show that if well-formulated small and medium avalanches are exogenously triggered in the system, the energy of the system is released in a way that large avalanches are rarer.

可控雪崩的设计。Daniel O.Cajueiro和Roberto F.S.Andrade表明，如果系统中形成良好的中小规模雪崩是外来触发的，那么系统的能量会以更罕见的方式释放出来。

可控雪崩的设计。Daniel O.Cajueiro和Roberto F.S.Andrade表明，如果系统中成熟的中小规模雪崩是靠外部触发的，那么系统的能量会以不同于大规模雪崩的方式释放出来。 <ref name="cajand10a" /><ref name="cajand10b" /><ref name="cajand10c" />

#'' The modification of the degree of interdependence of the network where the avalanche spreads.'' [[Charles D. Brummitt]], [[Raissa M. D'Souza]] and [[E. A. Leicht]] show that the dynamics of self-organized critical systems on [[complex network]]s depend on connectivity of the complex network. They find that while some connectivity is beneficial (since it suppresses the largest cascades in the system), too much connectivity gives space for the development of very large cascades and increases the size of capacity of the system.<ref name=brum12>{{cite journal

#'' The modification of the degree of interdependence of the network where the avalanche spreads.'' [[Charles D. Brummitt]], [[Raissa M. D'Souza]] and [[E. A. Leicht]] show that the dynamics of self-organized critical systems on [[complex network]]s depend on connectivity of the complex network. They find that while some connectivity is beneficial (since it suppresses the largest cascades in the system), too much connectivity gives space for the development of very large cascades and increases the size of capacity of the system.{{cite journal

  The modification of the degree of interdependence of the network where the avalanche spreads. Charles D. Brummitt, Raissa M. D'Souza and E. A. Leicht show that the dynamics of self-organized critical systems on complex networks depend on connectivity of the complex network. They find that while some connectivity is beneficial (since it suppresses the largest cascades in the system), too much connectivity gives space for the development of very large cascades and increases the size of capacity of the system.<ref name=brum12>{{cite journal

  The modification of the degree of interdependence of the network where the avalanche spreads. Charles D. Brummitt, Raissa M. D'Souza and E. A. Leicht show that the dynamics of self-organized critical systems on complex networks depend on connectivity of the complex network. They find that while some connectivity is beneficial (since it suppresses the largest cascades in the system), too much connectivity gives space for the development of very large cascades and increases the size of capacity of the system.<ref name=brum12>{{cite journal

雪崩蔓延地区网络相互依赖程度的修正：Charles D. Brummitt，Raissa M. D'Souza和 E. A. Leicht 证明了复杂网络上自组织临界系统的动力学依赖于复杂网络的连通性。他们发现，虽然有些连通性是有益的(因为它压制了系统中最大的级联) ，但过多的连通性为非常大的级联的发展提供了空间，并增加了系统的容量。

雪崩蔓延地区网络相互依赖程度的修正：Charles D. Brummitt，Raissa M. D'Souza和 E. A. Leicht 证明了复杂网络上自组织临界系统的动力学依赖于复杂网络的连通性。他们发现，虽然有些连通性是有益的(因为它压制了系统中最大的级联) ，但过多的连通性为大型级联的发展提供了空间，并增加了系统的容量。<ref name=brum12>

  | author = C. D. Brummitt, R. M. D'Souza and E. A. Leicht

  | author = C. D. Brummitt, R. M. D'Souza and E. A. Leicht

  The modification of the deposition process of the self-organized system.  Pierre-Andre Noel, Charles D. Brummitt and Raissa M. D'Souza show that it is possible to control the self-organized system by modifying the natural deposition process of the self-organized system adjusting the place where the avalanche starts.<ref name=noel13>{{cite journal

  The modification of the deposition process of the self-organized system.  Pierre-Andre Noel, Charles D. Brummitt and Raissa M. D'Souza show that it is possible to control the self-organized system by modifying the natural deposition process of the self-organized system adjusting the place where the avalanche starts.<ref name=noel13>{{cite journal

自组织系统沉积工艺的改进。 Pierre-Andre Noel、Charles D. Brummitt和Raissa M. D'Souza 指出，通过改变自组织系统的自然沉积过程，调整雪崩开始的位置，可以控制自组织系统。

自组织系统沉积工艺的改进。 Pierre-Andre Noel、Charles D. Brummitt和Raissa M. D'Souza 指出，通过改变自组织系统的自然沉积过程来调整雪崩开始的位置，有可能实现对自组织系统的控制。

  | author = P. A. Noel, C. D. Brummitt and R. M. D'Souza

  | author = P. A. Noel, C. D. Brummitt and R. M. D'Souza

  | title = Controlling self-organized criticality on networks using models that self-organize

  | title = Controlling self-organized criticality on networks using models that self-organize

| 标题使用自组织模型控制网络上的自组织临界性

| 标题：使用自组织模型的网络上的自组织临界控制

  | journal = Physical Review Letters

  | journal = Physical Review Letters

23992086} / ref

23992086} / ref

#'' Dynamically modifying the local thresholds of cascading failures.'' In a model of an electric transmission network, Heiko Hoffmann and David W. Payton demonstrated that either randomly upgrading lines (sort of like preventive maintenance) or upgrading broken lines to a random breakage threshold suppresses self-organized criticality.<ref name=hh2014>{{cite journal

#'' Dynamically modifying the local thresholds of cascading failures.'' In a model of an electric transmission network, Heiko Hoffmann and David W. Payton demonstrated that either randomly upgrading lines (sort of like preventive maintenance) or upgrading broken lines to a random breakage threshold suppresses self-organized criticality.{{cite journal

  Dynamically modifying the local thresholds of cascading failures. In a model of an electric transmission network, Heiko Hoffmann and  David W. Payton  demonstrated that either randomly upgrading lines (sort of like preventive maintenance) or upgrading broken lines to a random breakage threshold suppresses self-organized criticality.<ref name=hh2014>{{cite journal

  Dynamically modifying the local thresholds of cascading failures. In a model of an electric transmission network, Heiko Hoffmann and  David W. Payton  demonstrated that either randomly upgrading lines (sort of like preventive maintenance) or upgrading broken lines to a random breakage threshold suppresses self-organized criticality.<ref name=hh2014>{{cite journal

动态修改级联故障的局部阈值；在一个电力传输网络模型中， H .霍夫曼 和 D. W. 佩顿 证明，要么随机升级线路(类似于预防性维护) ，要么将破损线路升级到随机破损阈值抑制自组织临界性。

动态修改级联故障的局部阈值；在一个电力传输网络模型中， H .霍夫曼 和 D. W. 佩顿 证明，要么随机升级线路(类似于预防性维护) ，要么将破损线路更新到到随机破损阈值，都可以抑制自组织临界性。 <ref name=hh2014>

   --~~~人名第一次出现用中文 后续用英文

   --~~~人名第一次出现用中文 后续用英文

2014{ cite journal

2014{ cite journal

| bibcode 2014CSF... 67... 87H

| bibcode 2014CSF... 67... 87H

  }}</ref> Apparently, these strategies undermine the self-organization of large critical clusters. Here, a critical cluster is a collection of transmission lines that are near the failure threshold and that collapse entirely if triggered.

  Apparently, these strategies undermine the self-organization of large critical clusters. Here, a critical cluster is a collection of transmission lines that are near the failure threshold and that collapse entirely if triggered.

  }}</ref> Apparently, these strategies undermine the self-organization of large critical clusters. Here, a critical cluster is a collection of transmission lines that are near the failure threshold and that collapse entirely if triggered.

  }}</ref> Apparently, these strategies undermine the self-organization of large critical clusters. Here, a critical cluster is a collection of transmission lines that are near the failure threshold and that collapse entirely if triggered.

There are several events that arise in nature or society where these ideas of control may help to avoid them:<ref name="cajand10a" /><ref name="cajand10b" /><ref name="cajand10c" /><ref name="brum12" /><ref name="noel13" /><ref name="hh2014" />

There are several events that arise in nature or society where these ideas of control may help to avoid them:

There are several events that arise in nature or society where these ideas of control may help to avoid them:

There are several events that arise in nature or society where these ideas of control may help to avoid them:

在自然界或社会中发生的一些事件中，这些控制观念可能有助于避免它们:

在自然界或社会中发生的一些事件中，这些控制观念可能有助于避免它们:<ref name="cajand10a" /><ref name="cajand10b" /><ref name="cajand10c" /><ref name="brum12" /><ref name="noel13" /><ref name="hh2014" />

  Cascades of load shedding that take place in power grids (a type of power outage). The OPA model is used to study different techniques for criticality control.

  Cascades of load shedding that take place in power grids (a type of power outage). The OPA model is used to study different techniques for criticality control.

电网中发生的减载级联(断电的一种形式)。利用OPA模型研究了不同的临界控制技术。

电网中发生的减载级联(断电的一种形式)。OPA模型可以用来研究不同的临界控制技术。

# [[Cascading failure]] in the internet switching fabric.

# [[Cascading failure]] in the internet switching fabric.

  Excursions in nuclear energy systems.

  Excursions in nuclear energy systems.