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此词条暂由Henry翻译。

此词条暂由Henry翻译。

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.

控制雪崩的设计 Daniel O. Cajueiro和Roberto F. S. Andrade的研究表明，如果配方良好的中小规模雪崩是由系统外部触发的，那么系统的能量释放方式将使大规模雪崩更为罕见。

控制雪崩的设计 Daniel O. Cajueiro和Roberto F. S. Andrade的研究表明，如果配方良好的中小规模雪崩是由系统外部触发的，那么系统的能量释放方式将使大规模雪崩更为罕见。

 

#'' 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.<ref name=brum12>{{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， Heiko Hoffmann 和 David W. Payton 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。 2014{ 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， Heiko Hoffmann 和 David W. Payton 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。  

2014{ cite journal

  | author = H. Hoffmann and D. W. Payton

  | author = H. Hoffmann and D. W. Payton