The Internal Model Principle for Biomolecular Control Theory

Ankit Gupta;Mustafa Khammash
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引用次数: 1

Abstract

The well-known Internal Model Principle (IMP) is a cornerstone of modern control theory. It stipulates the necessary conditions for asymptotic robustness of disturbance-prone dynamical systems by asserting that such a system must embed a subsystem in a feedback loop, and this subsystem must be able to reduplicate the dynamic disturbance using only the regulated variable as the input. The insights provided by IMP can help in both designing suitable controllers and also in analysing the regulatory mechanisms in complex systems. So far the application of IMP in biology has been case-specific and ad hoc, primarily due to the lack of generic versions of the IMP for biomolecular reaction networks that model biological processes. In this short article we highlight the need for an IMP in biology and discuss a recently developed version of it for biomolecular networks that exhibit maximal Robust Perfect Adaptation (maxRPA) by being robust to the maximum number of disturbance sources.
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生物分子控制理论的内模原理
众所周知的内部模型原理是现代控制理论的基石。它规定了易受扰动的动力系统渐近鲁棒性的必要条件,声称这样的系统必须在反馈回路中嵌入一个子系统,并且该子系统必须能够仅使用调节变量作为输入来重复动态扰动。IMP提供的见解有助于设计合适的控制器,也有助于分析复杂系统中的调节机制。到目前为止,IMP在生物学中的应用是针对具体情况和特殊情况的,主要是由于缺乏用于模拟生物过程的生物分子反应网络的IMP的通用版本。在这篇短文中,我们强调了生物学中对IMP的需求,并讨论了最近开发的用于生物分子网络的IMP版本,该版本通过对最大数量的干扰源具有鲁棒性而表现出最大鲁棒完全适应(maxRPA)。
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