Detection of minimal extended driver nodes in energetic costs reduction.

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Bingbo Wang, Jiaojiao He, Qingdou Meng
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Abstract

Structures of complex networks are fundamental to system dynamics, where node state and connectivity patterns determine the cost of a control system, a key aspect in unraveling complexity. However, minimizing the energy required to control a system with the fewest input nodes remains an open problem. This study investigates the relationship between the structure of closed-connected function modules and control energy. We discovered that small structural adjustments, such as adding a few extended driver nodes, can significantly reduce control energy. Thus, we propose MInimal extended driver nodes in Energetic costs Reduction (MIER). Next, we transform the detection of MIER into a multi-objective optimization problem and choose an NSGA-II algorithm to solve it. Compared with the baseline methods, NSGA-II can approximate the optimal solution to the greatest extent. Through experiments using synthetic and real data, we validate that MIER can exponentially decrease control energy. Furthermore, random perturbation tests confirm the stability of MIER. Subsequently, we applied MIER to three representative scenarios: regulation of differential expression genes affected by cancer mutations in the human protein-protein interaction network, trade relations among developed countries in the world trade network, and regulation of body-wall muscle cells by motor neurons in Caenorhabditis elegans nervous network. The results reveal that the involvement of MIER significantly reduces control energy required for these original modules from a topological perspective. Additionally, MIER nodes enhance functionality, supplement key nodes, and uncover potential mechanisms. Overall, our work provides practical computational tools for understanding and presenting control strategies in biological, social, and neural systems.

检测降低能耗成本的最小扩展驱动节点
复杂网络的结构是系统动力学的基础,其中节点状态和连接模式决定了控制系统的成本,是揭示复杂性的一个关键方面。然而,以最少的输入节点控制一个系统所需的能量最小化仍是一个悬而未决的问题。本研究探讨了封闭连接功能模块的结构与控制能量之间的关系。我们发现,微小的结构调整,如增加几个扩展驱动节点,就能显著降低控制能量。因此,我们提出了减少能耗成本(MIER)中的最小扩展驱动节点(MInimal extended driver nodes)。接下来,我们将 MIER 的检测转化为多目标优化问题,并选择 NSGA-II 算法来解决该问题。与基线方法相比,NSGA-II 能最大程度地逼近最优解。通过使用合成数据和真实数据进行实验,我们验证了 MIER 可以指数级降低控制能量。此外,随机扰动测试也证实了 MIER 的稳定性。随后,我们将 MIER 应用于三个具有代表性的场景:人类蛋白质-蛋白质相互作用网络中受癌症突变影响的差异表达基因的调控、世界贸易网络中发达国家之间的贸易关系以及草履虫神经网络中运动神经元对体壁肌肉细胞的调控。研究结果表明,从拓扑学角度来看,MIER 的参与大大降低了这些原始模块所需的控制能量。此外,MIER 节点还增强了功能,补充了关键节点,并揭示了潜在机制。总之,我们的工作为理解和展示生物、社会和神经系统中的控制策略提供了实用的计算工具。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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