The content presents a novel approach called "adaptive control" to address the challenge of controlling dynamic networks in real-time. Real-world networks are inherently dynamic, with their topologies continuously evolving over time. Previous methods for controlling dynamic networks often assume prior knowledge of future network changes, which is typically not the case in practice.
The key contributions are:
Formulation of the adaptive control problem, which aims to minimize changes to the minimum driver set (MDS) as the network topology evolves, without requiring knowledge of future network changes.
Development of the Adaptive Control (AC) algorithm, which leverages a novel node control importance metric to efficiently compute and update the MDS while maintaining consistency with previous MDSs.
The AC algorithm was extensively evaluated on both synthetic and real-world dynamic networks. The results demonstrate that AC outperforms the state-of-the-art maximum matching-based (MM) algorithm, especially on networks with gradual topological changes. The performance advantage of AC is attributed to its ability to prioritize stable and consistent driver nodes, thereby minimizing disruptions to the control scheme as the network evolves.
The adaptive control approach presented in this work is a significant advancement in the field of dynamic network control, providing a practical and effective solution for real-world applications where network topologies are unpredictable.
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