Abstract
In real systems, some damaged nodes can spontaneously become active again when recovered from themselves or their active neighbours. However, the spontaneous dynamical recovery of complex networks that suffer a local failure has not yet been taken into consideration. To model this recovery process, we develop a framework to study the resilience behaviours of the network under a localised attack (LA). Since the nodes’ state within the network affects the subsequent dynamic evolution, we study the dynamic behaviours of local failure propagation and node recoveries based on this memory characteristic. It can be found that the fraction of active nodes switches back and forth between high network activity and low network activity, which leads to the spontaneous emergence of phase-flipping phenomena. These behaviours can be found in a random regular network, Erdős-Rényi network and Scale-free network, which shows that these three types of networks have the same or different resilience behaviours under an LA and random attack. These results will be helpful for studying the spontaneous recovery real systems under an LA. Our work provides insight into understanding the recovery process and a protection strategy of various complex systems from the perspective of damaged memory.
Highlights
Network science has attracted a lot of attention, and it can map the actual system into a network by treating individuals/entities as nodes and the relationship between individuals as edges [1,2,3]
We assume that the p fraction of nodes subject to localised failure at each time, which means that these inactive p · N nodes are independent of other inactive nodes
This is assumed as the internal failure, and the external failure is dependent on nodes’ active neighbours
Summary
Network science has attracted a lot of attention, and it can map the actual system into a network by treating individuals/entities as nodes and the relationship between individuals as edges [1,2,3]. Shang proposed the recovery strategy for complex networks under random failures by considering that a fraction of the failed nodes are localised and recovered [21]. Most researches did not consider the dynamical recovery impact of different failure mechanisms and only studied the network under random failures.
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