Abstract

Targeted immunization of centralized nodes in large-scale networks has attracted significant attention. However, in real-world scenarios, knowledge and observations of the network may be limited, thereby precluding a full assessment of the optimal nodes to immunize (or quarantine) in order to avoid epidemic spreading such as that of the current coronavirus disease (COVID-19) epidemic. Here, we study a novel immunization strategy where only n nodes are observed at a time and the most central among these n nodes is immunized. This process can globally immunize a network. We find that even for small n (≈10) there is significant improvement in the immunization (quarantine), which is very close to the levels of immunization with full knowledge. We develop an analytical framework for our method and determine the critical percolation threshold pc and the size of the giant component P∞ for networks with arbitrary degree distributions P(k). In the limit of n → ∞ we recover prior work on targeted immunization, whereas for n = 1 we recover the known case of random immunization. Between these two extremes, we observe that, as n increases, pc increases quickly towards its optimal value under targeted immunization with complete information. In particular, we find a new general scaling relationship between |pc(∞) − pc(n)| and n as |pc(∞) − pc(n)| ∼ n−1exp(−αn). For scale-free (SF) networks, where P(k) ∼ k−γ, 2 < γ < 3, we find that pc has a transition from zero to nonzero when n increases from n = 1 to O(log N) (where N is the size of the network). Thus, for SF networks, having knowledge of ≈log N nodes and immunizing the most optimal among them can dramatically reduce epidemic spreading. We also demonstrate our limited knowledge immunization strategy on several real-world networks and confirm that in these real networks, pc increases significantly even for small n.

Highlights

  • Studies in networks found that immunizing real networks against an epidemic is highly challenging due to the existence of hubs which prevent eradication of the virus even if many nodes are immunized [29,30,31]

  • Connectivity of components is critical for maintaining the functioning of infrastructures like the internet [9] and transportation networks [10], as well as for understanding immunization against epidemics [11] and the spread of information in social systems [12]

  • Researchers have long focused on how a network can be optimally immunized or fragmented to prevent epidemics or to maintain infrastructure resilience [3, 13,14,15,16,17]

Read more

Summary

Efficient network immunization under limited knowledge

Yangyang Liu,1, ∗ Hillel Sanhedrai,2, ∗ GaoGao Dong,3, † Louis M. Connectivity of components is critical for maintaining the functioning of infrastructures like the internet [9] and transportation networks [10], as well as for understanding immunization against epidemics [11] and the spread of information in social systems [12] Due to this importance, researchers have long focused on how a network can be optimally immunized or fragmented to prevent epidemics or to maintain infrastructure resilience [3, 13,14,15,16,17]. If these hub nodes, largest degree nodes, are targeted, the network can reach immunity [29, 31, 32] These previous models of targeted immunization have assumed full knowledge of the network structure which in many cases is not available. This means that immunization with small n (not knowing the whole structure) can dramatically improve the immunization

Limited knowledge
The giant component S can be found by

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.