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Energy cost study for controlling complex social networks with conformity behavior

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arxiv 2101.03828 v6 pith:S2EJ6K7I submitted 2021-01-11 physics.soc-ph

Energy cost study for controlling complex social networks with conformity behavior

classification physics.soc-ph
keywords systemscomplexconformitycontrollingenergysocialcontrolcost
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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In order to understand controlling a complex system, an estimation of the required effort needed to achieve control is vital. Previous works have addressed this issue by studying the scaling laws of energy cost in a general way with continuous-time linear dynamics. However, continuous-time linear dynamics is unable to capture conformity behavior, which is common in many complex social systems. Therefore, to understand controlling social systems with conformity, discrete-time modelling is used and the energy cost scaling laws are derived. The results are validated numerically with model and real networks. In addition, the energy costs needed for controlling systems with and without conformity are compared, and it was found that controlling networked systems with conformity features always requires less control energy. Finally, it is shown through simulations that heterogeneous scale-free networks are less controllable, requiring a higher number of minimum drivers. Since the conformity-based model relates to various complex systems, such as flocking, or evolutionary games, the results of this paper represent a step forward towards developing realistic control of complex social systems.

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