Optimal size of a complex network

H. Hong; Beom Jun Kim; M. Y. Choi

doi:10.1103/PhysRevE.67.046101

Optimal size of a complex network

H. Hong^*
, Beom Jun Kim
, M. Y. Choi

^*Corresponding author for this work

Department of Physics

Korea Institute for Advanced Study
Ajou University
Seoul National University

Research output: Contribution to journal › Journal article › peer-review

Abstract

We investigate the response behavior of an Ising system, driven by an oscillating field, on a small-world network, with particular attention to the effects of the system size. The responses of the magnetization to the driving field are probed by means of Monte Carlo dynamic simulations with the varied rewiring probability. It is found that at low and high temperatures the occupancy ratio, measuring how many spins follow the driving field, behaves monotonically with the system size. At intermediate temperatures, on the other hand, the occupancy ratio first grows and then reduces as the size is increased, displaying a resonancelike peak at a finite value of the system size. In all cases, further increase of the size eventually leads to saturation to finite values; the size at which saturation emerges is observed to depend on the temperature, similarly to the correlation length of the system.

Original language	English
Pages (from-to)	5
Number of pages	1
Journal	Physical Review E
Volume	67
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevE.67.046101
State	Published - 2003

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title = "Optimal size of a complex network",

abstract = "We investigate the response behavior of an Ising system, driven by an oscillating field, on a small-world network, with particular attention to the effects of the system size. The responses of the magnetization to the driving field are probed by means of Monte Carlo dynamic simulations with the varied rewiring probability. It is found that at low and high temperatures the occupancy ratio, measuring how many spins follow the driving field, behaves monotonically with the system size. At intermediate temperatures, on the other hand, the occupancy ratio first grows and then reduces as the size is increased, displaying a resonancelike peak at a finite value of the system size. In all cases, further increase of the size eventually leads to saturation to finite values; the size at which saturation emerges is observed to depend on the temperature, similarly to the correlation length of the system.",

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AU - Hong, H.

AU - Kim, Beom Jun

AU - Choi, M. Y.

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AB - We investigate the response behavior of an Ising system, driven by an oscillating field, on a small-world network, with particular attention to the effects of the system size. The responses of the magnetization to the driving field are probed by means of Monte Carlo dynamic simulations with the varied rewiring probability. It is found that at low and high temperatures the occupancy ratio, measuring how many spins follow the driving field, behaves monotonically with the system size. At intermediate temperatures, on the other hand, the occupancy ratio first grows and then reduces as the size is increased, displaying a resonancelike peak at a finite value of the system size. In all cases, further increase of the size eventually leads to saturation to finite values; the size at which saturation emerges is observed to depend on the temperature, similarly to the correlation length of the system.

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DO - 10.1103/PhysRevE.67.046101

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SN - 2470-0045

VL - 67

SP - 5

JO - Physical Review E

JF - Physical Review E

IS - 4

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Optimal size of a complex network

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