We consider the effect of inducement to vaccinate during the spread of an infectious disease on complex networks. Suppose that public resources are finite and that only a small proportion of individuals can be vaccinated freely (complete subsidy), for the remainder of the population vaccination is a voluntary behavior --- and each vaccinated individual carries a perceived cost. We ask whether the classical targeted subsidy strategy is definitely better than the random strategy: does targeting subsidy at individuals perceived to be with the greatest risk actually help? With these questions, we propose a model to investigate the \emph{interaction effects} of the subsidy policies and individuals responses when facing subsidy policies on the epidemic dynamics on complex networks. In the model, a small proportion of individuals are freely vaccinated according to either the targeted or random subsidy policy, the remainder choose to vaccinate (or not) based on voluntary principle and update their vaccination decision via an imitation rule. Our findings show that the targeted strategy is only advantageous when individuals prefer to imitate the subsidized individuals' strategy. Otherwise, the effect of the targeted policy is worse than the random immunization, since individuals preferentially select non-subsidized individuals as the imitation objects. More importantly, we find that under the targeted subsidy policy, increasing the proportion of subsidized individuals may increase the final epidemic size. We further define social cost as the sum of the costs of vaccination and infection, and study how each of the two policies affect the social cost. Our result shows that there exist some optimal intermediate regions leading to the minimal social cost.
[1]
New Journal of Physics The
,
2007
.
[2]
Physics Reports
,
2022
.
[3]
M. Lindauer.
Ethology.
,
1962,
Annual review of psychology.
[4]
E. Riedmann.
Human Vaccines & Immunotherapeutics
,
2013,
Human Vaccines & Immunotherapeutics.
[5]
J. Herskowitz,et al.
Proceedings of the National Academy of Sciences, USA
,
1996,
Current Biology.
[6]
J. Rogers.
Chaos
,
1876,
Molecular Vibrations.
[7]
A. Châtelain,et al.
The European Physical Journal D
,
1999
.
[8]
E. V. Bergen,et al.
Proceedings of the Royal Society B : Biological Sciences
,
2013
.
[9]
K. F. Meyer,et al.
Preventive veterinary medicine.
,
1948,
Journal of the American Veterinary Medical Association.
[10]
E. Kandel,et al.
Proceedings of the National Academy of Sciences of the United States of America. Annual subject and author indexes.
,
1990,
Proceedings of the National Academy of Sciences of the United States of America.
[11]
G. G. Stokes.
"J."
,
1890,
The New Yale Book of Quotations.
[12]
C. Heyes,et al.
Social learning in animals : the roots of culture
,
1996
.
[13]
S. Snyder,et al.
Proceedings of the National Academy of Sciences
,
1999
.
[14]
October I.
Physical Review Letters
,
2022
.
[15]
O. Bagasra,et al.
Proceedings of the National Academy of Sciences
,
1914,
Science.