Optimal control strategies depending on interest level for the spread of rumor. (English) Zbl 1417.49052
Summary: Many media channels such as broadcast, newspaper, and social networks diffuse a variety of information which can cause spread of many rumors. There are social damage and economic damage due to the spread of rumors. Thus one needs to establish strategies for controlling the rumors. We first propose rumor model with three control strategies for preventing the spread of rumor, (1) announcing the truth before ignorant receives rumor, (2) punishing spreaders, and (3) deleting information of the rumor in media, and consider optimal control problems to minimize the number of spreaders while minimizing the cost of three control strategies for preventing the spread of rumors. The analysis of optimal control problems is conducted as Pontryagin’s Maximum Principle. Furthermore, adapted optimal control is performed to investigate the effect of three controls under isoperimetric constraints. By using numerical simulations, we compare the number of spreaders before and after applying the three controls and
confirm when and how each control should be applied with respect to the interest level of rumor. The lower the interest level of rumor is, the greater the number of spreaders drops after the three controls are applied. In terms of timing of three controls, control (1) should be applied in the early stage of rumor spreading and control (2) is required when the rumors spread the most. After the rumors spread the most, control (3) is needed. Commonly the higher the interest level is, the more controls (1) and (2) are required. On the other hand, control (3) is needed a lot when the interest level is low.
MSC:
| 49N90 | Applications of optimal control and differential games |
| 91D10 | Models of societies, social and urban evolution |
References:
| [1] | Doer, B.; Fouz, M.; Friedrich, T., Why rumors spread so quickly in social networks, Communications of the ACM, 55, 6, 70-75 (2012) · doi:10.1145/2184319.2184338 |
| [2] | Kimmel, A. J., Rumors and rum or control: A manager’s guide to understanding and combatting rumors, Rumors and Rumor Control: A Manager’s Guide to Understanding and Combatting Rumors, 1-256 (2003) · doi:10.4324/9781410609502 |
| [3] | Daley, D. J.; Kendall, D. G., Epidemics and Rumours [49], Nature, 204, 4963, 1118 (1964) · doi:10.1038/2041118a0 |
| [4] | Maki, D. P.; Thompson, M., Mathematical Models and Applications: With Emphasis on the Social, Life, and Management Sciences (1973), Englewood Cliffs, NJ, USA: Prentice Hall, Englewood Cliffs, NJ, USA |
| [5] | Kawachi, K., Deterministic models for rumor transmission, Nonlinear Analysis: Real World Applications, 9, 5, 1989-2028 (2008) · Zbl 1156.91460 · doi:10.1016/j.nonrwa.2007.06.004 |
| [6] | Kawachi, K.; Seki, M.; Yoshida, H.; Otake, Y.; Warashina, K.; Ueda, H., A rumor transmission model with various contact interactions, Journal of Theoretical Biology, 253, 1, 55-60 (2008) · Zbl 1398.91483 · doi:10.1016/j.jtbi.2007.11.024 |
| [7] | Huo, L.; Huang, P.; Guo, C.-x., Analyzing the dynamics of a rumor transmission model with incubation, Discrete Dynamics in Nature and Society (2012) · Zbl 1244.91079 · doi:10.1155/2012/328151 |
| [8] | Huo, L.; Lin, T.; Huang, P., Dynamical behavior of a rumor transmission model with psychological effect in emergency event, Abstract and Applied Analysis, 2013 (2013) · Zbl 1291.91181 · doi:10.1155/2013/282394 |
| [9] | Zhao, X.; Wang, J., Dynamical model about rumor spreading with medium, Discrete Dynamics in Nature and Society, 2013 (2013) · Zbl 1264.91109 · doi:10.1155/2013/586867 |
| [10] | Zhao, X.-X.; Wang, J.-Z., Dynamical behaviors of rumor spreading model with control measures, Abstract and Applied Analysis (2014) · Zbl 1406.91329 · doi:10.1155/2014/247359 |
| [11] | Lukes, D. L., Differential Equation Classical to Controlled Mathematical in Science And Engineering (1982) · Zbl 0509.34003 |
| [12] | Zaman, G.; Han Kang, Y.; Jung, I. H., Stability analysis and optimal vaccination of an SIR epidemic model, BioSystems, 93, 3, 240-249 (2008) · doi:10.1016/j.biosystems.2008.05.004 |
| [13] | Ullah, R.; Zaman, G.; Islam, S., Prevention of influenza pandemic by multiple control strategies, Journal of Applied Mathematics, 2012 (2012) · Zbl 1263.92030 · doi:10.1155/2012/294275 |
| [14] | Kamien, M. I.; Schwartz, N. L., Dynamic Optimization: The Calculus of Variations And Optimal Control in Economics And Management (2012), Courier Corporation · Zbl 0709.90001 |
| [15] | Lenhart, S. M.; Workman, J. T., Optimal Control Applied to Biological Models (2007), CRC Press · Zbl 1291.92010 |
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