|
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|
|
Библиографический список
|
|
| |
| 1. |
Lorenz E. N., “Deterministic nonperiodic flow”, Journal of the Atmospheric Sciences, 20:2 (1963), 130–141     |
| 2. |
Bak P., Tang C., Wiesenfeld K., “Self-organized criticality: An explanation of the 1/f noise”, Phys. Rev. Lett., 59:4 (1987), 381–384  |
| 3. |
May R., “Simple mathematical models with very complicated dynamics”, Nature, 261:5560 (1976), 459–467 |
| 4. |
Collier N., “RePast: An extensible framework for agent simulation”, Natural Resources and Environmental Issues, 8 (2001), 4 https://digitalcommons.usu.edu/nrei/vol8/iss1/4 (accessed 7 March 2019) |
| 5. |
Tisue S., Wilensky U., “NetLogo: A simple environment for modeling complexity”, International Conference on Complex Systems, 21 (2004), 16–21 |
| 6. |
Luke S., Cioffi-Revilla C., Panait L., Sullivan K., Balan G., “Mason: A multiagent simulation environment”, Simulation, 81:7 (2005), 517–527 |
| 7. |
Trevorrow A., Rokicki T., Hutton T., Greene D., Summers J., Verver M., Golly – a game of life simulator, http://golly.sourceforge.net/ (accessed 7 March 2019) |
| 8. |
Sayama H., “PyCX: A Python-based simulation code repository for complex systems education”, Complex Adaptive Systems Modeling, 1 (2013), 2 |
| 9. |
Waldrop M. M., Complexity: The Emerging Science at the Edge of Order and Chaos, Simon & Schuster, N. Y., 1992, 380 pp. |
| 10. |
Sayama H., Introduction to the Modeling and Analysis of Complex Systems, SUNY Binghamton, N. Y., 2015, 478 pp. |
| 11. |
Hamann H., Swarm Robotics: A Formal Approach, Springer International Publishing, N. Y., 2018, 210 pp. |
| 12. |
Fitzhugh R., “Impulses and Physiological States in Theoretical Models of Nerve Membrane”, Biophysical Journal, 1:6 (1961), 445–466 |
| 13. |
Drossel B., Schwabl F., “Self-organized criticality in a forest-fire model”, Physica A : Statistical Mechanics and its Applications, 191:1 (1992), 47–50 |
| 14. |
Strogatz S., Sync: The Emerging Science of Spontaneous Order, Penguin, N. Y., 2004, 339 pp. |
| 15. |
Wolfram S., A New Kind of Science, Wolfram Media, N. Y., 2002, 1197 pp. |
| 16. |
Bjorner A., Lovasz L., Shor P. W., “Chip-firing games on graphs”, European Journal of Combinatorics, 12:4 (1991), 283–291 |
| 17. |
Clifford P., Sudbury A., “A model for spatial conflict”, Biometrika, 60:3 (1973), 581–588 |
| 18. |
Kagel H. J., Roth E. A., The Handbook of Experimental Economics, Princeton Univ. Press, N. J., 1997, 744 pp. |
| 19. |
Levin S. A., “Public goods in relation to competition, cooperation, and spite”, PNAS, 111, Supplement 3 (2014), 10838–10845 |
| 20. |
Obolski U., Lewin-Epstein O., Even-Tov E., Ram Y., Hadany L., “With a little help from my friends: cooperation can accelerate the rate of adaptive valley crossing”, BMC Evolutionary Biology, 17 (2017), 143 |
| 21. |
Pfeiffer T., Bonhoeffer S., “An evolutionary scenario for the transition to undifferentiated multicellularity”, PNAS, 100:3 (2003), 1095–1098 |
| 22. |
Kreft J.-U., “Biofilms promote altruism”, Microbiology, 150:8 (2004), 2751–2760 |
| 23. |
Cesta A., Miceli M., Rizzo P., “Coexisting agents: Experiments on basic interaction attitude”, Journal of Intelligent Systems, 11:1 (2001), 1–42 |
| 24. |
Ivanko E., “Is evolution always “egolution”: Discussion of evolutionary efficiency of altruistic energy exchange”, Ecological Complexity, 34 (2018), 1–8 |
| 25. |
Hamilton W. D., “The genetical evolution of social behaviour”, Journal of Theoretical Biology, 7:1 (1964), 1–52 |
| 26. |
Trivers R. L., “The evolution of reciprocal altruism”, The Quarterly Review of Biology, 46:1 (1971), 35–57 |
| 27. |
Axelrod R., Hamilton W. D., “The evolution of cooperation”, Science, 211:4489 (1981), 1390–1396 |
| 28. |
Nowak M. A., “Five rules for the evolution of cooperation”, Science, 314:5805 (2006), 1560–1563 |
| 29. |
Stuart A., West A., Griffin S., Gardner A., “Evolutionary explanations for cooperation”, Current Biology, 17:16 (2007), R661–R672 |
| 30. |
Lewin-Epstein O., Aharonov R., Hadany L., “Microbes can help explain the evolution of host altruism”, Nature Communications, 8 (2017), 14040 |
| 31. |
Esteban-Fernández de Ávila B., Angsantikul P., Ramírez-Herrera D. E., Soto F., Teymourian H., Dehaini D., Chen Y., Zhang L., Wang J., “Hybrid biomembrane–functionalized nanorobots for concurrent removal of pathogenic bacteria and toxins”, Science Robotics, 3:18 (2018), eaat0485 |
| 32. |
Morice C. P., Kennedy J. J., Rayner N. A., Jones P. D., “Quantifying uncertainties in global and regional temperature change using an ensemble of observational estimates: The HadCRUT4 dataset”, Journal of Geophysical Research : Atmospheres, 117 (2012), D08101 |
| 33. |
Makeham W. M., “On the Law of Mortality and the Construction of Annuity Tables”, The Assurance Magazine, and Journal of the Institute of Actuaries, 8:6 (1860), 301–310 |
| 34. |
MacArthur R. H., Wilson E. O., The theory of island biogeography, Princeton Univ. Press, N. J., 2001, 224 pp. |
| 35. |
Aurenhammer F., Klein R., Lee D.-T., Voronoi Diagrams and Delaunay Triangulations, World Scientific Publishing, N. J., 2013, 348 pp. |
| 36. |
Uran cluster, http://parallel.uran.ru/node/419 (accessed 7 March 2019) |
| 37. |
Simon D., Evolutionary Optimization Algorithms, Wiley, N. Y., 2013, 772 pp. |
| 38. |
Schapire R. E., Freund Y. Y., Boosting: Foundations and Algorithms, The MIT Press, Cambridge, 2012, 544 pp. |
