NUMERICAL-ANALYTIC SOLUTION OF ONE MODELING PROBLEM OF FRACTIONAL-DIFFERENTIAL DYNAMICS OF COMPUTER VIRUSES

Q3 Engineering

Journal of Automation and Information Sciences Pub Date : 2022-01-01 DOI:10.34229/1028-0979-2022-1-6

V. Bogaenko, Vladimir Bulavatsky

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Abstract

The paper considers the problem of modeling the dynamics of computer viruses spreading using a model based on the mathematical theory of biological epidemics. The urgency of the considered problem arises from the need to build effective anti-virus protection systems for computer networks based on the results of mathematical modeling of the spread of malicious software. We consider the SIES-model (Gan C., Yang X., Zhu Q.), that studies spread dynamics of computer viruses separating the influence of the action of computers accessible and unavailable on the Internet. In order to take into account non-local effects in this model, in particular memory effects, its modification on the ideas of the theory of fractional-order integro-differentiation is proposed. The technique of obtaining a numerical-analytical solution of the problem of modeling of computer viruses spread dynamics on the base of the fractional-differential counterpart of the SIES-model is presented. Closed forms solutions of the problems for the number of vulnerable and external computers are obtained, and a finite-difference scheme of the fractional Adams method for the problem of determining the number of infected computers is constructed. The results of computational experiments based on the developed technique of numerical-analytical solution show that there is a subdiffusion evolution of the system to the steady state. At the same time, for the number of external computers, a fast short-term growth is observed at the initial stages of process development with subsequent smooth and slow decrease towards the steady state. For medium and large values of the time variable, the evolution of the number of infected computers to the steady state occurs in an ultra-slow mode. Thus, the proposed technique makes it possible to study the families of dynamic reactions in the process of computer viruses spreading, including fast transient processes and ultra-slow evolution of systems with memory.

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计算机病毒分数-微分动力学建模问题的数值解析解

本文考虑了利用基于生物流行病数学理论的模型对计算机病毒传播动力学进行建模的问题。所考虑的问题的紧迫性源于需要基于恶意软件传播的数学建模结果为计算机网络建立有效的防病毒保护系统。我们考虑了SIES模型（Gan C.，Yang X.，Zhu Q.），该模型研究了计算机病毒的传播动力学，分离了互联网上可访问和不可访问计算机的影响。为了考虑该模型中的非局部效应，特别是记忆效应，提出了对分数阶积分微分理论思想的修正。提出了在SIES模型的分数微分对应物的基础上获得计算机病毒传播动力学建模问题的数值解析解的技术。获得了易受攻击计算机和外部计算机数量问题的闭式解，并构造了确定受感染计算机数量的分数Adams方法的有限差分格式。基于所发展的数值解析解技术的计算实验结果表明，系统存在向稳态的亚扩散演化。同时，对于外部计算机的数量，在过程发展的初始阶段观察到快速的短期增长，随后平稳缓慢地减少到稳定状态。对于时间变量的中值和大值，受感染计算机的数量向稳态的演变是以超慢模式发生的。因此，所提出的技术使研究计算机病毒传播过程中的动态反应家族成为可能，包括具有记忆的系统的快速瞬态过程和超慢速进化。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Automation and Information Sciences AUTOMATION & CONTROL SYSTEMS-

自引率

0.00%

发文量

审稿时长

6-12 weeks

期刊介绍： This journal contains translations of papers from the Russian-language bimonthly "Mezhdunarodnyi nauchno-tekhnicheskiy zhurnal "Problemy upravleniya i informatiki". Subjects covered include information sciences such as pattern recognition, forecasting, identification and evaluation of complex systems, information security, fault diagnosis and reliability. In addition, the journal also deals with such automation subjects as adaptive, stochastic and optimal control, control and identification under uncertainty, robotics, and applications of user-friendly computers in management of economic, industrial, biological, and medical systems. The Journal of Automation and Information Sciences will appeal to professionals in control systems, communications, computers, engineering in biology and medicine, instrumentation and measurement, and those interested in the social implications of technology.