Malware propagation in large-scale networks

Shui Yu; Guofei Gu; Ahmed Barnawi; Song Guo; Ivan Stojmenovic

doi:10.1109/TKDE.2014.2320725

Malware propagation in large-scale networks

Shui Yu^*, Guofei Gu, Ahmed Barnawi, Song Guo, Ivan Stojmenovic

^*Corresponding author for this work

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

125 Citations (Scopus)

Abstract

Malware is pervasive in networks, and poses a critical threat to network security. However, we have very limited understanding of malware behavior in networks to date. In this paper, we investigate how malware propagates in networks from a global perspective. We formulate the problem, and establish a rigorous two layer epidemic model for malware propagation from network to network. Based on the proposed model, our analysis indicates that the distribution of a given malware follows exponential distribution, power law distribution with a short exponential tail, and power law distribution at its early, late and final stages, respectively. Extensive experiments have been performed through two real-world global scale malware data sets, and the results confirm our theoretical findings.

Original language	English
Article number	6807753
Pages (from-to)	170-179
Number of pages	10
Journal	IEEE Transactions on Knowledge and Data Engineering
Volume	27
Issue number	1
DOIs	https://doi.org/10.1109/TKDE.2014.2320725
Publication status	Published - 1 Jan 2015
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2014 IEEE.

Keywords

Malware
Modelling
Power law
Propagation

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1109/TKDE.2014.2320725

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title = "Malware propagation in large-scale networks",

abstract = "Malware is pervasive in networks, and poses a critical threat to network security. However, we have very limited understanding of malware behavior in networks to date. In this paper, we investigate how malware propagates in networks from a global perspective. We formulate the problem, and establish a rigorous two layer epidemic model for malware propagation from network to network. Based on the proposed model, our analysis indicates that the distribution of a given malware follows exponential distribution, power law distribution with a short exponential tail, and power law distribution at its early, late and final stages, respectively. Extensive experiments have been performed through two real-world global scale malware data sets, and the results confirm our theoretical findings.",

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AU - Yu, Shui

AU - Gu, Guofei

AU - Barnawi, Ahmed

AU - Guo, Song

AU - Stojmenovic, Ivan

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N2 - Malware is pervasive in networks, and poses a critical threat to network security. However, we have very limited understanding of malware behavior in networks to date. In this paper, we investigate how malware propagates in networks from a global perspective. We formulate the problem, and establish a rigorous two layer epidemic model for malware propagation from network to network. Based on the proposed model, our analysis indicates that the distribution of a given malware follows exponential distribution, power law distribution with a short exponential tail, and power law distribution at its early, late and final stages, respectively. Extensive experiments have been performed through two real-world global scale malware data sets, and the results confirm our theoretical findings.

AB - Malware is pervasive in networks, and poses a critical threat to network security. However, we have very limited understanding of malware behavior in networks to date. In this paper, we investigate how malware propagates in networks from a global perspective. We formulate the problem, and establish a rigorous two layer epidemic model for malware propagation from network to network. Based on the proposed model, our analysis indicates that the distribution of a given malware follows exponential distribution, power law distribution with a short exponential tail, and power law distribution at its early, late and final stages, respectively. Extensive experiments have been performed through two real-world global scale malware data sets, and the results confirm our theoretical findings.

KW - Malware

KW - Modelling

KW - Power law

KW - Propagation

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DO - 10.1109/TKDE.2014.2320725

M3 - Journal Article

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JO - IEEE Transactions on Knowledge and Data Engineering

JF - IEEE Transactions on Knowledge and Data Engineering

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Malware propagation in large-scale networks

Abstract

Bibliographical note

Keywords

UN SDGs

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