Volume 9 , Issue 2 , PP: 51-59, 2022 | Cite this article as | XML | Html | PDF | Full Length Article
Ahmed Sleem 1 * , Ibrahim Elhenawy 2
Doi: https://doi.org/10.54216/JCIM.090205
This paper proposes a privacy-preserving federated learning approach to enhance cyber threat intelligence sharing. Cyber threats are becoming more sophisticated and are posing serious security risks to organizations. Sharing threat intelligence information can help to detect and mitigate these threats quickly. However, privacy concerns and data protection regulations hinder the sharing of sensitive information. Federated learning is a promising approach that allows multiple parties to collaborate in building a global model while preserving data privacy. We propose a framework that utilizes federated learning to train a global threat intelligence model without compromising the privacy of individual organizations' data. Our approach also includes a differential privacy mechanism to ensure the anonymity of the participating organizations. We demonstrate the effectiveness of our approach through experiments conducted on real-world datasets, showing that it achieves high accuracy while maintaining data privacy. The proposed approach has the potential to facilitate more effective and secure cyber threat intelligence sharing among organizations.
Cyber Threat , Privacy-Preserving Federated Learning , Intelligent Systems , Cybersecurity
[1] Dash, B., Sharma, P., & Ali, A. (2022). Federated Learning for Privacy-Preserving: A Review of PII Data Analysis in Fintech. International Journal of Software Engineering & Applications (IJSEA), 13(4).
[2] Aïvodji, U. M., Gambs, S., & Martin, A. (2019, May). IOTFLA: A secured and privacy-preserving smart home architecture implementing federated learning. In 2019 IEEE security and privacy workshops (SPW) (pp. 175-180). IEEE.
[3] Qi, Yuanhang, M. Shamim Hossain, Jiangtian Nie, and Xuandi Li. "Privacy-preserving blockchain-based federated learning for traffic flow prediction." Future Generation Computer Systems 117 (2021): 328-337.
[4] Abdel-Basset, Mohamed, Nour Moustafa, and Hossam Hawash. "Privacy-Preserved Cyberattack Detection in Industrial Edge of Things (IEoT): A Blockchain -Orchestrated Federated Learning Approach." IEEE Transactions on Industrial Informatics 18, no. 11 (2022): 7920-7934.
[5] Liu, Ziyao, Jiale Guo, Wenzhuo Yang, Jiani Fan, Kwok-Yan Lam, and Jun Zhao. "Privacy-preserving aggregation in federated learning: A survey." IEEE Transactions on Big Data (2022).
[6] Zhang, Huiru, Guangshun Li, Yue Zhang, Keke Gai, and Meikang Qiu. "Blockchain-based privacypreserving medical data sharing scheme using federated learning." In Knowledge Science, Engineering and Management: 14th International Conference, KSEM 2021, Tokyo, Japan, August 14–16, 2021, Proceedings, Part III 14, pp. 634-646. Springer International Publishing, 2021.
[7] Qin, Zhenquan, Jin Ye, Jie Meng, Bingxian Lu, and Lei Wang. "Privacy-preserving blockchain-based federated learning for marine Internet of Things." IEEE Transactions on Computational Social Systems 9, no. 1 (2021): 159-173.
[8] Wang, Ruijin, Jinshan Lai, Zhiyang Zhang, Xiong Li, Pandi Vijayakumar, and Marimuthu Karuppiah. "Privacy-preserving federated learning for internet of medical things under edge computing." IEEE Journal of Biomedical and Health Informatics (2022).
[9] Lu, Shixiang, Zhiwei Gao, Qifa Xu, Cuixia Jiang, Aihua Zhang, and Xiangxiang Wang. "Class-imbalance privacy-preserving federated learning for decentralized fault diagnosis with biometric authentication." IEEE Transactions on Industrial Informatics 18, no. 12 (2022): 9101-9111.
[10] Abdel-Basset, Mohamed, Hossam Hawash, and Karam Sallam. "Federated threat-hunting approach for microservice-based industrial cyber-physical system." IEEE Transactions on Industrial Informatics 18, no. 3 (2021): 1905-1917.
[11] Yin, Lihua, Jiyuan Feng, Hao Xun, Zhe Sun, and Xiaochun Cheng. "A privacy-preserving federated learning for multiparty data sharing in social IoTs." IEEE Transactions on Network Science and Engineering 8, no. 3 (2021): 2706-2718.
[12] Wu, Xiang, Yongting Zhang, Minyu Shi, Pei Li, Ruirui Li, and Neal N. Xiong. "An adaptive federated learning scheme with differential privacy preserving." Future Generation Computer Systems 127 (2022): 362-372.
[13] Abdel-Basset, Mohamed, Nour Moustafa, Hossam Hawash, Imran Razzak, Karam M. Sallam, and Osama M. Elkomy. "Federated intrusion detection in blockchain-based smart transportation systems." IEEE Transactions on Intelligent Transportation Systems 23, no. 3 (2021): 2523-2537.
[14] Long, Guodong, Tao Shen, Yue Tan, Leah Gerrard, Allison Clarke, and Jing Jiang. "Federated learning for privacy-preserving open innovation future on digital health." In Humanity Driven AI: Productivity, Wellbeing, Sustainability and Partnership, pp. 113-133. Cham: Springer International Publishing, 2021.
[15] Lu, Xiaofeng, Yuying Liao, Pietro Lio, and Pan Hui. "Privacy-preserving asynchronous federated learning mechanism for edge network computing." IEEE Access 8 (2020): 48970-48981.
[16] Lu, Yunlong, Xiaohong Huang, Yueyue Dai, Sabita Maharjan, and Yan Zhang. "Federated learning for data privacy preservation in vehicular cyber-physical systems." IEEE Network 34, no. 3 (2020): 50-56.
[17] Huang, Jie, Cheng Xu, Zhaohua Ji, Shan Xiao, Teng Liu, Nan Ma, and Qinghui Zhou. "AFLPC: an asynchronous federated learning privacy-preserving computing model applied to 5G-V2X." Security and Communication Networks 2022 (2022).
[18] Zhang, Zehui, Cong Guan, Hui Chen, Xiangguo Yang, Wenfeng Gong, and Ansheng Yang. "Adaptive privacy-preserving federated learning for fault diagnosis in internet of ships." IEEE Internet of Things Journal 9, no. 9 (2021): 6844-6854.
[19] Awan, Sana, Fengjun Li, Bo Luo, and Mei Liu. "Poster: A reliable and accountable privacy-preserving federated learning framework using the blockchain." In Proceedings of the 2019 ACM SIGSAC conference on computer and communications security, pp. 2561-2563. 2019.
[20] Hao, Meng, Hongwei Li, Xizhao Luo, Guowen Xu, Haomiao Yang, and Sen Liu. "Efficient and privacyenhanced federated learning for industrial artificial intelligence." IEEE Transactions on Industrial Informatics 16, no. 10 (2019): 6532-6542.
[21] Wang, Naiyu, Wenti Yang, Xiaodong Wang, Longfei Wu, Zhitao Guan, Xiaojiang Du, and Mohsen Guizani. "A blockchain based privacy-preserving federated learning scheme for Internet of Vehicles." Digital Communications and Networks (2022).
[22] Wang, Naiyu, Wenti Yang, Zhitao Guan, Xiaojiang Du, and Mohsen Guizani. "Bpfl: A blockchain based privacy-preserving federated learning scheme." In 2021 IEEE Global Communications Conference (GLOBECOM), pp. 1-6. IEEE, 2021.
[23] Zhang, Linlin, Zehui Zhang, and Cong Guan. "Accelerating privacy-preserving momentum federated learning for industrial cyber-physical systems." Complex & Intelligent Systems 7 (2021): 3289-3301.
[24] Liu, Yi, J. Q. James, Jiawen Kang, Dusit Niyato, and Shuyu Zhang. "Privacy -preserving traffic flow prediction: A federated learning approach." IEEE Internet of Things Journal 7, no. 8 (2020): 7751-7763.
[25] Abdel-Basset, Mohamed, Hossam Hawash, and Nour Moustafa. "Toward Privacy Preserving Federated Learning in Internet of Vehicular Things: Challenges and Future Directions." IEEE Consumer Electronics Magazine 11, no. 6 (2021): 56-66.
[26] Wazzeh, Mohamad, Hakima Ould-Slimane, Chamseddine Talhi, Azzam Mourad, and Mohsen Guizani. "Privacy-preserving continuous authentication for mobile and iot systems using warmup-based federated learning." IEEE Network (2022).
[27] Abdel-Basset, Mohamed, Nour Moustafa, Hossam Hawash, Weiping Ding, Mohamed. "Federated learning for privacy-preserving Internet of Things." Deep Learning Techniques for IoT Security and Privacy (2022): 215-228.