Distributed Byzantine-Resilient Multiple-Message Dissemination in Wireless Networks

被引:22
作者
Zou, Yifei [1 ]
Yu, Dongxiao [1 ]
Yu, Jiguo [2 ,3 ]
Zhang, Yong [4 ]
Dressler, Falko [5 ]
Cheng, Xiuzhen [1 ]
机构
[1] Shandong Univ, Inst Intelligent Comp, Sch Comp Sci & Technol, Qingdao 266237, Peoples R China
[2] Qilu Univ Technol, Shandong Acad Sci, Sch Comp Sci & Technol, Jinan 250014, Peoples R China
[3] Natl Super Comp Ctr Jinan, Shandong Comp Sci Ctr, Jinan 250014, Peoples R China
[4] Chinese Acad Sci, Shenzhen Inst Adv Technol, Shenzhen 518055, Peoples R China
[5] TU Berlin, Sch Elect Engn & Comp Sci, D-10587 Berlin, Germany
来源
IEEE-ACM TRANSACTIONS ON NETWORKING | 2021年 / 29卷 / 04期
关键词
Protocols; Jamming; Wireless networks; Interference; Signal to noise ratio; Wireless sensor networks; Upper bound; Multiple-message dissemination; Byzantine-resilient; SINR model; COMPETITIVE MAC; BROADCAST; CONSENSUS;
D O I
10.1109/TNET.2021.3069324
中图分类号
TP3 [计算技术、计算机技术];
学科分类号
0812 ;
摘要
The byzantine model is widely used to depict a variety of node faults in networks. Previous studies on byzantine-resilient protocols in wireless networks assume reliable communications and do not consider the jamming behavior of byzantine nodes. Such jamming, however, is a very critical and realistic behavior to be considered in modern wireless networks. In this paper, for the first time, we integrate the jamming behavior of byzantine nodes into the network setting. We show that, in this much more comprehensive and harsh model, efficient distributed communication protocols can be still devised with elaborate protocol design. In particular, we developed an algorithm that can accomplish the basic multiple-message dissemination task close to the optimal solution in terms of running time. Empirical results validate the byzantine-resilience and efficiency of our algorithm.
引用
收藏
页码:1662 / 1675
页数:14
相关论文
共 38 条
[1]  
Alchieri EAP, 2008, LECT NOTES COMPUT SC, V5401, P22, DOI 10.1007/978-3-540-92221-6_4
[2]  
Augustine J., 2013, Proceedings of the 2013 ACM Symposium on Principles of Distributed Computing. PODC'13, DOI DOI 10.1145/2484239.2484275
[3]   MULTIPLE COMMUNICATION IN MULTIHOP RADIO NETWORKS [J].
BARYEHUDA, R ;
ISRAELI, A ;
ITAI, A .
SIAM JOURNAL ON COMPUTING, 1993, 22 (04) :875-887
[4]   Reliable Broadcast in Dynamic Networks with Locally Bounded Byzantine Failures [J].
Bonomi, Silvia ;
Farina, Giovanni ;
Tixeuil, Sebastien .
STABILIZATION, SAFETY, AND SECURITY OF DISTRIBUTED SYSTEMS, SSS 2018, 2018, 11201 :170-185
[5]  
Brauer S., 2016, 2016 IEEE C STAND CO, P1
[6]  
Brown T. X., 2006, MOBIHOC 2006. Proceedings of the Seventh ACM International Symposium on Mobile Ad Hoc Networking and Computing, P120, DOI 10.1145/1132905.1132919
[7]   Trading Private Range Counting over Big IoT Data [J].
Cai, Zhipeng ;
He, Zaobo .
2019 39TH IEEE INTERNATIONAL CONFERENCE ON DISTRIBUTED COMPUTING SYSTEMS (ICDCS 2019), 2019, :144-153
[8]   A Differential-Private Framework for Urban Traffic Flows Estimation via Taxi Companies [J].
Cai, Zhipeng ;
Zheng, Xu ;
Yu, Jiguo .
IEEE TRANSACTIONS ON INDUSTRIAL INFORMATICS, 2019, 15 (12) :6492-6499
[9]   A Private and Efficient Mechanism for Data Uploading in Smart Cyber-Physical Systems [J].
Cai, Zhipeng ;
Zheng, Xu .
IEEE TRANSACTIONS ON NETWORK SCIENCE AND ENGINEERING, 2020, 7 (02) :766-775
[10]   Collective Data-Sanitization for Preventing Sensitive Information Inference Attacks in Social Networks [J].
Cai, Zhipeng ;
He, Zaobo ;
Guan, Xin ;
Li, Yingshu .
IEEE TRANSACTIONS ON DEPENDABLE AND SECURE COMPUTING, 2018, 15 (04) :577-590
1234