Research on Cascading Faults of Hybrid Point-to-Point Power Information Network Based on Blockchain

doi:10.19596/j.cnki.1001-246x.8637

Abstract

Abstract:

By dividing the community of the power grid, the information network community is divided according to the current situation and the actual coupling relationship of the corresponding hierarchical partition construction of the power grid and the information network, and the node with the largest betweenness and the node with the largest degree of each community in the information network is selected for full connection. The power information interdependence network model based on the hybrid point-to-point structure of the blockchain, combined with the consensus mechanism of the blockchain, analyzes the advantages of the model, and uses the two attack strategies of high number attack and high betweenness attack to study the proposed interdependence The robustness of the network is compared with the traditional centralized control power information network and the fully decentralized point-to-point power information network. The research results show that the hybrid point-to-point power information interdependence network model can effectively reduce the communication overhead and consensus delay of the practical Byzantine fault-tolerant algorithm on the basis of improving the robustness of the network. In the hybrid peer-to-peer power information network, the system shows stronger vulnerability under the high-number attack mode.

Key words: blockchain, power network, cascading failure, community division, practical Byzantine fault tolerance

Fengping HOU, Yanli ZOU, Tanghuimei LIU, Zhiwei WANG, Shuyi TAN. Research on Cascading Faults of Hybrid Point-to-Point Power Information Network Based on Blockchain[J]. Chinese Journal of Computational Physics, 2023, 40(5): 633-642.

Figures/Tables 15

Fig.1 Diagram of power information dependency network model

Fig.2 Completely decentralized P2P network structure

Fig.3 Hybrid P2P network structure

Fig.4 Decentralized P2P dependent network model

Fig.5 Hybrid P2P dependent network model

Fig.6 The data structure of blockchain

Fig.7 IEEE 39 power information physical network diagram after community division

Fig.8 Load loss rate of height number attack in different power information interdependent networks (a)IEEE39; (b)IEEE118

Fig.9 Load loss rate of high mediator attack in different power information interdependent networks (a)IEEE39; (b)IEEE118

Fig.10 Results of two attack modes under MB connection mode (a)IEEE39; (b)IEEE118

Fig.11 Results of two attack modes under MD connection mode (a)IEEE39;(b)IEEE118

Fig.12 Results of two attack modes under MB mode

Fig.13 Results of two attack modes under MD mode

Table 1 PBFT communication cost comparison (consensus times)

网络类型	X_a	X_b	T/%
IEEE39	2 964	84	2.83
IEEE118	27 612	220	0.79

Table 2 Comparison of the number of connected sides of P2P information network

网络类型	L_a	L_b	M/%
IEEE39	741	66	8.90
IEEE118	6 903	234	3.38

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