基于电力大数据的电力骨干通信网络毁伤韧性评估方法

doi:10.11959/j.issn.1000-0801.2023105

Abstract

Abstract:

The damage toughness assessment method of power backbone communication network based on power big data was studied, and the damage toughness assessment results were used to formulate protection strategies and improve the network survivability.The power backbone communication network and the attacker were set as the two sides of the game, and the Nash equilibrium strategy of both sides was determined by the minimax method.The damage probability of nodes was obtained by the Nash equilibrium strategy, and the node damage probability was transformed into the network damage form.According to the network damage pattern, the repair conditions contained in the power big data were obtained by cloud computing technology.According to the importance of each node, the repair resources and repair budget were allocated to the nodes in order.The performance time-history response curve of the power backbone communication network was constructed, and the dynamic evaluation results of the network damage toughness were output.The experimental results show that all operations using cloud computing technology to process massive power big data can not exceed 330 ms.When the repair budget and repair resources are the highest, the damage toughness of the power backbone communication network can reach 0.925 at most, indicating that this method can effectively evaluate the damage toughness of the power backbone communication network.

Key words: power big data, backbone communication network, damage toughness, assessment method, the two sides of the game, cloud computing

CLC Number:

TM76

Xue HAN. Damage toughness assessment method of power backbone communication network based on power big data[J]. Telecommunications Science, 2023, 39(5): 136-143.

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References 15

[1]	许珞, 郭庆来, 刘新展 ,等. 提升电力信息物理系统韧性的通信网鲁棒优化方法[J]. 电力系统自动化, 2021,45(3): 68-75.
	XU L , GUO Q L , LIU X Z ,et al. Robust optimization method of communication network to improve resilience of cyber-physical power system[J]. Automation of Electric Power Systems, 2021,45(3): 68-75.
[2]	张洁斐, 任刚, 马景峰 ,等. 基于韧性评估的地铁网络修复时序决策方法[J]. 交通运输系统工程与信息, 2020,20(4): 14-20.
	ZHANG J F , REN G , MA J F ,et al. Decision-making method of repair sequence for metro network based on resilience evaluation[J]. Journal of Transportation Systems Engineering and Information Technology, 2020,20(4): 14-20.
[3]	程紫运, 吕明卉, 田云飞 ,等. 基于结构熵的电力骨干通信网抗毁性研究[J]. 电力系统保护与控制, 2020,48(5): 112-118.
	CHENG Z Y , LYU M H , TIAN Y F ,et al. Research on invulnerability for electric power backbone communication network based on structural entropy[J]. Power System Protection and Control, 2020,48(5): 112-118.
[4]	张秀丽, 许静静, 刘新红 . 基于量化指标的变电站抗震韧性评估方法[J]. 高压电器, 2022,58(8): 213-221.
	ZHANG X L , XU J J , LIU X H . Seismic resilience assessment method of substation based on quantitative index[J]. High Voltage Apparatus, 2022,58(8): 213-221.
[5]	徐悦, 李博, 孙建军 ,等. 基于运行韧性评价的配电网电压暂降治理评估[J]. 电力系统自动化, 2021,45(5): 104-110.
	XU Y , LI B , SUN J J ,et al. Evaluation of voltage sag management in distribution network based on operation resilience assessment[J]. Automation of Electric Power Systems, 2021,45(5): 104-110.
[6]	王晗, 侯恺, 余晓丹 ,等. 计及地震灾害不确定性的电气互联系统韧性评估与提升方法[J]. 中国电机工程学报, 2022,42(3): 853-863.
	WANG H , HOU K , YU X D ,et al. The assessment and improvement method of electricity-gas system resilience considering earthquake disaster uncertainty[J]. Proceedings of the CSEE, 2022,42(3): 853-863.
[7]	韩林, 赵旭东, 陈志龙 ,等. 蓄意攻击下城市电力网络毁伤韧性评估[J]. 中国安全科学学报, 2021,31(6): 161-169.
	HAN L , ZHAO X D , CHEN Z L ,et al. Research on damage resilience assessment of urban power networks under intentional attacks[J]. China Safety Science Journal, 2021,31(6): 161-169.
[8]	王珂, 田来, 吴俊 . 基于区域毁伤的基础设施网络抗毁性评估模型[J]. 系统工程与电子技术, 2020,42(5): 1102-1108.
	WANG K , TIAN L , WU J . Survivability assessing model of infrastructure networks based on regional damages[J]. Systems Engineering and Electronics, 2020,42(5): 1102-1108.
[9]	赵天阳, 张华君, 徐岩 ,等. 不确定环境下含云计算数据中心的电网韧性增强调度[J]. 电力系统自动化, 2021,45(3): 49-57.
	ZHAO T Y , ZHANG H J , XU Y ,et al. Resilience-enhanced scheduling of power system with cloud computing data centers under uncertainty[J]. Automation of Electric Power Systems, 2021,45(3): 49-57.
[10]	邵瑞瑞, 方志耕, 刘思峰 ,等. 基于韧性度的低轨卫星通信网络抗毁性度量及优化[J]. 运筹与管理, 2020,29(7): 9-17.
	SHAO R R , FANG Z G , LIU S F ,et al. Measurement and optimization of invulnerability of low-orbit satellite communication networks based on resilience[J]. Operations Research and Management Science, 2020,29(7): 9-17.
[11]	徐一鸣, 李笑, 杨凯凯 ,等. 基于多步攻击的多跳通信网拓扑态势预测仿真[J]. 计算机仿真, 2020,37(6): 4-7,12.
	XU Y M , LI X , YANG K K ,et al. Simulation of multi hop communication network topology situation prediction based on multi-step attack[J]. Computer Simulation, 2020,37(6): 4-7,12.
[12]	李清 . 基于改进 PSO-PFCM 聚类算法的电力大数据异常检测方法[J]. 电力系统保护与控制, 2021,49(18): 161-166.
	LI Q . Power big data anomaly detection method based on an improved PSO-PFCM clustering algorithm[J]. Power System Protection and Control, 2021,49(18): 161-166.
[13]	邓震峰, 刘小岗 . 毁伤评估无线传感网络能耗均衡方法[J]. 探测与控制学报, 2021,43(6): 101-105.
	DENG Z F , LIU X G . Damage assessment wireless sensor networks energy consumption balanced method[J]. Journal of Detection ＆ Control, 2021,43(6): 101-105.
[14]	林晓静, 刘文, 甘超飞 ,等. 基于卷积神经网络与多维度电力大数据的信用评估系统[J]. 电测与仪表, 2021,58(11): 101-106.
	LIN X J , LIU W , GAN C F ,et al. Corporate credit assessment system based on convolutional neural network and multi-dimensional power big data[J]. Electrical Measurement ＆ Instrumentation, 2021,58(11): 101-106.
[15]	马庆峰, 王庭钧, 单丽 ,等. 基于业务链路的电力通信网络可靠性评估模型[J]. 数学的实践与认识, 2019,49(19): 207-215.
	MA Q F , WANG T J , SHAN L ,et al. Reliability evaluation model of electric power communication network based on business link[J]. Mathematics in Practice and Theory, 2019,49(19): 207-215.

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链路序号	节点对	业务流量/(Gbit·s^-1)	链路序号	节点对	业务流量/(Gbit·s^-1)
1	1,2	3.854	15	14,15	3.854
2	2,3	2.851	16	15,16	1.687
3	3,4	1.687	17	16,17	2.915
4	5,6	2.695	18	17,18	1.815
5	3,6	3.648	19	17,23	3.645
6	1,8	4.051	20	18,19	2.781
7	7,8	3.945	21	18,20	1.854
8	8,9	2.874	22	20,21	2.495
9	9,10	3.156	23	21,25	3.851
10	6,11	2.945	24	24,25	4.854
11	11,12	2.945	25	23,24	5.618
12	10,12	2.495	26	22,23	3.648
13	10,13	3.185	27	22,25	2.648
14	13,14	4.185	28	14,24	1.854

节点序号	节点重要度	节点序号	节点重要度	节点序号	节点重要度
1	0.352	10	0.284	18	0.785
2	0.294	11	0.394	19	0.564
3	0.384	12	0.615	20	0.648
4	0.465	13	0.581	21	0.584
5	0.584	14	0.495	22	0.165
6	0.684	15	0.671	23	0.485
7	0.481	16	0.584	24	0.384
8	0.594	17	0.465	25	0.451
9	0.854	—	—	—	—

Damage toughness assessment method of power backbone communication network based on power big data

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