Modeling Fault Propagation Paths in Power Systems: A New Framework Based on Event SNP Systems With Neurotransmitter Concentration

In cyber–physical power systems (CPPSs), the interaction mechanisms between physical systems and cyber systems are becoming more and more complicated. Their deep integration has brought new unstable factors to the system. Faults or attacks may cause a chain reaction, such as control failure, state deterioration, or even outage, which seriously threatens the safe and stable operation of power grids. In this paper, given the interaction mechanisms, we propose an interdependent model of CPPS, based on a characteristic association method. Utilizing this model, we can study the fault propagation mechanisms when faulty or under cyber-attack. Simulation results quantitatively reveal the propagation process of fault risks and the impacts on the CPPS due to the change of state quantity of the system model.

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Specifying the Directionality of Fault Propagation Paths Using Transfer Entropy

IFAC Proceedings Volumes ◽

10.1016/s1474-6670(17)31812-8 ◽

2004 ◽

Vol 37 (9) ◽

pp. 203-208 ◽

Cited By ~ 8

Author(s):

Margret Bauer ◽

Nina F. Thornhill ◽

Adrian Meaburn

Keyword(s):

Transfer Entropy ◽

Fault Propagation ◽

Propagation Paths

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Security Assessment and Coordinated Emergency Control Strategy for Power Systems with Multi-Infeed HVDCs

Energies ◽

10.3390/en13123174 ◽

2020 ◽

Vol 13 (12) ◽

pp. 3174

Author(s):

Qiufang Zhang ◽

Zheng Shi ◽

Ying Wang ◽

Jinghan He ◽

Yin Xu ◽

...

Keyword(s):

Power Systems ◽

Control Strategy ◽

Transient Stability ◽

Short Circuit ◽

Hybrid Simulation ◽

Security Assessment ◽

Fault Propagation ◽

Multiple Control ◽

Emergency Control ◽

On Line

Short-circuit faults in a receiving-end power system can lead to blocking events of the feed-in high-voltage direct-current (HVDC) systems, which may further result in system instability. However, security assessment methods based on the transient stability (TS) simulation can hardly catch the fault propagation phenomena between AC and DC subsystems. Moreover, effective emergency control strategies are needed to prevent such undesired cascading events. This paper focuses on power systems with multi-infeed HVDCs. An on-line security assessment method based on the electromagnetic transient (EMT)-TS hybrid simulation is proposed. DC and AC subsystems are modeled in EMTDC/PSCAD and PSS/E, respectively. In this way, interactions between AC and DC subsystems can be well reflected. Meanwhile, high computational efficiency is maintained for the on-line application. In addition, an emergency control strategy is developed, which coordinates multiple control resources, including HVDCs, pumped storages, and interruptible loads, to maintain the security and stability of the receiving-end system. The effectiveness of the proposed methods is verified by numerical simulations on two actual power systems in China. The simulation results indicate that the EMT-TS hybrid simulation can accurately reflect the fault propagation phenomena between AC and DC subsystems, and the coordinated emergency control strategy can work effectively to maintain the security and stability of systems.

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An Improved FFIP Method Based on Mathematical Logic and SysML

Applied Sciences ◽

10.3390/app11083534 ◽

2021 ◽

Vol 11 (8) ◽

pp. 3534

Author(s):

Jian Jiao ◽

Shujie Pang ◽

Jiayun Chu ◽

Yongfeng Jing ◽

Tingdi Zhao

Keyword(s):

Mathematical Logic ◽

Failure Process ◽

Modeling Language ◽

Fault Propagation ◽

Functional Failure ◽

Cut Set ◽

Simulation Results ◽

Propagation Paths ◽

Graphics Processing ◽

State Machine Diagram

In recent years, the model-based safety analysis (MBSA) has been developing continuously. The Functional Failure Identification and Propagation (FFIP) method is a graphics processing technology which supports the analysis of fault propagation paths before making costly design commitments. However, the traditional FFIP has some deficiencies. In this paper, we extend the functional failure logic (FFL) in the FFIP and introduce the concept of deviation. So, FFIP can be used to analyze the failure process of the systems and make the logical analysis of functional failure easier. Based on the extended FFL, we present a new overview of the FFIP. The FFIP is improved by using mathematical logic and Systems Modeling Language (SysML). The standard expression of FFL is realized, which is conducive to the subsequent modeling and modification. Additionally, we use the failure logic analysis in the FFIP to improve the state machine diagram (SMD) in SysML. Finally, the improved FFIP method is used to analyze the fault propagation paths of the system and Simulink is used for simulation. The fault tree is generated according to the simulation results, the minimum cut set is calculated, and the key failure parts of the system are obtained.

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