In this paper, an optimal planning strategy is proposed for EV charging stations by considering travel demand based on non‐cooperative game theory. In the proposed methodology, a realistic and stochastic charging demand distribution was obtained with the travel chain of an EV and the associated probability density function. Based on the charging demand of EV owners and a multi‐operator scenario, a two‐stage effective and practical charging station planning model was established. The first stage of the planning model optimized the location of charging stations to decrease the total deadhead mileage of the EVs with the cooperation of the charging station operators. In the second stage, the operators were committed to increasing their economic benefits by developing a charging station capacity strategy in the framework of the non‐cooperative game. Furthermore, the combination of an adaptive mutation particle swarm optimization algorithm (AMPSO) and approximate Nash equilibrium had a better effect in reducing the difficulty of solving the game model and obtaining an optimal planning strategy. Finally, the results of the case study demonstrated the effectiveness of the proposed methodology for improving the charging experience of the EV owners and achieving a balance of benefits among multiple charging station operators.
With the rapid development of wireless technology, the deep coupling of cyber–physical power system (CPPS) is accelerated, and the openness of communication network makes the importance of secure information transmission increasingly prominent. As the communication module of CPPS, smart devices play an important role in data transmission, to ensure reliable and confident communication between the two layers. This paper presents a design for a secure and efficient smart devices utilizing anonymous security authentication and negotiation protocol supported by the identity-based cryptograph, elliptic curve cryptography, and digital signature algorithm are mainly used for that purpose. The security of the protocol is proved and validated under the random oracle model. The analysis show that the protocol has security performance such as bidirectional authentication, privacy protection, and replay attacks resistance; moreover, it has less computation and communication cost.
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