MétaCan
← tous les travaux

Mobile Charging Station Placements in Internet of Electric Vehicles: A Federated Learning Approach

2022· article· en· 60 citations· W4296706857 sur OpenAlex· 10.1109/tits.2022.3205596

Pourquoi ce travail est-il dans la base ?

Une base qui oublie comment elle a trouvé un travail ne peut pas être vérifiée. Voici les voies qui ont admis celui-ci.

Affiliation canadienneUne personne signataire a déclaré un établissement canadien. C'est la seule voie dont dispose la base habituelle.

Le tri à trois modèles

les 1 000 travaux triés →

Les trois modèles l'ont jugé hors champ.

strate : aff_core · poids de sondage : 5595.24 (l'échantillon est stratifié ; tout taux calculé sans le poids est faux)
Claude Opus 4.8OUT
genre : empirical
porte sur le Canada: non
confiance: high

Federated learning method for placing mobile EV charging stations; an engineering optimization question.

GPT-5.6 (high)OUT
genre : empirical
porte sur le Canada: non
confiance: high

The study proposes a federated-learning method for electric-vehicle charging placement.

Grok 4.5OUT
genre : empirical
porte sur le Canada: non
confiance: high

Federated-learning placement of mobile EV charging stations is engineering optimization, not study of research.

Résumé

In Internet of Electric Vehicles (IoEV), mobile charging stations (MCSs) can be deployed to complement fixed charging stations. Currently, the strategy of MCSs is to move towards the EVs with insufficient energy (IEVs) only after being requested, which is not efficient. However, similar to online car-hailing services, more IEVs could be charged and the charging expenses could be reduced if idle MCSs can actively move towards the potential charging positions. In this paper, the problem of placements of idle MCSs in an IoEV is investigated in order to enhance the proportion of charged IEVs and reduce the charging expenses of IEVs. To this end, we propose a Federated Learning based Placement Decision Method of Idle MCSs (FL-PDMIM) to help the idle MCSs to predict the future charging positions, by exploiting the historical routes of MCSs which contain rich information regarding the charging demand of IEVs. In the proposed framework, the historical routes are trained locally by each MCS, and then the local model parameters and charging records are periodically uploaded to an edge server for a global parameter aggregation. Then, idle MCSs decide their placements according to the predicted charging positions (potential charging positions). The training time can be largely shortened, because the distributed learning on each MCS is executed in parallel. Extensive simulations and comparisons demonstrate the performance superiority of FL-PDMIM. Specifically, with the proposed federated learning-based predictions, the waiting time of IEVs to be served can be significantly shortened, and FL-PDMIM enhances the proportion of charged IEVs and reduces the charging expenses of IEVs effectively.

Conservé avec la notice de tri, où il sert de preuve aux étiquettes ci-dessus.

La notice

Revue
IEEE Transactions on Intelligent Transportation Systems
Thématique
Electric Vehicles and Infrastructure
Domaine
Engineering
Établissements canadiens
University of Manitoba
Organismes subventionnaires
National Natural Science Foundation of China
Mots-clés
IdleUploadCharging stationComputer scienceEnhanced Data Rates for GSM EvolutionThe InternetReal-time computingElectric vehicleSimulationComputer networkTelecommunicationsOperating system
Résumé présent dans OpenAlex
oui