@inproceedings{35536307821046e1b72a3915fdbfb17d,
title = "A hybrid dynamic system model for the assessment of transportation electrification",
abstract = "In recent years, the electrification of transport has emerged as a trend to support energy efficiency and CO2 emissions reduction targets. The true success, however, of this trend depends on the successful integration of electric vehicles on the infrastructure systems that support them. Left unmanaged electric vehicles may suffer from delays due to charging or cause destabilizing charging loads on the electrical grid. While many works have sought to mitigate these effects with advanced functionality such as coordinated charging, vehicle-to-grid stabilization, and charging queue management, few works have assessed these impacts as a holistic transportation-electricity nexus. Furthermore, rigorous dynamic system mathematical models that couple the kinematic and electrical states have yet to be developed holistically. This paper develops such a model in the hopes of its application by EV fleet operators to not just assess but also improve their operations \& control. The hybrid dynamic system model is composed of a marked petri-net model superimposed on the continuous time kinematic and electrical state evolution. The application of the model is demonstrated on an illustrative example of modest size and sufficient functional heterogeneity.",
keywords = "Discrete event systems, Hybrid systems, Petri nets",
author = "Asha Viswanath and Farid, \{Amro M.\}",
year = "2014",
doi = "10.1109/ACC.2014.6858810",
language = "British English",
isbn = "9781479932726",
series = "Proceedings of the American Control Conference",
publisher = "Institute of Electrical and Electronics Engineers Inc.",
pages = "4617--4623",
booktitle = "2014 American Control Conference, ACC 2014",
address = "United States",
note = "2014 American Control Conference, ACC 2014 ; Conference date: 04-06-2014 Through 06-06-2014",
}
