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Bibliographic Details
Main Authors: Geng, Sijia, Lee, Thomas, Mallapragada, Dharik, Botterud, Audun
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2506.09388
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author Geng, Sijia
Lee, Thomas
Mallapragada, Dharik
Botterud, Audun
author_facet Geng, Sijia
Lee, Thomas
Mallapragada, Dharik
Botterud, Audun
contents Electrified transportation leads to a tighter integration between transportation and energy distribution systems. In this work, we develop scalable optimization models to co-design hydrogen and battery electric vehicle (EV) fleets, distributed energy resources, and fast-charging and hydrogen-fueling infrastructure to efficiently meet transportation demands. A novel integer-clustering formulation is used for optimizing fleet-level EV operation while maintaining accurate individual vehicle dispatch, which significantly improves the computation efficiency with guaranteed performance. We apply the optimization model to Boston's public transit bus network using real geospatial data and cost parameters. Realistic insights are provided into the future evolution of coupled electricity-transportation-hydrogen systems, including the effects of electricity price structure, hydrogen fuel cost, carbon emission constraint, temperature effects on EV range, and distribution system upgrade cost.
format Preprint
id arxiv_https___arxiv_org_abs_2506_09388
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Integer-Clustering Optimization of Hydrogen and Battery EV Fleets Considering DERs
Geng, Sijia
Lee, Thomas
Mallapragada, Dharik
Botterud, Audun
Systems and Control
Electrified transportation leads to a tighter integration between transportation and energy distribution systems. In this work, we develop scalable optimization models to co-design hydrogen and battery electric vehicle (EV) fleets, distributed energy resources, and fast-charging and hydrogen-fueling infrastructure to efficiently meet transportation demands. A novel integer-clustering formulation is used for optimizing fleet-level EV operation while maintaining accurate individual vehicle dispatch, which significantly improves the computation efficiency with guaranteed performance. We apply the optimization model to Boston's public transit bus network using real geospatial data and cost parameters. Realistic insights are provided into the future evolution of coupled electricity-transportation-hydrogen systems, including the effects of electricity price structure, hydrogen fuel cost, carbon emission constraint, temperature effects on EV range, and distribution system upgrade cost.
title Integer-Clustering Optimization of Hydrogen and Battery EV Fleets Considering DERs
topic Systems and Control
url https://arxiv.org/abs/2506.09388