Deep-MPC: A DAGGER-Driven Imitation Learning Strategy for Optimal Constrained Battery Charging

Jorge Espin, Dong Zhang, Daniele Toti, Andrea Pozzi

Research output: Chapter in Book/Report/Conference proceedingConference contribution

Abstract

In the realm of battery charging, several complex aspects demand meticulous attention, including thermal management, capacity degradation, and the need for rapid charging while maintaining safety and battery lifespan. By employing the imitation learning paradigm, this manuscript introduces an innovative solution to confront the inherent challenges often associated with conventional predictive control strategies for constrained battery charging. A significant contribution of this study lies in the adaptation of the Dataset Aggregation (DAGGER) algorithm to address scenarios where battery parameters are uncertain, and internal states are unobservable. Results drawn from a practical battery simulator that incorporates an electrochemical model highlight substantial improvements in battery charging performance, particularly in meeting all safety constraints and outperforming traditional strategies in computational processing.
Original languageEnglish
Title of host publicationProceedings of the American Control Conference
Pages2224-2229
Number of pages6
DOIs
Publication statusPublished - 2024
Event2024 American Control Conference, ACC 2024 - Toronto, Canada
Duration: 10 Jul 202412 Jul 2024

Publication series

NamePROCEEDINGS OF THE AMERICAN CONTROL CONFERENCE

Conference

Conference2024 American Control Conference, ACC 2024
CityToronto, Canada
Period10/7/2412/7/24

Keywords

  • Battery Charging
  • DAGGER
  • Model Predictive Control
  • Lithium-ion Battery
  • Imitation Learning

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