Direct Power Control Design for Charging Electric Vehicles: A Passivity-Based Control Approach

2020 IEEE International Autumn Meeting on Power, Electronics and Computing (ROPEC) Pub Date : 2020-11-04 DOI:10.1109/ROPEC50909.2020.9258690

O. Montoya, W. Gil-González, F. Serra, J. Dominguez, J. Campillo, J. C. Hernández

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引用次数: 1

Abstract

This paper explores the controller's design for charging batteries for electric vehicle applications using the direct power representation of the system. These controllers' design is made via passivity-based control (PBC) theory by considering the open-loop port-Hamiltonian representation of the converter. The usage of PBC theory allows designing controllers for closed-loop operation, guaranteeing stability operation in the sense of Lyapunov. Two different PBC methods are explored in this contribution; these are i) interconnection and damping assignment PBC, and ii) proportional-integral design. These methods work over the system's incremental model for reaching a control law that ensures asymptotic stability. Numerical validations show that both controllers allow controlling active and reactive power independently in four-quadrants. This is important due to allow using batteries as dynamic energy compensators if it is needed. All the simulations are conducted in MATLAB simulink via SymPowerSystems library.

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充电电动汽车直接功率控制设计:一种基于被动的控制方法

本文探讨了使用系统直接功率表示的电动汽车电池充电控制器的设计。这些控制器的设计是基于无源控制(PBC)理论，并考虑了变换器的开环端口-哈密顿表示。利用PBC理论可以设计闭环操作的控制器，保证李亚普诺夫意义上的稳定运行。本文探讨了两种不同的PBC方法;它们是i)互连和阻尼分配PBC，以及ii)比例积分设计。这些方法在系统的增量模型上工作，以达到保证渐近稳定的控制律。数值验证表明，两种控制器都可以在四象限内独立控制有功和无功功率。这是重要的，因为允许使用电池作为动态能量补偿，如果需要的话。所有仿真均在MATLAB simulink中通过SymPowerSystems库进行。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2020 IEEE International Autumn Meeting on Power, Electronics and Computing (ROPEC)

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