Abstract
The aging of rechargeable batteries, with its associated replacement costs, is one of the main issues limiting the diffusion of electric vehicles (EVs) as the future transportation infrastructure. An effective way to mitigate battery aging is to act on its charge cycles, more controllable than discharge ones, implementing so-called battery-aware charging protocols. Since one of the main factors affecting battery aging is its average state of charge (SOC), these protocols try to minimize the standby time, i.e., the time interval between the end of the actual charge and the moment when the EV is unplugged from the charging station. Doing so while still ensuring that the EV is fully charged when needed (in order to achieve a satisfying user experience) requires a “just-in-time” charging protocol, which completes exactly at the plug-out time. This type of protocol can only be achieved if an estimate of the expected plug-in duration is available. While many previous works have stressed the importance of having this estimate, they have either used straightforward forecasting methods, or assumed that the plug-in duration was directly indicated by the user, which could lead to sub-optimal results. In this paper, we evaluate the effectiveness of a more advanced forecasting based on machine learning (ML). With experiments on a public dataset containing data from domestic EV charge points, we show that a simple tree-based ML model, trained on each charge station based on its users’ behaviour, can reduce the forecasting error by up to 4× compared to the simple predictors used in previous works. This, in turn, leads to an improvement of up to 50% in a combined aging-quality of service metric.
Highlights
Given the environmental impact of petroleum-based transportation and the recent developments of renewable energy production technologies, electric vehicles (EVs) are gaining traction as the most promising transportation infrastructure for the future [1]
All charge events longer than 40 h have been filtered out as outliers, since we have found that they worsened the training results
LightGBM improves the quality of service (QoS)-state of health (SOH) product by 20% and 8% using the Aging Optimal and
Summary
Given the environmental impact of petroleum-based transportation and the recent developments of renewable energy production technologies, electric vehicles (EVs) are gaining traction as the most promising transportation infrastructure for the future [1]. EVs are considered environmental-friendly because the electric power they consume can be generated from a wide variety of sources including various renewable ones [2]. The capacity loss of rechargeable Lithium-ion batteries depends on four main factors [8,13,19,20]:. Aging worsens with an increase in any of these quantities Among these four main factors, given that temperature cannot be controlled and that DOD and discharge currents depend on the power demand and duration of the discharge phase, only the charging current and the average SOC can be managed during the charging process for optimization.
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