I. Introduction

As the major industrialised nations are becoming more concerned about global warming and fossil fuel depletion, they outline their plans for electric vehicles (EV) development and production in detriment of combustion engines. Battery technology has been one of the bottlenecks in EV, making the research on battery management systems (BMS) extremely important, especially for the battery state-of-charge (SoC) estimation — the current capacity of a battery expressed as a percentage of the fully-charged capacity. Factors that mainly affect battery SoC are: charge/discharge rate and times, polarisation effect, temperature, self-discharge or battery ageing. In fact, batteries are very complex due to their strong time-varying and non-linear properties, what makes the accurate estimate of SoC a challenging task. During the last years EV powered by lithium batteries have become popular since significant improvements in energy density and power capability have made Li-ion batteries [4], [19] the preferred solution for nowadays low carbon mobility. The change in behaviour of the batteries throughout a vehicle lifetime can have a significant detrimental effect on the whole vehicle performance and existence. Thence, exploring the causes of battery ageing, as well as developing mitigation strategies to avoid premature degradation becomes of paramount importance to vehicle manufacturers. In [24] various representative patents and papers related to SoC estimation methods for an electric vehicle battery are reviewed. According to their theoretical and experimental characteristics, the estimation methods were divided into traditional, based on battery experiments, and modern, based on control theory, especially intelligent algorithms.