Method for determining an optimal state-of-charge operating window for a battery

What is claimed is: 1 . A method for determining an optimal state-of-charge (SOC) operating window for a battery for use in an electric vehicle, comprising: learning a pattern of periodic charging of the battery for a plurality of time periods and a pattern of periodic usage of the battery for the plurality of time periods; determining a periodic energy requirement for the battery for the plurality of time periods based on the learned patterns using a statistical model; and setting a maximum SOC level and a minimum SOC level for the SOC operating window based on two or more of the periodic energy requirement, the learned patterns and a battery chemistry of the battery. 2 . The method of claim 1 , wherein the periodic charging, the periodic usage and the periodic energy requirement each have a periodicity of daily, weekly or monthly. 3 . The method of claim 1 , wherein the statistical model is a Weibull distribution, a log-normal distribution or a positively skewed parametric or nonparametric distribution. 4 . The method of claim 1 , wherein the learning step comprises: receiving a plurality of charging instances and a plurality of usage instances for the plurality of time periods; and establishing the patterns of periodic charging and periodic usage based on the received pluralities of charging instances and usage instances, respectively. 5 . The method of claim 4 , wherein each charging instance includes two or more of a respective charging start time, a respective charging end time, a respective charging duration, a respective charging level, a respective beginning battery charge level and a respective ending battery charge level, and wherein each usage instance includes two or more of a respective usage start time, a respective usage end time, a respective usage duration, a respective average energy use amount and a respective total energy use amount. 6 . The method of claim 1 , further comprising: accumulating additional instances of the periodic charging and the periodic usage of the battery; and utilizing a machine learning method to derive an updated maximum SOC level and an updated minimum SOC level for the SOC operating window based on the additional instances of periodic charging and periodic usage. 7 . The method of claim 6 , wherein the machine learning method is a neural network. 8 . The method of claim 7 , wherein the neural network is a recurrent neural network. 9 . The method of claim 1 , wherein the step of setting the maximum and minimum SOC levels comprises: selecting, as a candidate maximum SOC level, a lesser of a first recommended maximum SOC level based on a battery capacity model for the battery and a second recommended maximum SOC level based on a point of diminishing returns for thermal propagation performance for the battery; selecting, as a candidate minimum SOC level, a recommended minimum SOC level based on the battery capacity model for the battery; deriving a battery energy requirement by adding a factor to the periodic energy requirement or by multiplying the periodic energy requirement by a multiplier, wherein the factor and the multiplier are each based on the periodic charging of the battery and an availability of charging locations for the battery; and adjusting one or both of the candidate minimum and maximum SOC levels to establish the minimum and maximum SOC levels, respectively, so as to enable the battery to supply the battery energy requirement. 10 . The method of claim 9 , wherein the battery capacity model is based on a battery chemistry of the battery. 11 . The method of claim 9 , wherein the availability of charging locations for the battery is based on a range within which the battery may be utilized to motively power the electric vehicle. 12 . The method of claim 1 , wherein the periodic energy requirement is one of: a total energy requirement for all of the plurality of time periods; and a plurality of individual energy requirements, wherein each of the individual energy requirements corresponds to a respective one of the plurality of time periods. 13 . A method for determining an optimal state-of-charge (SOC) operating window for a battery for use in an electric vehicle, comprising: receiving a plurality of charging instances of the battery for a plurality of time periods and a plurality of usage instances of the battery for the plurality of time periods; establishing a pattern of periodic charging of the battery based on the received plurality of charging instances and a pattern of periodic usage of the battery based on the received plurality of usage instances; determining a periodic energy requirement for the battery for the plurality of time periods based on the learned patterns of periodic charging and periodic usage using a positively skewed parametric or nonparametric distribution; setting a maximum SOC level and a minimum SOC level for the SOC operating window based on two or more of the periodic energy requirement, the learned patterns of periodic charging and periodic usage and a battery chemistry of the battery; accumulating additional instances of the periodic charging and the periodic usage of the battery; and utilizing a recurrent neural network to derive an updated maximum SOC level and an updated minimum SOC level for the SOC operating window based on the additional instances of periodic charging and periodic usage. 14 . The method of claim 13 , wherein each charging instance includes two or more of a respective charging start time, a respective charging end time, a respective charging duration, a respective charging level, a respective beginning battery charge level and a respective ending battery charge level, and wherein each usage instance includes two or more of a respective usage start time, a respective usage end time, a respective usage duration, a respective average energy use amount and a respective total energy use amount. 15 . The method of claim 13 , wherein the step of setting the maximum and minimum SOC levels comprises: selecting, as a candidate maximum SOC level, a lesser of a first recommended maximum SOC level based on a battery capacity model for the battery and a second recommended maximum SOC level based on a point of diminishing returns for thermal propagation performance for the battery; selecting, as a candidate minimum SOC level, a recommended minimum SOC level based on the battery capacity model for the battery; deriving a battery energy requirement by adding a factor to the periodic energy requirement or by multiplying the periodic energy requirement by a multiplier, wherein the factor and the multiplier are each based on the periodic charging of the battery and an availability of charging locations for the battery; and adjusting one or both of the candidate minimum and maximum SOC levels to establish the minimum and maximum SOC levels, respectively, so as to enable the battery to supply the battery energy requirement. 16 . The method of claim 15 , wherein the battery capacity model is based on a battery chemistry of the battery, and wherein the availability of charging locations for the battery is based on a range within which the battery may be utilized to motively power the electric vehicle. 17 . The method of claim 13 , wherein the periodic energy requirement is one of: a total energy requirement for all of the plurality of time periods; and a plurality of individual energy requirements, wherein each of the individual energy requirements corresponds to a respective one of the plurality of time periods.