Managed fast charging for electric vehicles

What is claimed is: 1 . A method of charging a vehicle battery comprising: determining an estimated state of the vehicle battery; initiating charging of the vehicle battery at a charging current determined from a predetermined model for charging the vehicle battery, the predetermined model including a plurality of modeled secondary electrolyte-interphase layer (SEI) resistance values; measuring SEI resistance as the vehicle battery is charged; adjusting the charging current to enable the measured SEI resistance to track the modeled SEI resistance values. 2 . The method of claim 1 , wherein the predetermined model is derived by: defining a grid of temperatures; testing a test battery response to injected charge current for a plurality of the grid of temperatures in a series of test current injections corresponding to a plurality of charging current levels; measuring SEI resistance for the series of test current injections to calculate a series of SEI resistance values each associated with a temperature, an injected charge current and a battery state-of-charge (SOC); normalizing the series of SEI resistance values and storing a look-up table; and constructing a polynomial model of SEI resistance as a function of SOC and temperature and current dependent parameters from the look-up table. 3 . The method of claim 2 , wherein the predetermined model is further derived from the polynomial model by taking a time derivative, and replacing the temperature and current dependent parameters from the look-up table with piece-wise linear model structures. 4 . The method of claim 1 , wherein the step of adjusting the charging current is performed by: setting a maximum lithium plating boundary; estimating a first battery state of charge at a time instance; using the first battery state of charge and the SEI resistance as inputs to the predetermined model, determining from the predetermined model that the maximum lithium plating boundary has been exceeded and, in response, reducing the charging current. 5 . The method of claim 1 , wherein the step of adjusting the charging current is performed by: setting an acceptable lithium plating boundary; estimating a first battery state of charge at a time instance; using the first battery state of charge and the SEI resistance as inputs to the predetermined model, determining from the predetermined model that the acceptable lithium plating boundary has not been reached and, in response, increasing the charging current. 6 . The method of claim 1 , wherein the step of adjusting the charging current is performed by: setting an acceptable lithium plating boundary and a maximum lithium plating boundary; estimating a first battery state of charge at a time instance; using the first battery state of charge and the SEI resistance as inputs to the predetermined model, determining from the predetermined model one of the following: the acceptable lithium plating boundary has not been reached and, in response, increasing the charging current; or the maximum lithium plating boundary has been exceeded and, in response, reducing the charging current; or otherwise maintaining the charging current until at least a next time instance. 7 . The method of claim 1 , wherein the step of measuring SEI resistance as the vehicle battery is charged is performed by: applying an excitation current to one or more cells of the vehicle battery, the excitation current being applied at two or more frequencies; measuring voltage of the one or more cells responsive to the excitation current at the two or more frequencies; performing a spectral analysis on the measured voltage to determine excitation spectra; and estimating SEI resistance of the one or more cells using the excitation spectra. 8 . A method of charging a vehicle battery comprising: determining an estimated state of the vehicle battery; obtaining a nominal charge curve from a model for the vehicle battery; updating the nominal charge curve to set and adjust an actual charge curve by detecting lithium plating conditions during charging; using the adjusted actual charge curve to control charging current delivered to the vehicle battery. 9 . The method of claim 8 , wherein the step of updating the nominal charge curve to set and adjust the actual charge curve by detecting lithium plating conditions during charging is performed by measuring secondary electrolyte-interphase layer (SEI) resistance as the vehicle battery is charged. 10 . The method of claim 9 , wherein the step of measuring SEI resistance as the vehicle battery is charged is performed by: applying an excitation current to one or more cells of the vehicle battery, the excitation current being applied at two or more frequencies; measuring voltage of the one or more cells responsive to the excitation current at the two or more frequencies; performing a spectral analysis on the measured voltage to determine excitation spectra; and estimating SEI resistance of the one or more cells using the excitation spectra. 11 . The method of claim 9 , wherein the step of updating the nominal charge curve to set and adjust the actual charge curve is performed by: comparing the estimated SEI resistance to a threshold to determine whether lithium plating is occurring, and: if so, adjusting the actual charging curve down to reduce charging current; if not, adjusting the actual charging curve up to increase charging current. 12 . The method of claim 8 , wherein the step of updating the nominal charge curve to set and adjust the actual charge curve is performed by storing a correction and limitation logic, responsive to detection of lithium plating during charging. 13 . The method of claim 8 , wherein the nominal charge curve is derived from a nominal model that contains a set of optimal charge curves computed off-line for a set of operating points of battery SOC defining nominal lithium plating boundaries. 14 . The method of claim 13 , wherein the nominal model relies on estimates of Li/Li+ overpotential in the battery, and the step of updating the nominal charge curve to set and adjust the actual charge curve by detecting lithium plating conditions during charging is performed by measuring secondary electrolyte-interphase layer (SEI) resistance as the vehicle battery is charged. 15 . A vehicle comprising: a motor generator unit (MGU) for providing motive power to the vehicle; a rechargeable battery configured to provide electric power to the MGU; a charging controller configured to control charging of the rechargeable battery by: determining an estimated state of the rechargeable battery; initiating charging of the rechargeable battery at a charging current determined from a predetermined model for charging the rechargeable battery, the predetermined model including a plurality of modeled secondary electrolyte-interphase layer (SEI) resistance values; measuring SEI resistance as the rechargeable battery is charged; adjusting the charging current to enable the measured SEI resistance to track the modeled SEI resistance values. 16 . The vehicle of claim 15 , wherein charging controller stores the predetermined model which has been derived by: defining a grid of temperatures; testing a test battery response to injected charge current for a plurality of the grid of temperatures in a series of test current injections corresponding to a plurality of charging current levels; measuring SEI resistance for the series of test current injections to calculate a series of SEI resistance values each associated with a t