Adaptive system and method for optimizing battery life in a plug-in vehicle

The invention claimed is: 1. A system for optimizing life of a battery pack in a plug-in vehicle, the system comprising: a plurality of sensors operable for measuring battery performance data of the battery pack, wherein the battery performance data includes an open-circuit voltage, a charging current, and/or a temperature of the battery pack; a global positioning system (GPS) receiver operable for receiving position data of the vehicle; and a controller in communication with the plurality of sensors and the GPS receiver that is programmed to monitor degradation of the battery pack over time using the battery performance data, wherein the controller is further programmed to: determine a driving history and a battery charging history for an operator of the vehicle using the measured battery performance data and a position signal from the GPS receiver, wherein the driving history and battery charging history identify the days, hours, and/or locations at which the operator has driven the vehicle and charged the battery pack, respectively; determine a plurality of SOC breakpoints between an actual SOC of the battery pack and a control target SOC; identify, from among a plurality of state of charge (SOC) data bins each configured to store a corresponding portion of the measured battery performance data for a predetermined SOC range, multiple incomplete/stale SOC data bins within the SOC break points that are missing battery performance data or contain old battery performance data relative to a calibrated aging threshold; select a highest priority breakpoint by evaluating each of the incomplete/stale SOC data bins against an age criterion and/or a lack of data criterion; identify, from the multiple incomplete/stale SOC data bins, an incomplete/stale SOC data bin that corresponds to the selected highest priority breakpoint; automatically control a charging operation of the battery pack via a charging control signal until the actual SOC of the battery pack is within an SOC range defining the incomplete/stale SOC data bin that corresponds to the selected highest priority breakpoint; determine, while the actual SOC of the battery pack is within the SOC range that defines the incomplete/stale SOC data bin, new battery performance data of the battery pack that corresponds to the incomplete/stale SOC data bin; and record the new battery performance data for the incomplete/stale SOC data bin, thereby optimizing the life of the battery pack. 2. The system of claim 1 , wherein the controller is programmed to automatically control the charging operation by delaying charging of the battery pack for a predetermined duration after the battery pack has been plugged into an offboard power supply. 3. The system of claim 1 , wherein the plurality of sensors includes a voltage sensor operable for detecting the open-circuit voltage, and wherein the measured battery performance data includes the open-circuit voltage. 4. The system of claim 3 , wherein the plurality of sensors also includes a current sensor operable for detecting the charging current, and a temperature sensor operable for measuring a temperature of the battery pack, and wherein the measured battery performance data includes the charging current and the temperature. 5. The system of claim 1 , wherein the vehicle further includes a thermal conditioning device operable for thermally conditioning the battery pack, and wherein the controller is further programmed to automatically control the charging operation by controlling an operation of the thermal conditioning device in response to the temperature of the battery pack. 6. The system of claim 5 , wherein the controller is programmed to derate a charging current level to the battery pack so as to maintain the SOC of the battery pack until the thermal conditioning of the battery pack is complete. 7. The system of claim 1 , wherein the controller is further programmed to: receive an override signal from a user interface of the plug-in vehicle, and automatically control the charging operation by charging the battery pack to a default SOC in response to receipt of the override signal. 8. The system of claim 1 , wherein the controller is further programmed to: determine, from the position signal received from the GPS receiver, an elevation of the plug-in vehicle, and schedule the charging operation to coincide with a regenerative event of the vehicle using the elevation of the plug-in vehicle. 9. The system of claim 1 , wherein the controller is further programmed to: receive a designated range buffer via a user interface of the plug-in vehicle, and automatically control the charging operation using the designated range buffer such that the battery pack, upon completing a charging event, has an estimated range that equals or exceeds a range of the designated range buffer. 10. A method for optimizing life of a battery pack in a plug-in vehicle, the method comprising: measuring battery performance data of the battery pack via a plurality of sensors, including measuring an open-circuit voltage of the battery pack; determining a position of the vehicle using position data received via a global positioning system (GPS) receiver; monitoring degradation of the battery pack over time via a controller using the measured battery performance data; determining a driving history and a battery charging history for an operator of the vehicle using the measured battery performance data and a position signal from the GPS receiver, wherein the driving history and battery charging history identify the days, hours, and/or locations at which the operator drives the vehicle and charges the battery pack, respectively; determining a plurality of SOC breakpoints between an actual SOC of the battery pack and a control target SOC; identifying, via the controller from among a plurality of state of charge (SOC) data bins each configured to store a corresponding portion of the measured battery performance data for a predetermined SOC range, multiple incomplete/stale SOC data bins within the SOC break points that are missing battery performance data or contain old battery performance data relative to a calibrated aging threshold; selecting a highest priority breakpoint by evaluating each of the multiple incomplete/stale SOC data bins against an age criterion and/or a lack of data criterion; identifying, from the multiple incomplete/stale SOC data bins, an incomplete/stale SOC data bin that corresponds to the selected highest priority breakpoint; automatically controlling a charging operation of the battery pack via the controller using a charging control signal until the actual SOC of the battery pack is within an SOC range defining the incomplete/stale SOC data bin that corresponds to the selected highest priority breakpoint; determining, while the actual SOC of the battery pack is within the SOC range that defines the incomplete/stale SOC data bin, new battery performance data of the battery pack that corresponds to the incomplete/stale SOC data bin; and recording the new battery performance data for the incomplete/stale SOC data bin, thereby optimizing the life of the battery pack. 11. The method of claim 10 , wherein automatically controlling the charging operation includes automatically delaying charging of the battery pack for a predetermined duration after the battery pack has been plugged into an offboard power supply. 12. The method of claim 10 , wherein the plurality of sensors includes a current sensor operable for detecting a charging current of the charging operation, and a temperature sensor operable for measuring a temperature of the battery pack, and wherein measuring the battery p