Vehicle propulsion system having an energy storage system and optimized method of controlling operation thereof

What is claimed is: 1. A vehicle propulsion system comprising: at least three power sources coupled to a final drive of the vehicle propulsion system; and a controller configured with a database comprising an efficiency contour map for each power source, the controller programmed to: determine a power demand sufficient to operate the final drive; and operate the power sources to produce the power demand, wherein operating the power sources comprises: identifying a least efficient power source of the power sources; controlling the least efficient power source to produce power at an operating point relative to the point of maximum efficiency on the efficiency contour map of the least efficient power source; identifying a power output of the least efficient power source corresponding to the operating point; comparing the power output of the least efficient power source to the power demand; identifying a remaining power demand from the comparison; and controlling at least two remaining power sources of the power sources to produce the remaining power demand by selectively allocating production of power such that at least one remaining power source produces power at an operating point relative to the point of maximum efficiency on the efficiency contour map of the remaining power source. 2. The vehicle propulsion system of claim 1 further comprising: an internal combustion engine (ICE); and an electric powertrain comprising: a DC bus; at least two electromechanical devices coupled to the DC bus; and at least one energy storage unit coupled to the DC bus. 3. The vehicle propulsion system of claim 2 wherein the ICE comprises the least efficient power source. 4. The vehicle propulsion system of claim 2 further comprising a contactor positioned to selectively couple an output of the ICE to the DC bus via an alternator. 5. The vehicle propulsion system of claim 4 wherein the controller is further programmed to: identify an excess power output of the ICE from the comparison; and close the contactor to charge the energy storage unit using the excess power output. 6. The vehicle propulsion system of claim 5 wherein the controller is further programmed to: identify parameters of the excess power output; access a charging degradation model for the energy storage unit; and iteratively define a charging power allocation to charge the energy storage unit based on the identified parameters and the charging degradation model. 7. A method of powering a propulsion system of a hybrid electric vehicle, the method comprising: determining a power demand sufficient to operate a final drive of the hybrid electric vehicle; operating at least three power sources coupled to the final drive to produce the power demand, wherein operating the power sources comprises: identifying a least efficient power source of the power sources; controlling the least efficient power source to operate relative to a maximum operating efficiency of the least efficient power source based on an efficiency contour map of the least efficient power source stored in a database; determining a power output of the least efficient power source when operating relative to the maximum operating efficiency; comparing the power output of the least efficient power source to the power demand; identifying a remaining power demand from the comparison; and controlling at least two remaining power sources of the power sources to produce the remaining power demand by selectively allocating production of power such that the at least one remaining power source produces power at an operating point relative to the point of maximum efficiency on an efficiency contour map of the remaining power source stored in the database. 8. The method of claim 7 further comprising; identifying an excess power output from the comparison; and charging an energy storage unit of the propulsion system with the excess power output of the least efficient power source. 9. The method of claim 7 further comprising: identifying an excess power output from the comparison; querying a state of charge (SOC) of a plurality of energy storage units of the propulsion system; defining a charging power split between the energy storage units based on the SOC; and charging at least one of the energy storage units according to the charging power split. 10. The method of claim 9 further comprising defining the charging power split based on charging degradation models for the energy storage units. 11. The method of claim 9 further comprising iteratively defining the charging power split using a multi-objective optimization algorithm. 12. The method of claim 7 further comprising: controlling an internal combustion engine (ICE) to operate relative to a maximum operating efficiency of the ICE and produce a first portion of the power demand; controlling a first motor to operate relative to a maximum operating efficiency of the first motor and produce a second portion of the power demand; and controlling a second motor to produce a remaining portion of the power demand. 13. A control system for a vehicle propulsion system comprising an internal combustion engine (ICE) and an electric powertrain, the electric powertrain comprising at least one energy storage unit and at least two electric motors, the control system comprising a controller configured with a database comprising efficiency contour maps for the ICE and both electric motors, the controller programmed to: determine a power demand sufficient to operate a final drive of the vehicle propulsion system; identify an ICE power output corresponding to an operating point relative to the point of maximum efficiency on the efficiency contour map of the ICE; compare the ICE power output to the power demand; and if the ICE power output exceeds the power demand, supply a first subportion of the ICE power output to the final drive and supply a second subportion of the ICE power output to the energy storage unit to charge the energy storage unit; and if the ICE power output does not exceed the power demand, supply the ICE power output to the final drive and supply a remaining power from the electric motors by selectively allocating production of power such that at least one electric motor produces power at an operating point relative to the point of maximum efficiency on the efficiency contour map of the electric motor. 14. The control system of claim 13 wherein the controller is further programmed to iteratively define a charging power allocation for the energy storage unit. 15. The control system of claim 14 wherein the controller is further programmed to: determine a current state of charge (SOC) of the energy storage unit; access a charging power degradation model for the energy storage unit; and define the charging power allocation based on the determined current (SOC) and the charging power degradation model. 16. The control system of claim 13 wherein the controller is further programmed to supply the remaining power using a multi-objective optimization algorithm. 17. The control system of claim 16 wherein the multi-objective optimization algorithm determines an optimal vector of operating coefficients that maximizes an overall operating efficiency of the electric powertrain. 18. The vehicle propulsion system of claim 2 wherein the electromechanical devices comprise the remaining power sources.