System and method for integrated battery charging and propulsion in plug-in electric vehicles

What is claimed is: 1. A system for integrated charging an electric vehicle, the system comprising: a hybrid excitation machine operable in a traction mode as a traction motor or in an integrated charging (IC) mode and including a rotor separated by an air gap from a stator having a set of AC stator windings to conduct an AC electrical current; said set of AC stator windings configured to conduct the AC electrical current from an AC utility line voltage supply in the IC mode and for filtering and/or boosting an AC voltage therefrom; said AC electrical current in said set of AC stator windings inducing a magnetic flux across said air gap and in said rotor with the AC electrical current flowing therethrough; wherein the magnetic flux interacts with said rotor in the traction mode to produce a driving torque; and wherein said hybrid excitation machine is configured to reduce an interaction between the magnetic flux and said rotor in the IC mode. 2. The system for integrated charging an electric vehicle according to claim 1 , wherein said stator of said hybrid excitation machine further includes a DC winding configured to carry a DC current to reduce the magnetic flux across said air gap and into said rotor. 3. The system for integrated charging an electric vehicle according to claim 2 , wherein said DC winding includes two or more DC windings. 4. The system for integrated charging an electric vehicle according to claim 2 , further including a DC power supply configured to apply a DC voltage across said DC winding to reduce the magnetic flux across said air gap and to reduce the magnetic flux into said rotor. 5. The system for integrated charging an electric vehicle according to claim 2 , further including circuitry to cause said DC winding to be in one of an open circuit configuration or a short circuit configuration to reduce the magnetic flux across said air gap and to reduce the magnetic flux through said rotor. 6. The system for integrated charging an electric vehicle according to claim 1 wherein said rotor includes a permanent magnet. 7. The system for integrated charging an electric vehicle according to claim 6 , further including: said rotor including a secondary coil configured to be excited by a coupling magnetic field to generate an AC voltage, and a rectifier in electrical communication with said secondary coil for changing said AC voltage to a DC voltage between a DC positive node and a DC negative node; an AC supply providing an AC current in a primary coil magnetically coupled with said secondary coil in said rotor to induce the induced AC voltage therein and to thereby cause said field winding of said rotor to be excited in the traction mode; wherein said rotor is externally excited, with said field winding being isolated from the magnetic flux from said set of AC stator windings by being axially spaced outside of said stator; and wherein said AC supply is inhibited from providing the AC current in said primary coil to prevent inducing the induced AC voltage in said secondary coil and to thereby cause said field winding of said rotor to be de-excited in the IC mode. 8. The system for integrated charging an electric vehicle according to claim 1 wherein said rotor of said hybrid excitation machine further includes a field winding configured to be excited with a DC voltage in the traction mode to interact with the magnetic flux from said set of AC stator windings and to produce a driving torque; and wherein said field winding of said rotor is configured to be de-excited in the IC mode preventing said rotor from producing the driving torque. 9. The system for integrated charging an electric vehicle according to claim 8 , further including: a secondary coil included in said rotor and configured to be excited by a coupling magnetic field to generate an induced AC voltage, and a rectifier in electrical communication with said secondary coil for changing said induced AC voltage to a DC voltage between a DC positive node and a DC negative node; said rotor having a cylindrical configuration including a field winding connected between said DC positive node and said DC negative node and disposed within said stator; wherein said field winding of said rotor is configured to be excited with said DC voltage in the traction mode with said hybrid excitation machine operable as a traction motor, with said field winding interacting with the magnetic flux from said set of AC stator windings to produce a driving torque; and wherein said field winding of said rotor is configured to be de-excited in the IC mode for integrated charging (IC), thereby preventing said rotor from producing the driving torque. 10. The system for integrated charging an electric vehicle according to claim 9 , wherein said rotor is self-excited, with said field winding being in quadrature to said secondary coil and each configured to interact with the magnetic flux from said set of AC stator windings and further including: an IC controller configured to operate a plurality of power electronics switches in an AC-DC converter using a field-oriented control to cause the magnetic flux from said set of AC stator windings to produce the coupling magnetic field that is aligned with said secondary coil in said rotor to induce the induced AC voltage therein and to thereby cause said field winding of said rotor to be excited in the traction mode; and wherein said IC controller is configured to operate said plurality of power electronics switches in said AC-DC converter using the field-oriented control to cause the magnetic flux from said set of AC stator windings to produce a magnetic field that is out of phase from said secondary coil in said rotor to prevent the induction of the induced AC voltage in said secondary coil and to thereby cause said field winding of said rotor to be de-excited in the IC mode. 11. The system for integrated charging an electric vehicle according to claim 1 , further including: said rotor having a cylindrical configuration including a plurality of rotor bars extending axially therethrough; and each rotor bar of said plurality of rotor bars being electrically connected to an adjacent rotor bar of said plurality of rotor bars by a jumper conductor and configured to conduct electrical current in opposite axial directions; and all rotor bars of said plurality of rotor bars being electrically connected in a series configuration with electrical current in each rotor bar of said plurality of rotor bars flowing in a direction opposite to the electrical current in the adjacent rotor bar of the plurality of rotor bars. 12. The system for integrated charging an electric vehicle according to claim 1 , further including: an AC-DC converter, configured to rectify the AC electrical current from the AC utility line voltage supply to an intermediate DC voltage on an intermediate DC conductor; a DC-DC converter, producing an output DC voltage different than an input DC voltage to the DC-DC converter; a battery bus energized with a first DC voltage and; a second DC bus energized with a second DC voltage different than the first DC voltage; wherein the system is configured to operate in a first mode with the DC-DC converter transmitting electrical power from the AC-DC converter to the battery bus; and wherein the system is configured to operate in a second mode with the DC-DC converter transmitting electrical power from battery bus to the second DC bus. 13. The system for integrated charging an electric vehicle according to claim 12 , wherein the AC-DC converter includes a bridgeless totem pole power factor correction (PFC) circuit. 14. The system