Rotor power transfer circuit for electric machine

What is claimed is: 1 . A rotor power transfer circuit for an electric machine, comprising: a multiple leaf direct current (DC)-to-DC (DC-DC) converter having a plurality of branches connected in parallel to a source of DC power, each branch including a plurality of switches operable for selectively controlling DC power transfer therethrough; an electrical interface configured for electrically connecting each branch with one of a one or more rotor windings wrapped around a plurality of circumferentially spaced rotor protrusions of the electric machine; and a controller operable for controlling the switches according to a plurality of rotor winding excitations modes; wherein: the rotor winding excitation modes includes a powered excitation mode, the powered excitation mode transferring DC power from the source to one or more of the rotor windings; the rotor windings includes a first rotor winding and second rotor winding; the plurality of branches include a first branch and a second branch; and the powered excitation mode transfers the DC power simultaneously through the first branch and the second branch, with the first branch transferring the DC power to the first rotor winding and the second branch transferring the DC power to the second rotor winding. 2 . The rotor power transfer circuit according to claim 1 , wherein: the rotor winding excitation modes include a decaying excitation mode, the decaying excitation mode transferring DC power from one or more of the rotor windings to the source. 3 . The rotor power transfer circuit according to claim 1 , wherein: the rotor winding excitation modes include a freewheeling excitation mode, the freewheeling excitation mode providing a source bypass connection for one or more of the rotor windings, the source bypass connection bypassing the source to independently connect together a positive terminal and a negative terminal of the rotor windings associated therewith. 4 . The rotor power transfer circuit according to claim 1 , wherein: the rotor winding excitation modes include a decaying excitation mode, the decaying excitation mode providing a reverse connection for one or more of the rotor windings, the reverse connection electrically connecting the rotor winding associated therewith to the source with reversed polarity. 5 . The rotor power transfer circuit according to claim 1 , further comprising: a DC link capacitor connected in a parallel between the source and the multiple leaf direct current DC-DC converter. 6 . A rotor power transfer circuit for an electric motor, the electric motor operable for propelling a vehicle, comprising: a multiple leaf direct current (DC)-to-DC (DC-DC) converter having a first branch and a second branch connected in parallel to a source of DC power, the first branch including a plurality of first switches operable for selectively controlling DC power transfer therethrough, the second branch including a plurality of second switches operable for selectively controller DC power transfer therethrough; an electrical interface configured for electrically connecting the first and second branches with a plurality of rotor windings of the electric motor; and a controller operable for controlling the first and second switches according to a plurality of rotor winding excitations modes; wherein: the rotor winding excitation modes includes a powered excitation mode, the powered excitation mode transferring DC power from the source to one or more of the rotor windings; the rotor windings includes a first rotor winding and second rotor winding; the plurality of branches include a first branch and a second branch; and the powered excitation mode transfers the DC power simultaneously through the first branch and the second branch, with the first branch transferring the DC power to the first rotor winding and the second branch transferring the DC power to the second rotor winding. 7 . The rotor power transfer circuit according to claim 6 , wherein: the first branch is phase shifted relative to the DC power transferred through the second branch. 8 . The rotor power transfer circuit according to claim 7 , wherein: the first branch includes a first inside leg and a first outside leg connected in parallel across the source, the first inside leg including a first upper switch of the first switches connected in series with a first lower diode, the first outside leg including a first lower switch of the first switches connected in series with a first upper diode; and the second branch includes a second inside leg and a second outside leg connected in parallel across the source, the second inside leg including a second upper switch of the second switches connected in series with a second lower diode, the second outside leg including a second lower switch of the second switches connected in series with a second upper diode. 9 . The rotor power transfer circuit according to claim 8 , wherein: the electrical interface connects a positive terminal of the rotor windings to the first inside leg between the first upper switch and the first lower diode and to the second inside leg between the second upper switch and the second lower diode; and electrical interface connects a negative terminal of the rotor windings to the first outside leg between the first lower switch and the first upper diode and to the second outside leg between the second lower switch and the second upper diode. 10 . A rotor power transfer circuit for an electric motor of a vehicle, the electric motor having a plurality of rotor winding sets wrapped around each of a plurality of circumferentially spaced rotor poles, comprising: a multiple leaf direct current (DC)-to-DC (DC-DC) converter having a first branch and a second branch connected in parallel to a source of DC power, the first branch including a plurality of first switches operable for selectively controlling DC power transfer therethrough, the second branch including a plurality of second switches operable for selectively controller DC power transfer therethrough; an electrical interface having a first interface configured for electrically connecting the first branch with a first winding set of the rotor winding sets and a second interface configured for electrically connecting the second branch with a second winding set of the rotor winding sets; and a controller operable for controlling the first and second switches according to a plurality of rotor winding excitations modes. 11 . The rotor power transfer circuit according to claim 10 , wherein: the rotor winding excitation modes includes a dual powered excitation mode, the dual powered excitation mode transferring DC power from the source simultaneously through the first and second branches respectively to the first and second rotor winding sets. 12 . The rotor power transfer circuit according to claim 10 , wherein: the rotor winding excitation modes includes a powered-freewheeling excitation mode, the powered-freewheeling excitation mode transferring DC power from the source through the first branch to the first winding set and providing a source bypass connection for the second rotor winding set, the source bypass connection bypassing the source to independently connect together a positive terminal and a negative terminal of the second rotor winding set. 13 . The rotor power transfer circuit according to claim 10 , wherein: the rotor winding excitation modes include a decaying excitation mode, the decaying excitation mode providing a reverse connection for the first and/or second rotor winding sets, the reverse connection electrically connecting the rotor windi