Brushless, Self-Excited Synchronous Field-Winding Machine

What is claimed is: 1 . An electric machine, comprising: a rotor; an AC stator arranged adjacent to and interoperable with the rotor, wherein the AC stator is configured with four or more phases to independently produce magnetic fields at two or more spatial harmonics; wherein the rotor includes an excitation winding and a field winding and the field winding is electrically coupled to the excitation winding, wherein the excitation winding and the field winding are configured to magnetically couple to the two or more spatial harmonics of the AC drive signal, such that the excitation winding is independently excitable from the field winding by different spatial harmonics of the AC drive signal; and a controller electrically coupled to windings of the AC stator and independently controls the magnetic fields at the two or more spatial harmonics. 2 . The electric machine of claim 1 wherein the torque of the electric machine is determined as a function of current in the field winding and current in the stator that produces the spatial harmonic which magnetically couples to the field winding. 3 . The electric machine of claim 1 wherein the excitation winding is configured to magnetically couple to a given harmonic of the magnetic fields produced by the AC stator and the field winding is configured to magnetically couple to another harmonic which is three times the given harmonic. 4 . The electric machine of claim 1 wherein the AC stator includes windings arranged to generate an AC drive signal. 5 . The electric machine of claim 1 wherein the AC stator is configured with five windings and the excitation winding is further defined as a three phase winding. 6 . The electric machine of claim 1 wherein the field winding is electrically coupled by a rectifier circuit to the excitation winding. 7 . The electric machine of claim 1 wherein the controller is electrically coupled via an inverter circuit to the windings of the AC stator. 8 . The electric machine of claim 1 wherein the controller is configured to receive measurements of current in windings of the stator and convert the current measurements to d-q currents using a direct-quadrature-zero transformation. 9 . The electric machine of claim 8 where the controller calculate an difference between the d-q currents and a set of reference currents, converts the differences to voltages and generate command voltages for the AC stator using an inverse direct-quadrature-zero transformation. 10 . An electric machine, comprising: a rotor; an AC stator arranged adjacent to and interoperable with the rotor, wherein the AC stator having windings arranged to independently produce magnetic fields at two or more spatial harmonics; wherein the rotor includes an excitation winding and a field winding and the field winding is electrically coupled by a rectifier circuit to the excitation winding, such that the excitation winding is configured to magnetically couple to a given spatial harmonic of the two or more spatial harmonics of the AC drive signal and the field winding is configured to magnetically couple to another harmonic of the two or more spatial harmonics of the AC drive signal, where the given harmonic differs from the another harmonic; and a controller electrically coupled via an inverter circuit to windings of the AC stator and independently controls the magnetic fields at the two or more spatial harmonics. 11 . The electric machine of claim 10 wherein the torque of the electric machine is determined as a function of current in the field winding and current in the stator that produces the spatial harmonic which magnetically couples to the field winding. 12 . The electric machine of claim 10 wherein the excitation winding is configured to magnetically couple to a given harmonic of the magnetic fields produced by the AC stator and the field winding is configured to magnetically couple to another harmonic which is three times the given harmonic. 13 . The electric machine of claim 10 wherein the excitation winding has a 2-pole winding arrangement and the field winding has a 6-pole winding arrangement. 14 . The electric machine of claim 10 wherein the excitation winding has a 4-pole winding arrangement and the field winding has a 12-pole winding arrangement. 15 . The electric machine of claim 10 wherein the AC stator has 4-pole winding arrangement. 16 . The electric machine of claim 10 wherein the controller is configured to receive measurements of current in windings of the stator and convert the current measurements to d-q currents using a direct-quadrature-zero transformation. 17 . The electric machine of claim 16 where the controller calculate an difference between the d-q currents and a set of reference currents, converts the differences to voltages and generate command voltages for the AC stator using an inverse direct-quadrature-zero transformation.