Systems and methods concerning exciterless synchronous machines

The invention claimed is: 1. A system for operating a synchronous machine, comprising: a first surface of the rotor and second surface of the stator separated by an air gap, the rotor including a field winding, a rotating DC power supply and an exciter winding disposed in the first surface of the rotor adjacent the air gap, the exciter winding electrically coupled to an input of the DC power supply and the field winding coupled to an output of the DC power supply; and a converter electrically coupled to the stator, structured to transfer AC power including a fundamental frequency component between the converter and the stator, and including a harmonic injector, wherein the harmonic injector is configured to determine a harmonic component based on a prescribed current level of the field winding, wherein the harmonic injector is configured to selectively control the converter so as to add the harmonic component to the AC power transferred between the converter and the stator, wherein the exciter winding is structured to receive the harmonic component of the AC power, and wherein the DC power supply is structured to receive the harmonic component from the exciter winding, convert the harmonic component to DC power, and transmit the DC power to the field winding. 2. The system of claim 1 , wherein the DC power supply is a passive DC power supply. 3. The system of claim 1 , wherein converter includes a rectifier having an input electrically coupled to a multi-phase supply and an output coupled to an inverter, the harmonic injector electrically coupled to the inverter and configured to selectively supply one or both of temporal and spatial harmonics to the inverter. 4. A method for operating a synchronous machine, comprising: selecting a prescribed current level in a rotor winding of the synchronous machine; determining a harmonic distortion based on the prescribed current level, the harmonic distortion including a harmonic frequency; injecting the harmonic distortion to the stator winding of the synchronous machine so as to transfer AC power to the stator winding including a fundamental frequency component and the harmonic distortion, inducing current attributable to the harmonic distortion in an exciter winding disposed in a surface of the rotor adjacent an air gap of the machine; rectifying current in the exciter winding; and, supplying the rectified current to rotor windings of the rotor, thereby effecting the prescribed current level in the rotor winding. 5. The method of claim 4 , wherein the selecting step includes selecting one or more of a voltage level or power level corresponding to a prescribed current level. 6. A method for operating a synchronous machine, comprising: selecting a prescribed current level in a rotor winding of the synchronous machine based at least in part on electrical conditions in stator windings of the machine; calculating a harmonic component based on the prescribed current level; operating a converter including a harmonic injector so as to output AC power including a fundamental frequency component and the harmonic component; transferring the AC power from the converter to the stator windings; receiving the harmonic frequency component of the AC power with exciter windings disposed in an outer surface of a rotor adjacent an air gap of the machine; communicating a wireless control signal from the converter to a rotating DC power supply in the rotor, the control signal corresponding to the prescribed current level; rectifying current in the exciter windings; and supplying the current to the rotor winding based on the control signal. 7. The method of claim 6 , wherein the communicating step includes communicating a control signal from a transmitter electrically coupled to an automatic voltage regulator to a receiver coupled to the DC power supply.