Synchronous machine with common motor/generator exciter stage

The invention claimed is: 1. A synchronous machine operable in a selected mode of a generator mode and a motor mode, the synchronous machine comprising: a frame; a shaft extending from at least one end of the frame; a main section, comprising: a stationary winding mounted to the frame; and a rotating winding, mounted on the shaft, and spaced apart from and magnetically coupled to the stationary winding; a single, high-frequency exciter section, comprising: a transformer having a primary winding and a secondary winding magnetically coupled to each other, each winding being in the shape of a disk, the secondary winding having an exterior radius and being secured to the shaft, the primary winding having an interior radius and being mounted to the frame, the exterior radius being less than the interior radius, the secondary winding being positioned within the primary winding; a rectifier, secured to the shaft, to rectify an output of the secondary winding and provide a rectified output to the rotating winding; and a plurality of first electrical conductors to connect the output of the secondary winding to the rectifier, and to connect the rectified output of the rectifier to the rotating winding; and a control unit coupled with the stationary winding via a plurality of electrical lines, the control unit configured to: determine a first frequency of a voltage on the plurality of electrical lines; and provide a control signal to the primary winding of the transformer via a plurality of second electrical conductors, wherein a second frequency of the control signal is selected to be at least ten times greater than the determined first frequency. 2. The synchronous machine of claim 1 wherein the stationary winding is an armature winding and the rotating winding is a field winding. 3. The synchronous machine of claim 1 wherein the synchronous machine operates in the generator mode when an input torque is applied to the shaft. 4. The synchronous machine of claim 3 wherein: in the generator mode, the control unit receives an output voltage from the stationary winding via the plurality of electrical lines, the output voltage having an output frequency; and the control unit causes the control signal to have a frequency at least ten times greater than the output frequency of the output voltage. 5. The synchronous machine of claim 1 wherein the synchronous machine operates in the motor mode when an input voltage is applied to the stationary winding. 6. The synchronous machine of claim 5 wherein: the input voltage has an input frequency; and the control unit causes the control signal to have a frequency at least ten times greater than the input frequency of the input voltage. 7. The synchronous machine of claim 1 , wherein the control signal is provided to the primary winding further using at least one of a measured rotation speed and an angular position of the shaft. 8. The synchronous machine of claim 1 , wherein the control unit is further configured to: monitor at least a first electrical parameter associated with the stationary winding when operating in the generator mode; and monitor at least a second electrical parameter associated with the stationary winding when operating in the motor mode, wherein the second electrical parameter is different from the first electrical parameter, wherein the control signal is based on the first electrical parameter when operating in the generator mode, and wherein the control signal is based on the second electrical parameter when operating in the motor mode. 9. The synchronous machine of claim 8 , wherein in the generator mode, the first electrical parameter comprises an output voltage provided by the stationary winding to the control unit, and wherein in the motor mode, the control signal is provided to the primary winding further using the angular position of the shaft. 10. The synchronous machine of claim 9 , wherein the control unit is configured to vary at least one of a duty cycle, a frequency, or an output voltage of the control signal responsive to the first electrical parameter or responsive to the second electrical parameter. 11. The synchronous machine of claim 1 , wherein the first frequency is 400 hertz and the second frequency is 10 kilohertz. 12. The synchronous machine of claim 1 , wherein in the motor mode, the control unit is further configured to: apply the voltage to the stationary winding via the plurality of electrical lines. 13. The synchronous machine of claim 1 , wherein in the generator mode, the control signal provided by the control unit to the primary winding of the transformer is the sole excitation source. 14. A method of manufacturing a synchronous machine operable as either a synchronous motor or a synchronous generator, the method comprising: providing a frame; mounting a stationary winding to the frame; providing a shaft which extends from at least one end of the frame; mounting a rotating winding on the shaft, the rotating winding being spaced apart from, and magnetically coupled to, the stationary winding; mounting a primary winding of a transformer on the frame, wherein the primary winding has an interior radius; mounting a secondary winding of the transformer on the shaft, the secondary winding being spaced apart from, and magnetically coupled to, the primary winding, wherein the secondary winding has an exterior radius that is less than the interior radius, and wherein the secondary winding is positioned within the primary winding; securing a rectifier to the shaft, connecting an input of the rectifier to the secondary winding, and connecting an output of the rectifier to the rotating winding; and coupling a control unit with the stationary winding via a plurality of electrical lines, the control unit configured to: determine a first frequency of a voltage on the plurality of electrical lines; and provide a control signal to the primary winding of the transformer, wherein a second frequency of the control signal is selected to be at least ten times greater than the determined first frequency. 15. The method of claim 14 , wherein: the primary winding and the secondary winding are each in the form of a disk, the disk of the primary winding defines a plane, and the disk of the secondary winding is substantially in that same plane. 16. The method of claim 14 , wherein the control unit is configured to: monitor at least a first electrical parameter associated with the stationary winding when operating as a synchronous generator; and monitor at least a second electrical parameter associated with the stationary winding when operating as a synchronous motor, wherein the second electrical parameter is different from the first electrical parameter, wherein the control signal is based on the first electrical parameter when operating as a synchronous generator, and wherein the control signal is based on the second electrical parameter when operating as a synchronous motor.