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A synchronous brushless machine having a single exciter field stator winding. The single exciter field stator winding is energized by a high frequency alternating current to provide a single excitation field to magnetically couple with the exciter field armature winding in both the starter mode and

A synchronous brushless machine having a single exciter field stator winding. The single exciter field stator winding is energized by a high frequency alternating current to provide a single excitation field to magnetically couple with the exciter field armature winding in both the starter mode and the generator mode. With a higher excitation frequency relative to the main armature current frequency, a steady main field voltage can be achieved which improves stability control while in the starter mode. In one or more configurations, the single exciter field stator winding is driven by a H-bridge converter.

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1. A starter-generator system comprising: a stator;a rotor mounted for rotation with respect to the stator;a main field winding;an exciter field armature winding;a rectifier for rectifying an output from the exciter field armature winding to provide DC excitation for the main field winding, wherein

1. A starter-generator system comprising: a stator;a rotor mounted for rotation with respect to the stator;a main field winding;an exciter field armature winding;a rectifier for rectifying an output from the exciter field armature winding to provide DC excitation for the main field winding, wherein the main field winding, the exciter field armature winding, and the rectifier are mounted for rotation with the rotor;a main armature winding mounted on the stator and magnetically coupled to the main field winding; anda single dual-mode exciter field stator winding configured to provide a single excitation field to magnetically couple with the exciter field armature winding when the starter-generator system is operating in a starter mode and when the starter-generator system is operating in a generator mode. 2. The starter-generator system of claim 1, wherein a single excitation source is provided to the single exciter field stator winding when the starter-generator system is operating in the starter mode and when the starter-generator system is operating in a generator mode. 3. The starter-generator system of claim 2, wherein the single excitation source comprises a high frequency alternating current. 4. The starter-generator system of claim 3, wherein a frequency of the high frequency alternating current is greater than a fundamental electrical frequency of the starter-generator system. 5. The starter-generator system of claim 1, wherein the single exciter field stator winding is driven by an H-bridge converter. 6. The starter-generator system of claim 1, wherein only the single exciter field stator winding is magnetically coupled to the exciter field armature winding while operating in the starter mode and while operating in the generator mode. 7. The starter-generator system of claim 1, wherein a magnetic field created by the exciter field stator winding does not rotate. 8. The starter-generator system of claim 1, wherein an amplitude of a voltage waveform at the main field winding remains constant while a speed of the rotor varies. 9. The starter-generator system of claim 1, wherein frequencies of voltage waveforms at the exciter field armature winding vary with a speed of the rotor and the voltage waveforms have substantially the same amplitude as the speed of the rotor varies. 10. The starter-generator system of claim 1, wherein the exciter field armature winding is a single phase winding. 11. The starter-generator system of claim 1, wherein the exciter field armature winding is a multi-phase winding. 12. The starter-generator system of claim 1, wherein the single exciter field stator winding and the exciter field armature winding are both single phase windings. 13. The starter-generator system of claim 1, wherein the exciter field armature winding and the single exciter field stator winding define a transformer configured to transform an alternating current input voltage between the single exciter field stator winding and the exciter field armature winding. 14. The starter-generator system of claim 1, wherein the starter-generator system is a two-stage synchronous brushless machine. 15. The starter-generator system of claim 1, wherein the starter-generator system is a three-stage synchronous brushless machine. 16. A starter-generator system comprising: a stator;a rotor mounted for rotation with respect to the stator;a main field winding;an exciter field armature winding;a rectifier for rectifying an output from the exciter field armature winding to provide DC excitation for the main field winding, wherein the main field winding, the exciter field armature winding, and the rectifier are mounted for rotation with the rotor;a main armature winding mounted on the stator and magnetically coupled to the main field winding; anda single dual-mode exciter field stator winding configured to be energized by a high frequency alternating current to provide a single excitation field to magnetically couple with the exciter field armature winding when the starter-generator system is operating in a starter mode and when the start-generator system is operating in a generator mode,wherein frequencies of voltage waveforms at the exciter field armature winding vary with a speed of the rotor, the voltage waveforms at the exciter field armature winding have substantially the same amplitude as the speed of the rotor varies, and an amplitude of a voltage waveform at the main field winding remains constant as the speed of the rotor varies. 17. The starter-generator system of claim 16, wherein a magnetic field created by the exciter field stator winding does not rotate. 18. A method for controlling a synchronous brushless machine having a rotor and stator and configured to be operated in a starter mode and in a generator mode, the method comprising: energizing a single dual-mode exciter field stator winding of the synchronous brushless machine with a high frequency alternating current, thereby generating a single excitation field,wherein the generated single excitation field operates, in the starter mode and in the generator mode of the synchronous brushless machine, to magnetically couple the single exciter field stator winding with an exciter field armature winding of the synchronous brushless machine. 19. The method of claim 18, further comprising maintaining an amplitude of a voltage waveform at a main field winding of the synchronous brushless machine while a speed of the rotor varies. 20. The method of claim 18, further comprising varying frequencies of voltage waveforms at an exciter field armature winding of the synchronous brushless machine while the voltage waveforms have substantially the same amplitude as a speed of the rotor varies. 21. The method of claim 18, wherein energizing the single exciter field stator winding comprises driving the single exciter field stator winding with an H-bridge converter. 22. The method of claim 18, further comprising starting an engine of an aircraft while the synchronous brushless machine is operating in the starter mode. 23. The method of claim 18, further comprising powering equipment loads of an aircraft while the synchronous brushless machine is operating in the generator mode.