Synchronous electric power distribution startup system

We claim: 1. A system comprising: a synchronous generator rotatable by a prime mover; a controller configured to provide excitation signals to the synchronous generator to excite the synchronous generator to output electric power; the controller further configured to provide an excitation signal at a first magnitude, during rotation of the synchronous generator at a speed less than rated speed, to supply a load bus with a first magnitude of current flow, the load bus electrically connected to a plurality of synchronous motor loads that are non-rotational in response to receipt of the first magnitude of current flow; the controller further configured to determine a rotating rotor position of the synchronous generator during rotation of the synchronous generator at less than the rated speed and a rotor position of at least one of the synchronous motor loads; the controller further configured to provide a pulse of the excitation signal at a second magnitude, the pulse provided coincident with a predetermined relative position of the rotating rotor position of the synchronous generator with respect to the rotor position of the at least one of the synchronous motor loads to supply the load bus with a second magnitude of current flow such that the plurality of synchronous motor loads rotate with the synchronous generator at the speed less than rated speed; and the controller further configured to synchronously ramp rotational speed of the synchronous generator and the plurality of synchronous motor loads to the rated speed of the synchronous generator. 2. The system of claim 1 , wherein the controller is configured to provide the pulse coincident with the predetermined relative position to create a flux linkage between the synchronous generator and the plurality of synchronous motor loads. 3. The system of claim 1 , wherein the first magnitude of current flow is insufficient to induce torque producing current flow at the plurality of synchronous motor loads to induce rotation, and the second magnitude of current flow is sufficient to induce torque producing current flow at the plurality of synchronous motor loads to induce rotation. 4. The system of claim 1 , wherein the second magnitude of the current flow establishes a flux linkage between the synchronous generator and the plurality of synchronous motor loads sufficient to overcome static friction and induce rotation of the plurality of synchronous motor loads. 5. The system of claim 1 , wherein the controller is further configured to provide excitation signals of the second magnitude at a time that a phase position of the rotating rotor position of the synchronous generator and the rotor position of the at least one of the synchronous motor loads substantially aligns. 6. The system of claim 1 , wherein the controller is configured to supply the load bus with the second magnitude of current flow to coincide with a projected minimum apparent power on the load bus. 7. The system of claim 1 , wherein the controller is further configured to provide the pulse of the excitation signal at the second magnitude at a time ahead of a projected minimum apparent power on the load bus. 8. The system of claim 1 , wherein the controller is configured to provide the pulse of the excitation signal at the second magnitude to coincide with a rocking movement of the at least one of the synchronous motor loads. 9. The system of claim 1 , wherein a back EMF flux linkage of the synchronous generator is at a nominal full load flux linkage in response to the excitation signal at the first magnitude, and back EMF flux linkage of the synchronous generator is increased to a predetermined percentage above the nominal full load flux linkage in response to the pulse of the excitation signal at the second magnitude. 10. A method comprising: controlling, with a controller, excitation signals that excite a synchronous generator rotatable by a prime mover to output electric power; directing, with the controller, provision of an excitation signal at a first magnitude, during rotation of the synchronous generator at a speed less than rated speed, to supply a load bus with a first magnitude of current flow, the load bus electrically connected to a plurality of synchronous motor loads that are non-rotational in response to receipt of the first magnitude of current flow; determining, with the controller, a rotating rotor position of the synchronous generator during rotation of the synchronous generator at less than the rated speed with respect to a rotor position of at least one of the synchronous motor loads; directing, with the controller, provision of a pulse of the excitation signal at a second magnitude coincident with a predetermined relative position of the rotating rotor position of the synchronous generator with respect to the rotor position of at least one of the synchronous motor loads to supply the load bus with a second magnitude of current flow such that the plurality of synchronous motor loads rotate with the synchronous generator at the speed less than rated speed; and synchronously ramping rotational speed of the synchronous generator and the plurality of synchronous motor loads to the rated speed of the synchronous generator. 11. The method of claim 10 , wherein the rotor position of at least one of the synchronous motor loads is stationary at a time when the pulse of the excitation signal at the second magnitude is provided. 12. The method of claim 10 , wherein the rotor position of at least one of the synchronous motor loads is rocking at a time when the pulse of the excitation signal at the second magnitude is provided. 13. The method of claim 10 , wherein directing, with the controller, provision of the pulse of the excitation signal at the second magnitude comprises selectively increasing the excitation signal at the first magnitude to the excitation signal at the second magnitude. 14. The method of claim 10 , wherein directing, with the controller, provision of the pulse of the excitation signal at the second magnitude comprises directing provision of a positive pulse of the excitation signal at the second magnitude coincident with a first predetermined relative position of the rotating rotor position of the synchronous generator with respect to the rotor position of the at least one of the synchronous motor loads and directing provision of a negative pulse of the excitation signal at the second magnitude coincident with a second predetermined relative position of the rotating rotor position of the synchronous generator with respect to the rotor position of the at least one of the synchronous motor loads. 15. The method of claim 10 , wherein directing, with the controller, provision of the pulse of the excitation signal at the second magnitude comprises urging, by the controller, the plurality of synchronous motor loads into synchronous electrical alignment with the synchronous generator using the pulse of the excitation signal at the second magnitude. 16. A system comprising: a controller configured to control output of a variable excitation signal; and a synchronous generator configured to generate output power for a plurality of rotational synchronous motor loads in response to receipt of the variable excitation signal; the controller configured to control output of the variable excitation signal to the synchronous generator such that the synchronous generator outputs a first torque producing current while the synchronous generator is rotating at less than rated speed and the plurality of rotational synchronous motor loads remain in a non-rotating state; the contro