Method and apparatus for control of pulsed power in hybrid energy storage module

What is claimed is: 1. A system, comprising: an inertial energy storage device; a first dynamo-electric machine directly coupled to the inertial energy storage device, the first dynamo-electric machine having (i) multiple input stator windings configured to accept alternating current (AC) input power, (ii) a rotor winding configured to be excited by an exciter, and (iii) at least one polyphase output stator winding configured to deliver electric power at a first rate to a direct current (DC) bus; a secondary energy storage system coupled to the DC bus and configured to exchange electrical energy in a bi-directional manner; a second dynamo-electric machine coupled to the inertial energy storage device and the first dynamo-electric machine by a shaft, the second dynamo-electric machine having (i) an input stator winding and (ii) at least one polyphase output stator winding coupled to an AC/DC power converter, the power converter coupled to a DC output configured to couple to a load device, and a polyphase boost exciter configured to derive energy from the DC bus and excite the input stator winding of the second dynamo-electric machine, wherein the second dynamo-electric machine is configured to be excited at a second rate that is faster than the first rate. 2. The system as specified in claim 1 , wherein the at least one polyphase output stator winding of the first dynamo-electric machine is configured to deliver the electric power to the DC bus at a plurality of power, duty-cycle, and voltage levels. 3. The system as specified in claim 1 , wherein the system is configured to bi-directionally transfer energy between the DC output, the secondary energy storage system, the inertial energy storage device, and an AC source associated with the AC input power. 4. The system as specified in claim 1 , further comprising a polyphase pulse foiming network (PFN) coupled between the DC bus and the polyphase boost exciter, the PFN configured to provide fast excitation control of the second dynamo-electric machine. 5. The system as specified in claim 4 , wherein the second dynamo-electric machine has a plurality of electrically isolated stator outputs formed by a plurality of polyphase output stator windings configured to create discrete electrical phase shifts between the plurality of polyphase output stator windings. 6. The system as specified in claim 5 , wherein the second dynamo-electric machine has four electrically isolated 3-phase stator outputs configured to provide discrete phase shifts of 0 degrees, 15 degrees, 30 degrees, and 45 degrees. 7. The system as specified in claim 5 , wherein the power converter is coupled between the at least one polyphase output stator winding of the second dynamo-electric machine and the DC output, the power converter configured to increase or decrease frequency and voltage and to perform rectification and inversion functions. 8. The system as specified in claim 7 , wherein the power converter comprises a bi-directional rectifier and inverter configured to permit power flow into and out of the second dynamo-electric machine and energy recovery to the inertial energy storage device. 9. The system as specified in claim 5 , further comprising an array of active front end (AFE) and load resonant converters (LRCs) coupled between the stator outputs of the second dynamo-electric machine and the DC output. 10. The system as specified in claim 1 , further comprising a bi-directional rectifier and inverter coupled between the at least one polyphase output stator winding of the first dynamo-electric machine and the DC bus. 11. The system as specified in claim 1 , further comprising a pulse foi ming network (PFN) driven load coupled to the DC bus, wherein the first dynamo-electric machine is configured to control a charging rate to the PFN driven load. 12. The system as specified in claim 11 , further comprising a stochastic load coupled to the DC bus and configured to draw energy from either the secondary energy storage system or the inertial energy storage device. 13. The system as specified in claim 1 , further comprising an array of active front end (AFE) and load resonant converters (LRCs) coupled to the input stator windings of the first dynamo-electric machine and configured to receive energy from a power source. 14. The system as specified in claim 13 , wherein the AFE and LRCs are configured to provide variable-voltage variable-frequency power from a DC power source. 15. The system as specified in claim 1 , further comprising a gearbox coupled to the shaft, the gearbox configured to increase a speed of the shaft at the second dynamo-electric machine and the inertial energy storage device. 16. The system as specified in claim 1 , wherein the first dynamo-electric machine and the second dynamo-electric machine each comprise a wound-rotor field doubly-fed induction machine. 17. The system as specified in claim 1 , wherein the secondary energy storage system comprises an electro-chemical battery. 18. A system, comprising: a flywheel; a first dynamo-electric machine directly coupled to the flywheel, the first dynamo-electric machine having (i) multiple input stator windings configured to accept power, (ii) a rotor winding configured to be excited by both a direct current (DC) and an alternating current (AC), exciter, and (iii) at least one polyphase output stator winding configured to deliver electric power at a first rate to a DC bus at different power, duty-cycle, and voltage levels; an array of active front end (AFE) and load resonant converters (LRCs) coupled to the input stator windings of the first dynamo-electric machine and configured to provide variable-voltage variable-frequency power from a power source to the input stator windings of the first dynamo-electric machine; an electro-chemical battery coupled to the DC bus and configured to exchange electrical energy in a bi-directional manner; a second dynamo-electric machine coupled to the flywheel and the first dynamo-electric machine by a shaft, the second dynamo-electric machine having (i) a controllable input stator winding and (ii) a plurality of polyphase output stator windings each coupled to a DC output; and a polyphase boost exciter configured to derive energy from the DC bus and excite the input stator winding of the second dynamo-electric machin, wherein the second dynamo-electric machine is configured to be excited at a second rate that is faster than the first rate; wherein the system is configured to bi-directionally transfer energy between the DC output, the electro-chemical battery, the flywheel, and the power source. 19. The system as specified in claim 18 , wherein the polyphase output stator windings of the second dynamo-electric machine are configured to create discrete phase shifts, the polyphase output stator windings forming multiple groups of polyphase windings that are galvanically isolated from each other. 20. The system as specified in claim 19 , further comprising an array of step-up transformers and power converters configured to drive a pulse forming network or a pulsed load. 21. The system as specified in claim 19 , wherein: the first dynamo-electric machine is operable in a dual mode whereby the rotor winding is configured to be powered by either DC excitation current or polyphase AC excitation current, and the dual mode comprises (i) a first mode where the first dynamo-electric machine is operating synchronously and (ii) a second mode where the first dynamo-electric machine is operating