Fault-tolerant power distribution in a vehicle

What is claimed is: 1. A vehicle comprising: a basic structure; and coupled to the basic structure, a plurality of power sources; a propulsion system including a plurality of electric motors configured to power a plurality of propulsors to generate propulsive forces that cause the vehicle to move; and power distribution circuitry configured to deliver direct current (DC) electric power from the plurality of power sources to the plurality of electric motors, the power distribution circuitry including a plurality of DC-to-DC converter assemblies configured to input the DC electric power from the plurality of power sources and deliver voltage-regulated outputs to the plurality of electric motors, a DC-to-DC converter assembly operatively coupled to multiple ones of the plurality of power sources and multiple ones of the plurality of electric motors, and the DC-to-DC converter assembly including a multiple-input and multiple-output (MIMO) transformer with a single transformer core. 2. The vehicle of claim 1 , wherein the plurality of propulsors include one or more of rotors, propellers or wheels. 3. The vehicle of claim 1 , wherein the MIMO transformer further includes multiple primary coils and multiple secondary coils wound around the single transformer core, and isolated from one another but magnetically coupled by the single transformer core. 4. The vehicle of claim 3 , wherein the DC-to-DC converter assembly further includes a plurality of high-frequency power converters including a first multiple high-frequency power converters coupled to respective ones of the multiple primary coils of the MIMO transformer, and a second multiple high-frequency power converters coupled to respective ones of the secondary coils of the MIMO transformer. 5. The vehicle of claim 4 , wherein at least some of the plurality of high-frequency power converters include bridge circuits with respective switches, and wherein the power distribution circuitry further includes power control circuitry configured to control the respective switches to thereby control power flow through the DC-to-DC converter assembly, and manage magnetic flux through the single transformer core. 6. The vehicle of claim 5 , wherein the power control circuitry is configured to control the respective switches to synchronize the power flow through the DC-to-DC converter assembly. 7. The vehicle of claim 5 , wherein the power control circuitry is configured to control the respective switches to control different amounts of power through the DC-to-DC converter assembly simultaneously. 8. The vehicle of claim 5 , wherein the power control circuitry is further configured to control the respective switches of one or more of the high-frequency power converters to compensate for a fault or failure at one of the high-frequency power converters, or a fault or failure at one of the multiple ones of the plurality of power sources operatively coupled to the DC-to-DC converter assembly. 9. The vehicle of claim 1 , wherein each electric motor has dual armature windings driven by dual, independent motor drives to develop a magnetic field to provide torque to rotate a motor shaft that causes a respective one of the plurality of propulsors to generate a propulsive force, and the DC-to-DC converter assembly includes at least: a first DC-to-DC converter configured to deliver first voltage-regulated outputs to a first of the dual, independent motor drives and thereby a first of the dual armature windings of a first and a second of the plurality of electric motors; and a second DC-to-DC converter configured to deliver second voltage-regulated outputs to a second of the dual, independent motor drives and thereby a second of the dual armature windings of the first and the second of the electric motors. 10. The vehicle of claim 9 , wherein the first DC-to-DC converter is configured to input the DC electric power from a first and a second of the plurality of power sources, and the second DC-to-DC converter is configured to input the DC electric power from a third and a fourth of the plurality of power sources. 11. The vehicle of claim 9 , wherein the first DC-to-DC converter is configured to input the DC electric power from a first and a second of the plurality of power sources, and the second DC-to-DC converter is configured to input the DC electric power from the first or the second of the plurality of power sources, and a third of the plurality of power sources. 12. A method of managing power in a vehicle, the method comprising: providing the vehicle including a plurality of power sources, a propulsion system including a plurality of electric motors configured to power a plurality of propulsors to generate propulsive forces that cause the vehicle to move, and power distribution circuitry electrically coupling the plurality of power sources to the plurality of propulsors; and delivering direct current (DC) electric power from the plurality of power sources to the plurality of electric motors via the power distribution circuitry that includes a plurality of DC-to-DC converter assemblies inputting the DC electric power from the plurality of power sources and delivering voltage-regulated outputs to the plurality of electric motors, a DC-to-DC converter assembly operatively coupled to multiple ones of the plurality of power sources and multiple ones of the plurality of electric motors, and the DC-to-DC converter assembly including a multiple-input and multiple-output (MIMO) transformer with a single transformer core. 13. The method of claim 12 , wherein providing the vehicle includes providing the vehicle in which the MIMO transformer further includes multiple primary coils and multiple secondary coils wound around the single transformer core, and isolated from one another but magnetically coupled by the single transformer core. 14. The method of claim 13 , wherein providing the vehicle includes providing the vehicle in which the DC-to-DC converter assembly further includes a plurality of high-frequency power converters including a first multiple high-frequency power converters coupled to respective ones of the multiple primary coils of the MIMO transformer, and a second multiple high-frequency power converters coupled to respective ones of the secondary coils of the MIMO transformer. 15. The method of claim 14 , wherein providing the vehicle includes providing the vehicle in which at least some of the plurality of high-frequency power converters include bridge circuits with respective switches, and wherein the power distribution circuitry further includes power control circuitry, and the method further comprises the power control circuitry controlling the respective switches to thereby control power flow through the DC-to-DC converter assembly, and manage magnetic flux through the single transformer core. 16. The method of claim 15 , wherein controlling the respective switches includes the power control circuitry controlling the respective switches to synchronize the power flow through the DC-to-DC converter assembly. 17. The method of claim 15 , wherein controlling the respective switches includes the power control circuitry controlling the respective switches to control different amounts of power through the DC-to-DC converter assembly simultaneously. 18. The method of claim 15 , wherein the method further comprises the power control circuitry controlling the respective switches of one or more of the high-frequency power converters to compensate for a fault or failure at one of the high-frequency power converters, or a fault or failure at