On-board redundant power system for unmanned aerial vehicles

What is claimed is: 1. An unmanned aerial vehicle (UAV) comprising: propellers to generate thrust to propel the UAV in air; propeller motors, each propeller motor to rotate at least one of the propellers; a power system comprising: a battery assembly to provide power to the propeller motors; a combustion engine configured to convert potential energy of a fuel stored on-board the UAV into kinetic energy, the combustion engine having: an electric starting motor to start the combustion engine; and a starter battery to provide power to the electric starting motor; a generator, coupled to the combustion engine, to convert the kinetic energy from the combustion engine into electrical energy; a navigation module to estimate a remaining flight time of the UAV to complete a journey; and a power system controller to selectively start the combustion engine using the starter battery and the electric starting motor of the combustion engine upon determining that: a charge level of the battery assembly is less than a threshold charge level; or the battery assembly is inoperable, wherein the power system controller is further configured to activate the combustion engine based at least in part on determining that the charge level of the battery assembly is insufficient to provide power for an entirety of the remaining flight time. 2. The UAV of claim 1 , wherein the power system further comprises a battery controller to transfer the electrical energy from the generator to the battery assembly to charge the battery, and wherein the power system controller is further configured to selectively utilize the combustion engine to: charge the battery assembly via the battery controller; or power at least one of the one or more propeller motors. 3. The UAV of claim 1 , wherein the combustion engine is connected to a propeller configured to propel the UAV in a horizontal direction. 4. An unmanned aerial vehicle (UAV) comprising: one or more propeller motors configured to rotate one or more propellers of the UAV; a navigation module configured to estimate a remaining flight time of the UAV to complete a journey; and a power system comprising: a battery to provide power to the one or more propeller motors; a combustion engine configured to convert potential energy of a fuel stored on-board the UAV into kinetic energy; a generator coupled to the combustion engine to convert the kinetic energy from the combustion engine into electrical energy; and a power system controller configured to selectively operate the combustion engine to provide the electrical energy from the generator to charge the battery or to power at least one of the one or more propeller motors, wherein the power system controller is further configured to operate the combustion engine based at least in part on determining that a charge level of the battery is insufficient to provide power for an entirety of the remaining flight time. 5. The UAV of claim 4 , wherein the combustion engine comprises: an electric starting motor to start the combustion engine; and a starter battery to provide power to the electric starting motor. 6. The UAV of claim 4 , wherein the power system controller is further configured to control a distribution of power provided from the battery and power provided from the combustion engine. 7. The UAV of claim 4 , wherein the power system further comprises a battery controller to transfer the electrical energy from the generator to the battery to charge the battery. 8. The UAV of claim 4 , wherein the power system further comprises a battery monitor to monitor the charge level of the battery, and wherein the power system controller is further configured to operate the combustion engine based at least in part on determining that the charge level of the battery is less than a threshold level. 9. The UAV of claim 4 , wherein the navigation module is further configured to determine that the UAV is to begin flying substantially horizontally relative to ground, wherein the power system controller is configured to utilize the kinetic energy from the combustion engine to power at least one of the propeller motors that provides forward thrust to the UAV based as least in part on determining that the UAV is to begin flying substantially horizontally relative to ground. 10. The UAV of claim 4 , further comprising an altimeter to determine an altitude of the UAV, wherein the power system controller is configured to power the at least one propeller motor with the electrical energy from the generator based at least in part on determining that the altitude of the UAV meets or exceeds a threshold altitude. 11. The UAV of claim 10 , wherein the power system controller is further configured to select an air-to-fuel ratio utilized by the combustion engine based at least in part on the altitude of the UAV. 12. The UAV of claim 4 , further comprising a location sensor to measure a latitude and a longitude of the UAV, wherein the power system controller is further configured to: compare the measured latitude and the longitude of the UAV to geo-fence information; and power the at least one propeller motor from the electrical energy provided by the generator based at least in part on comparing the measured latitude and the longitude of the UAV to the geo-fence information. 13. The UAV of claim 4 , wherein the power system further comprises: at least one additional combustion engine, resulting in the power system comprising a plurality of combustion engines; and a power system controller to selectively utilize individual ones of the plurality of combustion engines. 14. The UAV of claim 13 , wherein the power system controller is further configured to utilize a predetermined number of the plurality of combustion engines based at least in part on: (i) a weight of a payload carried by the UAV, (ii) a total weight of the UAV and the payload, or (iii) a charge rate that is to be used to charge the battery. 15. A method to operate a power system of an unmanned aerial vehicle (UAV), the method comprising: providing power to one or more propeller motors of the UAV from a battery on-board the UAV; determining, by a power system controller of the UAV, that a trigger event has occurred; and based at least in part on the determining that the trigger event has occurred, operating a combustion engine on-board the UAV to charge the battery or power at least one propeller motor of the UAV, wherein the trigger event includes at least determining that a charge level of the battery is insufficient for providing power for an entirety of an estimated remaining flight time of the UAV. 16. The method of claim 15 , wherein the combustion engine is utilized to power the at least one propeller motor based at least in part on the determining the trigger event, and wherein the trigger event further comprises at least one of: determining that the battery is inoperable; determining that an altitude of the UAV is above a threshold altitude; determining that a latitude and a longitude of the UAV is outside of a geo-fence; or determining that a horizontal component of thrust is desired. 17. The method of claim 15 , wherein the combustion engine is utilized to charge the battery based at least in part on the determining the trigger event, and wherein the trigger event further comprises determining that the charge level of the battery has dropped below a threshold charge level. 18. The method of claim 15 , further comprising: selectively engaging a generator with the combustion engine to provide electrica