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Spacecraft transfer orbit operations include separating a spacecraft from a launch vehicle, while in a launch vehicle transfer orbit. The spacecraft includes a propulsion subsystem and a spacecraft controller that controls the spacecraft in a three-axis stabilized mode. With the spacecraft continuou

Spacecraft transfer orbit operations include separating a spacecraft from a launch vehicle, while in a launch vehicle transfer orbit. The spacecraft includes a propulsion subsystem and a spacecraft controller that controls the spacecraft in a three-axis stabilized mode. With the spacecraft continuously in the three-axis stabilized mode, one or more orbit raising maneuvers are performed by firing either or both of a chemical thruster and an electric thruster firing. Any two consecutive orbit raising maneuvers are separated by a respective intervening coast period. While in the three-axis stabilized mode, the spacecraft does not rotate about any axis at a rate greater than 0.1 degree/sec and dumping of momentum stored in a reaction wheel system is avoided.

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1. A method for performing spacecraft transfer orbit operations, the method comprising: separating a spacecraft from a launch vehicle, while in a launch vehicle transfer orbit, the spacecraft comprising a propulsion subsystem and a spacecraft controller;controlling the spacecraft in a three-axis sta

1. A method for performing spacecraft transfer orbit operations, the method comprising: separating a spacecraft from a launch vehicle, while in a launch vehicle transfer orbit, the spacecraft comprising a propulsion subsystem and a spacecraft controller;controlling the spacecraft in a three-axis stabilized mode; andperforming, with the spacecraft continuously in the three-axis stabilized mode, one or more orbit raising maneuvers, each orbit raising maneuver comprising either or both of a chemical thruster firing and an electric thruster firing, any two consecutive orbit raising maneuvers being separated by a respective intervening coast period, wherein, while in the three-axis stabilized mode, the spacecraft does not rotate about any axis at a rate greater than 0.1 degree/sec and dumping of momentum stored in a momentum storage system during each respective intervening coast period is avoided. 2. The method of claim 1, further comprising deploying, prior to performing the one or more orbit raising maneuvers, a solar array. 3. The method of claim 1, wherein the momentum storage system comprises one or more reaction wheels and control authority for maintaining spacecraft orientation is provided by one or both of the reaction wheels and thrusters. 4. The method of claim 3, wherein control authority for maintaining spacecraft orientation is provided only by the reaction wheels. 5. The method of claim 1, wherein during the orbit raising maneuvers, the spacecraft is in a maneuver orientation wherein a thrust vector of either or both of the chemical thruster and the electric thruster is aligned along a steering profile. 6. The method of claim 5, wherein during at least one of the intervening coast periods, the spacecraft is in a sun-safe orientation. 7. The method of claim 6, wherein reorientation from the sun-safe orientation to the maneuver orientation is performed by a slow slew of the spacecraft, using reaction wheels. 8. The method of claim 7, wherein the reorientation is performed without use of propellant. 9. The method of claim 1, wherein, at least one orbit raising maneuver comprises a chemical thruster firing and not an electric thruster firing. 10. A spacecraft comprising a propulsion subsystem and a spacecraft controller, the spacecraft controller configured to: control the spacecraft in a three-axis stabilized mode, wherein, while in the three-axis stabilized mode, the spacecraft does not rotate about any axis at a rate greater than 0.1 degree/sec and dumping of momentum stored in a momentum storage system during each respective intervening coast period is avoided; andcause the propulsion subsystem to perform, while the spacecraft is continuously in the three-axis stabilized mode, one or more orbit raising maneuvers, each orbit raising maneuver comprising either or both of a chemical thruster firing and an electric thruster firing, any two consecutive orbit raising maneuvers being separated by a respective intervening coast period. 11. The spacecraft of claim 10, further comprising a solar array, the spacecraft controller being configured to deploy the solar array, prior to causing the propulsion system to perform the one or more orbit raising maneuvers. 12. The spacecraft of claim 10, wherein the momentum storage system comprises one or more reaction wheels and control authority for maintaining satellite orientation is provided by one or both of the reaction wheels and thrusters. 13. The spacecraft of claim 12, wherein control authority for maintaining satellite orientation is provided only by the reaction wheels. 14. The spacecraft of claim 10, wherein during orbit raising maneuvers, the spacecraft is in a maneuver orientation wherein a thrust vector of either or both of the chemical thruster and the electric thruster is aligned along a steering profile. 15. The spacecraft of claim 14, wherein during at least one of the intervening coast periods, the spacecraft is in a sun-safe orientation. 16. The spacecraft of claim 15, wherein reorientation from the sun-safe orientation to the maneuver orientation is performed by a slow slew of the spacecraft, using reaction wheels. 17. The spacecraft of claim 16, wherein the reorientation is performed without use of propellant. 18. The spacecraft of claim 10, wherein, at least one orbit raising maneuver comprises a chemical thruster firing and not an electric thruster firing. 19. The spacecraft of claim 10, wherein, at least one orbit raising maneuver comprises an electric thruster firing and not a chemical thruster firing.