Efficient stationkeeping design for mixed fuel systems

1 . An apparatus comprising: a satellite configured to orbit around the Earth, the satellite comprising: a satellite bus having a nadir side that faces the Earth and a zenith side opposite the nadir side; a north electric thruster installed toward a north region of the zenith side and oriented downward to produce thrust through a center of mass of the satellite; a south electric thruster installed toward a south region of the zenith side and oriented upward to produce thrust through the center of mass of the satellite; and an orbit controller that controls stationkeeping maneuvers for the satellite; the orbit controller is configured to select a duration of a burn of the north electric thruster proximate to an ascending node that differs from a duration of a burn of the south electric thruster proximate to a descending node; the orbit controller is configured to select an offset of the burn of the north electric thruster in relation to the ascending node that differs from an offset of the burn of the south electric thruster in relation to the descending node. 2 . The apparatus of claim 1 wherein: the satellite comprises: an east chemical thruster installed on an east side of the satellite bus to produce thrust through the center of mass of the satellite; and a west chemical thruster installed on a west side of the satellite bus to produce thrust through the center of mass of the satellite. 3 . The apparatus of claim 2 wherein: the orbit controller is configured to control a burn of one of the west chemical thruster or the east chemical thruster proximate to the ascending node. 4 . The apparatus of claim 3 wherein: the orbit controller is configured to control a burn of the other one of the west chemical thruster or the east chemical thruster proximate to the descending node. 5 . The apparatus of claim 2 wherein: the difference in the burn durations for the electric thrusters and the difference in the offsets of the burns of the electric thrusters produce a net radial velocity change of the satellite, wherein the net radial velocity change produces a delta-eccentricity component for the orbit of the satellite due to the burns of the electric thrusters; the orbit controller is configured to control a burn of one of the east chemical thruster or the west chemical thruster at a first location along the orbit of the satellite which produces a first tangential velocity change of the satellite, wherein the first tangential velocity change produces a delta-eccentricity component due to the burn of the one chemical thruster; and the orbit controller is configured to select the first location of the burn of the one chemical thruster so that the delta-eccentricity component due to the burn of the one chemical thruster adds to the delta-eccentricity component due to the burns of the electric thrusters. 6 . The apparatus of claim 5 wherein: the orbit controller is configured to control a burn of the other one of the east chemical thruster or the west chemical thruster at a second location along the orbit of the satellite which produces a second tangential velocity change of the satellite, wherein the second tangential velocity change produces a delta-eccentricity component due to the burn of the other chemical thruster; and the orbit controller is configured to select the second location of the burn of the other chemical thruster so that the delta-eccentricity component due to the burn of the other chemical thruster adds to the delta-eccentricity component due to the burns of the electric thrusters and the delta-eccentricity component due to the burn of the one chemical thruster. 7 . The apparatus of claim 1 wherein: the orbit controller is configured to determine an inclination of an orbital plane of the satellite, and to determine a total burn time for the burn of the north electric thruster and the burn of the south electric thruster based on the inclination. 8 . The apparatus of claim 1 wherein: the orbit controller is configured to determine a position of the Sun in a geocentric coordinate system based on time of year, and to select the duration and offset of the burn of the north electric thruster and the duration and offset of the burn of the south electric thruster to produce a target eccentricity change that points behind the position of the Sun by 90°±5°. 9 . The apparatus of claim 1 wherein: the north electric thruster is oriented at a first angle to a north-south axis of the satellite, wherein the first angle is 35°±25°; and the south electric thruster is oriented at a second angle to the north-south axis of the satellite, wherein the second angle is 35°±25°. 10 . The apparatus of claim 1 wherein: the north electric thruster and the south electric thruster use xenon as a propellant. 11 . A method for controlling stationkeeping maneuvers for a satellite, wherein the satellite comprises a satellite bus having a nadir side that faces the Earth and a zenith side opposite the nadir side, a north electric thruster installed toward a north region of the zenith side and oriented downward to produce thrust through a center of mass of the satellite, and a south electric thruster installed toward a south region of the zenith side and oriented upward to produce thrust through the center of mass of the satellite, the method comprising: selecting a duration of a burn of the north electric thruster proximate to an ascending node that differs from a duration of a burn of the south electric thruster proximate to a descending node; and selecting an offset of the burn of the north electric thruster in relation to the ascending node that differs from an offset of the burn of the south electric thruster in relation to the descending node. 12 . The method of claim 11 wherein: the satellite further comprises an east chemical thruster installed on an east side of the satellite bus to produce thrust through the center of mass of the satellite, and a west chemical thruster installed on a west side of the satellite bus to produce thrust through the center of mass of the satellite; the method further comprises: controlling a burn of one of the west chemical thruster or the east chemical thruster proximate to the ascending node. 13 . The method of claim 12 further comprising: controlling a burn of the other one of the west chemical thruster or the east chemical thruster proximate to the descending node. 14 . The method of claim 11 wherein: the satellite further comprises an east chemical thruster installed on an east side of the satellite bus to produce thrust through the center of mass of the satellite, and a west chemical thruster installed on a west side of the satellite bus to produce thrust through the center of mass of the satellite; and the difference in the burn durations for the electric thrusters and the difference in the offsets of the burns of the electric thrusters produce a net radial velocity change of the satellite, wherein the net radial velocity change produces a delta-eccentricity component for the orbit of the satellite due to the burns of the electric thrusters; the method further comprises: controlling a burn of one of the east chemical thruster or the west chemical thruster at a first location along the orbit of the satellite which produces a first tangential velocity change of the satellite, wherein the first tangential velocity change produces a delta-eccentricity component due to the burn of the one chemical thruster; wherein the first location of the burn of the one chemical thruster is selected so that the delta-eccentricity component due to the burn of the one chemic