Motion control system

What is claimed is: 1. A suspension actuator comprising: a top mount; a bottom mount; an upper housing that extends from the top mount; a lower housing that extends from the bottom mount; an air spring configured to form a first load path between a first portion of a vehicle and a second portion of the vehicle, the air spring including a pressurized cavity having an upper chamber that is defined by the upper housing, and a lower chamber that is defined by the lower housing and a membrane that extends radially between the upper housing and the lower housing, wherein the pressurized cavity contains a pressurized gas that transfers force of the first load path; and a ball-screw actuator configured to form a second load path between the first portion of the vehicle and the second portion of the vehicle in parallel to the first load path, the ball-screw actuator comprising a motor coupled to the upper housing and having a stator and a rotor, wherein an air flow path is defined radially outward from the stator such that the upper chamber and the lower chamber of the pressurized cavity are in fluidic communication with each other through the air flow path. 2. The suspension actuator of claim 1 , wherein the motor of the ball-screw actuator is contained in the pressurized cavity. 3. The suspension actuator of claim 1 , wherein the air flow path is defined by a channel between the upper housing and the stator. 4. The suspension actuator of claim 1 , wherein the air flow path is defined by a gap between the upper housing and the stator. 5. The suspension actuator of claim 1 , wherein the air flow path is defined by an axial channel in the upper housing. 6. The suspension actuator of claim 1 , wherein the ball-screw actuator further comprises: a shaft; a ball nut to which the motor applies torque to transfer force of the second load path between the upper housing and the shaft; and a ball spline that applies torque to the shaft to prevent rotation thereof relative to the upper housing. 7. The suspension actuator of claim 6 , wherein the upper housing, the stator, and the ball spline are coupled to each other to form a stationary assembly, and the rotor and the ball nut are coupled to each other to form a rotating assembly that is rotatably supported and axially fixed to the stationary assembly with a thrust bearing. 8. The suspension actuator of claim 7 , wherein the thrust bearing is coupled to the ball nut and the upper housing. 9. The suspension actuator of claim 8 , wherein the upper housing transfers the force of the second load path. 10. The suspension actuator of claim 9 , wherein the stator is in contact with an inner surface of the upper housing. 11. The suspension actuator of claim 6 , wherein the upper housing surrounds the motor and the ball nut. 12. The suspension actuator of claim 1 , wherein the upper housing surrounds the motor and includes cooling passages for receiving a fluid for cooling the motor. 13. The suspension actuator of claim 1 , wherein an upper end of the upper housing is coupled to the top mount with an isolator. 14. The suspension actuator of claim 13 , wherein the isolator includes inner and outer rigid rings coupled to and separated by an intermediate compliant ring. 15. A suspension actuator comprising: an upper housing; a lower housing; an air spring disposed between the upper housing and the lower housing and configured to form a first load path between a sprung mass of a vehicle and an unsprung mass of the vehicle; and a ball-screw actuator configured to form a second load path between the sprung mass and the unsprung mass in parallel to the first load path, the ball-screw actuator comprising: a motor coupled to the upper housing and having a stator and a rotor, a shaft, a ball nut to which the motor applies torque to transfer force of the second load path between the upper housing and the shaft, and a ball spline that applies torque to the shaft to prevent rotation thereof relative to the upper housing, wherein the upper housing, the stator, and the ball spline are coupled to each other to form a stationary assembly, and the rotor and the ball nut are coupled to each other to form a rotating assembly that is rotatably supported and axially fixed to the stationary assembly with a thrust bearing. 16. The suspension actuator of claim 15 , wherein the thrust bearing is coupled to the ball nut and the upper housing. 17. The suspension actuator of claim 16 , wherein the rotating assembly is further rotatably supported by the upper housing with another bearing coupled to the upper housing and the rotor. 18. The suspension actuator of claim 17 , wherein the other bearing is spaced apart from and positioned axially above the thrust bearing. 19. The suspension actuator of claim 17 , wherein the stator is positioned axially between the thrust bearing and the other bearing. 20. A suspension actuator comprising: an upper housing; a lower housing; an air spring configured to form a first load path between a vehicle body of a vehicle and a wheel of the vehicle, the air spring including a pressurized cavity having an upper chamber that is defined by the upper housing, and a lower chamber that is defined by the lower housing and a membrane that extends radially between the upper housing and the lower housing, wherein the pressurized cavity contains a pressurized gas that transfers force of the first load path; and a ball-screw actuator configured to form a second load path between the vehicle body and the wheel in parallel to the first load path, the ball-screw actuator comprising a motor, wherein the upper housing surrounds the motor and includes cooling passages for receiving a fluid for cooling the motor. 21. The suspension actuator of claim 20 , wherein the motor comprises a stator and a rotor, with the stator in contact with an inner surface of the upper housing.