Inverted harmonic gear actuator

What is claimed is: 1. An inverted harmonic gear actuator, comprising: a motor stator; a motor rotor radially disposed within the motor stator; a wave generator radially disposed within the motor rotor, the wave generator comprising a radially inner surface with a cammed shape comprising a multi-lobed shape; an actuator output shaft radially disposed within the wave generator; a flex spline radially interposable between the radially inner surface of the wave generator and the actuator output shaft, the flex spline deformable to conform to the radially inner surface of the wave generator and drive the rotation of the actuator output shaft slower than rotation of the motor rotor, wherein a radially inner surface of the flex spline comprises a first plurality of gear teeth configured to mesh with a second plurality of gear teeth of a gear interface of the actuator output shaft with at least three gear meshing regions; a plurality of roller bearings radially disposed between the radially inner surface of the wave generator and a radially outer surface of the flex spline; a first motor bearing axially positioned between the roller bearings and a splined interface of the actuator output shaft, the first motor bearing supporting rotation of the actuator output shaft; a second motor bearing radially disposed between the radially inner surface of the wave generator and a radially outer surface of the actuator output shaft, wherein the second motor bearing is axially offset from the first motor bearing and the roller bearings with respect to an axis of rotation of the actuator output shaft; and a third motor bearing radially disposed between a radially outer surface of the wave generator and a housing of the inverted harmonic gear actuator. 2. The inverted harmonic gear actuator according to claim 1 , wherein the radially inner surface of the flex spline comprises a greater number of gear teeth than a number of gear teeth on the gear interface of the actuator output shaft. 3. The inverted harmonic gear actuator according to claim 2 , wherein the actuator output shaft extends axially outward from the motor rotor and comprises the splined interface to drive rotation of a load. 4. The inverted harmonic gear actuator according to claim 2 , wherein the motor rotor and the gear interface of the actuator output shaft are substantially circular. 5. The inverted harmonic gear actuator according to claim 1 , further comprising: a roller bearing inner race disposed between the flex spline and the roller bearings; and a roller bearing outer race disposed between the wave generator and the roller bearings. 6. The inverted harmonic gear actuator according to claim 1 , further comprising: a plurality of windings coupled to the motor stator; and a plurality of magnets coupled to the motor rotor. 7. The inverted harmonic gear actuator according to claim 1 , wherein the wave generator and the motor rotor are integrated in a single piece. 8. A method of assembling an inverted harmonic gear actuator, the method comprising: coupling a wave generator radially within a motor rotor, the wave generator comprising a radially inner surface with a cammed shape comprising a multi-lobed shape; interposing a flex spline radially between the radially inner surface of the wave generator and an actuator output shaft, the flex spline deformable to conform to the radially inner surface of the wave generator and drive rotation of the actuator output shaft slower than rotation of the motor rotor, wherein a radially inner surface of the flex spline comprises a first plurality of gear teeth configured to mesh with a second plurality of gear teeth of a gear interface of the actuator output shaft with at least three gear meshing regions; positioning a plurality of roller bearings between the radially inner surface of the wave generator and a radially outer surface of the flex spline; positioning a first motor bearing axially between the roller bearings and a splined interface of the actuator output shaft, the first motor bearing supporting rotation of the actuator output shaft; positioning a second motor bearing radially between the radially inner surface of the wave generator and a radially outer surface of the actuator output shaft, wherein the second motor bearing is axially offset from the first motor bearing and the roller bearings with respect to an axis of rotation of the actuator output shaft; positioning a third motor bearing radially between a radially outer surface of the wave generator and a housing of the inverted harmonic gear actuator; and positioning the motor rotor radially within a motor stator. 9. The method according to claim 8 , wherein the radially inner surface of the flex spline comprises a greater number of gear teeth than a number of gear teeth on the gear interface of the actuator output shaft. 10. The method according to claim 9 , wherein the actuator output shaft extends axially outward from the motor rotor and comprises the splined interface to drive rotation of a load. 11. The method according to claim 9 , wherein the motor rotor and the gear interface of the actuator output shaft are substantially circular. 12. The method according to claim 8 , further comprising: positioning a roller bearing inner race between the flex spline and the roller bearings; and positioning a roller bearing outer race between the wave generator and the roller bearings. 13. The method according to claim 8 , further comprising: coupling a plurality of windings to the motor stator; and coupling a plurality of magnets to the motor rotor. 14. The method according to claim 8 , wherein coupling the wave generator radially within the motor rotor comprises integrally forming the wave generator and the motor rotor as a single piece.