Gimbal having parallel stability mechanism

What is claimed is: 1. A gimbal mechanism for providing movement of a payload about at least two degrees of freedom, the gimbal mechanism comprising: a first actuator providing rotation about a first actuator axis; a second actuator providing rotation about a second actuator axis different from the first actuator axis; a first coupler operatively coupling the first actuator and the payload, the first coupler being configured to affect rotation of the payload about the first actuator axis, and the first coupler including a first cantilever member coupled to the first actuator and a first joint member coupled to the payload; and a second coupler operatively coupling the second actuator and the payload, the second coupler being configured to affect rotation of the payload about the second actuator axis, the second coupler including a second cantilever member coupled to the second actuator and a second joint member coupled to the payload, the second cantilever member including a first cantilever component and a second cantilever component movably coupled to each other via a hinge, and the hinge being configured to provide free rotation of the second cantilever component about a hinge axis, wherein both the first coupler and the second coupler are directly coupled to the payload. 2. The gimbal mechanism of claim 1 , wherein the first coupler is coupled to the payload at a first location, and the second coupler is coupled to the payload at a second location different from the first location. 3. The gimbal mechanism of claim 1 , wherein the first actuator and the second actuator are configured to be actuated independently. 4. The gimbal mechanism of claim 1 , wherein the gimbal mechanism is configured to provide rotation of less than or equal to 90 degrees of the payload about the first actuator axis. 5. The gimbal mechanism of claim 1 , wherein the gimbal mechanism is configured to provide rotation of less than or equal to 90 degrees of the payload about the second actuator axis. 6. The gimbal mechanism of claim 1 , wherein the first cantilever member is configured to translate a torque generated by the first actuator to the payload via the first joint member, and the second cantilever member is configured to translate a torque generated by the second actuator to the payload via the second joint member. 7. The gimbal mechanism of claim 1 , wherein: the first joint member includes a first joint member axis configured to provide free rotation of the payload about the second actuator axis, and the second joint member includes a second joint member axis configured to provide free rotation of the payload about the first actuator axis. 8. The gimbal mechanism of claim 7 , wherein the first joint member axis and the second joint member axis are configured to remain orthogonal to each other during actuation of the first actuator or the second actuator, such that the payload is free to rotate about both the first actuator axis and the second actuator axis. 9. The gimbal mechanism of claim 7 , wherein: during actuation of the first actuator, the second joint member axis is configured to be co-axial with the first actuator axis, thereby allowing free rotation of the payload about the first actuator axis, and during actuation of the second actuator, the first joint member axis is configured to be co-axial with the second actuator axis or with an axis comprising a component of the second actuator axis, thereby allowing free rotation of the payload about the second actuator axis. 10. The gimbal mechanism of claim 1 , further comprising: a support structure, wherein the first actuator and the second actuator are coupled to the support structure. 11. The gimbal mechanism of claim 10 , wherein the support structure has a fixed configuration. 12. The gimbal mechanism of claim 10 , wherein the first actuator is coupled to the support structure at a first location, and the second actuator is coupled to the support structure at a second location different from the first location. 13. The gimbal mechanism of claim 12 , wherein the first location is disposed on a first plane, and the second location is disposed on a second plane orthogonal to the first plane. 14. The gimbal mechanism of claim 1 , wherein the first actuator axis and the second actuator axis are positioned at a non-zero angle relative to each other. 15. The gimbal mechanism of claim 1 , wherein the payload is a camera having an adjustable optical axis orthogonal to both the first actuator axis and the second actuator axis. 16. The gimbal mechanism of claim 1 , wherein the payload is a camera having an adjustable optical axis parallel to the first actuator axis. 17. The gimbal mechanism of claim 1 , wherein the payload is a camera having an adjustable optical axis parallel to the second actuator axis. 18. The gimbal mechanism of claim 1 , further comprising: a third actuator providing rotation about a third actuator axis different from the first actuator axis and the second actuator axis. 19. The gimbal mechanism of claim 1 , wherein the gimbal mechanism is coupled to an unmanned aerial vehicle. 20. The gimbal mechanism of claim 1 , wherein the gimbal mechanism is coupled to an unmanned aerial vehicle via a support structure supporting the first actuator, the second actuator, the first coupler, the second coupler, and the payload.