Systems and methods for payload stabilization

What is claimed is: 1. A stabilizing device comprising: a handle assembly including one or more grips; a payload stabilization assembly configured to support a payload and permit the payload to rotate about at least one axis of rotation; and a constant force assembly operably connected to the handle assembly, configured to support the payload stabilization assembly, and including a parallelogram linkage including four pivots and a resilient member obliquely arranged within the parallelogram linkage, the constant force assembly being configured to provide a force that equipoises a gravity force of the payload stabilization assembly with the payload in a vertical. 2. The stabilizing device of claim 1 , wherein one attachment point of the resilient member is displaced in a horizontal direction by a negative offset distance from a vertical plane passing through longitudinal axes of two of the four pivots that are adjacent to the handle assembly, the negative offset indicating that the one attachment point is closer to the handle assembly than the vertical plane. 3. The stabilizing device of claim 2 , wherein the negative offset distance is formed by connecting the one attachment point of the resilient member to a point that locates at an opposite side of the vertical plane with respect to the resilient member. 4. The stabilizing device of claim 2 , wherein the negative offset distance is in a range from −0.6 mm to −0.2 mm. 5. The stabilizing device of claim 1 , wherein: the resilient member is positioned proximately along a diagonal of the parallelogram linkage; and each of four pivots is positioned at one of four corners of the parallelogram linkage. 6. The stabilizing device of claim 5 , wherein: the four pivots include a first pivot, a second pivot, a third pivot, and a fourth pivot; the first pivot and the second pivot are configured to be proximal to the handle assembly and to be vertically aligned with one another at an initial state, the second pivot being higher than the first pivot in the vertical direction; and the third pivot and the fourth pivot are configured to be proximal to the payload stabilization assembly and to be vertically aligned with one another at the initial state, the fourth pivot being higher than the third pivot in the vertical direction. 7. The stabilizing device of claim 5 , wherein the resilient member includes a tension spring having a first end and a second end, the first end being attached to a connecting rod connecting the first pivot and the third pivot at a first attachment point proximal to the third pivot, and the second end being attached to a connector between the second pivot and the first pivot in the vertical direction at a second attachment point. 8. The stabilizing device of claim 7 , wherein the connector is moveably connected with an adjustment knob configured to be adjusted to cause the connector to move up and down in the vertical direction, thereby changing a height of the second attachment point in the vertical direction relative to the first pivot. 9. The stabilizing device of claim 8 , wherein the connector includes an adjusting nut. 10. The stabilizing device of claim 7 , wherein the second attachment point is offset in the vertical direction by a distance from a horizontal plane passing through longitudinal axes of the first pivot and the third pivot. 11. The stabilizing device of claim 7 , wherein the first attachment point is offset in a horizontal direction by a distance from a vertical plane passing through longitudinal axes of the first pivot and the second pivot. 12. The stabilizing device of claim 7 , wherein a vertical distance between the second attachment point and a center of the first pivot is variable such that the constant force assembly provides different forces for different payloads having different gravity forces. 13. The stabilizing device of claim 7 , wherein the force provided by the parallelogram linkage is determined according to one or more parameters of the tension spring, structural parameters of the parallelogram linkage, and positions of the first and second attachment points. 14. The stabilizing device of claim 13 , wherein the one or more parameters of the tension spring include at least one of a mean coil diameter, a wire diameter, or a number of coils. 15. The stabilizing device of claim 1 , wherein the parallelogram linkage is configured to have a natural frequency that is low enough to reduce or eliminate low-frequency jitter in the vertical direction. 16. The stabilizing device of claim 1 , wherein the handle assembly is attached to the parallelogram linkage by a rotating hinge configured to adjust an orientation of the payload stabilization assembly relative to the handle assembly to switch between different modes, the modes including: that the handle assembly is perpendicular to the parallelogram linkage, and that the handle assembly is collinear to the parallelogram linkage. 17. The stabilizing device of claim 1 , wherein: the payload is configured to be detachably connected to the payload stabilization assembly; and/or the constant force assembly is configured to be detachably connected to the payload stabilization assembly using an interface of the constant force assembly. 18. The stabilizing device of claim 17 , wherein: the interface of the constant force assembly is a first interface; the constant force assembly is detachably connected to the handle assembly using a second interface of the constant force assembly; the handle assembly is configured to be disconnected from the constant force assembly and directly connected to the payload stabilization assembly to form a hand-held gimbal; and the handle assembly is configured to be disconnected from the constant force assembly and the payload stabilization assembly and directly attached to the payload to form a hand-held imaging device. 19. The stabilizing device of claim 1 , wherein the constant force assembly is configured to provide the force such that a net force of the payload stabilization assembly with the payload in the vertical direction is substantially zero. 20. A gimbal system comprising: a payload; and a stabilizing device including: a handle assembly including one or more grips; a payload stabilization assembly configured to support the payload and permit the payload to rotate about at least one axis of rotation; and a constant force assembly operably connected to the handle assembly, configured to support the payload stabilization assembly, and including a parallelogram linkage including four pivots and a resilient member obliquely arranged within the parallelogram linkage, the constant force assembly being configured to provide a force that equipoises a gravity force of the payload stabilization assembly with the payload in a vertical direction.