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The bottom portion of the mechanism can be modeled as a slider-crank which receives its power from the linear motion of the slider rather than the rotary motion of the crank. The angles and angular velocities of the joint can be derived as functions of slider position d and its derivative, the sliding velocity. Both of these are directly proportional to the motor output and the pitch of the screw.
The top portion of the mechanism can be modeled as a closed loop composed of one ground link (green), a grounded sliding joint, and two links. The angles and angular velocities of the joints can be derived as a function of the input angle, from the cyan link, which is solved for in the analysis of the bottom linkage.
TODO finish in gdocs
Shown below are plots of the angular positions and velocities of the two gripper finger links (color-coded to match the CAD figures) for the full range of input slider displacements where 0mm of input displacement corresponds to the gripper in its maximally closed grasp state and roughly 80mm of slider displacement corresponds to the gripper in its most open, widest stance landing-gear state.
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