An Underactuated Prosthetic Hand Based on Postural Synergies
December 2011 to present
It is a particularly challenging task to build and attach an anthropomorphic prosthetic hand that can replicate delicate motions of the biological original. In order to achieve this goal, the prosthetic hand shall be versatile enough for various daily tasks and controllable through a bio-signal interface, such as EMG (electro-myography) or EEG (electro-encephalography). However limited bandwidth of these interfaces used to prevent fully actuated robotic hands from being applied as prostheses if each DoF (Degree of Freedom) requires individual control to perform dexterous grasping tasks, even though many designs were absolutely the state-of-the-art.
Recent advances in neurology showed that CNS (Central Nervous System) controls hand muscles in a coordinated manner. This coordination is referred as to a postural synergy. Each postural synergy corresponds to flexion/extension actuation statuses of several involved muscles. CNS combines postural synergies, adjusting each synergy’s weight (coefficient), to realize various hand motions. Combination of two primary postural synergies accounts for more than 80% of the variance of dozens of different grasping postures.
This project proposes a complete process of designing underactuated prosthetic hands to realize intended continuous hand motions. The specific paradigm is to rotate two rehabilitation training balls on palm using coordinated finger motions as shown in the figure. This exercise helps the elderly or patients after mild stroke to maintain or recover their hand motor function. Although this motion sequence might not seem practically meaningful for amputees, the motivation here is to demonstrate the capability and effectiveness of this proposed design process.
In order to realize the intended motion sequence of manipulating rehabilitation training balls on a prosthetic hand, a dummy hand was first constructed and manually posed for six different key poses. The dummy hand had identical enveloping dimensions and geometry as the one to be constructed with transmissions and actuations. The poses of the dummy hand were measured using an optical tracker and the postural synergies were extracted to guide the design of a complicated transmission system which maps two synergy inputs to 15 outputs to drive the prosthetic hand.
Then the prosthetic hand with transmission was designed, following the exact enveloping dimensions and geometry of the dummy hand, as shown in the figure. It was expected that the exact motion sequence on the dummy hand can be precisely repeated by the prosthetic hand.