Abstract
The purpose of this study was to find a parsimonious representation of hand kinematics data that could facilitate prosthetic hand control. Principal Component Analysis (PCA) and a non-linear Autoencoder Network (nAEN) were compared in their effectiveness at capturing the essential characteristics of a wide spectrum of hand gestures and actions. Performance of the two methods was compared on (a) the ability to accurately reconstruct hand kinematic data from a latent manifold of reduced dimension, (b) variance distribution across latent dimensions, and (c) the separability of hand movements in compressed and reconstructed representations derived using a linear classifier. The nAEN exhibited higher performance than PCA in its ability to more accurately reconstruct hand kinematic data from a latent manifold of reduced dimension. Whereas, for two dimensions in the latent manifold, PCA was able to account for 78% of input data variance, nAEN accounted for 94%. In addition, the nAEN latent manifold was spanned by coordinates with more uniform share of signal variance compared to PCA. Lastly, the nAEN was able to produce a manifold of more separable movements than PCA, as different tasks, when reconstructed, were more distinguishable by a linear classifier, SoftMax regression. It is concluded that non-linear dimensionality reduction may offer a more effective platform than linear methods to control prosthetic hands.
Highlights
The complexity of the human hand makes it the subject of intensive research in prosthetics and robotics control
Instead of allowing the independent control of each degree of freedom, currently available market options include a variety of prosthetic hands with a limited number of preset gestures associated with the most common grasp patterns to be performed in activities of daily living (ADLs)
When comparing non-linear Autoencoder Network (nAEN) and Principal Component Analysis (PCA), the difference in the performance between the two methods decreased as the number of dimensions in the latent manifold increased (Figure 5)
Summary
The complexity of the human hand makes it the subject of intensive research in prosthetics and robotics control. Controlling several degrees of freedom (DOFs)—there are 27 in each hand—can be a difficult task when both precision and speed are required as in dexterous prosthetic hand control. Since their first development in the 1940s, myoelectric prostheses, operated by electromyographic (EMG) signals, have undergone a series of design and control changes (Zuo and Olson, 2014). Instead of allowing the independent control of each degree of freedom, currently available market options include a variety of prosthetic hands with a limited number of preset gestures associated with the most common grasp patterns to be performed in activities of daily living (ADLs). The Michelangelo Hand (Ottobock, Duderstadt, Germany) includes seven grip patterns whereas its successor, the Bebionic Hand, from the same company includes 14 grip patterns
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