Abstract
Eight human test subjects attempted to track a desired position trajectory with an instrumented manipulandum (MN). The test subjects used the MN with three different levels of stiffness. A transfer function was developed to represent the human application of a precision grip from the data when the test subjects initially displaced the MN so as to learn the position mapping from the MN onto the display. Another transfer function was formed from the data of the remainder of the experiments, after significant displacement of the MN occurred. Both of these transfer functions accurately modelled the system dynamics for a portion of the experiments, but neither was accurate for the duration of the experiments because the human grip dynamics changed while learning the position mapping. Thus, an adaptive system model was developed to describe the learning process of the human test subjects as they displaced the MN in order to gain knowledge of the position mapping. The adaptive system model was subsequently validated following comparison with the human test subject data. An examination of the average absolute error between the position predicted by the adaptive model and the actual experimental data yielded an overall average error of 0.34mm for all three levels of stiffness.
Highlights
Dexterous manipulation is a challenging task for autonomous robots [1]
The stiffness of the MN did not have a significant impact on the OS or the tP in any of the experiments (p > 0.05). What these results indicate is that the OS and tP data of the human test subjects for the three inputs is independent of stiffness
The dynamics of the test subjects showed no significant difference for the subsequent steps
Summary
Like the Shadow Hand, the Gifu Hand and the Anatomically Correct Testbed Hand, appear anthropomorphic and have similar functionality to the human hand [2,3,4,5] These manipulators lack the intellect that humans possess for learning from and adapting to variable parameters in an unstructured environment. A better understanding of people’s learning processes during different manipulation tasks could be beneficial in imparting higher levels of autonomy to artificial hands. This is important for autonomous artificial hands and for teleoperated manipulators, because there will always be some level of position mapping www.intechopen.com
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