2,212 research outputs found
Online Discrimination of Nonlinear Dynamics with Switching Differential Equations
How to recognise whether an observed person walks or runs? We consider a
dynamic environment where observations (e.g. the posture of a person) are
caused by different dynamic processes (walking or running) which are active one
at a time and which may transition from one to another at any time. For this
setup, switching dynamic models have been suggested previously, mostly, for
linear and nonlinear dynamics in discrete time. Motivated by basic principles
of computations in the brain (dynamic, internal models) we suggest a model for
switching nonlinear differential equations. The switching process in the model
is implemented by a Hopfield network and we use parametric dynamic movement
primitives to represent arbitrary rhythmic motions. The model generates
observed dynamics by linearly interpolating the primitives weighted by the
switching variables and it is constructed such that standard filtering
algorithms can be applied. In two experiments with synthetic planar motion and
a human motion capture data set we show that inference with the unscented
Kalman filter can successfully discriminate several dynamic processes online
Analysis and Transfer of Human Movement Manipulability in Industry-like Activities
Humans exhibit outstanding learning, planning and adaptation capabilities
while performing different types of industrial tasks. Given some knowledge
about the task requirements, humans are able to plan their limbs motion in
anticipation of the execution of specific skills. For example, when an operator
needs to drill a hole on a surface, the posture of her limbs varies to
guarantee a stable configuration that is compatible with the drilling task
specifications, e.g. exerting a force orthogonal to the surface. Therefore, we
are interested in analyzing the human arms motion patterns in industrial
activities. To do so, we build our analysis on the so-called manipulability
ellipsoid, which captures a posture-dependent ability to perform motion and
exert forces along different task directions. Through thorough analysis of the
human movement manipulability, we found that the ellipsoid shape is task
dependent and often provides more information about the human motion than
classical manipulability indices. Moreover, we show how manipulability patterns
can be transferred to robots by learning a probabilistic model and employing a
manipulability tracking controller that acts on the task planning and execution
according to predefined control hierarchies.Comment: Accepted for publication in IROS'20. Website:
https://sites.google.com/view/manipulability/home . Video:
https://youtu.be/q0GZwvwW9A
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