3,378 research outputs found
Fast human motion prediction for human-robot collaboration with wearable interfaces
In this paper, we aim at improving human motion prediction during human-robot
collaboration in industrial facilities by exploiting contributions from both
physical and physiological signals. Improved human-machine collaboration could
prove useful in several areas, while it is crucial for interacting robots to
understand human movement as soon as possible to avoid accidents and injuries.
In this perspective, we propose a novel human-robot interface capable to
anticipate the user intention while performing reaching movements on a working
bench in order to plan the action of a collaborative robot. The proposed
interface can find many applications in the Industry 4.0 framework, where
autonomous and collaborative robots will be an essential part of innovative
facilities. A motion intention prediction and a motion direction prediction
levels have been developed to improve detection speed and accuracy. A Gaussian
Mixture Model (GMM) has been trained with IMU and EMG data following an
evidence accumulation approach to predict reaching direction. Novel dynamic
stopping criteria have been proposed to flexibly adjust the trade-off between
early anticipation and accuracy according to the application. The output of the
two predictors has been used as external inputs to a Finite State Machine (FSM)
to control the behaviour of a physical robot according to user's action or
inaction. Results show that our system outperforms previous methods, achieving
a real-time classification accuracy of after
from movement onset
Trajectory Deformations from Physical Human-Robot Interaction
Robots are finding new applications where physical interaction with a human
is necessary: manufacturing, healthcare, and social tasks. Accordingly, the
field of physical human-robot interaction (pHRI) has leveraged impedance
control approaches, which support compliant interactions between human and
robot. However, a limitation of traditional impedance control is that---despite
provisions for the human to modify the robot's current trajectory---the human
cannot affect the robot's future desired trajectory through pHRI. In this
paper, we present an algorithm for physically interactive trajectory
deformations which, when combined with impedance control, allows the human to
modulate both the actual and desired trajectories of the robot. Unlike related
works, our method explicitly deforms the future desired trajectory based on
forces applied during pHRI, but does not require constant human guidance. We
present our approach and verify that this method is compatible with traditional
impedance control. Next, we use constrained optimization to derive the
deformation shape. Finally, we describe an algorithm for real time
implementation, and perform simulations to test the arbitration parameters.
Experimental results demonstrate reduction in the human's effort and
improvement in the movement quality when compared to pHRI with impedance
control alone
Progress and Prospects of the Human-Robot Collaboration
International audienceRecent technological advances in hardware designof the robotic platforms enabled the implementationof various control modalities for improved interactions withhumans and unstructured environments. An important applicationarea for the integration of robots with such advancedinteraction capabilities is human-robot collaboration. Thisaspect represents high socio-economic impacts and maintainsthe sense of purpose of the involved people, as the robotsdo not completely replace the humans from the workprocess. The research community’s recent surge of interestin this area has been devoted to the implementation of variousmethodologies to achieve intuitive and seamless humanrobot-environment interactions by incorporating the collaborativepartners’ superior capabilities, e.g. human’s cognitiveand robot’s physical power generation capacity. In fact,the main purpose of this paper is to review the state-of-thearton intermediate human-robot interfaces (bi-directional),robot control modalities, system stability, benchmarking andrelevant use cases, and to extend views on the required futuredevelopments in the realm of human-robot collaboration
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