Abstract
Designed to safely share the same workspace as humans and assist them in a variety of tasks, the new collaborative robots are targeting manufacturing and service applications that once were considered unattainable. The large diversity of tasks to carry out, the unstructured environments and the close interaction with humans call for collaborative robots to seamlessly adapt their behaviors so as to cooperate with the users successfully under different and possibly new situations (characterized, for example, by positions of objects/landmarks in the environment, or by the user pose). This paper investigates how controllers capable of reactive and proactive behaviors in collaborative tasks can be learned from demonstrations. The proposed approach exploits the temporal coherence and dynamic characteristics of the task observed during the training phase to build a probabilistic model that enables the robot to both react to the user actions and lead the task when needed. The method is an extension of the Hidden Semi-Markov Model where the duration probability distribution is adapted according to the interaction with the user. This Adaptive Duration Hidden Semi-Markov Model (ADHSMM) is used to retrieve a sequence of states governing a trajectory optimization that provides the reference and gain matrices to the robot controller. A proof-of-concept evaluation is first carried out in a pouring task. The proposed framework is then tested in a collaborative task using a 7 DOF backdrivable manipulator.
Highlights
The first generations of robots were mostly designed to handle heavy parts, do dangerous tasks, or execute operations at fast pace in a stand-alone manner
We propose to learn a model of the collaborative task with a modified version of the hidden semi-Markov model (Yu, 2010) where the duration probability distribution is adapted online according to the interaction, which permits to modify the temporal dynamics of the task as a function of the user actions
Similar to the previous experiment, this was achieved by taking advantage of the probabilistic modeling of temporal variability employed by adaptive duration hidden semi-Markov model (ADHSMM), through state transition and state duration probabilities
Summary
The first generations of robots were mostly designed to handle heavy parts, do dangerous tasks, or execute operations at fast pace in a stand-alone manner. Reactive behaviors refer to actions that are conditioned on the interaction with the user, while proactive behaviors involve taking the lead of the task These two types of behaviors allow the collaborative robot to assist users in a larger variety of tasks, in which the robot adapts its behavior according to the user actions and takes advantage of the taught knowledge in a proactive manner. To achieve this goal, we propose to learn a model of the collaborative task with a modified version of the hidden semi-Markov model (Yu, 2010) where the duration probability distribution is adapted online according to the interaction, which permits to modify the temporal dynamics of the task as a function of the user actions
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