Combining Model-Based and Data-Based Approaches for Online Predictions of Human Trajectories

Accurately predicting human movement trajectories is of critical interest in multiple fields, including human-exoskeleton interaction. In general, such predictions can be obtained from model-based approaches (e.g., optimal control theory) or from data-driven approaches (e.g., learning from human dem...

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Bibliographic Details
Published in2024 10th IEEE RAS/EMBS International Conference for Biomedical Robotics and Biomechatronics (BioRob) pp. 1764 - 1771
Main Authors Orhan, Aymeric, Verdel, Dorian, Bruneau, Olivier, Geffard, Franck, Berret, Bastien
Format Conference Proceeding
LanguageEnglish
Published IEEE 01.09.2024
Subjects
Computational modeling
Cost function
Motors
Optimal control
Predictive models
Real-time systems
Robots
Stochastic processes
Training data
Trajectory
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Summary:Accurately predicting human movement trajectories is of critical interest in multiple fields, including human-exoskeleton interaction. In general, such predictions can be obtained from model-based approaches (e.g., optimal control theory) or from data-driven approaches (e.g., learning from human demonstrations). Data-driven methods generally require numerous demonstrations but avoid the computational burden of model-based methods. In this paper, we introduce a hybrid method mixing the strengths of these two approaches to enable the prediction of human trajectories in a receding-horizon fashion when the number of actual demonstrations is very limited. First, we propose to use the stochastic optimal feedforward-feedback control framework to generate a large set of humanlike trajectories, including their variability. Second, we used the probabilistic movement primitives (ProMPs) frame-work to learn the distribution of these synthetic trajectories and make online predictions about the upcoming human trajectories from the observation of past movement data. Here, we evaluated our hybrid method on an existing data set composed of arm reaching movements in a parasagittal plane. Overall, our method proves to be advantageous when generalization is needed and demonstrations are lacking, such as in novel targets scenarios. The introduced method shows promise to efficiently predict realistic human trajectories on a given time horizon, even when limited or no human demonstration is available for the task at hand.
ISSN:2155-1782
DOI:10.1109/BioRob60516.2024.10719877