Interactive Trajectory Adaptation through Force-guided Bayesian Optimization

Rozo, Leonel

doi:10.1109/iros40897.2019.8968571

Cited by 12 publications

(15 citation statements)

References 27 publications

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“…Figs. [14][15][16][17] show the angular responses of θ res s1 and the torque responses of τ res s1 , τ res s2 , and τ res s3 for a height of 5.6 cm. The blue lines represent the responses of the motion-copying system, whereas the orange lines show the responses of the proposed method.…”

Section: Resultsmentioning

confidence: 99%

Imitation Learning for Variable Speed Contact Motion for Operation up to Control Bandwidth

Sakaino

Fujimoto²,

Saigusa³

et al. 2022

IEEE Open J. Ind. Electron. Soc.

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The generation of robot motions in the real world is difficult by using conventional controllers alone and requires highly intelligent processing. In this regard, learning-based motion generations are currently being investigated. However, the main issue has been improvements of the adaptability to spatially varying environments, but a variation of the operating speed has not been investigated in detail. In contact-rich tasks, it is especially important to be able to adjust the operating speed because a nonlinear relationship occurs between the operating speed and force (e.g., inertial and frictional forces), and it affects the results of the tasks. Therefore, in this study, we propose a method for generating variable operating speeds while adapting to spatial perturbations in the environment. The proposed method can be adapted to nonlinearities by utilizing a small amount of motion data. We experimentally evaluated the proposed method by erasing a line using an eraser fixed to the tip of the robot as an example of a contact-rich task. Furthermore, the proposed method enables a robot to perform a task faster than a human operator and is capable of operating close to the control bandwidth.

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Section: Resultsmentioning

confidence: 99%

Imitation Learning for Variable Speed Contact Motion for Operation up to Control Bandwidth

Sakaino

Fujimoto²,

Saigusa³

et al. 2022

IEEE Open J. Ind. Electron. Soc.

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“…In addition, when adapting parametric robot policies, some of their parameters such as mean vectors or covariance matrices lie in Riemannian manifolds. This inherent geometry is often overlooked in robotic applications [33,40,41]. In this paper, we demonstrate that incorporating the correct geometric structure of X into the Gaussian process is an important potential avenue for improving performance of Bayesian optimization.…”

Section: Geometry-aware Bayesian Optimizationmentioning

confidence: 91%

Geometry-aware Bayesian Optimization in Robotics using Riemannian Matérn Kernels

Jaquier¹,

Borovitskiy²,

Smolensky³

et al. 2021

Preprint

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Bayesian optimization is a data-efficient technique which can be used for control parameter tuning, parametric policy adaptation, and structure design in robotics. Many of these problems require optimization of functions defined on non-Euclidean domains like spheres, rotation groups, or spaces of positive-definite matrices. To do so, one must place a Gaussian process prior, or equivalently define a kernel, on the space of interest. Effective kernels typically reflect the geometry of the spaces they are defined on, but designing them is generally nontrivial. Recent work on the Riemannian Matérn kernels, based on stochastic partial differential equations and spectral theory of the Laplace-Beltrami operator, offers promising avenues towards constructing such geometry-aware kernels. In this paper, we study techniques for implementing these kernels on manifolds of interest in robotics, demonstrate their performance on a set of artificial benchmark functions, and illustrate geometry-aware Bayesian optimization for a variety of robotic applications, covering orientation control, manipulability optimization, and motion planning, while showing its improved performance.

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“…In [18], a hidden Markov model (HMM) is combined with Bayesian optimization, which has capability to learn a task with few demonstrations. In [19], Bayesian optimization is combined with PbD to make the robot learn the intended trajectory of human based on the noisy interaction force.…”

Section: Introductionmentioning

confidence: 99%

“…(3) Different from the machine learning method that requires prior knowledge about the task model [17]- [19], the proposed method is suitable for tasks where the nominal plan of the robot does not conform with a presumed probabilistic model.…”

Section: Introductionmentioning

confidence: 99%

Path Learning in Human–Robot Collaboration Tasks Using Iterative Learning Methods

Xia

Huang

2022

IEEE Trans. Contr. Syst. Technol.

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Interactive Trajectory Adaptation through Force-guided Bayesian Optimization

Cited by 12 publications

References 27 publications

Imitation Learning for Variable Speed Contact Motion for Operation up to Control Bandwidth

Imitation Learning for Variable Speed Contact Motion for Operation up to Control Bandwidth

Geometry-aware Bayesian Optimization in Robotics using Riemannian Matérn Kernels

Path Learning in Human–Robot Collaboration Tasks Using Iterative Learning Methods

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