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Your search keyword '"Ramon, Juan Antonio Corrales"' showing total 8 results
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8 results on '"Ramon, Juan Antonio Corrales"'

1. Robotic Control of the Deformation of Soft Linear Objects Using Deep Reinforcement Learning

Author

Zakaria, Mélodie Hani Daniel, Aranda, Miguel, Lequièvre, Laurent, Lengagne, Sébastien, Ramón, Juan Antonio Corrales, and Mezouar, Youcef

Subjects
Computer Science - Robotics
Abstract

This paper proposes a new control framework for manipulating soft objects. A Deep Reinforcement Learning (DRL) approach is used to make the shape of a deformable object reach a set of desired points by controlling a robotic arm which manipulates it. Our framework is more easily generalizable than existing ones: it can work directly with different initial and desired final shapes without need for relearning. We achieve this by using learning parallelization, i.e., executing multiple agents in parallel on various environment instances. We focus our study on deformable linear objects. These objects are interesting in industrial and agricultural domains, yet their manipulation with robots, especially in 3D workspaces, remains challenging. We simulate the entire environment, i.e., the soft object and the robot, for the training and the testing using PyBullet and OpenAI Gym. We use a combination of state-of-the-art DRL techniques, the main ingredient being a training approach for the learning agent (i.e., the robot) based on Deep Deterministic Policy Gradient (DDPG). Our simulation results support the usefulness and enhanced generality of the proposed approach., Comment: 7 pages, 5 figures, 1 table, Accepted for IEEE CASE 2022

Published
2023

2. Multi Actor-Critic DDPG for Robot Action Space Decomposition: A Framework to Control Large 3D Deformation of Soft Linear Objects

Author

Daniel, Mélodie, Magassouba, Aly, Aranda, Miguel, Lequièvre, Laurent, Ramon, Juan Antonio Corrales, Rodriguez, Roberto Iglesias, and Mezouar, Youcef

Subjects
Computer Science - Robotics
Abstract

Robotic manipulation of deformable linear objects (DLOs) has great potential for applications in diverse fields such as agriculture or industry. However, a major challenge lies in acquiring accurate deformation models that describe the relationship between robot motion and DLO deformations. Such models are difficult to calculate analytically and vary among DLOs. Consequently, manipulating DLOs poses significant challenges, particularly in achieving large deformations that require highly accurate global models. To address these challenges, this paper presents MultiAC6: a new multi Actor-Critic framework for robot action space decomposition to control large 3D deformations of DLOs. In our approach, two deep reinforcement learning (DRL) agents orient and position a robot gripper to deform a DLO into the desired shape. Unlike previous DRL-based studies, MultiAC6 is able to solve the sim-to-real gap, achieving large 3D deformations up to 40 cm in real-world settings. Experimental results also show that MultiAC6 has a 66\% higher success rate than a single-agent approach. Further experimental studies demonstrate that MultiAC6 generalizes well, without retraining, to DLOs with different lengths or materials., Comment: 9 pages, 7 figures, 5 tables, Accepted for IEEE Robotics and Automation Letters (RA-L)

Published
2023

4. Robotic Motion Coordination Based on a Geometric Deformation Measure

Author

Aranda, Miguel, Sanchez, Jose, Ramon, Juan Antonio Corrales, and Mezouar, Youcef

Subjects
Computer Networks and Communications, Computer science, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Centroid, Deformation (meteorology), Measure (mathematics), Computer Science Applications, Term (time), Control and Systems Engineering, Control theory, Robot, Affine transformation, Electrical and Electronic Engineering, Rotation (mathematics), ComputingMethodologies_COMPUTERGRAPHICS, Information Systems
Abstract

This article describes a novel approach to achieve motion coordination in a multirobot system based on the concept of deformation. Our main novel contribution is to link these two elements (namely, coordination and deformation). In particular, the core idea of our approach is that the robots’ motions minimize a global measure of the deformation of their positions relative to a prescribed shape. Based on this idea, we propose a linear shape controller that also incorporates a term modeling an affine deformation. We show that the affine term is particularly useful when the deformation to be controlled is large. We also propose controls for the other variables (centroid, rotation, and size) that define the geometric configuration of the team. Importantly, these additional controls are completely decoupled from the shape control. The overall approach is simple and robust, and it creates closely coordinated robot motions. Being based on deformation, it is useful in several scenarios involving manipulation tasks, e.g., handling of a highly deformable object, control of an object’s shape, or regulation of the shape formed by the fingertips of a robotic hand. We present simulation and experimental results to validate the proposed approach.

Published
2022
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