Tactile sensing and control of robotic manipulation

AbstractA key component of many robotics model-based planning and control algorithms is physics predictions, that is, forecasting a sequence of states given an initial state and a sequence of controls. This process is slow and a major computational bottleneck for robotics planning algorithms. Parallel-in-time integration methods can help to leverage parallel computing to accelerate physics predictions and thus planning. The Parareal algorithm iterates between a coarse serial integrator and a fine parallel integrator. A key challenge is to devise a coarse model that is computationally cheap but accurate enough for Parareal to converge quickly. Here, we investigate the use of a deep neural network physics model as a coarse model for Parareal in the context of robotic manipulation. In simulated experiments using the physics engine Mujoco as fine propagator we show that the learned coarse model leads to faster Parareal convergence than a coarse physics-based model. We further show that the learned coarse model allows to apply Parareal to scenarios with multiple objects, where the physics-based coarse model is not applicable. Finally, we conduct experiments on a real robot and show that Parareal predictions are close to real-world physics predictions for robotic pushing of multiple objects. Code (https://doi.org/10.5281/zenodo.3779085) and videos (https://youtu.be/wCh2o1rf-gA) are publicly available.

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Translational and rotational slip detection and control in robotic manipulation

IFAC Proceedings Volumes ◽

10.1016/s1474-6670(17)56110-8 ◽

1999 ◽

Vol 32 (2) ◽

pp. 647-652 ◽

Cited By ~ 3

Author(s):

Claudio Melchiorri

Keyword(s):

Robotic Manipulation ◽

And Control ◽

Rotational Slip ◽

Slip Detection

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Tactile Sensing System Device for Robotic Manipulation

10.1109/imc.1990.687441 ◽

2005 ◽

Author(s):

M. Witte ◽

A. Mitchell

Keyword(s):

Robotic Manipulation ◽

Tactile Sensing ◽

Sensing System

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Tactile Sensing and Control of Robotic Manipulator Integrating Fiber Bragg Grating Strain-Sensor

Frontiers in Neurorobotics ◽

10.3389/fnbot.2019.00008 ◽

2019 ◽

Vol 13 ◽

Cited By ~ 6

Author(s):

Luca Massari ◽

Calogero M. Oddo ◽

Edoardo Sinibaldi ◽

Renaud Detry ◽

Joseph Bowkett ◽

...

Keyword(s):

Fiber Bragg Grating ◽

Strain Sensor ◽

Robotic Manipulator ◽

Bragg Grating ◽

Tactile Sensing ◽

And Control

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High-performance vision-based tactile sensing with applications in robotic manipulation

10.14711/thesis-991012873058903412 ◽

2020 ◽

Author(s):

Yazhan Zhang

Keyword(s):

High Performance ◽

Robotic Manipulation ◽

Tactile Sensing

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Modeling and Control of Four-bar Mechanism with Series Elastic Actuators

10.48011/asba.v2i1.1396 ◽

2020 ◽

Author(s):

Felipe R. Lopes ◽

Marco A. Meggiolaro

Keyword(s):

Human Interaction ◽

Robotic Manipulation ◽

Modeling And Control ◽

Lqr Control ◽

In Series ◽

Flexible Behavior ◽

Series Elastic Actuators ◽

New Generation ◽

And Control ◽

Series Elastic

A new generation of robots that work in cooperation with humans (called collaborative robots) needs some flexibility to adapt to the environment and activities with people. That is why the Series Elastic Actuator (SEA) has been a breakthrough in actuator technologies. The idea of inserting an elastic element in series with a motor allows a lower output impedance, consequently a flexible behavior in the manipulator, in addition to providing torque feedback to better compensate disturbances caused e.g. by friction losses. This article presents a four-bar mechanism with SEA for the purpose of robotic manipulation. Its kinematics and dynamicsare studied, as well as its regulation and trajectory control. The behavior of the decoupled four-bar mechanism and the characteristics of the SEA are also analyzed. Then the regulation control of the complete system is carried out using LQR control. Finally, a circular trajectory is controlled in a simulation to validate the proposed control strategy. The simulation results show the effectiveness of the proposed controller for the mechanism in the presence of SEAs estimating torque and providing the desired compliance for human interaction.

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Deep Reinforcement Learning for the Control of Robotic Manipulation: A Focussed Mini-Review

Robotics ◽

10.3390/robotics10010022 ◽

2021 ◽

Vol 10 (1) ◽

pp. 22

Author(s):

Rongrong Liu ◽

Florent Nageotte ◽

Philippe Zanne ◽

Michel de Mathelin ◽

Birgitta Dresp-Langley

Keyword(s):

Deep Learning ◽

Reinforcement Learning ◽

Robotic Manipulation ◽

Significant Progress ◽

Expert Performance ◽

Optimal Behavior ◽

Real World Applications ◽

Critical Issues ◽

And Control ◽

Manipulation And Control

Deep learning has provided new ways of manipulating, processing and analyzing data. It sometimes may achieve results comparable to, or surpassing human expert performance, and has become a source of inspiration in the era of artificial intelligence. Another subfield of machine learning named reinforcement learning, tries to find an optimal behavior strategy through interactions with the environment. Combining deep learning and reinforcement learning permits resolving critical issues relative to the dimensionality and scalability of data in tasks with sparse reward signals, such as robotic manipulation and control tasks, that neither method permits resolving when applied on its own. In this paper, we present recent significant progress of deep reinforcement learning algorithms, which try to tackle the problems for the application in the domain of robotic manipulation control, such as sample efficiency and generalization. Despite these continuous improvements, currently, the challenges of learning robust and versatile manipulation skills for robots with deep reinforcement learning are still far from being resolved for real-world applications.

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