Related papers: DeepCloth-ROB$^2_{\text{QS}}$P&P: Towards a Robust Robot Deployment for Quasi-Static Pick-and-Place Cloth-Shaping Neural Controllers

DeepCloth-ROB$^2_{\text{QS}}$P&P: Towards a Robust Robot Deployment for Quasi-Static Pick-and-Place Cloth-Shaping Neural Controllers

URL: http://arxiv.org/abs/2409.15159v1
Date: Mon, 23 Sep 2024 16:08:16 GMT
Title: DeepCloth-ROB$^2_{\text{QS}}$P&P: Towards a Robust Robot Deployment for Quasi-Static Pick-and-Place Cloth-Shaping Neural Controllers
Authors: Halid Abdulrahim Kadi, Jose Alex Chandy, Luis Figueredo, Kasim Terzić, Praminda Caleb-Solly,
Abstract summary: The fidelity gap between simulation-trained vision-based data-driven cloth neural controllers and real-world operation impedes reliable deployment of methods from simulation into physical trials. We propose DeepCloth-ROB$2_textQS$P&P with a simulation-to-reality transfer strategy Towel-Sim2Real and a cloth grasping protocol. Our approach allows us to compare multiple neural controllers in a real environment for the first time, offering valuable insights to the cloth manipulation community.
Score: 2.720296126199296
License: http://creativecommons.org/licenses/by/4.0/
Abstract: The fidelity gap between simulation-trained vision-based data-driven cloth neural controllers and real-world operation impedes reliable deployment of methods from simulation into physical trials. Real-world grasping errors, such as misgrasping and multilayer grasping, degrade their performance; additionally, some fabrics made of synthetic material also tend to stick to the commonly employed Franka Emika Panda's original gripper. Different approaches adopted various strategies to resolve these problems, further complicating real-world comparison between state-of-the-art methods. We propose DeepCloth-ROB$^2_{\text{QS}}$P&P with a simulation-to-reality transfer strategy Towel-Sim2Real and a cloth grasping protocol to consider and mitigate these grasping errors for robustly deploying quasi-static pick-and-place neural controllers in cloth shaping and demonstrate its generalisability across different deep-learning methods, fabric contexts and robot platforms. Our approach allows us to compare multiple neural controllers in a real environment for the first time, offering valuable insights to the cloth manipulation community.

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