On robot grasp learning using equivariant models

IF 3.7 3区计算机科学 Q2 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE Autonomous Robots Pub Date : 2023-07-04 DOI:10.1007/s10514-023-10112-w

Xupeng Zhu, Dian Wang, Guanang Su, Ondrej Biza, Robin Walters, Robert Platt

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Abstract

Real-world grasp detection is challenging due to the stochasticity in grasp dynamics and the noise in hardware. Ideally, the system would adapt to the real world by training directly on physical systems. However, this is generally difficult due to the large amount of training data required by most grasp learning models. In this paper, we note that the planar grasp function is \(\textrm{SE}(2)\)-equivariant and demonstrate that this structure can be used to constrain the neural network used during learning. This creates an inductive bias that can significantly improve the sample efficiency of grasp learning and enable end-to-end training from scratch on a physical robot with as few as 600 grasp attempts. We call this method Symmetric Grasp learning (SymGrasp) and show that it can learn to grasp “from scratch” in less that 1.5 h of physical robot time. This paper represents an expanded and revised version of the conference paper Zhu et al. (2022).

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基于等变模型的机器人抓取学习

由于抓取动力学的随机性和硬件的噪声，在现实世界中抓取检测具有挑战性。理想情况下，该系统将通过直接在物理系统上进行训练来适应现实世界。然而，这通常是困难的，因为大多数掌握学习模型需要大量的训练数据。在本文中，我们注意到平面抓取函数是\(\textrm{SE}(2)\) -等变的，并证明这种结构可以用来约束学习过程中使用的神经网络。这就产生了一种归纳偏差，可以显著提高抓取学习的样本效率，并实现在物理机器人上从头开始的端到端训练，只需600次抓取尝试。我们称这种方法为对称抓取学习(SymGrasp)，并表明它可以在不到1.5小时的物理机器人时间内“从零开始”学习抓取。本文是会议论文Zhu et al.(2022)的扩展和修订版本。

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来源期刊

Autonomous Robots 工程技术-机器人学

CiteScore

7.90

自引率

5.70%

发文量

审稿时长

3 months

期刊介绍： Autonomous Robots reports on the theory and applications of robotic systems capable of some degree of self-sufficiency. It features papers that include performance data on actual robots in the real world. Coverage includes: control of autonomous robots · real-time vision · autonomous wheeled and tracked vehicles · legged vehicles · computational architectures for autonomous systems · distributed architectures for learning, control and adaptation · studies of autonomous robot systems · sensor fusion · theory of autonomous systems · terrain mapping and recognition · self-calibration and self-repair for robots · self-reproducing intelligent structures · genetic algorithms as models for robot development. The focus is on the ability to move and be self-sufficient, not on whether the system is an imitation of biology. Of course, biological models for robotic systems are of major interest to the journal since living systems are prototypes for autonomous behavior.