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用于肌肉骨骼机器人的自组织行为生成

Self-Organized Behavior Generation for Musculoskeletal Robots.

作者信息

Der Ralf, Martius Georg

机构信息

Institute for Computer Science, University of Leipzig Leipzig, Germany.

IST AustriaKlosterneuburg, Austria; Autonomous Learning Group, Max Planck Institute for Intelligent SystemsTübingen, Germany.

出版信息

Front Neurorobot. 2017 Mar 16;11:8. doi: 10.3389/fnbot.2017.00008. eCollection 2017.

DOI:10.3389/fnbot.2017.00008
PMID:28360852
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5352682/
Abstract

With the accelerated development of robot technologies, control becomes one of the central themes of research. In traditional approaches, the controller, by its internal functionality, finds appropriate actions on the basis of specific objectives for the task at hand. While very successful in many applications, self-organized control schemes seem to be favored in large complex systems with unknown dynamics or which are difficult to model. Reasons are the expected scalability, robustness, and resilience of self-organizing systems. The paper presents a self-learning neurocontroller based on extrinsic differential plasticity introduced recently, applying it to an anthropomorphic musculoskeletal robot arm with attached objects of unknown physical dynamics. The central finding of the paper is the following effect: by the mere feedback through the internal dynamics of the object, the robot is learning to relate each of the objects with a very specific sensorimotor pattern. Specifically, an attached pendulum pilots the arm into a circular motion, a half-filled bottle produces axis oriented shaking behavior, a wheel is getting rotated, and wiping patterns emerge automatically in a table-plus-brush setting. By these object-specific dynamical patterns, the robot may be said to recognize the object's identity, or in other words, it discovers dynamical affordances of objects. Furthermore, when including hand coordinates obtained from a camera, a dedicated hand-eye coordination self-organizes spontaneously. These phenomena are discussed from a specific dynamical system perspective. Central is the dedicated working regime at the border to instability with its potentially infinite reservoir of (limit cycle) attractors "waiting" to be excited. Besides converging toward one of these attractors, variate behavior is also arising from a self-induced attractor morphing driven by the learning rule. We claim that experimental investigations with this anthropomorphic, self-learning robot not only generate interesting and potentially useful behaviors, but may also help to better understand what subjective human muscle feelings are, how they can be rooted in sensorimotor patterns, and how these concepts may feed back on robotics.

摘要

随着机器人技术的加速发展,控制成为研究的核心主题之一。在传统方法中,控制器凭借其内部功能,基于手头任务的特定目标找到合适的动作。虽然在许多应用中非常成功,但自组织控制方案似乎在具有未知动力学或难以建模的大型复杂系统中更受青睐。原因在于自组织系统预期的可扩展性、鲁棒性和弹性。本文提出了一种基于最近引入的外在微分可塑性的自学习神经控制器,并将其应用于带有未知物理动力学附加物体的拟人化肌肉骨骼机器人手臂。本文的核心发现是以下效果:仅通过物体内部动力学的反馈,机器人就学会将每个物体与非常特定的感觉运动模式联系起来。具体而言,一个附着的摆锤引导手臂做圆周运动,一个半满的瓶子产生轴向摇晃行为,一个轮子被旋转,并且在桌子加刷子的设置中自动出现擦拭模式。通过这些特定于物体的动态模式,可以说机器人识别了物体的身份,或者换句话说,它发现了物体的动态可供性。此外,当纳入从相机获得的手部坐标时,一种专门的手眼协调会自发地自组织。从特定的动态系统角度讨论了这些现象。核心是处于不稳定边界的专门工作模式,其具有潜在无限的(极限环)吸引子“储备”等待被激发。除了趋向于这些吸引子之一外,变化行为也源于由学习规则驱动的自诱导吸引子变形。我们声称,对这个拟人化、自学习机器人的实验研究不仅产生了有趣且可能有用的行为,还可能有助于更好地理解人类主观肌肉感觉是什么、它们如何扎根于感觉运动模式以及这些概念如何反馈到机器人技术中。

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