体操运动员 "在自由飞行和与支撑物接触状态过渡期间的运动控制问题

Q4 Engineering

Russian Journal of Biomechanics Pub Date : 2020-03-31 DOI:10.15593/rjbiomech/2020.1.07

Eduard Lavrovskii

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引用次数: 0

摘要

本研究从理论力学的角度讨论了 "体操运动员"--运动员（或机器人--"体操运动员"）从 "横杆 "上向下跳跃的某些方面。我们讨论了平面情况下跳跃的所有阶段。"体操运动员 "的身体被建模为三连杆物理摆，然而，在离开 "横杆 "并放下 "手 "模型后，动态系统变成了两连杆摆。对于 "运动学 "控制模式下的双连杆模型，我们处理的是手的下降过程、自由飞行、"腿 "在框架上的输出（绝对无弹性冲击）和支撑阶段的保持操作，目的是使摆锤系统垂直稳定。运动控制 "模式指的是瞬间改变身体各环节之间角度的能力（在一定范围内）。对于每个运动阶段，我们都找到了一种方便的动态方程描述形式。这些方程以系统相对于身体或空间各点的可变动量为基础。该方程系统的阶数低于全阶系统。在脚踏上支撑物表面之后出现的 "体操运动员 "的平静阶段，也将根据这种类型的特殊方程组进行研究。结果表明，我们可以使用数值分析来建立双连杆模型在稳定状态下过渡的可控区域，稳定状态对应于支撑脚的水平坐标和双连杆摆系统的重心相等。设计了稳定控制算法。根据对问题的分析结果，我们可以方便地构建一个整体现象的近似模型，并用它来控制对应的机器人。作为一个例子，我们考虑了与拟人模型相对应的一种运动情况。

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The problem of "gymnast" motion control in free flight and during the transition in the state of contact with the support

The study from the position of theoretical mechanics discusses some aspects of the jump down of the "gymnast" – athlete (or the robot – "gymnast") from the "crossbar". We discuss all phases of the jump in the planar case. "Gymnast" body is modeled as three-links physical pendulum, however, after departing from the "crossbar" and lowering the "hands" model the dynamic system becomes two-links pendulum. For a two-links model in the regime of "kinematic" control, we deal with the process of lowering hands, free flight, the output of the "legs" on the frame (absolutely inelastic impact) and holding operation in support phase with the aim of vertical stabilize of the pendulum system. Mode "kinematic control" means the ability to instantly change the angle between the links of the body (in some limits). For each of the phases of movement, we found a convenient form of describing dynamical equations. These equations are based on the use as a variable momentum of the system relative to various points of the body or space. The order of this system of equations is lower than for the full order system. The stage of calm "gymnast" that occurs after the foot on the surface of the support, will also be examined on the basis of special system of equations of this type. It was shown, that we can use numerical analysis to build the region of controllability for transition of the two-links model in a state of stabilization, corresponding to the equality of the horizontal coordinate of the support foot and the center of gravity of the two-links pendulum system. The algorithm of stabilizing control is designed. The results of presented of the analysis of the problem allow us to construct a convenient approximate model of the phenomenon as a whole, and to use it to control a robotic counterpart. As an example, it is considered one of the cases of motion that corresponds to the anthropomorphic model.

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来源期刊

Russian Journal of Biomechanics Biochemistry, Genetics and Molecular Biology-Biophysics

CiteScore

1.10

自引率

0.00%

发文量

期刊介绍： Russian Journal of Biomechanics publishes peer reviewed articles related to the principal topics in biomechanics. This Journal was established to improve the information interchange between specialists on biomechanics from Russia and other countries. Biomechanics is defined as the mechanics of living tissues and biomaterials. The Journal presents original papers of a wide biomechanical profile. A balance of biomechanical and medical problems is the principal aspect of the Journal activities. The Journal encourages the submission of original articles, reviews, short communications and case studies in all areas of biomechanics, including, but not limited to: • General problems and methods of biomechanics • Rheological properties of living tissues • Biomaterials and prostheses • Dental biomechanics • Human movement analysis • Musculoskeletal biomechanics • Cardiovascular biomechanics • Biomechanics of breathing • Tissue and cellular biomechanics • Sport biomechanics • Biomechanical problems in biotechnology.