ANALYTICAL MODEL FOR COMPENSATING MOTION ERROR IN THE ADAPTIVE MOTION CONTROL OF THE BIOMECHANICAL SYSTEM

IF 0.2 Q4 SPORT SCIENCES Human Sport Medicine Pub Date : 2019-07-13 DOI:10.14529/HSM190210
V. Zagrevskiy, O. Zagrevskiy
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引用次数: 0

Abstract

Aim. The article deals with developing software to simulate the motion of an object with the given parameters of initial and final phase status. Materials and methods. A motion error in sports exercise is the result of kinematic deviation from the parameters of a given motion program. The mathematical apparatus of adaptive control allows neutralizing motion mistakes between a program and a real trajectory. It is based on utilising the information about current parameters of a phase status of a moving object in a mathematical structure of the control function. The article proposes and experimentally proves the hypothesis about the computer synthesis of motions in biomechanical systems based on the mathematical apparatus of adaptive control. In the computational experiments, a mathematical description of an object is based on a well-established law of open-time approximation (A.P. Batenko, 1977), which requires that both velocity and coordinates simultaneously take the given values. Motion time in this law is an uncontrolled parameter. The mathematical model of a moving object is built as a system of a first-order differential equation. Results. A mathematical model describing the motion of a material point with given phase coordinates at the initial and final points in time is implemented in a computer program. The program works based on the integrated development environment Visual Studio Express 2013 and the Visual Basic 2010 language environment. Conclusion. The developed computer model of adaptive control achieves the aim of any motion, which implies transferring an object from a given initial state to the required final state.
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生物力学系统自适应运动控制中运动误差补偿的解析模型
的目标。本文讨论了在给定初始和末相状态参数下,开发模拟物体运动的软件。材料和方法。在体育运动中,运动误差是由于运动偏离给定运动程序的参数而产生的。自适应控制的数学装置可以抵消程序和实际轨迹之间的运动误差。它基于在控制函数的数学结构中利用关于运动对象的相位状态的电流参数的信息。本文提出了基于自适应控制数学装置的生物力学系统运动计算机综合的假设,并通过实验证明了这一假设。在计算实验中,一个对象的数学描述是基于一个公认的开放时间近似定律(A.P. Batenko, 1977),它要求速度和坐标同时取给定的值。在这个定律中,运动时间是一个不受控制的参数。将运动物体的数学模型建立为一阶微分方程系统。结果。在计算机程序中实现了描述具有给定相位坐标的质点在初始和最终时间点上的运动的数学模型。该程序是在Visual Studio Express 2013集成开发环境和Visual Basic 2010语言环境下完成的。结论。所开发的自适应控制计算机模型可以实现任何运动的目标,即将物体从给定的初始状态转移到所需的最终状态。
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来源期刊
Human Sport Medicine
Human Sport Medicine SPORT SCIENCES-
CiteScore
0.70
自引率
50.00%
发文量
0
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