Optimal control method for the sphericity error using CMMs

机译：坐标测量机的球形度误差最优控制方法

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Spherical surfaces are utilized widely in precision bearing, MEMS and parts of precision engineering. Constantly growing needs in the high motion performance of spherical parts, sphericity error is becoming an indispensable component in the control of form error. However, currently the quality control of a spherical surface is restricted by the lack of science-based mathematical models. This paper presents a unified approach to evaluate sphericity error using three methods: Least Square Sphere, Minimum Zone Sphere, Maximum Inscribed Sphere. The research originated from the need compare the effectiveness of these methods for different requirements for measurement accuracy. Three experiments are used to verify the effectiveness of the methods with 28, 36 and 50 datasets measured on Coordinate Measuring Machines. Presents a mathematical models of sphericity measurement and comparative results of the verification of these models.

机译：球面广泛用于精密轴承，MEMS和精密工程的零件中。球形零件的高运动性能需求不断增长，球形误差已成为控制形状误差中必不可少的组成部分。然而，目前缺乏基于科学的数学模型限制了球形表面的质量控制。本文提出了一种使用三种方法评估球度误差的统一方法：最小二乘球面，最小区域球面，最大内接球面。该研究源于需要比较这些方法对不同测量精度要求的有效性。使用三个实验来验证在坐标测量机上测量的28、36和50个数据集的方法的有效性。提出了球形度测量的数学模型以及这些模型验证的比较结果。

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来源
《2016 Dynamics of Systems, Mechanisms and Machines》|2016年|1-3|共3页
会议地点 Omsk(RU)
作者
Oleg V. Zakharov; Igor N. Bobrovskij; Nikolaj M. Bobrovskij; Andrey A. Korolev; Andrei V. Kochetkov; Vladimir A. Ivashchenko;
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作者单位

Samara university, Samara, Russia;

Togliatti State University, Togliatti, Russia;

Togliatti State University, Togliatti, Russia;

Yuri Gagarin State Technical University, Saratov, Russia;

Perm National Research Polytechnic University, Perm, Russia;

Laboratory of system issues management and automation in mechanical engineering Institute of Precision Mechanics and Control of RAS Saratov, Russia;

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原文格式 PDF
正文语种 eng
中图分类
关键词
Coordinate measuring machines; Mathematical model; Precision engineering; Measurement techniques; Measurement uncertainty; Micromechanical devices; Quality control;

机译：坐标测量机;数学模型;精密工程;测量技术;测量不确定度;微机械装置;质量控制;

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2. Convergence and quasi-optimality of an adaptive finite element method for controlling L₂ errors [J] . Alan Demlow, Rob Stevenson Numerische Mathematik . 2011,第2期

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3. Convergence and quasi-optimality of an adaptive finite element method for controlling L_2 errors [J] . Demlow A., Stevenson R. Numerische Mathematik . 2010,第2期

机译：控制L_2误差的自适应有限元方法的收敛性和拟最优性
4. Optimal control method for the sphericity error using CMMs [C] . Oleg V. Zakharov, Igor N. Bobrovskij, Nikolaj M. Bobrovskij, International Scientific and Technical Conference on Dynamics of Systems, Mechanisms and Machines . 2016

机译：使用CMMS的球形误差的最佳控制方法
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7. Convergence and quasi-optimality of an adaptive finite element method for controlling L2 errors [O] . Alan Demlow, Rob Stevenson 2014

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8. Investigation into the Application of Dynamic Programming to Determine Optimal Controls for Tracking a Cruise Missile Maneuver by CMMCA (Cruise Missile Mission Control Aircraft) [R] . Heavner, L. G. 1989

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Optimal control method for the sphericity error using CMMs

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