Geometric Approximation Technique for Minimum Zone Sphericity Error

The mathematical modeling for evaluation of the sphericity error is proposed with minimum radial separation center. To obtain the minimum sphericity error from the form data, a geometric approximation technique was devised.The technique regarded the least square sphere center as the initial center of the concentric spheres containing all measurement points,and then the center was moved gradually to reduce the radial separation till the minimum radial separation center was got where the constructed concentric spheres conformed to the minimum zone condition.The method was modeled firstly,then the geometric approximation process was analyzed,and finally,the software for data processing was programmed.As evaluation example,five steel balls were measured and the measurement data were processed with the developed program.The average iteration times of the approximation technique is 4.2,and on average the obtained sphericity error is 0.529 μm smaller than the least square solution,with accuracy increased by 7.696%.

作 者： He Gaiyun Wang Taiyong Qin Xuda GUO Xiaojun   作者單位： School of Mechanical Engineering, Tianjin University, Tianjin 300072, China  刊 名： 天津大學學報（英文版）  EI 英文刊名： TRANSACTIONS OF TIANJIN UNIVERSITY  年，卷(期)： 2005 11(4)  分類號： Q95  關(guān)鍵詞： sphericity error   minimum zone condition   data processing   form error evaluation  

【Geometric Approximation Technique fo】相關(guān)文章：

Influences of Geometric Parameters upon Nozzle Performances in Scramjets04-28

Numerical Approximation of a Reaction-Diffusion System with Fast Reversible Reaction04-26

Studies on the Interaction of Beryllon Ш with Proteins by Voltammetric Technique and its Application04-27

A computer code for beam optics calculation--third order approximation04-26

Geometric/G/1離散時間可修排隊系統(tǒng)04-29

Test and numerical simulation of a new type of hybrid control technique04-29

Thermal property of biological tissues characterized by piezoelectric photoacoustic technique04-27

A Numerical Study of Sensitivity of the Physical Dissipative Technique to Precipitation Parameterization in a Mesoscale04-28

An Extrapolation Method of Vector Magnetic Field via Surface Integral Technique04-28

Microacoustic Imaging Technique for Bulk Microstructure Characterization of Woven CFRC Materials04-27