Tool condition monitoring by SVM classification of machined surface images in turning

被引:56
作者
Bhat, Nagaraj N. [1 ]
Dutta, Samik [2 ]
Vashisth, Tarun [3 ]
Pal, Srikanta [4 ]
Pal, Surjya K. [5 ]
Sen, Ranjan [2 ]
机构
[1] BIT, Dept Elect & Elect Engn, Ranchi 835215, Bihar, India
[2] CSIR Cent Mech Engn Res Inst, Precis Engn & Metrol Grp, Durgapur, India
[3] BIT, Dept Elect & Commun Engn, Ranchi 835215, Bihar, India
[4] Shiv Nadar Univ, Dept Elect Engn, Gautam Budh Nagar 201314, Uttar Pradesh, India
[5] Indian Inst Technol, Dept Mech Engn, Kharagpur 721302, W Bengal, India
来源
INTERNATIONAL JOURNAL OF ADVANCED MANUFACTURING TECHNOLOGY | 2016年 / 83卷 / 9-12期
关键词
Feature selection; Turning; GLCM; Surface texture; Fisher discriminant analysis; Tool condition monitoring; Support vector machines; SUPPORT VECTOR MACHINE; LEAST-SQUARES; VISION SYSTEM; ROUGHNESS; TEXTURE; WEAR; PREDICTION; FEATURES; SIGNALS; MODEL;
D O I
10.1007/s00170-015-7441-3
中图分类号
TP [自动化技术、计算机技术];
学科分类号
0812 ;
摘要
Tool condition monitoring has found its importance to meet the requirement of quality production in industries. Machined surface is directly affected by the extent of tool wear. Hence, by analyzing the machined surface, the information about the cutting tool condition can be obtained. This paper presents a novel technique for multi-classification of tool wear states using a kernel-based support vector machine (SVM) technique applied on the features extracted from the gray-level co-occurrence matrix (GLCM) of machined surface images. The tool conditions are classified into sharp, semi-dull, and dull tool states by using Gaussian and polynomial kernels. The proposed method is found to be cost-effective and reliable for online tool wear classification.
引用
收藏
页码:1487 / 1502
页数:16
相关论文
共 56 条
[41]  
Paneque-Galvez, 2011, TEXTURAL CLASSIFICAT
[42]   STATISTICAL APPROACHES TO SURFACE TEXTURE CLASSIFICATION [J].
RAMAMOORTHY, B ;
RADHAKRISHNAN, V .
WEAR, 1993, 167 (02) :155-161
[43]   Statistical methods to compare the texture features of machined surfaces [J].
Ramana, KV ;
Ramamoorthy, B .
PATTERN RECOGNITION, 1996, 29 (09) :1447-1459
[44]   Sensor integration using neural networks for intelligent tool condition monitoring [J].
Rangwala, S. ;
Dornfeld, D. .
Journal of engineering for industry, 1990, 112 (03) :219-228
[45]  
Rode KN, 2012, INT J ENG RES APPL, V2, P1925
[46]   An approach based on current and sound signals for in-process tool wear monitoring [J].
Salgado, D. R. ;
Alonso, F. J. .
INTERNATIONAL JOURNAL OF MACHINE TOOLS & MANUFACTURE, 2007, 47 (14) :2140-2152
[47]   Tool wear predictive model based on least squares support vector machines [J].
Shi, Dongfeng ;
Gindy, Nabil N. .
MECHANICAL SYSTEMS AND SIGNAL PROCESSING, 2007, 21 (04) :1799-1814
[48]  
Sun J, 2004, INT SYM ELECT DES TE, P295
[49]   Multiclassification of tool wear with support vector machine by manufacturing loss consideration [J].
Sun, J ;
Rahman, M ;
Wong, YS ;
Hong, GS .
INTERNATIONAL JOURNAL OF MACHINE TOOLS & MANUFACTURE, 2004, 44 (11) :1179-1187
[50]   Identification of feature set for effective tool condition monitoring by acoustic emission sensing [J].
Sun, J ;
Hong, GS ;
Rahman, M ;
Wong, YS .
INTERNATIONAL JOURNAL OF PRODUCTION RESEARCH, 2004, 42 (05) :901-918
123456