In this paper, a method for predicting progressive tool flank wear using extracted features from turned surface images has been proposed. Acquired turned surface images are analyzed by using texture analyses, viz., gray level co-occurrence matrix (GLCM), Voronoi tessellation (VT), and discrete wavelet transform (DWT) based methods to obtain information about waviness, feed marks, and roughness from machined surface images for describing tool flank wear. Two features from each texture analyses are extracted and fed into support vector machine (SVM) based regression models for predicting progressive tool flank wear. Mean correlation coefficient between the measured and predicted tool flank wear is found as 0.991.
Issue Section:
Research Papers
References
1.
Dutta
, S.
, Pal
, S. K.
, and Sen
, R.
, 2014
, “Digital Image Processing in Machining
,” Modern Mechanical Engineering—Research, Development and Education
, J. P.
Davim
, ed., Springer
, Berlin
, pp. 369
–412
.2.
Roth
, J. T.
, Djurdjanovic
, D.
, Yang
, X.
, Mears
, L.
, and Kurfess
, T.
, 2010
, “Quality and Inspection of Machining Operations—Tool Condition Monitoring
,” ASME J. Manuf. Sci. Eng.
, 132
(4
), p. 041015
.3.
Rao
, P.
, Bukkapatnam
, S.
, Beyca
, O.
, Kong
, Z.
, and Komanduri
, R.
, 2014
, “Real-Time Identification of Incipient Surface Morphology Variations in Ultraprecision Machining Process
,” ASME J. Manuf. Sci. Eng.
, 136
(2
), p. 021008
.4.
Ertekin
, Y. M.
, Kwon
, Y.
, and Tseng
, T. L.
, 2003
, “Identification of Common Sensory Features for the Control of CNC Milling Operations Under Varying Cutting Conditions
,” Int. J. Mach. Tool. Manuf.
, 43
(9
), pp. 897
–904
.5.
Kuttolamadom
, M.
, Mehta
, P.
, Mears
, L.
, and Kurfess
, T.
, 2015
, “Correlation of the Volumetric Tool Wear Rate of Carbide Milling Inserts With the Material Removal Rate of Ti–6Al–4V
,” ASME J. Manuf. Sci. Eng.
, 137
(2
), p. 021021
.6.
Dutta
, S.
, Pal
, S. K.
, Mukhopadhyay
, S.
, and Sen
, R.
, 2013
, “Application of Digital Image Processing in Tool Condition Monitoring: A Review
,” CIRP J. Manuf. Sci. Technol.
, 6
(3
), pp. 212
–232
.7.
Tuceryan
, M.
, and Jain
, A. K.
, 1998
, “Texture Analysis
,” The Handbook of Pattern Recognition and Computer Vision
, C. H.
Chen
, L. F.
Pau
, and P. S. P.
Wang
, eds., World Scientific Publisher
, Singapore
, pp. 207
–248
.8.
Gadelmawla
, E. S.
, 2011
, “Estimation of Surface Roughness for Turning Operations Using Image Texture Features
,” Proc. Inst. Mech. Eng.
, Part B, 225
(8
), pp. 1281
–1292
.9.
Gadelmawla
, E. S.
, Eladawi
, A. E.
, Abouelatta
, O. B.
, and Elewa
, I. M.
, 2009
, “Application of Computer Vision for the Prediction of Cutting Conditions in Milling Operations
,” Proc. Inst. Mech. Eng.
, Part B, 223
(7
), pp. 791
–800
.10.
Bamberger
, H.
, Ramachandran
, S.
, Hong
, E.
, and Katz
, R.
, 2011
, “Identification of Machining Chatter Marks on Surfaces of Automotive Valve Seats
,” ASME J. Manuf. Sci. Eng.
, 133
(4
), p. 041003
.11.
Liu
, W.
, Tu
, X.
, Jia
, Z.
, Wang
, W.
, Ma
, X.
, and Bi
, X.
, 2013
, “An Improved Surface Roughness Measurement Method for Micro-Heterogeneous Texture in Deep Hole Based on Gray-Level Co-Occurrence Matrix and Support Vector Machine
,” Int. J. Adv. Manuf. Technol.
, 69
(1–4
), pp. 583
–593
.12.
Wang
, M.
, Ken
, T.
, Du
, S.
, and Xi
, L.
, 2015
, “Tool Wear Monitoring of Wiper Inserts in Multi-Insert Face Milling Using Three-Dimensional Surface Form Indicators
,” ASME J. Manuf. Sci. Eng.
, 137
(3
), p. 031006
.13.
Datta
, A.
, Dutta
, S.
, Pal
, S. K.
, and Sen
, R.
, 2013
, “Progressive Cutting Tool Wear Detection From Machined Surface Images Using Voronoi Tessellation Method
,” J. Mater. Process. Technol.
, 213
(12
), pp. 2339
–2349
.14.
Fu
, S.
, Muralikrishnan
, B.
, and Raja
, J.
, 2003
, “Engineering Surface Analysis With Different Wavelet Bases
,” ASME J. Manuf. Sci. Eng.
, 125
(4
), pp. 844
–852
.15.
Josso
, B.
, Burton
, D. R.
, and Lalor
, M. J.
, 2001
, “Wavelet Strategy for Surface Roughness Analysis and Characterisation
,” Comput. Method Appl. Mech. Eng.
, 191
(8–10
), pp. 829
–842
.16.
Josso
, B.
, Burton
, D. R.
, and Lalor
, M. J.
, 2002
, “Frequency Normalised Wavelet Transform for Surface Roughness Analysis and Characterization
,” Wear
, 252
(5–6
), pp. 491
–500
.17.
Chang
, S. I.
, and Ravathur
, J. S.
, 2005
, “Computer Vision Based Non-Contact Surface Roughness Assessment Using Wavelet Transform and Response Surface Methodology
,” Qual. Eng.
, 17
(3
), pp. 435
–451
.18.
Zawada-Tomkiewicz
, A
., 2010
, “Estimation of Surface Roughness Parameter Based on Machined Surface Image
,” Metrol. Meas. Syst.
, 17
(3
), pp. 493
–504
.19.
Morala-Argüello
, P.
, Barreiro
, J.
, and Alegre
, E.
, 2012
, “An Evaluation of Surface Roughness Classes by Computer Vision Using Wavelet Transform in the Frequency Domain
,” Int. J. Adv. Manuf. Technol.
, 59
(1
), pp. 213
–220
.20.
Lee
, B. Y.
, Yu
, S. F.
, and Juan
, H.
, 2004
, “The Model of Surface Roughness Inspection by Vision System in Turning
,” Mechatronics
, 14
(1
), pp. 129
–141
.21.
Kassim
, A. A.
, Mian
, Z.
, and Mannan
, M. A.
, 2006
, “Tool Condition Classification Using Hidden Markov Model Based on Fractal Analysis of Machined Surface Textures
,” Mach. Vis. Appl.
, 17
(5
), pp. 327
–336
.22.
Du
, S.
, Liu
, C.
, and Xi
, L.
, 2015
, “A Selective Multiclass Support Vector Machine Ensemble Classifier for Engineering Surface Classification Using High Definition Metrology
,” ASME J. Manuf. Sci. Eng.
, 137
(1
), p. 011003
.23.
Lee
, B. Y.
, and Tarng
, Y. S.
, 2001
, “Surface Roughness Inspection by Computer Vision in Turning Operations
,” Int. J. Mach. Tool Manuf.
, 41
(9
), pp. 1251
–1263
.24.
Ho
, S. Y.
, Lee
, K. C.
, Chen
, S. S.
, and Ho
, S. J.
, 2002
, “Accurate Modeling and Prediction of Surface Roughness by Computer Vision in Turning Operations Using an Adaptive Neuro-Fuzzy Inference System
,” Int. J. Mach. Tool Manuf.
, 42
(13
), pp. 1441
–1446
.25.
Lee
, K. C.
, Ho
, S. J.
, and Ho
, S. Y.
, 2005
, “Accurate Estimation of Surface Roughness From Texture Features of the Surface Image Using an Adaptive Neuro-Fuzzy Inference System
,” Precis. Eng.
, 29
(1
), pp. 95
–100
.26.
Dhanasekar
, B.
, and Ramamoorthy
, B.
, 2008
, “Assessment of Surface Roughness Based on Super Resolution Reconstruction Algorithm
,” Int. J. Adv. Manuf. Technol.
, 35
(11
), pp. 1191
–1205
.27.
Dhanasekar
, B.
, and Ramamoorthy
, B.
, 2010
, “Restoration of Blurred Images for Surface Roughness Evaluation Using Machine Vision
,” Tribol. Int.
, 43
(1–2
), pp. 268
–276
.28.
Palani
, S.
, and Natarajan
, U.
, 2011
, “Prediction of Surface Roughness in CNC End Milling by Machine Vision System Using Artificial Neural Network Based on 2D Fourier Transform
,” Int. J. Adv. Manuf. Technol.
, 54
(9
), pp. 1033
–1042
.29.
Saini
, S
, Ahuja
, I. S.
, and Sharma
, V. S.
, 2012
, “Residual Stresses, Surface Roughness, and Tool Wear in Hard Turning: A Comprehensive Review
,” Mater. Manuf. Process.
, 27
(6
), pp. 583
–598
.30.
Zawada-Tomkiewicz
, A
., 2011
, “Analysis of Surface Roughness Parameters Achieved by Hard Turning With the Use of PCBN Tools
,” Est. J. Eng.
, 17
(1
), pp. 88
–99
.31.
Rodrigues
, L. L. R.
, Kantharaj
, A. N.
, Kantharaj
, B.
, Freitas
, W. R. C
, and Murthy
, B. R. N.
, 2012
, “Effect of Cutting Parameters on Surface Roughness and Cutting Force in Turning Mild Steel
,” Res. J. Recent Sci.
, 1
(10
), pp. 19
–26
.32.
Isik
, Y
., 2010
, “An Experimental Investigation on Effect of Cutting Fluids in Turning With Coated Carbides Tool
,” J. Mech. Eng.
, 56
(3
), pp. 195
–201
.33.
ISO 3685
: 1993
Tool Life Testing With Single Point Turning Tools
, ISO
, Geneva, Switzerland.34.
Burke
, M. W.
, 1996
, Image Acquisition: Handbook of Machine Vision Engineering
, Vol. 1
, Chapman and Hall
, London
.35.
ISO 25178-2
:2012
, Geometrical Product Specifications (GPS)—Surface Texture: Areal—Part 2: Terms, Definitions and Surface Texture Parameters
, ISO
, Geneva, Switzerland.36.
Whitehouse
, D. J.
, 2011
, Handbook of Surface and Nanometrology
, CRC Press
, Boca Raton, FL
, Chap. 2.37.
Gonzalez
, R. C.
, and Woods
, R. E.
, 2002
, Digital Image Processing
, Prentice-Hall
, Upper Saddle River, NJ
.38.
Pizer
, S. M.
, Amburn
, E. P.
, Austin
, J. D.
, Cromartie
, R.
, Geselowitz
, A.
, Greer
, T.
, Romeny
, B. H.
, Zimmerman
, J. B.
, and Zuiderveld
, K.
, 1987
, “Adaptive Histogram Equalization and Its Variations
,” Comput. Vision Graphics Image Process.
, 39
(3
), pp. 355
–368
.39.
Baraldi
, A.
, and Parmiggiani
, F.
, 1995
, “An Investigation of the Textural Characteristics Associated With Gray Level Co-Occurrence Matrix Statistical Parameters
,” IEEE Trans. Geosci. Remote Sens.
, 33
(2
), pp. 293
–304
.40.
Haralick
, R. M.
, Shanmugam
, K.
, and Dinsten
, I.
, 1973
, “Textural Features for Image Classification
,” IEEE Trans. Syst. Man Cybernet.
, 3
(6
), pp. 610
–621
.41.
Dutta
, S.
, Datta
, A.
, Chakladar
, N. D.
, Pal
, S. K.
, Mukhopadhyay
, S.
, and Sen
, R.
, 2012
, “Detection of Tool Condition From the Turned Surface Images Using an Accurate Grey Level Co-Occurrence Technique
,” Precis. Eng.
, 36
(3
), pp. 458
–466
.42.
Canny
, J.
, 1986
, “A Computational Approach to Edge Detection
,” IEEE Trans. Pattern Anal. Mach. Intell.
, 8
(6
), pp. 679
–698
.43.
Mallat
, S.
, 1999
, A Wavelet Tour of Signal Processing—The Sparse Way
, Academic Press
, Burlington, MA
.44.
Petrou
, M.
, and Sevilla
, P. G.
, 2006
, Image Processing Dealing With Texture
, Wiley
, West Sussex, UK
, Chap. 4.45.
Reed
, G. F.
, Lynn
, F.
, and Meade
, B. D.
, 2002
, “Use of Coefficient of Variation in Assessing Variability of Quantitative Assays
,” Clin. Diagn. Lab. Immun.
, 10
(6
), pp. 1235
–1239
.46.
Smola
, A. J.
, and Schölkopf
, B.
, 2004
, “A Tutorial on Support Vector Regression
,” Stat. Comput.
, 14
(3
), pp. 199
–222
.47.
Ahuja
, N.
, Lertrattanapanich
, S.
, and Bose
, N. K.
, 2005
, “Properties Determining Choice of Mother Wavelet
,” IEEE Proc. Vision Image Signal Process.
, 152
(5
), pp. 659
–664
.48.
Fushiki
, T
., 2011
, “Estimation of Prediction Error by Using k-Fold Cross-Validation
,” Stat. Comput.
, 21
(2
), pp. 137
–146
.49.
Cherkassy
, V.
, and Ma
, Y.
, 2004
, “Practical Selection of SVM Parameters and Noise Estimation for SVM Regression
,” Neural Networks
, 17
(1
), pp. 113
–126
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