A review of machining monitoring systems based on artificial intelligence process models

Liang SY, Hecker RL, Landers RG (2004) Machining process monitoring and control: the state-of-the-art. J Manuf Sci E-T ASME 126:297–310

Zhou Y, Orban P, Nikumb S (1995) Sensors for intelligent machining-a research and application survey. In: Systems, man and cybernetics IEEE international conference on intelligent systems for the 21st century, vol 2, pp 1005–1010

Cho DW, Leeb SJ, Chu CN (1999) The state of machining process monitoring research in Korea. Int J Mach Tools Manuf 39:1697–1715

Bahr B, Motavalli S, Arfi T (1997) Sensor fusion for monitoring machine tool conditions. Int J Comput Integr Manuf 10:314–323

Ertekin YM, Kwon Y, Tseng TL (2003) Identification of common sensory features for the control of CNC milling operations under varying cutting conditions. Int J Mach Tools Manuf 43:897–904

Guyon I, Elisseeff A (2003) An introduction to variable and feature selection. J Mach Learn Res 3:1157–1182

Zhang JZ, Chen JC (2007) The development of an in-process surface roughness adaptive control system in end milling operations. Int J Adv Manuf Technol 31:877–887

Benardos PG, Vosniakos GC (2002) Prediction of surface roughness in CNC face milling using neural networks and Taguchi’s design of experiments. Robot Comput Integr Manuf 18:343–354

Niu YM, Wong YS, Hong GS (1998) An intelligent sensor system approach for reliable tool flank wear recognition. Int J Adv Manuf Technol 14:77–84

Haber RE, Jimenez JE, Peres CR, Alique JR (2004) An investigation of tool-wear monitoring in a high-speed machining process. Sens Actuators A-Phys 116:539–545

Lan MS, Dornfeld DA (1982) Experimental studies of tool wear via acoustic emission analysis. In: Proceedings of the 10th NAMRC, SME, pp 305–311

Wong YS, Nee AYC, Li XQ, Reisdorf C (1997) Tool condition monitoring using laser scatter pattern. J Mater Process Technol 63:205–210

Kurada S, Bradley C (1997) A machine vision system for tool wear assessment. Tribol Int 30:295–304

Dong JF, Subrahmanyam KVR, Wong YS, Hong GS, Mohanty AR (2006) Bayesian-inference-based neural networks for tool wear estimation. Int J Adv Manuf Technol 30:797–807

Haber RE, Haber RH, Alique JR, Ros S (2002) Application of knowledge-based systems for supervision and control of machining processes. In: Handbook of software engineering and knowledge engineering, vol 2. World Scientific, Singapore, pp 673–710

Chen SL, Jen YW (2000) Data fusion neural network for tool condition monitoring in CNC milling machining. Int J Mach Tools Manuf 40:381–400

Liu YM, Wang CJ (1999) Neural network based adaptive control and optimisation in the milling process. Int J Adv Manuf Technol 15:791–795

Altintas Y (1988) In-process detection of tool breakages using time-series monitoring of cutting forces. Int J Mach Tools Manuf 28:157–172

Azouzi R, Guillot M (1997) On-line prediction of surface finish and dimensional deviation in turning using neural network based sensor fusion. Int J Mach Tools Manuf 37:1201–1217

Ouafi AE, Guillot M, Bedrouni A (2000) Accuracy enhancement of multi-axis CNC machines through on-line neurocompensation. J Intell Manuf 11:535–545

Jemielniak K, Kosmol J (1995) Tool and process monitoring—state of art and future prospects. In: Scientific papers of the institute of mechanical engineering and automation of the Technical University of Wroclaw, vol 61, pp 90–112

Dey S, Stori JA (2005) A Bayesian network approach to root cause diagnosis of process variations. Int J Mach Tools Manuf 45:75–91

Chen JC, Chen WL (1999) A tool breakage detection system using an accelerometer sensor. J Intell Manuf 10:187–197

Jang DY, Choi YG, Kim HG, Hsiao A (1996) Study of the correlation between surface roughness and cutting vibrations to develop an on-line roughness measuring technique in hard turning. Int J Mach Tools Manuf 36:453–464

Chen JC, Huang LH, Lan AX, Lee S (1999) Analysis of an effective sensing location for an in-process surface recognition system in turning operations. J Ind Technol 15:1–6

Abburi NR, Dixit US (2006) A knowledge-based system for the prediction of surface roughness in turning process. Robot Comput Integr Manuf 22:363–372

Abouelatta OB, Madl J (2001) Surface roughness prediction based on cutting parameters and tool vibrations in turning operations. J Mater Process Technol 118:269–277

Lee SS, Chen JC (2003) On-line surface roughness recognition system using artificial neural networks system in turning operations. Int J Adv Manuf Technol 22:498–509

Tsai YH, Chen JC, Lou SJ (1999) An in-process surface recognition system based on neural networks in end milling cutting operations. Int J Mach Tools Manuf 39:583–605

Dimla DE (2002) The correlation of vibration signal features to cutting tool wear in a metal turning operation. Int J Adv Manuf Technol 19:705–713

Li XL (2002) A brief review: acoustic emission method for tool wear monitoring during turning. Int J Mach Tools Manuf 42:157–165

Jemielniak K (2000) Some aspects of AE application in tool condition monitoring. Ultrasonics 38:604–608

Li XL, Yuan ZJ (1998) Tool wear monitoring with wavelet packet transform fuzzy clustering method. Wear 219:145–154

Li XL, Dong S, Yuan ZJ (1999) Discrete wavelet transform for tool breakage monitoring. Int J Mach Tools Manuf 39:1935–1944

Blum T, Inasaki I (1990) A study on acoustic emission from the orthogonal cutting process. Trans ASME J Eng Ind 112:203–211

Ravindra HV, Srinivasa YG, Krishnamurthy R (1997) Acoustic emission for tool condition monitoring in metal cutting. Wear 212:78–84

Stein JL, Wang CH (1990) Analysis of power monitoring on Ac induction drive systems. J Dyn Syst Meas Control Trans ASME 112:239–248

Jones J, Wu Y (1996) Cutting tool’s power consumption measured. US Patent, US 5-587-931

Ghosh N, Ravi YB, Patra A, Mukhopadhyay S, Paul S, Mohanty AR, Chattopadhyay AB (2007) Estimation of tool wear during CNC milling using neural network-based sensor fusion. Mech Syst Signal Process 21:466–479

Lee JM, Choi DK, Kim J, Chu CN (1995) Real-time tool breakage monitoring for NC milling process. CIRP Ann—Manuf Technol 44:59–62

Li XL (2001) Detection of tool flute breakage in end milling using feed-motor current signatures. IEEE-ASME Trans Mechatron 6:491–498

Choudhury SK, Bartarya G (2003) Role of temperature and surface finish in predicting tool wear using neural network and design of experiments. Int J Mach Tools Manuf 43:747–753

Sreejith PS, Ngoi BKA (2000) Dry machining: machining of the future. J Mater Process Technol 101:287–291

Hoy D, Yu F (1991) Surface quality assessment using computer vision methods. J Mater Process Technol 28:265–274

Lee BY, Tarng YS (2001) Surface roughness inspection by computer vision in turning operations. Int J Mach Tools Manuf 41:1251–1263

Coker SA, Shin YC (1996) In-process control of surface roughness due to tool wear using a new ultrasonic system. Int J Mach Tools Manuf 36:411–422

Dimla DE, Lister PM, Leighton NJ (1997) Neural network solutions to the tool condition monitoring problem in metal cutting—a critical review of methods. Int J Mach Tools Manuf 37:1219–1241

Abellan JV, Morales-Menéndez R, Vallejo AJ, Rodriguez C (2006) Surface roughness and cutting tool-wear diagnosis based on Bayesian networks. In: Sixth IFAC symposium on fault detection, supervision and safety of technical processes, pp 439–444

Al-Habaibeh A, Gindy N (2000) A new approach for systematic design of condition monitoring systems for milling processes. J Mater Process Technol 107:243–251

Kuo RJ, Cohen PH (1999) Multi-sensor integration for on-line tool wear estimation through radial basis function networks and fuzzy neural network. Neural Netw 12:355–370

Yoon SI, Lee SS, Kim HS (1995) Tool wear monitoring in milling operation using ART2 neural network. J Korean Soc Precis Eng 12:120–129

Li X, Dong S, Venuvinod PK (2000) Hybrid learning for tool wear monitoring. Int J Adv Manuf Technol 16:303–307

Maeng MJ, Cho SS, Chung JK (1997) Tool fracture detection in end milling using cutting force and acoustic emission propagated through cutting fluid. J Korean Soc Precis Eng 14:163–170

Risbood KA, Dixit US, Sahasrabudhe AD (2003) Prediction of surface roughness and dimensional deviation by measuring cutting forces and vibrations in turning process. J Mater Process Technol 132:203–214

Kim GD, Chu CN (2001) In-process tool fracture monitoring in face milling using spindle motor current and tool fracture index. Int J Adv Manuf Technol 18:383–389

Yao Y, Fang XD, Arndt G (1990) Comprehensive tool wear estimation in finish-machining via multivariate time-series analysis of 3-D cutting forces. Ann CIRP 39:57–60

Dontamsetti SK, Fischer GW (1988) Factors affecting surface roughness in finish turning of gray cast iron. Adv Mater Manuf Process 3:689–725

Moriwaki T, Tobito M (1990) A new approach to automatic detection of life of coated tool based on acoustic-emission measurement. J Eng Ind-Trans ASME 112:212–218

Kamarthi SV, Kumara SRT, Cohen PH (2000) Flank wear estimation in turning through wavelet representation of acoustic emission signals. J Manuf Sci E-T ASME 122:12–19

Li XL, Yao YX, Yuan ZJ (1997) On-line tool condition monitoring system with wavelet fuzzy neural network. J Intell Manuf 8:271–276

Alpaydin E (2004) Introduction to machine learning. MIT, Cambridge

Kirby E, Zhang Z, Chen JC (2004) Development of an accelerometer-based surface roughness prediction system in turning operations using multiple regression techniques. J Ind Technol 20:1–8

Jack LB, Nandi AK (2000) Genetic algorithms for feature selection in machine condition monitoring with vibration signals. IEE Proc-Vis Imag Signal Process 147:205–212

Thawonmas R, Abe S (1997) A novel approach to feature selection based on analysis of class regions. IEEE Trans Syst Man Cybern Part B-Cybern 27:196–207

Shi DF, Gindy NN (2007) Tool wear predictive model based on least squares support vector machines. Mech Syst Signal Process 21:1799–1814

Montgomery DC (2001) Design and analysis of experiments, 5th edn. Wiley, New York

Roy RK (2001) Design of experiments using the Taguchi approach. Wiley, New York

Zhang JZ, Chen JC (2007) The development of an in-process surface roughness adaptive control system in end milling operations. Int J Adv Manuf Technol 31:877–887

Vallejo AG, Nolazco-Flores JA, Morales-Menendez R, Sucar LE, Rodriguez CA (2005) Tool-wear monitoring based on continuous hidden Markov models. Lect Notes Comput Sci 3773:880–890

Zhang JZ, Chen JC, Kirby ED (2007) Surface roughness optimization in an end-milling operation using the Taguchi design method. J Mater Process Technol 184:233–239

Suresh PVS, Rao PV, Deshmukh SG (2002) A genetic algorithmic approach for optimization of surface roughness prediction model. Int J Mach Tools Manuf 42:675–680

Kohli A, Dixit US (2005) A neural-network-based methodology for the prediction of surface roughness in a turning process. Int J Adv Manuf Technol 25:118–129

Dweiri F, Al-Jarrah M, Al-Wedyan H (2003) Fuzzy surface roughness modeling of CNC down milling of alumic-79. J Mater Process Technol 133:266–275

Lo SP (2003) An adaptive-network based fuzzy inference system for prediction of workpiece surface roughness in end milling. J Mater Process Technol 142:665–675

Wang LT, Mehrabi MG, Kannatey-Asibu E (2002) Hidden markov model-based tool wear monitoring in turning. J Manuf Sci E-T ASME 124:651–658

Colak O, Kurbanoglu C, Kayacan MC (2007) Milling surface roughness prediction using evolutionary programming methods. Mater Des 28:657–666

Brezocnik M, Kovacic M, Ficko M (2004) Prediction of surface roughness with genetic programming. J Mater Process Technol 157–158:28–36

Cho S, Asfour S, Onar A, Kaundinya N (2005) Tool breakage detection using support vector machine learning in a milling process. Int J Mach Tools Manuf 45:241–249

NIST/SEMATECH (2006) NIST/SEMATECH e-handbook of statistical methods. http://www.itl.nist.gov/div898/handbook/ . Accessed 20 May 2009