Coping with Complexity When Predicting Surface Roughness in Milling Processes: Hybrid Incremental Model with Optimal Parametrization

The complexity of machining processes relies on the inherent physical mechanisms governing these processes including nonlinear, emergent, and time-variant behavior. The measurement of surface roughness is a critical step done offline by expensive quality control procedures. The surface roughness prediction using an online efficient computational method is a difficult task due to the complexity of machining processes. The paradigm of hybrid incremental modeling makes it possible to address the complexity and nonlinear behavior of machining processes. Parametrization of models is, however, one bottleneck for full deployment of solutions, and the optimal setting of model parameters becomes an essential task. This paper presents a method based on simulated annealing for optimal parameters tuning of the hybrid incremental model. The hybrid incremental modeling plus simulated annealing is applied for predicting the surface roughness in milling processes. Two comparative studies to assess the accuracy and overall quality of the proposed strategy are carried out. The first comparative demonstrates that the proposed strategy is more accurate than theoretical, energy-based, and Taguchi models for predicting surface roughness. The second study also corroborates that hybrid incremental model plus simulated annealing is better than a Bayesian network and a multilayer perceptron for correctly predicting the surface roughness.

[1]  Robert Ivor John,et al.  Learning of interval and general type-2 fuzzy logic systems using simulated annealing: Theory and practice , 2016, Inf. Sci..

[2]  Rob A. Rutenbar,et al.  Simulated annealing algorithms: an overview , 1989, IEEE Circuits and Devices Magazine.

[3]  Gandjar Kiswanto,et al.  The effect of spindle speed, feed-rate and machining time to the surface roughness and burr formation of Aluminum Alloy 1100 in micro-milling operation , 2014 .

[4]  Radu-Emil Precup,et al.  An overview on fault diagnosis and nature-inspired optimal control of industrial process applications , 2015, Comput. Ind..

[5]  Rodolfo E. Haber,et al.  Hybrid Incremental Modeling Based on Least Squares and Fuzzy $K$-NN for Monitoring Tool Wear in Turning Processes , 2012, IEEE Transactions on Industrial Informatics.

[6]  Francisco Herrera,et al.  Evolutionary fuzzy k-nearest neighbors algorithm using interval-valued fuzzy sets , 2016, Inf. Sci..

[7]  Concha Bielza,et al.  Comparison of Bayesian networks and artificial neural networks for quality detection in a machining process , 2009, Expert Syst. Appl..

[8]  Vladimir Modrak,et al.  Novel Complexity Indicator of Manufacturing Process Chains and Its Relations to Indirect Complexity Indicators , 2017, Complex..

[9]  Seok-Beom Roh,et al.  The refinement of models with the aid of the fuzzy k-nearest neighbors approach , 2010, IEEE Transactions on Instrumentation and Measurement.

[10]  E. Lee,et al.  Nonparametric fuzzy regression—k-NN and kernel smoothing techniques , 1999 .

[11]  Gerardo Beruvides,et al.  Application of hybrid incremental modeling for predicting surface roughness in micromachining processes , 2014, 2014 IEEE Symposium on Computational Intelligence for Engineering Solutions (CIES).

[12]  Yi Hong,et al.  A hybrid algorithm based on particle swarm optimization and simulated annealing to holon task allocation for holonic manufacturing system , 2007 .

[13]  Mikolaj Kuzinovski,et al.  Modeling and prediction of surface roughness profile in longitudinal turning , 2016 .

[14]  Potsang B. Huang An intelligent neural-fuzzy model for an in-process surface roughness monitoring system in end milling operations , 2014, Journal of Intelligent Manufacturing.

[15]  Rosario Domingo,et al.  Integration of Error Compensation of Coordinate Measuring Machines into Feature Measurement: Part I—Model Development , 2016, Sensors.

[16]  Julio Blanco-Fernández,et al.  New Product Development and Innovation in the Maquiladora Industry: A Causal Model , 2016 .

[17]  Hazim El-Mounayri,et al.  Prediction of surface roughness in end milling using swarm intelligence , 2003, Proceedings of the 2003 IEEE Swarm Intelligence Symposium. SIS'03 (Cat. No.03EX706).

[18]  Gerardo Beruvides,et al.  Surface roughness modeling and optimization of tungsten–copper alloys in micro-milling processes , 2016 .

[19]  A. M. M. Sharif Ullah,et al.  Tool-wear prediction and pattern-recognition using artificial neural network and DNA-based computing , 2015, Journal of Intelligent Manufacturing.

[20]  R. Haber,et al.  Application of Knowledge Based Systems for Supervision and Control of Machining Processes , 2022 .

[21]  Rodolfo E. Haber,et al.  A neural network-based model for the prediction of cutting force in milling process. A progress study on a real case , 2000, Proceedings of the 2000 IEEE International Symposium on Intelligent Control. Held jointly with the 8th IEEE Mediterranean Conference on Control and Automation (Cat. No.00CH37147).

[22]  W. Lu,et al.  A novel approach to predicting surface roughness based on specific cutting energy consumption when slot milling Al-7075 , 2016 .

[23]  Ming-Yung Wang,et al.  Experimental study of surface roughness in slot end milling AL2014-T6 , 2004 .

[24]  Antonio Javier Barragán,et al.  Hibridación de sistemas borrosos para el modelado y control , 2014 .

[25]  Daim-Yuang Sun,et al.  The Solution of Time Optimal Control Problems by Simulated Annealing , 2006 .

[26]  Witold Pedrycz,et al.  The Development of Incremental Models , 2007, IEEE Transactions on Fuzzy Systems.

[27]  Rodolfo E. Haber,et al.  Nonlinear internal model control using neural networks: an application for machining processes , 2004, Neural Computing & Applications.

[28]  Michael P Sealy,et al.  Energy based process signature for surface integrity in hard milling , 2016 .

[29]  A. Alique,et al.  Embedded fuzzy-control system for machining processes: Results of a case study , 2003, Comput. Ind..

[30]  Petr Suchánek,et al.  Modelling Decision-Making Processes in the Management Support of the Manufacturing Element in the Logistic Supply Chain , 2017, Complex..

[31]  Rosario Domingo,et al.  Integration of Error Compensation of Coordinate Measuring Machines into Feature Measurement: Part II—Experimental Implementation , 2016, Sensors.

[32]  Giuseppe Di Fatta,et al.  Simulated annealing technique for fast learning of SOM networks , 2013, Neural Computing and Applications.

[33]  Zhu Ming,et al.  A Study on Speech Emotion Recognition Based On Fuzzy K Nearest Neighbor , 2015, MUE 2015.

[34]  Gang Wang,et al.  A novel bankruptcy prediction model based on an adaptive fuzzy k-nearest neighbor method , 2011, Knowl. Based Syst..

[35]  Gerardo Beruvides,et al.  Sensoring systems and signal analysis to monitor tool wear in microdrilling operations on a sintered tungsten–copper composite material , 2013 .