Top

Journal of Intelligent Manufacturing

Published in:

01-12-2014

A hybrid \(\text{ M}5^\prime \)-genetic programming approach for ensuring greater trustworthiness of prediction ability in modelling of FDM process

Authors: A. Garg, K. Tai, C. H. Lee, M. M. Savalani

Published in: Journal of Intelligent Manufacturing | Issue 6/2014

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Abstract

Recent years have seen various rapid prototyping (RP) processes such as fused deposition modelling (FDM) and three-dimensional printing being used for fabricating prototypes, leading to shorter product development times and less human intervention. The literature reveals that the properties of RP built parts such as surface roughness, strength, dimensional accuracy, build cost, etc are related to and can be improved by the appropriate settings of the input process parameters. Researchers have formulated physics-based models and applied empirical modelling techniques such as regression analysis and artificial neural network for the modelling of RP processes. Physics-based models require in-depth understanding of the processes which is a formidable task due to their complexity. The issue of improving trustworthiness of the prediction ability of empirical models on test (unseen) samples is paid little attention. In the present work, a hybrid M5\(^{\prime }\)-genetic programming (M5\(^{\prime }\)-GP) approach is proposed for empirical modelling of the FDM process with an attempt to resolve this issue of ensuring trustworthiness. This methodology is based on the error compensation achieved using a GP model in parallel with a M5\(^{\prime }\) model. The performance of the proposed hybrid model is compared to those of support vector regression (SVR) and adaptive neuro fuzzy inference system (ANFIS) model and it is found that the M5\(^{\prime }\)-GP model has the goodness of fit better than those of the SVR and ANFIS models.

previous article Multi-objective optimal design of small scale resistance spot welding process with principal component analysis and response surface methodology

next article Order allocation for multiple supply-demand networks within a cluster

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

inform now

Ahn, D., Kweon, J. H., Kwon, S., Song, J., & Lee, S. (2009). Representation of surface roughness in fused deposition modeling. Journal of Materials Processing Technology, 209, 5593–5600.

Aijun, L., Zhuohui, Z., Daoming, W., & Jinyong, Y. (2010). Optimization method to fabrication orientation of parts in fused deposition modeling rapid prototyping. IEEE International Conference on Mechanic Automation and Control engineering (MACE) (pp. 416–419).

Anitha, R., Arunachalam, S., & Radhakrishnan, P. (2001). Critical parameters influencing the quality of prototypes in fused deposition modelling. Journal of Materials Processing Technology, 118, 385–388.CrossRef

Azadeh, A., Saberi, M., Anvari, M., & Mohamadi, M. (2011). An integrated artificial neural network-genetic algorithm clustering ensemble for performance assessment of decision making units. Journal of Intelligent Manufacturing, 22, 229–245.CrossRef

Basak, D., Pal, S., & Patranabis, D. C. (2007). Support vector regression. Neural Information Processing-Letters and Reviews, 11, 203–224.

Baziar, M. H., Jafarian, Y., Shahnazari, H., Movhed, V., & Amin Tutunchian, M. (2011). Prediction of strain energy-based liquefaction resistance of sand-silt mixtures: An evolutionary approach. Computers & Geosciences, 37(11), 1883–1893.

Bernard, A., & Fischer, A. (2002). New trends in rapid product development. CIRP Annals-Manufacturing Technology, 51, 635–652.CrossRef

Bhattacharya, B., & Solomatine, D. (2005). Neural networks and \(\text{ M}5^\prime \) model trees in modelling water level-discharge relationship. Neurocomputing, 63, 381–396.CrossRef

Borges, C. E., Alonso, C. L., & Montana, J. L. (2010). Model selection in genetic programming. In Genetic and evolutionary computation conference (GECCO) (pp. 985–986). ACM.

Brezak, D., Majetic, D., Udiljak, T., & Kasac, J. (2012). Tool wear estimation using an analytic fuzzy classifier and support vector machines. Journal of Intelligent Manufacturing, 23, 797–809.CrossRef

Buyukbingol, E., Sisman, A., Akyildiz, M., Alparslan, F. N., & Adejare, A. (2007). Adaptive neuro-fuzzy inference system (ANFIS): A new approach to predictive modeling in QSAR applications: A study of neuro-fuzzy modeling of PCP-based NMDA receptor antagonists. Bioorganic & Medicinal Chemistry, 15, 4265–4282.CrossRef

Byun, H. S., & Lee, K. H. (2006). Determination of the optimal build direction for different rapid prototyping processes using multi-criterion decision making. Robotics and Computer-Integrated Manufacturing, 22, 69–80.

Byvatov, E., & Schneider, G. (2003). Support vector machine applications in bioinformatics. Applied Bioinformatics, 2, 67–77.

Campanelli, S., Cardano, G., Giannoccaro, R., Ludovico, A., and Bohez, E. (2007). Statistical analysis of the stereolithographic process to improve the accuracy. Computer-Aided Design, 39, 80–86.CrossRef

Carrascal, A., & Alberdi, A. (2010). Evolutionary industrial physical model generation. Hybrid Artificial Intelligence Systems, 6076, 327–334.

Casalino, G., De Filippis, L., Ludovico, A., & Tricarico, L. (2002). An investigation of rapid prototyping of sand casting molds by selective laser sintering. Journal of Laser Applications, 14, 100–106.CrossRef

Çaydas, U., & Ekici, S. (2012). Support vector machines models for surface roughness prediction in CNC turning of AISI 304 austenitic stainless steel. Journal of Intelligent Manufacturing, 23, 639–650.CrossRef

Chang, D. Y., & Huang, B. H. (2011). Studies on profile error and extruding aperture for the RP parts using the fused deposition modeling process. The International Journal of Advanced Manufacturing Technology, 53, 1027–1037.CrossRef

Chatterjee, S., & Hadi, A. S. (2006). Regression analysis by example. New York: Wiley.CrossRef

Cheng, R., Wu, X., & Zheng, J. (2010). Improving dimensional accuracy of SLS processed part using Taguchi method. Fourth International seminar on Modern cutting and Measurement engineering. Proceedings of the SPIE, 7997, 799715–799715-5.CrossRef

Chiu, S. L. (1994). Fuzzy model identification based on cluster estimation. Journal of Intelligent and Fuzzy Systems, 2, 267–278.

Choi, J. W., Quintana, R., & Wicker, R. B. (2011). Fabrication and characterization of embedded horizontal micro-channels using line-scan stereolithography. Rapid Prototyping Journal, 17, 351–361.

Dixit, P. M., & Dixit, U. S. (2008). Modeling of metal forming and machining processes: By finite element and soft computing methods. Berlin: Springer.

Duan, B., Cheung, W. L., & Wang, M. (2011). Optimized fabrication of Ca-P/PHBV nanocomposite scaffolds via selective laser sintering for bone tissue engineering. Biofabrication, 3, 015001.CrossRef

Equbal, A., Sood, A. K., & Mahapatra, S. (2011). Prediction of dimensional accuracy in fused deposition modelling: A fuzzy logic approach. International Journal of Productivity and Quality Management, 7, 22–43.CrossRef

Erginel, N. (2010). Modeling and analysis of packing properties through a fuzzy inference system. Journal of Intelligent Manufacturing, 21, 869–874.CrossRef

Etemad-Shahidi, A., & Mahjoobi, J. (2009). Comparison between \(\text{ M}5^\prime \)’ model tree and neural networks for prediction of significant wave height in Lake Superior. Ocean Engineering, 36, 1175–1181.CrossRef

Flores, J., & Graff, M. (2005). System identification using genetic programming and gene expression programming. Computer and Information Sciences-ISCIS, 3733(2005), 503–511.

Gaitonde, V. N., & Karnik, S. R. (2012). Minimizing burr size in drilling using artificial neural network (ANN)-particle swarm optimization (PSO) approach. Journal of Intelligent Manufacturing, 23, 1783–1793.CrossRef

Garg, A., & Tai, K. (2011). A hybrid genetic programming-artificial neural network approach for modeling of vibratory finishing process. In International Proceedings of Computer Science and Information Technology (IPCSIT) (vol. 18, pp. 14–19).

Garg, A., & Tai, K. (2012a). Comparison of regression analysis, artificial neural network and genetic programming in handling the multicollinearity problem. In Proceedings of 2012 international conference on modelling, identification & control (ICMIC 2012), Wuhan, China, 24–26 June 2012 (pp. 353–358), IEEE.

Garg, A., & Tai, K. (2012b). Review of genetic programming in modeling of machining processes. In Proceedings of 2012 international conference on modelling, identification & control (ICMIC 2012), Wuhan, China, 24–26 June 2012 (pp. 653–658). IEEE.

Gologlu, C., & Arslan, Y. (2009). Zigzag machining surface roughness modelling using evolutionary approach. Journal of Intelligent Manufacturing, 20, 203–210.CrossRef

Gunn, S. R. (1998). Support vector machines for classification and regression. ISIS technical report, 14.

Gupta, A. K. (2008). Predictive modelling of turning operations using response surface methodology, artificial neural networks and support vector regression. International Journal of Production Research, 48, 763–778.CrossRef

Hearst, M. A., Dumais, S., Osman, E., Platt, J., & Scholkopf, B. (1998). Support vector machines. IEEE Intelligent Systems and Their Applications, 13, 18–28.CrossRef

Hiden, H.G. (1998). Data-based modelling using genetic programming. PhD Thesis, Dept. Chemical and Process Engineering, University of Newcastle, UK.

Hinchliffe, M., Hiden, H., Mckay, B., Willis, M., Tham, M., & Barton, G. (1996). Modelling chemical process systems using a multi-gene genetic programming algorithm (pp. 28–31). Late breaking paper, GP’96. Stanford.

Hopkinson, N., Hague, R., & Dickens, P. (2006). Rapid manufacturing. New York: Wiley.

Iba, H., & Sasaki, T. (1996). Using genetic programming to predict financial data. In IEEE Proceedings of congress on evolutionary computation (CEC) (vol. 1, pp. 244–251).

Jang, J. S. R. (1993). ANFIS: Adaptive-network-based fuzzy inference system. IEEE Trans. Syst., Man, and Cyber, 23, 665–685.

Jeguirim, S. E. G., Dhouib, A. B., Sahnoun, M., Cheikhrouhou, M., Schacher, L., & Adolphe, D. (2011). The use of fuzzy logic and neural networks models for sensory properties prediction from process and structure parameters of knitted fabrics. Journal of Intelligent Manufacturing, 22, 873–884.CrossRef

Katherasan, D., Elias, J. V., Sathiya, P., & Haq, A. N. (2012). Simulation and parameter optimization of flux cored arc welding using artificial neural network and particle swarm optimization algorithm. Journal of Intelligent Manufacturing, 23, 1–10.CrossRef

Kecman, V. (2001). Learning and soft computing: Support vector machines, neural networks, and fuzzy logic models. Cambridge, MA: MIT press.

Kennard, R. W., & Stone, L. A. (1969). Computer aided design of experiments. Technometrics, 11, 137–148.CrossRef

Kotanchek, M., Smits, G., & Vladislaveva, E. (2008). Trustable symbolic regression models: using ensembles, interval arithmetic and pareto fronts to develop robust and trust-aware models. Genetic Programming Theory and Practice, V, 201–220.

Kovacic, M., Balic, J., & Brezocnik, M. (2004). Evolutionary approach for cutting forces prediction in milling. Journal of Materials Processing Technology, 155, 1647–1652.CrossRef

Kovacic, M., & Brezocnik, M. (2003). Genetic programming approach for surface quality prediction. Tehnicki Vjesnik, 10, 19–24.

Koza, J. R. (1994). Genetic programming II: Automatic discovery of reusable programs.

Kroh, M., Bonten, C., & Eyerer, P. (2011). Effects of process parameters on additive assisted laser sintering of polyetheretherketone. In Soceity of plastic engineers (SPE) annual technical conference (vol. 2, pp. 1806–1811).

Kruth, J. P., & Kumar, S. (2005). Statistical analysis of experimental parameters in selective laser sintering. Advanced Engineering Materials, 7, 750–755.CrossRef

Kumagai, A., Liu, T. I., & Hozian, P. (2006). Control of shape memory alloy actuators with a neuro-fuzzy feedforward model element. Journal of Intelligent Manufacturing, 17, 45–56.CrossRef

Kumar, G. P., & Regalla, S. P. (2012). Optimization of support material and build time in fused deposition modeling (FDM). Applied Mechanics and Materials, 110, 2245–2251.

Kuschu, I. (2002). Genetic programming and evolutionary generalization. Evolutionary Computation, IEEE Transactions on, 6, 431–442.

Laeng, J., Khan, Z. A., & Khu, S. (2006). Optimizing flexible behaviour of bow prototype using Taguchi approach. Journal of Applied Sciences, 6, 622–630.CrossRef

Lee, S., Park, W., Cho, H., Zhang, W., & Leu, M. (2001). A neural network approach to the modelling and analysis of stereolithography processes. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 215, 1719–1733.CrossRef

Li, C. L., Fu, G. Y., & Guo, K. B. (2011). Study on forecast of forming temperature of ABS resign during fused deposition manufacturing by fuzzy comprehensive evaluation. Key Engineering Materials, 464, 264–267.CrossRef

Li, T. S., Huang, C. L., & Wu, Z. Y. (2006). Data mining using genetic programming for construction of a semiconductor manufacturing yield rate prediction system. Journal of Intelligent Manufacturing, 17, 355–361.CrossRef

Liu, W., Liu, Q., Ruan, F., Liang, Z., & Qiu, H. (2007). Springback prediction for sheet metal forming based on GA-ANN technology. Journal of Materials Processing Technology, 187, 227–231.CrossRef

Mahesh, M., Fuh, J., Wong, Y., & Loh, H. (2005). Benchmarking for decision making in rapid prototyping systems. In IEEE International Conference on Automation Science and, Engineering (pp. 19–24).

Mansour, S., & Hague, R. (2003). Impact of rapid manufacturing on design for manufacture for injection moulding. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 217, 453–461.CrossRef

May, R., Maier, H. R., & Dandy, G. C. (2010). Data splitting for artificial neural networks using SOM-based stratified sampling. Neural Networks, 23, 283–294.CrossRef

Monzon, M., Hernandez, P. M., Benitez, A. N., Marrero, M. D., & Fernandez, Á. (2009). Predictability of plastic parts behaviour made from rapid manufacturing. Tsinghua Science & Technology, 14, 100–107.CrossRef

Munguia, J., Ciurana, J., & Riba, C. (2009). Neural-network-based model for build-time estimation in selective laser sintering. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 223, 995–1002.CrossRef

Pandey, P. M., Venkata Reddy, N., & Dhande, S. G. (2003). Improvement of surface finish by staircase machining in fused deposition modeling. Journal of materials processing technology, 132, 323–331.CrossRef

Park, T. C., Kim, U. S., Kim, L. H., Jo, B. W., & Yeo, Y. K. (2010). Heat consumption forecasting using partial least squares, artificial neural network and support vector regression techniques in district heating systems. Korean Journal of Chemical Engineering, 27, 1063–1071.CrossRef

Pearson, R. K., & Pottmann, M. (2000). Gray-box identification of block-oriented nonlinear models. Journal of Process Control, 10, 301–315.CrossRef

Pelckmans, K., Suykens, J. A. K., Vangestel, T., DE Brabanter, J., Lukas, L., Hamers, B., et al. (2002). LS-SVMlab: A matlab/c toolbox for least squares support vector machines. Tutorial. Leuven: KULeuven-ESAT.

Pham, D., & Gault, R. (1998). A comparison of rapid prototyping technologies. International Journal of Machine Tools and Manufacture, 38, 1257–1287.CrossRef

Quinlan, J. R. (1992). Learning with continuous classes. In Proceedings of the fifth Australian joint conference on artificial intelligence (pp. 343–348). Singapore: World Scientific.

Quintana, R., Choi, J. W., Puebla, K., & Wicker, R. (2010). Effects of build orientation on tensile strength for stereolithography-manufactured ASTM D-638 type I specimens. The International Journal of Advanced Manufacturing Technology, 46, 201–215.CrossRef

Reddy, T., Kumar, Y. R., & Rao, C. (2006). Determination of optimum process parameters using Taguchi’s approach to improve the quality of SLS parts. In Proceedings of the 17th IASTED international conference on Modelling and simulation. ACTA Press (pp. 228–233).

Rowland, J. (2003). Model selection methodology in supervised learning with evolutionary computation. Biosystems, 72, 187–196.CrossRef

Salgado, D., & Alonso, F. (2007). An approach based on current and sound signals for in-process tool wear monitoring. International Journal of Machine Tools and Manufacture, 47, 2140–2152.CrossRef

Salgado, D., Alonso, F., Cambero, I., & Marcelo, A. (2009). In-process surface roughness prediction system using cutting vibrations in turning. The International Journal of Advanced Manufacturing Technology, 43, 40–51.CrossRef

Saptoro, A., Tade, M. O., & Vuthaluru, H. (2012). A modified Kennard-stone algorithm for optimal division of data for developing artificial neural network models. Chemical Product and Process Modeling, 7, 13.CrossRef

Searson, D. P., Leahy, D. E., & Willis, M. J. (2010). GPTIPS: An open source genetic programming toolbox for multigene symbolic regression. In International multiconference of engineers and computer scientists 2010 (vol. 1, pp. 77–80).

Sharma, V. S., Sharma, S. K., & Sharma, A. K. (2008). Cutting tool wear estimation for turning. Journal of Intelligent Manufacturing, 19, 99–108.CrossRef

Shen, X., Yao, J., Wang, Y., & Yang, J. (2004). Density prediction of selective laser sintering parts based on artificial neural network. In Advances in neural networks-ISNN 2004 (vol. 3174/2004, pp. 153–165).

Solomatine, D. P., & Siek, M. (2004). Flexible and optimal M5 model trees with applications to flow predictions. In Liong, Phoon, & Babovic (Eds.), Proceedings of the sixth international conference on hydroinformatics. Singapore: World Scientific.

Solomatine, D. P., & Xue, Y. (2004). M5 model trees and neural networks: Application to flood forecasting in the upper reach of the Huai River in China. Journal of Hydrologic Engineering, 9, 491– 501.

Sood, A., Ohdar, R., & Mahapatra, S. (2010a). A hybrid ANN-BFOA approach for optimization of FDM process parameters. Swarm, Evolutionary, and Memetic Computing, 6466, 396–403.CrossRef

Sood, A., Ohdar, R., & Mahapatra, S. (2010b). Parametric appraisal of fused deposition modelling process using the grey Taguchi method. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 224, 135–145.CrossRef

Sood, A. K., Equbal, A., Toppo, V., Ohdar, R., & Mahapatra, S. (2011a). An investigation on sliding wear of FDM built parts. CIRP Journal of Manufacturing Science and Technology, 1, 48–54.

Sood, A. K., Ohdar, R., & Mahapatra, S. (2009). Improving dimensional accuracy of fused deposition modelling processed part using grey Taguchi method. Materials & Design, 30, 4243–4252.CrossRef

Sood, A. K., Ohdar, R. K., & Mahapatra, S. S. (2011b). Experimental investigation and empirical modelling of FDM process for compressive strength improvement. Journal of Advanced Research, 3, 81–90.CrossRef

Takagi, T., & Sugeno, M. (1985). Fuzzy identification of system and its applications to modelling and control. IEEE Trans. Syst., Man, and Cyber, 15, 116–132.CrossRef

Thrimurthuli, K., Pandey, P. M., & Venkata Reddy, N. (2004). Optimum part deposition orientation in fused deposition modeling. International Journal of Machine Tools and Manufacture, 44, 585–594.CrossRef

Upcraft, S., & Fletcher, R. (2003). The rapid prototyping technologies. Assembly Automation, 23, 318–330.CrossRef

Vapnik, V. (1995). The nature of statistical learning. New York: Springer.

Vosniakos, G., Maroulis, T., & Pantelis, D. (2007). A method for optimizing process parameters in layer-based rapid prototyping. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 221, 1329–1340.

Wang, G., Wang, Y., Zhao, J., & Chen, G. (2012). Process optimization of the serial-parallel hybrid polishing machine tool based on artificial neural network and genetic algorithm. Journal of Intelligent Manufacturing, 23, 365–374.

Wang, R. J., Li, J., Wang, F., & Li, X. (2009). ANN model for the prediction of density in selective laser sintering. International Journal of Manufacturing Research, 4, 362–373.CrossRef

Wang, W., Cheah, C., Fuh, J., & Lu, L. (1996). Influence of process parameters on stereolithography part shrinkage. Materials & Design, 17, 205–213.CrossRef

Wang, Y., & Witten, I. H. (1996). Induction of model trees for predicting continuous classes (Working paper 96/23). Hamilton, New Zealand: University of Waikato, Department of Computer Science

Wiedemann, B., & Jantzen, H. A. (1999). Strategies and applications for rapid product and process development in Daimler-Benz AG. Computers in Industry, 39, 11–25.CrossRef

Willis, M., Hiden, H., Hinchliffe, M., Mckay, B., & Barton, G. W. (1997). Systems modelling using genetic programming. Computers & Chemical Engineering, 21, S1161–S1166.CrossRef

Witten, I. H., & Frank, E. (2005). Data mining: Practical machine learning tools and techniques (2nd ed.). Burlington, MA: Morgan Kaufmann.

Yan, X., & Gu, P. (1996). A review of rapid prototyping technologies and systems. Computer-Aided Design, 28, 307–318.CrossRef

Zadeh, L. A. (1994). Fuzzy logic, neural networks, and soft computing. Communications of the ACM, 37, 77–84.CrossRef

Zhang, Y., & Bhattacharyya, S. (2004). Genetic programming in classifying large-scale data: An ensemble method. Information Sciences, 163, 85–101.CrossRef

Title: A hybrid -genetic programming approach for ensuring greater trustworthiness of prediction ability in modelling of FDM process
Authors: A. Garg
K. Tai
C. H. Lee
M. M. Savalani
Publication date: 01-12-2014
Publisher: Springer US
Published in: Journal of Intelligent Manufacturing / Issue 6/2014
Print ISSN: 0956-5515
Electronic ISSN: 1572-8145
DOI: https://doi.org/10.1007/s10845-013-0734-1

Springer Professional

Abstract

Please log in to get access to your license.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Other articles of this Issue 6/2014

Intelligent modelling of back-side weld bead geometry using weld pool surface characteristic parameters

Knowledge-based systems using neural networks for electron beam welding process of reactive material (Zircaloy-4)

Native metaheuristics for non-permutation flowshop scheduling

Multi-objective optimal design of small scale resistance spot welding process with principal component analysis and response surface methodology

Scheduling a single mobile robot for part-feeding tasks of production lines

Clustering and group selection of interim product in shipbuilding

Premium Partners