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Fusion: Practice and Applications
Volume 13 , Issue 1, PP: 37-48 , 2023 | Cite this article as | XML | Html |PDF

Title

Regression Analysis and Artificial Neural Network Approach to Predict of Surface Roughness in Milling Process

  Zaineb Hameed Neamah 1 * ,   Ahmad Al-Talabi 2 ,   Asma A. Mohammed Ali 3

1  Alshaab University, Department of Medical Instrumentation Techniques Engineering, Iraq
    (zaineb.hameed@alshaab.edu.iq)

2  Alshaab University, Department of Medical Instrumentation Techniques Engineering, Iraq
    (Ahmad.Altalabi@alshaab.edu.iq)

3  Ministry of Electricity, Baghdad, Iraq
    (asmaa.albayati92@gmail.com)

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Doi   :   https://doi.org/10.54216/FPA.130103

Received: March 11, 2023 Revised: June 07, 2023 Accepted: August 09, 2023

Abstract :

Surface roughness (Ra) has a significant influence on the fatigue strength, corrosion resistance, and aesthetic appeal of machine components. Ra is hence a crucial manufacturing process parameter. This study predicts Ra of aluminum alloy Al-7024 after milling. Regression analysis and artificial neural network (ANN) modeling approaches are suggested for predicting Ra values. For better surface roughness, the cutting parameter must be set properly. Spindle speed, feed rate, and depth of cut have been chosen as predictors. Through 31 study cases, regression and ANN were used to examine how these parameters affected Ra. The measurement of surface roughness, together with comprehensive Ra analysis and regression analysis. The findings of this investigation indicate that Ra was predicted by both the regression and ANN models. convergent results from model predictions are obtained. This convergence highlights the promising methodology used in this work to forecast Ra in the milling of Al-7024. The findings demonstrated that, in comparison to the regression model, which had an average variation from the actual values of roughly 1%, The surface roughness was accurately predicted by the ANN model.

Keywords :

Prediction; Surface Roughness , Milling; Artificial Neural Networks and Regression Analysis.

References :

[1] Dijmărescu, Manuela-Roxana, et al. "Surface Roughness Analysis and Prediction with an Artificial Neural Network Model for Dry Milling of Co–Cr Biomedical Alloys." Materials 14.21 (2021): 6361.

[2] Yang, Dayong, et al. "Surface Roughness Prediction and Optimization in the Orthogonal Cutting of Graphite/Polymer Composites Based on Artificial Neural Network." Processes 9.10 (2021): 1858.

[3] Kosarac, Aleksandar, et al. "Neural-Network-Based Approaches for Optimization of Machining Parameters Using Small Dataset." Materials 15.3 (2022): 700.

[4] Hussein, Hiba K., Israa R. Shareef, and Iman A. Zayer. "Mathematical Modelling of Engineering Problems." Journal homepage: http://iieta. org/journals/mmep 9.1 (2022): 186-193.

[5] Rizvi, Saadat Ali, and Wajahat Ali. "An artificial neural network approach to prediction of surface roughness and material removal rate in CNC turning of C40 steel." International Journal of Industrial Engineering & Production Research 32.3 (2021): 1-10.

[6] Parmar, Jignesh G., and Alpesh Makwana. "Prediction of surface roughness for end milling process using Artificial Neural Network." International Journal of Modern Engineering Research (IJMER) 2.3 (2012): 1006-1013.

[7] Lin, Yung-Chih, et al. "Prediction of surface roughness based on cutting parameters and machining vibration in end milling using regression method and artificial neural network." Applied Sciences 10.11 (2020): 3941.

[8] Chen, Cheng-Hung, Shiou-Yun Jeng, and Cheng-Jian Lin. "Prediction and analysis of the surface roughness in CNC end milling using neural networks." Applied Sciences 12.1 (2021): 393.

[9] Acayaba, G.M.A., de Escalona, P.M. (2015). Prediction of surface roughness in low speed turning of AISI316 austenitic stainless steel. CIRP Journal of Manufacturing Science and Technology, 11: 62-67. https://doi.org/10.1016/j.cirpj.2015.08.004

[10] Ahmad, N.; Janahiraman, T.V.; Tarlochan, F. Modeling of Surface Roughness in Turning Operation Using Extreme Learning Machine. Arab. J. Sci. Eng. 2015, 40, 595–602. [CrossRef]

[11] 21. Zerti, A.; Yallese, M.A.; Zerti, O.; Nouioua, M.; Khettabi, R. Prediction of Mechanical Engineers. Part C J. Mech. Eng. Sci. 2019, 233,4439–4462. [CrossRef].

[12] Thangarasu, S.S.; Mohanraj, T.; Devendran, K. Tool wear prediction in hard turning of EN8 steel using cutting force and surface roughness with artificial neural network. Proc. Inst. Mech. Eng. Part C J. Mech. Eng. Sci. 2019, 234, 329–342.

[13] Srinivasan, D., et al. "Investigation of surface roughness and material removal rate of WEDM of SS304 using ANOVA and regression models." Surface Topography: Metrology and Properties 10.2 (2022): 025014.

[14] Tam, Vivian WY, et al. "A prediction model for compressive strength of CO2 concrete using regression analysis and artificial neural networks." Construction and Building Materials 324 (2022): 126689.

[15] Mouloodi, Saeed, et al. "Feedforward backpropagation artificial neural networks for predicting mechanical responses in complex nonlinear structures: A study on a long bone." Journal of the Mechanical Behavior of Biomedical Materials 128 (2022): 105079.

[16] Nadweh, R., " On The Fusion of Neural Networks and Fuzzy Logic, Membership Functions and Weights", Galoitica Journal of Mathematical Structures and Applications, Vol 7, 2023.

[17] Charchekhandra, B., " The Reading and Analyzing of The Brain Electrical Signals to Execute a Control Command and Move an Automatic Arm", Pure Mathematics for Theoretical Computer Science, Vol 1, 2023.

[18] Al Basheer, O., " On Some Novel Simplex Linear Codes Defined Over the Algebraic Ring F2+vF2 ", Neoma Journal of Mathematics and Computer Science, 2023.

Cite this Article as :
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MLA Zaineb Hameed Neamah, Ahmad Al-Talabi, Asma A. Mohammed Ali. "Regression Analysis and Artificial Neural Network Approach to Predict of Surface Roughness in Milling Process." Fusion: Practice and Applications, Vol. 13, No. 1, 2023 ,PP. 37-48 (Doi   :  https://doi.org/10.54216/FPA.130103)
APA Zaineb Hameed Neamah, Ahmad Al-Talabi, Asma A. Mohammed Ali. (2023). Regression Analysis and Artificial Neural Network Approach to Predict of Surface Roughness in Milling Process. Journal of Fusion: Practice and Applications, 13 ( 1 ), 37-48 (Doi   :  https://doi.org/10.54216/FPA.130103)
Chicago Zaineb Hameed Neamah, Ahmad Al-Talabi, Asma A. Mohammed Ali. "Regression Analysis and Artificial Neural Network Approach to Predict of Surface Roughness in Milling Process." Journal of Fusion: Practice and Applications, 13 no. 1 (2023): 37-48 (Doi   :  https://doi.org/10.54216/FPA.130103)
Harvard Zaineb Hameed Neamah, Ahmad Al-Talabi, Asma A. Mohammed Ali. (2023). Regression Analysis and Artificial Neural Network Approach to Predict of Surface Roughness in Milling Process. Journal of Fusion: Practice and Applications, 13 ( 1 ), 37-48 (Doi   :  https://doi.org/10.54216/FPA.130103)
Vancouver Zaineb Hameed Neamah, Ahmad Al-Talabi, Asma A. Mohammed Ali. Regression Analysis and Artificial Neural Network Approach to Predict of Surface Roughness in Milling Process. Journal of Fusion: Practice and Applications, (2023); 13 ( 1 ): 37-48 (Doi   :  https://doi.org/10.54216/FPA.130103)
IEEE Zaineb Hameed Neamah, Ahmad Al-Talabi, Asma A. Mohammed Ali, Regression Analysis and Artificial Neural Network Approach to Predict of Surface Roughness in Milling Process, Journal of Fusion: Practice and Applications, Vol. 13 , No. 1 , (2023) : 37-48 (Doi   :  https://doi.org/10.54216/FPA.130103)