Prediction of surface roughness when end milling Ti6Al4V alloy using adaptive neurofuzzy inference system

Research output: Contribution to journalArticle

Abstract

Surface roughness is considered as the quality index of the machine parts. Many diverse techniques have been applied in modelling metal cutting processes. Previous studies have revealed that artificial intelligence techniques are novel soft computing methods which fit the solution of nonlinear and complex problems like metal cutting processes. The present study used adaptive neurofuzzy inference system for the purpose of predicting the surface roughness when end milling Ti6Al4V alloy with coated (PVD) and uncoated cutting tools under dry cutting conditions. Real experimental results have been used for training and testing of ANFIS models, and the best model was selected based on minimum root mean square error. A generalized bell-shaped function has been adopted as a membership function for the modelling process, and its numbers were changed from 2 to 5. The findings provided evidence of the capability of ANFIS in modelling surface roughness in end milling process and obtainment of good matching between experimental and predicted results.

Original languageEnglish
Article number932094
JournalModelling and Simulation in Engineering
Volume2013
DOIs
Publication statusPublished - 2013

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Adaptive Neuro-fuzzy Inference System
Surface Roughness
Metal cutting
Surface roughness
Prediction
Metals
Computing Methods
Soft computing
Machine components
Soft Computing
Physical vapor deposition
Cutting tools
Membership functions
Process Modeling
Membership Function
Modeling
Mean square error
Artificial intelligence
Artificial Intelligence
Roots

ASJC Scopus subject areas

  • Computer Science Applications
  • Modelling and Simulation
  • Engineering(all)

Cite this

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title = "Prediction of surface roughness when end milling Ti6Al4V alloy using adaptive neurofuzzy inference system",
abstract = "Surface roughness is considered as the quality index of the machine parts. Many diverse techniques have been applied in modelling metal cutting processes. Previous studies have revealed that artificial intelligence techniques are novel soft computing methods which fit the solution of nonlinear and complex problems like metal cutting processes. The present study used adaptive neurofuzzy inference system for the purpose of predicting the surface roughness when end milling Ti6Al4V alloy with coated (PVD) and uncoated cutting tools under dry cutting conditions. Real experimental results have been used for training and testing of ANFIS models, and the best model was selected based on minimum root mean square error. A generalized bell-shaped function has been adopted as a membership function for the modelling process, and its numbers were changed from 2 to 5. The findings provided evidence of the capability of ANFIS in modelling surface roughness in end milling process and obtainment of good matching between experimental and predicted results.",
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language = "English",
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journal = "Modelling and Simulation in Engineering",
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