2019
Juez-Gil, Mario; Erdakov, Ivan Nikolaevich; Bustillo, Andrés; Pimenov, Danil Yurievich
A regression-tree multilayer-perceptron hybrid strategy for the prediction of ore crushing-plate lifetimes Journal Article
In: Journal of Advanced Research, vol. July 2019, no. 18, pp. 173-184, 2019, ISSN: 2090-1232.
Abstract | Links | BibTeX | Tags: Artificial intelligence, Hadfield steel, Lifetime prediction, Multi-layer perceptrons, Regression trees, Resource savings
@article{Juez-Gil2019,
title = {A regression-tree multilayer-perceptron hybrid strategy for the prediction of ore crushing-plate lifetimes},
author = {Mario Juez-Gil and Ivan Nikolaevich Erdakov and Andrés Bustillo and Danil Yurievich Pimenov},
doi = {10.1016/j.jare.2019.03.008},
issn = {2090-1232},
year = {2019},
date = {2019-07-01},
journal = {Journal of Advanced Research},
volume = {July 2019},
number = {18},
pages = {173-184},
abstract = {Highly tensile manganese steel is in great demand owing to its high tensile strength under shock loads. All workpieces are produced through casting, because it is highly difficult to machine. The probabilistic aspects of its casting, its variable composition, and the different casting techniques must all be considered for the optimisation of its mechanical properties. A hybrid strategy is therefore proposed which combines decision trees and artificial neural networks (ANNs) for accurate and reliable prediction models for ore crushing plate lifetimes. The strategic blend of these two high-accuracy prediction models is used to generate simple decision trees which can reveal the main dataset features, thereby facilitating decision-making. Following a complexity analysis of a dataset with 450 different plates, the best model consisted of 9 different multilayer perceptrons, the inputs of which were only the Fe and Mn plate compositions. The model recorded a low root mean square error (RMSE) of only 0.0614 h for the lifetime of the plate: a very accurate result considering their varied lifetimes of between 746 and 6902 h in the dataset. Finally, the use of these models under real industrial conditions is presented in a heat map, namely a 2D representation of the main manufacturing process inputs with a colour scale which shows the predicted output, i.e. the expected lifetime of the manufactured plates. Thus, the hybrid strategy extracts core training dataset information in high-accuracy prediction models. This novel strategy merges the different capabilities of two families of machine-learning algorithms. It provides a high-accuracy industrial tool for the prediction of the full lifetime of highly tensile manganese steel plates. The results yielded a precision prediction of (RMSE of 0.061 h) for the full lifetime of (light, medium, and heavy) crusher plates manufactured with the three (experimental, classic, and highly efficient (new)) casting methods.},
keywords = {Artificial intelligence, Hadfield steel, Lifetime prediction, Multi-layer perceptrons, Regression trees, Resource savings},
pubstate = {published},
tppubtype = {article}
}
2018
Oleaga, Ibone; Pardo, Carlos; Zulaika, Juan J; Bustillo, Andres
A machine-learning based solution for chatter prediction in heavy-duty milling machines Journal Article
In: Measurement, vol. 128, pp. 34 - 44, 2018, ISSN: 0263-2241.
Abstract | Links | BibTeX | Tags: Chatter, Milling, Polar diagrams, Random forest, Regression trees, Vibrations
@article{OLEAGA201834,
title = {A machine-learning based solution for chatter prediction in heavy-duty milling machines},
author = {Ibone Oleaga and Carlos Pardo and Juan J Zulaika and Andres Bustillo},
url = {http://www.sciencedirect.com/science/article/pii/S0263224118305542},
doi = {https://doi.org/10.1016/j.measurement.2018.06.028},
issn = {0263-2241},
year = {2018},
date = {2018-11-01},
journal = {Measurement},
volume = {128},
pages = {34 - 44},
abstract = {The main productivity constraints of milling operations are self-induced vibrations, especially regenerative chatter vibrations. Two key parameters are linked to these vibrations: the depth of cut achievable without vibrations and the chatter frequency. Both parameters are linked to the dynamics of machine component excitation and the milling operation parameters. Their identification in any cutting direction in milling machine operations requires complex analytical models and mechatronic simulations, usually only applied to identify the worst cutting conditions in operating machines. This work proposes the use of machine learning techniques with no need to calculate the two above-mentioned parameters by means of a 3-step strategy. The strategy combines: 1) experimental frequency responses collected at the tool center point; 2) analytical calculations of both parameters; and, 3) different machine learning techniques. The results of these calculations can then be used to predict chatter under different combinations of milling directions and machine positions. This strategy is validated with real experiments on a bridge milling machine performing concordance roughing operations on AISI 1045 steel with a 125 mm diameter mill fitted with nine cutters at 45°, the results of which have confirmed the high variability of both parameters along the working volume. The following regression techniques are tested: artificial neural networks, regression trees and Random Forest. The results show that Random Forest ensembles provided the highest accuracy with a statistical advantage over the other machine learning models; they achieved a final accuracy of 0.95 mm for the critical depth and 7.3 Hz for the chatter frequency (RMSE) in the whole working volume and in all feed directions, applying a 10 × 10 cross validation scheme. These RMSE values are acceptable from the industrial point of view, taking into account that the critical depth of this range varies between 0.68 mm and 19.20 mm and the chatter frequency between 1.14 Hz and 65.25 Hz. Besides, Random Forest ensembles are more easily optimized than artificial neural networks (1 parameter configuration versus 210 MLPs). Additionally, tools that incorporate regression trees are interesting and highly accurate, providing immediately accessible and useful information in visual formats on critical machine performance for the design engineer.},
keywords = {Chatter, Milling, Polar diagrams, Random forest, Regression trees, Vibrations},
pubstate = {published},
tppubtype = {article}
}
2017
Maudes, Jesus; Bustillo, Andrés; Guerra, Antonio J; Ciurana, Joaquim
Random Forest ensemble prediction of stent dimensions in microfabrication processes Journal Article
In: The International Journal of Advanced Manufacturing Technology, vol. 91, no. 1, pp. 879–893, 2017, ISSN: 1433-3015.
Abstract | Links | BibTeX | Tags: Data Mining, Ensembles of regressors, Random forest, Regression trees, Stents Laser machining
@article{Maudes2017,
title = {Random Forest ensemble prediction of stent dimensions in microfabrication processes},
author = {Jesus Maudes and Andrés Bustillo and Antonio J Guerra and Joaquim Ciurana},
url = {https://doi.org/10.1007/s00170-016-9695-9},
doi = {10.1007/s00170-016-9695-9},
issn = {1433-3015},
year = {2017},
date = {2017-07-01},
journal = {The International Journal of Advanced Manufacturing Technology},
volume = {91},
number = {1},
pages = {879–893},
abstract = {The recent development of new laser machine tools for the manufacture of micro-scale metallic components has boosted demand in the field of medical applications. However, the optimization of this process encounters a major problem: a knowledge gap concerning the relation between the controllable parameters of these machine tools and the quality of the machined components. Our research proposes a two-step strategy to approach this problem for the manufacture of stents. First, a screening test identifies good and bad performance conditions for the laser process and generates useful information on cutting performance; then, a stent is manufactured under different cutting conditions and the most accurate machine learning technique to model this process is identified. This strategy is validated with the performance of experiments that vary pulse duration, laser power, and cutting speed, and measure two geometrical characteristics of the stent geometry. The results showed that linear Support Vector Machines can identify good and bad cutting conditions, while Random Forest ensembles of regression trees can predict with high accuracy the two characteristics of the stent geometry under study. Besides, this technique can extract useful information from the screening test that improves its final accuracy. In view of the small dataset size, an alternative based on the leave-one-out technique was used, instead of standard cross validation, so as to assure the generalization capability of the models.},
keywords = {Data Mining, Ensembles of regressors, Random forest, Regression trees, Stents Laser machining},
pubstate = {published},
tppubtype = {article}
}
2016
Bustillo, Andres; Lacalle, Luis López N; Fernández-Valdivielso, Asier; Santos, Pedro
Data-mining modeling for the prediction of wear on forming-taps in the threading of steel components Journal Article
In: Journal of Computational Design and Engineering, vol. 3, no. 4, pp. 337 - 348, 2016, ISSN: 2288-4300.
Abstract | Links | BibTeX | Tags: Ensembles, Forming taps, Regression trees, Roll taps, Roll-tap wear, Rotation forest, Threading
@article{BUSTILLO2016337,
title = {Data-mining modeling for the prediction of wear on forming-taps in the threading of steel components},
author = {Andres Bustillo and Luis López N Lacalle and Asier Fernández-Valdivielso and Pedro Santos},
url = {http://www.sciencedirect.com/science/article/pii/S2288430016300306},
doi = {https://doi.org/10.1016/j.jcde.2016.06.002},
issn = {2288-4300},
year = {2016},
date = {2016-10-01},
journal = {Journal of Computational Design and Engineering},
volume = {3},
number = {4},
pages = {337 - 348},
abstract = {An experimental approach is presented for the measurement of wear that is common in the threading of cold-forged steel. In this work, the first objective is to measure wear on various types of roll taps manufactured to tapping holes in microalloyed HR45 steel. Different geometries and levels of wear are tested and measured. Taking their geometry as the critical factor, the types of forming tap with the least wear and the best performance are identified. Abrasive wear was observed on the forming lobes. A higher number of lobes in the chamber zone and around the nominal diameter meant a more uniform load distribution and a more gradual forming process. A second objective is to identify the most accurate data-mining technique for the prediction of form-tap wear. Different data-mining techniques are tested to select the most accurate one: from standard versions such as Multilayer Perceptrons, Support Vector Machines and Regression Trees to the most recent ones such as Rotation Forest ensembles and Iterated Bagging ensembles. The best results were obtained with ensembles of Rotation Forest with unpruned Regression Trees as base regressors that reduced the RMS error of the best-tested baseline technique for the lower length output by 33%, and Additive Regression with unpruned M5P as base regressors that reduced the RMS errors of the linear fit for the upper and total lengths by 25% and 39%, respectively. However, the lower length was statistically more difficult to model in Additive Regression than in Rotation Forest. Rotation Forest with unpruned Regression Trees as base regressors therefore appeared to be the most suitable regressor for the modeling of this industrial problem.},
keywords = {Ensembles, Forming taps, Regression trees, Roll taps, Roll-tap wear, Rotation forest, Threading},
pubstate = {published},
tppubtype = {article}
}