Predicting thrust of aircraft using artificial neural networks

Purpose The purpose of this study is to make artificial neural network (ANN)-based prediction about thrust using the flight control parameters of aircrafts. Design/methodology/approach In today’s transportation, airplanes have an important place because of their safety, quality and speed. One of the...

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Published in	Aircraft engineering Vol. 93; no. 1; pp. 35 - 41
Main Authors	Yildirim Dalkiran, Fatma, Toraman, Mustafa
Format	Journal Article
Language	English
Published	Bradford Emerald Publishing Limited 16.02.2021 Emerald Group Publishing Limited
Subjects	Aircraft Aircraft engines Algorithms Altitude Ambient temperature Artificial neural networks Automobiles Aviation Back propagation networks Datasets Design parameters Energy consumption Flight control Flight data recorders Flight safety Gas turbine engines Gases Mathematical models Methods Multilayers Neural networks Optimization Propagation velocity Sea level Thrust Transportation safety Unmanned aerial vehicles ANN Flight control parameters Thrust Prediction
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ISSN	1748-8842 1758-4213
DOI	10.1108/AEAT-05-2020-0089

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Abstract	Purpose The purpose of this study is to make artificial neural network (ANN)-based prediction about thrust using the flight control parameters of aircrafts. Design/methodology/approach In today’s transportation, airplanes have an important place because of their safety, quality and speed. One of the most important parameters affecting the secure flying of aircrafts is the thrust value of aircraft engines. Determining the optimum thrust value should be investigated. If thrust value is less than optimum level, the flight safety runs a risk. Otherwise, fuel consumption goes high and some unwanted vibrations occur that cause uncomfortable flight. In this study, multi-layer perceptron ANNs, which are one of the intelligent optimization methods and frequently used in the literature, are preferred to predict the optimum thrust value during take-off, cruise and landing. The actual flight data, which is taken from the black box of an Airbus A319 aircraft, is used to train ANN models using back propagation algorithms. Velocity, altitude and ambient temperature values of the aircraft are selected as inputs and the thrust value is selected as output. During the training process of ANN, eight different training algorithms with different structures are used to figure out optimum ANN model with minimum error. Findings Different ANN models were trained using eight different training algorithms. The ANN model with minimum error has multi-layer perceptron structure, which is trained using Levenberg–Marquardt (LM) algorithm. Research limitations/implications To obtain the ANN structure with minimum error training, process takes more than a day depending on the capacity of a computer for LM training algorithm. But after training process, the trained ANN model produces sufficient output in a few milliseconds. Practical implications Totally 15,670 input-output data sets are obtained from an Airbus A319 aircraft. 12,889 of them are used as training data and the rest of the data sets, selected randomly are used as test data. Test data sets are never used in training phase, and the obtained results show that the ANN model successfully predicts thrust value using unseen input data. Social implications The ANN could be used as an alternative method to predict other flight control parameters of aircrafts. Originality/value To the best of authors’ knowledge, this study is the first example in literature to predict the thrust value of the aircraft using ANN.
AbstractList	Purpose The purpose of this study is to make artificial neural network (ANN)-based prediction about thrust using the flight control parameters of aircrafts. Design/methodology/approach In today’s transportation, airplanes have an important place because of their safety, quality and speed. One of the most important parameters affecting the secure flying of aircrafts is the thrust value of aircraft engines. Determining the optimum thrust value should be investigated. If thrust value is less than optimum level, the flight safety runs a risk. Otherwise, fuel consumption goes high and some unwanted vibrations occur that cause uncomfortable flight. In this study, multi-layer perceptron ANNs, which are one of the intelligent optimization methods and frequently used in the literature, are preferred to predict the optimum thrust value during take-off, cruise and landing. The actual flight data, which is taken from the black box of an Airbus A319 aircraft, is used to train ANN models using back propagation algorithms. Velocity, altitude and ambient temperature values of the aircraft are selected as inputs and the thrust value is selected as output. During the training process of ANN, eight different training algorithms with different structures are used to figure out optimum ANN model with minimum error. Findings Different ANN models were trained using eight different training algorithms. The ANN model with minimum error has multi-layer perceptron structure, which is trained using Levenberg–Marquardt (LM) algorithm. Research limitations/implications To obtain the ANN structure with minimum error training, process takes more than a day depending on the capacity of a computer for LM training algorithm. But after training process, the trained ANN model produces sufficient output in a few milliseconds. Practical implications Totally 15,670 input-output data sets are obtained from an Airbus A319 aircraft. 12,889 of them are used as training data and the rest of the data sets, selected randomly are used as test data. Test data sets are never used in training phase, and the obtained results show that the ANN model successfully predicts thrust value using unseen input data. Social implications The ANN could be used as an alternative method to predict other flight control parameters of aircrafts. Originality/value To the best of authors’ knowledge, this study is the first example in literature to predict the thrust value of the aircraft using ANN. PurposeThe purpose of this study is to make artificial neural network (ANN)-based prediction about thrust using the flight control parameters of aircrafts.Design/methodology/approachIn today’s transportation, airplanes have an important place because of their safety, quality and speed. One of the most important parameters affecting the secure flying of aircrafts is the thrust value of aircraft engines. Determining the optimum thrust value should be investigated. If thrust value is less than optimum level, the flight safety runs a risk. Otherwise, fuel consumption goes high and some unwanted vibrations occur that cause uncomfortable flight. In this study, multi-layer perceptron ANNs, which are one of the intelligent optimization methods and frequently used in the literature, are preferred to predict the optimum thrust value during take-off, cruise and landing. The actual flight data, which is taken from the black box of an Airbus A319 aircraft, is used to train ANN models using back propagation algorithms. Velocity, altitude and ambient temperature values of the aircraft are selected as inputs and the thrust value is selected as output. During the training process of ANN, eight different training algorithms with different structures are used to figure out optimum ANN model with minimum error.FindingsDifferent ANN models were trained using eight different training algorithms. The ANN model with minimum error has multi-layer perceptron structure, which is trained using Levenberg–Marquardt (LM) algorithm.Research limitations/implicationsTo obtain the ANN structure with minimum error training, process takes more than a day depending on the capacity of a computer for LM training algorithm. But after training process, the trained ANN model produces sufficient output in a few milliseconds.Practical implicationsTotally 15,670 input-output data sets are obtained from an Airbus A319 aircraft. 12,889 of them are used as training data and the rest of the data sets, selected randomly are used as test data. Test data sets are never used in training phase, and the obtained results show that the ANN model successfully predicts thrust value using unseen input data.Social implicationsThe ANN could be used as an alternative method to predict other flight control parameters of aircrafts.Originality/valueTo the best of authors’ knowledge, this study is the first example in literature to predict the thrust value of the aircraft using ANN.
Author	Yildirim Dalkiran, Fatma Toraman, Mustafa
Author_xml	– sequence: 1 givenname: Fatma surname: Yildirim Dalkiran fullname: Yildirim Dalkiran, Fatma email: fatmay@erciyes.edu.tr – sequence: 2 givenname: Mustafa surname: Toraman fullname: Toraman, Mustafa email: mustafa_toraman025@hotmail.com
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Snippet	Purpose The purpose of this study is to make artificial neural network (ANN)-based prediction about thrust using the flight control parameters of aircrafts.... PurposeThe purpose of this study is to make artificial neural network (ANN)-based prediction about thrust using the flight control parameters of...
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SubjectTerms	Aircraft Aircraft engines Algorithms Altitude Ambient temperature Artificial neural networks Automobiles Aviation Back propagation networks Datasets Design parameters Energy consumption Flight control Flight data recorders Flight safety Gas turbine engines Gases Mathematical models Methods Multilayers Neural networks Optimization Propagation velocity Sea level Thrust Transportation safety Unmanned aerial vehicles
Title	Predicting thrust of aircraft using artificial neural networks
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