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Arabian Journal for Science and Engineering
Published in: Arabian Journal for Science and Engineering 8/2022

10-11-2021 | Research Article-Computer Engineering and Computer Science

An Improved Animal Migration Optimization Algorithm to Train the Feed-Forward Artificial Neural Networks

Author: Şaban Gülcü

Published in: Arabian Journal for Science and Engineering | Issue 8/2022

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Abstract

The most important and demanding part of the artificial neural network is the training process which involves finding the most suitable values for the weights in the network architecture, a challenging optimization problem. Gradient approaches and the meta-heuristic approaches are two methods extensively used to optimize the weights in the network. Gradient approaches have serious disadvantages including getting stuck in local optima, inadequate exploration, etc. To overcome these disadvantages, meta-heuristic approaches are preferred in training the artificial neural network instead of gradient methods. Therefore, in this study, an improved animal migration optimization algorithm with the Lévy flight feature was proposed to train the multilayer perceptron. The proposed hybrid algorithm is named IAMO-MLP. The main contributions of this article are that the IAMO algorithm was developed, the IAMO-MLP algorithm can successfully escape from local optima, and the initial positions did not affect the performance of the IAMO-MLP algorithm. The enhanced algorithm was tested and validated against a wider set of benchmark functions and indicated that it substantially outperformed the original implementation. Afterward, the IAMO-MLP was compared with ten algorithms on five classification problems (xor, balloon, iris, breast cancer, and heart) and one real-world problem in terms of mean squared error, classification accuracy, and nonparametric statistical Friedman test. According to the results, the IAMO was successful in training the multilayer perceptron.
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Literature
1.
Turkoglu, B.; Kaya, E.: Training multi-layer perceptron with artificial algae algorithm. Eng. Sci. Technol. Int. J. 23, 1342–1350 (2020)
2.
Öztemel, E.: Yapay sinir ağları Artificial Neural Networks. Papatya Publishing, London (2012)
3.
Frimpong, E.A.; Oluwasanmi, A.; Baagyere, E.Y.; Zhiguang, Q.: A feedforward artificial neural network model for classification and detection of type 2 diabetes. J. Phys. Conf. Ser. 1734, 012026 (2021)CrossRef
4.
Tümer, A.; Edebali, S.; Gülcü, Ş: Modeling of removal of chromium (VI) from aqueous solutions using artificial neural network. Iran. J. Chem. Chem. Eng. 39, 163–175 (2020)
5.
Sarkar, S.D.; KB, A.S.: Face recognition using artificial neural network and feature extraction. In: 2020 7th International Conference on Signal Processing and Integrated Networks (SPIN), IEEE, pp. 417–422 (2020)
6.
Patel, P.; Doss, A.S.A.; Kalyan, L.P.; Tarwadi, P.J.: Speech recognition using neural network for mobile robot navigation. Trends Mech. Biomed. Des. 6, 665–676 (2021)CrossRef
7.
Madenci, E.; Gülcü, Ş: Optimization of flexure stiffness of FGM beams via artificial neural networks by mixed FEM. Struct. Eng. Mech. 75, 633–642 (2020)
8.
Kamal, L.; Kodaz, H.: Training artificial neural network by bat optimization algorithms. Int. J. Adv. Comput. Eng. Netw. 5, 53–56 (2017)
9.
Tang, R.; Fong, S.; Deb, S.; Vasilakos, A.V.; Millham, R.C.: Dynamic group optimisation algorithm for training feed-forward neural networks. Neurocomputing 314, 1–19 (2018)CrossRef
10.
Chiclana, F.; Kumar, R.; Mittal, M.; Khari, M.; Chatterjee, J.M.; Baik, S.W.: ARM–AMO: an efficient association rule mining algorithm based on animal migration optimization. Knowl.-Based Syst. 154, 68–80 (2018)CrossRef
11.
Hou, L.; Gao, J.; Chen, R.: An information entropy-based animal migration optimization algorithm for data clustering. Entropy 18, 185 (2016)CrossRef
12.
Duraki, S.; Demirci, S.; Aslan, S.: UAV placement with animal migration optimization algorithm. In: 2020 28th Telecommunications Forum (TELFOR), IEEE, pp. 1–4 (2020)
13.
Verma, J.; Kesswani, N.: AMIGM: animal migration inspired group mobility model for mobile Ad hoc networks. Scalable Comput. Pract. Exper. 20, 577–590 (2019)CrossRef
14.
Chinta, P.; Subhashini, K.; Satapathy, J.: Optimal power flow using a new evolutionary approach: animal migration optimization (2018)
15.
Ülker, E.: An elitist approach for solving the traveling salesman problem using an animal migration optimization algorithm. Turk. J. Electr. Eng. Comput. Sci. 26, 605–617 (2018)CrossRef
16.
Morales, A.; Crawford, B.; Soto, R.; Lemus-Romani, J.; Astorga, G.; Salas-Fernández, A.; Rubio, J.-M.: Optimization of bridges reinforcement by conversion to tied arch using an animal migration algorithm. In: International Conference on Industrial, Engineering and Other Applications of Applied Intelligent Systems, Springer, pp. 827–834 (2019)
17.
Farshi, T.R.: A multilevel image thresholding using the animal migration optimization algorithm. Iran J. Comput. Sci. 2, 9–22 (2019)CrossRef
18.
Aljarah, I.; Faris, H.; Mirjalili, S.: Optimizing connection weights in neural networks using the whale optimization algorithm. Soft. Comput. 22, 1–15 (2018)CrossRef
19.
Benmessahel, I.; Xie, K.; Chellal, M.: A new evolutionary neural networks based on intrusion detection systems using multiverse optimization. Appl. Intell. 48, 2315–2327 (2018)CrossRef
20.
Chatterjee, S.; Sarkar, S.; Hore, S.; Dey, N.; Ashour, A.S.; Balas, V.E.: Particle swarm optimization trained neural network for structural failure prediction of multistoried RC buildings. Neural Comput. Appl. 28, 2005–2016 (2017)CrossRef
21.
Tezel, G.; Uymaz, S.A.; Yel, E.: Combining artificial Algae Algorithm to artificial neural network for optimization of weights. Data Sci. Appl. 1, 37–44 (2018)
22.
Yamany, W.; Fawzy, M.; Tharwat, A.; Hassanien, A.E.: Moth-flame optimization for training multi-layer perceptrons. In: 2015 11th International Computer Engineering Conference (ICENCO), IEEE, pp. 267–272 (2015)
23.
Jaddi, N.S.; Abdullah, S.; Hamdan, A.R.: Optimization of neural network model using modified bat-inspired algorithm. Appl. Soft Comput. 37, 71–86 (2015)CrossRef
24.
Erdoğan, F.; Gülcü, Ş.: Training of Artificial Neural Networks using Meta Heuristic Algorithms. In: The International Aluminium-Themed Engineering and Natural Sciences Conference (IATENS19), Konya, Turkey, pp. 124–128 (2019).
25.
Mirjalili, S.: How effective is the Grey Wolf optimizer in training multi-layer perceptrons. Appl. Intell. 43, 150–161 (2015)CrossRef
26.
Gülcü, Ş: Training of the artificial neural networks using states of matter search algorithm. Int. J. Intell. Syst. Appl. Eng. 8, 131–136 (2020)CrossRef
27.
Zivkovic, M.; Bacanin, N.; Venkatachalam, K.; Nayyar, A.; Djordjevic, A.; Strumberger, I.; Al-Turjman, F.: COVID-19 cases prediction by using hybrid machine learning and beetle antennae search approach. Sustain. Cities Soc. 66, 102669 (2021)CrossRef
28.
De Rosa, G.H.; Papa, J.P.; Yang, X.-S.: Handling dropout probability estimation in convolution neural networks using meta-heuristics. Soft. Comput. 22, 6147–6156 (2018)CrossRef
29.
Cuevas, E.; Echavarría, A.; Ramírez-Ortegón, M.A.: An optimization algorithm inspired by the States of Matter that improves the balance between exploration and exploitation. Appl. Intell. 40, 256–272 (2014)CrossRef
30.
Hagan, M.; Demuth, H.; Beale, M.: Neural Network Design. PWS, Boston (1996)
31.
Moghaddam, A.H.; Moghaddam, M.H.; Esfandyari, M.: Stock market index prediction using artificial neural network. J. Econ. Finance Administr. Sci. 21, 89–93 (2016)CrossRef
32.
Salah, M.; Altalla, K.; Salah, A.; Abu-Naser, S.S.: Predicting medical expenses using artificial neural network. Int. J. Eng. Inf. Syst. 2, 11–17 (2018)
33.
34.
Beşikçi, E.B.; Arslan, O.; Turan, O.; Ölçer, A.: An artificial neural network based decision support system for energy efficient ship operations. Comput. Oper. Res. 66, 393–401 (2016)MATHCrossRef
35.
Torabi-Kaveh, M.; Naseri, F.; Saneie, S.; Sarshari, B.: Application of artificial neural networks and multivariate statistics to predict UCS and E using physical properties of Asmari limestones. Arab. J. Geosci. 8, 2889–2897 (2015)CrossRef
36.
Elkatatny, S.; Tariq, Z.; Mahmoud, M.: Real time prediction of drilling fluid rheological properties using Artificial Neural Networks visible mathematical model (white box). J. Petrol. Sci. Eng. 146, 1202–1210 (2016)CrossRef
37.
Bre, F.; Gimenez, J.M.; Fachinotti, V.D.: Prediction of wind pressure coefficients on building surfaces using artificial neural networks. Energy and Buildings 158, 1429–1441 (2018)CrossRef
38.
Ahire, J.: Artificial Neural Networks: the Brain behind AI, Lulu. com, (2018)
39.
Braha, D.: Global civil unrest: contagion, self-organization, and prediction. PloS One 7, e48596 (2012)CrossRef
40.
Li, X.; Zhang, J.; Yin, M.: Animal migration optimization: an optimization algorithm inspired by animal migration behavior. Neural Comput. Appl. 24, 1867–1877 (2014)CrossRef
41.
Lai, Z.; Hu, X.; Jiang, C.: An intelligent algorithm with interactive learning mechanism for high-dimensional optimization problem based on improved animal migration optimization. Concurr. Comput. Pract. Exper. 5, e5774 (2020)
42.
Cao, Y.; Li, X.; Wang, J.: Opposition-based animal migration optimization. Math. Problems Eng. 2, 19 (2013)MathSciNetMATH
43.
Humphries, N.E.; Queiroz, N.; Dyer, J.R.; Pade, N.G.; Musyl, M.K.; Schaefer, K.M.; Fuller, D.W.; Brunnschweiler, J.M.; Doyle, T.K.; Houghton, J.D.: Environmental context explains Lévy and Brownian movement patterns of marine predators. Nature 465, 1066–1069 (2010)CrossRef
44.
45.
Bachir, R.; Mohammed, A.M.S.; Habib, T.: Using artificial neural networks approach to estimate compressive strength for rubberized concrete. Periodica Polytechnica Civ. Eng. 62, 858–865 (2018)
46.
Kennedy, J.; Eberhart, R.: Particle swarm optimization. In: Proceedings of ICNN'95-International Conference on Neural Networks, Institute of Electrical and Electronics Engineers (IEEE), pp. 1942–1948 (1995)
47.
Storn, R.; Price, K.: Differential evolution–a simple and efficient heuristic for global optimization over continuous spaces. J. Global Optim. 11, 341–359 (1997)MathSciNetMATHCrossRef
48.
Simon, D.: Biogeography-based optimization. IEEE Trans. Evol. Comput. 12, 702–713 (2008)CrossRef
49.
Yang, X.-S.; Deb, S.: Cuckoo search via Lévy flights. In: IEEE 2009 World congress on nature & biologically inspired computing (NaBIC), pp. 210–214 (2009).
50.
Yang, X.-S.: Firefly algorithm, Levy flights and global optimization. In: Research and development in intelligent systems XXVI, Springer, pp. 209–218 (2010)
51.
Rashedi, E.; Nezamabadi-Pour, H.; Saryazdi, S.: GSA: a gravitational search algorithm. Inf. Sci. 179, 2232–2248 (2009)MATHCrossRef
52.
Karaboga, D.; Basturk, B.: A powerful and efficient algorithm for numerical function optimization: artificial bee colony (ABC) algorithm. J. Global Optim. 39, 459–471 (2007)MathSciNetMATHCrossRef
53.
Raj, B.; Ganesan, N.; Shashikala, A.: Engineering properties of self-compacting rubberized concrete. J. Reinf. Plast. Compos. 30, 1923–1930 (2011)CrossRef
54.
Duplan, F.; Abou-Chakra, A.; Turatsinze, A.; Escadeillas, G.; Brule, S.; Masse, F.: Prediction of modulus of elasticity based on micromechanics theory and application to low-strength mortars. Constr. Build. Mater. 50, 437–447 (2014)CrossRef
55.
Gesoğlu, M.; Güneyisi, E.; Khoshnaw, G.; İpek, S.: Investigating properties of pervious concretes containing waste tire rubbers. Constr. Build. Mater. 63, 206–213 (2014)CrossRef
56.
Topcu, I.B.; Sarıdemir, M.: Prediction of properties of waste AAC aggregate concrete using artificial neural network. Comput. Mater. Sci. 41, 117–125 (2007)CrossRef
57.
Gandomi, A.H.; Alavi, A.H.: Krill herd: a new bio-inspired optimization algorithm. Commun. Nonlinear Sci. Numer. Simul. 17, 4831–4845 (2012)MathSciNetMATHCrossRef
58.
Wang, G.-G.; Deb, S.; Cui, Z.: Monarch butterfly optimization. Neural Comput. Appl. 31, 1995–2014 (2019)CrossRef
59.
Wang, G.-G.; Deb, S.; Coelho, L.D.S.: Earthworm optimisation algorithm: a bio-inspired metaheuristic algorithm for global optimisation problems. Int. J. Bio-inspired Comput. 12, 1–22 (2018)CrossRef
60.
Li, J.; Lei, H.; Alavi, A.H.; Wang, G.-G.: Elephant herding optimization: variants, hybrids, and applications. Mathematics 8, 1415 (2020)CrossRef
61.
Wang, G.-G.: Moth search algorithm: a bio-inspired metaheuristic algorithm for global optimization problems. Memetic Comput. 10, 151–164 (2018)CrossRef
62.
Li, S.; Chen, H.; Wang, M.; Heidari, A.A.; Mirjalili, S.: Slime mould algorithm: A new method for stochastic optimization. Futur. Gener. Comput. Syst. 111, 300–323 (2020)CrossRef
63.
Heidari, A.A.; Mirjalili, S.; Faris, H.; Aljarah, I.; Mafarja, M.; Chen, H.: Harris hawks optimization: Algorithm and applications. Futur. Gener. Comput. Syst. 97, 849–872 (2019)CrossRef
Metadata
Title
An Improved Animal Migration Optimization Algorithm to Train the Feed-Forward Artificial Neural Networks
Author
Şaban Gülcü
Publication date
10-11-2021
Publisher
Springer Berlin Heidelberg
Published in
Arabian Journal for Science and Engineering / Issue 8/2022
Print ISSN: 2193-567X
Electronic ISSN: 2191-4281
DOI
https://doi.org/10.1007/s13369-021-06286-z

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