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Neural Computing and Applications

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07.07.2020 | Original Article

Time series forecasting with feedforward neural networks trained using particle swarm optimizers for dynamic environments

verfasst von: Salihu A. Abdulkarim, Andries P. Engelbrecht

Erschienen in: Neural Computing and Applications | Ausgabe 7/2021

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Abstract

Several studies have applied particle swarm optimization (PSO) algorithms to train neural networks (NNs) for time series forecasting and the results indicated good performance. These studies, however, assumed static environments, making the PSO trained NNs unsuitable for forecasting many real-world time series which are generated by non-stationary processes. This study formulates training of a NN forecaster as a dynamic optimization problem, to investigate the application of a dynamic PSO algorithm to train NNs in forecasting time series in non-stationary environments. For this purpose, a set of experiments were conducted on three simulated and seven real-life time series forecasting problems under four different dynamic scenarios. Results obtained are compared to the results of NNs trained using a standard PSO and resilient backpropagation (Rprop). The results show that the NNs trained using dynamic PSO algorithms outperform the NNs trained using PSO and Rprop. These findings highlight the potential of using dynamic PSO in training NNs for real-world forecasting applications.

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Abdulkarim S, Garko A (2016) Effectiveness of firefly algorithm based neural network in time series forecasting. Bayero J Pure Appl Sci 9(1):6–10CrossRef

Abdulkarim SA (2018) Time series forecasting using dynamic particle swarm optimizer trained neural networks. Phd thesis, University of Pretoria

Abdulkarim SA, Engelbrecht AP (2019) Time series forecasting using neural networks: Are recurrent connections necessary? Neural Process Lett 50:2763–2795CrossRef

Adhikari R, Agrawal RK (2011) Effectiveness of PSO based neural network for seasonal time series forecasting. In: Proceedings of the fifth Indian international conference on artificial intelligence, pp 231–244

Ahmadi MH, Aghaj SSG, Nazeri A (2013) Prediction of power in solar stirling heat engine by using neural network based on hybrid genetic algorithm and particle swarm optimization. Neural Comput Appl 22(6):1141–1150CrossRef

Blackwell T, Branke J (2006) Multiswarms, exclusion, and anti-convergence in dynamic environments. IEEE Trans Evol Comput 10(4):459–472CrossRef

Blackwell T, Branke J, Li X (2008) Particle swarms for dynamic optimization problems. Swarm intelligence. Springer, Berlin pp 193–217

Blackwell TM, Bentley PJ (2002) Dynamic search with charged swarms. In: Proceedings of the genetic and evolutionary computation conference, pp 9–16

Box GEP, Jenkins GM, Reinsel GC, Ljung GM (2015) Time series analysis: forecasting and control. Wiley, New YorkMATH

10.

Brezak D, Bacek T, Majetic D, Kasac J, Novakovic B (2012) A comparison of feed-forward and recurrent neural networks in time series forecasting. In: Proceedings of IEEE conference on computational intelligence for financial engineering and economics, pp 1–6

11.

Carlisle A, Dozier G (2000) Adapting particle swarm optimization to dynamic environments. Int Conf Artif Intell 1:429–434

12.

Carlisle A, Dozler G (2002) Tracking changing extrema with adaptive particle swarm optimizer. In: Automation congress, 2002 proceedings of the 5th biannual world, vol 13. IEEE, pp 265–270

13.

Chatfield C (2016) The analysis of time series: an introduction. CRC Press, Boca RatonMATH

14.

Deb C, Zhang F, Yang J, Lee SE, Shah KW (2017) A review on time series forecasting techniques for building energy consumption. Renew Sustain Energy Rev 74:902–924CrossRef

15.

Demšar J (2006) Statistical comparisons of classifiers over multiple data sets. J Mach Learn Res 7(Jan):1–30MathSciNetMATH

16.

Duhain JGOL (2011) Particle swarm optimization in dynamically changing environment an empirical study. MSc Thesis, University of Pretoria

17.

Eberhart RC, Kennedy J (1995) Particles swarm optimization. In: Proceedings of IEEE international conference on neural networks, Perth, Australia, pp 1942–1948

18.

Engelbrecht AP (2007) Computational intelligence: an introduction. Wiley, New YorkCrossRef

19.

Frank RJ, Davey N, Hunt SP (2001) Time series prediction and neural networks. J Intell Robot Syst 31(1–3):91–103CrossRef

20.

Galvan IM, Isasi P (2001) Multi-step learning rule for recurrent neural models: an application to time series forecasting. Neural Process Lett 13(2):115–133CrossRef

21.

Gordan B, Armaghani DJ, Hajihassani M, Monjezi M (2016) Prediction of seismic slope stability through combination of particle swarm optimization and neural network. Eng Comput 32(1):85–97CrossRef

22.

Grimaldi EA, Grimaccia F, Mussetta M, Zich RE (2004) PSO as an effective learning algorithm for neural network applications. In: 2004 3rd International Conference on proceedings of the computational electromagnetics and its applications, 2004 (ICCEA 2004). IEEE, pp 557–560

23.

Hajihassani M, Armaghani DJ, Monjezi M, Mohamad ET, Marto A (2015) Blast-induced air and ground vibration prediction: a particle swarm optimization-based artificial neural network approach. Environ Earth Sci 74(4):2799–2817CrossRef

24.

Hamzacebi C (2008) Improving artificial neural networks performance in seasonal time series forecasting. Inf Sci 178(23):4550–4559CrossRef

25.

Harrison KR, Ombuki-berman BM, Engelbrecht AP (2016) A radius-free quantum particle swarm optimization technique for dynamic optimization problems. In: Proceedings of IEEE congress on evolutionary computation, pp 578–585

26.

Hornik K, Stinchcombe M, White H (1989) Multilayer feedforward networks are universal approximators. Neural Netw 2(5):359–366CrossRef

27.

Iqbal S, Zang X, Zhu Y, Liu X (2014) Introducing undergraduate electrical engineering students to chaotic dynamics: computer simulations with logistic map and buck converter. In: IEEE modelling symposium, pp 47–52

28.

Jha GK, Thulasiraman P, Thulasiram RK (2009) PSO based neural network for time series forecasting. In: Proceedings of IEEE international joint conference on neural networks, pp 1422–1427

29.

Jordehi AR (2014) Particle swarm optimisation for dynamic optimisation problems: a review. Neural Comput Appl 25:1507–1516CrossRef

30.

Kedrowski R, Nelson J, Nair AS, Ranganathan P (2018) Short-term seasonal energy forecasting. In: 2018 IEEE international conference on electro/information technology (EIT). IEEE, pp 696–700

31.

Kennedy J, Mendes R (2002) Population structure and particle swarm performance. Proc IEEE Congr Evol Comput 2:1671–1676

32.

Laepes A, Farben R (1987) Nonlinear signal processing using neural networks: prediction and system modelling. In: Technical Report, Los Alamos National Laboratory, Los Alamos, NM

33.

Lasheras FS, de Cos Juez FJ, Sánchez AS, Krzemień A, Fernández PR (2015) Forecasting the comex copper spot price by means of neural networks and arima models. Resour Policy 45:37–43CrossRef

34.

LeCun YA, Bottou L, Orr GB, Müller KR (2012) Efficient backprop. Neural networks: tricks of the trade. Springer, Berlin, pp 9–48CrossRef

35.

Li C, Sprott JC, Thio W (2015) Linearization of the Lorenz system. Phys Lett A 379(10):888–893MathSciNetCrossRef

36.

Li X, Dam KH (2003) Comparing particle swarms for tracking extrema in dynamic environments. IEEE Proc Evol Comput 3:1772–1779

37.

Mann HB, Whitney DR (1947) On a test of whether one of two random variables is stochastically larger than the other. Ann Math Stat 18(1):50–60MathSciNetCrossRef

38.

Milano P, Elettrotecnica D (2004) PSO as an effective learning algorithm for neural network applications. In: Proceedings of the international conference on computational electronics and its applications, pp 557–560

39.

Mohammad AA, Sohrab Z, Ali L, Ali E, Ioannis E (2013) Reservoir permeability prediction by neural networks combined with hybrid genetic algorithm and particle swarm optimization. Geophys Prospect 61(3):582–598CrossRef

40.

Momeni E, Armaghani DJ, Hajihassani M, Amin M (2015) Prediction of uniaxial compressive strength of rock samples using hybrid particle swarm optimization-based artificial neural networks. Measurement 60:50–63CrossRef

41.

Morrison RW (2003) Performance measurement in dynamic environments. In: Proceedings of the GECCO workshop on evolutionary algorithms for dynamic optimization problems, pp 5–8

42.

Pampara G, Engelbrecht AP (2015) Towards a generic computational intelligence library: preventing insanity. In: Proceedings of the IEEE symposium series on computational intelligence, pp 1460–1467

43.

Qi M, Zhang GP (2001) An investigation of model selection criteria for neural network time series forecasting. Eur J Oper Res 132(3):666–680CrossRef

44.

Rakitianskaia A (2011) Using particle swarm optimisation to train feedforward neural networks in dynamic environments. MSc. thesis, University of Pretoria

45.

Rakitianskaia A, Engelbrecht AP (2008) Cooperative charged particle swarm optimiser. In: IEEE congress on evolutionary computation, pp 933–939

46.

Rakitianskaia A, Engelbrecht AP (2009) Training neural networks with PSO in dynamic environments. In: IEEE congress on evolutionary computation, 2009 (CEC’09), pp 667–673

47.

Rakitianskaia A, Engelbrecht AP (2015) Saturation in PSO neural network training: good or evil? IEEE Congr Evol Comput 2:125–132

48.

Riedmiller M, Braun H (1993) A direct adaptive method for faster backpropagation learning: the RPROP algorithm. In: IEEE international conference on neural networks, pp 586–591

49.

Röbel A (1994) The dynamic pattern selection algorithm: effective training and controlled generalization of backpropagation neural networks. In: Technical Report, Tech- nische Universität Berlin

50.

Sitte R, Sitte J (2000) Analysis of the predictive ability of time delay neural networks applied to the S&P 500 time series. IEEE Trans Syst Man Cybern C Appl Rev 30(4):568–572CrossRef

51.

Soodi HA, Vural AM (2018) STATCOM estimation using back-propagation, PSO, shuffled frog leap algorithm, and genetic algorithm based neural networks. Comput Intell Neurosci 2018:6381610. https://doi.org/10.1155/2018/6381610

52.

Suresh A, Harish K, Radhika N (2015) Particle swarm optimization over back propagation neural network for length of stay prediction. Procedia Comput Sci 46:268–275CrossRef

53.

Tang Z, Fishwick PA (1993) Feedforward neural nets as models for time series forecasting. ORSA J Comput 5(4):374–385CrossRef

54.

Unger NJ, Ombuki-Berman BM, Engelbrecht AP (2013) Cooperative particle swarm optimization in dynamic environments. In: Proceedings of IEEE symposium on swarm intelligence, pp 172–179

55.

Van den Bergh F (2001) An analysis of particle swarm optimizers. Phd Thesis, University of Pretoria

56.

Van den Bergh F, Engelbrecht AP (2001) Effects of swarm size on cooperative particle swarm optimisers. In: Proceedings of the genetic and evolutionary computation conference, pp 892–899

57.

Van den Bergh F, Engelbrecht AP (2004) A cooperative approach to particle swarm optimization. IEEE Trans Evol Comput 8(3):225–239CrossRef

58.

Van Wyk AB, Engelbrecht AP (2010) Overfitting by PSO trained feedforward neural networks. In: IEEE congress on evolutionary computation, pp 1–8

59.

Wessels LFA, Barnard E (1992) Avoiding false local minima by proper initialization of connections. IEEE Trans Neural Netw 3(6):899–905CrossRef

60.

Yalcin N, Tezel G, Karakuzu C (2015) Epilepsy diagnosis using artificial neural network learned by PSO. Turk J Electr Eng Comput Sci 23(2):421–432CrossRef

61.

Yeh W, Yeh Y, Chang P, Ke Y, Chung V (2014) Forecasting wind power in the Mai Liao wind farm based on the multi-layer perceptron artificial neural network model with improved simplified swarm optimization. Int J Electr Power Energy Syst 55:741–748CrossRef

62.

Zhang G, Patuwo BE, Hu MY (1998) Forecasting with artificial neural networks: the state of the art. Int J Forecast 14(1):35–62CrossRef

Titel: Time series forecasting with feedforward neural networks trained using particle swarm optimizers for dynamic environments
verfasst von: Salihu A. Abdulkarim
Andries P. Engelbrecht
Publikationsdatum: 07.07.2020
Verlag: Springer London
Erschienen in: Neural Computing and Applications / Ausgabe 7/2021
Print ISSN: 0941-0643
Elektronische ISSN: 1433-3058
DOI: https://doi.org/10.1007/s00521-020-05163-4

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