Abstract
This dissertation aims to develop an effective and practical method to forecast chaotic time series. Chaotic behaviour has been observed in the areas of marketing, stock markets, supply chain management, foreign exchange rates, weather forecasting and many others. An effective forecasting model can reduce the potential risks and uncertainty and facilitate planning and decision making in chaotic systems. In this study, residual analysis using a combination of the embedding theorem and ensemble artificial neural networks is adopted to forecast chaotic time series. Based on the embedding theorem, the embedding parameters are determined and the time series is reconstructed into proper phase space points. The embedded phase space points are fed into the first neural network and trained. The weights and biases are kept to predict the future values of phase space points and accordingly to obtain future values of chaotic time series. The residual of the predicted time series is further analyzed; and, if a chaotic behaviour is observed, then the residuals are processed as a new chaotic time series and predicted. This iterative residual analysis can be repeated several times depending on the desired accuracy level and computational efficiency. Finally, the last neural network is trained using neural networks' result values of the time series and the residuals as input and the original time series as output. The initial weights and biases of the neural networks are improved using genetic algorithms. Taguchi's design of experiments is adopted to identify appropriate factor-level combinations to improve the result of the proposed forecasting method. A systematic approach is proposed to improve the combination of ensemble artificial neural networks and their parameters. The proposed methodology is applied to a number of benchmark and some real life chaotic time series. In addition, the proposed forecasting method has been applied to financial sector time series, namely, the stock markets and foreign exchange rates. The experimental results confirm that the proposed method can predict the chaotic time series more effectively in terms of error indices when compared with other forecasting methods in the literature.
Highlights
1.1 Background and MotivationOver the last several decades, prediction of chaotic time series has been a popular and challenging subject
In order to evaluate the prediction performance and compare it with the results reported in the literature, the mean squared error (MSE) and the normalized mean squared error (NMSE) are calculated by Eq (27) and Eq (28), respectively
In order to evaluate the prediction performance and compare it with the results reported in the literature, the mean squared error (MSE), normalized mean squared error (NMSE) and root mean squared error (RMSE) are calculated according to Eq (27), Eq (28) and Eq (34), respectively
Summary
1.1 Background and MotivationOver the last several decades, prediction of chaotic time series has been a popular and challenging subject. Chaotic time series show the characteristics of dynamical systems as random, in the embedding phase space, they present deterministic behaviour [1]. An early application of chaos theory was proposed in modelling and data analysis of mixing processes [2,3]. Data analysis methods developed for the analysis of chaotic behaviour have been applied to bulk chemical reactions [7]. The idea of DOE was first introduced by Sir Ronald Fisher in the early 1920s when he proposed a systematic and analytical method to determine the impact of multiple factors on the output of his experiments [213,214]. Taguchi’s DOE is usually performed with the aid of an analysis of variance (ANOVA) It is one of the most effective techniques for improving the performance of a system by selecting the optimum levels for the involved parameters
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