Abstract

AimFuzzy wavelet neural network (FWNN) has proven to be a promising strategy in the identification of nonlinear systems. The network considers both global and local properties, deals with imprecision present in sensory data, leading to desired precisions. In this paper, we proposed a new FWNN model nominated “Fuzzy Jump Wavelet Neural Network” (FJWNN) for identifying dynamic nonlinear-linear systems, especially in practical applications.MethodsThe proposed FJWNN is a fuzzy neural network model of the Takagi-Sugeno-Kang type whose consequent part of fuzzy rules is a linear combination of input regressors and dominant wavelet neurons as a sub-jump wavelet neural network. Each fuzzy rule can locally model both linear and nonlinear properties of a system. The linear relationship between the inputs and the output is learned by neurons with linear activation functions, whereas the nonlinear relationship is locally modeled by wavelet neurons. Orthogonal least square (OLS) method and genetic algorithm (GA) are respectively used to purify the wavelets for each sub-JWNN. In this paper, fuzzy rule induction improves the structure of the proposed model leading to less fuzzy rules, inputs of each fuzzy rule and model parameters. The real-world gas furnace and the real electromyographic (EMG) signal modeling problem are employed in our study. In the same vein, piecewise single variable function approximation, nonlinear dynamic system modeling, and Mackey–Glass time series prediction, ratify this method superiority. The proposed FJWNN model is compared with the state-of-the-art models based on some performance indices such as RMSE, RRSE, Rel ERR%, and VAF%.ResultsThe proposed FJWNN model yielded the following results: RRSE (mean±std) of 10e-5±6e-5 for piecewise single-variable function approximation, RMSE (mean±std) of 2.6–4±2.6e-4 for the first nonlinear dynamic system modelling, RRSE (mean±std) of 1.59e-3±0.42e-3 for Mackey–Glass time series prediction, RMSE of 0.3421 for gas furnace modelling and VAF% (mean±std) of 98.24±0.71 for the EMG modelling of all trial signals, indicating a significant enhancement over previous methods.ConclusionsThe FJWNN demonstrated promising accuracy and generalization while moderating network complexity. This improvement is due to applying main useful wavelets in combination with linear regressors and using fuzzy rule induction. Compared to the state-of-the-art models, the proposed FJWNN yielded better performance and, therefore, can be considered a novel tool for nonlinear system identification.

Highlights

  • System identification is a challenging work in the many fields of engineering, which is concerned with achieving the model of dynamic nonlinear or linear systems based on the input and output observations, especially from experimental data with prior knowledge or inadequate information [1]

  • number of rules (NOR), Number of rules; NOP, Number of model parameters; root relative square error (RRSE), Root relative square error; Fuzzy Jump Wavelet Neural Network” (FJWNN), Fuzzy jump wavelet neural network; 2FWNN, Type 2 fuzzy wavelet neural network; FWNNII, Fuzzy wavelet neural network II; T2WNN, Type 2 wavelet neural network; fuzzy wavelet neural networks (FWNN), Fuzzy wavelet neural network; - - No information is mentioned in the reference

  • NOR, Number of rules; NOP, Number of model parameters; root mean square error (RMSE), Root mean square error; FWNN, Fuzzy wavelet neural network; PRWNN, Pipeline recurrent wavelet neural network; FCM, Fuzzy C-means clustering; - - No information is mentioned in the reference

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Summary

Aim

Fuzzy wavelet neural network (FWNN) has proven to be a promising strategy in the identification of nonlinear systems. The network considers both global and local properties, deals with imprecision present in sensory data, leading to desired precisions. We proposed a new FWNN model nominated “Fuzzy Jump Wavelet Neural Network” (FJWNN) for identifying dynamic nonlinear-linear systems, especially in practical applications

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Results
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Introduction
Materials and methods
Results and discussion
Method

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