Online Self-Learning Stochastic Configuration Networks for Nonstationary Data Stream Analysis

Stochastic configuration networks (SCNs) have been widely used as predictive models to model complex nonlinear systems due to their advantages in terms of easy-to-implement, fast learning speed, and universal approximation property. In many fields, however, the data generated by nonlinear systems are often characterized by dynamic time series and nonstationary, which result in the learner model with poor generalization performance. This article presents an online self-learning stochastic configuration network to improve the continuous learning ability of SCNs to model nonstationary data streams. The method can autonomously adjust the parameters and structure of the network according to the real-time arriving data streams. Specifically, we use a recursive learning mechanism to update the network parameters online based on the data acquired in real time. In addition, the structure of the SCNs is dynamically adjusted by sensitivity analysis and stochastic configuration algorithm to improve the adaptive and continuous learning capability of the network. A series of comparisons are carried out over two benchmark datasets and one practical industrial case from the wastewater treatment process to verify the effectiveness of the proposed method. Experimental results demonstrate that the proposed method has good potential for nonstationary data stream analysis.

Automated summary

This article presents an online self-learning stochastic configuration network that improves the continuous learning ability of SCNs for modeling nonstationary data streams. The network autonomously adjusts parameters and structure based on real-time arriving data streams, using recursive learning mechanism and sensitivity analysis. Experimental results demonstrate the potential of the proposed method for analyzing nonstationary data streams.