Evolutionary‐Based Sparse Regression for the Experimental Identification of Duffing Oscillator

Published in Mathematical Problems in Engineering, 2020

In this paper, an evolutionary-based sparse regression algorithm is proposed and applied onto experimental data collected from a Duffing oscillator setup and numerical simulation data. Our purpose is to identify the Coulomb friction terms as part of the ordinary differential equation of the system. Correct identification of this nonlinear system using sparse identification is hugely dependent on selecting the correct form of nonlinearity included in the function library. Consequently, in this work, the evolutionary-based sparse identification is replacing the need for user knowledge when constructing the library in sparse identification. Constructing the library based on the data-driven evolutionary approach is an effective way to extend the space of nonlinear functions, allowing for the sparse regression to be applied on an extensive space of functions. The results show that the method provides an effective algorithm for the purpose of unveiling the physical nature of the Duffing oscillator. In addition, the robustness of the identification algorithm is investigated for various levels of noise in simulation. The proposed method has possible applications to other nonlinear dynamic systems in mechatronics, robotics, and electronics.

Recommended citation: Saeideh Khatiry Goharoodi, Kevin Dekemele, Mia Loccufier, Luc Dupre, Guillaume Crevecoeur (2020). Evolutionary‐Based Sparse Regression for the Experimental Identification of Duffing Oscillator. Mathematical Problems in Engineering, 2020(1), 7286575.
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