Abstract
This paper proposes a novel approach for identification of nonlinear systems. By transforming the data space into a feature space, kernel methods can be used for modeling nonlinear systems. The spline kernel is adopted to produce a Hilbert space. However, a problem exists as the spline kernel-based identification method cannot deal with data with high dimensions well, resulting in huge computational cost and slow estimation speed. Additionally, owing to the large number of parameters to be estimated, the amount of training data required for accurate identification must be large enough to satisfy the persistence of excitation conditions. To solve the problem, a dimensionality reduction strategy is proposed. Transformation of coordinates is made with the tool of differential geometry. The purpose of the transformation is that no intersection of information with relevance to the output will exist between different new states, while the states with no impact on the output are extracted, which are then abandoned when constructing the model. Then, the dimension of the kernel-based model is reduced, and the number of parameters to be estimated is also reduced. Finally, the proposed identification approach was validated by simulations performed on experimental data from wind tunnel tests. The identification result turns out to be accurate and effective with lower dimensions.
Highlights
System identification plays an important role in control systems with applications in many fields, e.g., biology, chemistry, physics, electrical engineering, aeronautical engineering, computer engineering, and marine systems [1,2,3,4,5,6,7]
The goal of system identification is to construct the relationship between u and y, given the set of pairs ∈ (Rn, R), where xk is the value of the state vector at time k with xk = [ x1k, x2k, · · ·, xnk ] T, and n is the number of the states
A novel spine kernel-based approach with dimensionality reduction is designed for nonlinear system identification
Summary
System identification plays an important role in control systems with applications in many fields, e.g., biology, chemistry, physics, electrical engineering, aeronautical engineering, computer engineering, and marine systems [1,2,3,4,5,6,7]. The artificial intelligence techniques applied for modeling include neural network [14,15], K-nearest neighbors [16], support vector machine [17,18,19], and kernel methods [20,21]. Each of these artificial techniques has its own characteristics. There exists a problem for kernel method that, in cases with large dimensions, the performance of kernel-based identification method is poor due to the many parameters to be estimated, together with the large computational cost and low constructing speed.
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