Finite Sample Analysis of System Poles for Ho-Kalman Algorithm
Abstract
The Ho-Kalman algorithm has been widely employed for the identification of discrete-time linear time-invariant (LTI) systems. In this paper, we investigate the pole estimation error for the Ho-Kalman algorithm based on finite input/output sample data. Building upon prior works, we derive finite sample error bounds for system pole estimation in both single-trajectory and multiple-trajectory scenarios. Specifically, we prove that, with high probability, the estimation error for an n-dimensional system decreases at a rate of at least O(T-1/2n) in the single-trajectory setting with trajectory length T, and at a rate of at least O(N-1/2n) in the multiple-trajectory setting with N independent trajectories. Furthermore, we reveal that in both settings, achieving a constant estimation error requires a super-polynomial sample size in \n/m, n/p\ , where n/m and n/p denote the state-to-output and state-to-input dimension ratios, respectively. Finally, numerical experiments are conducted to validate the non-asymptotic results of system pole estimation.
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