Finite Sample Analysis of Subspace Identification for Stochastic Systems

Abstract

The subspace identification method (SIM) has become a widely adopted approach for the identification of discrete-time linear time-invariant (LTI) systems. In this paper, we derive finite sample high-probability error bounds for the system matrices A,C, the Kalman filter gain K and the estimation of system poles. Specifically, we demonstrate that, ignoring the logarithmic factors, for an n-dimensional LTI system with no external inputs, the estimation error of these matrices decreases at a rate of at least O(1/N) , while the estimation error of the system poles decays at a rate of at least O(N-1/2n) , where N represents the number of sample trajectories. Furthermore, we reveal that achieving a constant estimation error requires a super-polynomial sample size in n/m , where n/m denotes the state-to-output dimension ratio. Finally, numerical experiments are conducted to validate the non-asymptotic results.